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Crops, Browse and
Pollinators in Africa
An Initial Stock-taking
produced by the
African Pollinators Initiative
This publication has been supported by the FAO Netherlands Partnership
Programme and the Government of Norway
Food and Agriculture Organization of the United Nations
2007
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ROPS, BROWSE AND POLLINATORS IN AFRICA:
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FIRST PUBLISHED IN 2003 BY THE AFRICAN POLLINATOR INITIATIVE SECRETARIAT
ENVIRONMENT LIAISON CENTRE INTERNATIONAL
P.O. BOX 72461, NAIROBI, KENYA
TEL: +254 20 576119
FAX: +254 20 576125
PLANT PROTECTION RESEARCH INSTITUTE
AGRICULTURAL RESEARCH COUNCIL
PRIVATE BAG X134
PRETORIA, 0001, SOUTH AFRICA
TEL: +27 12 323-8540
FAX: +27 12 325-6998
EMAIL: [email protected]
NATIONAL MUSEUMS OF KENYA
DEPARTMENT OF INVERTEBRATE ZOOLOGY
P.O. BOX 40658, NAIROBI, KENYA
TEL: +254 20 374-2445
FAX: +254 20 374-4833
EMAIL: [email protected]
DEPARTMENT OF ZOOLOGY
UNIVERSITY OF CAPE COAST
CAPE COAST, GHANA
TEL: +233 42 31191
FAX: +233 42 32446
EMAIL: [email protected]
INTERNATIONAL CENTRE OF INSECT PHYSIOLOGY AND ECOLOGY
P.O. BOX 30772, NAIROBI, KENYA
TEL: +254 20 861680
FAX: +254 20 861690
EMAIL: [email protected]
INSECT COMMITTEE OF NATURE KENYA
The East Africa Natural History Society
P.O.Box 44486 GPO 00100
NAIROBI, Kenya
Email: [email protected]
Republished in 2007, with assistance from FAO and Nature Kenya
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ROPS, BROWSE AND POLLINATORS IN AFRICA:
List of Contributors
Connal Eardley: Agricultural Research Council, Plant Protection Research Institute (ARC-PPRI), Private
Bag X134, Pretoria, Queenswood, 0121, South Africa, Fax (+27 12) 304 9578 / 325 6998. EMAIL: EardleyC@
arc.agric.za
Barbara Gemmill-Herren: Food and Agriculture Organization. Vialle delle termedi caracalla, Roma, 0153,
Itary. Tel: +390657056835. barbara.Herr[email protected]
Mary Gikungu, Invertebrate Zoology Department, National Museums of Kenya (NMK), P.O. Box 40658,
Nairobi, Kenya. Tel/Fax (254 2) 3742 445 / 3744 833., mgikungu@yahoo.com
Rachel Kagoiya: Invertebrate Zoology Department, National Museums of Kenya (NMK), P.O. Box 40658,
Nairobi, Kenya. Tel/Fax (254 2) 3742 445 / 3744 833. [email protected]
Wanja Kinuthia: Invertebrate Zoology Department, National Museums of Kenya (NMK), P.O. Box 40658,
Nairobi, Kenya. Tel/Fax (254 2) 3742 445 / 3744 833. [email protected]
Peter Kwapong: Department of Entomology and Wildlife, University of Cape Coast, Cape Coast, Ghana. Tel/
Fax +233 42 31191/32095 pkw[email protected]
Dino Martins: Insect Committee of Nature Kenya,The East Africa Natural History Society
P.O.Box 44486 GPO 00100, NAIROBI, Kenya. [email protected]vard.edu
Grace Njoroge: Jomo Kenyatta University of Agricultural Technology, Nairobi, Kenya,
Laban Njoroge: Invertebrate Zoology Department, National Museums of Kenya (NMK), P.O. Box 40658,
Nairobi, Kenya. Tel/Fax (254 2) 3742 445 / 3744 833. [email protected]
Geoff Tribe: ARC-PPRI, Private Bag x5017, Stellenbosch, 7559, South Africa Tel/Fax (+27 21) 8874690 / 8833285,
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Table of Contents
List of Contributors iv
List of Figures and Titles vi
Frontpiece: Pollinators of Selected Crops in Africa vii
Preface viii
Summary of Lessons Learned ix
Introduction 1
Identifying the State of Knowledge 2
Farmers’ Knowledge in Kenya 2
Rachel Kagoiya
Farmers’ and Extensionists Knowledge in Ghana 2
Peter Kwapong
Research and Civil Society Organisations: Knowledge of Pollination 3
Dino Martins
In the Literature 4
Barbara Gemmill -Herren
Initial Assessments and Lessons Learned 11
Methods and Approaches 11
Fruit Crops 14
Deciduous fruit in South Africa: 14
Geoff Tribe
Watermelon in Kenya 20
Grace Njoroge, Laban Njoroge, and Barbara Gemmill
Mango in Ghana 22
Peter Kwapong and Mary Botchey
Papaya in Kenya 24
Dino Martins
Avocado in Kenya 27
Wanja Kinuthia and Laban Njoroge
NUT CROPS 29
Cashew in Ghana 29
Peter Kwapong
OIL CROPS 31
Coconut in Ghana 31
Peter Kwapong
Groundut in Ghana 33
Peter Kwapong and Wisdom Hordzi
Oil Palm in Ghana 35
Peter Kwapong and Benjamin Mensah
BROWSE 37
Acacia Pods in Kenya 37
Dino Martins
Indigofera in Kenya 43
Barbara Gemmill-Herren
BEVERAGE AND STIMULANT CROPS 45
Coffee in Kenya 45
Wanja Kinuthia, Barbara Gemmill-Herren and Laban Njoroge
Summary and Conclusion 51
Acknowledgements 53
Picture Credits 53
References Cited 54
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Frontpiece: Pollinators of Selected Crops in Africa vii
Figure 1: Subfields covered in African pollination literature 4
Figure 2: Types of research covered in African pollination literature 4
Figure 3: Interview bouquets 11
Figure 4: Peach trees in South Africa 14
Figure 5: Non-Apis visitation patterns to watermelon, Kenya 20
Figure 6: Male flowers, Watermelon 20
Figure 7: Infloresence and immature fruits of mangoes 22
Figure 8: Male flower of Papaya 24
Figure 9: Female flower of Papaya 24
Figure 10: Herse convolvuli (with tongue extended)- one of the
hawkmoths pollinating Papaya 24
Figure 11. Cashew flowers and young fruit 29
Figure 12. Female Coconut Flowers 31
Figure 13. Groundnut in flower with flower beetle feeding on petals 33
Figure 14. Female inflorescence, Oil Palm 35
Figure 15. Male inflorescence, Oil Palm 35
Figure 16. Percentage types of floral visitors to Acacia tortilis, Kerio Valley 37
Figure 17. Acacia flowers 37
Figure 18. Percentage types of floral visitors to Acacia tortilis,
close to bomas 38
Figure 19. Percentage types of floral visitors to Acacia tortilis,
natural vegetation site 38
Figure 20. Indigofera blossoms 43
Figure 21. Stingless bee nest entry 43
Figure 22. Honeybees on Coffee 46
Figure 23. Bagged Coffee inflorescences 46
Figure 24. Coffee plantation and riparian forest, with wild honeybee hives 46
Figure 25. Percentage types of floral visitors to coffee 47
Figure 26. Average number of flowers visited by taxa 47
Table 1. Commodities dependent on pollination in Africa 6
Table 2. Number of Blossums visited by a single honeybee in five minutes 15
Table 3. Floral visitor to orchard tree species at Bien Donne 16
Table 4. Floral visitors to Watermelon, Kenya 21
Table 5. Floral visitors to Mango, Ghana 23
Table 6. Floral visitors to Papaya, Kenya 25
Table 7. Floral visitors to Avocado in Gachie village,
Kiambu District, Kenya 28
Table 8. Floral visitors to Cashew, Ghana 30
Table 9. Floral visitors to Coconut , Ghana 32
Table 10. Floral visitors to Groundnut (peanut), Ghana 34
Table 11. Floral visitors to Oil Palm, Ghana 36
Table 12. Ranking of effectiveness- Acacia visitors 38
Table.13. Behaviour of floral visitors on Acacia tortilis blossoms 40
Table 14. Major bee visitors to
Indigofera spp. 44
Table 15. Other bees visiting coffee flowers 48
Table 16. Insects besides bees visiting coffee 49
List of Tables and Figures
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Frontpiece:
* note that in none of the systems studied did vertebrate pollinators play a documented role.
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ROPS, BROWSE AND POLLINATORS IN AFRICA:
Preface
When the Fifth Conference of the Parties to the Convention Biological Diversity established an International
Initiative for the Conservation and Sustainable Use of Pollinators (also known as the International Pollinators
Initiative-IPI) in 2000 (COP decision V/5, section II), FAO was requested to facilitate and co-ordinate the
Initiative in close co-operation with other relevant organisations. A Plan of Action for the IPI was adopted
at COP 6 (decision VI/5), providing an overall structure to the initiative, with four elements of assessment,
adaptive management, capacity building and mainstreaming.
FAO, through the FAO/Netherlands Partnership Programme, supported the initial establishment of a regional
African Pollinator Initiative, the development and publication of its Plan of Action in 2003, and an initial
stocktaking of pollinator-dependent crops and browse plants in Africa. The stocktaking document has only
been available in electronic form; support from the Government of Norway has permitted its publication in
2007.
We hope that the information contained in this stocktaking document will inspire others to make assessments
of pollination services in their countries or regions as appropriate. We would encourage those that do so to
share these with FAO for wider dissemination, through the following address: [email protected].
Linda Collette
FAO Responsible Officer for the IPI
Rome, Italy
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Lessons learned . . .
in South African pollination assessments
Honeybees were essential as pollinators of the five orchard crops; some exotic weed species
were beneficial to indigenous pollinators especially honeybees in supplying nectar and pollen;
but the greatest variety and numbers of pollinator species were present on indigenous flower-
ing plants.
Lessons learned . . .
in Ghanian pollination assessments
In Ghana, farmers would appreciate more extension information on pollination services.
In a rapid assessment of crop pollination, it was found that even though honeybees visit man-
gos early in the morning, the main pollinators of mango seem to be various fly species, which
remain on the little flowers most of the day. Cashew had wider species diversity of pollinators,
while for oil palm beetles are the main pollinators. The main pollinator of Coconut are sting-
less bees, some wasps and other small bees. Flower visitors to groundut were noted, including
halictid bees
Lessons learned . . .
in Kenyan pollination assessments
In Kenya, it was found that farmers’ knowledge of pollination is limited: many farmers lump
pollinators together with insect pests, and do not explicitly manage to conserve them, although
pollinators may contribute substantially to yields at no cost to the farmer. Most researchers
working on projects related to pollination are addresssing bee-keeping, or bee taxonomy. Other
aspects of pollination services are not being addressed.
In a rapid assessment of crop pollination needs, it was noted that while bees that nest in cavi-
ties are often considered the most manageable, non-honeybee pollinators of watermelon made
use of on-farm conditions to nest in the field soil. Conditions promoting them to nest could be
studied and utilised to increase watermelon pollination. Papaya needs pollinators able to fly long
distances between scattered trees with separate male and female blossoms. Recommendations
for conserving the hawkmoths that pollinate papaya effectively are needed. Although avocado
is an exotic tropical fruit to Kenya, its reproduction has adapted well to a diverse range of local
pollinators. Coffee producers do not seem to be aware that pollination can increase yields, and
are removing habitat on farm for wild bee populations.
Browse pollinators are important, but often overlooked. Most of the important Acacia pollina-
tors nest in dead wood, making room for low-tech pollination management in that farmers that
depend on this resource should not denude the areas of dead wood. Many crop and browse
pollinator species could only be identified to genera. This severely limits our ability to assess
whether they are shared amongst several crops, or specific to individual crops.
Summary of Lessons Learned
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Introduction
Pollination is an ecosystem service that is key to food security. Pollinators are essential for many fruit
and vegetable crops. In agriculture, especially amongst pollen-limited crops, promoting pollination
services is a means of increasing productivity without resorting to expensive agricultural inputs of
pesticides or herbicides. Indeed, pollination services are most likely underpinning productivity in
many crops without farmers even recognising it, so long as habitat and alternative pollinator forage
are readily available as they often are in smallholder farming systems.
By developing larger and larger fields and landscapes for agriculture, we remove the habitat that pol-
linators may need. Increasing dependence on pesticides for pest control is also highly detrimental to
beneficial insects such as pollinators, unless planned and undertken with extreme care. Pollination
is a service nature provides that we have tended to take for granted, and that we often do little to
encourage until we start to lose it. As wild ecosystems are increasingly converted to more human-
dominated uses to meet the compelling demands of food security, it is critical for us to understand
what pollination services are most important for food security, and how we can preserve pollinator
services in sustainable farming systems.
A crop’s pollinator dependence differs between species, including between crops and crop varieties.
Some plants must be cross-pollinated, others do not need pollinators but produce better fruit and
seed if pollinated, and a number are strictly self-pollinated. Further, plants differ in their pollina-
tor-type requirements; some require specific pollinators while others are pollinated by a variety of
visitors, and many are wind pollinated. Effective pollinators of the same crop may vary from one site
to another. Specific knowledge on pollinator dependence and types is important for agriculture and
biodiversity (including agro-biodiversity) conservation. With this objective, researchers in Ghana,
Kenya and South Africa were supported by the United Nations Food and Agriculture Organisation
in 2003 to undertake an initial assessment of pollination needs and gaps in knowledge of the key
pollinators of a few crops, and indigenous plants used by people or livestock (Acacia and Indigofera),
in their respective countries. This assessment included both literature reviews and field observation;
and is on-going. The long-term aim of assessments is to identify the key pollinators and prioritize
vulnerable pollination systems, in particular those in which explicit pollinator management practices
can have the most beneficial impacts. As the African Pollinator Initiative plan of action has specified,
methodologies were used that must give results that are scientifically justifiable, and comparable.
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ROPS, BROWSE AND POLLINATORS IN AFRICA:
Identifying the State of Knowledge:
Farmer’s Knowledge in Kenya
Rachel Kagoiya
Farmers around the world understand better than most of the public that good environmental health
is fundamental to their sustainable existence, but often in a holistic way that may not include an
in-depth understanding of the role of pollination. The importance of ecosystem services will not
be ‘mainstreamed’ or become considered as a part of accepted farming practice unless the farming
community understands explicitly what it is and how it works. A good example of this is pollination
services. Globally, within the United Nations Convention on Biological Diversity, and regionally,
within the African Pollinator Initiative, the contribution of pollinators for increasing genetic diversity,
adaptation, seed set or crop production and crop quality, and natural regeneration of wild species has
been recognised, and the need to conserve pollinators has been stressed. Yet the public’s, including
farmers’, knowledge of the role of pollinators, remains poor. Surveys carried out amongst farmers
in central Kenya highlighted the fact that many farmers lump pollinators together with insect pests,
and do not explicitly manage to conserve them, although pollinators may substantially contribute
to yields at no direct cost to the farmer. Ecosystem services such as pollination and soil biodiver-
sity are aspects of the environment that relate closely to human livelihoods, and may convince the
public that biodiversity is not only wild animals that may damage their crops, but also creatures that
live on their farms and help to sustain crop production. Further public awareness programmes on
ecosystem services are merited.
Farmers’ and Agricultural Extension Agents’ Knowledge in Ghana
Peter Kwapong
In Ghana, interviews with farmers, extension agents, and agricultural lecturers indicated that all of
these groups are aware of pollination and pollinators, to varying degrees. All respondents agreed
that pollination is important in agriculture and that absence of pollination will not result in fruit and
seed formation. Only a few believed that plants can reproduce vegetatively. Respondents (83%)
think that crop yield increases when flowers are sufficiently pollinated. But most people sampled
(93%) think that humans have a major role to play in ensuring adequate pollination and only a few
understood that it is a natural ecosystem service that should be allowed to go on unaided.
Farmers had limited knowledge on pollination and pollinators. With respect to pollinators, most of
the farmers said they left any insect found on plants during flowering not because they really un-
derstand their role but they think bees provide honey for medicinal purposes and also form part of
God’s creation and must be left alone. A few farmers however claim that they sprayed bees found on
their crops for fear of attack. In order to promote pollination services some of the respondents sug-
gested natural habitat should not be destroyed through bush burning, deforestation and insecticide
spraying. Some people think that pollinator friendly type of farming should be adopted to protect
pollinators from physical, chemical and biological enemies.
Extension agents had more knowledge on pollination: for example, 75% of Agricultural agents
thought that pollinators need to be protected from sprays compared to 31% of farmers who think
the same.
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But such information was not being disseminated: farmers felt that the Ministry of Agriculture had
not been proactive in promoting the awareness and occurence of pollination and the need to protect
the service. In terms of help to farmers, 49% of the agents think that they have created the pollinator
awareness to farmers. From the farmers’ point of view, 73.7% said the have had no help from the
Ministry of Agriculture on the subject whilst 26.3 said they have received such help (awarenesss).
The agents (75%) think that the Ministry has no policy to promote the awareness of pollination and
pollinators in crop production.
Civil Society and Research Organisations: Knowledge of Pollination
Dino Martins
A survey of a biodiversity conservationists and practitioners, researchers and non-governmental or-
ganisations (NGOs) in Kenya was carried out to assess the level of knowledge of pollination services.
Questionnaires were sent to all members of the African Pollinator Initiative. Most respondents were
scientists, or technicians working for scientific institutions, and to a lesser extent, from conservation
civil society organisations.
Organisations involved in conservation programmes carried out their work through community
projects, public education and awareness and ecosystem management initiatives. Only two respon-
dents identified with species-focused programmes. This highlights an important trend towards a
community and public awareness focus in terms of the conservation message, and an overwhelming
endorsement of the ecosystem approach to management practice. This is important information for
the planning of pollination-related activities and projects.
Most of the respondents working in science and conservation have a basic knowledge of pollina-
tion as the process that transfers pollen and results in fertilization. People were also aware that pol-
lination requires an agent, but only two respondents identified these in this question as including
insects. While basic knowledge of what pollination is, as a process, is widespread, fewer people are
aware that many different organisms, and insects in particular, are important pollinators. Most or-
ganisations and individuals indicated that pollination or pollinators were included in some form or
aspect of their progammes. But the means of addressing pollination was limited to: bee keeping or
taxonomy. For example, one organisation encourages farmers to grow flower-rich crops, including
sunflower and fodder trees to boost honey production. Education was seen as the main means to
incorporate knowledge on pollination and pollinators into agriculture and biodiversity conservation
projects. No organistion promoted any direct conservation needs and/or practices directly related to
pollinators. This is one area where much work can be done by API, in raising real awareness among
conservation and biodiversity-related practitioners.
Respondents identified the two most important training needs as bee/pollinator conservation (38%)
and pollination ecology/assessment (38%). Seventy percent of respondents felt that their knowledge
of pollination was only average, and 10% felt it was low. There is clear awareness of the need for
targeted education and awareness-raising among key groups- a need that API should seek to fill.
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The above responses highlight the need for a lot of groundwork on pollinator awareness among
natural biodiversity practitioners and conservationists. Knowledge on the diversity of pollinators
and range of pollination systems needs to be improved. API has a real role to play in this, through
the dissemination of existing studies and building links with institutions that can go on to develop
further pollination-related programmes.
Identifying the State of Knowledge In the Literature
Barbara Gemmill-Herren
The literature covering pollination ecology in Africa is not new: articles were published as long ago as
1890 in South Africa, on the pollination of bananas, strelizias and Traveler’s palm. (Scott-Elliot 1890)
But it is, compared to other continents, fairly sparse and not with an applied aspect. As part of a joint
publication of the African Pollinator Initiative, a comprehensive literature review was carried out, com-
piling all known literature references to pollination studies in Africa (Rodger, Balkwill and Gemmill
2004). The review was published in a special issue of the International Journal of Tropical Insect Sci-
ence, dedicated to the African Pollinator Initiative. The bibliography is intended for widespread use by
those practitioners and research organizations contemplating pollination research in Africa. It will be
continually updated and maintained
as a searchable database on the API
website, currently hosted by PPRI in
South Africa at (http://www.arc.agric.
za/home.asp?pid=3493)
The review found that of 355 ar-
ticles (now up to 400, with further
searches and publications) focused
on different aspects of pollination
in Africa, the vast majority have fo-
cused on the evolutionary aspects of
pollination syndromes and breeding
systems (Figure 1). Less than one-
fifth (72) addressed pollination in
agricultural systems, or with specific
crops. Research in Africa has iden-
tified interesting mutualisms, such
as that between figs and fig wasps
and bats and various trees (Baijnath
et al., 1983, Compton 1990, Galil
and Esikovitch 1960). Yet applied,
agricultural aspects of pollination
have received much less attention,
and many of these studies remain in
the “grey literature”, not easily trace-
able or accessible to practitioners in
the field.
F
IGURES 1 AND 2.
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Out of all the papers identified, only 93 included manipulative (experimental) work (Fig. 2). Pollina-
tion biology is a field that lends itself readily to short-term, reasonably inexpensive manipulation
experiments that can put observations and hypotheses to a test. There is scope for considerably more
hypothesis testing and deductive science than has been conducted on the continent in pollination
studies up until now.
Given the paucity of specific information linking pollination services with crop production in Africa,
people wanting to know about pollination needs in Africa will turn to the standard reference volumes
on pollination first. To assist with this, and to identify the prominent gaps in knowledge with respect
to African crops, the literature review also included the development of a table featuring the impor-
tant commercial commodities within Africa known to benefit from animal vectors for pollination,
and where information on these can be found in these reference volumes this is indicated. As it is
increasingly recognised that pollination ecology is highly site-specific, and local, native pollinators
should be promoted over exotic solutions, we have added an additional column noting if and how
many pollination studies for a particular commodity have been carried out in Africa (Table 1). This
may help us to priortise future studies, to fill in the obvious gaps.
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Table 1. Commodity Free Crane McGregor Known Studies
1996 & 1976 Pollinator(s) conducted
pages Walker from within
1984 literature Africa
pages
Grain legumes
Bambara groundnut, Self pollinated and self fertile
Voandzeia subterranea 342-3 73 - ants noted pollinating in Ghana 2
Broad beans,
Vicia faba var. major 298 23
/chap4/broad.html Self and bees 1
Common (field) bean,
Vicia faba var. minor 298 23
/chap4/broad.html Self and bees 1
Cowpea, Vigna unguiculata 341-2 107
/chap4/cow.html Self and bees 2
Lima bean, Phaseolus lunatus 269-70 22
/chap4/lima.html Self and bees 0
Pigeon pea, Cajanus cajanus 317-20 107
/chap4/pig.html Probably self and bees
but not well known 2
Vegetables
Amaranth, Amaranthus spp. - - - Not known 0
Aubergine/eggplant, Bees other than
Solanum melongena 503-4 62
/chap6/eggplant.html honeybees 0
Chayote, Sechium edule - 40
/chap6/chayote.html Not known but
insects are necessary 0
Cucumber, Cucumis sativus 196-201 58
/chap6/cucumber.html Bees 0
Hot/sweet pepper, Self and bees-
Capsicum frutescens/annum 499-500 110
/chap6/pepper.html but not well known 0
Karela, Momordica charantia 208 -
/chap6/balsam.html Bees and beetles 0
Okra, 352-4 100
/chap6/okra.html Self, bees, wasps,
Abelmoschus esculentus flies, beetles, birds? 0
Oyster nut. Telfairia pedata - - - Not known 0
French beans,
Phaseolus vulgaris 270 24
/chap4/beans.html Self and bees 0
Field peas, Pisum sativum 338-9 107 - Self and bees 0
Pumpkin, squash, marrow,
Cucurbita 203-7 69
/chap6/pumpkin.html Bees 0
Tomato,
Lycopersicon esculentum 492-8 137
/chap6/tomato.html Self and large bees 0
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Commodity Free Crane McGregor Known Studies
1996 & 1976 Pollinator(s) conducted
pages Walker from within
1984 literature Africa
pages
Fruit crops
Custard apple, cherimoya
Annona squamosa 129 40
/chap9/cherimoya.html beetles 0
Apple, Malus domestica 434-45 16
/chap5/apple.html Bees 0
Avocado, Persea americana 240-4 19
/chap5/avocado.html Bees, wasps, flies 1
Borassus palm,
Borassus flabellifer - 32 - Not known 0
Breadfruit, Artocarpus altilis 372 33 - Not well known 0
Cape gooseberry
Physalis peruviana 504 - - Not known 0
Carambola, Averrhoa carambola 391 35
/chap9/carambola.html Bees and other insects 0
Citrus, Citrus 479-85 44
/chap5/citrus.html Bees and other insects 2
Cherry, Prunus avium 431-66 41
/chap5/cherry.html Bees 0
Date palm, Phoenix dactylifera 401-2 61
/chap5/date.html Not known 0
Figs, Ficus carica 373-8 65
/chap5/fig.html Fig wasps 2
Guava, Psidium guajava 386 73
/chap7/guava.html Self, bees, other insects 0
Litchie, Litchi chinensis 487-8 88
/chap5/litchi.html Bees, flies, ants and wasps 1
Mango, Mangifera indica 124-8 90
/chap5/mango.html Not well understood 1
Marula, Sclerocarya birrea - - - Not known 0
Melon, Cucumis melo 190-6 92
/chap6/muskmelon.html Bees 0
Watermelon, Citrullus lanatus 201-3 93
/chap6/watermelon.html Bees 1
Natal Plum, Carissa grandiflora 131-2 98 - Not known 0
Papaya, Carica papaya 137-9 103
/chap5/papaya.html Hawkmoths,
skipper butterflies 3
Passion fruit, Passiflora edulis 408-9 104 /
chap5/passionfruit.html Large bees 0
Peach, Prunus persica 431-66 108
/chap5/peach.html Self and bees 0
Pears, Pyrus communis 431-66 108
/chap5/pear.html Bees 0
Plum, Prunus spp. 431-66 113
/chap5/plum.html Bees 0
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ROPS, BROWSE AND POLLINATORS IN AFRICA:
Fruit crops, continued
Commodity Free Crane McGregor Known Studies
1996 & 1976 Pollinator(s) conducted
pages Walker from within
1984 literature Africa
pages
Strawberry, Fragaria x ananassa 425-30 130 /chap7/strawberry.html Bees 0
Tamarind, Tamarindus indica 340-1 134 - Not known in Africa
(Apis dorsata in
Asia) 0
Nut crops
Cashew nut, Bees, flies
Anacardium occidentale 122-4 37
/chap5/cashew.html ants 1
Macadamia nut, Bees,
Macadamia integrifolia 418-20 89
/chap5/mac.html wasps, beetles 0
Oil Crops
Castor, Ricinis communis 226-7 38 - Wind and bees 1
Coconut, Cocos nucifera 52 52
/chap5/coconut.html Wind and bees 1
Groundnut, Arachis hypogaea 314-7 72
/chap3/peanut.html Self but bees and thrips
seen to increase production
in Congo 1
Niger seed, Guizotia abyssinica 149,161 98
/chap9/niger.html Bees but not
well known 1
Oil Palm, Elaeis guineensis 398-401 99
/chap5/oil.html Beetles 5
Safflower, Carthamus tinctorius 145-8 123
/chap9/safflower.html Self and bees 0
Sesame, Sesamum indicum 410-11 127
/chap9/sesame.html Self and bees 1
Shea,
Butryospermum pardoxum - - - Not known 0
Soybean, Glycine max 325-9 27 /chap4/soy.html Self and bees 0
Sunflower, Helianthus annus - 132
/chap9/sun.html Bees and other insects 3
Beverage/stimulant crops
Cacao, Ceratopogonid midges,
Theobroma cacao 504-14 51
/chap5/cacao.html thrips, ants 12
Cola nut, - 81
/chap7/kolanut.html Flies-
Cola acuminata and nitida but not well known 1
Coffee, Coffea spp. 475-8 53
/chap7/coffee.html Self and bees 0
page 9
A
N INITIAL STOCK-TAKING
Commodity Free Crane McGregor Known Studies
1996 & 1976 Pollinator(s) conducted
pages Walker from within
1984 iterature Africa
pages
Fibre/container Crops
Cotton, Gossypium spp. 354-9 55
/chap9/cotton.html Self, but bees
increase production 3
Bottle Gourd, Lagenaria siceria 207-8 68
/chap6/white.html Hawkmoths, bees, bats 0
Kapok, Ceiba petandra 134-5 128 - Bats, hawkmoths 1
Raffia palm, Raphia spp. - 117 - Not known 0
Forage Crops
Acacia tortilis pods - - - Bees other than honeybees,
butterflies, wasps 1?
Desmodium - Not known 1
Egyptian clover, or berseem,
Trifolium alexandrinum 271-97 30
/chap3/berseem.html Bees 7
Indigofera (browse in Africa) - - - Bees other than honeybees,
small butterflies 0
Stylosanthus - - Not known 0
Agroforestry crops
Calliandra calthyrsus - 35 - Bees 0
Gliricidium sepium - - - Not known 0
Grevillea robusta - 128 - Not known 0
Leucaena leucophala and hybrids - - - Not known 0
Sesbania sesban - - - Not known 0
Cosmetics
Bixa, Bixa orelllana (lipstick bush) - - Not known 0
Loofah sponge, 208 85
/chap6/veg.html Moths and butterflies,
Luffa cylindrica possibly bees 1
Pesticides
Mexican marigold, Tagetes lucida - - - Not known 0
Neem. Azadirachta indica - - - Not Known 0
Pyrethrum, Beetles, flies, also bees; more
Chrysanthemum cinerariifolium 148 116
/chap9/pyrethrum.html potent insecticide derived when
flowers visited by insects 2
page 10
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ROPS, BROWSE AND POLLINATORS IN AFRICA:
Rotenone, Tephrosia vogelii - 136
/chap9/tephrosia.html Not known 0
Spices
Black pepper, Piper nigrum 412-13 109
/chap9/black.html Not well known 0
Vanilla, Vanilla planifolia 389-90 141
/chap9/vanilla.html Specialised bees in area
where vanilla is indigenous;
largely by hand within
Madagascar and Africa 0
Pesticides, continued
Commodity Free Crane McGregor Known Studies
1996 & 1976 Pollinator(s) conducted
pages Walker from within
1984 iterature Africa
pages
page 11
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N INITIAL STOCK-TAKING
FIGURE 3: INTERVIEW BOUQUETS
Estimating the pollination efficiency of different pollinators
requires that a flower be exposed to a single pollinator visit,
from which the number of pollen grains can be compared to
a flower receiving no visits. Rather than wait for a specific
pollinator to visit a flower, it is possible to take the flower
to the pollinator. In
this study, interview
bouquets were
used to assess
the contribution of
a single bee visit
to coffee and wa-
termelon. Flowers,
previously bagged
to ensure that no
pollination had
taken place, were
placed in a plastic
vial filled with water,
that was attached
to the end of a long
stick.
Assessments and Lessons Learned:
Methods and Approaches
An initial assessment of crop dependence on pollination services in Africa was carried out in Ghana,
Kenya and South Africa; three countries that are sufficiently different to capture the variation in
pollination needs.
In Kenya, field assessments were carried out in on farms near Thika town in the central
province, and in arid regions both near Tsavo, in the south-east, and Kerio Valley and Lai-
kipia Plateau just north of the equator. The areas have savannah and upland forest veg-
etation and two rainy seasons, April-June and November. The results for Kenya are to
be found in the chapters on Watermelon, Avocado, Acacia pods, Indigofera and Coffee.
Field assessments were carried out in the southwestern and central regions of Ghana in ag-
ricultural fields in clearings in the coastal rain forests. In this region, rainfall occurs through-
out the year, but mainly during March to August, during which it is very wet. Flowering,
however, is mostly in the dry season when pollinators are more active. The heavy, persistent
rains along the Ghanaian coast inhibit pollinator activity during the wet season. The re-
sults are reported in the chapters on Mango, Cashew, Coconut, Groundnut and Oil Palm.
In South Africa field assessments were undertaken in the south-western region (around 34º00’S
19º00’E), among fold mountains. Here rainfall occurs in winter (June-August), and is often accompa-
nied by snow; the summers are hot and dry. The natural vegetation is cape macchia, but it is extremely
threatened and fragmented by agriculture, invasive plants and urbanization. The flowering season for
crops and wild plants is mostly in spring (August to November). Deciduous fruits (peaches, plums,
apricots, pears and apples) were studied to better understand their pollination needs.
All these countries have rich pollinator
diversity, and where the activities took
place the conservation of this biologi-
cal diversity is a matter of concern. In
Ghana and South Africa the work took
place in Conservation International
biodiversity hotspots.
Small farmers were earmarked as the
primary beneficiaries of this survey,
but some of the assessment was done
on experimental or commercial farms.
This was mainly for logistic reasons,
because it is easier to plan surveys us-
ing systematically managed farms than
informal systems. The crops studied are
important to small farmer in the study
areas.
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ROPS, BROWSE AND POLLINATORS IN AFRICA:
Visual observation was used to determine what pollinates flowers. The flower visitors potential as
pollinators was recorded. The categories for pollinator potential are:
(1) = almost certainly a pollinator, e.g., a regular visitor whose pollen load comes into contact with
the stigma.
(2) = possibly pollinates on some visits, e.g., a regular visitor whose pollen load usually does not
come into contact with stigma.
(3) = unlikely, e.g., a wasp that may carry pollen but is unlikely to visit two flowers of the same spe-
cies.
In some cases pollination efficiency was confirmed using “interview bouquets” (see Figure 3).
In Kenya and Ghana, all observations of pollinators were standardised over time and space, by
observing flowers for 10-minute periods, and counting the number of flowers in a 1-meter square
area. This protocol has been followed in several pollination studies in Kenya and is permitting the
compilation of a large database on pollination observations. Where possible, similar observations
of pollinator visitation to wild plant species growing near the crop being studied were made to as-
sess alternative forage for the pollinators, but this component of the study merits much more time
devoted to it than was possible within this rapid assessment.
In South Africa, where crops known to be pollinated by honeybees were assessed, fifteen pollen-col-
lecting honeybees were followed for five minutes and the number of blossoms visited by them during
this period was counted on each of the five species of fruit trees – peaches, plums, apricots, pears
and apples. The numbers and identities of other insect species visiting these same blossoms were
recorded (initially at 10 minute intervals, but the dearth of such pollinators and the overwhelming
presence of honeybees did not warrant continuation of this). This was to establish the comparative
attractiveness of the different blossoms to honeybees and other pollinators.
Similarly, fifteen pollen-collecting honeybees were followed for five minutes as they visited the exotic
weeds, Echium plantagineum and Raphanus raphanistrum growing in adjacent plots. This to establish
whether the blossoms of these two weed species were more attractive to bees than fruit blossoms.
Other pollinators, besides honeybees, were collected and recorded from these two weed species.
The indigenous perennial spring flowering plants growing mainly along the river banks but also
interspersed between the orchards were sampled for pollinators. Ten-minute counts were also made
of the number of the major pollinators visiting the most widespread of these species, viz. the Cape
marigold, Arctotheca calendula. Similarly, the Australian Acacia species and the South American bug-
weed (Solanum mauritianum) were inspected for pollinators. The indigenous plants would indicate
what pollinators were present and whether they also occurred on the deciduous tree blossoms and
those of the exotic weed species.
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N INITIAL STOCK-TAKING
The presence or absence of honeybees on the exotic weeds would indicate their beneficial or detri-
mental affect in allowing the build-up of colonies or by drawing bees from the possibly less attractive
deciduous species.
Manageability of pollinators was determined from the known life history of the pollinator. Pollina-
tion management for agriculture has been most successful with only a few organism groups, like
honey bees and leaf-cutter bees. This is because certain nesting behaviours, those that nest above
ground, lend themselves better to the development of pollination management technology. Africa
has several unique pollinators (like certain small carpenter bees) that have not been tried for crop
pollination, but have potential because they nest above ground in hollow sticks. Taxonomists and
pollination biologists together estimated the likelihood for pollinators to be managed.
This rapid assessment stressed the need to positively identify the floral visitors. Specimens were
collected for identification in the course of field observation, and sent to taxonomic experts for iden-
tification down to species if possible. In addition a key to the African genera of bees was developed,
and around fifteen field researchers and parataxonomists were trained in Kenya and Ghana on the
use of the key.
page 14
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ROPS, BROWSE AND POLLINATORS IN AFRICA:
Fruit crops: Deciduous Fruit
in South Africa
Geoff Tribe
The rapid assessment of deciduous fruit in South
Africa was carried out in a region that indicates
the future of pollination services in Africa: it is
a region that, through a combination of human
disturbance and native ecology, is not rich in
bees, and farmers pay for pollination services.
The south-western Cape has been intensely
cultivated for about 350 years, when a re-
freshment station was established to service
ships passing the Cape of Good Hope. The
existing landscape has changed due to the
introduction of European crops and farming
methods, and by the introduction of many
invasive weed species. Today the major crops
of this region include winter wheat, grapes
and fruit. Only marginal land, often on steep
slopes, has not been cultivated, and much of the region has been invaded by alien plant species.
The two study sites were in the Franschhoek Valley on the farm Bien Donné, presently managed
by the Department of Agriculture, and an apple orchard located at the Elgin Experimental Farm
at Grabouw. The farm Bien Donné consists of peach, plum, apricot and pear orchards, with a
small area devoted to the production of lavender (Lavandula sp.) oil. Small patches of indigenous
and exotic vegetation occur around the periphery of the farm and along the river that bisects the
property. On this farm were at least six natural swarms of the indigenous honeybee, Apis mellifera
capensis Escholtz, located in oak trees, and two hives were situated near the lavender field. The El-
gin Experimental Farm is surrounded by natural montane fynbos. No honeybee colonies had been
brought in for pollination and what honeybees there were came from wild swarms in the vicinity.
Despite the low insect biomass in the fynbos region (Schlettwein and Giliomee 1987) and the
apparent scarcity of pollinating insects, the majority of fynbos plants (about 83% according to
Steiner (1987)) are insect pollinated (Whitehead et al. 1987). Despite the floral diversity of the
fynbos, the region does not appear to have a particularly rich bee fauna (Michener 1979), al-
though beetles are an important and conspicuous component of the insect pollinator fauna in
fynbos (Johnson 1992). Butterflies are not common in fynbos probably because the sclerophyllous
vegetation with its low nitrogen content is unsuitable for phytophagous larvae (Cottrell 1985).
Growers of apples and pears in the south-western Cape regard the presence of honeybees brought
in for that purpose as essential for full pollination of the crop. This also ensures that each fruit is of
a large and uniform size, and properly formed, which are essential requirements for export grade.
FIGURE 4: P
EACH TREES
IN SOUTH AFRICA.
page 15
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N INITIAL STOCK-TAKING
When flowers of some varieties are inadequately fertilized they develop into misshapen fruits,
and immature fruits with relatively few seeds, which are more inclined to be shed later than
ones with many seeds (Free 1970). Certain cultivars of pears are regarded as unattractive to
honeybees who rapidly find more profitable forage in the vicinity of the orchard and this ne-
cessitates that a second batch of honeybee colonies are brought in midway during the blos-
som period. Abundant pollen is released but the nectar is not attractive because it has a low
sugar content – recorded as 8-10% (Crane & Walker 1984). Most varieties of apple, pear
and plum are self-unfruitful, whereas peach and apricot are largely self-fruitful (Free 1970).
Fruit farmers pay beekeepers to place honeybee colonies within their orchards to ensure full pol-
lination. The parasitic Asian mite Varroa destructor Anderson & Trueman (Acari: Mesostigmata) which
destroys honeybee brood was discovered in South Africa in 1997 and rapidly spread throughout
the country (Allsopp et al. 1997). Presently the destructiveness of this mite in South Africa (Martin
& Kryger 2002) is not nearly as severe as that reported amongst European races of honeybees in
both Europe and the Americas. The question arises that had honeybees been totally or partially
debilitated by this mite (or a disease in the future), are there alternative indigenous pollinators that
could replace them?
P
EACHES (PRUNUS PERSICA (L.) BATSCH.)
Peach blossoms (Figure 4) were almost 100% pollinated by the indigenous honeybee Apis mel-
lifera capensis. A few syrphid (Metasyrphus sp. 1;Ischiodon aegyptus (Wiedemann)) and black flies
(Bibio turneri Edwards) frequented individual flowers to obtain nectar but spent most of their
time patrolling leaves and can therefore only be regarded as occasional pollinators at best. Hon-
eybees systematically worked the flowers for the first three days after the trees began to blossom,
and pollen collectors were especially frequent. After the first three days the pink blossoms began
to deteriorate (after been fully pollinated) and visits by honeybees, especially pollen collectors
declined rapidly. The nectar collectors then tended to move rapidly between trees and rows if
no reward was forthcoming. This pattern was followed on all the deciduous fruit tree species.
All peach cultivars are self-compatible and therefore do not necessarily require pollinators, but pol-
linating insects are of value even for the self-fertile cultivars (Crane and Walker 1984). Peach trees
originate in the Near East and as such fall within the distribution range of the Western Honeybee,
Apis mellifera. Yellow flowers are most attractive to insects. The peach flowers do not discriminate
between floral visitors (as do for example the constricted tubular flowers of some Aloe species) and
their pollen and nectar are readily exposed.
TABLE 2. NUMBER OF BLOSSOMS VISITED BY
A SINGLE HONEYBEE IN FIVE MINUTES.
Crop Date T range No. Total no. Mean no.
C visits blossoms blossoms
visited visited
Peaches 06/08/03 13 – 21 15 223 14.8
Plums 28/08/03 9 – 17 15 697 46.4
Apricots 25/09/03 13 – 25 15 576 38.4
Pears 26/09/03 14 - 25 15 756 50.4
Apples 21/10/03 22 - 32 15 638 42.5
Rhamnas 06/08/03 13 – 21 15 515 34.3
Echium 06/10/03 14 - 23 15 508 33.8
page 16
C
ROPS, BROWSE AND POLLINATORS IN AFRICA:
Arctotheca calendula(Cape Marigold) Hymenoptera Specidae Dasyproctus sp.
Scoliidae
Campsomeris sp.
Andrenidae
Andrena sp.
Colletidae
Scrapter pallidipennsi (Cockerall)*
Colletidae
Scrapter caesariatus Eardley
Colletidae
Scrapter heterodoxus (Cockerell)*
Halictidae
Patellapis (Lamatalictus) sp.*
Halictidae
Patellapis (Zonalictus) sp. 1
Halictidae
Patellapis (Zonalictus) sp.2
Halictidae
Patellapis (Zonalictus) sp. 3 ***.
Halictidae
Halictus (Seladonia) sp
Apidae
Ceratina (Ceratina) sp.
Diptera Bibionidae
Bibio turneri Edwards*
Empididae Sp. 1
Empididae Sp. 2
Bombyliidae Sp.
Muscidae
Orthelia ringiaeformis (Vileneuve)
Syrphidae
Betasyrphus sp.*
Syrphidae
Metasyrphus sp. 1
Syrphidae
Metasyrphus sp. 2*
Syrphidae
Eristalis sp.
Anthomyiidae
Delia sp.*
Coleoptera Phalacridae
Olibrus sp.
Cleridae Sp.
Cleridae Dolichopsia cf. cyanella Gorham
Melyridae
Pagurodactylus sp.
Melyridae
Pagurodactylus angustissimus Pic
Tenebrionidae
Eutrapela sp.*
Melolonthinae Sp.1
Melolonthinae Sp.2
Melolonthinae Sp.3
Melolonthinae
Pachycnema pulverulenta Burmeister
Anthicidae
Formicomus caeruleus (Thunberg)
Meloidea
Ceroctis capensis (Linné)
Cerambycidae Cf
. Promeces sp.
Buprestidae
Acmeodera decemgutta (Thunberg)
Nitidulidae
Meligethes cf. variabilis Reitter*
Dermestidae
Attagenus nr.
auratofasciatus Reitter
Dermestidae
Attagenus cf. breviusculus (Reitter)
Chrysomelidae Sp.
Chrysomelidae
Oulema erythrodera (Lacordaire)
Chrysomelidae
Eurythenes sp.
Raphanus raphanistrum (Wild radish) Hymenoptera Eumenidae Delta sp.
Colletidae
Scrapter heterodoxis (Cockerell)*
Halictidae
Patellapis (Lamatalictus) sp.*
Lepidoptera Pieridae
Colias electo electo (Linnaeus)
Pieridae
Dixeia sp.
Nymphalidae
Cynthia (Vanessa) cardui (Linnaeus)
Diptera Empididae Sp.1**
TABLE 3. INSECTS VISITING THE FLOWERS OF VARIOUS PLANTS AT BIEN DONNÉ (FRANSCHHOEK) AND GRABOUW
WHICH WERE SIMULTANEOUSLY IN FLOWER WITH FIVE ORCHARD TREE SPECIES. ASTERISK * DENOTES NUMBER OF
ADDITIONAL PLANT SPECIES FLOWERS THEY VISITED.
FLOWERING PLANT INSECT VISITOR
ORDER FAMILY SPECIES
page 17
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N INITIAL STOCK-TAKING
The low mean number of 14.8 peach blossoms visited in five minutes is largely because of the long
time taken by the bees to pack the pollen on their bodies into the pollen-baskets, and to the cold
days prior to the day records were taken (Table 2). This may also be reflected in the blooms appearing
in very early spring when most insects have yet to start foraging.
P
LUMS (PRUNUS DOMESTICA L.)
Plum blossoms were pollinated almost exclusively by honeybees. The relatively large mean number
(46.4) of flowers visited in five minutes by honeybees (Table 2) can partly be ascribed to the clustering
of blossoms about which the honeybees clambered without having to fly to each individual blossom.
An insignificantly small number of syrphid flies (Ischiodon aegyptus (Wiedemann)) visited flowers to
collect nectar at infrequent intervals.
In Europe, honeybees are the primary pollinators because plums bloom in early spring when popula-
tions of other insect species are low. A high population of pollinators is required to produce a high
fruit yield because the pollen grain must come from another compatible flower and at the right time
(Crane and Walker 1984).
A
PRICOT (PRUNUS ARMENIACA L.)
Honeybees were the almost exclusive pollinators of apricot flowers. The mean number of flowers
visited by an individual honeybee in five minutes was 38.4, which was slightly lower than expected.
In a study in Australia, honeybees comprised over 97% of insects on the flowers and improved fruit
set and yield (Langridge and Goodman 1981).
P
EARS (PYRUS COMMUNIS L.)
The recommended pollination strategy for the commercial pollination of pears is to bring in two
waves of honeybee colonies because the flowers of many cultivars are reported to be unattractive
to bees. However, the pears (early Bon Chretien cultivar) at Bien Donné proved to be so attractive
Syrphidae Betasyrphus sp.*
Coleoptera Cleridae
Dolichopsis cf. cyanella Gorham
Zantedeschia aethiopia (Arum lily) Diptera Empididae Sp.1
Tipulidae Sp.
Coleoptera Melyridae Cf.
Troglops
Melyridae Pagurodactylus sp.
Cleridae
Dolichopsis cf. cyanella Gorham
Cleridae
Notostenus viridis (Thunberg)
Tenebrionidae
Eutrapela sp.
Melolonthinae Sp.1
Melolonthinae
Peritrichia albovillosa Schein
Meloidea
Ceroctis capensis (Linné)
Nitidulidae
Meligethes cf. variabilis Reitter*
Cenia turbinate (Goose daisy) Hymenoptera Colletidae Scrapter pallidipennsi (Cockerell)*
Vicia atropurpurea Purple vetch Hymenoptera Halictidae Patellapis (Zonalictus) sp. 3***
Vicia sativa Broad-leaved purple vetch Hymenoptera Halictidae Patellapis (Zonalictus) sp.3***
Diptera Anthomyiidae
Delia sp.*
Solanum mauritianum (Bug-weed) Diptera Syrphidae Metasyrphus sp.2*
Lupinus luteus (Yellow lupin) Hymenoptera Halictidae Patellapis (Zonalictus) sp.3***
FLOWERING PLANT INSECT VISITOR
ORDER FAMILY SPECIES
page 18
C
ROPS, BROWSE AND POLLINATORS IN AFRICA:
to honeybees that the highest mean number of 50.4 of flowers visited by a single bee in five min-
utes was recorded. Honeybees again proved to be almost exclusive pollinators of pears. The pollen
baskets also contained the largest accumulation of pollen. It has been recorded that the nectar of
pears is not attractive because it has a low sugar content (8-10%) but supplies abundant pollen that
is highly attractive to honeybees (Crane and Walker 1984).
A
PPLES (MALUS DOMESTICA BORKH.)
At the Elgin Experimental Farm at Grabouw, it was shown that 98.2% (n=1254) of the pollinators
were honeybees. The other 1.8% insects occurring on the blossoms consisted of syrphid flies (5),
painted lady butterflies Cynthia (Vanessa) cardui (5), blowflies (5), solitary bees (2), a twig wilter (1),
a lacewing (1), a wasp (1), a blackfly (1), a housefly (1), and the carpenter bee Xylocopa capitata (1).
But this underestimates the effectiveness of the honeybees because there is no comparison between
them and these other insects in pollination efficiency. Most visitors other than honeybees visited
apple blossoms only erratically.
E
XOTIC WEEDS
The exotic weeds adjacent to the deciduous fruit crops were surveyed to assess to what degree they
provide alternative resources for the crop pollinators. None of the Australian Acacia species grow-
ing along the river banks and elsewhere (within 5 to 50 metres from each orchard) were visited by
any pollinators over the observation period. The Australian stink bean Paraserianthes lophantha at-
tracted a few honeybees that foraged for pollen, but no other pollinators were recorded. Two exotic
weed species that were highly attractive to honeybees were Echium plantagineum from Europe and
Asia, and wild radish (ramnas) Raphanus raphanistrum from Europe. The mean number of flowers
visited by individual pollen-collecting honeybees in five minutes was 33.8 for Echium and 34.3 for
Raphanus (Table 2).
These latter two exotic weeds may be important for honeybees, and also for other members of the
pollination community: adjacent to the river where Ramnas grew amongst indigenous vegetation,
a far greater number of insect species visited these plants although honeybees still predominated.
These included solitary bees, xylocopids, wasps and several small beetle species.
I
NDIGENOUS FLOWERING PLANTS
Indigenous flowering plants in farm margins were also surveyed to assess to what degree they pro-
vide alternative resources for the crop pollinators. The most prevalent indigenous plant flowering
during this time was the Cape Marigold Arctotheca calendula. Other species included a Senecio sp., the
Arum lily, Zantedeschia aethiopia, and yellow sorrel, Oxalis pes-caprae. Few of these indigenous plants
were attractive to honeybees, although many- such as Cape marigold- were important resources for
solitary bees and syrphid flies, among other pollinators.
CONCLUSIONS
All five species of deciduous fruit trees were thoroughly pollinated almost exclusively by honeybees,
which comprised over 98% of all pollinators recorded on these trees. This is even an underestimation
of the effectiveness of the honeybees because the other insects recorded on the blossoms, such as
the odd Xylocopa caffra (Linnaeus), Xylocopa capitata Smith or solitary bee,
page 19
A
N INITIAL STOCK-TAKING
although effective as pollinators, visited only a few blossoms and could in no way match the effi-
ciency of the honeybees. The few flies (syrphids and Muscidae, Orthellia ringiaeformis (Villeneuve)),
and beetles observed on the blossoms were only occasional visitors and inefficient pollinators and
collected nectar usually without touching the anthers of the blossom.
In the course of gathering these observations, it was noted that both nectar and pollen was collected
from all the deciduous fruit species except for apples where 98.2% of the foragers were collecting
nectar only. This is confirmed by the fact that only honeybee colonies placed on apples for pollination
purposes produce any honey (Mostert, pers comm.). The Bon Chretien pear trees were especially
attractive as suppliers of pollen and the pollen-baskets of the honeybees were packed high with the
greyish pollen. The pollen produced by the apples was not attractive to the honeybees.
Honeybees visited alternative floral resources at a lower rate than they visited the fruit species (ex-
cept for peach). Nonetheless they clearly obtained floral resources from Echium and Ramnas, and
also serve as pollinators at least of the Echium where they emerge from flowers coated in a film of
blue pollen.
Plants originating in Europe and Asia, where Apis mellifera naturally occurs, did have a beneficial affect
on both the Cape honeybee and several indigenous solitary bee species and produced both nectar
and pollen. Not only do honeybees find Echium and Ramnas highly attractive, but so do indigenous
bees which also frequent Vicia spp.
With the recent expansion of the fruit growing area in South Africa, there is presently a shortage
of pollination units available for deciduous fruit. Part of the problem lies in the systematic removal
of Eucalyptus trees, which were classified as invader species but were the most important source of
nectar and pollen to tide colonies over the summer dearth period. So plant species that contribute
to the well being of honeybee colonies are beneficial. There was no indication that honeybees were
enticed away from the fruit blossoms by the exotic weeds, and the indigenous solitary bees also
benefited by the presence of these floral resources.
Honeybees are indispensable as pollinators of deciduous fruit in the south-western Cape and should
they be afflicted by a debilitating disease or other parasites, the export fruit industry will be severely
affected. Continued efforts to document alternative pollinators, and alternative floral resources for
honeybees and other potentially important pollinators, will be useful.
page 20
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ROPS, BROWSE AND POLLINATORS IN AFRICA:
Kenya is within the probable area of domestication of watermelon (Citrullus lanatus), yet no pol-
lination work on the plant has previously been carried out in the region. One of the members of
the African Pollinator Initiative, Grace Njoroge, is pursing a PhD on the topic of watermelon pol-
lination in the region of Yatta. The majority of her study has focused on the behaviour and patterns
of honeybee pollination of watermelon, as these are by far the predominant visitors. But through
the support of the FAO Rapid Assessment project, we were able to supplement her field observa-
tions with several days of deliberate, focused observations on alternative pollinators of watermelon.
The Yatta Plateau of Kenya, to the east and below the important agricultural town of Thika, is intensely
farmed by smallholders and some large estates. The region, though fairly dry, is dissected by rivers
and also fortunate to have a major engineering work, the Yatta Furrow, running near the top of the
ridge between two valleys, diverting water from the Thika river to farms along the plateau. Although
the region is arid, the furrow permits irrigation of crops such as coffee and watermelon.
On both of the farms in Yatta region where informa-
tion was collected on pollination, honeybees were
by far the most numerous and thus important as
pollinators for watermelon. Yet, the national youth
service farm at Yatta where we observed watermelon
pollination, does not keep bees. Thus farmers in the
region rely on wild bee colonies, of which several
can be seen in riparian zones on farms in this region.
Unfortunately, the National Youth Farm has em-
ployed its many young workers to clear fields to the
river, and have greatly reduced the riparian zones.
Female watermelon flowers are much less abun-
dant than male flowers (Figure 6), and also appear
to be less visited by honeybees. The team observing
watermelon for non- Apis visitors thus separated
observations of male and female flowers to see if
this held true with other flower visitors. As with
the other investigations within Kenya, watermelon
flowers were observed in the field over 10-minute
intervals of time, at all times of the day, and in this
case over six days. The non-honeybee visitors
to watermelon flowers included those in table 4.
Female flowers were considerably less frequently
visited by both non- Apis bees and flies, as well as
by honeybees (Figure 5).
F
IGURE 5: NON-APIS VISITATION
PATTERNS TO WATERMELON, YATTA
FIGURE 6: MALE FLOWERS,
W
ATERMELON
Watermelon in Kenya
Grace Njoroge, Laban Njoroge, and Barbara Gemmill-Herren
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However, if we consider the ratio of male to female flowers (13:1), then it is evident that particularly
in the case of non-Apis bees, the visitors are actually preferring and seeking out the female flowers.
Interestingly, at least two of the non-honeybee bee pollinators in the watermelon field were found
nesting in the soil of the field. If nesting habits can be observed more closely, land management
practices could be prescribed to best conserve these nests on-farm.
Indigenous bees pollinating watermelon at Yatta, in Kenya- aside from honeybees - show appropri-
ate pollination behaviour, and evidently are able to make use of conditions on-farm to nest. While
soil-nesting bees may be among the hardest to manage, the fact that they are already able to nest
within a field suggests that management procedures to ensure their survival could be developed.
TABLE 4. VISITORS TO WATERMELON FLOWERS
Order Family Subfamily Genus Species
(a) Bees
Hymenoptera Halictidae Lasioglossum sp.A
Hymenoptera Halictidae Lasioglossum sp.B
Hymenoptera Halictidae Lipotriches sp.
Hymenoptera Apidae Apis melifera
(b) Other visitors
Diptera Syrphidae Syrphinae Allobaccha sp.
Diptera Syrphidae Syrphinae Allograpta nasuta
Diptera Syrphidae Syrphinae Betasryphus adligatus
Diptera Calliphoridae Chrysomyinae chrysomya chloropyga
Diptera Calliphoridae Chrysomyinae chrysomya sp.
Diptera Calliphoridae Calliphorinae Hemipyrellia sp.
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Mango in Ghana
Peter Kwapong
Mango (Mangifera indica L.) is one of the most important fruit crops world wide. The major pro-
ducing areas of Mango include: United States of America (Florida), Mexico, Central America, West
Indes (Caribbean Islands), South America (Brazil), Africa (Tanzania, Zaire), Arabian Peninsula, Asia
(India, Pakistan, Philippines, Indochina and Indonesia). There are about 150 varieties of mango
grown world wide. The plant is very important for its high economic value and as foodstuff for the
inhabitants of the tropics. The fruits of mango are eaten fresh or canned. They are used to make
fruit drinks. The unripe fruit is used in pickles. The stem bark is boiled with shea-butter and used
to treat bronchial disorders in children. In Ghana, both local and improved varieties of mango are
grown for local use and for export.
Mangos belong to the family Anacardiaceae. It is a large evergreen tree which can live for over 100
years. Mangoes grow best at altitudes below 1,500 metres, rainfall of 1.500 mm per year, and with
very little variation in day and night temperatures.
Mango flowers (Figure 7) occur in a conical panicle up to 45 cm long depending on the variety and
environmental conditions during its development. The panicle bears 500 – 600 flowers. Both bisexual
and male flowers are present on the same panicle. However, their proportions depend on the variety
and temperature during its development. The size of both male and hermaphrodite flowers varies
from 6-8 mm in diameter. They are subsessile
and have a sweet smell.
Mango produces relatively small amount of
pollen per flower. The mango (hermaphroditic)
flower is such that any organism that lands on
the flower is likely to effectuate pollination. The
flower opens early in the morning. Maximum
pollen shedding is from about 8 am to noon. The
flowers secrete nectar in considerable quantities.
This attracts a large number of insects.
F
IGURE 7: INFLORESCENCE AND IMMATURE
FRUITS OF MANGOES
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Sites selected for research into the pollination of mango include: Dodowa, a major mango growing
area and Cape Coast. These locations are in the Greater Accra and Central Regions respectively.
About 29 species of dipteran flies were collected. These seem to be the main pollinators even though
bees and wasps were also found on the flowers. Apart from honeybees, 4 other bee species and 7
species of wasps were also collected from the flowers. Three species of chrysomelid beetles, and some
Lepidoptera were also collected. No alternative host flowering plants were found around since the
vegetation was mainly grass.
TABLE 5. FLORAL VISITORS TO MANGO, GHANA.
Species observed Score Notes
Apis melifera (honey bee) 1 Visited early from 7.30 am and took over the
pollination of mango
Halictidae (Pseudalpis sp) 1 Collected on flowers
Dactyrarina sp (Stingless bee) 1 Collected on flowers
Wasps (9) 1-2 Collecting nectar
Syrphidae (2) 1-2 Hovering and occasionally landing on
flowers
Calliphoridae 1-2 Walking over flowers
Muscidae (4) 1-2 Walking over flowers
Coleoptera 1-2 Were many on flowers in the evening from
(brown soft bodied) 5.00pm
Arctiidae,,Ctenuchinae,
Euchromia sp (Moth) 1-2 Flying over trees with occasional landing on
flowers
Chrysomelidae (2) 2-3 Feeding on plant material
Dolichopodidae 3 Walking over flowers
Ichneumonidae (1) 3 Parasitoid, predating on other insects
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FIGURE 10: HERSE CONVOLVULI (WITH TONGUE EXTENDED)
––
ONE OF THE HAWKMOTHS POLLINATING PAPAYA
FIGURE 8: MALE FLOWER OF PAPAYA
FIGURE 9: FEMALE FLOWER OF PAPAYA
Papaya in Kenya
Dino Martins
Papaya (Carica papaya), also known as paw-
paw, is a widespread fruit crop throughout
Kenya where enough water is available for
it to be cultivated. It is a perennial tree crop,
dioecious, i.e., separate male and female
flowers, and therefore requires a pollinator
in order to set fruit. In tropical and sub-
tropical climates, fruit set occurs throughout
the year. Papaya is sold and eaten locally
as a fresh fruit, with much demand from
the numerous hotels, local grocery stores
and the town markets. Papaya is dried and
exported as part of a dried fruit mixture. The
‘milk’- a latex produced by the unripe fruit
is harvested and used in the production of
papain, an enzyme that acts on protein.
Papain is used in the brewing industry,
canned meats and medicinally. Coastal
peoples also use the latex from unripe fruit
to ease the pain and remove the spines and
stinging cells of sea-urchins and jellyfish.
The seeds are dried and exported to health
food stores.
In some areas, the leaves are used to wrap
meat, which is then roasted. This is said
to act as a tenderiser and improve flavour.
Unripe fruits are also boiled and eaten as
a vegetable by some communities. Sale of
fresh papaya across Kenya provides some
regular income for farmers. Single fruits
are sold for between 20-100 Kshs ($ 0.26-
1.3), depending on the location and local
abundance or availability of fruit. Most
small-holder farms produce at least fifty
individual saleable fruits a season.
Papaya pollination observations (Table 6)
were made in multiple sites including the
following: Kerio Valley, Machakos, Kitisuru
(Nairobi), Kitengela and Mosoriot (Eldo-
ret).
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The Kerio Valley had the largest stands of trees, with farms near rivers supporting hundreds of trees
and supplying fruit to traders in lorries. Fruits are transported to Nairobi and other towns
The Papaya plant is a relatively fast-growing species. It reaches a height of several metres. Papaya
requires pollination to set fruit. There are separate male and female flowers (Figures 8 and 9), as a
rule, on separate trees. Occasionally hemaphrodite trees are found. The male flowers on ‘male’ trees
are smaller but are produced in larger numbers than female flowers.
TABLE 6. FLORAL VISITORS TO PAPAYA, KENYA
Species observed Notes/observations/sites where present
Diptera
Calliphoridae Occasional diurnal visitors to female flowers.
Not pollinating. (All sites studied).
Tephritidae: Didacus sp. Common diurnal visitor to female flowers.
Not pollinating. May be laying eggs in young
fruit. (Kitisuru and Kerio valley)
Hymenoptera
Apidae:Apis mellifera Occasional visitor to male flowers. Not
pollinating. (Kerio valley)
Lepidoptera
Hesperiidae:Ceoliades sp. Occasional diurnal visitor to both male and
female flowers. Some pollen transport.
Pollinator. (Kerio valley)
Sphingidae: Hippotion celerio Abundant floral visitor. Seen at both male
and female trees. Hovers while feeding.
Pollinator (Kerio valley, Machakos and
Kitengela)
Sphingidae: Herse convolvuli Abundant floral visitor. Seen at both male
and female trees. Hovers while
feeding. Pollinator (Mosoriot and Kitengela)
Sphingidae: Macroglossum trochilus Abundant floral visitor. Seen at both male
and female trees. Hovers while
feeding. Diurnal. Pollinator (Mosoriot)
Sphingidae:Daphnis nerii Abundant floral visitor. Seen at both male
and female trees. Hovers while feeding.
Pollinator (Mosoriot)
Sphingidae:Nephele comma Abundant floral visitor. Seen at both male
and female trees. Hovers while feeding.
Pollinator (Machakos)
Noctuidae: Sphingomorpha chlorea Occasional floral visitor. Hovers
and alights on flowers. Pollinator (?)
(Kitengela and Kitisuru)
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They are produced in small bunches on short panicles originating from the trunk in-between the
leaf-bases. Female flowers occur single at the base of leaves appressed to the trunk. Both flowers
offer nectar rewards to pollinators.
Given the dioecious nature of the trees, both male and female flowers were observed during this
pollination assessment study. Floral production of fragrance and floral visitor activity is highest
after dusk, and before eight p.m. Flowers were watched for between 30 minutes to an hour at each
site studied (generally after sunset). Initial observations indicated little pollinator activity during the
day. Diurnal visitors included fruit flies and calliphorid flies (female flowers). Occasional honeybees
visit (male flowers) and flower moths visit (female flowers). One large species of skipper butterflies
(Hesperiidae), were observed visiting during the day at one location. They visited both male and
female flowers. This is important for transfer of pollen.
The pollination of the dioecious flowers is primarily carried out by crepuscular/nocturnal moths
(Sphingidae). These moths, better known as hawkmoths or sphinxmoths, are fast-flying, large and
highly mobile insects (Figure 10). This makes them extremely efficient pollinators. Preliminary ob-
servations on Kenyan farms show that different moth species are responsible for pollination across
different sites. Pollination happens primarily after dusk, within an hour or so. This is a fairly narrow
window and only the hawkmoths visit both male and female flowers at this time, and are able to
cover the distances between trees and plantations quickly.
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Avocado in Kiambu, Central Kenya
Wanja Kinuthia and Laban Njoroge
The avocado tree originated in Central America, where it co-evolved with native pollinators. Effec-
tive pollinators, whether co-evolved or not must be adapted to visit both male and female flower
stages, coming in contact with the dehisced anthers and receptive stigma at the same pollen col-
lection zones. Small and medium flying insects (3-8 mm in length) are especially apt to efficiently
collect avocado nectar.
Avocado is currently grown in most countries in the world. According to Wysoki et al. (1997), the main
avocado producing countries in Africa are South Africa, Democratic Republic of Congo, Cameroon,
Kenya, Egypt and the Canary Islands. Kenya is among the top exporting countries in Africa mainly
to France, Germany and United Kingdom (Collin, Pers. comm.)
The avocado flower is small and has both male and female reproductive organs. The flowers are
carried on terminal panicles. Each panicle carries a few hundred flowers. All cultivars have similar
flower structures though they may differ slightly in flower size.
An individual avocado flower goes through two stages. When it opens in stage I, the pistil is receptive,
and pollination and fertilization can occur. The flower closes after stage I and opens again in stage
II when the anthers dehisce. Avocado cultivars fit into two general types according to the time of
day their flowers are in different stages. The flowers of type A cultivar are in stage I in the morning
of the first day and stage II in the afternoon of the following day, so that the flower’s opening cycle
lasts about 36 hours. Type B cultivar are in stage I in the afternoon of the first day and stage II in the
morning of the following day. The flower opening cycle lasts about 20 hours (Free 1993). A farmer
with type A and B is ideal so that, in the morning, type A are pollinated with pollen from type B trees
and in the afternoon, type B would receive pollen from type A.
Self-pollination is possible because flowering dichogamy is rarely absolute: opening and closing of
flowers of the same tree is not necessarily perfectly synchronized. Therefore, early opening flow-
ers may overlap with late opening ones (Free 1993). Even when self-pollination within a tree is
possible, insects are needed to transfer the pollen between flowers. The three types of pollination:
cross, close and self-pollination occurs in avocado. Robbertse et al. (1996) were able to demonstrate
a clear advantage of cross over self-pollination.
A pollination survey was conducted on six trees of “Hass” and “Fuerte” varieties, in Kiambu District
Central Province. This site was chosen because the plants had flowers at eye-level for ease of ob-
servation (Table 7).
The honeybee, Apis mellifera L. was clearly the most prolific visitor on avocado flowers, visiting in
much larger numbers than other visitors. Honeybees appeared in the morning between 6:00 to 10:00
and never to return again until the following day. There were various species of flies observed visiting
the flowers. Flower beetles and ants were also observed (Table 7). Although ants were permanently
on the flowers, they appeared less effective as pollinators as they rarely came into contact with the
anthers and stigma of the flower. They were also observed to deter
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other would-be effective pollinators from visiting the flowers due to their intimidating large num-
bers. The ants also deplete the nectar from flowers, making other visitors spend very little time on
flowers. Farmers often band their Avocado trees with appropriate products to keep the ants away.
The variety of species observed on the avocado flowers in Gachie, Kiambu are shown on Table 7.
However, the pollination efficiency for each species was not carried out in this study.
Though avocado is an exotic tropical fruit to Kenya, its reproduction has adapted well to the local
pollinators as shown in this study. The exposed flower with large amount of nectar and pollen at-
tracts a large number of visitors. The area of study is densely populated, where most farms are less
than four acres. The farmers keep cattle in near to zero-grazing level, and are averse to bee keep-
ing according to a survey reported elsewhere in this study. The only other flowering plants were
the Lantana sp. hedge surrounding the farm. In spite of this, the honeybees A. mellifera visited the
flowers abundantly followed by several genera of Diptera. Ants, flower beetles and wasps were
also observed. The study should be repeated and the sampling period extended to cover the entire
flowering period. It would be interesting to compare Kiambu, Murang’a and Nyeri since the later
two have less degraded environment. Determination of the frequency of other indigenous bees
would compliment studies done elsewhere.
TABLE 7. FLORAL VISITORS TO AVOCADO IN GACHIE VILLAGE, KIAMBU DISTRICT, KENYA
ORDER FAMILY SUBFAMILY GENUS SPECIES
Diptera Calliphoridae Calliphorinae Lucilia sp.
Diptera Sarcophagidae Miltogramminae Hoplacephala tesselata
Diptera Calliphoridae Chrysomyinae Chrysomya chloropyga
Diptera Sarcophagidae Sarcophaginae Sarcophaga inaequalis
Diptera Calliphoridae Calliphorinae Hemigymnochaete varia
Diptera Calliphoridae Rhiniinae Rhyncomya stannocuprea
Diptera Calliphoridae Rhiniinae Rhinia sp.
Diptera Anthomyiidae - Anthomyia sp
Diptera Muscidae Muscinae Musca sp
Diptera Muscidae Muscinae Musca sp
Diptera Muscidae Muscinae Musca sp
Diptera Muscidae Phaoniinae Atherigona sp
Diptera Muscidae Coenosiinae Anaphalantus sp.
Diptera Syrphidae Syrphinae Allobaccha sp
Diptera Syrphidae Syrphinae Paragus sp
Diptera Agromyzidae - Melanagromyza sp.
Hymenoptera Apidae Apinae Apis mellifera
Hymenoptera Braconidae Microgasterinae Apanteles sp.
Hymenoptera Formicidae Formicinae Acantholepis sp
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NUT CROPS
Cashew in Ghana
Peter Kwapong
Cashew (Anacardium occidentale L) is a hardy, drought-resistant tropical or subtropical tree. In the
neotropical zone, it grows from Mexico to Peru and Brazil, including Hawaii, Puerto Rico, and parts
of the southern tip of Florida. Worldwide India is the leading producer: other producing countries
include Mozambique and Tanzania (Mutter and Bigger 1961, Purseglove, 1968).
Even though wild cashew has been growing in various part of Ghana for over fifty years now mainly
for its apple, it is increasingly being cultivated commercially in several areas around the country as an
export crop. Hence cashew has become one of the most important non traditional crops in Ghana.
Research is therefore need to support it successful cultivation especially in the area of pollinators.
The cashew nut is rich in protein and oil and the apple is extremely high in vitamin C (greater than
500% of US-specified Recommended Daily Allowance) and other minerals. In Ghana the nuts are
processed for export as dried roasted nuts. The apple is consumed fresh as found in many local com-
munities in Ghana or partially dried and candied.
Flowers are tiny, pinkish, borne terminally on panicles. Flowers can be male or hermaphrodite flowers
on the same panicle (inflorescence). Both flower types produce pollen and nectar. The cashew fruit is
a 1 inch nut, shaped like a small boxing glove, hanging below a fleshy, swollen peduncle (receptacle)
called the “cashew apple”, which has a value in addition to the nut. (See Figure 11).
Cashew pollination was observed at the Winneba junction in a farmer’s field on the same site as
coconut. The plantation covers about 200 acres, part of which has been intercropped with coconut.
The field had mixed varieties of cashew, which are not too tall making sampling convenient. Pol-
linators from many different taxa were observed on cashew (Table 8).
There are a variety of potential pollinators on cashew in Ghana. Honey bees, leafcutter bees and
the large carpenter bees offer good
potential for pollinator manage-
ment. However, their efficiency as
pollinators needs to be studied and
compared.
FIGURE 11: CASHEW FLOWERS AND YOUNG FRUIT
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TABLE 8. FLORAL VISITORS TO CASHEW, GHANA
Species observed Score Notes
Honey bee (Apis mellifera) 1 Collecting pollen and are major pollinators
Green metallic bee
(Halictidae) 1 Definitely pollinators
Megachilidae 1 Definitely pollinator
Xylocopa sp. 1 Buzz pollinator
Syrphidae 1 Pollinators
Diptera (unidentified) 1-2 Possible pollinator
Wasps(3) 1-2 Probably nectar and pollen collectors
Calliphoridae 1-2 Walking over flowers causing pollination
Oecophylla longinida (Ant) 1-2 Walking over flowers could result in
pollination
Camponotus 2-3 Probably predators
Muscidae (diptera) 2-3 Probably a pollinator
Coreidae 3 Plant sucking insects
Pyrrhocoridae (cotton stainer) 3 Plant sucking insects
Mantidae 3 Predator
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OIL CROPS
Coconuts in Ghana
Peter Kwapong
The coconut (Cocos nucifera L.) is found along tropical seashores around the world, and in some
areas it is cultivated far inland. Coconut is described as one of Nature’s greatest gifts to man be-
cause almost every part of the tree is used in some way. Coconut oil, extracted from the dried
endosperm (copra), is unusual amongst plant oils in that it is solid below 24’
o
C. It was the major
raw material in the production of margarine in the early day of its production. In Ghana, the milk
is usually a refreshing drink for most people. The soft endosperm inside the hard pericarp is a good
source of fat, protein and carbohydrate. The leaflets are used for fencing and for raising temporary
sheds. Along most of the fishing coasts, the stems are used to anchor small canoes or fishing boats.
The coconut plant has a tall unbranched trunk surrounded by a crown of fronds, although branched
forms are occasionally found. A leaf requires 10 years to reach full size, then it will last for 2 more years.
A new leaf and an inflorescence forms about once each month. The coconut is monoecious, having
both staminate and pistillate florets on the same many-branched inflorescence, the 2- to 4-foot long
spadix or fleshy panicle in the leaf axil. There are only a few female flower on each inflorescence and
these are found together with a pair of male flowers at the base of the branches (Figure 12); most of
the male flowers are borne singly or in pairs towards the branch tips. As the flowers contain nectar
and are sweet scented, it is likely that insects are important for pollination. However, as the pollen is
light and dry, there may also be some wind pollination. The male flowers mature and wither before
the female flowers become receptive (a condition known as protandry) so that flowers in the same
inflorescence cannot pollinate one another. This ensures cross-pollination. Flowering occurs on the
plant throughout the year.
Coconut pollination was studied in a farmer’s field at Winneba junction half way between Cape Coast
and Accra in the Central region of Ghana. It consist of about 20 acres of coconut plantation, in part
intercropped with cashew. Flower visitors and their behaviour on the inflorescence are summarized
in the table 9.
Bees appear to be the most impor-
tant pollinators, although this needs
to be confirmed through pollination
efficiency experiments and not just
flower visitation. Both honey bees
and stingless bees are social and can
be easily managed in large numbers.
The choice of managed pollinator
should depend on their pollination
efficiency and the farm structure.
Stingless bees are not dangerous like
honey bees and can be safely kept
near farm residences.
FIGURE 12: FEMALE COCONUT FLOWERS
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TABLE 9. FLORAL VISITORS TO COCONUT, GHANA.
Species observed Score Notes
Honey bee (Apis melifera) 1 Collecting pollen
Stingless bee (Meliponula sp) 1 Many were collected on freshly opened
flowers with pollen on them
Halictidae (Halictus sp) 1 Pollinator
Ants (Campnotus) 2-3 Walking on flowers could result in
pollination
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Groundnut in Ghana
Peter Kwapong
Groundnut (Arachis hypogea) is an annual plant of the legume family. The edible seeds are called
peanuts. Groundnut is also called goobers, goober peas, earthnuts, monkey-nuts and pinders. They
are native of South America but are cultivated in many parts of the world, chiefly in Asia, Africa and
the United States. Groundnut plants differ from other types of leguminous plants by producing
their pods underground.
Groundnut serves principally as human food and livestock feed. The seeds are especially rich in oil
and protein. The roasted seeds can be ground into a paste which makes a delicious spread on bread.
Peanut oil extracted from the seeds can be used for cooking. The whole plant including the seeds
is used as livestock feed. Plants from which seeds have been harvested are fed as hay. Peanut cake,
concentrated food made from seeds that have been crushed to extract oil is also fed to livestock.
Margarine, cheese, a coffee substitute, several kinds of milk, flour, medicine, cosmetics, ink, stains,
dyes, glues, plastics, fibres and insulating boards can be made from peanuts. Manufacturers grind
the shells (pods) into a powder which serves as an ingredient in plastics, cork substitutes, wallboards,
and abrasives. Harvested plants can also be used as organic manure.
Two general types of groundnut (peanuts) are grown commercially all over the world. These are:
bunch or erect (upright) type, which is about two feet high and matures in 3 to 30 months, and the
vine-like runner, creeping or prostrate type, which is about one foot high and branches two feet
long on the ground. This latter type matures after 4 to 5 months and has large seeds. Both types of
plants have thickening stems and small yellow flowers (Figure 13). Generally, flowers are produced
near the ground on bunch plants and along the runners of the vine-like types. Each flower puts out
a sharp stalk called peg. The flower buds open at sunrise. Fertilization takes place during the morn-
ing and the flowers usually wither about noon.
Within a few days the pegs (stalk
stems of the pods) begin to grow.
They grow slowly at first, but gradu-
ally grow more rapidly. The peg
enters the ground and the pod
grows from its tip. The tough, fi-
brous pod is about one to two
inches long when matured. In most
commercial varieties, each pod en-
closes two, sometimes three seeds.
Apart from the bunchy and runner
types numerous intermediates exist.
The runner types are more widely
grown in West Africa. In this re-
search the variety that was sampled
was the runner type.
FIGURE 13: GROUNDNUT IN FLOWER WITH
FLOWER BEETLE FEEDING ON PETALS
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Groundnut pollination was observed in Cape Coast in the Central Region of Ghana, and Northwest
of Accra, the capital city. The area is mainly made up of coastal savannah and groundnut is not a
major crop of the area. However, a few people grow the crop on a very small scale. Insect visitors
to groundnut flowers are recorded in Table 10.
Flower beetles (Decapotoma sp) were found eating petals including stamens as well as styles in some
cases. The flower beetles were seen on peanut flowers as early as 7.50 a.m. Few were found on the
flowers initially but population increased with time especially from 9.00 a.m. onwards when flowers
(keel) began to open. It appears that groundnuts are mainly self-pollinated.
The flower beetles were also found and collected from the flowers of the following plants: Spigelia
sp., Merremia tridentata, Sida acuta, Aspilia africana, Commelina benghalensis, about 500 metres away
from the sampling site.
Leaf beetles were also collected on the plant but were not pollinating. Ladybird beetles were seen
feeding on aphids on the stems. Three bee species belonging to the family Halictidae and an un-
identified bee were collected from the keel and are probably the main pollinators. Stalk-eyed shoot
flies were also collected, along with two other fly species. Damsel flies were observed on flowers
but are apparently not pollinators.
Halictidae, which are small ground dwelling bees appeared to be the most important pollinators of
groundnut. It will be difficult to increase their population size through management. As it appears as
if bees are the most important pollinators of groundnut, a survey should be carried out in another area
to see if the bees that visit the crop differ, and perhaps more manageable species occur elsewhere.
TABLE 10. FLORAL VISITORS TO GROUNDNUT, GHANA.
Species observed Score Notes
Halictidae (Pseudapis sp) 1 Moved very fast and spent less than 10 seconds
after entering a flower
Halictidae (Lipotriches sp) 1 Definitely a pollinator
Caliphoridae (dipteran fly) 2-3 Possible pollinator
Flower beetles Meloidae
(Decapotoma sp) 2-3 Eating corolla, stamens and style
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Oil Palm in Ghana
Peter Kwapong
The oil palm (Elaeis guineensis Jacq. ) is a tree crop believed to originate from West Africa. It is cultivated
in other regions of Africa, in Asia, East and West Indies and South and Central America. In Ghana,
oil palm is grown in six of the ten administrative regions. The oil palm is a high-yielding vegetable
oil crop. It produces oil from the mesocarp of the fruit as well as from the kernel. The uses of oil palm
include manufacture of cooking oil, margarine, soap, cosmetics and other industrial uses. In Ghana,
palm leaves are used for building temporary sheds. Mid-ribs of leaflets are put together into brooms.
Leaf stalks are used for weaving baskets. Palm wine is obtained from felled old stems.
Palms may reach a height of 30 meters in high forests; in other areas they are between 15 to 18 me-
ters tall. The oil palm is monoecious; male and female flowers occur separately in male and female
inflorescences on the same plant. Occasionally, hermaphrodite flowers occur. An inflorescence is a
compound spike held on a stout peduncle. Spikelets are spirally arranged around a central rachis.
Each inflorescence contains thousands of flowers.
Oil palm requires adequate pollination to set
fruit. Though both male and female inflores-
cences occur on the same plant (Figures 13 and
14), cross-pollination is necessary because the
inflorescences on a plant are seldom simulta-
neously receptive.
The study sites for this assessment were oil
palm plantations at Jukwa and Abrafo, both
in the Central Region of Ghana. Observations
were made on both male and female inflores-
cences for visiting insects. Some insects were
caught with sweep nets but the structure of
the palm and position of flowers limit the use
of nets. It was more effective to shake the in-
florescence and collect insects in a receptacle.
Insects so far collected (from male flowers) are
listed in Table 11.
Though these collections were from male
flowers only, the beetles are known from
previous work to that the main pollina-
tors of oil palm. About four species of small
beetles were collected on male inflorescence
as major pollinators. Three bee species and
FIGURE 15: MALE INFLORESCENCE,
O
IL PALM
FIGURE 14: FEMALE INFLORESCENCE,
O
IL PALM
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ROPS, BROWSE AND POLLINATORS IN AFRICA:
one wasps species were also collected. All the bees as well as the wasps had pollen on their bod-
ies but their role in pollination is unconfirmed, as they are not known to visit female inflorescence.
Further work is required to correctly identify all pollinators and ensure their conservation. Being
indigenous to West Africa, the origin of the oil palm, their conservation is in the interest of the oil
palm and palm oil industries world wide.
TABLE 11. FLORAL VISITORS ON OIL PALM, GHANA.
Species observed Score Notes
Oil palm weevils (Curculionidae) 1 Main pollinators (100s of them)
Nitudilidae 1 Pollinator
Honey bee 2-3 Many bees collecting pollen
Megachilidae 2-3 Few with pollen under abdomen
Halictidae 2-3 Few to many collecting pollen
Thrips 2-3 Probably pollination
Wasps 2-3 Collecting pollen
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BROWSE
Acacia pods in Kenya
Dino Martins
The Umbrella thorn (Acacia tortilis) is a spiny acacia (Mimosoideae), usually a shrub to a large
spreading tree in Kenya. It is among the most drought resistant acacia species and grows with
200-900mm of rainfall. Its pollination was observed primarily in the Kerio Valley, Northwest-
ern Kenya, where these trees are typically large and spreading forming extensive woodlands.
The trees’ branches are armed at each node with a straight white thorn as well as two short
grey sharply recurved spines, and the small leaves are closely spaced, making the tree densely
leafy. Umbrella thorn flowers are in white, cream or sometimes pale yellow capitate heads.
Acacia tortilis is in many ways a tree of high, and sometimes unrecognised potential. Products
are derived that directly or indirectly contribute to pastoral communities’ livelihoods and survival
in times of extreme drought. The main use in the Kerio valley is collection of pods for livestock
fodder. These are additionally transported out of the valley and into the adjacent highlands
where they are sold to people with livestock as a supplement food for goats, sheep and cattle.
Ripe fresh pods are eaten but the seeds are normally discarded, except in times of extreme food short-
age. Then seeds are eaten as well. The crunchy pods have a faint sweet taste. Besides the pods the
gum can also be eaten but is of inferior quality, is sticky and may cause choking. It is a typical famine
food and a last resource in Somali Region of Ethiopia where it is collected by children and women
when other foodstuff gets scarce. Pods are col-
lected and eaten by peoples inhabiting the Kerio
valley and Lake Turkana Basin of Kenya, as well
as throughout the Samburu and North-eastern
districts. When rains fail or are insufficient for a
number of other wild foodstuffs to grow, seed-
pods from A. tortilis are a secure food than can
be picked at the end of a severe drought period.
Furthermore, the inner bark can be chewed to
relieve thirst and the bark is also used medicinally.
The main use of the seedpods from this acacia as
a supplementary feed/nutritional supplement to
livestock- primarily goats, sheep and cattle. This
is where effective pollination is crucial. Hundreds
of Keiyo and Pokot women (mostly) throughout
the western and central areas of the Kerio Valley
gather the pods when ripe/semi-ripe. The pods
are shaken from the tree using a long notched
stick. In some cases young boys climb half-way
into the tree and aid in dislodging the pods. The
pods are then collected by hand from the ground
and packed
F
IGURE 17: ACACIA FLOWERS
FIGURE 16: PERCENTAGE TYPES OF FLORAL
V
ISTORS TO ACACIA TORTILIS, KERIO VALLEY
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ROPS, BROWSE AND POLLINATORS IN AFRICA:
into sacks. These are trans-
ported by donkey or on lorries
to the town centres of Biretwo
and Iten, where they are sold.
The price per sack of acacia
pods ranges from 100-200
Kshs ($ 1.3 – 2.6). Most of
the pods end up being fed to
livestock in the adjacent high-
lands, where heavy rainfall
has resulted in leached soils
and consequently mineral-
deficient grazing and browse. Pods, once dry, can be stored in sacks for many months, and are fed
to livestock in handfuls each day.
Herders and household with large numbers of livestock will also drive the stock under certain tree
that are heavily-laden with pods and then shake the tree to loosen the pods for the animals to eat.
The two main periods of pod harvest are a couple of months
after each rainy season (flowering) mainly in July-August and
December-January.
The inner wood of dead trees oozes a dark sap that is used by
the Borana peoples of northern Kenya as a source of perfume.
The wood is crumbly and highly aromatic with a spicy-sweet
scent. It is harvested and widely traded in markets throughout
the region. The local name for the perfume from Acacia tortilis
is “Foras”.
Fuel wood and charcoal prepared from this species are widely
sold on local markets and along commercial tracks throughout
Kenya and in the Somali Region. The charcoal from this and
other acacia species is in high demand and considered of the
highest quality for roasting meat.
Umbrella thorn pollination was investigated in the Kerio Valley,
Northwestern Kenya, East Africa, with additional observations
made in the southern Great Rift Valley, near Olorgesailie.
The flowers of umbrella thorn are borne singly or in small axil-
lary groups distributed on all the outer branchlets and twigs
(Figure 16). They flowers are capitate (spherical) and gener-
ally off-white or pale ivory in colour. As with many species
of acacias, pollen dehiscence is controlled by the tree, with a
distinctive peak in dehiscence that corresponds to a peak in
floral visitors and consequently pollinator activity.
TABLE 12. RANKING OF EFFECTIVENESS- ACACIA VISITORS.
Group under consideration Score
Native bee/wild bee species 1
Honeybees- Apis mellifera 1
Syrphid flies 2
Butterflies, moths (and Microlepidoptera) 2
Wasps 2-3
Ants 3
Beetles 3
FIGURE 19: PERCENTAGE TYPES OF
F
LORAL VISTORS TO ACACIA TORTILIS,
N
ATURAL VEGETATION SITE
FIGURE 18: PERCENTAGE TYPES OF
F
LORAL VISTORS TO ACACIA TORTILIS,
C
LOSE TO BOMAS
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In the Kerio Valley, the flowers were observed to begin to open after sunrise. Pollen dehiscence began
around 11.00 a.m. and peaked later between noon and 2.00 p.m. This period of dehiscence is later
that observed further south in Mkomazi, Tanzania, where trees peak dehiscence between 7.30 a.m.
and 9.00 a.m. (Stone et al. 1996).
Individual capitate flowers actually consist of many tiny flowers, densely packed to form the spherical
blossom. The anthers are arranged in a thick bunch, radiating outward from the floral cup. Stigmas
vary in number and are also variable in protandry and distribution within and across flowering trees.
Nectar was assumed to be present, given the presence of large numbers of nectarivores, including
butterflies and sunbirds, that were seen actually feeding from flowers. Some captured lycaenids
squirted droplets of moisture and this was also taken as an indication that the flowers contained
some amounts of nectar.
The capitate flowers are easily accessed by a large number of animals, primarily insects. Most insects
land on the flowers directly and move around from flower to flower once on a flowering tree. This
movement and behaviour, as well as the morphology of the potential pollinators, are the primary
factors used in assessing pollination in this species. Following is an analysis of the floral visitors, in
terms of diversity, trends, patterns and their efficacy as pollinators.
A wide range of insect species are visitors to Acacia tortilis. Floral visitors include species of bees, ants,
wasps, butterflies, moths, sunbirds and beetles (Figure 17). From this chart, it can be seen that Wild
bees (native bee species other than honeybees) form the bulk of visitors to this acacia. Native bees
account for 61 % of the total visits to Acacia tortilis when compared directly against the numbers
and frequency of all other insect visitor taxa.
Insect floral visitors were also observed at length at another site, the southern portion of the Great
Rift Valley, near Olorgesailie. Here, as in the Kerio Valley, A. tortilis forms an important part of the
woody vegetation. Trees at two distinct sites were studied. One located adjacent to a pastoralist
homestead (boma), where most of the natural vegetation other than the individual Acacia trees had
been removed. The ground cover was mostly eaten by the livestock and most of the ground was
bare and rocky. The second site where pollination observations were carried out on this species was
located in an area relatively undisturbed and with many other species of plants in flower. A distinct
difference was noted in the floral visitors between the two sites, as illustrated in Figures 18 and 19.
The site with lots of natural vegetation, in particular other flowering plants, had far more diversity
of native bees, than the site where most other natural vegetation had been removed.
Based on the criteria developed for scoring insect visitors as pollinators, careful observations of each
major group, across all sites, yielded the scores recorded in table 12. For the most part, wild bee
species were seen to spend the longest time on the tree’s flowers and moved among inflorescences
and between flowering trees. Native bee species were also found to carry the most pollen on their
bodies, where it was available for pollination.
Butterflies and honeybees also spent time on flowers and their pollen loads were seen brushing floral
parts. It is important to note that most butterflies studied, mainly lycaenids (which form
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TABLE 13. FLORAL VISITORS TO ACACIA TORTILIS BLOSSOMS, KENYA
Floral visitor group Observations/behaviour
ANTS:
Camponotus sp. Seen patrolling branches, scavenging
opportunistically, occasionally see on flowers
Crematogaster sp. Many thousands of this genus seen on some
trees, no major flower visitation observed.
Technomyrmex sp. Large numbers of this species seen
periodically in disturbed sites, seen attacking
other insects on tree.
BEETLES:
Buprestidae: Sternocera orissa Small groups of these large beetles were
seen feeding amongst flowers, pollen
transported on ventral surface of abdomen.
Cerambycidae: Promeces sp. Seen perched on flowers.
Scarabaeidae: Rose chafers- Pachnoda spp. Feeding on flowers, little pollen observed on
bodies
Scarabaeidae: Rose chafers-Rhabdotis sp. Feeding on flowers, little pollen observed on
bodies
Scarabaeidae: Rose chafers-Cyrtothyrea sp. Feeding on flowers, little pollen observed on
bodies
Lycidae: Lycusspp. Feeding on flowers, little pollen observed to
be carried.
FLIES:
Asilidae: robber flies Perch on branches and hunt floral visitors
Bombyliidae: bee fliesNotolomatia sp. Common floral visitors, some pollen present.
Syrphidae:Phytomia sp. Very common at some sites. Tend to visit
trees before pollen dehiscence begins.
Limited pollen transport.
Syrphidae:Allograpta sp. Very common at some sites. Tend to visit
trees before pollen dehiscence begins.
Limited pollen transport.
Syrphidae:Eristalis sp. Very common at some sites. Tend to visit
trees before pollen dehiscence begins.
Limited pollen transport.
Milichiidae: Jackal flies Seen scavenging near crab (flower)
spiders with prey.
Calliphoridae:Chrysomya sp. Visiting flowers, common in areas near
homesteads, no significant pollen transport.
BUTTERFLIES AND MOTHS:
Scythrididae: flower moths Common on flowers, diurnal moths, little
pollen transport
Sphingidae: Hawkmoths Fairly common visitors, hover while feeding
Macroglossum sp.Cephonodes sp. so little opportunity of collecting pollen on
body from capitate flowers.
Ctenuchidae: handmaidens Seen visiting flowers, stay high in trees
Agaristidae:Utetheisa sp. Occasionally observed on flowers
continued..
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TABLE 13. BEHAVIOUR OF FLORAL VISITORS ON ACACIA TORTILIS BLOSSOMS, CONTINUED
Floral visitor group Observations/behaviour
Hesperiidae : skippersSpialia sp.Coeliades sp. Active feeders, moving around, heavy-bodied
and seen to carry a little pollen.
Nymphalidae:Danaus chrysippus, All fairly common, some pollen transport.
Junonia oenone, Junonia hierta
Hamanumida daedulus,Hypolimnas misippus,
Byblia ilythia
Lycaenidae: Azanus spp. Very common at some sites, feeding at flowers.
Larvae recorded on Acacia leaves. Adults also
roost on acacias. Little pollen transport evident.
Lycaenidae: Cacyreus spp. Common on flowering trees. Little pollen
transport evident.
WASPS:
Chalcididae:Hockeria sp. Parasitic wasps, occasional visitors to acacia
flowers, more common amongst surrounding
herbaceous flora
Scoliidae Common, patrolling underneath flowering trees
Chrysididae Regular visitors to flowers. Little pollen seen on
bodies.
Tiphiidae Common, patrolling underneath flowering trees
Pompilidae:Cyphononyx sp.Hemipepsis sp. Regular and noticeable visitors, more common at
trees in Rift near bomas.
Vespidae:Polistes spp. Very common floral visitors, little pollen
movement.
Eumenidae:Anterhynchium sp.Delta spp. Regular floral visitors, hunt on and around
flowering trees.
Sphecidae:Ammophila spp. Common floral visitors, seen hunting on tree,
little pollen transport. Moves rapidly amongst
flowers, barely stopping.
BEES:
Apidae:Xylocopa somalica, X. inconstans, Common visitors to flowers. Transport of large
X. nigrita, X. caffra pollen loads (amongst the largest recorded),
move large distances between trees.
Apidae:Hypotrigona spp. Very abundant visitors at some sites. Spend long
time on flowers, good pollen loads.
Megachilidae:Megachile spp. Very common floral visitors, move systematically
and thoroughly over open flowers. Pollen loads
large.
Apidae:Amegilla spp.Anthophora spp. Regular visitors to flowers, good pollen
transporters
Thyreus sp. Regular floral visitor, some pollen observed.
Allodapula spp. Abundant, spend time on flowers, carry pollen.
Apidae:Ceratina sp. Common visitors to flowers. Pollen transport
clearly evident.
Braunsapis sp. Common floral visitors. Spend time crawling over
flowers. Pollen transport evident.
continued.
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the bulk of lepidopteran floral visitors), actually carried miniscule amounts of pollen. Syrphid flies
carried little pollen, but did spend time moving about the flowers.
Wasps varied in number and diversity from site to site, but included both solitary and social species.
Some wasps spent more time on the flowers than others. Many wasps were opportunistic visitors
to the flowering trees, seeking both nectar and preying on other insects. Ants and beetles were the
least effective floral visitors based on the criteria of pollen loads and movement. Many beetles simple
ate the flowers, despoiling them for other potential pollinators. Only large buprestids were found to
carry much pollen, but these tended to stay on a single tree for a long time.
Table 13 summarises the diversity of floral visitors to Acacia tortilis and notes on their behaviour and
efficacy as pollinators.
Native bees species, analysed in terms of behaviour, pollen loads, pollen movement and abundance
and distribution are the primary pollinators of Acacia tortilis at all sites studied. Native bee diversity
is directly proportional to pollination success on this species. Much more work needs to be done
on bee diversity in relation to seed set and pollination on acacias. It is unlikely that technologically
advanced pollination will be managed for Acacia tortilis because a food source for stock during
particularly drought periods for poor farmers. However, most of the important pollinators nest in
dead wood, making room for low-tech pollination management in that farmers that depend on this
resource should not denude the areas of dead wood.
TABLE 13. BEHAVIOUR OF FLORAL VISITORS ON ACACIA TORTILIS BLOSSOMS, CONTINUED
Floral visitor group Observations/behaviour
Apis mellifera Common floral visitor in some sites, often does
not visit during peak pollen dehiscence due to
temperature constraints. Good pollen transport
when present.
Tetraloniella spp. Occasional visitors, good pollen transport.
Macrogalea candida One of the most abundant native bee visitor
species, good pollen loads. Spends time on
flowers.
Halictidae:Nomia spp. Common floral visitors, transport large
amounts of pollen.
Lipotriches sp. Common floral visitors, transport of pollen
evident.
Pseudapis sp. Common floral visitors, often seen rising into
air from flowers to comb pollen from body.
Lasioglossum sp. Common floral visitors at some sites. Good
pollen transport.
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Indigofera (Dwarf Rangeland Browse Shrubs) in Kenya
Barbara Gemmill-Herren
In arid and semi-arid ecosystems, grasses dominate the herbaceous layer, but particularly on sites
with deeper soils other forage is important. On sites with good soils about 7 kg/ha/y of forage may
be produced for each mm of rainfall. In the dry season, browse that is high in protein forms a criti-
cal part of the diet for both livestock and wildlife. Dwarf shrubs form a large part of the browse in
livestock and wildlife diet. Among the most important of dwarf shrubs in this Kenyan rangeland
ecosystem are the Indigoferas: Indigofera spinosa, Indigofera volkensii, and Indigofera cliffordiana among
others, and Barleria.
In the north of Kenya, studies tracing the human food obtained as livestock products back to the plant
community responsible for their production reveals the importance of browse in this system. Dwarf
shrubs, particularly Indigofera spinosa, were the most important component of the plant community,
being ultimately responsible for 43% of the energy consumed by humans (Swift, Coughenour and
Atsedu 1996).
The responses of shrubs to grazing have been less studied than that of grasses. Work in south Turkana
on Indigofera spinosa, however, reports that at even fairly high levels of herbivore removal, no depres-
sion in aboveground production or nitrogen yield was found. This is not to suggest that rangeland can
be continuously overgrazed. Many of the dwarf shrubs, such as Indigofera and Barleria, are short-lived
perennials which means that their persistence depends
on successful reproduction. Since neither reproduces
vegetatively, their reproduction depends on effective
pollination and reproduction by seed.
Some information is known about the pollination of
species within the genus Indigofera, not because of its
browse value, but because some species are cultivated
as a source of indigo dye: Indigofera arrecta A. Rich, and
Indigofera tinctoria L. var. tinctoria. In both species, the
flowers are bisexual and seed is set only if visited by bees.
Extensive cross-pollination seems to result in better seed
set (Howard and Howard 1915, Howard et al. 1919).
Indigofera (Figure 20) is a species that may rapidly build
up to dominate the understory of arid woodlands, such
as the Tsavo ecosystem, in years following heavy rainfall.
In the year after the heavy rains of La Niña in Kenya
(1998), people working on Rukinga Ranch remember
vast hectares of Commiphora woodland turned pink with
Indigofera blossoms under the tree canopies.
FIGURE 20: INDIGOFERA BLOSSOMS
FIGURE 21: STINGLESS BEE NEST ENTRY TUBE
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It is interesting to inquire how a spe-
cies, dependent of bees for seed set
and seed set for dispersal, can build
up so quickly under favorable condi-
tions; in particular, the pollination
community must somehow manage
to cover the resource adequately for
this to occur.
Dwarf shrub species of the genus
Indigofera have been observed at
Mpala Research Center in the Lai-
kipia Plateau of Kenya; an area of
great importance both to livestock
production and wildlife populations.
Indigofera was also observed on
Rukinga Ranch, Taita District, which
forms a critical wildlife migration
corridor between the Tsavo East and
Tsavo West. Ranches in this area are
used for fattening cattle brought from Somalia for sale in Nairobi, and thus the graze resource is of
high economic importance.
Non-Apis bees make up the vast majority of visitors. All visitors appeared to handle the flowers
properly and should be considered pollinators (Table 14)
.
One population of stingless bees that visited Indigofera flowers in Rukinga were found nesting in
a tree next to the patches of flowers (Figure 21).
The average number of flowers visited by pollinators to Indigofera, per 10-minute observations period
was about half a flower, due to the many observation periods with no visitors. The overall visitation
rate for Indigofera is far lower than mass flowering species such as Acacia, or densely flowering crops
such as coffee. Visitation rates were not strongly affected by the number of flowers in a patch; in
fact higher average visitation rates occurred on patches of 10 flowers or less, than for patches of 10
flowers or more. While this correlation is not strong, it does indicate that Indigofera is not a flower
that attracts masses of generalized pollinators over short periods of time. The indigofera flowers are
not strongly scented and must be tripped by an insect, and are therefore more likely to be attractive
to specialized pollinators that know how to “work” the flower.
The successful reproduction of Indigofera, with its dependence upon pollinators, highlights the
critical but unseen ways in which pollination underpins ecosystem health. The importance of dwarf
shrubs such as Indigofera ripple throughout the ecosystem, fixing nitrogen to improve soil fertility
and providing important browse to livestock and thus food security for people, as well as browse
and cover for wildlife in savanna ecology.
TABLE 14: FLORAL VISITORS TO INDIGOFERA SPP. ON MPALA AND
R
UKINGA RANCHES, AND ALSO NEAR MURANGA, SOUTH OF SAGANA
WERE:
Family Genus and species
Halictidae Nomia theryi
Lipotriches sp. 3
Lipotriches sp. 4
Lipotriches sp. 6
Lipotriches sp. 7
Pseudapis sp.1
Nomia sp.
Megachilidae Heriades sp.
Pachyanthidium sp.
Apidae Ceratina sp.
Hypotrigona sp.
Liotrigona sp.
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This small sample of Indigofera pollinators highlights the importance of non-Apis bees. The diversity,
particularly of halictid bees visiting Indigofera flowers is striking; taxonomic experts think there may
be new species amongst those gathered in this preliminary assessment. The ability of rather special-
ized bees such as the Lipotriches to presumably build up in number during seasons of high rainfall
to provide sufficient pollination services to Indigofera so that the shrub can vastly expand its cover
remains an interesting puzzle, and one whose answer might help us to understand the resilience of
arid ecosystems. Lipotriches have been thought, at one time, to be rather specialized on harvesting
grass pollen (Immelmann and Eardley 2000), but further observations are finding that Lipotriches
species exploit a wide range of floral resources, including crops such as watermelon and groundnut.
What we do not know until more taxonomic work can be done on Lipotriches is how specialised
each individual species is on particular floral resources.
A variety of bees visit Indigofera. Their nesting habits include social nests in cavities, solitary nests
in hollow sticks and wood borer burrows in wood, and burrows in the ground. Effective pollination
management for an indigenous shrub species such as Indigofera involves maintaining a healthy,
natural ecosystem.
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FIGURE 22: HONEYBEES ON COFFEE
FIGURE 23: BAGGED COFFEE INFLORESCENCES
FIGURE 24: COFFEE PLANTATION AND RIPARIAN
F
OREST, WITH WILD HONEYBEE HIVES
Coffee is by far the most important cash crop
throughout eastern and central Africa. It is a
commodity that provides the major source
of foreign exchange for many countries in
the region, and supports the livelihoods of
millions of smallholder farm families. More
than 80% of the coffee produced in East Af-
rica is produced by an estimated 10 million
smallholder coffee farmers. In Kenya alone,
18,000,000 farm families rely on coffee for
income, and the coffee produced amounts
to 140 million USD.
Despite its economic importance to the
region, coffee production in the region is de-
clining, from a high of 8 million bags in 1983
to the current average of 6 million bags per
year, amounting to less than 6 percent of the
global coffee market. A major factor in this
decline is the abolition of economic clauses
of the International Coffee Agreement (ICA)
and the consequent collapse in prices lead-
ing to reduced husbandry; although other
contributing factors include social, economic
and political issues. In many places, the prices
now received by growers are insufficient
even to enable them to maintain the trees.
There is a renewed interest in the region,
however, for the development of specialty
coffee markets, to obtain premium prices for
excellent quality coffee from the region, for
organically and fair-trade produced coffee,
and for biodiversity-friendly coffee grown
under shade trees.
The question of whether bees are important
for coffee production has been fairly well
resolved by recent research.
BEVERAGE CROPS
Coffee in Kenya
Wanja Kinuthia, Laban Njoroge, and
Barbara Gemmill-Herren
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Traditionally, coffee was considered to be self-
pollinating, but recent research in both Costa
Rica (Roubik 2002) and in Indonesia (Klein et
al. 2003) have shown conclusively that animal
pollination contributes substantially to coffee
yields. In Costa Rica, two varieties showed over
25% fruit retention increases from pollinating
visits by bees. In one variety, coffee berries were
over 25% heavier and developed faster from
open pollination. The yield benefit from open
pollination, chiefly by feral African bees, was
56%. In Indonesia, self pollination accounted for
only 10- 60% of the yields obtainable by open or
deliberate cross-pollination. In Costa Rica, feral
Africanised honey bees were the principal pol-
linators of coffee, making it all the more ironic
that coffee pollination has not been studied in
the centre of origin of the crop (Ethiopia-Ke-
nya). Up until the present, pollination has not
been a subject of research at institutes such as
the Coffee Research Foundation in Kenya.
Coffee flowers were observed in Sasini, Twin
Rivers Farm in the Yatta region, and the Cof-
fee Research Foundation in Riuru, Kabete,
and Thika. On both of the farms in Yatta
region where information was collected on
pollination, honey bees were by far the most
numerous and thus important of pollinators for both coffee and for watermelon. Yet, the coffee
estate where observations were made does not keep bees, out of fear that the honey will be stolen.
Thus farmers in the region are relying on wild bee colonies, of which there are several. On the cof-
fee estate, bees had formed a nest in the thicket of grasses and woody plants where the land was
too swampy to farm, and also had established nests high up in riparian trees near the river. (Figure
24). One of these nests had just been attacked by a honey badger, attesting to the high on-farm
biodiversity in the area (along with buffalo said to live in the swamp).
Unfortunately, the owner of one coffee whera pollination observations were carried out was de-
termined to plant as much acreage as possible to coffee, and had labourers removing all riparian
vegetation on several streams, right to the edge of the water- in contravention to Kenyan land-use
law. It is unlikely that the farm would be managed in this way if the land managers understood the
importance of wild spaces on farm, as nesting sites for pollinators.
Another potential source of pollinators, both honeybee and non-honeybee, is the few protected
areas in the region. In this intensely cultivated region, protected areas tend to be rocky, low fertility
inselbergs or outcroppings.
F
IGURE 25: PERCENTAGE TYPES OF FLORAL
V
ISITORS TO COFFEE OVER TOTAL OBSERVATION
PERIOD OF 18.2 HOURS, MULTIPLE SITES, KENYA
FIGURE 26: AVERAGE NUMBER OF FLOWERS
VISITED BY TAXA, OVER 10-MINUTE PERIODS
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While these have generally been
considered too weedy to be treated
as forest reserves, and of little or no
agricultural value, they often have a
rich and diverse flora of outstanding
botanical interest. Two have been
protected in the region. About 10
kilometres away in one direction is
ol’ Donyo Sabuk, a massive inselberg
managed by Kenya Wildlife Ser-
vices. The lower slopes of the hill are
dominated by Acacia bushland and
thicket. The upper forest is a rem-
nant of a once-common montane
forest type dominated by African
Olive (Olea), Podo (Podocarpus), Fig
trees (Ficus) and Croton. About 10
kilometres in another direction is
the Mutomo Hill Plant Sanctuary,
gazetteted as a plant sanctuary in
the 1950s by the National Museum
of Kenya. Interestingly, Mutomo was identified as an important botanical area by the well-known
Swiss botanist Peter Bally, and was the first plant, as opposed to wildlife sanctuary established in
Africa. While it is unlikely that pollinators visiting the coffee and watermelon that we observed in
the region came directly from these reserves, their presence in this largely agricultural landscape
may be providing sources of populations of pollinators to establish in agricultural fields (even if they
will often be exterminated due to soil disturbance or use of pesticides).
Even more interesting to on-farm biodiversity, however, is the previous practice, almost non-existant
in Kenya today, to grow coffee under shade trees. Historically, two indigenous species were used
in Kenya for shade-grown coffee: Erthrynia (the famous “Flame Trees of Thika” and Croton. Both of
these species are highly attractive to pollinators, as well as to birds and other taxa. The Coffee Re-
search Foundation of Kenya is interested in re-introducing research on shade-grown coffee, which
may have sustainability benefits that sun coffee cannot provide. Including a pollination component
in such comparative research would be a valuable addition.
Coffea arabica, the most common coffee species in this region, has flowers in groups of 2-20 in the
axils of the leaves. The stigma is receptive when a flower opens at dawn, and flowers are usually pol-
linated within two hours after opening. Flowers wither within 48 hours after opening if pollinated,
but persist for much longer if not visited by insects.
Coffee flowers were visited by primarily by honey bees, flies, and other bees, with butterflies,
wasps and beetles making up an insignificant contribution (Figure 25). The average number of
flowers visited by each of these groups, per 10-minute observations period is given in Figure 26.
TABLE 15. FLORAL VISITORS TO COFFEE, KENYA
Family Genus and species
Collectidae Hylaeus (Nothylaeus) sp.
Hylaeus (Deranchylaeus) sp.
Halictidae Lasioglossum (Dialictus sp.)
Sphecodes sp.
Lipotriches sp.
Halictus (Seladonia) sp.
Pseudapis sp.
Apidae Braunsapis fascialis (Gerstaecker)
Braunsapis rolini (Vachal)
Braunsapis trochanterata (Gerstaecker)
Braunsapis sp.
Amegilla atrocincta (Lepeletier)
Amegilla acraensis (fabricius)
Ceratina (Ctenoceratina)
Ceratina sp.
Xylocopa inconstans (Smith)
Apis mellifera (L.)
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A
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Although ants rapidly scurried over flowers and did visit a considerable number of flowers per ten
minute period, they were infrequent, and did not appear to approaching the flowers in ways that
ensure proper pollination. Thus, honey bees, flies and other bees were observed as the most effective
pollinators (Figures 22, and 26).
Particularly numerous, among the non-Apis bee, were Lasioglossum (Dialictus sp.) and the two Bra-
unsapis species, Braunsapis fascialis and Braunsapis rolini.
TABLE 16. INSECTS BESIDES BEES VISITING COFFEE INCLUDED:
Order Family Sub-family Genus Species
Coleoptera Bruchidae Amblycerinae Spermophogus sp
Diptera Syrphidae Milesiinae Eristaliaus quinqualineatus
Diptera Syrphidae Syrphinae Allograpta Nasuta
Diptera Syrphidae Syrphinae Betasyrphus sp.
Diptera Syrphidae Milesiinae Phytomia incisa
Diptera Syrphidae Milesiinae Eristalinus sp.
Diptera Muscidae Phaoninae Atherigona sp.
Diptera Muscidae Muscinae Orthellia sp.
Diptera Conopidae - - -
Diptera Calliphoridae Chrysomyinae Chrysomyia sp.
Diptera Calliphoridae Rhiniinae Stomorhina rugosa
Diptera Calliphoridae Rhiniinae Stegosoma sp.
Diptera Calliphoridae Rhiniinae Isomyia sp.
Diptera Calliphoridae Rhiniinae Rhinia apicalis
Diptera Tipulidae - - -
Diptera Lauxaniidae Lauxaniinae Lauxania sp.
Diptera Lauxaniidae - Pahcycerina sp.
Diptera Agromizidae - - -
Diptera Sciaridae - Apeimocrengris sp.
Hemiptera Pyrrhocoridae - Dycercus sp.
Hymenoptera Formicidae Formicinae Polyrhachis sp.
Lepidoptera Heliodinidae - Eretmocera sp.
Lepidoptera Sphingidae - Cephonodes sp.
Lepidoptera Pieridae - Catopsilia florella
Lepidoptera Papilionidae - Papilio demodocus
Lepidoptera Lycaenidae - Leptptes pirithous
Lepidoptera Lycaenidae - Cupidesthes arescopa
Lepidoptera Nymphalidae - Hypolimnus misippus
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C
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It is interesting to see how pollinators cover the flowering resources as coffee trees enter their peak
flowering period. When flowers are less abundant, at the beginning of the flowering season, a typical
number of flowers per meter square might be 100 flowers. Over any ten-minute period, an average
of twenty may be visited, thus 20%. During peak flowering, of around 3000 flowers per meter square,
the total number of flowers visited rises to 40, but the percentage coverage falls dramatically to 1%.
It is likely that the pollination community cannot saturate the flowering resources, at peak flowering
times- at least in these farms where there is no deliberate effort to enhance pollinator presence by
keeping hives of honeybees.
To determine the effectiveness of a single pollinator visit on coffee, which can self-pollinate, forty-six
coffee flowers were bagged so that no visitation could occur, and the bags removed to allow a single visit
of one honeybee to one flower. (Figure 23). The stigma of this flower was then excised, prepared on a
slide and examined under a microscope to count pollen deposited. An equal number of open-pollinated
flowers, experiencing unlimited pollination visits, and a small number of control flowers, bagged so as to
experience no animal pollinator visits (except possibly ants which might have been able to manoeuvre
into the net bags) were examined in the same way. Open pollinated flowers had about twice as many
pollen grains deposited on stigmas, as opposed to those flowers experiencing no visits or only one visit.
The importance of insect visitation is apparent, but needs to definitively determine pollinator ef-
fectiveness, (as opposed to the rapid assessment conducted here) it is necessary to follow berry
development from pollination through to actual yield. Another interesting research question, posed
by Dr. David Roubik on the basis of his work on coffee pollination in Costa Rica, is whether pol-
lination may not only contribute to yield, but also to quality. He suggests (D. Roubik, pers. Comm..)
that flowers able to widely out-cross (by being visited by far-flying pollinators) may have improved
coffee flavour. As coffee production and research is turning increasingly to questions of quality (and
the premium prices paid for quality), this is also an important research question for the future, to be
answered through a longer-term study that follows pollination through to harvest.
Coffee pollination in its center of origin- Eastern Africa- is a neglected subject that can contribute
substantially to coffee yields and possibly quality. Even without managing pollinators, we found
that farmers in this agricultural area were still benefiting from pollinators that nest in adjacent wild
habitat. Yet this wild habitat is being cleared rapidly as farmers seek to expand their agricultural area.
If coffee quality might be enhanced by having more pollinators, the farmers’ (erroneous) perceived
reduction in yield from not clearing bee-nesting habitat on farm might be made up in actual in-
creases in both yield and quality. Since the coffee tree builds up to peaks of mass flowering, means
of conserving pollinators on-farm could have value in assuring that the pollinator community can
build up to meet peak flowering periods.
Around the world coffee is principally self and bee pollinated (Roubik 2002 and Klein et. al. 2003.)
and Kenya is no exception. Honey bees are the principal pollinators, and much technology exists to
manage honey bees. Of the other bees there are soil nesting and above ground nesting bees. These
will both occur in natural areas, and certain practices can increase their numbers, like leaving dry
wood in place and clearing parts of the ground.
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Summary and Conclusions
Most countries wishing to start a pollinator conservation program will be faced with the
challenge of assessing the role of pollinators, and knowledge on these roles, in their coun-
try. Working out the complete pollination biology of a specific crop is multi-year study,
but if pollinators are indeed being lost as agricultural development proceeds, most coun-
tries and regions will have neither the time nor resources to study each crop in depth.
As a contribution to the International Pollinator Initiative, the Food and Agriculture Organization of
the United Nations invited national partners in Ghana, Kenya and South Africa to undertake a rapid
assessment of pollination systems important to crop production in each respective country. Within the
scope of time and resources, it was possible to identify and rank the important pollinators for a range
of crops, and to identify threats and barriers to pollinator conservation in the different agroecosystems.
Farmers’ knowledge of pollination in both Kenya and Ghana was found to be widely variable, from
farmers who understood the role of pollination in seed set, to farmers who believe that bees are harm-
ful and need to be killed. Extension agents in Ghana has somewhat better knowledge of pollination
services, but did not seem to be actively passing this on to farmers. Researchers and civil society or-
ganisations tended to focus on beekeeping as a source of sustainable livelihoods, and were not directly
concerned with the conservation of pollination services. The published literature on pollination of
crops important in Africa is not small, but few of the studies have been carried out in an African context.
Methodologies are presented here that are easily replicable for a rapid assessment of the impor-
tant pollinators visiting pollinator-dependent crops. It should be noted that in a rapid assess-
ment, it is not possible to conclusively determine degree of dependence on pollinators and which
pollinators are the most effective; this would require a study carried out over one or more years
including following the pollination process through to seed set and fruit yield. Moreoever, as is
well known in pollination research, the vagility and high variability of insect abundance means
that many controlled observation samples of pollinator visitation will result in “zeros”- no visi-
tors. This vastly increases the number of observations needed to carry out statistically analyzable
data. In this rapid assesment, we have focused on characterising a number of crop-pollination
systems, rather than developing datasets for a statistically complete assessment of any one system.
Within the limitations of the present assessment, however, the ecology of pollination in up to twelve
agroecosystems was characterised. In only one of them, deciduous fruit tree farms in South Africa,
were honeybees essentially the only pollinator. In all other farming systems, from Ghana to Kenya,
a wide array of wild insects visited flowers and were seen to be effective pollinators. While honeybee
visits to watermelon are known to be essential to crop production, in Kenya it was shown that two
other bees, nesting in the soil of the field, are more effective pollinators. One does not need to be
selected over the other; good management of pollination services in agriculture will promote the
complex of beneficial insects, so that if one is impacted by disease or weather, others may provide a
buffering effect, ensuring that the services are maintained. Information on managing wild ground-
nesting bees in agricultural fields is virtually non-existant, however.
page 52
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Tree crops often recieve visits from a broadly diverse complex of visitors. In Ghana, the importance
of flies visiting Mangoes was evident, yet proscriptions for maintaining fly populations in mango
orchards are unknown. Papaya’s key pollinator, in observations in Kenya, were long-distance flying
hawkmoths, whose needs and pollination services are spread across mulitple agro and wild eco-
systems. Flies and bees were both important to Avocado pollination in Kenya, although neither
are appreciated adequately or managed. Nut crops such as cashew also have a diverse range of
pollinators, including several larger bees (honeybees, carpenter bees and leafcutter bees) with good
potential as visitors that could be encouraged through pollinator-friendly practices.
Palm crops, such as oil palm and coconut, attract a wide array of small insects, some of which may
not directly pollinate, but serve to disturb male flowers sufficiently so that the pollen becomes more
easily wind-borne and is carried to female flowers. This highlights the diverse nature of pollination
services: what is needed is quite specific to each system, but the role may be carried out by a diverse
group of pollinators.
Groundnuts have traditionally thought to be self-pollinated, but in this assessment as well as in
some other observations in Africa, the flowers attract insects, and the potential for yield increase in
this highly important African crop through pollinator management remains unexplored.
Browse pollinators are important, but often overlooked. Most of the important Acacia pollinators
nest in dead wood, making room for low-tech pollination management in that farmers that depend
on this resource should not denude the areas of dead wood. Browse species such as Indigofera are
shortlived and respond rapidly to changing climatic conditions through establishment by seed, mak-
ing their depedence on pollinators very important.
Coffee producers do not seem to be aware that pollination can increase yields, and are removing
habitat on farm for wild bee populations. The potential for coffee quality to be increased through
management of pollination is gaining considerable public attention, from studies in Costa Rica and
Indonesia. Yet in East Africa, in the center of origin of the domesticated coffee crop, there is no ap-
preciation of the role of pollinators, and habitat on-farm is rapidly being degraded. The reintroduc-
tion of shade-tree coffee to the region, now being discussed amongst regional research networks,
may provide an opporunity to reverse such degradation.
With respect to the taxonomic impediment, it should be noted that many crop and browse pollinator
species could only be identified to genera. This severely limits our ability to assess whether they are
shared amongst several crops, or specific to individual crops
This rapid assessment has served to bring to the attention of those involved, that pollinator biodiversity
conservation in agriculture and in natural ecosystems clearly cannot be separated. An ecosystem ap-
proach in pollinator biodiversity conservation must consider a surrounding milieu of well preserved,
natural areas, and patches of wild habitat on-farm, to be an integral part of an agro-ecosystem.
page 53
A
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Acknowledgements
The contributors to this initial stock-taking wish to acknowledge the support and contribution of
their respective organisations, the Plant Protection Research Institute of South Africa’s Agricultural
Research Council, Environment Liaison Centre International based in Nairobi, Kenya, the Invertebrate
Zoology Department of the National Museums of Kenya ,University of Cape Coast, Ghana, and
the overall support and encouragement of the Food and Agriculture Organization of the United
Nations
Picture Credits
Front Cover; Top, Hawkmoth, Dino Martins; Bottom: Cattle in Forest, Matthew Herren
Page 15: Interview bouquet, Barbara Gemmill-Herren
Page 18: Peach trees in South Africa, Geoff Tribe
Page 24: Male flowers, Watermelon, Hannah Nadel
Page 26: Infloresence and immature fruits of mangoes, Wanja Kinuthia
Page 28: Male flower of Papaya, Female flower of Papaya, and Herse convolvuli, Dino Martins
Page 33: Cashew flowers and young fruit, Peter Kwapong
Page 35: Female Coconut Flowers, Peter Kwapong
Page 37: Groundnut in flower with flower beetle feeding on petals, Peter Kwapong
Page 39: Female inflorescence, Oil Palm and Male inflorescence, Oil Palm, Peter Kwapong
Page 41: Acacia flowers, Dino Martins
Page 47: Indigofera blossoms and Stingless bee nest entry, Barbara Gemmill-Herren
Page 50: Honeybees on Coffee, Bagged Coffee inflorescences, Coffee plantation and riparian forest,
with wild honeybee hives, Barbara Gemmill-Herren
Back Cover: Papaya flower and cowpea flower and bee, Dino Martins, Riparian area in coffee plantation,
Barbara Herren
page 54
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