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Roles of insect pollinators, natural enemies and farmers’ knowledge on improving bean production in tropical Africa

By: Martin G. Mkindi, Patrick A. Ndakidemi, Ernest R Mbega

Key Words: Parasitoids, Ecosystem services, Phaseolus vulgaris, Providers of ecosystem services

J. Bio. Env. Sci. 11(4), 229-239, October 2017.

Certification: jbes 2017 0106 [Generate Certificate]

Abstract

Ecosystem services play a significant role in sustainable agricultural development worldwide. Commonly examples of well-known groups of providers of ecosystem services are insect pollinators and natural enemies of bean pests. These providers of ecosystem services and other natural services are crucial for ecosystems’ proper functioning and thereby sustaining plant growth, crop production and protection against crop pests. Literature provides evidence for a great role that the ecosystem services play in sustainable crop production. However, limited information is available on significance, farmer’s knowledge and their functions in bean pest management in tropical Africa. Lack of understanding on the ecosystem services and the providers of ecosystem services can lead to improper providers of ecosystem services conservation as a consequence, increase pest pressure which can result in poor crop yields. Therefore, this review discusses the level of understanding of small scale farmers, significance and potential use of the ecosystem services (pollinators and natural enemies of bean pests) for sustainable bean production and further, outlines potential research gaps for management and optimization of the ecosystem services in the tropical Africa.

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Roles of insect pollinators, natural enemies and farmers’ knowledge on improving bean production in tropical Africa

Abate T, Van Huis A, Ampofo JKO. 2000. Pest management strategies in traditional agriculture: an African perspective. Annual review of entomology 45(1), 631-659.

Abate T, Ampofo JKO. 1996. Insect pests of beans in Africa: their ecology and management. Annual review of entomology 41(1), 45-73.

Abrol DP. 2012. Value of Bee Pollination. In Pollination Biology Springer Netherlands pp. 185-222.

Bale JS, Van Lenteren JC, Bigler F. 2008. Biological control and sustainable food production. Philosophical Transactions of the Royal Society of London B: Biological Sciences 363 (1492), 761-776.

Bartomeus I, Potts SG, Steffan-Dewenter I, Vaissiere BE, Woyciechowski M, Krewenka KM, Bommarco R. 2014. Contribution of insect pollinators to crop yield and quality varies with agricultural intensification, Peer J2, e328.

Beckage NE, Gelman DB. 2004. Wasp parasitoid disruption of host development: implications for new biologically based strategies for insect control. Annual Reviews in Entomology 49(1), 299-330.

Berkes F, Colding J, Folke C. 2000. Rediscovery of traditional ecological knowledge as adaptive management. Ecological Applications 10(5), 1251-1262.

Boafo YA, Saito O, Kato S, Kamiyama C, Takeuchi K, Nakahara M. 2016. The role of traditional ecological knowledge in ecosystem services management: the case of four rural communities in Northern Ghana. International Journal of Biodiversity Science, Ecosystem Services & Management 12(1-2), 24-38.

Cohen JE, Jonsson T, Müller CB, Godfray HCJ, Savage VM. 2005. Body sizes of hosts and parasitoids in individual feeding relationships. Proceedings of the National Academy of Sciences of the United States of America 102(3), 684-689.

Cornelius ML, Dieckhoff C, Vinyard BT, Hoelmer KA. 2016. Parasitism and predation on sentinel egg masses of the brown marmorated stink bug (Hemiptera: Pentatomidae) in three vegetable crops: importance of dissections for evaluating the impact of native parasitoids on an exotic pest. Environmental Entomology, nvw134.

Chalmers N, Fabricius C. 2007. Expert and generalist local knowledge about land-cover change on South Africa’s Wild Coast: can local ecological knowledge add value to science? Ecology and Society 12(1).

Chapman RF, Bernays EA, Simpson SJ. 1981. Attraction and repulsion of the aphid, Cavariella aegopodii, by plant odors. Journal of Chemical Ecology 7(5), 881-888.

Cranshaw WS. 2014. Lady Beetles. Colorado State University (311), 1.

Cruz DDO, Freitas BM, Silva LAD, Silva EMSD, Bomfim IGA. 2005. Pollination efficiency of the stingless bee Melipona subnitida on greenhouse sweet pepper. Pesquisa agropecuária brasileira 40(12), 1197-1201.

Dicks LV, Wright HL, Ashpole JE, Hutchison J, McCormack CG, Livoreil B, Sutherland WJ. 2016. What works in conservation? Using expert assessment of summarized evidence to identify practices that enhance natural pest control in agriculture. Biodiversity and Conservation 25(7), 1383-1399.

Dos Santos SA, Roselino AC, Hrncir M, Bego LR. 2009. Pollination of tomatoes by the stingless bee Melipona quadrifasciata and the honey bee Apismellifera (Hymenoptera, Apidae). Genetics and Molecular Research 8(2), 751-757.

Evans EW. 2009. Lady beetles as predators of insects other than Hemiptera. Biological Control 51(2), 255-267.

Flint ML, Dreistadt SH. 2005. Interactions among convergent lady beetle (Hippodamia convergens) releases aphid populations and rose cultivar. Biological Control 34(1), 38-46.

Gadgil M, Berkes F, Folke C. 1993. Indigenous knowledge for biodiversity conservation. Ambio 151-156.

Garibaldi LA, Steffan-Dewenter I, Winfree R, Aizen MA, Bommarco R, Cunningham SA, Bartomeus I. 2013. Wild pollinators enhance fruit set of crops regardless of honey bee abundance. Science 339(6127), 1608-1611.

Garbach K, Milder JC, Montenegro M, Karp DS, DeClerck FAJ. 2014. Biodiversity and ecosystem services in agro ecosystems. Encyclopedia of agriculture and food systems 2, 21-40.

Garratt MP, Coston DJ, Truslove CL, Lappage MG, Polce C, Dean R, Potts SG. 2014. The identity of crop pollinators helps target conservation for improved ecosystem services. Biological Conservation 169, 128-135.

Getanjaly RVL, Sharma P, Kushwaha R. 2015. Beneficial Insects and Their Value to Agriculture. Research Journal of Agriculture and Forestry Sciences 3, 25-30.

Gil RJ, Baldock KC, Brown MJ, Cresswell JE, Dicks LV, Fountain MT, Ollerton J. 2016. Chapter four-protecting an ecosystem service: approaches to understanding and mitigating threats to wild insect pollinators. Advances in Ecological Research 54, 135-206.

Gurney B, Hussey NW. 1970. Evaluation of some coccinellid species for the biological control of aphids in protected cropping. Annals of Applied Biology 65(3), 451-458.

Green OO, Garmestani AS, Albro S, Ban NC, Berland A, Burkman CE, Shuster WD. 2016. Adaptive governance to promote ecosystem services in urban green spaces. Urban ecosystems 19(1), 77-93.

Grzywacz D, Stevenson PC, Mushobozi WL, Belmain S, Wilson K. 2014. The use of indigenous ecological resources for pest control in Africa. Food Security 6(1), 71-86.

Hassell MP. 2000. Host-parasitoid population dynamics. Journal of Animal Ecology 69(4), 543–566 https://doi.org/10.1046/j.1365-2656.2000.00445.x

Heard TA. 1999. The role of stingless bees in crop pollination. Annual review of entomology 44(1), 183-206.

Kedia A, Prakash B, Mishra PK, Singh P, Dubey NK. 2015. Botanicals as ecofriendly bio rational alternatives of synthetic pesticides against Callosobruchus spp. (Coleoptera: Bruchidae) a review. Journal of food science and technology 52(3), 1239-1257.

Kelly JD. 2010. The story of bean breeding, white paper prepared for bean CAP & PBG works on the topic of dry bean production and breeding research in the USA. Michigan State University, 1-29.

KovácsHostyánszki A, Espíndola A, Vanbergen AJ, Settele J, Kremen C, Dicks LV. 2017. Ecological intensification to mitigate impacts of conventional intensive land use on pollinators and pollination. Ecology Letters 20(5), 673-689.

Klein AM, Vaissiere BE, Cane JH, Steffan-Dewenter I, Cunningham SA, Kremen C, Tscharntke T. 2007. Importance of pollinators in changing landscapes for world crops. Proceedings of the Royal Society of London B: Biological Sciences 274(1608), 303-313.

Kremen C, Williams NM, Aizen MA, GemmillHerren B, LeBuhn G, Minckley R, Winfree R. 2007. Pollination and other ecosystem services produced by mobile organisms: a conceptual framework for the effects of land‐use change. Ecology letters 10(4), 299-314.

Lamarque P, Meyfroidt P, Nettier B, Lavorel S. 2014. How ecosystem services knowledge and values influence farmers’ decision-making. PloSone 9(9), e107572.

Lewis WJ, Stapel JO, Cortesero AM, Takasu K. 1998. Understanding how parasitoids balance food and host needs: importance to biological control. Biological control 11(2), 175-183.

Libersat F, Delago A, Gal R. 2009. Manipulation of host behavior by parasitic insects and insect parasites. Annual review of entomology 54, 189-207.

Machekano H, Mvumi BM, Nyamukondiwa C. 2017. Diamondback Moth, Plutella xylostella (L.) in Southern Africa: Research Trends, Challenges and Insights on Sustainable Management Options. Sustainability 9(2), 91.

Messelink GJ, Bennison J, Alomar O, Ingegno BL, Tavella L, Shipp L, Wäckers FL. 2014. Approaches to conserving natural enemy populations in greenhouse crops: current methods and future prospects. BioControl 59(4), 377-393.

Moquet L, Laurent E, Bacchetta R, Jacquemart AL. 2017. Conservation of hoverflies (Diptera, Syrphidae) requires complementary resources at the landscape and local scales. Insect Conservation and Diversity.

Munyuli T. 2011. Farmers’ perceptions of pollinators’ importance in coffee production in Uganda. Agricultural Sciences 2(03), 318.

Munyuli MT. 2013. Pollinator biodiversity in Uganda and in Sub-Sahara Africa: landscape and habitat management strategies for its conservation. International Journal of Biodiversity and Conservation 3(11), 551-609.

Musallam IW, Haddad NJ, Tawaha ARM, Migdadi OS. 2004. The importance of bee-pollination in four genotypes of faba bean (Vicia faba L.). International Journal of Agriculture and Biology 6(1), 9-12.

Mkindi AG, Mtei KM, Njau KN, Ndakidemi PA. 2015. The Potential of Using Indigenous Pesticidal Plants for Insect Pest Control to Small Scale Farmers in Africa. American Journal of Plant Sciences 6(19), 3164.

Mkindi A, Mpumi N, Tembo Y, Stevenson PC, Ndakidemi PA, Mtei K, Belmain SR. 2017. Invasive weeds with pesticidal properties as potential new crops. Industrial Crops and Products.

Mwanauta RW, Mtei KA, Ndakidemi PA. 2014. Prospective bioactive compounds from Vernonia amygdalina, Lippia javanica, Dysphania ambrosioides and Tithonia diversifolia in controlling legume insect pests. Agricultural Sciences 5(12), 1129.

Mwanauta RW, Mtei KM, Ndakidemi PA. 2015. Potential of Controlling Common Bean Insect Pests (Bean Stem Maggot (Ophiomyia phaseoli), Ootheca (Ootheca bennigseni) and Aphids (Aphis fabae)) Using Agronomic, Biological and Botanical Practices in Field. Agricultural Sciences 6(05), 489.

Nunes-Silva P, Hrncir M, da Silva CI, Roldão YS, Imperatriz-Fonseca VL. 2013. Stingless bees, Melipona fasciculata, as efficient pollinators of eggplant (Solanum melongena) in greenhouses. Apidologie 44(5), 537-546.

Ndakidemi B, Mtei K, Ndakidemi PA. 2016. The Potential of Common Beneficial Insects and Strategies for Maintaining Them in Bean Fields of Sub Saharan Africa. American Journal of Plant Sciences 7(3).

Olson DM, Andow DA. 2006. Walking pattern of Trichogram manubilale Ertle & Davis (Hymen optera; Trichogram matidae) on various surfaces. Biological Control 39(3), 329-335.

Ollerton J, Winfree R, Tarrant S. 2011. How many flowering plants are pollinated by animals? Oikos 120(3), 321-326.

Parker JE, Snyder WE, Hamilton GC, RodriguezSaona C. 2013. Companion planting and insect pest control. In Weed and Pest Control-Conventional and New Challenges. InTech.

Parrotta J, Yeo-Chang Y, Camacho LD. 2016. Traditional knowledge for sustainable forest management and provision of ecosystem services. International Journal of Biodiversity Science, Ecosystem Services & Management 12(1–2), 1–4.

Puech C, Poggi S, Baudry J, Aviron S. 2015. Do farming practices affect natural enemies at the landscape scale? Landscape ecology 30(1), 125-140.

Rader R, Bartomeus I, Garibaldi LA, Garratt MP, Howlett BG, Winfree R, Bommarco R. 2016. Non-bee insects are important contributors to global crop pollination. Proceedings of the National Academy of Sciences 113(1), 146-151.

Rehman A, Powell W. 2010. Host selection behavior of aphid parasitoids (Aphidiidae: Hymenoptera). Journal of Plant Breeding and Crop Science 2(10), 299-311.

Riddick EW, Cottrell TE, Kidd KA. 2009. Natural enemies of the Coccinellidae: parasites, pathogens, and parasitoids. Biological control 51(2), 306-312.

Riddick EW. 2017. Identification of Conditions for Successful Aphid Control by Ladybirds in Greenhouses. Insects 8(2), 38.

Romeis J, Babendreier D, Wäckers FL, Shanower TG. 2005. Habitat and plant specificity of Trichogramma egg parasitoids—underlying mechanisms and implications. Basic and Applied Ecology 6(3), 215-236.

Sarwar M, Salman M. 2015. Biological Insecticide Trichogramma spp. (Hymenoptera : Trichogram matidae) Strikes for Caterpillar Control. International Journal of Entomology Research 1(1), 31–36.

Sileshi G, Nyeko P, Nkunika P, Sekematte B, Akinnifesi F, Ajayi O. 2009. Integrating ethno-ecological and scientific knowledge of termites for sustainable termite management and human welfare in Africa. Ecology and Society 14(1).

Singh A, Weisser WW, Hanna R, Houmgny R, Zytynska SE. 2017. Reduce pests, enhance production: Benefits of intercropping at high densities for okra farmers in Cameroon. Pest Management Science.

Singh HB. 2014. Management of plant pathogens with microorganisms. Proc Natl Acad Sci 80, 443-454.

Soares AO, Coderre D, Schanderl H. 2003. Influence of prey quality on the reproductive capacity of two phenotypes of Harmonia axyridis PALLAS (Coleoptera: Coccinelidae).

Slaa EJ, Chaves LAS, Malagodi-Braga KS, Hofstede FE. 2006. Stingless bees in applied pollination: practice and perspectives. Apidologie 37(2), 293-315.

Tscharntke T, Clough Y, Wanger TC, Jackson L, Motzke I, Perfecto I, Whitbread A. 2012. Global food security, biodiversity conservation and the future of agricultural intensification. Biological conservation 151(1), 53-59.

Van Nouhuys S, Kaartinen R. 2008. A parasitoid wasp uses landmarks while monitoring potential resources. Proceedings of the Royal Society of London B: Biological Sciences 275(1633), 377-385.

Wang XG, Keller MA. 2002. A comparison of the host‐searching efficiency of two larval parasitoids of Plutella xylostella. Ecological Entomology 27(1), 105-114.

Wei J, Wang L, Zhu J, Zhang S, Nandi OI, Kang L. 2007. Plants attract parasitic wasps to defend themselves against insect pests by releasing hexenol. PLOS one 2(9), e852.

Wilby A, Thomas MB. 2002. Natural enemy diversity and pest control: patterns of pest emergence with agricultural intensification. Ecology Letters 5(3), 353-360.

Woodcock TS, Initiative CP. 2012. Pollination in the agricultural landscape. Best Management Practices for Crop Pollination. Guelph, ON, Canada: Canadian Pollination Initiative, University of Guelph.

Zheng XL, Li J, Su L, Liu JY, Meng LY, Lin MY, Lu W. 2015. Ecological and morphological characteristics of parasitoids in Phauda flammans (Lepidoptera, Zygaenidae). Parasite 22.

Martin G. Mkindi, Patrick A. Ndakidemi, Ernest R Mbega.
Roles of insect pollinators, natural enemies and farmers’ knowledge on improving bean production in tropical Africa.
J. Bio. Env. Sci. 11(4), 229-239, October 2017.
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