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Plant Attractants and Rewards for Pollinators: Their Significant to Successful Crop Pollination

Year 2022, Volume: 5 Issue: 2, 270 - 293, 15.08.2022
https://doi.org/10.38001/ijlsb.1069254

Abstract

Plant and pollination have a mutualistic relationship where both parties offer and gain benefits for each other. The plant-pollinator interactions resulted in successful crop pollination in which the plant received pollination services by animal pollinator to increase food production that eventually increase crop economic value. Overall, ecosystem is highly dependent on pollinator thus there is a need to review potential valuation method of crop production and analyse the current understanding of the value of pollination service towards the ecosystem as well as the traits plant offer and benefits that pollinators gain from the relationship. The attractant and rewards highly depending on each other. Plant often able to attract pollinators through traits like the shape, size and colours of flower, deception, scents as well as location. In the meantime, plant would provide a reward for pollinators that visited the flower which includes food from pollen and nectar that contains high nutritional value, energetic rewards to reduces energy cost of survival, protection and shelter against predator and not to forget breading, oviposition and mating sites inside the flower plant. The ecological relationship of plant and pollinator resulting in effective crop pollination if the attractant and incentives are significantly reliant on one another. With this review and current technological advancements, optimistically more deeper investigations in the interaction of pollinator and flowering plant can be conducted and best pollinator management approaches can be established to secure sustainable crops production

References

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Year 2022, Volume: 5 Issue: 2, 270 - 293, 15.08.2022
https://doi.org/10.38001/ijlsb.1069254

Abstract

References

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  • 2. McCallum K.P., McDougall F.O. and Seymour R.S. A review of the energetics of pollination biology. Journal of Comparative Physiology B., 2013. 183: 867–876.
  • 3. Carr D.E. et al., Variation in reward quality and pollinator attraction: The consumer does not always get it right. AoB Plants, 201. 7: 1–12.
  • 4. Chartier M., Gibernau M. and Renner S.S., The evolution of pollinator-plant interaction types in the araceae. Evolution, 2014. 68: 1533–1543.
  • 5. Sapir Y., Shmida A. and Ne’eman G. Morning floral heat as a reward to the pollinators of the Oncocyclus irises. Oecologia, 2006. 147: 53–59.
  • 6. Mori S. et al., Biocommunication between Plants and Pollinating Insects through Fluorescence of Pollen and Anthers. Journal of Chemical Ecology, 2018. 44: 591–600.
  • 7. Woodcock T.S. et al., Flies and Flowers II: Floral Attractants and Rewards. Journal of Pollination Ecology, 2014. 12: 63–94.
  • 8. Glover B.J., Pollinator attraction: The importance of looking good and smelling nice. Current Biology, 2011;. 21: R307–309.
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  • 13. Ahmad S, et al., Effects of native pollinator communities on the physiological and chemical parameters of loquat tree (Eriobotrya japonica) under open field condition. Saudi Journal of Biological Science, 2021. 28(6): 3235-3241.
  • 14. Smith M.R. et al., Effects of decreases of animal pollinators on human nutrition and global health: A modelling analysis. The Lancet, 2015. 386: 1964–1972.
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  • 16. Cooley H. and Vallejo-Marín M., Buzz-Pollinated Crops: A Global Review and Meta-analysis of the Effects of Supplemental Bee Pollination in Tomato. Journal of Economic Entomology, 2021. 1–15.
  • 17. Williams I.H., Insect Pollination and Crop Production: A European Perspective. Pollinating Bees - Conservation Link Between Agriculture and Nature, 2002. 59–65.
  • 18. Abrol D.P., Pollination and Fruit Productivity. Pollination Biology. Vol.1 Pests Pollinators Fruit Crop, 2015, Switzerland: Springer International Publishing: Switzerland. 25–58.
  • 19. Adnan N., Mamat M.P. and Tuan Ibrahim T.M., Pollination services support for agriculture productions values. IOP Conference Series: Earth & Environmental Sciences, 2021. 756: 1–5.
  • 20. Vanbergen A.J. et al., Status and value of pollinators and pollination services: a report to DEFRA. Department of Environmental Food & Rural Affairs, 2014. 3: 54.
  • 21. Omar N.A., Zariman N.A. and Huda A.N., Pollination in the Tropics : Role of Pollinator in Guava Production. Journal of Life Science and Biotechnology, 2021. 4: 623–39.
  • 22. Raven P.H. and Wagner D.L., Agricultural intensification and climate change are rapidly decreasing insect biodiversity. Proceedings of National Academy of Science, 2021. 118: 1–6.
  • 23. Belavadi V.V. and Ganeshaiah K.N., Effects of Climate Change on Pollinator Populations. Indian Council of Agricultural Research, 2013. 316–21: 44.
  • 24. Harwood G.P,. and Dolezal A.G., Pesticide – Virus Interactions in Honey Bees : Challenges and Opportunities for Understanding Drivers of Bee Declines. Viruses, 2020. 12: 2–19.
  • 25. Vanbergen A.J., Espíndola A. and Aizen M.A., Risks to pollinators and pollination from invasive alien species. Nature Ecology & Evolution, 2018. 2: 16–25.
  • 26. Kluser S. and Peduzzi P., Global Pollinator Decline : A Literature Review. 2007. 4.
  • 27. Borges R.C. et al., The Value of Crop Production and Pollination Services in the Eastern Amazon. Neotropical Entomology, 2020. 49: 545–56.
  • 28. Abrol D.P. et al., Impact of insect pollinators on yield and fruit quality of strawberry. Saudi Journal of Biological Sciences, 2017. 26: 524–530.
  • 29. Winfree R., Gross B.J. and Kremen C., Valuing pollination services to agriculture. Ecological Economics, 2011. 71: 80–88.
  • 30. Reilly JR et al., Crop production in the USA is frequently limited by a lack of pollinators. Proceedings of Royal Society B: Biological Sciences, 2020. 287: 2–9.
  • 31. Rader R. et al., Non-bee insects are important contributors to global crop pollination. Proceedings of the National Academy of Sciences, 2016. 113: 146–151.
  • 32. Breeze TD et al., Economic Measures of Pollination Services: Shortcomings and Future Directions. Trends in Ecology & Evolution, 2016. 31: 927–939.
  • 33. Ono E.R., Valentin-silva A. and Guimar E., Spatial and temporal distribution of floral resources used by pollinators in a semi-deciduous seasonal forest. International Journal of Plant Reproductive Biology, 2020. 12: 11–24.
  • 34. Ghosh S. et al., Pollination mechanisms and adaptations in flower and ornamental crops- A review. Journal of Pharmacognosy & Phytochemistry, 2017. 6:662–665.
  • 35. Primante C., The role of floral traits in structuring plant-pollinator interactions. 2015.
  • 36. Alcorn K., Whitney H. and Glover B., Flower movement increases pollinator preference for flowers with better grip. Functional Ecology, 2012. 26: 941–947.
  • 37. Balamurali G.S., Krishna S. and Somanathan H., Senses and signals: Evolution of floral signals, pollinator sensory systems and the structure of plant-pollinator interactions. Current Science, 2015. 108: 1852–1861.
  • 38. Clarke D. et al., Detection and Learning of Floral Electric Fields by Bumblebees. Science, 2013. 340: 66–69.
  • 39. Myczko Ł, et al., Do queens of bumblebee species differ in their choice of flower colour morphs of Corydalis cava (Fumariaceae)?. Apidologie, 2015. 46: 337–345.
  • 40. Parra-Tabla V. and Vargas C.F., Flowering synchrony and floral display size affect pollination success in a deceit-pollinated tropical orchid. Acta Oecologica, 2007. 32: 26–35.
  • 41. Brunet J., Flick A.J. and Bauer A.A., Phenotypic Selection on Flower Color and Floral Display Size by Three Bee Species. Frontiers in Plant Science, 2021. 11: 1–13.
  • 42. Roguz K. et al., Visibility and attractiveness of Fritillaria (Liliaceae) flowers to potential pollinators. Scientific Reports, 2021. 11.
  • 43. de Camargo M.G.G. et al., How flower colour signals allure bees and hummingbirds: a community-level test of the bee avoidance hypothesis. New Phytologist, 2019. 222: 1112–1122.
  • 44. Faheem M., Aslam M. and Razaq M., Pollination ecology with special reference to insects a review. Journal of Research Science, 2004. 4: 395–409.
  • 45. Prasifka J.R et al., Using nectar-related traits to enhance crop-pollinator interactions. Frontiers in Plant Science, 2018. 9: 1–8.
  • 46. Miller R., Owens S.J. and Rørslett B., Plants and colour: Flowers and pollination. Optic and Laser Technology, 2011. 43: 282–294.
  • 47. Petanidou T. and Lamborn E., A land for flowers and bees: Studying pollination ecology in Mediterranean communities. Plant Biosystems – An International Journal Dealing with All Aspects of Plant Biology, 2005. 139: 279–294.
  • 48. Yan J. et al., Pollinator responses to floral colour change, nectar, and scent promote reproductive fitness in Quisqualis indica (Combretaceae). Scientific Reports, 2016. 6: 1–10.
  • 49. Sobral M. et al., Selective pressures explain differences in flower color among Gentiana lutea populations. PLoS One, 2015. 10: 1–15.
  • 50. Veiga T. et al., Are pollinators and seed predators selective agents on flower color in Gentiana lutea? Evolutionary Ecology, 2015. 29: 451–464.
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There are 104 citations in total.

Details

Primary Language English
Subjects Botany, Zoology, Agricultural Engineering (Other)
Journal Section Review Articles
Authors

Nur Athirah Zariman This is me

Nurul Alia Omar This is me

A. Nurul Huda 0000-0002-7629-9681

Publication Date August 15, 2022
Published in Issue Year 2022 Volume: 5 Issue: 2

Cite

EndNote Zariman NA, Omar NA, Nurul Huda A (August 1, 2022) Plant Attractants and Rewards for Pollinators: Their Significant to Successful Crop Pollination. International Journal of Life Sciences and Biotechnology 5 2 270–293.



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