¿Diversidad o dominancia en la producción de alimentos? El caso de los polinizadores

Lucas A. Garibaldi; Sebastián Aguiar; Marcelo A. Aizen; Carolina L. Morales; Agustín Sáez

doi:10.25260/EA.17.27.3.0.494

Authors

Lucas A. Garibaldi Instituto de Investigaciones en Recursos Naturales, Agroecología y Desarrollo Rural (IRNAD), Sede Andina, Universidad Nacional de Río Negro (UNRN) - Consejo Nacional de Investigaciones Científicas y Técnicas (CONICET). San Carlos de Bariloche, Río Negro, Argentina.
Sebastián Aguiar Laboratorio de Análisis Regional y Teledetección. IFEVA, Universidad de Buenos Aires, CONICET, Facultad de Agronomía, CABA.
Marcelo A. Aizen Laboratorio Ecotono, Instituto de Investigaciones en Biodiversidad y Medio Ambiente (INIBIOMA), Centro Regional Universitario Bariloche, Universidad Nacional del Comahue - Consejo Nacional de Investigaciones Científicas y Técnicas (CONICET). San Carlos de Bariloche, Río Negro, Argentina.
Carolina L. Morales Laboratorio Ecotono, Instituto de Investigaciones en Biodiversidad y Medio Ambiente (INIBIOMA), Centro Regional Universitario Bariloche, Universidad Nacional del Comahue - Consejo Nacional de Investigaciones Científicas y Técnicas (CONICET). San Carlos de Bariloche, Río Negro, Argentina.
Agustín Sáez Laboratorio Ecotono, Instituto de Investigaciones en Biodiversidad y Medio Ambiente (INIBIOMA), Centro Regional Universitario Bariloche, Universidad Nacional del Comahue - Consejo Nacional de Investigaciones Científicas y Técnicas (CONICET). San Carlos de Bariloche, Río Negro, Argentina.

DOI:

https://doi.org/10.25260/EA.17.27.3.0.494

Abstract

Biodiversity is being lost at an alarming rate. One of the main causes of this loss is the land-use change caused by the expansion of conventional agriculture and livestock production. Management practices such as monocultures and the intensive use of agrochemicals reduce the number of species of plants, birds, insects and other taxonomic groups, and increase, at the same time, the relative abundance (dominance) of one or a few cultivated and wild (e.g., weed) species. Given that ~40% of the terrestrial surface is occupied by crop and livestock lands, it is critical to increase food production without destroying biodiversity. In addition to the value given by its ethical and spiritual dimensions, and the potential use of future generations, in this article we discuss the value of biodiversity for agriculture, using pollinators as a case of study. Paradoxically, conventional agriculture is reducing pollinator diversity, but this diversity is necessary for increasing productivity (and its temporal and spatial stability) of many crops. Several studies show that the loss of wild pollinator diversity cannot be replaced by a high abundance of a single pollinator species (dominance). Therefore, we discuss actions that producers, consumers, politicians and scientists can take to recover diversity. For example, producers can implement management practices in- and outside the crop fields to increase floral and nesting resources, and therefore pollinator abundance and diversity. In addition, consumers can modify diets, reduce waste and produce food at small scales, among many other actions. One single strategy will not be enough to solve the dilemma of producing food and preserving biodiversity. We argue that multiple actions must be taken urgently from all the stakeholders.

DOI: https://doi.org/10.25260/EA.17.27.3.0.494

References

Aizen, M. A., L. A. Garibaldi, S. A. Cunningham, and A. M. Klein. 2008. Long-term global trends in crop yield and production reveal no current pollination shortage but increasing pollinator dependency. Current Biology 18:1572-5.

Aizen, M. A., C. L. Morales, D. P. Vázquez, L. A. Garibaldi, A. Sáez, and L. D. Harder. 2014. When mutualism goes bad: density-dependent impacts of introduced bees on plant reproduction. New Phytologist 204:322-328.

Brittain, C., N. Williams, C. Kremen, and A. M. Klein. 2013. Synergistic effects of non-Apis bees and honey bees for pollination services. Proceedings of the Royal Society B: Biological Sciences 280:20122767.

Cardinale, B. J., J. E. Duffy, A. Gonzalez, D. U. Hooper, C. Perrings, P. Venail, A. Narwani, G. M. Mace, D. Tilman, D. A. Wardle, A. P. Kinzig, G. C. Daily, M. Loreau, J. B. Grace, A. Larigauderie, D. S. Srivastava, and S. Naeem. 2012. Biodiversity loss and its impact on humanity. Nature 486:59-67.

Fernández, R. J. 2014. Decálogo del ambientalismo estéril. Ecología Austral 24:356-364.

Foley, J. A., N. Ramankutty, K. A. Brauman, E. S. Cassidy, J. S. Gerber, M. Johnston, N. D. Mueller, C. O’Connell, D. K. Ray, P. C. West, C. Balzer, E. M. Bennett, S. R. Carpenter, J. Hill, C. Monfreda, S. Polasky, J. Rockström, J. Sheehan, S. Siebert, D. Tilman, and D. P. M. Zaks. 2011. Solutions for a cultivated planet. Nature 478:337-342.

Garibaldi, L. A., I. Bartomeus, R. Bommarco, A. M. Klein, S. A. Cunningham, M. A. Aizen, V. Boreux, M. P. D. Garratt, L. G. Carvalheiro, C. Kremen, C. L. Morales, C. Schüepp, N. P. Chacoff, B. M. Freitas, V. Gagic, A. Holzschuh, B. K. Klatt, K. M. Krewenka, S. Krishnan, M. M. Mayfield, I. Motzke, M. Otieno, J. Petersen, S. G. Potts, T. H. Ricketts, M. Rundlöf, A. Sciligo, P. A. Sinu, I. Steffan-Dewenter, H. Taki, T. Tscharntke, C. H. Vergara, B. F. Viana, and M. Woyciechowski. 2015. Trait matching of flower visitors and crops predicts fruit set better than trait diversity. Journal of Applied Ecology 52:1436-1444.

Garibaldi, L. A., L. G. Carvalheiro, S. D. Leonhardt, M. A. Aizen, B. R. Blaauw, R. Isaacs, M. Kuhlmann, D. Kleijn, A. M. Klein, C. Kremen, L. Morandin, J. Scheper, and R. Winfree. 2014. From research to action: enhancing crop yield through wild pollinators. Frontiers in Ecology and the Environment 12:439-447.

Garibaldi, L. A., L. G. Carvalheiro, B. E. Vaissiere, B. Gemmill-Herren, J. Hipolito, B. M. Freitas, H. T. Ngo, N. Azzu, A. Saez, J. Astrom, J. An, B. Blochtein, D. Buchori, F. J. C. Garcia, F. Oliveira da Silva, K. Devkota, M. d. F. Ribeiro, L. Freitas, M. C. Gaglianone, M. Goss, M. Irshad, M. Kasina, A. J. S. P. Filho, L. H. P. Kiill, P. Kwapong, G. N. Parra, C. Pires, V. Pires, R. S. Rawal, A. Rizali, A. M. Saraiva, R. Veldtman, B. F. Viana, S. Witter, and H. Zhang. 2016. Mutually beneficial pollinator diversity and crop yield outcomes in small and large farms. Science (New York, N.Y.) 351:388-391.

Garibaldi, L. A., I. Steffan-Dewenter, C. Kremen, J. M. Morales, R. Bommarco, S. A. Cunningham, L. G. Carvalheiro, N. P. Chacoff, J. H. Dudenhöffer, S. S. Greenleaf, A. Holzschuh, R. Isaacs, K. Krewenka, Y. Mandelik, M. M. Mayfield, L. A. Morandin, S. G. Potts, T. H. Ricketts, H. Szentgyörgyi, B. F. Viana, C. Westphal, R. Winfree, and A. M. Klein. 2011. Stability of pollination services decreases with isolation from natural areas despite honey bee visits. Ecology Letters 14:1062-1072.

Garibaldi, L. A., I. Steffan-Dewenter, R. Winfree, M. A. Aizen, R. Bommarco, S. A. Cunningham, C. Kremen, L. G. Carvalheiro, L. D. Harder, O. Afik, I. Bartomeus, F. Benjamin, V. Boreux, D. Cariveau, N. P. Chacoff, J. H. Dudenhöffer, B. M. Freitas, J. Ghazoul, S. Greenleaf, J. Hipólito, A. Holzschuh, B. Howlett, R. Isaacs, S. K. Javorek, C. M. Kennedy, K. Krewenka, S. Krishnan, Y. Mandelik, M. M. Mayfield, I. Motzke, T. Munyuli, B. A. Nault, M. Otieno, J. Petersen, G. Pisanty, S. G. Potts, R. Rader, T. H. Ricketts, M. Rundlöf, C. L. Seymour, C. Schüepp, H. Szentgyörgyi, H. Taki, T. Tscharntke, C. H. Vergara, B. F. Viana, T. C. Wanger, C. Westphal, N. Williams, and A. M. Klein. 2013. Wild pollinators enhance fruit set of crops regardless of honey bee abundance. Science (New York, N.Y.) 339:1608-1611.

Lefcheck, J. S., J. E. K. Byrnes, F. Isbell, L. Gamfeldt, J. N. Griffin, N. Eisenhauer, M. J. S. Hensel, A. Hector, B. J. Cardinale, and J. E. Duffy. 2015. Biodiversity enhances ecosystem multifunctionality across trophic levels and habitats. Nature Communications 6:6936.

Maxwell, S. L., R. A. Fuller, T. M. Brooks, and J. E. M. Watson. 2016. The ravages of guns, nets and bulldozers. Nature 536:146-145.

Newbold, T. 2016. Has land use pushed terrestrial biodiversity beyond the planetary boundary? A global assessment. Science (New York, N.Y.) 353:288-291.

Nyborg, K., J. M. Anderies, A. Dannenberg, T. Lindahl, C. Schill, M. Schüter, W. N. Adger, K. J. Arrow, S. Barrett, S. Carpenter, F. S. Chapin III, A. S. Crépin, G. Daily, P. Ehrlich, C. Folke, W. Jager, N. Kautsky, S. A. Levin, O. J. Madsen, S. Polasky, M. Scheffer, B. Walker, E. U. Weber, J. Wilen, A. Xepapadeas, and A. de Zeeuw. 2016. Social norms as solutions. Science 354:42-43.

Paruelo, J. M. 2016. El papel de la Ciencia en el proceso de Ordenamiento Territorial (y en otras cuestiones vinculadas con problemas ambientales ). Ecología Austral 26(1):51-58.

Potts, S. G., V. L. Imperatriz-Fonseca, H. T. Ngo, J. C. Biesmeijer, T. D. Breeze, L. V. Dicks, L. A. Garibaldi, R. Hill, J. Settele, A. J. Vanbergen, M. A. Aizen, S. A. Cunningham, C. Eardley, B. M. Freitas, N. Gallai, P. G. Kevan, A. Kovács-Hostyánszki, P. K. Kwapong, X. L. J. Li, D. J. Martins, G. Nates-Parra, J. S. Pettis, R. Rader, and B. F. Viana. 2016. IPBES (2016): Summary for policymakers of the assessment report of the Intergovernmental Science-Policy Platform on Biodiversity and Ecosystem Services on pollinators, pollination and food production.

Tilman, D., F. Isbell, and J. M. Cowles. 2014. Biodiversity and ecosystem functioning. Annual Review of Ecology, Evolution, and Systematics 45:471-493.

World Health Organization. 2016. Obesity and overweight. URL: www.who.int/mediacentre/factsheets/fs311/en/.