Ecología y conservación de las aves asociadas con Polylepis: ¿qué sabemos de esta comunidad cada vez más vulnerable?

Cristian S. Sevillano Ríos; Amanda D. Rodewald; Laura V. Morales

doi:10.25260/EA.18.28.1.1.519

Autores/as

Cristian S. Sevillano Ríos Cornell Lab of Ornithology. Ithaca, NY, United States of America. http://orcid.org/0000-0002-0642-5224
Amanda D. Rodewald Cornell Lab of Ornithology. Ithaca, NY, United States of America. Department of Natural Resources, Cornell University. Ithaca, NY, United States of America.
Laura V. Morales Department of Plant Science, University of California Davis, United States of America.

DOI:

https://doi.org/10.25260/EA.18.28.1.1.519

Resumen

A lo largo de las montañas de Sudamérica, los bosques de Polylepis y la comunidad de aves que albergan sobresalen como uno de los ecosistemas de mayor prioridad de conservación. Estos bosques forman uno de los límites arbóreos más altos del mundo y son centros de diversidad y de endemismo biológico. Sin embargo, sus diferentes características ecológicas y las presiones de los seres humanos los hacen cada vez más vulnerables a la degradación y a los futuros cambios climáticos. Realizamos una revisión del estado del conocimiento de las diversas especies de aves asociadas con Polylepis a fin de guiar los esfuerzos para su conservación. Varias publicaciones sugieren que la función de los ecosistemas de Polylepis como hábitat para las aves está influenciada por su distribución continental y por factores locales y de paisaje, incluyendo las actividades humanas y las perturbaciones. Identificamos 29 áreas de prioridad para la conservación de Polylepis a lo largo de toda su distribución, que en conjunto mantienen 44 especies de aves endémicas, amenazadas o con alto grado de asociación con los bosques de Polylepis. Según la lista de aves amenazadas de la IUCN, dos especies están categorizadas en estado crítico, 8 en peligro, 8 vulnerables y 9 como casi amenazadas. Además, 70% de estas especies (31) poseen rangos de distribución restringida, y son endémicas a un solo país, mientras que 52% (23) poseen un alto o mediano grado de asociación con los bosques de Polylepis. Las recomendaciones de diversos estudios coinciden en que aumentar la conectividad entre parches y la permeabilidad de la matriz, y reducir la erosión, la quema y la ganadería contribuirían a mejorar la conservación y la recuperación de los ecosistemas de Polylepis y de las aves que en ella habitan.

https://doi.org/10.25260/EA.18.28.1.1.519

Biografía del autor/a

Cristian S. Sevillano Ríos, Cornell Lab of Ornithology. Ithaca, NY, United States of America.

Recursos Naturales

Estudiante de Doctorado

Citas

Alinari, J., A. von Müller, and D. Renison. 2015. The contribution of fire damage to restricting high mountain Polylepis australis forests to ravines: Insights from an un-replicated comparison. Ecología Austral 25:11-18.

Arnal, H., A. Sampson, G. Navarro, W. Palomino, W. Ferreira, K. Romoleroux, D. Caro, I. Teich, E. Cuyckens, C. Antezana, S. Arrazola, C. Aucca, J. Balderrama, S. Beck, S. Burneo, N. De la Barra, A. Bustamante, Y. Fandinso, G. Ferro, I. Gomez, G. Guzman, J. Iglesias, J. Irazabal, P. Lozano, M. Mercado, A. Monsalve, D. Renison, S. Salgado, and E. Samochuallpa. 2014. Mapa Pan Andino de Bosques de Polylepis prioritarios para Conservación. American Bird Conservancy, The Plains, USA.

Aucca, C., F. Olmos, O. Santander, and A. Chamorro. 2015. Range extension and new habitat for the Critically Endangered Royal Cinclodes Cinclodes aricomae. Cotinga 37:12-17.

Aucca, C., and P. M. Ramsay. 2005. Management of biodiversity and land use in southern Peru: ECOAN's activities to help conserve Polylepis woodlands. Mountain Research and Development 25:287-289.

Bellis, L. M., L. Rivera, N. Politi, E. Martin, M. L. Perasso, F. Cornell, and D. Renison. 2009. Latitudinal patterns of bird richness, diversity and abundance in Polylepis australis mountain forest of Argentina. Bird Conservation International 19:265-276.

Bellis, L. M., A. Pidgeon, C. Alcántara, S. Dardanelli, and V. Radeloff. 2015. Influences of succession and erosion on bird communities in a South American highland wooded landscape. Forest Ecology and Management 349:85-93. doi: 10.1016/j.foreco.2015.03.047.

BirdLife International. 2017. IUCN Red List for birds. URL: www.birdlife.org (24/04/2017).

Cahill, J., and E. Matthysen. 2007. Habitat use by two specialist birds in high-Andean Polylepis forests. Biology Conservation 140:62-69.

Cierjacks, A., S. Salgado, K. Wesche, and I. Hensen. 2008. Post-fire population dynamics of two tree species in high-altitude Polylepis forests of Central Ecuador. Biotropica 40:176-182.

Colwell, R. K., G. Brehm, C. L. Cardelús, A. C. Gilman, and J. T. Longino. 2008. Global warming, elevational range shifts, and lowland biotic attrition in the wet tropics. Science 322:258-261.

Crick, H. Q. 2004. The impact of climate change on birds. Ibis 146:48-56.

Cuyckens, E., D. A. Christie, A. I. Domic, L.R. Malizia, and D. Renison. 2016. Climate change and the distribution and conservation of the world’s highest elevation woodlands in the South American Altiplano. Glob Planet Change 137:79-87.

Domic, A. I., G.R. Camilo, and J.M. Capriles. 2014. Small-scale farming and grazing reduce regeneration of Polylepis tomentella (Rosaceae) in the Semiarid Andes of Bolivia. Biotropica 46:106-114. doi: 10.1111/btp.12075.

Fandiño, Y., and D. Caro. 2009. Mapa general de identificación de áreas potenciales de bosques de Polylepis en los Andes colombianos. Conservación Colombiana 10:7-44

Fjeldså, J. 1992. Biogeography of the birds of the Polylepis woodlands of the Andes. Pp. 71-84 in J. L. Luteyn and H. Balslev (eds.). Paramo, an Andean ecosystem under human influence. Academic Press, London, UK.

Fjeldså, J. 1993. The avifauna of the Polylepis woodlands of the Andean highlands: the efficiency of basing conservation priorities on patterns of endemism. Bird Conservation International 3: 37-55.

Fjeldså, J. 2002. Polylepis Forest-Vestiges of a vanishing Andean Ecosystem. Ecotropica 8:111-123.

Fjeldså, J., and N. K. Krabbe. 1990. Birds of the high Andes. Zoological Museum University of Copenhagen and Apollo Books, Copenhagen, Denmark.

Fjeldså, J., E. Lambin, and B. Mertens. 1999. Correlation between endemism and local ecoclimatic stability documented by comparing Andean bird distributions and remotely sensed land surface data. Ecography 22:63-78.

Fjeldså, J., R. Bowie, and C. Rahbek. 2012. The role of mountain ranges in the diversity of birds. Annu Rev Ecol Evol Syst 43:249-65.

Fraser, B. 2012. Melting in the Andes: Goodbye glaciers. Nature 491:180-182.

Frimer, O., and S. M. Nielsen. 1989. The status of Polylepis forests and their avifauna in Cordillera Blanca, Peru: technical report from an inventory in 1988, with suggestions for conservation management. Zoological Museum, University of Copenhagen, Copenhagen, Denmark.

Fuentealba, B., and C. S. Sevillano-Ríos. 2016. Experiencias de rehabilitación comunitaria con queñual (Polylepis sp.) en el Departamento de Ancash, Perú. Pp. 331 en E. Ceccon and D. R. Pérez (eds.). Más allá de la ecología de la restauración: perspectivas sociales en América Latina y el Caribe. Vázquez Mazzini Editores, Buenos Aires, Argentina.

Gareca, E. E., M. Hermy, J. Fjeldså, and O. Honnay. 2010. Polylepis woodland remnants as biodiversity islands in the Bolivian high Andes. Biodiversity and conservation 19:3327-3346.

GBIF.org. 2017. GBIF Occurrence. doi: 10.15468/dl.v9sm0j.

Gosling, W. D., J. A. Hanselman, C. Knox, B. G. Valencia, and M. B. Bush. 2009. Long‐term drivers of change in Polylepis woodland distribution in the central Andes. Journal of Vegetation Science 20: 1041-1052.

Herzog, S. K., R. Martínez, P. M. Jørgensen, and H. Tiessen. 2011. Climate change and biodiversity in the tropical Andes. São José dos Campos: Inter-American Institute for Global Change Research. Pp. 348.

Herzog, S. K., R. Soria, and E. Matthysen. 2003. Seasonal variation in avian community composition in a high-Andean Polylepis (Rosaceae) forest fragment. The Wilson Bulletin of Ornithology 115:438-447.

Hjarsen, T. 1999. Bird diversity and community structure. En Monitoring and management of high Andean biodiversity - a study from Cochabamba, Bolivia. Centre for Research on the Cultural and Biological Diversity of Andean Rainforests.

Hoch, G., and C. Körner. 2005. Growth, demography and carbon relations of Polylepis trees at the world's highest treeline. Functional Ecology 19:941-951.

Jameson, J. S., and P. M. Ramsay. 2007. Changes in high-altitude Polylepis forest cover and quality in the Cordillera de Vilcanota, Perú, 1956-2005. Biological Conservation 138:38-46.

Kessler, M. 1995. The genus Polylepis (Rosaceae) in Bolivia. Candollea 50:131-171.

Kessler, M. 2002. The “Polylepis problem”: where do we stand. Ecotropica 8:97-110.

Kessler, M. 2006. Bosques de Polylepis. Pp. 110-120 en M. Baslev (eds.). Botánica económica de los Andes Centrales. Universidad Mayor de San Andrés, La Paz, Bolivia.

Kessler, M., and A. N. Schmidt-Lebuhn. 2006. Taxonomical and distributional notes on Polylepis (Rosaceae). Organisms diversity and evolution 6:67-69.

Kessler, M., J. M. Toivonen, S. P. Sylvester, J. Kluge, and D. Hertel. 2014. Elevational patterns of Polylepis tree height (Rosaceae) in the high Andes of Peru: role of human impact and climatic conditions. Frontiers in Plant Science 5:194. doi: 10.3389/fpls.2014.00194.

La Sorte, F. A., and W. Jetz. 2010. Projected range contractions of montane biodiversity under global warming. Proceedings of the Royal Society of London B. Biological Sciences. doi: 10.1098/rspb.2010.0612.

Lloyd, H. 2008a. Abundance and patterns of rarity of Polylepis birds in the Cordillera Vilcanota southern Peru: implications for habitat management strategies. Bird Conservation International 18:164-180.

Lloyd, H. 2008b. Foraging ecology of high Andean insectivorous birds in remnant Polylepis forest patches. The Wilson Bulletin of Ornithology 120:531-544.

Lloyd, H. 2008c. Influence of within‐patch habitat quality on high‐Andean Polylepis bird abundance. Ibis 150:735-745.

Lloyd, H., and S. J. Marsden. 2008. Bird community variation across Polylepis woodland fragments and matrix habitats: implications for biodiversity conservation within a high Andean landscape. Biodiversity and Conservation 17:2645-2660.

Lloyd, H., and S. J. Marsden. 2011. Between‐patch bird movements within a high‐Andean Polylepis woodland/matrix landscape: Implications for habitat restoration. Restoration Ecology 19:74-82.

Márcora, P., I. Hensen, D. Renison, P. Seltmann, and K. Wesche. 2008. The performance of Polylepis australis trees along their entire altitudinal range: implications of climate change for their conservation. Diversity and Distributions 144: 630-636.

Martínez, R., D. Ruiz, M. Andrade, L. Blacutt, D. Pabón, E. Jaimes, G. León, M. Villacís, J. Quintana, E. Montealegre, and C. Euscátegui. 2011. Synthesis of the climate of the Tropical Andes. S. K. Herzog, R. Martínez, P. M. Jørgensen and H. Tiessen (eds.). Climate change and biodiversity in the tropical Andes. São José dos Campos: Inter-American Institute for Global Change Research.

Matthysen, E., F. Collet, and J. Cahill. 2008. Mixed flock composition and foraging behavior of insectivorous birds in undisturbed and disturbed fragments of high-Andean Polylepis woodland. Ornitologia Neotropical 19:403-416.

Mazar-Barnett, J., G. D. Pugnali, and M. Della Seta. 1998. Primer registro del Sai grande Oreomanes fraseri (Passeriformes: Coerebidae, Thraupidae) en la Argentina. El Hornero 15:044-046.

Mendoza, W., and A. Cano. 2011. Diversidad del género Polylepis (Rosaceae, Sanguisorbeae) en los Andes peruanos. Revista Peruana de Biología 18:197-200.

Mendoza, W., and A. Cano. 2012. El Género Polylepis en el Perú. Taxonomía, Morfología y Distribución. Perú: Editorial Académica Española.

Møller, A., W. Fiedler, and P. Berthold. 2010. Effects of climate change on Birds. Oxford University Press. Pp. 321.

Morales, L. 2017. Polylepis regeneration and the potential for forest expansion in the Peruvian Andes: The influence of cattle and environmental conditions. Doctoral Dissertation, University of California Davis.

Morales, L. V., C. S. Sevillano., S. Fick., and T. Young. 2018. Differential seedling regeneration patterns across forest-grassland ecotones in two tropical treeline species (Polylepis spp.). Austral Ecology. Early View.

DOI: 10.1111/aec.12588.

Neelin, J. D., M. Münnich, H. Su, J. Meyerson, and C. Holloway. 2006. Tropical drying trends in global warming models and observations. Proceedings of the National Academy of Sciences 103:6110-6115.

Ocampo-Peñuela, N., C. N. Jenkins, V. Vijay, B. V. Li, and S. L. Pimm. 2016. Incorporating explicit geospatial data shows more species at risk of extinction than the current Red List. Sci Adv 2:e1601367.

Parker, T. A. III. 1981. Distribution and biology of the White-cheeked Cotinga Zaratornis stresemanni, a high Andean frugivore. Bulletin of the British Ornithologists’ Club 101:156-265.

Parmesan, C. 2006. Ecological and evolutionary responses to recent climate change. Annual Review in Ecology Evolutions and Systematics. 37:637-669.

Purcell, J., and A. Brelsford. 2004. Reassessing the causes of decline of Polylepis, a tropical subalpine forest. Ecotropica 10:155-158.

Rabatel, A., B. Francou, A. Soruco, J. Gómez, B. Cáceres, J. L. Ceballos, R. Basantes, M. Vuille, J. Sicart, C. Huggel, M. Scheel, Y, Lejeune, Y. Arnaud, M. Collet, T. Condom, G. Consoli, V. Favier, V. Jomelli, R. Galarraga, P. Ginot, L. Maisincho, J. Mendoza, M. Menegoz, E. Ramírez, P. Ribstein, W. Suarez, M. Villacis, and P. Wagnon. 2013. Current state of glaciers in the tropical Andes: a multi-century perspective on glacier evolution and climate change. Cryosphere 7:81-102.

Rehm, E., and K. Feely. 2013. Forest patches and the upward migration of timberline in the southern Peruvian Andes. Forest Ecology and Management 305:204-211.

Rehm, E., and K. Feeley. 2016. Many species risk mountain top extinction long before they reach the top. Frontiers of Biogeography 8:e27788.

Renison, D., I. Hensen, and A. M. Cingolani. 2006. Cover and growth habit of Polylepis woodlands and shrublands in the mountains of central Argentina: human or environmental influence? Journal of Biogeography 33:876-887.

Renison, D., I. Hensen, R. Suárez, A. M. Cingolani, P. Márcora, and M. A. Giorgis. 2010. Soil conservation in Polylepis mountain forests of Central Argentina: Is livestock reducing our natural capital? Austral Ecology 35:435-443.

Renison, D., G. A. Cuyckens, S. Pacheco, G. F. Guzmán, H. R. Grau, P. Márcora, G. Robledo, A. M. Cingolani, J. Domínguez, M. Landi, and L. Bellis. 2013. Distribución y estado de conservación de las poblaciones de árboles y arbustos del género Polylepis (Rosaceae) en las montañas de Argentina. Ecología Austral 23:27-36.

Renison, D., M. L. Herrero, R. Torres, R. Suárez, P. Friedlander, S. Navarro, F. Barri, and A. Cingolani. 2016. El rol de los voluntariados en la restauración ecológica del centro argentino. Pp. 55-76 en E. Ceccon and D. R. Pérez (eds.). Más allá de la ecología de la restauración: perspectivas sociales en América Latina y el Caribe. Vázquez Mazzini Editores, Buenos Aires, Argentina.

Ridbäck, U. A. 2008. Floristic Study of Polylepis Forest Fragments in the Central Andes of Ecuador. 25. Gotland University, Visby, Sweden.

Robledo, G., and D. Renison. 2010. Wood-decaying polypores in the mountains of central Argentina in relation to Polylepis forest structure and altitude. Fungal Ecology 3:178-184

Schulenberg, T. S., D. F. Stotz, D. F. Lane, J. P. O'Neill, and T. A. Parker III. 2010. Birds of Peru: revised and updated edition. Princeton University Press, Princeton, New Jersey.

Şekercioğlu, Ç. H., S. H. Schneider, J. P. Fay, and S. R. Loarie. 2008. Climate change, elevational range shifts, and bird extinctions. Conservation Biology 22:140-150.

Şekercioğlu, Ç. H., R. B. Primack, and J. Wormworth. 2012. The effects of climate change on tropical birds. Biology and Conservation 1481:1-18.

Servat, G. P. 2006. The role of local and regional factors in the foraging ecology of birds associated with Polylepis woodlands. Doctoral Dissertation, University of Missouri-St. Louis, USA. Dissertations 588. URL: goo.gl/Umxhkt.

Sevillano-Ríos, C. S. 2010. Efectos de la fragmentación y degradación de hábitat de queñual (Polylepis spp.) con respecto a la avifauna asociada en la Reserva de Biosfera Huascarán. Tesis de Licenciatura, Universidad Peruana Cayetano Heredia. Lima. Perú. Pp. 102.

Sevillano-Ríos, C. S. 2016. Diversity ecology and conservation of bird communities of Polylepis woodlands in the northern Andes of Peru. Master Thesis, Cornell University. Ithaca. USA. Pp. 149.

Sevillano-Ríos, C. S., H. Lloyd, and A. Valdés-Velásquez. 2011. Bird species richness diversity and abundance in Polylepis woodlands Huascaran Biosphere Reserve Peru. Studies on Neotropical Fauna and Environment 46:69-76.

Sevillano-Ríos, C. S., and A. D. Rodewald. 2017. Avian community structure and habitat use of Polylepis forests along an elevation gradient. PeerJ 5:e3220. doi: 10.7717/peerj.3220.

Simpson, B. B. 1979. A revision of the genus Polylepis (Rosaceae). Sanguisorbeae No. 43. Smithsonian Institution Press, Washington, DC.

Sylvester, S. P., M. D. Sylvester, and M. Kessler. 2014. Inaccessible ledges as refuges for the natural vegetation of the high Andes. Journal of Vegetation Science 25:1225-1234.

Tinoco, B. A., P. X. Astudillo, S. C. Latta, D. Strubbe, and C. H. Graham. 2013. Influence of patch factors and connectivity on the avifauna of fragmented Polylepis forest in the Ecuadorian Andes. Biotropica 45:602-611.

Toivonen, J. M. 2014. Determinants of Polylepis (Rosaceae) forest distribution and treeline formation in the high Andes. Doctoral thesis. University of Turku. Finlandia. Pp. 41.

Torres, R. C., D. Renison, I. Hensen, R. Suárez, and L. Enrico. 2008. Polylepis australis' regeneration niche in relation to seed dispersal, site characteristics and livestock density. Forest Ecology and Management 254:255-260.

Urrutia, R., and M. Vuille. 2009. Climate change projections for the tropical Andes using a regional climate model: Temperature and precipitation simulations for the end of the 21st century. Journal of Geophysical Research 114:D02108. doi: 10.1029/2008JD011021.

Valderrama, S., and J. C. Verhelst. 2009. Avifauna asociada a los bosques de Polylepis en Colombia. Conservación Colombiana 10:45-68.

Valencia, B. G., M. B. Bush., A. L. Coe., E. Orren., and W. D. Gosling. 2018. Polylepis woodland dynamics during the last 20,000 years. J Biogeogr 00:1-12. DOI: 10.1111/jbi.13209.

Vuille, M., B. Francou, P. Wagnon, I. Juen, G. Kaser, B. G. Mark, and R. S. Bradley. 2008. Climate change and tropical Andean glaciers: Past present and future. Earth-Sci Rev 89:79-96.

Vuilleumier, F. 1984. Patchy distribution and systematics of Oreomanes fraseri (Aves, Coerebidae) of Andean Polylepis woodlands. American Museum Novitates 2777:1-17.

Williams, R., and J. Ferrigno. 1999. Glaciers of South America. In R. Williams and J. Ferrigno (eds.). Satellite Image Atlas of Glaciers of the World. U.S. Geological Survey professional paper 1386. ISBN 0-607-92475-6. URL: pubs.usgs.gov/pp/p1386i.

Wormworth, J., and C. H. Sekercioglu. 2011. Winged sentinels: birds and climate change. Cambridge University Press. Pp. 262.

Wormworth, J., and K. Mallon. 2007. Bird Species and Climate Change. The Global Status Report. Climate Risk, New South Wales (Australia). Pp. 75.

Yallico, E. 1992. Distribución de Polylepis en el sur de Puno. Arbolandino. Puno, Perú. Pp. 134.

Young, K. 2011. Introduction to Andean Geographies. Pp. 128-140 in S. K. Herzog, R. Martínez, P. M. Jørgensen and H. Tiessen (eds.). Climate Change and Biodiversity in the Tropical Andes. Inter-American Institute for Global Change Research (IAI) and Scientific Committee on Problems of the Environment (SCOPE). ISBN: 978-85-99875-05-6. doi: 10.13140/2.1.3718.4969.

Zutta, B. R., P. W. Rundel, S. Saatchi, J. D. Casana, P. Gauthier, A. Soto, and W. Buermann. 2012. Prediciendo la distribución de Polylepis: bosques Andinos vulnerables y cada vez más importantes. Revista Peruana de Biología 19:205-212.