Riesgos de desaparición de líquenes por desplazamiento del hábitat en un escenario de calentamiento global en el suroeste de los Andes venezolanos

Vicente Marcano; Laura Castillo

doi:10.3989/collectbot.2023.v42.003

Autores/as

Vicente Marcano Laboratorio de Biología Evolutiva y Organismos Extremos, Grupo de Ciencias Atmosféricas y el Espacio, Facultad de Ciencias, Universidad de Los Andes - Biological Station “Vicente Marcano”, Kailasha Organization, Sierra Nevada National Park https://orcid.org/0000-0002-0068-6642
Laura Castillo Biological Station “Vicente Marcano”, Kailasha Organization, Sierra Nevada National Park - ETSUFOR, Facultad de Ciencias Forestales y Ambientales, Universidad de Los Andes https://orcid.org/0000-0001-8495-8387

DOI:

https://doi.org/10.3989/collectbot.2023.v42.003

Palabras clave:

Andes tropicales, bosques nublados, cambio climático, macrolíquenes, páramos, pérdida de hábitat

Resumen

Con la finalidad de determinar los riesgos de pérdida local de hábitats de líquenes tomando en consideración la migración ascendente de las condiciones ambientales debido al calentamiento previsto para el presente siglo, se realizaron muestreos en el suroeste de los Andes venezolanos, Parque Nacional General Juan Pablo Peñaloza, en un rango de elevación entre los 2000 m (bosque montano) a 3660 m (páramo andino). Después de dos años de exploraciones se registraron 104 especies y 39 géneros, 44 especies en el bosque montano y 82 especies en el páramo. Ante un incremento de 2°C a fin de siglo, los taxones requerirían un desplazamiento ascendente de ~363 m, mientras si se escoge un incremento máximo de 4°C, el desplazamiento sería >725 m. Los resultados indican que el 64% de los géneros estarían amenazados de desaparición local por pérdida de hábitat ante un incremento de temperatura ≤2°C, mientras el 12,8% conservarían su hábitat a pesar de un incremento de 4°C; 81,73% de las especies estarían amenazadas de extinción local por pérdida de hábitat ante un incremento ≤2°C, mientras el 92,3% de las especies perderían su hábitat ante un incremento ≤4°C. En ambos escenarios existiría un riesgo de desaparición masiva.

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