Journal
PROCEEDINGS OF THE NATIONAL ACADEMY OF SCIENCES OF THE UNITED STATES OF AMERICA
Volume 119, Issue 25, Pages -Publisher
NATL ACAD SCIENCES
DOI: 10.1073/pnas.2122944119
Keywords
life; telomere; climate change; fitness
Categories
Funding
- Max Planck Society Minerva Program
- Australian Research Council [FT10100505, DP150103595, DP180100058]
- Monash University
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Climate warming poses risks to wildlife by exposing them to sublethal high temperatures, leading to long-term impacts and reduced adaptability. This study found that the early-life telomere length (TL) of purple-crowned fairy-wren nestlings was associated with climatic and environmental conditions, particularly temperature and water availability. Models predicted that shorter TL under projected warming scenarios could result in population decline. However, if TL is an adaptive trait, population viability may be maintained through evolution.
Climate warming is increasingly exposing wildlife to sublethal high temperatures, which may lead to chronic impacts and reduced fitness. Telomere length (TL) may link heat exposure to fitness, particularly at early-life stages, because developing organisms are especially vulnerable to adverse conditions, adversity can shorten telomeres, and TL predicts fitness. Here, we quantify how climatic and environmental conditions during early life are associated with TL in nestlings of wild purple-crowned fairy-wrens (Malurus coronatus), endangered songbirds of the monsoonal tropics. We found that higher average maximum air temperature (range 31 to 45 degrees C) during the nestling period was associated with shorter early-life TL. This effect was mitigated by water availability (i.e., during the wet season, with rainfall), but independent of other pertinent environmental conditions, implicating a direct effect of heat exposure. Models incorporating existing information that shorter early-life TL predicts shorter lifespan and reduced fitness showed that shorter TL under projected warming scenarios could lead to population decline across plausible future water availability scenarios. However, if TL is assumed to be an adaptive trait, population viability could be maintained through evolution. These results are concerning because the capacity to change breeding phenology to coincide with increased water availability appears limited, and the evolutionary potential of TL is unknown. Thus, sublethal climate warming effects early in life may have repercussions beyond individual fitness, extending to population persistence. Incorporating the delayed reproductive costs associated with sublethal heat exposure early in life is necessary for understanding future population dynamics with climate change.
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