Telomeres, protective caps at the end of chromosomes, are often positively related to lifespan and are thought to be an important mechanism of organismal aging. To better understand the casual relationships between telomere length and longevity, it is essential to be able to experimentally manipulate telomere dynamics (length and loss rate). Previous studies suggest that exposure to TA‐65, an extract from the Chinese root
- Award ID(s):
- 1656194
- PAR ID:
- 10245276
- Date Published:
- Journal Name:
- Molecular ecology
- ISSN:
- 1365-294X
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
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Abstract Astragalus membranaceus , activates telomerase, lengthens telomeres, increases the growth of keratin‐based structures, and boosts the immune system in adults. However, telomere loss is expected to be greatest during early life but whether TA‐65 has similar effects during this life stage is currently unknown. Here, we experimentally exposed free‐living house sparrow (Passer domesticus ) chicks to TA‐65 during post‐natal development and examined the effects on telomere length and loss, growth of keratin‐based structures, and a measure of cellular immunity. Contrary to expectation, the growth of keratin‐based structures was reduced in TA‐65 chicks and in the second year of the study, chicks exposed to TA‐65 experienced more telomere loss than controls. Thus, the effects of TA‐65 on telomeres and keratin‐based structures differ across life stages and future research will be necessary to determine the mechanisms underlying these age‐specific effects. -
Abstract Parental age at offspring conception often influences offspring longevity, but the mechanisms underlying this link are poorly understood. One mechanism that may be important is telomeres, highly conserved, repetitive sections of non‐coding DNA that form protective caps at chromosome ends and are often positively associated with longevity. Here, the potential pathways by which the age of the parents at the time of conception may impact offspring telomeres are described first, including direct effects on parental gamete telomeres and indirect effects on offspring telomere loss during pre‐ or post‐natal development. Then a surge of recent studies demonstrating the effects of parental age on offspring telomeres in diverse taxa are reviewed. In doing so, important areas for future research and experimental approaches that will enhance the understanding of how and when these effects likely occur are highlighted. It is concluded by considering the potential evolutionary consequences of parental age on offspring telomeres.
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Parental stress often has long-term consequences for offspring. However, the mechanisms underlying these effects and how they are shaped by conditions offspring subsequently experience are poorly understood. Telomeres, which often shorten in response to stress and predict longevity, may contribute to, and/or reflect these cross-generational effects. Traditionally, parental stress is expected to have negative effects on offspring telomeres, but experimental studies in captive animals suggest that these effects may depend on the subsequent conditions that offspring experience. Yet, the degree to which parental stress influences and interacts with stress experienced by offspring to affect offspring telomeres and survival in free-living organisms is unknown. To assess this, we experimentally manipulated the stress exposure of free-living parent and offspring house sparrows ( Passer domesticus ). We found a weak, initial, negative effect of parental stress on offspring telomeres, but this effect was no longer evident at the end of post-natal development. Instead, the effects of parental stress depended on the natural sources of stress that offspring experienced during post-natal development whereby some outcomes were improved under more stressful rearing conditions. Thus, the effects of parental stress on offspring telomeres and survival are context-dependent and may involve compensatory mechanisms of potential benefit under some circumstances.more » « less
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Abstract Conditions during early life can have dramatic effects on adult characteristics and fitness. However, we still know little about the mechanisms that mediate these relationships. Telomere shortening is one possibility. Telomeres are long sequences of DNA that protect the ends of chromosomes. They shorten naturally throughout an individual's life, and individuals with short telomeres tend to have poorer health and reduced survival. Given this connection between telomere length (TL) and fitness, natural selection should favor individuals that are able to retain longer telomeres for a greater portion of their lives. However, the ability of natural selection to act on TL depends on the extent to which genetic and environmental factors influence TL. In this study, we experimentally enlarged broods of Tree Swallows (
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Abstract Telomeres, tandem repeats of TTAGGG at the ends of chromosomes, are highly dynamic structures that shorten in response to a variety of factors, including organismal stress and tissue‐specific growth rates. Cell turnover rates are frequently linked to their functions, resource availability and telomere dynamics. Using male red‐sided garter snakes,
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