6 research outputs found
Exposure to Environmental Radionuclides Associates With Tissue-Specific Impacts on Telomerase Expression and Telomere Length
Telomeres, the protective structures at the ends of chromosomes, can be shortened when individuals are exposed to stress. In some species, the enzyme telomerase is expressed in adult somatic tissues, and potentially protects or lengthens telomeres. Telomeres can be damaged by ionizing radiation and oxidative stress, although the effect of chronic exposure to elevated levels of radiation on telomere maintenance is unknown for natural populations. We quantified telomerase expression and telomere length (TL) in different tissues of the bank vole Myodes glareolus, collected from the Chernobyl Exclusion Zone, an environment heterogeneously contaminated with radionuclides, and from uncontaminated control sites elsewhere in Ukraine. Inhabiting the Chernobyl Exclusion Zone was associated with reduced TL in the liver and testis, and upregulation of telomerase in brain and liver. Thus upregulation of telomerase does not appear to associate with longer telomeres but may reflect protective functions other than telomere maintenance or an attempt to maintain shorter telomeres in a stressful environment. Tissue specific differences in the rate of telomere attrition and apparent radiosensitivity weaken the intra-individual correlation in telomere length among tissues in voles exposed to radionuclides. Our data show that ionizing radiation alters telomere homeostasis in wild animal populations in tissue specific ways
Data from: Maintenance costs of male dominance and sexually antagonistic selection in the wild
1. Variation in dominance status determines male mating and reproductive success, but natural selection for male dominance can be detrimental or antagonistic for female performance, and ultimately their fitness. Attaining and maintaining a high dominance status in a population of competing individuals is physiologically costly for males. But how male dominance status is mediated by maintenance energetics is currently not well understood, nor are the correlational effects of male energetics on his sisters recognized. 2. We conducted laboratory and field experiments on rodent populations to test whether selective breeding for male dominance status (dominant vs. subordinate breeding lines) antagonistically affected basal metabolic rate (BMR) and fitness of females in the wild conditions. 3. Our results showed elevated BMR in females, but not in males, from the dominant breeding line. However, phenotypically dominant males from the subordinate breeding line had the highest BMR. 4. Males from the dominant line with low BMR sired the most litters and offspring in the field. Similarly, females from the dominant selection line tended to have more offspring if they had lower BMR, while the opposite trend was found in females from the subordinate selection line. The highest probability to reproduce had females of both high and low BMR, as indicated by significant quadratic selection gradient. 5. The increased female BMR resulting from selection for male dominance suggests genetic incompatibility between sexes in metabolism inheritance. Elevated BMR in behaviourally dominant males, but not in males from the dominant breeding line, suggests physiological costs in males not genetically suited for dominance. 6. Fitness costs of elevated maintenance costs (measured as BMR) shown here support the energetic compensation hypothesis where high BMR is selected against as it would trade-off energy required for other important life functions
Repeated evolution of camouflage in speciose desert rodents
There are two main factors explaining variation among species and the evolution of characters along
phylogeny: adaptive change, including phenotypic and genetic responses to selective pressures,
and phylogenetic inertia, or the resemblance between species due to shared phylogenetic history.
Phenotype-habitat colour match, a classic Darwinian example of the evolution of camouflage (crypsis),
offers the opportunity to test the importance of historical versus ecological mechanisms in shaping
phenotypes among phylogenetically closely related taxa. To assess it, we investigated fur (phenotypic
data) and habitat (remote sensing data) colourations, along with phylogenetic information, in
the species-rich Gerbillus genus. Overall, we found a strong phenotype-habitat match, once the
phylogenetic signal is taken into account. We found that camouflage has been acquired and lost
repeatedly in the course of the evolutionary history of Gerbillus. Our results suggest that fur colouration
and its covariation with habitat is a relatively labile character in mammals, potentially responding
quickly to selection. Relatively unconstrained and substantial genetic basis, as well as structural and
functional independence from other fitness traits of mammalian colouration might be responsible for
that observation.peerReviewe
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North African fox genomes show signatures of repeated introgression and adaptation to life in deserts
Elucidating the evolutionary process of animal adaptation to deserts is key to understanding adaptive responses to climate change. Here we generated 82 individual whole genomes of four fox species (genus Vulpes) inhabiting the Sahara Desert at different evolutionary times. We show that adaptation of new colonizing species to a hot arid environment has probably been facilitated by introgression and trans-species polymorphisms shared with older desert resident species, including a putatively adaptive 25 Mb genomic region. Scans for signatures of selection implicated genes affecting temperature perception, non-renal water loss and heat production in the recent adaptation of North African red foxes (Vulpes vulpes), after divergence from Eurasian populations approximately 78 thousand years ago. In the extreme desert specialists, Rueppell's fox (V. rueppellii) and fennec (V. zerda), we identified repeated signatures of selection in genes affecting renal water homeostasis supported by gene expression and physiological differences. Our study provides insights into the mechanisms and genetic underpinnings of a natural experiment of repeated adaptation to extreme conditions