Xiaqing Zhao scite author profile

Wild populations of the model organism Drosophila melanogaster experience highly heterogeneous environments over broad geographical ranges as well as over seasonal and annual timescales. Diapause is a primary adaptation to environmental heterogeneity, and in D. melanogaster the propensity to enter diapause varies predictably with latitude and season. Here we performed global transcriptomic profiling of naturally occurring variation in diapause expression elicited by short day photoperiod and moderately low temperature in two tissue types associated with neuroendocrine and endocrine signaling, heads, and ovaries. We show that diapause in D. melanogaster is an actively regulated phenotype at the transcriptional level, suggesting that diapause is not a simple physiological or reproductive quiescence. Differentially expressed genes and pathways are highly distinct in heads and ovaries, demonstrating that the diapause response is not uniform throughout the soma and suggesting that it may be comprised of functional modules associated with specific tissues. Genes downregulated in heads of diapausing flies are significantly enriched for clinally varying single nucleotide polymorphism (SNPs) and seasonally oscillating SNPs, consistent with the hypothesis that diapause is a driving phenotype of climatic adaptation. We also show that chromosome location-based coregulation of gene expression is present in the transcriptional regulation of diapause. Taken together, these results demonstrate that diapause is a complex phenotype actively regulated in multiple tissues, and support the hypothesis that natural variation in diapause propensity underlies adaptation to spatially and temporally varying selective pressures.

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Evolution of natural lifespan variation and molecular strategies of extended lifespan in yeast

Kaya

Phua

Lee

et al. 2021

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To understand the genetic basis and selective forces acting on longevity, it is useful to examine lifespan variation among closely related species, or ecologically diverse isolates of the same species, within a controlled environment. In particular, this approach may lead to understanding mechanisms underlying natural variation in lifespan. Here, we analyzed 76 ecologically diverse wild yeast isolates and discovered a wide diversity of replicative lifespan (RLS). Phylogenetic analyses pointed to genes and environmental factors that strongly interact to modulate the observed aging patterns. We then identified genetic networks causally associated with natural variation in RLS across wild yeast isolates, as well as genes, metabolites, and pathways, many of which have never been associated with yeast lifespan in laboratory settings. In addition, a combined analysis of lifespan-associated metabolic and transcriptomic changes revealed unique adaptations to interconnected amino acid biosynthesis, glutamate metabolism, and mitochondrial function in long-lived strains. Overall, our multiomic and lifespan analyses across diverse isolates of the same species shows how gene–environment interactions shape cellular processes involved in phenotypic variation such as lifespan.

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The metabolome as a biomarker of aging in Drosophila melanogaster

et al. 2022

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Chronological age is the single greatest risk factor for functional deterioration, chronic diseases, and mortality (Harman, 1991). Several decades of research in laboratory organisms have led to the discovery of numerous hallmarks of aging and of evolutionarily conserved genetic pathways that can extend health span and lifespan (Kaeberlein et al., 2015). However, in real-world settings, individuals vary in genetic and environmental background, and these factors mean that individuals of the same age can differ considerably in patterns of aging, even at quite young age (Belsky et al., 2015). To quantify this variation, to predict future trajectories of aging, and to identify the mechanisms that might underlie this variation, researchers have long sought predictive and prognostic biomarkers of aging (Baker & Sprott, 1988).A diverse array of traits have been identified that associated with chronological age, including morphological and physiological features such as handgrip strength (Bohannon, 2015), vascular structure and function (Fedintsev et al., 2017), facial morphology

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A resource on latitudinal and altitudinal clines of ecologically relevant phenotypes of the Indian Drosophila

2017

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The unique geography of the Indian subcontinent has provided diverse natural environments for a variety of organisms. In this region, many ecological indices such as temperature and humidity vary predictably as a function of both latitude and altitude; these environmental parameters significantly affect fundamental dynamics of natural populations. Indian drosophilids are diverse in their geographic distribution and climate tolerance, possibly as a result of climatic adaptation. These associations with environmental parameters are further reflected in a large number of clines that have been reported for various fitness traits along these geographical ranges. This unique amalgamation of environmental variability and genetic diversity make the subcontinent an ecological laboratory for studying evolution in action. We assembled data collected over the last 20 years on the geographical clines for various phenotypic traits in several species of drosophilids and present a web-resource on Indian-Drosophila ( http://www.indian-drosophila.org/). The clinal data on ecologically relevant phenotypes of Indian drosophilids will be useful in addressing questions related to future challenges in biodiversity and ecosystems in this region.

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Xiaqing Zhao

Global Transcriptional Profiling of Diapause and Climatic Adaptation inDrosophila melanogaster

Evolution of natural lifespan variation and molecular strategies of extended lifespan in yeast

The metabolome as a biomarker of aging in Drosophila melanogaster

A resource on latitudinal and altitudinal clines of ecologically relevant phenotypes of the Indian Drosophila

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