Temperature-dependent behaviours are genetically variable in the nematode <i>Caenorhabditis briggsae</i>

Stegeman, Gregory W.; Mesquita, Matthew Bueno de; Ryu, William S.; Cutter, Asher D.

doi:10.1242/jeb.075408

Cited by 18 publications

(29 citation statements)

References 45 publications

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“…Given this ecological context, along with resources such as recombinant inbred line (RIL) libraries and chromosomescale genome assembly (Ross et al, 2011;Stegeman, Baird, Ryu, & Cutter, 2019), C. briggsae represents a valuable system to understand the links between temperature and genetic background in differential gene expression. The exemplar tropical and temperate genotypes used as RIL parents (AF16 and HK104), the focus of the present study, exhibit diverse temperature-dependent phenotypic differences consistent with adaptive differentiation of the phylogeographic groups overall, including for fecundity (~2-fold difference at 14°C and ~4-fold difference at 30°C), motility and gamete developmental traits (Poullet et al, 2015;Prasad et al, 2011;Stegeman et al, 2019Stegeman et al, , 2013. By rearing these animals at hot and cold sublethal temperatures near their fertile limits, as well as under benign thermal conditions, we characterize genotypic and environmentally induced differential gene expression across the genome.…”

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confidence: 81%

“…Here, we quantified transcriptome expression for C. briggsae nematodes from populations with distinct genetic backgrounds adapted to temperature differences associated with their origins in tropical vs. temperate latitudes (Poullet, Vielle, Gimond, Ferrari, & Braendle, ; Prasad, Croydon‐Sugarman, Murray, & Cutter, ; Stegeman, Bueno de Mesquita, Ryu, & Cutter, ). Global collections and population genomic analyses of C. briggsae wild isolates from tropical and temperate regions show that they form distinct phylogeographic groups (Cutter, Félix, Barriere, & Charlesworth, ; Felix et al, ; Jovelin & Cutter, ; Thomas, Wang, & Jovelin, ).…”

Section: Introductionmentioning

confidence: 99%

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Genome structure predicts modular transcriptome responses to genetic and environmental conditions

et al. 2019

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Understanding the plasticity, robustness and modularity of transcriptome expression to genetic and environmental conditions is crucial to deciphering how organisms adapt in nature. To test how genome architecture influences transcriptome profiles, we quantified expression responses for distinct temperature‐adapted genotypes of the nematode Caenorhabditis briggsae when exposed to chronic temperature stresses throughout development. We found that 56% of the 8,795 differentially expressed genes show genotype‐specific changes in expression in response to temperature (genotype‐by‐environment interactions, GxE). Most genotype‐specific responses occur under heat stress, indicating that cold vs. heat stress responses involve distinct genomic architectures. The 22 co‐expression modules that we identified differ in their enrichment of genes with genetic vs. environmental vs. interaction effects, as well as their genomic spatial distributions, functional attributes and rates of molecular evolution at the sequence level. Genes in modules enriched for simple effects of either genotype or temperature alone tend to evolve especially rapidly, consistent with disproportionate influence of adaptation or weaker constraint on these subsets of loci. Chromosome‐scale heterogeneity in nucleotide polymorphism, however, rather than the scale of individual genes predominates as the source of genetic differences among expression profiles, and natural selection regimes are largely decoupled between coding sequences and noncoding flanking sequences that contain cis‐regulatory elements. These results illustrate how the form of transcriptome modularity and genome structure contribute to predictable profiles of evolutionary change.

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confidence: 81%

Section: Introductionmentioning

confidence: 99%

Genome structure predicts modular transcriptome responses to genetic and environmental conditions

et al. 2019

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“…In some cases, one sex is more strongly affected by environmental changes (e.g., Hutter and Ashburner 1987;Wade et al 1999). Temperature differences also appear to act as an important selective agent within C. briggsae (Prasad et al 2011;Stegeman et al 2013) and between C. briggsae and C. nigoni (Woodruff et al 2010). We therefore examined the effect of temperature on total offspring production and sex ratio of both pure C. nigoni crosses and C. nigoni hybridized with C. briggsae males (virtually no F1 hybrid males are produced in the reciprocal hybrid cross, precluding evaluation of their temperature sensitivity).…”

Section: Haldane's Rule Is Temperature Sensitivementioning

confidence: 99%

Gametic selection, developmental trajectories, and extrinsic heterogeneity in Haldane's rule

2015

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Deciphering the genetic and developmental causes of the disproportionate rarity, inviability, and sterility of hybrid males, Haldane's rule, is important for understanding the evolution of reproductive isolation between species. Moreover, extrinsic and prezygotic factors can contribute to the magnitude of intrinsic isolation experienced between species with partial reproductive compatibility. Here, we use the nematodes Caenorhabditis briggsae and C. nigoni to quantify the sensitivity of hybrid male viability to extrinsic temperature and developmental timing, and test for a role of mito-nuclear incompatibility as a genetic cause. We demonstrate that hybrid male inviability manifests almost entirely as embryonic, not larval, arrest and is maximal at the lowest rearing temperatures, indicating an intrinsic-by-extrinsic interaction to hybrid inviability. Crosses using mitochondrial substitution strains that have reciprocally introgressed mitochondrial and nuclear genomes show that mito-nuclear incompatibility is not a dominant contributor to postzygotic isolation and does not drive Haldane's rule in this system. Crosses also reveal that competitive superiority of X-bearing sperm provides a novel means by which postmating prezygotic factors exacerbate the rarity of hybrid males. These findings highlight the important roles of gametic, developmental, and extrinsic factors in modulating the manifestation of Haldane's rule.

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“…Indeed, this species is now an active target of research into the molecular basis of trait variation and adaptation (Baird et al 2005;Prasad et al 2011;Ross et al 2011;Stegeman et al 2013), the evolution of development (Delattre and Félix 2001;Hill et al 2006;Guo et al 2009;Marri and Gupta 2009), and speciation (Woodruff et al 2010;Baird and Stonesifer 2012;Kozlowska et al 2012;Yan et al 2012). Yet, the limited genomic scope of understanding for its natural variation constrains our ability to fully exploit it.…”

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Full-genome evolutionary histories of selfing, splitting, and selection in Caenorhabditis

et al. 2015

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The nematode Caenorhabditis briggsae is a model for comparative developmental evolution with C. elegans. Worldwide collections of C. briggsae have implicated an intriguing history of divergence among genetic groups separated by latitude, or by restricted geography, that is being exploited to dissect the genetic basis to adaptive evolution and reproductive incompatibility; yet, the genomic scope and timing of population divergence is unclear. We performed high-coverage whole-genome sequencing of 37 wild isolates of the nematode C. briggsae and applied a pairwise sequentially Markovian coalescent (PSMC) model to 703 combinations of genomic haplotypes to draw inferences about population history, the genomic scope of natural selection, and to compare with 40 wild isolates of C. elegans. We estimate that a diaspora of at least six distinct C. briggsae lineages separated from one another approximately 200,000 generations ago, including the “Temperate” and “Tropical” phylogeographic groups that dominate most samples worldwide. Moreover, an ancient population split in its history approximately 2 million generations ago, coupled with only rare gene flow among lineage groups, validates this system as a model for incipient speciation. Low versus high recombination regions of the genome give distinct signatures of population size change through time, indicative of widespread effects of selection on highly linked portions of the genome owing to extreme inbreeding by self-fertilization. Analysis of functional mutations indicates that genomic context, owing to selection that acts on long linkage blocks, is a more important driver of population variation than are the functional attributes of the individually encoded genes.

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Temperature-dependent behaviours are genetically variable in the nematode Caenorhabditis briggsae

Cited by 18 publications

References 45 publications

Genome structure predicts modular transcriptome responses to genetic and environmental conditions

Genome structure predicts modular transcriptome responses to genetic and environmental conditions

Gametic selection, developmental trajectories, and extrinsic heterogeneity in Haldane's rule

Full-genome evolutionary histories of selfing, splitting, and selection in Caenorhabditis

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