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1. The Tiger Rattlesnake genome reveals a complex genotype underlying a simple venom phenotype

   https://doi.org/10.1073/pnas.2014634118  

   Margres, Mark J.; Rautsaw, Rhett M.; Strickland, Jason L.; Mason, Andrew J.; Schramer, Tristan D.; Hofmann, Erich P.; Stiers, Erin; Ellsworth, Schyler A.; Nystrom, Gunnar S.; Hogan, Michael P.; et al (January 2021, Proceedings of the National Academy of Sciences)

   Variation in gene regulation is ubiquitous, yet identifying the mechanisms producing such variation, especially for complex traits, is challenging. Snake venoms provide a model system for studying the phenotypic impacts of regulatory variation in complex traits because of their genetic tractability. Here, we sequence the genome of the Tiger Rattlesnake, which possesses the simplest and most toxic venom of any rattlesnake species, to determine whether the simple venom phenotype is the result of a simple genotype through gene loss or a complex genotype mediated through regulatory mechanisms. We generate the most contiguous snake-genome assembly to date and use this genome to show that gene loss, chromatin accessibility, and methylation levels all contribute to the production of the simplest, most toxic rattlesnake venom. We provide the most complete characterization of the venom gene-regulatory network to date and identify key mechanisms mediating phenotypic variation across a polygenic regulatory network. 

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2. The impact of species-wide gene expression variation on Caenorhabditis elegans complex traits

   https://doi.org/10.1038/s41467-022-31208-4  

   Zhang, Gaotian; Roberto, Nicole M.; Lee, Daehan; Hahnel, Steffen R.; Andersen, Erik C. (June 2022, Nature Communications)

   Abstract Phenotypic variation in organism-level traits has been studied inCaenorhabditis eleganswild strains, but the impacts of differences in gene expression and the underlying regulatory mechanisms are largely unknown. Here, we use natural variation in gene expression to connect genetic variants to differences in organismal-level traits, including drug and toxicant responses. We perform transcriptomic analyses on 207 genetically distinctC. eleganswild strains to study natural regulatory variation of gene expression. Using this massive dataset, we perform genome-wide association mappings to investigate the genetic basis underlying gene expression variation and reveal complex genetic architectures. We find a large collection of hotspots enriched for expression quantitative trait loci across the genome. We further use mediation analysis to understand how gene expression variation could underlie organism-level phenotypic variation for a variety of complex traits. These results reveal the natural diversity in gene expression and possible regulatory mechanisms in this keystone model organism, highlighting the promise of using gene expression variation to understand how phenotypic diversity is generated. 

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3. Evolutionary walks through flower colour space driven by gene expression in Petunia and allies (Petunieae)

   https://doi.org/10.1098/rspb.2023.0275  

   Wheeler, Lucas C.; Dunbar-Wallis, Amy; Schutz, Kyle; Smith, Stacey D. (July 2023, Proceedings of the Royal Society B: Biological Sciences)

   The structure and function of biochemical and developmental pathways determine the range of accessible phenotypes, which are the substrate for evolutionary change. Accordingly, we expect that observed phenotypic variation across species is strongly influenced by pathway structure, with different phenotypes arising due to changes in activity along pathway branches. Here, we use flower colour as a model to investigate how the structure of pigment pathways shapes the evolution of phenotypic diversity. We focus on the phenotypically diverse Petunieae clade in the nightshade family, which containsca180 species ofPetuniaand related genera, as a model to understand how flavonoid pathway gene expression maps onto pigment production. We use multivariate comparative methods to estimate co-expression relationships between pathway enzymes and transcriptional regulators, and then assess how expression of these genes relates to the major axes of variation in floral pigmentation. Our results indicate that coordinated shifts in gene expression predict transitions in both total anthocyanin levels and pigment type, which, in turn, incur trade-offs with the production of UV-absorbing flavonol compounds. These findings demonstrate that the intrinsic structure of the flavonoid pathway and its regulatory architecture underlies the accessibility of pigment phenotypes and shapes evolutionary outcomes for floral pigment production. 

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4. An atlas of gene expression variation across the Caenorhabditis elegans species

   https://doi.org/10.1101/2022.02.06.479320  

   Zhang, Gaotian; Roberto, Nicole M.; Lee, Daehan; Hahnel, Steffen R; Andersen, Erik C. (February 2022, bioRxiv)

   Phenotypic variation in diverse organism-level traits have been studied in Caenorhabditis elegans wild strains, but differences in gene expression and the underlying variation in regulatory mechanisms are largely unknown. Here, we use natural variation in gene expression to connect genetic variants to differences in organismal- level traits, including drug and toxicant responses. We performed transcriptomic analysis on 207 genetically distinct C. elegans wild strains to study natural regulatory variation of gene expression. Using this massive dataset, we performed genome-wide association mappings to investigate the genetic basis underlying gene expression variation and revealed complex genetic architectures. We found a large collection of hotspots enriched for expression quantitative trait loci across the genome. We further used mediation analysis to understand how gene expression variation could underlie organism-level phenotypic variation for a variety of complex traits. These results reveal the natural diversity in gene expression and possible regulatory mechanisms in this keystone model organism, highlighting the promise of gene expression variation in shaping phenotypic diversity. 

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5. Venom Gene Sequence Diversity and Expression Jointly Shape Diet Adaptation in Pitvipers

   https://doi.org/10.1093/molbev/msac082  

   Mason, Andrew J.; Holding, Matthew L.; Rautsaw, Rhett M.; Rokyta, Darin R.; Parkinson, Christopher L.; Gibbs, H. Lisle (April 2022, Molecular Biology and Evolution)

   Yoder, Anne (Ed.)

   Abstract Understanding the joint roles of protein sequence variation and differential expression during adaptive evolution is a fundamental, yet largely unrealized goal of evolutionary biology. Here, we use phylogenetic path analysis to analyze a comprehensive venom-gland transcriptome dataset spanning three genera of pitvipers to identify the functional genetic basis of a key adaptation (venom complexity) linked to diet breadth (DB). The analysis of gene-family-specific patterns reveals that, for genes encoding two of the most important venom proteins (snake venom metalloproteases and snake venom serine proteases), there are direct, positive relationships between sequence diversity (SD), expression diversity (ED), and increased DB. Further analysis of gene-family diversification for these proteins showed no constraint on how individual lineages achieved toxin gene SD in terms of the patterns of paralog diversification. In contrast, another major venom protein family (PLA2s) showed no relationship between venom molecular diversity and DB. Additional analyses suggest that other molecular mechanisms—such as higher absolute levels of expression—are responsible for diet adaptation involving these venom proteins. Broadly, our findings argue that functional diversity generated through sequence and expression variations jointly determine adaptation in the key components of pitviper venoms, which mediate complex molecular interactions between the snakes and their prey. 

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