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1. XOL-1 regulates developmental timing by modulating the H3K9 landscape in C. elegans early embryos

   https://doi.org/10.1371/journal.pgen.1011238  

   Jash, Eshna; Azhar, Anati Alyaa; Mendoza, Hector; Tan, Zoey M; Escher, Halle Nicole; Kaufman, Dalia S; Csankovszki, Györgyi (August 2024, PLOS Genetics)

   Garsin, Danielle A (Ed.)

   Sex determination in the nematodeC.elegansis controlled by the master regulator XOL-1 during embryogenesis. Expression ofxol-1is dependent on the ratio of X chromosomes and autosomes, which differs between XX hermaphrodites and XO males. In males,xol-1is highly expressed and in hermaphrodites,xol-1is expressed at very low levels. XOL-1 activity is known to be critical for the proper development ofC.elegansmales, but its low expression was considered to be of minimal importance in the development of hermaphrodite embryos. Our study reveals that XOL-1 plays an important role as a regulator of developmental timing during hermaphrodite embryogenesis. Using a combination of imaging and bioinformatics techniques, we found that hermaphrodite embryos have an accelerated rate of cell division, as well as a more developmentally advanced transcriptional program whenxol-1is lost. Further analyses reveal that XOL-1 is responsible for regulating the timing of initiation of dosage compensation on the X chromosomes, and the appropriate expression of sex-biased transcriptional programs in hermaphrodites. We found thatxol-1mutant embryos overexpress the H3K9 methyltransferase MET-2 and have an altered H3K9me landscape. Some of these effects of the loss ofxol-1gene were reversed by the loss ofmet-2. These findings demonstrate that XOL-1 plays an important role as a developmental regulator in embryos of both sexes, and that MET-2 acts as a downstream effector of XOL-1 activity in hermaphrodites. 

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2. Induction and inhibition of Drosophila X chromosome gene expression are both impeded by the dosage compensation complex

   https://doi.org/10.1093/g3journal/jkac165  

   Meisel, Richard P.; Asgari, Danial; Schlamp, Florencia; Unckless, Robert L.; Betran, ed., E. (July 2022, G3 Genes|Genomes|Genetics)

   Abstract Sex chromosomes frequently differ from the autosomes in the frequencies of genes with sexually dimorphic or tissue-specific expression. Multiple hypotheses have been put forth to explain the unique gene content of the X chromosome, including selection against male-beneficial X-linked alleles, expression limits imposed by the haploid dosage of the X in males, and interference by the dosage compensation complex on expression in males. Here, we investigate these hypotheses by examining differential gene expression in Drosophila melanogaster following several treatments that have widespread transcriptomic effects: bacterial infection, viral infection, and abiotic stress. We found that genes that are induced (upregulated) by these biotic and abiotic treatments are frequently under-represented on the X chromosome, but so are those that are repressed (downregulated) following treatment. We further show that whether a gene is bound by the dosage compensation complex in males can largely explain the paucity of both up- and downregulated genes on the X chromosome. Specifically, genes that are bound by the dosage compensation complex, or close to a dosage compensation complex high-affinity site, are unlikely to be up- or downregulated after treatment. This relationship, however, could partially be explained by a correlation between differential expression and breadth of expression across tissues. Nonetheless, our results suggest that dosage compensation complex binding, or the associated chromatin modifications, inhibit both up- and downregulation of X chromosome gene expression within specific contexts, including tissue-specific expression. We propose multiple possible mechanisms of action for the effect, including a role of Males absent on the first, a component of the dosage compensation complex, as a dampener of gene expression variance in both males and females. This effect could explain why the Drosophila X chromosome is depauperate in genes with tissue-specific or induced expression, while the mammalian X has an excess of genes with tissue-specific expression. 

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3. Transposon wave remodeled the epigenomic landscape in the rapid evolution of X-Chromosome dosage compensation

   https://doi.org/10.1101/gr.278127.123  

   Metzger, David C.H.; Porter, Imogen; Mobley, Brendan; Sandkam, Benjamin A.; Fong, Lydia J.M.; Anderson, Andrew P.; Mank, Judith E. (November 2023, Genome Research)

   Sex chromosome dosage compensation is a model to understand the coordinated evolution of transcription; however, the advanced age of the sex chromosomes in model systems makes it difficult to study how the complex regulatory mechanisms underlying chromosome-wide dosage compensation can evolve. The sex chromosomes ofPoecilia pictahave undergone recent and rapid divergence, resulting in widespread gene loss on the male Y, coupled with complete X Chromosome dosage compensation, the first case reported in a fish. The recent de novo origin of dosage compensation presents a unique opportunity to understand the genetic and evolutionary basis of coordinated chromosomal gene regulation. By combining a new chromosome-level assembly ofP. pictawith whole-genome bisulfite sequencing and RNA-seq data, we determine that the YY1 transcription factor (YY1) DNA binding motif is associated with male-specific hypomethylated regions on the X, but not the autosomes. These YY1 motifs are the result of a recent and rapid repetitive element expansion on theP. pictaX Chromosome, which is absent in closely related species that lack dosage compensation. Taken together, our results present compelling support that a disruptive wave of repetitive element insertions carrying YY1 motifs resulted in the remodeling of the X Chromosome epigenomic landscape and the rapid de novo origin of a dosage compensation system. 

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4. Single cell RNA-sequencing reveals no evidence for meiotic sex chromosome inactivation in the threespine stickleback fish

   https://doi.org/10.1371/journal.pgen.1011875  

   Shaw, Daniel E; Ross, Wynter D; Lambert, Alexis V; White, Michael A (September 2025, PLOS Genetics)

   Meiklejohn, Colin (Ed.)

   Sex chromosomes often evolve unique patterns of gene expression during spermatogenesis. In many species, sex-linked genes are downregulated during meiosis in response to asynapsis of the heterogametic sex chromosome pair (meiotic sex chromosome inactivation; MSCI). This process has evolved convergently across many taxa with independently derived sex chromosomes. Our understanding how quickly MSCI can evolve and whether it is connected to the degree of sequence degeneration remains limited. Teleost fish are a noteworthy group to investigate MSCI because sex chromosomes have evolved repeatedly across species, often over short evolutionary timescales. Here, we investigate whether MSCI occurs in the threespine stickleback fish (Gasterosteus aculeatus), which have an X and Y chromosome that evolved less than 26 million years ago. Using single-cell RNA-seq, we found that the X and Y chromosomes do not have a signature of MSCI, maintaining gene expression across meiosis. Using immunofluorescence, we also show the threespine stickleback do not form a condensed sex body around the X and Y, a feature of MSCI in many species. We did not see patterns of gene content evolution documented in other species with MSCI. Y-linked ampliconic gene families were expressed across multiple stages of spermatogenesis, rather than being restricted to post-meiotic stages, like in mammals. Our work shows MSCI does not occur in the threespine stickleback fish and has not shaped the evolution of the Y chromosome. In addition, the absence of MSCI in the threespine stickleback suggests this process may not be a conserved feature of teleost fish, despite overall sequence degeneration and structural evolution of the Y chromosome, and argues for additional investigation in other species. We also observed testis-dependent differences in coding and expression evolution for X-linked genes, revealing evidence of testis specific faster-X effect and gene-by-gene dosage compensation. 

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5. Conditional knockdown of transformer in sheep blow fly suggests a role in repression of dosage compensation and potential for population suppression

   https://doi.org/10.1371/journal.pgen.1009792  

   Williamson, Megan E.; Yan, Ying; Scott, Maxwell J. (October 2021, PLOS Genetics)

   Palli, Subba Reddy (Ed.)

   The transformer ( tra ) gene is essential for female development in many insect species, including the Australian sheep blow fly, Lucilia cuprina . Sex-specific tra RNA splicing is controlled by Sex lethal ( Sxl ) in Drosophila melanogaster but is auto-regulated in L . cuprina . Sxl also represses X chromosome dosage compensation in female D . melanogaster . We have developed conditional Lctra RNAi knockdown strains using the tet-off system. Four strains did not produce females on diet without tetracycline and could potentially be used for genetic control of L . cuprina . In one strain, which showed both maternal and zygotic tTA expression, most XX transformed males died at the pupal stage. RNAseq and qRT-PCR analyses of mid-stage pupae showed increased expression of X-linked genes in XX individuals. These results suggest that Lctra promotes somatic sexual differentiation and inhibits X chromosome dosage compensation in female L . cuprina . However, XX flies homozygous for a loss-of-function Lctra knockin mutation were fully transformed and showed high pupal eclosion. Two of five X-linked genes examined showed a significant increase in mRNA levels in XX males. The stronger phenotype in the RNAi knockdown strain could indicate that maternal Lctra expression may be essential for initiation of dosage compensation suppression in female embryos. 

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