Recapitulating Evolutionary Divergence in a Single Cis-Regulatory Element Is Sufficient to Cause Expression Changes of the Lens Gene Tdrd7

Genomic signatures associated with recurrent scale loss in cyprinid fish

Scale morphology represents a fundamental feature of fish and a key evolutionary trait underlying fish diversification. Despite frequent and recurrent scale loss throughout fish diversification, comprehensive genome-wide analyses of the genomic signatures associated with scale loss in divergent fish lineages remain scarce. In the current study, we investigated genome-wide signatures, specifically convergent protein-coding gene loss, amino acid substitutions, and cis-regulatory sequence changes, associated with recurrent scale loss in two divergent Cypriniformes lineages based on large-scale genomic, transcriptomic, and epigenetic data. Results demonstrated convergent changes in many genes related to scale formation in divergent scaleless fish lineages, including loss of P/Q-rich scpp genes (e.g. scpp6 and scpp7), accelerated evolution of non-coding elements adjacent to the fgf and fgfr genes, and convergent amino acid changes in genes (e.g. snap29) under relaxed selection. Collectively, these findings highlight the existence of a shared genetic architecture underlying recurrent scale loss in divergent fish lineages, suggesting that evolutionary outcomes may be genetically repeatable and predictable in the convergence of scale loss in fish.

Functional evidence supports the potential role of Tbx4-HLEA in the hindlimb degeneration of cetaceans

The evolution of limb morphology plays an important role in animal adaptation to different ecological niches. To fully adapt to aquatic life, cetaceans underwent hindlimb degeneration and forelimb transformed into flipper; however, the molecular mechanisms underlying the limb changes in cetaceans remain unclear. We previous study had shown that the Tbx4 hindlimb enhancer A (Tbx4-HLEA) in cetaceans exhibited specific deletions and nucleotide substitutions, with significantly reduced regulatory activity. To further investigate whether cetacean HLEA has a potential impact on hindlimb development in vivo, a knock-in mouse model was generated by knocking in the homologous cetacean HLEA in the present study. Phenotypic analysis showed a significant reduction in hindlimb bud development in homozygous knock-in mice at embryonic day (E)10.5; however, the phenotypic difference was rescued after E11.5. Transcriptomic and epigenetic analyses indicated that the cetacean HLEA acts as an enhancer in the mouse embryos and significantly reduces the transcriptional expression levels of Tbx4 at E10.5, supporting that downregulation of cetaceans HLEA regulatory activity reduces the expression of Tbx4. Additionally, both the number of activated non-coding elements and chromatin accessibility near Tbx4 were increased in homozygous knock-in mice at E11.5. The functional redundancy of enhancers compensated for the functional defect of cetacean HLEA, rescuing the expression level of Tbx4, and may account for the phenotype restoration after E11.5. In conclusion, our study suggested that the evolution of cetacean HLEA may be an important link with relevant molecular mechanism for the hindlimb degeneration.

Unearthing the secrets of Australia's most enigmatic and cryptic mammal, the marsupial mole

The marsupial moles are arguably Australia's most enigmatic marsupials. Almost indistinguishable from placental (eutherian) moles, they provide a striking example of convergent evolution. Exploring the genome of the southern marsupial mole, we provide insights into its unusual biology. We show definitively by retrophylogenomic analysis that marsupial moles are most closely related to bandicoots and bilbies (order Peramelemorphia). We find evidence of a marked decline in marsupial mole effective population size, most likely preceding the arrival of humans in regions near its range, and potentially corresponding to periods of climatic change. Our analysis of loss of eye function-an adaptation to subterranean life-reveals a structured order of loss of gene function associated first with the lens, then cone, and finally rod cells. Last, we identify genetic changes suggestive of adaptation to an oxygen-poor environment and of its evolution of partially descended testes.

Target silencing of porcine SPAG6 and PPP1CC by shRNA attenuated sperm motility

The quality of sperm significantly influences the reproductive efficiency of pig herds. High-quality sperm is necessary for efficient fertilization and to maximize the litter numbers in commercial pig farming. However, the understanding of genes regulating porcine sperm motility and viability is limited. In this study, we validated porcine sperm/Sertoli-specific promoters through the luciferase reporter system and identified vital genes for sperm quality via loss-of-function means. Further, the shRNAs driven by the ACE and SP-10 promoters were used to knockdown the SPAG6 and PPP1CC genes which were provisionally important for sperm quality. We assessed the effects of SPAG6 and PPP1CC knockdown on sperm motility by using the sperm quality analyzer and flow cytometry. The results showed that the ACE promoter is active in both porcine Sertoli cells and sperms, whereas the SP-10 promoter is operating exclusively in sperm cells. Targeted interference with SPAG6 and PPP1CC expression in sperm cells decreases the motility and increases apoptosis rates in porcine sperms. These findings not only offer new genetic tools for targeting male germ cells but also highlight the crucial roles of SPAG6 and PPP1CC in porcine sperm function.

Vision-related convergent gene losses reveal SERPINE3's unknown role in the eye

Despite decades of research, knowledge about the genes that are important for development and function of the mammalian eye and are involved in human eye disorders remains incomplete. During mammalian evolution, mammals that naturally exhibit poor vision or regressive eye phenotypes have independently lost many eye-related genes. This provides an opportunity to predict novel eye-related genes based on specific evolutionary gene loss signatures. Building on these observations, we performed a genome-wide screen across 49 mammals for functionally uncharacterized genes that are preferentially lost in species exhibiting lower visual acuity values. The screen uncovered several genes, including SERPINE3, a putative serine proteinase inhibitor. A detailed investigation of 381 additional mammals revealed that SERPINE3 is independently lost in 18 lineages that typically do not primarily rely on vision, predicting a vision-related function for this gene. To test this, we show that SERPINE3 has the highest expression in eyes of zebrafish and mouse. In the zebrafish retina, serpine3 is expressed in Müller glia cells, a cell type essential for survival and maintenance of the retina. A CRISPR-mediated knockout of serpine3 in zebrafish resulted in alterations in eye shape and defects in retinal layering. Furthermore, two human polymorphisms that are in linkage with SERPINE3 are associated with eye-related traits. Together, these results suggest that SERPINE3 has a role in vertebrate eyes. More generally, by integrating comparative genomics with experiments in model organisms, we show that screens for specific phenotype-associated gene signatures can predict functions of uncharacterized genes.