Project description:The pachynema progression, a crucial meiotic process, contributes to the completion of prophase I. Nevertheless, the regulation of this significant meiotic process remains poorly understood. In this study, we identified a novel testis-specific protein HSF5, which regulates pachynema progression during male meiosis in a chromatin-binding manner. Deficiency of HSF5 results in meiotic arrest and male infertility, characterized as unconventionally accumulated pachynema halting at the mid-to-late stage, with extensive spermatocyte apoptosis. Our scRNA-seq data confirmed consistent expressional alterations of certain driver genes(Sycp1, Msh4, Meiob, etc.) crucial for pachynema progression in Hsf5-/- individuals. Ulteriorly, HSF5 was revealed to primarily bind to promoter regions of such key divers by CUT&Tag analysis. Also, our results demonstrated that HSF5 biologically interacted with the chromatin-remodeling SWI/SNF complex, and it could function as a transcriptional factor for pachynema progression during meiosis. Therefore, our study underscored the importance of the chromatin-associated HSF5 for the differentiation of spermatocytes, improving the protein regulatory network of the pachynema progression.

Project description:To investigate the role of HSF5 protein in mouse reproduction, We collected WT or Hsf5+/- (control) and Hsf5-/- testes at postnatal day 16 (P16) for RNA sequencing.

Project description:Here, we report on a novel chicken comb phenotype, designated Antler-comb. Using a 600K Axiom® Genome-Wide Chicken Genotyping Array, we separately genotyped 12 and 24 female Hetian Wildtype-comb and Antler-comb chickens, respectively. Meanwhile, we sequenced the genomes of 10 Hetian Antler-comb and 10 Wildtype-comb chickens to interrogate the GWAS results and explore the potential genetic variants underlying this phenotype. After conducting a genome-wide association study (GWAS), a 36.5-kb candidate genomic region (chromosome 19:757,754-794,200) related to the Antler-comb phenotype was identified, which wholly and partially encompassed heat shock factor 5 (HSF5) and ring finger protein 43 (RNF43), respectively. HSF5 was ectopically expressed and RNF43 was up-regulated in Antler-comb chickens at embryo ages 7 and 9 (E7 and E9). We further genotyped the most significant single-nucleotide polymorphism (SNP) site, Chr19:794200, across 222 chickens of 16 breeds. We found that the major allele G in Antler-comb chickens remained highly significant across different breeds, and each Antler-comb chicken harbored an allele G. Whole-genome re-sequencing (WGS) involving 10 Hetian Antler-comb and 10 Wildtype-comb chickens reaffirmed the 36.5-kb candidate genomic region, and revealed a genomic duplication, which was 15.7 kb in length and pertained to the 5’-untranslated region and 5’-flanking region of HSF5 (Chr19:784,335-800,034), suggesting its possible role in inducing ectopic expression of HSF5 and altering expression of RNF43 during comb development (E7 and E9). The present study furthers our understanding of this novel chicken comb phenotype, and likely gives another example regarding interactions between genetic variation and phenotype.

Project description:A deletion in the CMAH gene in humans occurred approximately 3.5 million years ago. This resulted in the inactivation of the CMP-Neu5Ac hydroxylase enzyme, and hence, in the specific deficiency in N-glycolylneuraminic acid (Neu5Gc), a form of sialic acid, in all modern humans. Although there is evidence that this molecular milestone in the origin of humans may have led to the evolution of human-specific pathogens, how deficiency in Neu5Gc might alter progression of non-infectious human diseases remains unanswered. Here, we have investigated cardiac and skeletal muscle gene expression changes in mdx mice, a model of Duchenne muscular dystrophy (DMD), that do or do not carry the human-like inactivating mutation in the mouse Cmah gene. We have evidence that Neu5Gc-deficiency in humans might explain some of the discrepancies in the disease phenotype between mdx mice and DMD patients. The study had four groups of mice: 1) Wild type, 2) Cmah KO (mice carrying a human-like mutation in the Cmah gene and hence have human-like deficiency in Neu5Gc sialic acid), 3) mdx (mouse model for Duchenne Muscular Dystrophy), and 4) mdx mice deficient in Cmah. Gene expression was studied in heart and gastrocnemius muscle samples. Three replicates per group/tissue.

Project description:Circulating microRNA profile in humans with congenital GH deficiency

Project description:Expression profiling of Hsf5 WT and Hsf5 KO testes in mouse on postnatal day 12 and 16

Project description:Hsf5 is required for spermatogenesis in zebrafish

Project description:Dual T cell– and B cell–intrinsic deficiency in humans

Project description:A deletion in the CMAH gene in humans occurred approximately 3.5 million years ago. This resulted in the inactivation of the CMP-Neu5Ac hydroxylase enzyme, and hence, in the specific deficiency in N-glycolylneuraminic acid (Neu5Gc), a form of sialic acid, in all modern humans. Although there is evidence that this molecular milestone in the origin of humans may have led to the evolution of human-specific pathogens, how deficiency in Neu5Gc might alter progression of non-infectious human diseases remains unanswered. Here, we have investigated cardiac and skeletal muscle gene expression changes in mdx mice, a model of Duchenne muscular dystrophy (DMD), that do or do not carry the human-like inactivating mutation in the mouse Cmah gene. We have evidence that Neu5Gc-deficiency in humans might explain some of the discrepancies in the disease phenotype between mdx mice and DMD patients.

Project description:NGS analysis of HSF5 function in meiotic progression