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Deciphering the Role of the SREBF1 Gene in the Transcriptional Regulation of Porcine Adipogenesis Using CRISPR/Cas9 Editing
Sterol regulatory element-binding protein 1 (SREBP1) is an important transcription factor that controls lipid metabolism and adipogenesis. Two isoforms, SREBP1a and SREBP1c, are generated by alternative splicing of the first exon of the SREBF1 gene. The porcine SREBF1 gene has mainly been studied for its role in lipid metabolism in adipose tissues, but little is known about its involvement, and the role of its two isoforms, in adipogenesis. The aim of the present study was to introduce a deletion in the 5′-regulatory region of the SREBF1c gene, considered crucial for adipogenesis, using the Clustered Regularly Interspaced Short Palindromic Repeats/CRISPR-associated protein 9 (CRISPR/Cas9) method. This approach allows for the evaluation of how inhibiting SREBF1c transcription affects the expression of other genes essential for adipocyte differentiation, particularly PPARG, CEBPA, CEBPB, CEBPD, GATA2, and FABP4. It was observed that disrupting the SREBF1c isoform had no effect on the GATA2 gene but did result in a decrease in the expression of the CEBPA and CEBPD genes, an increase in the expression of CEBPB, and an inhibition in the expression of the PPARG and FABP4 genes. These changes in gene expression blocked adipogenesis, as could be seen by the failure of lipid droplets to accumulate. Our results provide evidence highlighting the pivotal role of the SREBP1c isoform in the regulation of porcine adipogenesis.
Elevated serum concentration of anti‐Mullerian hormone and its association with SNP variants in the AMH gene in a tortoiseshell tomcat with a disorder of sex development (38,XX; SRY-negative)
AbstractTesticular disorders of sex development (DSD) in cats with XX sex chromosomes and the absence of the SRY gene are rare congenital abnormalities. A Maine Coon tomcat with a normal penis, gonads in the scrotum, low serum testosterone concentration, and an elevated level of anti‐Müllerian hormone (AMH) was subjected to genetic analyses due to an unusual tortoiseshell coat color for males. Primary studies revealed the presence of XX sex chromosomes, the lack of SRY and the presence of two copies of the candidate SOX9. The DSD tomcat and its parents were analyzed using whole genome sequencing. Candidate SNPs in AMH, ORC1, DOCK8, PRKAR1A, and TMEM186 genes, as well as a known intronic 5‐kb deletion in X‐linked ARHGAP36 gene, which is responsible for orange coat, were identified. Potentially pathogenic homozygous genotypes were observed in all candidate genes; however, only in AMH and ORC1 were these genotypes rare in a control cohort. Further studies were focused on two SNPs located in the 5′‐and 3′‐untranslated regions (UTRs) of AMH. It has been experimentally demonstrated that only a short AMH transcript is present in feline testes. In silico analysis revealed that the SNP located in the 3′UTR of AMH occurs within a sequence that partially matches the canonical binding site for human miR‐5571‐5p. This microRNA is expressed in mammalian testes, which we confirmed in feline testicular tissue. We concluded that SNP in the 3′UTR of AMH is associated with elevated expression of the encoded hormone; however, it is not the cause of the testicular DSD phenotype in the studied Maine Coon tomcat.
Lack of causative mutation in the AMH and AMHR2 genes in a cat (38,XY) with persistent Mullerian duct syndrome (PMDS)
AbstractA 1‐year‐old European shorthair male cat with a normally developed penis was subjected to genetic, endocrinological and histological studies due to unilateral cryptorchidism. The blood testosterone level was typical for males, while the level of anti‐Mullerian hormone (AMH) was very low. Surgical removal of internal reproductive organs was followed by a histological study, which revealed inactive testicles with neoplastic changes and derivatives of Mullerian ducts. Cytogenetic analysis showed a normal XY sex chromosome complement and molecular analysis confirmed the presence of Y‐linked genes (SRY and ZFY). Although the level of AMH was low, two normal copies of the AMH gene were found using droplet digital PCR (ddPCR). Analysis of the coding sequences of two candidate genes (AMH and AMHR2) for persistent Mullerian duct syndrome (PMDS) in the affected cat and in control male cats (n = 24) was performed using the Sanger sequencing method. In the affected cat, homozygosity was found for three novel missense variants in Exon 1 (one SNP) and Exon 5 (two SNPs) of AMH, but the same homozygous genotypes were also observed in one and two control cats, respectively, whose sex development was not examined. Three known synonymous variants with homozygous status were found in AMHR2. We conclude that the DNA variants identified in AMH and AMHR2 are not responsible for PMDS in the affected cat.