RNA-Seq explores the functional role of the FGF10 gene in bovine adipocytes differentiation.

Objective: The present study was executed to explore the molecular mechanism of FGF10 gene in bovine adipogenesis. Methods: The bovine FGF10 gene was overexpressed through Ad-FGF10 or inhibited through siFGF10 and their NCs in bovine adipocytes, and the MOI, transfection efficiency, interference efficiency were evaluated through qRT-PCR, western blotting and fluorescence microscopy. The lipid droplets, TG content and the expression levels of adipogenic marker genes were measured during preadipocytes differentiation. The differentially expressed genes were explored through deep RNA sequencing. Results: The highest mRNA level was found in omasum, subcutaneous fat, and intramuscular fat. Moreover, the highest mRNA level was found in adipocytes at day 4 of differentiation. The results of red-oil o staining showed that overexpression (Ad-FGF10) of the FGF10 gene significantly (p<0.05) reduced the lipid droplets and TG content, and their down-regulation (siFGF10) increased the measurement of lipid droplets and TG in differentiated bovine adipocytes. Furthermore, the overexpression of the FGF10 gene down regulated the mRNA levels of adipogenic marker genes such as C/EBPa, FABP4, PPARy, LPL, and FAS, similarly, down-regulation of the FGF10 gene enriched the mRNA levels of C/EBPa, PPARy, FABP4, and LPL genes (P˂0.01). Additionally, the protein levels of PPARγ and FABP4 were reduced (p<0.05) in adipocytes infected with Ad-FGF10 gene and enriched in adipocytes transfected with siFGF10. Moreover, a total of 1774 DEGs (differentially expressed genes) including 157 up regulated and 1617 down regulated genes were explored in adipocytes infected with Ad-FGF10 or Ad-NC through deep RNA-sequencing. The top KEGG pathways regulated through DEGs were the PPAR signaling pathway, cell cycle, base excision repair, DNA replication, apoptosis, and regulation of lipolysis in adipocytes. Conclusion: Therefore, we can conclude that the FGF10 gene is a negative regulator of bovine adipogenesis and could be used as a candidate gene in marker-assisted selection.

Genetic variants of TORC1 gene promoter and their association with carcass quality and body measurement traits in Qinchuan beef cattle.

In the present study, sequencing of TORC1 prompter region explored three SNPs at loci g.80G>T, g.93A>T, and g.1253G>A. The SNP1 produced GG, GT and TT, SNP2 AA, AT and TT, and SNP3 produced GG, GA and AA genotypes. Allelic and genotypic frequencies analysis exhibited that SNP1 is within Hardy-Weinberg equilibrium (HWE). All three SNPs were found highly polymorphic as PIC value (0.25 < PIC < 0.50). At loci g.80G>T the cattle with genotype GG showed significantly (P <0.01) larger body length (BL), Wither height (WH), Hip height (HH), Rump length (RL), Hip width (HW), Chest depth (CD), and Chest circumference (CC). The genotype AA at g.93A>T showed significantly (P< 0.01 and 0.05) Larger body length (BL), Wither height (WH), Hip height, Rump length (RL), Hip width (HW), Chest depth (CD), and Chest circumference (CC). Interestingly, the carcass quality parameters such as Ultrasound loin area (ULA) and Intramuscular fat percentage (IF%) was highest in genotype GG at loci g.1253G>A. These findings conclude that genotype GG at loci g.80 G>T and AA at loci g.93A>T could be used as genetic markers for body measurement and genotype GG at loci g.1253G>A for carcass quality traits of TORC1 gene in Qinchuan beef cattle.

Transcriptional regulation of adipogenic marker genes for the improvement of intramuscular fat in Qinchuan beef cattle.

The intramuscular fat content plays a crucial role in meat quality traits. Increasing the degree of adipogenesis in beef cattle leads to an increase in the content of intramuscular fat. Adipogenesis a complex biochemical process which is under firm genetic control. Over the last three decades, the Qinchuan beef cattle have been extensively studied for the improvement of meat production and quality traits. In this study, we reviewed the literature regarding adipogenesis and intramuscular fat deposition. Then, we summarized the research conducted on the transcriptional regulation of key adipogenic marker genes, and also reviewed the roles of adipogenic marker genes in adipogenesis of Qinchuan beef cattle. This review will elaborate our understanding regarding transcriptional regulation which is a vital physiological process regulated by a cascade of transcription factors (TFs), key target marker genes, and regulatory proteins. This synergistic action of TFs and target genes ensures the accurate and diverse transmission of the genetic information for the accomplishment of central physiological processes. This information will provide an insight into the transcriptional regulation of the adipogenic marker genes and its role in bovine adipogenesis for the breed improvement programs especially for the trait of intramuscular fat deposition.

Function and characterization of the promoter region of perilipin 1 (PLIN1): Roles of E2F1, PLAG1, C/EBPß, and SMAD3 in bovine adipocytes.

Perilipin 1 (PLIN1) protein, also known as lipid droplet-associated protein, is encoded by the PLIN1 gene and is able to anchor itself to the membranes of lipid droplets. The phosphorylation of PLIN1 is critical for the mobilization of fat in adipose tissue and plays an important role in regulating lipolysis and lipid storage in adipocytes. However, research on the synthesis and lipid metabolism of lipid droplets by PLIN1 in bovine adipocytes is limited. In the present study, we found that bovine PLIN1 was highly expressed in subcutaneous adipose tissue. The highest level of PLIN1 mRNA expression in bovine adipocytes was observed on day 6 of differentiation. Moreover, the cytoplasmic subcellular localization of PLIN1 was observed in bovine preadipocytes. To elucidate the molecular mechanism of bovine PLIN1 transcriptional regulation, we cloned eight fragments containing the 5' regulatory region of the PLIN1 gene. The results showed that the -209/-17 bp region of the bovine PLIN1 gene was the core promoter region. Based on the transcriptional activities of the promoter vector fragments, the luciferase activity of the mutated fragment, the siRNA interference, and the results of the electrophoretic mobility shift assay (EMSA), we identified the binding sites of E2F transcription factor 1 (E2F1), pleiomorphic adenoma gene 1 (PLAG1), CCAAT enhancer binding protein beta (C/EBPß), and SMAD family member 3 (SMAD3) as the transcriptional activators or repressors of the core promoter region. Further experiments confirmed that the knockdown of the PLIN1 gene affected the ability of these transcription factors to regulate the lipid metabolism in bovine adipocytes. In conclusion, our results reveal a potential mechanism for the transcriptional regulation of PLIN1 in bovine adipocytes.

Bioinformatics analysis and transcriptional regulation of TORC1 gene through transcription factors NRF1 and Smad3 in bovine preadipocytes.

Intramuscular fat is the an important factor that defines meat quality; however, enhancing its deposition without increasing the other three adipose depots (subcutaneous, visceral, and intermuscular fat) is a challenge for animal science and the meat industry. The TORC1 is a key regulator of adipogenesis and its regulation in bovine intramuscular preadipocytes has not been studied. The TORC1 is a member of the gene family that codes for a binding proteins which regulate transcription of cAMP which, is a key regulator of adipogenesis. In the present study, expression and sub-cellular localization of the TORC1 gene was analyzed in bovine preadipocytes. Bioinformatics tools were applied to characterize TORC1. To investigate the molecular mechanism of bovine TORC1 gene regulation, we cloned a 1008 bp of the 5'UTR regulatory region into a luciferase reporter vector. Different fragments were amplified using 5'UTR unidirectional deletion of the TORC1 promoter. Site directed mutation, dual luciferase reporter assay, RNAi interference and DNA-protein interaction (EMSA) were used to validate the regulatory roles of Smad3 and NRF1 in the regulation of TORC1 gene in bovine preadipocytes. The core promoter region of the TORC1 gene was identified at a location -410 to -155 bp upstream of transcription start site. Different vectors were constructed through serial deletion of the 5'UTR flanking region and in combination with site directed mutations and transcription interference through siRNA or shRNA, two transcription factors of NRF1 and Smad3 were found to be repressors in the promoter of the TORC1 gene. These findings were further confirmed through Electrophoretic Mobility Shift Assay (EMSA) within nuclear extracts of bovine adipocytes. The core promoter region of the TORC1 gene, spanning from -410 to -155 bp upstream of the transcription start site was specified in this study and this information will provide opportunity for the improvement of intramuscular fat in cattle.

Function and Transcriptional Regulation of Bovine TORC2 Gene in Adipocytes: Roles of C/EBP, XBP1, INSM1 and ZNF263.

The TORC2 gene is a member of the transducer of the regulated cyclic adenosine monophosphate (cAMP) response element binding protein gene family, which plays a key role in metabolism and adipogenesis. In the present study, we confirmed the role of TORC2 in bovine preadipocyte proliferation through cell cycle staining flow cytometry, cell counting assay, 5-ethynyl-2'-deoxyuridine staining (EdU), and mRNA and protein expression analysis of proliferation-related marker genes. In addition, Oil red O staining analysis, immunofluorescence of adiponectin, mRNA and protein level expression of lipid related marker genes confirmed the role of TORC2 in the regulation of bovine adipocyte differentiation. Furthermore, the transcription start site and sub-cellular localization of the TORC2 gene was identified in bovine adipocytes. To investigate the underlying regulatory mechanism of the bovine TORC2, we cloned a 1990 bp of the 5' untranslated region (5'UTR) promoter region into a luciferase reporter vector and seven vector fragments were constructed through serial deletion of the 5'UTR flanking region. The core promoter region of the TORC2 gene was identified at location -314 to -69 bp upstream of the transcription start site. Based on the results of the transcriptional activities of the promoter vector fragments, luciferase activities of mutated fragments and siRNAs interference, four transcription factors (CCAAT/enhancer-binding protein C/BEP, X-box binding protein 1 XBP1, Insulinoma-associated 1 INSM1, and Zinc finger protein 263 ZNF263) were identified as the transcriptional regulators of TORC2 gene. These findings were further confirmed through Electrophoretic Mobility Shift Assay (EMSA) within nuclear extracts of bovine adipocytes. Furthermore, we also identified that C/EBP, XBP1, INSM1 and ZNF263 regulate TORC2 gene as activators in the promoter region. We can conclude that TORC2 gene is potentially a positive regulator of adipogenesis. These findings will not only provide an insight for the improvement of intramuscular fat in cattle, but will enhance our understanding regarding therapeutic intervention of metabolic syndrome and obesity in public health as well.

Halal slaughtering, welfare, and empathy in farm animals: a review.

Pre-slaughter and slaughter stressors are considered major concerns in animal welfare. Halal slaughtering method is considered one of the slaughtering stressors in livestock. This method seems to cause fear followed by stress in animals mainly due to inhuman handling. In this review, empathy and animal welfare are discussed in light of Islamic sharia and has further linked with animal's physiology and behavioral responses during slaughtering. Islam as a religion forbids slaughtering an animal in front of another animal as through optic, olfactory, and cochlear senses animals can perceive the stress state of conspecifics. This suggests and strengthens the hypothesis that animals being slaughtered in front of each other may produce stress in them. This argument further leads to a claim that animals can experience empathy of each other through olfaction of semiochemicals (stress pheromones) emitted from animals slaughtered in the stressful condition that can be detected by other animals in abattoirs. Hence, research is needed to find out these specific stress pheromones and legislation needs to be adopted in slaughterhouses to isolate the areas of butchery from slaughtering lines to ensure proper guidelines of Halal slaughtering in slaughterhouses.