Your search keyword '"Jiang, Keren"' showing total 5 results

1. Global investigation of estrogen-responsive genes regulating lipid metabolism in the liver of laying hens

Author

Ren, Junxiao, Tian, Weihua, Jiang, Keren, Wang, Zhang, Wang, Dandan, Li, Zhuanjian, Yan, Fengbin, Wang, Yanbin, Tian, Yadong, Ou, Kepeng, Wang, Hongjun, Kang, Xiangtao, Li, Hong, and Liu, Xiaojun

Published

2021

2. Evolution, Expression Profile, Regulatory Mechanism, and Functional Verification of EBP-Like Gene in Cholesterol Biosynthetic Process in Chickens (Gallus Gallus).

Author

Jiang, Keren, Ma, Zheng, Wang, Zhang, Li, Hong, Wang, Yanbin, Tian, Yadong, Li, Donghua, and Liu, Xiaojun

Subjects

CHICKENS, JAPANESE quail, EGG quality, GENES, BIOSYNTHESIS, CHOLESTEROL

Abstract

The emopamil binding protein (EBP) is an important enzyme participating in the final steps of cholesterol biosynthesis in mammals. A predictive gene EBP-like , which encodes the protein with a high identity to human EBP, was found in chicken genome. No regulatory mechanisms and biological functions of EBP-like have been characterized in chickens. In the present study, the coding sequence of EBP-like was cloned, the phylogenetic trees of EBP/EBP-like were constructed and the genomic synteny of EBP-like was analyzed. The regulatory mechanism of EBP-like were explored with in vivo and in vitro experiments. The biological functions of EBP-like in liver cholesterol biosynthetic were examined by using gain- or loss-of-function strategies. The results showed that chicken EBP-like gene was originated from a common ancestral with Japanese quail EBP gene, and was relatively conservative with EBP gene among different species. The EBP-like gene was highly expressed in liver, its expression level was significantly increased in peak-laying stage, and was upregulated by estrogen. Inhibition of the EBP-like mRNA expression could restrain the expressions of EBP-like downstream genes (SC5D , DHCR24 , and DHCR7) in the cholesterol synthetic pathway, therefore downregulate the liver intracellular T-CHO level. In conclusion, as substitute of EBP gene in chickens, EBP-like plays a vital role in the process of chicken liver cholesterol synthesis. This research provides a basis for revealing the molecular regulatory mechanism of cholesterol synthesis in birds, contributes insights into the improvement of the growth and development, laying performance and egg quality in poultry. [ABSTRACT FROM AUTHOR]

Published

2021

3. MicroRNA-101-2-5p targets the ApoB gene in the liver of chicken ( Gallus Gallus).

Author

Ma, Zheng, Li, Hong, Zheng, Hang, Jiang, Keren, Jia, Lijuan, Yan, Fengbin, Tian, Yadong, Kang, Xiangtao, Wang, Yanbin, Liu, Xiaojun, and Ryan, A.K.

Subjects

ANTISENSE RNA, COOKING with liver, BILIARY tract, MICRORNA, JUNGLEFOWL

Abstract

Copyright of Genome is the property of Canadian Science Publishing and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2017

4. Hepatic ELOVL6 mRNA is regulated by the gga-miR-22-3p in egg-laying hen.

Author

Ma, Zheng, Li, Hong, Zheng, Hang, Jiang, Keren, Yan, Fengbin, Tian, Yadong, Kang, Xiangtao, Wang, Yanbin, and Liu, Xiaojun

Subjects

*MESSENGER RNA, *ELONGATION factors (Biochemistry), *FATTY acids, *LIPID synthesis, *GENE expression

Abstract

The elongation of very long chain fatty acids protein 6 (ELOVL6) encodes a fatty acid elongase that is responsible for the final step in endogenous saturated fatty acid synthesis and involves in de novo lipogenesis. Though the regulatory mechanism of ELOVL6 expression has been studied extensively, little is known about the role of miRNA in regulating ELOVL6 gene expression in chicken until now. To investigate the regulatory mechanism of miRNA on the expression of ELOVL6 gene, bioinformatics analysis was employed to predict the potential miRNAs that binding with the 3′untranslated region (3′UTR) of ELOVL6. The putative miRNA was further screened by comparative analysis with previous miRNA-seq results. Gga-miR-22-3p, which could bind with the 3′UTR of ELOVL6 and showed negative expression correlation with ELOVL6 gene in chicken liver, was obtained. Tissue expression profiles showed that gga-miR-22-3p and ELOVL6 are extensively expressed in many tissues, and ELOVL6 with high expression level in kidney and liver tissues, and gga-miR-22-3p with high expression in lung and heart. Dual-luciferase reporter assays results indicated that the expression of luciferase reporter gene linked with part sequence of the 3′UTR of chicken ELOVL6 gene was down-regulated by the overexpression of gga-miR-22-3p in the DF1 cells, and the down-regulation behavior was abolished when the gga-miR-22-3p binding site in 3′UTR of ELOVL6 was mutated ( P > 0.05). Furthermore, the ELOVL6 expression in chicken hepatocytes was down-regulated when miR-22-3p was over-expressed. Therefore, we concluded that miR-22-3p might involve in controlling the hepatic lipid composition through affecting the expression of ELOVL6 gene, and could serve as a regulator of lipid metabolism in the liver of egg-laying hen. [ABSTRACT FROM AUTHOR]

Published

2017

5. Evolution, expression profile, and regulatory characteristics of ACSL gene family in chicken (Gallus gallus).

Author

Tian, Weihua, Wang, Dandan, Wang, Zhang, Jiang, Keren, Li, Zhuanjian, Tian, Yadong, Kang, Xiangtao, Liu, Xiaojun, and Li, Hong

Subjects

*CHICKENS, *LIPID synthesis, *GENE expression profiling, *ACYLTRANSFERASES, *LIGASES, *GENE families

Abstract

• Chicken ACSL2 was evolutionally lost. • Chicken ACSLs were evolutionally clustered into ACSL1/5/6 and ACSL3/4. • Decreased ACSL1 and increased ACSL5 expression levels were detected in the liver of peak- versus pre-laying hens. • Estrogen could transcriptionally inhibit ACSL1/3/4 and activate ACSL6. Long chain acyl-CoA synthetases (ACSLs), which drive the conversion of long chain fatty acid into acyl-CoA, an ingredient of lipid synthesis, have been well-acknowledged to exert an indispensable role in many metabolic processes in mammals, especially lipid metabolism. However, in chicken, the evolutionary characteristics, expression profiles and regulatory mechanisms of ACSL gene family are rarely understood. Here, we analyzed the genomic synteny, gene structure, evolutionary event and functional domains of the ACSL gene family members using bioinformatics methods. The spatiotemporal expression profiles of ACSL gene family, and their regulatory mechanism were investigated via bioinformatics analysis incorporated with in vivo and in vitro estrogen-treated experiments. Our results indicated that ACSL2 gene was indeed evolutionarily lost in the genome of chicken. Chicken ACSLs shared an AMP-binding functional domain, as well as highly conversed ATP/AMP and FACS signature motifs, and were clustered into two clades, ACSL1/5/6 and ACSL3/4, based on high sequence similarity, similar gene features and conversed motifs. Chicken ACSLs showed differential tissue expression distributions, wherein the significantly decreased expression level of ACSL1 and the significantly increased expression level of ACSL5 were found, respectively, the expression levels of the other ACSL members remained unchanged in the liver of peak-laying hens versus pre-laying hens. Moreover, the transcription activity of ACSL1 , ACSL3 and ACSL4 was silenced and ACSL6 was activated by estrogen, but no response to ACSL5. In conclusion, though having highly conversed functional domains, chicken ACSL gene family is organized into two separate groups, ACSL1/5/6 and ACSL3/4 , and exhibits varying expression profiles and estrogen effects. These results not only pave the way for better understanding the specific functions of ACSL genes in avian lipid metabolism, but also provide a valuable evidence for gene family characteristics. [ABSTRACT FROM AUTHOR]

Published

2021