Your search keyword '"Chen, Hou-Zao"' showing total 9 results

1. Therapeutic potential of alternative splicing in cardiovascular diseases

Author

Cao, Jun, Wei, Ziyu, Nie, Yu, and Chen, Hou-Zao

Published

2024

2. Lysine crotonylation of SERCA2a correlates to cardiac dysfunction and arrhythmia in Sirt1 cardiac-specific knockout mice

Author

Chen, Huan-Xin, Wang, Xiang-Chong, Hou, Hai-Tao, Wang, Jun, Yang, Qin, Chen, Yuan-Lu, Chen, Hou-Zao, and He, Guo-Wei

Published

2023

3. What we talk about when we talk about spinal cord aging.

Author

Ji, Xianhong, Zhang, Jiajia, Tang, Xiaoqiang, and Chen, Hou-Zao

Abstract

Spinal cord-associated disorders are common in the elderly population; however, the mechanisms underlying spinal aging remain elusive. In a recent Nature paper, Sun et al. systemically analyzed aged spines in nonhuman primates and identified a new cluster of CHIT1-positive microglia that drives motor neuron senescence and subsequent spine aging. [ABSTRACT FROM AUTHOR]

Published

2024

4. Lysine-specific Demethylase 1 Represses THP-1 Monocyte-to-macrophage Differentiation

Author

Yang, Rui-feng, Zhao, Guo-wei, Liang, Shu-ting, Chen, Hou-zao, and Liu, De-pei

Published

2013

5. Up-regulation of Fas Ligand Expression by Sirtuin 1 in both Flow-restricted Vessels and Serum-stimulated Vascular Smooth Muscle Cells

Author

Li, Li, Gao, Peng, Chen, Hou-zao, Zhang, Zhu-qin, Xu, Ting-ting, Jia, Yu-yan, Zhang, Hui-na, Du, Guan-hua, and Liu, De-pei

Published

2013

6. Regulation of Acyl-coenzyme A:Cholesterol Acyltransferase 2 Expression by Saturated Fatty Acids

Author

Zhang, Zhu-qin, Chen, Hou-zao, Yang, Rui-feng, Zhang, Ran, Jia, Yu-yan, Xi, Yang, Liu, De-pei, and Liang, Chih-chuan

Published

2010

7. Sirt1 deacetylates c-Myc and promotes c-Myc/Max association

Author

Mao, Beibei, Zhao, Guowei, Lv, Xiang, Chen, Hou-Zao, Xue, Zheng, Yang, Ben, Liu, De-Pei, and Liang, Chih-Chuan

Subjects

*MYC proteins, *TELOMERASE, *LACTATE dehydrogenase, *CELL proliferation, *APOPTOSIS, *CELL differentiation, *METABOLISM, *GENETIC regulation

Abstract

Abstract: The c-Myc oncoprotein plays critical roles in multiple biological processes by controlling cell proliferation, apoptosis, differentiation, and metabolism. Especially, c-Myc is frequently overexpressed in many human cancers and widely involved in tumorigenesis. However, how the post-translational modifications, especially acetylation of c-Myc, contribute to its activity in the leukemia cells remains largely unknown. Sirt1, a NAD-dependent class III histone deacetylase, has a paradoxical role in tumorigenesis by deacetylating several transcription factors, including p53, E2F1 and forkhead proteins. In this study, we show that Sirt1 interacts physically with the C-terminus of c-Myc and deacetylates c-Myc both in vitro and in vivo. Moreover, the deacetylation of c-Myc by Sirt1 promotes its association with Max, a partner essential for its activation, thereby facilitating c-Myc transactivation activity on hTERT promoter. Finally, inhibition of endogenous Sirt1 in K562 cells by either RNAi or its inhibitor NAM causes the overall decrease of c-Myc target genes expression, including hTERT, cyclinD2 and LDHA, which further suppress cell proliferation and arrest cell cycle at G1/S phase. Thus, our results demonstrate the positive effect of Sirt1 on c-Myc activity by efficiently enhancing c-Myc/Max association in human leukemia cell line K562, suggesting a potential role of Sirt1 in tumorigenesis. [Copyright &y& Elsevier]

Published

2011

8. Positive regulation of hepatic miR-122 expression by HNF4α

Author

Li, Zhen-Ya, Xi, Yang, Zhu, Wen-Nan, Zeng, Chao, Zhang, Zhu-Qin, Guo, Zhi-Chen, Hao, De-Long, Liu, Guang, Feng, Lei, Chen, Hou-Zao, Chen, Feng, Lv, Xiang, Liu, De-Pei, and Liang, Chih-Chuan

Subjects

*GENE expression, *OXIDATION, *CHOLESTEROL, *GENETIC regulation, *PROMOTERS (Genetics), *LIVER diseases, *BIOINFORMATICS, *BINDING sites, *GENETICS

Abstract

Background & Aims: miR-122 is the most abundant microRNA in the liver and regulates metabolic pathways including cholesterol biosynthesis, fatty acid synthesis, and oxidation. However, little is known about mechanisms that regulate the expression of miR-122 in the liver. The aim of this study was to identify key transcriptional regulators for miR-122 expression through intensively studying its primary transcript and promoter region. Methods: Bioinformatics analysis, Northern blotting, RT-PCR, and 5′/3′ RACE were performed to analyze miR-122 primary transcript structure, its promoter region, and potential transacting factor binding sites. Reporter gene assays integrated with truncation and site-mutation in miR-122 promoter were performed to determine the trans-activation effect of HNF4α to miR-122-promoter in vitro. ChIP and EMSA assays were performed to determine HNF4α binding to miR-122 promoter. Finally, forced expression and RNAi were performed to verify the regulatory roles of HNF4 to miR-122 expression in vitro and in vivo. Results: Here, we show that miR-122 is processed from a long spliced primary transcript directed by a distal upstream promoter region conserved across species. We dissected this promoter region and identified putative binding sites for liver-enriched transcriptional factors that contribute to the regulation of miR-122 expression, including a putative binding site for hepatocyte nuclear factor 4α (HNF4α). We demonstrate that HNF4α binds to the miR-122 promoter region through the conserved DR-I element. We observed the DR-1-element-dependent activation effect of HNF4α on the conserved miR-122 promoter and the activation could be further enhanced by the addition of PGC1α. Using overexpression and knockdown strategies, we show that HNF4α positively regulates miR122 expression in both Huh7 cells and the mouse liver. Conclusions: Our results suggest that HNF4α is a key regulator of miR-122 expression in the liver. [Copyright &y& Elsevier]

Published

2011

9. Metabolic regulation of immune cells in proinflammatory microenvironments and diseases during ageing.

Author

Li, Pei-Heng, Zhang, Ran, Cheng, Li-Qin, Liu, Jin-Jing, and Chen, Hou-Zao

Subjects

*METABOLIC regulation, *CELLULAR aging, *CELLULAR control mechanisms, *ENDOTHELIAL cells, *EXTRACELLULAR matrix, *AMINO acid metabolism

Abstract

• The metabolism of major nutrients (glucose, lipids, and amino acids) within immune cells changes during aging. • NAD + metabolism connects metabolic dysregulation during aging with immune cell senescence and corresponding senescence-associated secretory phenotype (SASP). • The senescent immune cells in tissues interact with other cells leading to proinflammatory microenvironments and diseases at the systemic level. • Targeting metabolic pathways in senescent immune cells to attenuate inflammatory diseases deserve further investigation. The process of ageing includes molecular changes within cells and interactions between cells, eventually resulting in age-related diseases. Although various cells (immune cells, parenchymal cells, fibroblasts and endothelial cells) in tissues secrete proinflammatory signals in age-related diseases, immune cells are the major contributors to inflammation. Many studies have emphasized the role of metabolic dysregulation in parenchymal cells in age-related inflammatory diseases. However, few studies have discussed metabolic modifications in immune cells during ageing. In this review, we introduce the metabolic dysregulation of major nutrients (glucose, lipids, and amino acids) within immune cells during ageing, which leads to dysfunctional NAD + metabolism that increases immune cell senescence and leads to the acquisition of the corresponding senescence-associated secretory phenotype (SASP). We then focus on senescent immune cell interactions with parenchymal cells and the extracellular matrix and their involvement in angiogenesis, which lead to proinflammatory microenvironments in tissues and inflammatory diseases at the systemic level. Elucidating the roles of metabolic modifications in immune cells during ageing will provide new insights into the mechanisms of ageing and therapeutic directions for age-related inflammatory diseases. [ABSTRACT FROM AUTHOR]

Published

2020