Your search keyword '"Fan, Zhiwen"' showing total 3 results

1. Ag-organic coordination polymers with multi-dimensional electron transfer channels for enhancing CO2 electroreduction.

Author

Zou, Yingbing, Pan, Tangxing, Fan, Zhiwen, Li, Yunbin, Zhang, Hao, Ju, Yan, Zhang, Yongfan, Ma, Xiuling, Chen, Qianhuo, Xiang, Shengchang, and Zhang, Zhangjing

Subjects

*COORDINATION polymers, *CHARGE exchange, *ELECTROLYTIC reduction, *CARBON dioxide, *BAND gaps, *SINGLE crystals

Abstract

Two Ag-MOCPs with different dimensional electron transfer Channels were used for electrocatalytic conversion CO 2 to CO. [Display omitted] • New Ag-MOCP materials for CO 2 RR electrocatalysts were synthesized. • CO 2 -to-CO conversion was boosted with the regulation of the electron transfer channel. • The FE CO for Ag-MOCP-2 with multi-dimensional electron transfer channels is higher than that for Ag-MOCP-1 with single channel at most given potentials. • The mechanism of its reaction was further explored by DFT calculation. Although, electrons transfer plays an important role in achieving the electrocatalytic CO 2 reduction reaction (CO 2 RR), it is scarce to regulate the electron transfer channels for enhancing the performance of CO 2 RR via rational design. Here, based on different solvothermal conditions, two metal–organic coordination polymers (MOCPs, Ag-MOCP-1 and Ag-MOCP-2) electrocatalyst for CO 2 RR were obtained by the same Ag ions and 5-phenyltetrazolium ligands. Single crystal X-ray diffraction showed Ag-MOCP-2 with intra-&inter-layer C H···π and π···π interactions, while Ag-MOCP-1 with intra-layer π···π interactions. The intra-&inter-layer π interactions in Ag-MOCP-2 makes it show multi-dimensional electron transfer channels, which enable Ag-MOCP-2 with higher electron conductivities and lower band gap than Ag-MOCP-1. And the Faradaic efficiency of CO for Ag-MOCP-2 with 78.3 % is higher than that for Ag-MOCP-1 with 69.1 % at −1.08 V vs RHE, and the maximum difference can reach 22 % at −1.48 V vs RHE. Based on the same central metal and organic ligands of the two MOCPs, we believe that multi-dimensional electron transfer channels make a predominant contribution for improving CO 2 RR performance in this work. [ABSTRACT FROM AUTHOR]

Published

2023

2. The chromatin remodeling protein BRG1 contributes to liver ischemia-reperfusion injury by regulating NOXA expression.

Author

Li, Nan, Liu, Hong, Xue, Yujia, Zhu, Qiang, and Fan, Zhiwen

Subjects

*REPERFUSION injury, *LIVER injuries, *CHROMATIN, *KNOCKOUT mice, *CHROMATIN-remodeling complexes, *LIVER transplantation

Abstract

Hepatic ischemia-reperfusion injury (IRI) is a common complication secondary to liver transplantation. Extensive death of hepatocytes, typically in the form of apoptosis, is observed in and contributes to IRI. In the present study we investigated the role of BRG1 (encoded by Smarca4), a chromatin remodeling protein, in the pathogenesis of liver IRI focusing on the transcriptional mechanism and translational potential. Smarca4 f/f mice were crossed to Alb -Cre mice to generate hepatocytes-specific BRG1 knockout mice (CKO). Alterations in cellular transcriptome were evaluated by RNA-seq. BRG1 expression was up-regulated in liver tissues of mice subjected to I/R and in hepatocytes exposed to hypoxia-reoxygenation (H/R). Compared to wild type (WT) littermates, the BRG1 CKO mice displayed significant amelioration of liver injury following ischemia-reperfusion as evidenced by decreased ALT/AST levels and cell apoptosis. Primary hepatocytes isolated from the CKO mice were protected from H/R-induced apoptosis compared to those from the WT mice. RNA-seq analysis revealed phorbol-12-myristate-13-acetate-induced protein 1 (PMAIP1, also known as NOXA) as a novel target for BRG1. Consistently, NOXA knockdown attenuated liver IRI in mice. More importantly, administration of a small-molecule BRG1 inhibitor (PFI-3) protected the mice from liver IRI. Our data uncover a pivotal role for BRG1 in liver IRI and suggest that targeting BRG1 with small-molecule inhibitors can be considered as a reasonable therapeutic strategy. [ABSTRACT FROM AUTHOR]

Published

2023

3. Ubiquitin specific peptidase 47 contributes to liver regeneration.

Author

Zhu, Yuwen, Guo, Yan, Liu, Hong, Zhou, Anqi, Fan, Zhiwen, Zhu, Xi, and Miao, Xiulian

Subjects

*DEUBIQUITINATING enzymes, *LIVER regeneration, *PEPTIDASE, *DNA-protein interactions, *KNOCKOUT mice, *LIVER failure

Abstract

Hepatocytes resume proliferation following liver injuries to compensate for the loss of liver mass. Robust liver regeneration is an intrinsic and pivotal process that facilitates restoration of liver anatomy and function. In the present study we investigated the role of ubiquitin-specific peptidase 47 (USP47) in liver regeneration. Proliferation of hepatocytes was evaluated by Ki67 staining in vivo and EdU incorporation in vitro. DNA-protein interaction was evaluated by chromatin immunoprecipitation (ChIP). USP47 expression was up-regulated in hepatocytes isolated from mice subjected to partial hepatectomy (PHx) or exposed to HGF treatment. Ingenuity pathway analysis revealed E2F1 as a primary regulator of USP47 transcription. Reporter assay and ChIP assay confirmed that E2F1 directly bound to the USP47 promoter and activated USP47 transcription. Consistently, E2F1 knockdown abrogated USP47 induction by HGF. Compared to the wild type littermates, USP47 knockout mice displayed compromised liver regeneration following PHx. In addition, USP47 inhibition by a small-molecule compound impaired liver regeneration in mice. On the contrary, USP47 over-expression enhanced proliferation of hepatocytes in vitro and promoted liver regeneration in mice. Importantly, a positive correlation between USP47 expression and hepatocyte proliferation was identified in patients with acute liver failure (ALF). Our data suggest that USP47, transcriptionally activated by E2F1, plays an essential role in liver regeneration. [ABSTRACT FROM AUTHOR]

Published

2023