PIAS1

Last update 08 May 2025

Basic Info

Synonyms

DDXBP1, DEAD/H box-binding protein 1, E3 SUMO-protein ligase PIAS1

+ [9]

Introduction

Functions as an E3-type small ubiquitin-like modifier (SUMO) ligase, stabilizing the interaction between UBE2I and the substrate, and as a SUMO-tethering factor (PubMed:11583632, PubMed:11867732, PubMed:14500712, PubMed:21965678, PubMed:36050397). Catalyzes sumoylation of various proteins, such as CEBPB, MRE11, MTA1, PTK2 and PML (PubMed:11583632, PubMed:11867732, PubMed:14500712, PubMed:21965678, PubMed:36050397). Plays a crucial role as a transcriptional coregulation in various cellular pathways, including the STAT pathway, the p53 pathway and the steroid hormone signaling pathway (PubMed:11583632, PubMed:11867732). In vitro, binds A/T-rich DNA (PubMed:15133049). The effects of this transcriptional coregulation, transactivation or silencing, may vary depending upon the biological context (PubMed:11583632, PubMed:11867732, PubMed:14500712, PubMed:21965678, PubMed:36050397). Mediates sumoylation of MRE11, stabilizing MRE11 on chromatin during end resection (PubMed:36050397). Sumoylates PML (at 'Lys-65' and 'Lys-160') and PML-RAR and promotes their ubiquitin-mediated degradation (By similarity). PIAS1-mediated sumoylation of PML promotes its interaction with CSNK2A1/CK2 which in turn promotes PML phosphorylation and degradation (By similarity). Enhances the sumoylation of MTA1 and may participate in its paralog-selective sumoylation (PubMed:21965678). Plays a dynamic role in adipogenesis by promoting the SUMOylation and degradation of CEBPB (By similarity). Mediates the nuclear mobility and localization of MSX1 to the nuclear periphery, whereby MSX1 is brought into the proximity of target myoblast differentiation factor genes (By similarity). Also required for the binding of MSX1 to the core enhancer region in target gene promoter regions, independent of its sumoylation activity (By similarity). Capable of binding to the core enhancer region TAAT box in the MYOD1 gene promoter (By similarity). (Microbial infection) Restricts Epstein-Barr virus (EBV) lytic replication by acting as an inhibitor for transcription factors involved in lytic gene expression (PubMed:29262325). The virus can use apoptotic caspases to antagonize PIAS1-mediated restriction and express its lytic genes (PubMed:29262325).

100 Clinical Results associated with PIAS1

100 Translational Medicine associated with PIAS1

0 Patents (Medical) associated with PIAS1

393

Literatures (Medical) associated with PIAS1

01 May 2025·Virology

Coinfection with bacterial pathogens and genetic modification of PRRSV-2 for suppression of NF-κB and attenuation of proinflammatory responses

Review

Author: Du, Yijun ; Tang, Junyu ; Yoo, Dongwan ; Su, Chia-Ming ; Wang, Leyi ; Fang, Weihuan ; Kim, Jineui

Porcine reproductive and respiratory syndrome virus (PRRSV) infects pulmonary alveolar macrophages and induces inflammation in the respiratory system. In swine farms, coinfection with PRRSV and bacterial pathogens is common and can result in clinically complicated outcomes, including porcine respiratory disease complex. Coinfection can cause excessive expressions of proinflammatory mediators and may lead to cytokine-storm-like syndrome. An immunological hallmark of PRRSV-2 is the bidirectional regulation of NF-κB with the nucleocapsid (N) protein identified as the NF-κB activator. We generated an NF-κB-silencing mutant PRRSV-2 by mutating the N gene to block its binding to PIAS1 [protein inhibitor of activated STAT-1 (signal transducer and activator of transcription 1)]. PIAS1 functions as an NF-κB repressor, and thus, the PIAS1-binding modified N-mutant PRRSV-2 became NF-κB activation-resistant in its phenotype. During coinfection of pigs with PRRSV-2 and Streptococcus suis, the N-mutant PRRSV-2 decreased the expression of proinflammatory cytokines and showed clinical attenuation. This review describes the coinfection of pigs with various pathogens, the generation of mutant PRRSV for NF-κB suppression, inflammatory profiles during bacterial coinfection, and the potential application of these findings to designing a new vaccine candidate for PRRSV-2.

01 May 2025·Molecular Biotechnology

MicroRNA-361-5p Alleviates Leydig Cell Apoptosis and Promotes Cell Growth by Targeting PIAS1 in Late-Onset Hypogonadism

Article

Author: Feng, Ninghan ; Ben, Chunsheng ; He, Bin ; Wu, Cheng ; Zhou, Xunrong ; Wu, Dong ; Chang, Ping'an ; Xia, Anle

Late-onset hypogonadism (LOH) is an age-related syndrome characterized by deficiency of serum testosterone produced by Leydig cells. Previous evidence suggested that microRNA (miR)-361-3p can serve as a promising biomarker for LOH. Nonetheless, its detailed function and molecular mechanism in LOH remain unclarified. The 24-month-old male mice were selected as an animal LOH model, and mouse Leydig cell line TM3 was stimulated with H₂O₂. ELISA was employed for testosterone level evaluation. Hematoxylin-eosin staining was implemented for histologic analysis of mouse testicular tissues. Western blotting and RT-qPCR were utilized for evaluating molecular protein and RNA expression, respectively. Functional experiments were conducted to test miR-361-5p roles. Luciferase reporter assay was for verifying the interaction between miR-361-5p and protein inhibitor of activated STAT 1 (PIAS1). miR-361-5p displayed a decreased level in the testes of LOH mice. Overexpressing miR-361-5p attenuated Leydig cell loss in the testis and elevated serum and intratesticular testosterone levels in LOH mice. H₂O₂ stimulation impaired TM3 cell viability, proliferation and intracellular testosterone production and enhanced cell apoptosis. miR-361-5p targeted PIAS1 in TM3 cell. PIAS1 upregulation counteracted miR-361-5p overexpression-mediated alleviation of cell apoptosis and elevation of testosterone synthesis in H₂O₂-stimualetd TM3 cells. miR-361-5p ameliorates LOH progression by increasing testosterone production and alleviate Leydig cell apoptosis via downregulation of PIAS1.

22 Apr 2025·JCI Insight

SPOP mutations increase PARP inhibitor sensitivity via CK2/PIAS1/SPOP axis in prostate cancer

Article

Author: Jin, Jiabei ; Liu, Yadong ; Zheng, Zhong ; You, Hongjie ; Zhang, Hui ; Jin, Xiaofeng ; Yan, Zejun ; Wu, Liangpei ; Zhao, Yiting ; Kong, Lili ; Lv, Xiuyi ; Li, Jinhui ; Chai, Lin ; Cao, Xinyi ; Liu, Zhihan

It is well documented that impaired DNA damage repair (DDR) induces genomic instability that can efficiently increase the sensitivity of prostate cancer (PCa) cells to PARP inhibitors; however, the underlying mechanism remains elusive. Here, we found profound genomic instability in PCa cells with SPOP gene mutations and confirmed the sensitivity of SPOP-mutated PCa cells to olaparib-induced apoptosis. Mechanistically, we identified olaparib-induced CK2-mediated phosphorylation of PIAS1-S468, which in turn mediated SUMOylation of SPOP, thus promoting its E3 ligase activity in the DDR. Moreover, an abnormal CK2/PIAS1/SPOP axis due to SPOP mutations or defects in CK2-mediated phosphorylation of PIAS1, as well as SPOP inhibitor treatment, led to impaired DDR, thus increasing olaparib-induced apoptosis of PCa cells and enhancing olaparib sensitivity in animal models and patient-derived organoids. This suggested that disruption of the CK2/PIAS1/SPOP signaling axis could serve as an indicator for targeted therapy of PCa using a PARP inhibitor.

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PIAS1

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