TRIAP1

Last update 08 May 2025

Basic Info

Synonyms

15E1.1, HSPC132, MDM35

+ [7]

Introduction

Involved in the modulation of the mitochondrial apoptotic pathway by ensuring the accumulation of cardiolipin (CL) in mitochondrial membranes. In vitro, the TRIAP1:PRELID1 complex mediates the transfer of phosphatidic acid (PA) between liposomes and probably functions as a PA transporter across the mitochondrion intermembrane space to provide PA for CL synthesis in the inner membrane (PubMed:23931759). Likewise, the TRIAP1:PRELID3A complex mediates the transfer of phosphatidic acid (PA) between liposomes (in vitro) and probably functions as a PA transporter across the mitochondrion intermembrane space (in vivo) (PubMed:26071602). Mediates cell survival by inhibiting activation of caspase-9 which prevents induction of apoptosis (PubMed:15735003).

100 Clinical Results associated with TRIAP1

100 Translational Medicine associated with TRIAP1

0 Patents (Medical) associated with TRIAP1

102

Literatures (Medical) associated with TRIAP1

01 Jun 2025·Burns

Identification of the potential role of PANoptosis-related genes in burns via bioinformatic analyses and experimental validation

Article

Author: Zhou, Qin ; Wang, Lin ; Zhang, Yan ; Li, Junxi ; Cao, Yang ; Tang, Xuexian ; Chen, Jiacong ; Liang, Bing

BACKGROUNDThe treatment of burns is highly challenging due to their complex pathophysiological mechanisms. PANoptosis, as an important form of cell death, is suggested to play a crucial role in the inflammatory response and tissue damage following burns. However, the role of PANoptosis-related biomarkers in the pathophysiological processes of burns remains unclear. In this study, we aim to identify PANoptosis-related signature genes and validate them as biomarkers in burns METHODS: Burn-related datasets were obtained from the Gene Expression Omnibus（GEO） database. GSE37069 was used for bioinformatic analysis and machine learning, while GSE19743 was used specifically for external validation. A set of PANoptosis-associated genes was obtained from the GeneCards database. Three machine learning models (LASSO, RF, and SVM-RFE) and WGCNA were utilized to screen for signature genes. The diagnostic efficacy of the identified genes was assessed through receiver operating characteristic (ROC) curves. Gene Set Enrichment Analysis (GSEA) was performed to identify pathways associated with the signature genes, while single-sample gene set enrichment analysis (ssGSEA) was employed to investigate the immune landscape. Finally, Western blotting and RT-qPCR were employed to validate the signature genes.RESULTSBCL-2, CCAR1, CERK, TRIAP1, S100A8, and SNHG1 were identified as signature genes. The biological processes involving these genes mainly include endocytosis, apoptosis, and ECM receptor interaction. Immune infiltration analysis revealed that neutrophils, eosinophils, M0 macrophages, and monocytes are significantly elevated in burn samples. Additionally, these signature genes showed significant correlations with multiple immune cell types. Finally, Western blotting and RT-qPCR analysis revealed that the expression levels of BCL2, CCAR1, CERK, and TRIAP1 were significantly down-regulated in the burn groups compared to the normal groups, with the exception of S100A8.CONCLUSIONOur study has identified BCL-2, CCAR1, CERK, and TRIAP1 as reliable potential biomarkers for burn injuries. These genes play crucial roles in immune response, wound healing, and anti-apoptotic mechanisms, which are key pathological processes involved in the progression of burn injuries. Specifically, BCL-2, CCAR1, CERK, and TRIAP1 have been shown to significantly impact the regulation of inflammation, the efficiency of wound repair, and the prevention of cell apoptosis during burn injury.

01 Mar 2025·Journal of Biological Chemistry

MIA40 circumvents the folding constraints imposed by TRIAP1 function

Article

Author: Banci, Lucia ; Teilum, Kaare ; Bartolomé-Nafría, Andrea ; Pujols, Jordi ; Fornt-Suñé, Marc ; Canals, Francesc ; Gil-García, Marcos ; Esperante, Sebastián A ; Cerofolini, Linda ; Ventura, Salvador

The MIA40 relay system mediates the import of small cysteine-rich proteins into the intermembrane mitochondrial space (IMS). MIA40 substrates are synthesized in the cytosol and assumed to be disordered in their reduced state in this compartment. As they cross the outer mitochondrial membrane, MIA40 promotes the oxidation of critical native disulfides to facilitate folding, trapping functional species in the IMS. Here, we study the redox-controled folding of TRIAP1, a small cysteine-rich protein with moonlighting function: regulating phospholipid trafficking between mitochondrial membranes in the IMS and preventing apoptosis in the cytosol. TRIAP1 dysregulation is connected to oncogenesis. Although TRIAP1 contains a canonical twin CX9C motif, its sequence characteristics and folding pathway deviate from typical MIA40 substrates. In its reduced state, TRIAP1 rapidly populates a hydrophobic collapsed, alpha-helical, and marginally stable molten globule. This intermediate biases oxidative folding towards a non-native Cys37-Cys47 kinetic trap, slowing the reaction. MIA40 accelerates TRIAP1 folding rate by 30-fold, bypassing the formation of this folding trap. MIA40 drives the oxidation of the inner disulfide bond Cys18-Cys37, and subsequently, it can catalyze the formation of the outer disulfide bond Cys8-Cys47 to attain the native two-disulfide-bridged structure. We demonstrate that, unlike most MIA40 substrates, TRIAP1's folding pathway is strongly constrained by the structural requirements for its function in phospholipid traffic at the IMS. The obligatory population of a reduced, alpha-helical, metastable molten globule in the cytoplasm may explain TRIAP1's connection to the p53-dependent cell survival pathway, constituting a remarkable example of a functional molten globule state.

01 Dec 2024·Current Computer-Aided Drug Design

Identification of Prognostic Markers and Potential Therapeutic Targets using Gene Expression Profiling and Simulation Studies in Pancreatic Cancer

Article

Author: Singh, Samvedna ; Sahi, Shakti ; Kaushik, Aman Chandra ; Gupta, Himanshi ; Jhinjharia, Divya

Background:Pancreatic ductal adenocarcinoma (PDAC) has a 5-year relative survival rate of less than 10% making it one of the most fatal cancers. A lack of early measures of prognosis, challenges in molecular targeted therapy, ineffective adjuvant chemotherapy, and strong resistance to chemotherapy cumulatively make pancreatic cancer challenging to manageObjective:The present study aims to enhance understanding of the disease mechanism and its progression by identifying prognostic biomarkers, potential drug targets, and candidate drugs that can be used for therapy in pancreatic cancer.Methods:Gene expression profiles from the GEO database were analyzed to identify reliable prognostic markers and potential drug targets. The disease's molecular mechanism and biological pathways were studied by investigating gene ontologies, KEGG pathways, and survival analysis to understand the strong prognostic power of key DEGs. FDA-approved anti-cancer drugs were screened through cell line databases, and docking studies were performed to identify drugs with high affinity for ARNTL2 and PIK3C2A. Molecular dynamic simulations of drug targets ARNTL2 and PIK3C2A in their native state and complex with nilotinib were carried out for 100 ns to validate their therapeutic potential in PDAC.Results:Differentially expressed genes that are crucial regulators, including SUN1, PSMG3, PIK3C2A, SCRN1, and TRIAP1, were identified. Nilotinib as a candidate drug was screened using sensitivity analysis on CCLE and GDSC pancreatic cancer cell lines. Molecular dynamics simulations revealed the underlying mechanism of the binding of nilotinib with ARNTL2 and PIK3C2A and the dynamic perturbations. It validated nilotinib as a promising drug for pancreatic cancer.Conclusion:This study accounts for prognostic markers, drug targets, and repurposed anti-cancer drugs to highlight their usefulness for translational research on developing novel therapies. Our results revealed potential and prospective clinical applications in drug targets ARNTL2, EGFR, and PI3KC2A for pancreatic cancer therapy.

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TRIAP1

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