Table 2.
Partners in regulating IREα endoribonuclease activity.
| IRE1α Binding Partner | Function of IRE1α Binding Partner | Functional Implication | References |
|---|---|---|---|
| NMIIB (Non muscle myosin IIB) | A Cytoskeleton myosin protein | Interacts with IRE1α and regulates its oligomerization and activation. In addition, recruits other regulatory molecules to oligomerized foci. | [136] |
| AIP1 | Apoptotic signaling transducer | AIP1-IRE1α association enhances IRE1 dimerization and its downstream JNK/XBP1 activation. | [137] |
| PDIA6 | Chaperonic protein of ER that inhibits aggregation of misfolded proteins | PDIA6 attenuates the activity of IRE1α. PDIA6, an ER resident protein disulfide isomerase. Negatively regulates IRE1α by binding to its luminal domain at cysteine 148, if it is oxidized, IRE1α will be activated. PDIA6-deficient cells hyperrespond to ER stress with sustained autophosphorylation of IRE1α and increased XBP1s, pJNK. | [138] |
| PTP-1B | Protein-tyrosine phosphatase 1B | In the absence of PTP-1B, ER stress-induced IRE1α downstream activities were impaired, especially XBP1 splicing and JNK activation. | [139] |
| UbD | Ubiquitin-like modifier family member | UbD regulates IRE1α/c-Jun N-terminal kinase signaling pathway. It provides a negative feedback on cytokine-induced activation of the IRE1α/JNK pro-apoptotic pathway in cytokine-exposed beta cells, but did not change cytokine-induced XBP1 splicing. | [140] |
| TMBIM6 | ER localized antiapoptotic protein, also known as Bax inhibitor-1 (BI-1) | This has been implicated in the negative modulation of XBP1 splicing activity through interacting with a cytosolic region of IRE1α. | [141] |
| Hsp47 | Heat shock protein | Hsp47 binds directly to the IRE1 ER luminal domain with high affinity, eliminating BiP from the complex to allow IRE1α oligomerization for optimal signaling. | [142] |
| HSP72 | Heat shock protein | Overexpression of HSP72, survival effect of HSP72 under ER stress is mediated by enhanced XBP1splicing and its target genes. Regulation of UPR by HSP72 is by formation of stable protein complex with IRE1α. | [143] |
| HSP90 | Heat shock protein | HSP90 stabilizes IRE1α by preventing the proteasomal degradation, and treatment of HSP90 inhibitor decreases IRE1α protein stability. | [144] |
| JIK | c-Jun N-terminal inhibitory kinase | IRE1α and TRAF2 complex induce apoptotic signal through c-Jun N-terminal kinase pathway and activation of caspase-12. | [145] |
| JAB1 | Jun activation domain-binding protein-1 | Mutant JAB1 down-regulates the UPR signaling pathway through tight binding with IRE1alpha. | [146] |
| RACK1 | Receptor for activated C-kinase 1 | Interacts with IRE1α and plays a role in dephosphorylation of IRE1α by protein phosphatase (PP2A). Furthermore, IRE1α and RACK1 association may contribute in this process of antiapoptosis by phosphorylating AMPK and Bcl-2 through enhancing autophagy. | [147,148] |
| Nck | SH2/SH3 adaptor protein | Nck and IRE1α association in immune T cells have a critical role in ER-stressed activation of MAPK pathway and cell survival. | [149] |
| RNF13 | RING finger protein | RNF13 knockdown cells showed resistance to apoptosis and JNK activation triggered by ER stress. Conversely, overexpression of RNF13 induces JNK activation and caspase-dependent apoptosis. | [150] |
| PARP16/ARTD15 | Poly ADP-ribose polymerases/ADP-ribosyl transferase D proteins | PARP16 is an upstream regulator, and modification increases its kinase and the endonuclease activity of IRE1α. | [151] |
| BAX/BAK | Pro-apoptotic protein | BAX and BAK directly interact at cytosolic domain of IRE1α during stress condition and promote the stabilized IRE1α activity. | [152] |
| BIM/PUMA | Pro-apoptotic protein | BIM and PUMA have also been linked to IRE1α regulation by direct binding with IRE1α via their BH3 domain in stress-dependent manner. Cells deficient in both BIM and PUMA exhibited reduced splicing of XBP-1 and RIDD. | [153] |
| NMI | N-Myc interactor | Interacts and modulates IRE1α especially in pancreatic beta cell. It negatively regulates the IRE1α-mediated JNK activation and further the cell death. | [154] |
| DCR2 | Dose-dependent cell-cycle regulator 2 | Physically interacts with phosphorylated IRE1α and causes dephosphorylation and IRE1 deactivation. | [155] |
| Cab45S | A member of the CREC family | Negatively regulates RNAse activity of IRE1α and prevents more spliced forms of X-box-binding protein 1 mRNA at the early stage of stress and further phosphorylation of c-Jun N-terminal kinase induced apoptosis. | [156] |
| SYVN1 | Functions in ER-associated degradation process | Coexpression of IRE1 and SYVN1 increased IRE1 degradation and ubiquitination. | [157] |
| DDRGK1 | DDRGK domain-containing protein 1 | Interaction of DDRGK1 with IRE1α counteracts ubiquitination and subsequently inhibits the ERAD-mediated degradation of IRE1α. | [55] |
| PRKCSH | Protein kinase C substrate 80K-H | In ER stress condition, PRKCH steps up ER stress-mediated autophosphorylation and oligomerization of IRE1 through mutual interaction followed by XBP1 splicing and MAPK activation which contribute to tumorigenesis. | [158] |
| Sigma-1 receptor | Unique ligand-regulated molecular chaperone in the ER. | Under ER stress conditions, interacts with and stabilizes IRE1α and enhances cell survival through prolonged activation of the IRE1α-XBP1 pathway, especially in cancer cell survival. | [159] |
| Sec61 | Channel-forming translocon complex | Forms a hetero-oligomeric complex with IRE1α upon ER stress. It recruits XBP1u and aids in splicing. The Sec61-IRE1α complex defines the extent of IRE1α activity and may determine cell fate decisions during ER stress conditions. | [160,161] |
| Fortilin | Pro-survival molecule | Interacts with the cytoplasmic domain of IRE1α, inhibits both kinase and RNase activities, and protects cells from apoptotic cell death. | [162] |
| Filamin A | Actin crosslinking factor involved in the remodeling of cytoskeletons | Through a novel domain located at the distal C-terminal region, monomeric IRE1α interacts physically with Filamine A. A pro-migratory stimulus causes dimerization of IRE1α, increasing Filamin A binding and PKCα recruitment. Phosphorylation of Filamine A by PKCα at S2152 improves actin cytoskeleton remodeling and cell migration in different animal species | [163] |
| ABL kinase | Tyrosine-protein kinase | ABL kinase interaction enhances IRE1α RNase activity and potentiates its apoptosis signaling pathway. | [164] |