{"type": "root", "children": [{"type": "p", "children": [{"type": "t", "text": "\nMORC3, also known as NXP2, is a multifunctional nuclear regulator that plays pivotal roles in chromatin organization, transcriptional control, and the induction of cellular senescence. Early work characterized MORC3 as a nuclear matrix‐associated protein containing an ATPase and a CW‐type zinc-finger domain, enabling binding to methylated histone H3 tails and targeting to chromatin (‑"}, {"type": "fg", "children": [{"type": "fg_f", "ref": "1"}]}, {"type": "t", "text": "‑). Subsequent studies demonstrated that when tethered to promoters, MORC3 can repress transcription, consistent with its function in SUMO-mediated gene repression (‑"}, {"type": "fg", "children": [{"type": "fg_f", "ref": "2"}]}, {"type": "t", "text": "‑). Moreover, MORC3 is important for cellular senescence by facilitating the recruitment and activation of the tumor suppressor p53 within promyelocytic leukemia nuclear bodies (PML-NBs) (‑"}, {"type": "fg", "children": [{"type": "fg_f", "ref": "3"}]}, {"type": "t", "text": "‑, ‑"}, {"type": "fg", "children": [{"type": "fg_f", "ref": "4"}]}, {"type": "t", "text": "‑). Its intrinsic ATPase activity is tightly regulated by an intramolecular interaction with its CW domain—which not only directs binding to methylated histones but also autoinhibits the ATPase—thereby serving as a molecular clamp whose activity can be modulated, including by viral proteins (‑"}, {"type": "fg", "children": [{"type": "fg_f", "ref": "5"}]}, {"type": "t", "text": "‑, ‑"}, {"type": "fg", "children": [{"type": "fg_f", "ref": "6"}]}, {"type": "t", "text": "‑, ‑"}, {"type": "fg", "children": [{"type": "fg_f", "ref": "7"}]}, {"type": "t", "text": "‑). In addition, MORC3 has been shown to regulate chromatin structure by orchestrating Daxx-mediated incorporation of histone H3.3 at endogenous retroviral loci, contributing to transcriptional silencing (‑"}, {"type": "fg", "children": [{"type": "fg_f", "ref": "8"}]}, {"type": "t", "text": "‑).\n"}]}, {"type": "t", "text": "\n\n"}, {"type": "p", "children": [{"type": "t", "text": "\nMORC3 exerts significant antiviral functions by serving as a host restriction factor that is actively involved in mounting intrinsic immune defenses against diverse viruses. During herpes simplex virus type 1 (HSV-1) infection, MORC3 is recruited to nuclear sites associated with incoming viral genomes where it helps to assemble antiviral nuclear domains containing proteins such as PML, Sp100, and γH2AX; however, HSV-1’s virulence factor ICP0 targets MORC3 for degradation to subvert this defense (‑"}, {"type": "fg", "children": [{"type": "fg_f", "ref": "9"}]}, {"type": "t", "text": "‑, ‑"}, {"type": "fg", "children": [{"type": "fg_f", "ref": "10"}]}, {"type": "t", "text": "‑). In a broader context, MORC3 operates within a “self-guarded” immune pathway where its degradation releases an otherwise repressed antiviral type I interferon response independent of canonical IRF3/IRF7 signalling (‑"}, {"type": "fg", "children": [{"type": "fg_f", "ref": "11"}]}, {"type": "t", "text": "‑, ‑"}, {"type": "fg", "children": [{"type": "fg_f", "ref": "12"}]}, {"type": "t", "text": "‑). In influenza A virus infections, MORC3 interacts with viral polymerase and ribonucleoprotein (RNP) complexes to promote viral transcription, with its depletion leading to a marked reduction in viral gene expression (‑"}, {"type": "fg", "children": [{"type": "fg_f", "ref": "9"}]}, {"type": "t", "text": "‑). Similarly, during human cytomegalovirus (HCMV) infection, MORC3 suppresses immediate-early gene expression via repression of the major immediate early promoter (MIEP), although the virus transiently depletes MORC3 through proteasomal degradation to facilitate a productive infection or reactivation from latency (‑"}, {"type": "fg", "children": [{"type": "fg_f", "ref": "13"}]}, {"type": "t", "text": "‑, ‑"}, {"type": "fg", "children": [{"type": "fg_f", "ref": "14"}]}, {"type": "t", "text": "‑).\n"}]}, {"type": "t", "text": "\n\n"}, {"type": "p", "children": [{"type": "t", "text": "\nBeyond its roles in nuclear homeostasis and antiviral defense, MORC3 is a clinically important autoantigen in idiopathic inflammatory myopathies such as dermatomyositis. Autoantibodies directed against MORC3/NXP2 have been identified in both juvenile and adult patients, with their presence correlating with distinct clinical subtypes, an increased risk of cancer, and the development of interstitial lung disease. Multiple serological studies support the utility of anti-MORC3 (anti-NXP2) antibody testing as a diagnostic tool to stratify patients and predict clinical outcomes in these disorders (‑"}, {"type": "fg", "children": [{"type": "fg_f", "ref": "15"}]}, {"type": "t", "text": "‑, ‑"}, {"type": "fg", "children": [{"type": "fg_f", "ref": "16"}]}, {"type": "t", "text": "‑, ‑"}, {"type": "fg", "children": [{"type": "fg_f", "ref": "17"}]}, {"type": "t", "text": "‑, ‑"}, {"type": "fg", "children": [{"type": "fg_f", "ref": "18"}]}, {"type": "t", "text": "‑).\n"}]}, {"type": "rg", "children": [{"type": "r", "ref": 1, "children": [{"type": "t", "text": "Yukio Kimura, Fumie Sakai, Osami Nakano, et al. "}, {"type": "b", "children": [{"type": "t", "text": "The newly identified human nuclear protein NXP-2 possesses three distinct domains, the nuclear matrix-binding, RNA-binding, and coiled-coil domains."}]}, {"type": "t", "text": " "}, {"type": "i", "children": [{"type": "t", "text": "J Biol Chem (2002)"}]}, {"type": "t", "text": " DOI: "}, {"type": "a", "children": [{"type": "t", "text": "10.1074/jbc.M201440200"}], "href": "https://doi.org/10.1074/jbc.M201440200"}, {"type": "t", "text": " PMID: "}, {"type": "a", "children": [{"type": "t", "text": "11927593"}], "href": "https://pubmed.ncbi.nlm.nih.gov/11927593"}]}, {"type": "r", "ref": 2, "children": [{"type": "t", "text": "Adam Rosendorff, Shuhei Sakakibara, Sixin Lu, et al. "}, {"type": "b", "children": [{"type": "t", "text": "NXP-2 association with SUMO-2 depends on lysines required for transcriptional repression."}]}, {"type": "t", "text": " "}, {"type": "i", "children": [{"type": "t", "text": "Proc Natl Acad Sci U S A (2006)"}]}, {"type": "t", "text": " DOI: "}, {"type": "a", "children": [{"type": "t", "text": "10.1073/pnas.0601066103"}], "href": "https://doi.org/10.1073/pnas.0601066103"}, {"type": "t", "text": " PMID: "}, {"type": "a", "children": [{"type": "t", "text": "16567619"}], "href": "https://pubmed.ncbi.nlm.nih.gov/16567619"}]}, {"type": "r", "ref": 3, "children": [{"type": "t", "text": "Keiko Takahashi, Naofumi Yoshida, Naoko Murakami, et al. 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