Affinage

NCAPG2

Condensin-2 complex subunit G2 · UniProt Q86XI2

Length
1143 aa
Mass
131.0 kDa
Annotated
2026-06-10
20 papers in source corpus 12 papers cited in narrative 12 extracted findings
Cross-family judge vs UniProt: Affinage preferred faithfulness: 5/5 claims corpus-supported (100%)

Mechanistic narrative

Synthesis pass · prose summary of the discoveries below

NCAPG2 is a non-SMC subunit of the condensin II complex that ensures proper chromosome condensation and segregation during mitosis (PMID:25109385, PMID:30609410). Its highly conserved C-terminal region, when phosphorylated (residues 1007VLS-pT-L1011), directly binds the polo-box domain of PLK1 and recruits PLK1 to prometaphase kinetochores, promoting phosphorylation of the kinetochore substrate BubR1; loss of NCAPG2 loosens and misaligns spindle-kinetochore attachments in both human cells and C. elegans (PMID:25109385). Recessive loss-of-function mutations in NCAPG2 cause abnormal chromosome condensation, anaphase chromatin bridges, and micronuclei, and produce a human and zebrafish phenotype of microcephaly and renal anomalies that is rescued by wild-type but not mutant NCAPG2, establishing NCAPG2 as a causative disease gene (PMID:30609410). Beyond its mitotic role, NCAPG2 functions in transcriptional and signaling contexts: in hematopoietic cells it is recruited to the nucleus by the bHLH factors SCL and E12 and represses SCL/E12-mediated transcription to promote erythroid differentiation (PMID:16673016), and in cancer cells it directly binds STAT3 and drives STAT3 occupancy of the MYC promoter to activate c-MYC (PMID:38166947), activates HBO1 phosphorylation and Wnt/β-catenin signaling (PMID:32897418), and engages STAT3/NF-κB signaling (PMID:31176678). NCAPG2 expression is set post-transcriptionally, being stabilized by PCBP2 binding to its mRNA (PMID:37544634) and suppressed through 3'UTR-targeting regulators (PMID:41894088).

Mechanistic history

Synthesis pass · year-by-year structured walk · 10 steps
  1. 2006 Medium

    The first mechanistic role for the NCAPG2 ortholog placed it outside mitosis, asking whether a condensin subunit could modulate hematopoietic transcription.

    Evidence Yeast two-hybrid, reciprocal Co-IP, luciferase reporter and MEL cell differentiation assays with the murine ortholog MTB/mCAP-G2

    PMID:16673016

    Open questions at the time
    • Mechanism by which nuclear recruitment by SCL/E12 represses transcription not defined
    • Mouse ortholog; human relevance not directly tested
    • No link to the condensin function established here
  2. 2012 Medium

    Established that NCAPG2 is a druggable mitotic target by showing a small molecule can bind it and disrupt chromosome segregation.

    Evidence mRNA display in vitro binding selection of Q15 to hCAP-G2 plus immunofluorescence and xenograft readouts

    PMID:23028663

    Open questions at the time
    • Binding site on NCAPG2 not mapped
    • Direct mechanistic link between compound binding and segregation defect not resolved
  3. 2014 High

    Resolved how NCAPG2 contributes mechanistically to mitosis, defining a direct phosphorylation-dependent interaction that recruits PLK1 to kinetochores.

    Evidence Co-IP, crystal structure of the PBD–NCAPG2 C-terminal phosphopeptide complex, phosphopeptide mutagenesis, kinase substrate assay, and siRNA/RNAi in human cells and C. elegans

    PMID:25109385

    Open questions at the time
    • Kinase responsible for the priming phosphorylation of NCAPG2 not identified
    • Whether condensin assembly is required for PLK1 recruitment not tested
  4. 2019 Medium

    Connected NCAPG2 to oncogenic signaling, asking how its overexpression drives tumor phenotypes.

    Evidence Co-IP, luciferase reporter, ELISA and in vitro/in vivo functional assays in hepatocellular carcinoma linking NCAPG2 to STAT3/NF-κB and miR-188-3p

    PMID:31176678

    Open questions at the time
    • Direct versus indirect activation of STAT3/NF-κB not distinguished
    • Single tumor type
  5. 2019 High

    Established NCAPG2 as a human disease gene by demonstrating causality of recessive loss-of-function alleles for chromosome instability and a microcephaly/renal phenotype.

    Evidence Patient fibroblast cytogenetics, zebrafish morpholino and CRISPR-F0 mutagenesis, mRNA rescue, and nphp1 epistasis

    PMID:30609410

    Open questions at the time
    • Tissue-specific basis of microcephaly versus renal phenotype not resolved
    • Relationship of condensation defect to the PLK1 recruitment role not directly connected
  6. 2020 Medium

    Extended NCAPG2's signaling repertoire by placing it upstream of HBO1 acetyltransferase activation and Wnt/β-catenin signaling in glioblastoma.

    Evidence Knockdown/overexpression functional assays, phospho-HBO1 and H4 acetylation western blots, MCM chromatin-binding assay, HBO1 knockdown rescue

    PMID:32897418

    Open questions at the time
    • How NCAPG2 promotes HBO1 phosphorylation mechanistically unknown
    • Direct binding to HBO1 not shown
  7. 2022 Medium

    Identified an upstream transcriptional regulator, showing brachyury directly drives NCAPG2 expression in HCC.

    Evidence ChIP-sequencing for brachyury occupancy plus knockdown functional assays and NCAPG2-brachyury epistasis in vitro and in vivo

    PMID:36119840

    Open questions at the time
    • Direct binding of brachyury to the NCAPG2 promoter not validated beyond ChIP-seq
    • Single tumor type
  8. 2023 Medium

    Defined post-transcriptional control of NCAPG2 abundance by identifying PCBP2 as an mRNA-stabilizing factor.

    Evidence Direct RNA binding assay and mRNA half-life measurement (8 h to 5 h) upon PCBP2 knockdown in MCF-7 and T-47D cells

    PMID:37544634

    Open questions at the time
    • Binding element on NCAPG2 mRNA not mapped
    • Single lab
  9. 2024 Medium

    Provided a direct transcriptional mechanism for NCAPG2 oncogenic activity by showing it binds STAT3 and induces STAT3 occupancy of the MYC promoter.

    Evidence Co-IP, ChIP, TMT proteomics and knockdown/overexpression with xenografts in prostate cancer

    PMID:38166947

    Open questions at the time
    • Whether NCAPG2 acts as a coactivator or alters STAT3 phosphorylation not resolved
    • Single lab
  10. 2025 Low

    Added regulators acting through the NCAPG2 3'UTR, defining a USP52–RBM5–NCAPG2 suppressive axis and RPL35A as a positive upstream factor.

    Evidence Co-IP ubiquitination and dual-luciferase 3'UTR reporter assays (RBM5/USP52) and shRNA/overexpression with gene expression analysis (RPL35A), in prostate cancer and HCC

    PMID:40552444 PMID:41894088

    Open questions at the time
    • RPL35A regulation of NCAPG2 shown only by expression analysis without direct binding
    • Mechanism of RBM5 3'UTR-mediated suppression not detailed

Open questions

Synthesis pass · forward-looking unresolved questions
  • How NCAPG2's mitotic condensin function mechanistically relates to its diverse transcriptional and signaling roles remains unresolved.
  • No unified model linking kinetochore PLK1 recruitment to STAT3/HBO1/SCL transcriptional functions
  • The priming kinase for NCAPG2 phosphorylation is unidentified
  • Whether signaling roles require the condensin complex is untested

Mechanism profile

Synthesis pass · controlled-vocabulary classification · explore literature graph →
Molecular activity
GO:0140110 transcription regulator activity 2 GO:0060090 molecular adaptor activity 1
Localization
GO:0005694 chromosome 2 GO:0005634 nucleus 1
Pathway
R-HSA-162582 Signal Transduction 3 R-HSA-1640170 Cell Cycle 2
Partners
BUBR1E12HBO1PCBP2PLK1RBM5SCLSTAT3
Complex memberships
condensin II

Evidence

Reading pass · 12 per-paper findings extracted from the source corpus
Year Finding Method Journal Conf PMIDs
2014 NCAPG2, as a component of the condensin II complex, directly interacts with the polo-box domain (PBD) of PLK1 via its highly conserved C-terminal region (residues 1007VLS-pT-L1011), recruits PLK1 to prometaphase kinetochores, and promotes phosphorylation of the kinetochore substrate BubR1. Loss of NCAPG2 in humans and C. elegans loosens and misaligns spindle-kinetochore attachment. The crystal structure of PBD-NCAPG2 C-terminal peptide complex was solved, confirming phosphorylation-dependent interaction. Co-immunoprecipitation, crystal structure determination, siRNA knockdown in human cells and C. elegans RNAi, immunofluorescence, kinase substrate phosphorylation assay Nature communications High 25109385
2006 The murine NCAPG2 ortholog MTB/mCAP-G2 was identified in a yeast two-hybrid screen as interacting with the hematopoietic bHLH transcription factor SCL; it also interacts with E12. MTB is recruited to the nucleus by SCL and E12, and represses SCL/E12-mediated transcriptional activation. Overexpression of MTB promotes terminal erythroid differentiation of murine erythroleukemia cells. Yeast two-hybrid screen, co-immunoprecipitation, nuclear localization assay, luciferase transcriptional reporter assay, overexpression in MEL cells with differentiation readout Leukemia Medium 16673016
2019 NCAPG2 overexpression activates STAT3 and NF-κB signaling pathways in hepatocellular carcinoma cells to promote proliferation, migration, and invasion. A positive feedback loop exists between NCAPG2 and p-STAT3. Additionally, miR-188-3p directly targets NCAPG2 (negative feedback loop), and NCAPG2 is a direct target of miR-188-3p as shown by luciferase reporter assay. Co-immunoprecipitation, luciferase reporter assay, immunocytochemistry, ELISA, in vitro and in vivo functional assays, western blotting EBioMedicine Medium 31176678
2019 Recessive loss-of-function mutations in NCAPG2 cause abnormal chromosome condensation, augmented anaphase chromatin-bridge formation, and micronuclei in daughter cells of patient fibroblasts. In zebrafish, ncapg2 morphant and CRISPR-F0 mutants display microcephaly, renal anomalies, increased apoptosis, and altered mitotic progression; these phenotypes are rescued by wild-type but not mutant human NCAPG2 mRNA, establishing causality. Co-suppression of nphp1 and ncapg2 in zebrafish results in significantly more dysplastic renal tubules. Patient fibroblast cytogenetics, zebrafish morpholino knockdown, CRISPR-Cas9 F0 mutagenesis, mRNA rescue experiments, genetic epistasis (ncapg2 + nphp1 co-suppression) American journal of human genetics High 30609410
2012 An anilinoquinazoline derivative (Q15) was identified as directly binding hCAP-G2 (NCAPG2), a subunit of the condensin II complex, using mRNA display technology. Q15 treatment compromises normal chromosome segregation, as shown by immunofluorescence, consistent with hCAP-G2 being a therapeutic target for mitotic disruption. mRNA display (in vitro binding selection), immunofluorescence, cell proliferation assays, in vivo xenograft PloS one Medium 23028663
2020 In glioblastoma cells, NCAPG2 promotes HBO1 phosphorylation and consequent H4 histone acetyltransferase activation, modulates Wnt/β-catenin pathway activation, and regulates MCM protein binding to chromatin. Knockdown of HBO1 reverses the proliferative and invasive effects of NCAPG2 overexpression, placing NCAPG2 upstream of HBO1 in this pathway. Knockdown/overexpression with functional assays (proliferation, migration, invasion, cell cycle), western blotting for phospho-HBO1 and H4 acetylation, chromatin binding assay for MCM, epistasis via HBO1 knockdown rescue Cell and tissue research Medium 32897418
2024 NCAPG2 directly binds STAT3 (shown by co-IP) and induces STAT3 occupancy on the MYC promoter (shown by ChIP assay), thereby transcriptionally activating c-MYC expression to promote prostate cancer malignancy and cancer stem cell self-renewal. TMT quantitative proteomics confirmed c-MYC activity is strongly correlated with NCAPG2 expression. Co-immunoprecipitation, chromatin immunoprecipitation (ChIP), TMT quantitative proteomics, knockdown/overexpression functional assays, xenograft models Journal of translational medicine Medium 38166947
2022 Brachyury transcription factor directly regulates NCAPG2 transcription in hepatocellular carcinoma, as demonstrated by ChIP-sequencing data showing brachyury occupancy at the NCAPG2 locus. Knockdown of brachyury reduces NCAPG2 levels and suppresses HCC proliferation and migration in vitro and in vivo; NCAPG2 knockdown similarly inhibits HCC progression and attenuates brachyury-induced tumorigenesis. ChIP-sequencing, knockdown functional assays (proliferation, migration), in vivo tumor models, epistasis (NCAPG2 KD reverses brachyury overexpression effects) American journal of cancer research Medium 36119840
2023 The RNA-binding protein PCBP2 directly binds NCAPG2 mRNA and protects it from degradation. PCBP2 knockdown reduces the mRNA half-life of NCAPG2 from approximately 8 hours to 5 hours, establishing PCBP2 as a post-transcriptional regulator (mRNA stability factor) of NCAPG2. RNA binding assay (direct binding shown), mRNA stability/half-life assay upon PCBP2 knockdown, label-free proteomics, functional assays in MCF-7 and T-47D cells Cellular signalling Medium 37544634
2026 USP52 deubiquitinates and stabilizes RBM5 protein in prostate cancer cells (shown by co-IP ubiquitination assay). RBM5 in turn interacts with the 3'UTR of NCAPG2 mRNA (shown by dual-luciferase reporter assay) to suppress NCAPG2 expression. This USP52–RBM5–NCAPG2 axis suppresses prostate cancer cell proliferation, migration, invasion, and stemness. Co-immunoprecipitation, ubiquitination assay, dual-luciferase reporter assay, knockdown/overexpression functional assays, xenograft tumor model Molecular and cellular biochemistry Medium 41894088
2021 miR-375 directly targets the 3'UTR of NCAPG2 mRNA, as confirmed by luciferase reporter assay, suppressing NCAPG2 protein expression. Overexpression of miR-375 represses HCC cell proliferation and migration; these effects are rescued by NCAPG2 overexpression, placing NCAPG2 downstream of miR-375. Luciferase reporter assay, western blotting, qRT-PCR, epistasis (NCAPG2 OE rescues miR-375 OE phenotype) Neoplasma Low 34818025
2025 RPL35A regulates NCAPG2 expression in HCC; RPL35A overexpression increases NCAPG2 levels and promotes tumor progression, while RPL35A knockdown reduces NCAPG2 and reverses oncogenic effects. Gene expression analysis identified NCAPG2 as a key downstream target of RPL35A. shRNA knockdown, overexpression, gene expression analysis, xenograft model, functional assays (proliferation, migration, invasion, apoptosis) Cancer medicine Low 40552444

Source papers

Stage 0 corpus · 20 papers · ranked by NIH iCite citations
Year Title Journal Citations PMID
2019 NCAPG2 overexpression promotes hepatocellular carcinoma proliferation and metastasis through activating the STAT3 and NF-κB/miR-188-3p pathways. EBioMedicine 54 31176678
2014 The condensin component NCAPG2 regulates microtubule-kinetochore attachment through recruitment of Polo-like kinase 1 to kinetochores. Nature communications 47 25109385
2006 MTB, the murine homolog of condensin II subunit CAP-G2, represses transcription and promotes erythroid cell differentiation. Leukemia 43 16673016
2019 Mutations in NCAPG2 Cause a Severe Neurodevelopmental Syndrome that Expands the Phenotypic Spectrum of Condensinopathies. American journal of human genetics 34 30609410
2020 NCAPG2 facilitates glioblastoma cells' malignancy and xenograft tumor growth via HBO1 activation by phosphorylation. Cell and tissue research 29 32897418
2013 Combined deletion of two Condensin II system genes (NCAPG2 and MCPH1) in a case of severe microcephaly and mental deficiency. European journal of medical genetics 25 24013099
2024 NCAPG2 promotes prostate cancer malignancy and stemness via STAT3/c-MYC signaling. Journal of translational medicine 14 38166947
2023 Circular RNA circ0001955 promotes cervical cancer tumorigenesis and metastasis via the miR-188-3p/NCAPG2 axis. Journal of translational medicine 13 37248471
2022 NCAPG2 Maintains Cancer Stemness and Promotes Erlotinib Resistance in Lung Adenocarcinoma. Cancers 13 36139554
2012 An anilinoquinazoline derivative inhibits tumor growth through interaction with hCAP-G2, a subunit of condensin II. PloS one 12 23028663
2023 The mRNA stability of NCAPG2, a novel contributor to breast invasive carcinoma, is enhanced by the RNA-binding protein PCBP2. Cellular signalling 11 37544634
2022 NCAPG2 contributes to the progression of malignant melanoma through regulating proliferation and metastasis. Biochemistry and cell biology = Biochimie et biologie cellulaire 10 36265182
2021 microRNA-375 inhibits the malignant behaviors of hepatic carcinoma cells by targeting NCAPG2. Neoplasma 8 34818025
2022 Brachyury promotes proliferation and migration of hepatocellular carcinoma via facilitating the transcription of NCAPG2. American journal of cancer research 7 36119840
2025 RPL35A Downregulation Suppresses Hepatocellular Carcinoma Cell Proliferation via NCAPG2 Inactivation. Cancer medicine 3 40552444
2024 MYC and NCAPG2 as molecular targets of colorectal cancer and gastric cancer in nursing. Medicine 2 38701261
2026 USP52 impedes malignant progression and cell stemness in prostate cancer by deubiquitinating RBM5 to down-regulate NCAPG2. Molecular and cellular biochemistry 0 41894088
2026 Bioinformatics and experimental analysis revealed the cancer-promoting role of NCAPG2 in epithelial ovarian cancer. Frontiers in oncology 0 41907601
2025 NCAPG2 promotes the proliferation, metastasis and resistance to nab-paclitaxel in gastric adenocarcinoma cells. Journal of chemotherapy (Florence, Italy) 0 40375564
2023 miR-638 suppresses cervical cancer progression by inhibiting NCAPG2 under the treatment of Tetrandrine. Histology and histopathology 0 37702425

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