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Showing VMA22CCDC115 is a alias.

VMA22

Vacuolar ATPase assembly protein VMA22 · UniProt Q96NT0

Length
180 aa
Mass
19.8 kDa
Annotated
2026-06-11
26 papers in source corpus 12 papers cited in narrative 12 extracted findings
Cross-family judge vs UniProt: Affinage preferred faithfulness: 6/6 claims corpus-supported (100%)

Mechanistic narrative

Synthesis pass · prose summary of the discoveries below

VMA22 (yeast Vma22p; human ortholog CCDC115) is a dedicated assembly factor for the vacuolar H+-ATPase (V-ATPase), required for productive biogenesis of the enzyme rather than for its catalytic cycle (PMID:7673216, PMID:8416931). In yeast, Vma22p is an ER membrane-associated protein that forms a stable complex with Vma12p; this Vma12p/Vma22p complex transiently binds the V0 subunit Vph1p to chaperone its assembly, and in its absence cytosolic V1 subunits fail to assemble while Vph1p is rapidly degraded in the ER (PMID:7673216, PMID:9660861). The human ortholog CCDC115 localizes to the ERGIC/COPI compartment rather than the ER and supports Golgi homeostasis and protein N-/O-glycosylation, with loss-of-function mutations causing a congenital disorder of glycosylation (PMID:26833332). Through its V-ATPase assembly role, CCDC115 controls organellar acidification, which underlies endocytic transferrin/iron uptake and heme distribution, and consequently cellular iron status: its disruption depletes intracellular iron and impairs iron-dependent PHD prolyl hydroxylases, stabilizing HIF1α (PMID:28296633, PMID:32510613). CCDC115 also governs lysosomal acidification and autophagic flux in hepatocytes, where its loss impairs lipophagy (PMID:34626841), and it acts at the autophagosome–lysosome fusion step by competing with STX17 for HOPS complex binding to limit autophagic degradation of YAP (PMID:36650560). In partnership with TMEM199, CCDC115 additionally directs IFN-γ receptor recycling through RAB11A-positive endosomes, recruiting TRAPP II and activating RAB11A to sustain JAK-STAT signaling and PD-L1 expression (PMID:41319859).

Mechanistic history

Synthesis pass · year-by-year structured walk · 11 steps
  1. 1993 Medium

    Established that VMA22 is genetically required for vacuolar ATPase function, before any molecular role was known, by linking its loss to failure of acidification-dependent growth.

    Evidence Genetic screen for neutral-pH growth defects with V-ATPase enzyme activity assay in yeast

    PMID:8416931

    Open questions at the time
    • Did not distinguish a structural subunit role from an assembly/regulatory role
    • No subcellular localization or partner defined
  2. 1995 High

    Defined VMA22 as an assembly factor rather than a V-ATPase subunit by showing that its deletion blocks V1 membrane assembly and triggers ER degradation of the V0 subunit Vph1p.

    Evidence Genetic deletion, subcellular fractionation, and pulse-chase degradation assays in yeast

    PMID:7673216

    Open questions at the time
    • Did not show direct physical contact with V0 subunits
    • Mechanism by which Vma12p anchors Vma22p to the ER unresolved
  3. 1998 High

    Resolved the molecular mechanism of assembly by showing a stable Vma12p/Vma22p ER complex transiently and directly binds Vph1p to chaperone its incorporation.

    Evidence Cross-linking, co-fractionation, density-gradient sedimentation, and sec12 epistasis in yeast

    PMID:9660861

    Open questions at the time
    • Structural basis of the Vma12p/Vma22p–Vph1p interaction not determined
    • Stoichiometry and release step not defined
  4. 2006 Low

    Placed VMA22 in a functional network with ER-to-Golgi transport machinery via synthetic genetic interactions.

    Evidence Synthetic Genetic Array screen in yeast

    PMID:17077122

    Open questions at the time
    • Genetic interaction is indirect and does not establish a physical or causal link
    • vma22 was one of many hits
  5. 2016 High

    Translated the yeast assembly-factor role to humans and tied it to disease, showing CCDC115 localizes to ERGIC/COPI and is required for Golgi glycosylation, with patient mutations causing a glycosylation disorder.

    Evidence Immunofluorescence, patient exome sequencing, sialic acid metabolic labeling, and complementation rescue in fibroblasts

    PMID:26833332

    Open questions at the time
    • Why human localization differs from yeast ER residence unexplained
    • Direct demonstration of human V-ATPase assembly defect not shown here
  6. 2017 High

    Connected V-ATPase assembly to cellular iron homeostasis, showing CCDC115 loss depletes iron and impairs PHD hydroxylases to stabilize HIF1α, rescued by iron supplementation.

    Evidence Genome-wide genetic screen in haploid human cells with iron rescue and PHD activity readout

    PMID:28296633

    Open questions at the time
    • Direct link from acidification defect to iron depletion at the transporter level not detailed
    • Tissue-specific consequences not addressed
  7. 2020 Medium

    Extended the acidification-dependent role to physiological iron uptake, showing CCDC115 is required for transferrin-bound iron uptake and heme distribution in erythroid cells.

    Evidence Genome-wide CRISPR screen and TBI uptake assays in CCDC115-deficient K562 cells

    PMID:32510613

    Open questions at the time
    • Single lab; endocytic acidification mechanism inferred rather than directly measured
    • Heme distribution defect not mechanistically dissected
  8. 2020 Medium

    Implicated CCDC115 in viral entry via its V-ATPase assembly function in an unbiased screen.

    Evidence Genome-wide CRISPR/Cas9 screen with influenza A entry validation

    PMID:31919360

    Open questions at the time
    • Mechanistic detail of the entry requirement limited
    • Whether the effect is purely acidification-dependent unresolved
  9. 2021 Medium

    Defined a hepatocyte role in lysosomal acidification and lipophagy, with CCDC115 loss impairing autophagic capacity and causing lipid droplet accumulation.

    Evidence siRNA knockdown in HepG2 cells with acidification, autophagy flux, lipid droplet imaging, and apoB secretion assays

    PMID:34626841

    Open questions at the time
    • Knockdown rather than knockout; off-target not excluded
    • Single lab
  10. 2023 Medium

    Identified a V-ATPase-independent role at autophagosome–lysosome fusion, with CCDC115 competing with STX17 for HOPS binding to limit autophagic YAP degradation and promote proliferation.

    Evidence Co-immunoprecipitation, autophagy flux, YAP degradation, and proliferation assays under starvation

    PMID:36650560

    Open questions at the time
    • Single lab Co-IP without structural mapping of the HOPS interface
    • How this reconciles with its acidification-promoting role not resolved
  11. 2025 Medium

    Revealed a receptor-trafficking function in which CCDC115/TMEM199 routes IFN-γ receptors through RAB11A endosomes via TRAPP II recruitment to sustain JAK-STAT signaling and PD-L1.

    Evidence Co-immunoprecipitation, receptor trafficking, RAB11A activation, TRAPP II recruitment, and PD-L1 assays

    PMID:41319859

    Open questions at the time
    • Single lab; direct vs indirect receptor binding not fully resolved
    • Generality beyond IFN-γ receptors unknown

Open questions

Synthesis pass · forward-looking unresolved questions
  • How CCDC115 partitions between its conserved V-ATPase assembly function and its V-ATPase-independent roles in HOPS-dependent fusion and RAB11A-mediated receptor recycling remains unresolved.
  • No structural model of human CCDC115 or its complexes
  • Mechanism partitioning assembly vs trafficking roles undefined
  • Whether TMEM199 partnership extends across all functions unknown

Mechanism profile

Synthesis pass · controlled-vocabulary classification · explore literature graph →
Molecular activity
GO:0060090 molecular adaptor activity 2 GO:0140096 catalytic activity, acting on a protein 2
Localization
GO:0005783 endoplasmic reticulum 2 GO:0031410 cytoplasmic vesicle 1
Pathway
R-HSA-1852241 Organelle biogenesis and maintenance 2 R-HSA-5653656 Vesicle-mediated transport 2 R-HSA-9612973 Autophagy 2 R-HSA-392499 Metabolism of proteins 1
Partners
HOPS COMPLEXIFNGR1IFNGR2RAB11ASTX17TMEM199VMA12VPH1
Complex memberships
Vma12p/Vma22p ER assembly complex

Evidence

Reading pass · 12 per-paper findings extracted from the source corpus
Year Finding Method Journal Conf PMIDs
1995 Vma22p (yeast ortholog of VMA22/CCDC115) is a 21-kDa hydrophilic protein associated with ER membranes that is required for V-ATPase assembly; in vma22Δ cells, V1 subunits accumulate in the cytosol and the V0 100-kDa subunit (Vph1p) is rapidly degraded in the ER. Vma22p ER association requires Vma12p. Genetic deletion, subcellular fractionation, pulse-chase degradation assay, membrane association studies The Journal of biological chemistry High 7673216
1998 Vma12p and Vma22p form a stable membrane-associated complex in the ER, demonstrated by co-fractionation on density gradients and chemical cross-linking. This Vma12p/Vma22p complex directly and transiently interacts with the V0 subunit Vph1p (half-life ~5 min) to facilitate its assembly; when ER-to-Golgi transport is blocked (sec12 mutant), the Vph1p–Vma12p/Vma22p interaction stabilizes. This represents the first dedicated assembly complex in the ER for an integral membrane protein complex. Subcellular fractionation, chemical cross-linking, density gradient sedimentation, genetic epistasis with sec12 mutant The Journal of cell biology High 9660861
1993 vma22 deletion mutants in yeast are defective in vacuolar ATPase enzyme activity, establishing VMA22 as essential for V-ATPase function; identified in a genetic screen based on inability to grow at neutral pH. Genetic screen, complementation analysis, V-ATPase enzyme activity assay The Journal of biological chemistry Medium 8416931
2016 Human CCDC115 (VMA22 ortholog) localizes primarily to the ERGIC and COPI vesicles (not the ER), distinct from yeast Vma22p. Loss-of-function mutations in CCDC115 in patients cause abnormal N- and O-glycosylation, and defective sialic acid metabolic labeling in fibroblasts is restored by complementation with wild-type CCDC115, indicating CCDC115 is required for Golgi homeostasis and glycosylation. Immunofluorescence localization, exome sequencing of patients, metabolic labeling of sialic acids, complementation assay in fibroblasts American journal of human genetics High 26833332
2017 CCDC115 functions as a V-ATPase assembly factor; genetic disruption of CCDC115 (or TMEM199) stabilizes HIF1α under aerobic conditions not by preventing lysosomal degradation of HIF1α but by causing intracellular iron depletion, which impairs PHD prolyl hydroxylase activity. Iron supplementation directly restores PHD catalytic activity after V-ATPase disruption. Genome-wide genetic screen in near-haploid human cells, iron supplementation rescue, HIF1α stabilization assay, PHD activity measurement eLife High 28296633
2020 CCDC115 and TMEM199 are required for viral entry of influenza A virus and regulation of V-type ATPase assembly, validated in a genome-wide CRISPR screen. Genome-wide CRISPR/Cas9 screen, functional validation of viral entry Nature communications Medium 31919360
2020 CCDC115 is required for transferrin-bound iron (TBI) uptake in human erythroid cells; CCDC115-deficient K562 cells show reduced TBI uptake. CCDC115 is also involved in cellular heme distribution, suggesting a role in endocytic vesicle acidification via its V-ATPase assembly function. Genome-wide CRISPR screen in human erythroid cells, validation in CCDC115-deficient K562 cells, TBI uptake assay American journal of hematology Medium 32510613
2021 Silencing CCDC115 (or TMEM199) in HepG2 hepatocytes causes impaired lysosomal acidification, impaired autophagic capacity, increased lipid droplet accumulation with abnormally large lipid droplets colocalizing with lysosomes, and increased apolipoprotein B secretion, indicating CCDC115 is required for lysosomal function and lipophagy. siRNA knockdown in HepG2 cells, lysosomal acidification assay, autophagy flux assay, lipid droplet imaging and colocalization, apoB secretion measurement Cellular and molecular gastroenterology and hepatology Medium 34626841
2023 CCDC115 interacts with the HOPS complex and competes with STX17 for this interaction, thereby inhibiting autophagosome–lysosome fusion. Through this mechanism, CCDC115 inhibits autophagic degradation of YAP (yes-associated protein), promoting cell proliferation under nutrient starvation. Co-immunoprecipitation, autophagy flux assay, YAP degradation assay, cell proliferation assay under starvation FEBS letters Medium 36650560
2025 CCDC115 interacts with IFNGR1/2 and its partner TMEM199, facilitating trafficking of IFN-γ receptors to RAB11A-positive recycling endosomes. CCDC115/TMEM199 also recruits TRAPP II to recycling endosomes and activates RAB11A, enhancing IFNGR1/2 recycling and downstream JAK-STAT signaling leading to PD-L1 upregulation. Co-immunoprecipitation, receptor trafficking assay, RAB11A activation assay, TRAPP II recruitment assay, PD-L1 expression assay Cancer letters Medium 41319859
2020 Swine CCDC115 physically interacts with classical swine fever virus structural glycoprotein E2 during virus replication, as shown by proximity ligation assay. Disruption of this interaction via mutations in E2 reduces viral replication in macrophages and attenuates virulence in swine. Yeast two-hybrid, proximity ligation assay, recombinant virus with E2 mutations, viral replication assay Viruses Low 32244508
2006 Synthetic genetic interactions between erv46Δ and vma22Δ (along with vma12Δ and vma21Δ) in yeast were identified, placing VMA22 in a functional relationship with ER-to-Golgi transport machinery. Synthetic Genetic Array (SGA) screen for genetic interactions Journal of cell science Low 17077122

Source papers

Stage 0 corpus · 26 papers · ranked by NIH iCite citations
Year Title Journal Citations PMID
2020 Genome-wide CRISPR screen identifies host dependency factors for influenza A virus infection. Nature communications 175 31919360
1993 Isolation of vacuolar membrane H(+)-ATPase-deficient yeast mutants; the VMA5 and VMA4 genes are essential for assembly and activity of the vacuolar H(+)-ATPase. The Journal of biological chemistry 112 8416931
1998 Assembly of the yeast vacuolar H+-ATPase occurs in the endoplasmic reticulum and requires a Vma12p/Vma22p assembly complex. The Journal of cell biology 85 9660861
2016 CCDC115 Deficiency Causes a Disorder of Golgi Homeostasis with Abnormal Protein Glycosylation. American journal of human genetics 84 26833332
2017 The vacuolar-ATPase complex and assembly factors, TMEM199 and CCDC115, control HIF1α prolyl hydroxylation by regulating cellular iron levels. eLife 83 28296633
2002 Systematic identification of the genes affecting glycogen storage in the yeast Saccharomyces cerevisiae: implication of the vacuole as a determinant of glycogen level. Molecular & cellular proteomics : MCP 80 12096123
2024 Analysis of somatic mutations in whole blood from 200,618 individuals identifies pervasive positive selection and novel drivers of clonal hematopoiesis. Nature genetics 68 38744975
1995 Vma22p is a novel endoplasmic reticulum-associated protein required for assembly of the yeast vacuolar H(+)-ATPase complex. The Journal of biological chemistry 59 7673216
2018 Clinical glycomics for the diagnosis of congenital disorders of glycosylation. Journal of inherited metabolic disease 48 29497882
2017 A Population-Based Study on Congenital Disorders of Protein N- and Combined with O-Glycosylation Experience in Clinical and Genetic Diagnosis. The Journal of pediatrics 29 28139241
2020 Genetics of Wilson disease and Wilson-like phenotype in a clinical series from eastern Spain. Clinical genetics 26 32043565
2021 Defective Lipid Droplet-Lysosome Interaction Causes Fatty Liver Disease as Evidenced by Human Mutations in TMEM199 and CCDC115. Cellular and molecular gastroenterology and hepatology 23 34626841
2006 Genetic and molecular interactions of the Erv41p-Erv46p complex involved in transport between the endoplasmic reticulum and Golgi complex. Journal of cell science 19 17077122
2020 Serum bikunin isoforms in congenital disorders of glycosylation and linkeropathies. Journal of inherited metabolic disease 15 32700771
2020 Congenital Disorders of Glycosylation in Portugal-Two Decades of Experience. The Journal of pediatrics 14 33340551
2018 Modifier locus mapping of a transgenic F2 mouse population identifies CCDC115 as a novel aggressive prostate cancer modifier gene in humans. BMC genomics 13 29890952
2020 Genetic screens reveal CCDC115 as a modulator of erythroid iron and heme trafficking. American journal of hematology 12 32510613
2020 Swine Host Protein Coiled-Coil Domain-Containing 115 (CCDC115) Interacts with Classical Swine Fever Virus Structural Glycoprotein E2 during Virus Replication. Viruses 11 32244508
2010 Regulation of cell proliferation and apoptosis in neuroblastoma cells by ccp1, a FGF2 downstream gene. BMC cancer 9 21118521
2005 Construction of Saccharomyces cerevisiae strain FAV20 useful in detection of immunosuppressants produced by soil actinomycetes. Journal of microbiological methods 7 15676204
2024 Genome-wide comparative analysis reveals selection signatures for reproduction traits in prolific Suffolk sheep. Frontiers in genetics 6 38911299
2025 Genomic modifiers of neurological resilience in a Niemann-Pick C family. FEBS letters 1 40504793
2025 TMEM199 promotes PD-L1 expression and tumor immune evasion by activating the recycling of IFNGR1/2. Cancer letters 1 41319859
2023 CCDC115 inhibits autophagy-mediated degradation of YAP to promote cell proliferation. FEBS letters 1 36650560
2025 Research on iron regulatory erythroid factors in children with β-thalassemia. Journal of investigative medicine : the official publication of the American Federation for Clinical Research 0 40103337
2025 A systematic study of regulating inorganic polyphosphates production in Saccharomyces cerevisiae. Synthetic and systems biotechnology 0 40291979

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