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CDC42

January 01, 1970

Cell division control protein 42 homolog (Cdc42 or CDC42) is a protein that in humans is encoded by the CDC42 gene. Cdc42 is involved in regulation of the cell cycle. It was originally identified in S. cerevisiae (yeast) as a mediator of cell division,[3][4] and is now known to influence a variety of signaling events and cellular processes in a variety of organisms from yeast to mammals.

CDC42
Available structures
PDBHuman UniProt search: PDBe RCSB
Identifiers
AliasesCDC42, CDC42Hs, G25K, TKS, cell division cycle 42
External IDsOMIM: 116952 HomoloGene: 123986 GeneCards: CDC42
Orthologs
SpeciesHumanMouse
Entrez

998

n/a

Ensembl

ENSG00000070831

n/a

UniProt

P60953

n/a

RefSeq (mRNA)

NM_044472
NM_001039802
NM_001791

n/a

RefSeq (protein)

NP_001034891
NP_001782
NP_426359

n/a

Location (UCSC)Chr 1: 22.05 – 22.1 Mbn/a
PubMed search[2]n/a
Wikidata
View/Edit Human

Function edit

Human Cdc42 is a small GTPase of the Rho family, which regulates signaling pathways that control diverse cellular functions including cell morphology, cell migration, endocytosis and cell cycle progression.[5] Rho GTPases are central to dynamic actin cytoskeletal assembly and rearrangement that are the basis of cell-cell adhesion and migration. Activated Cdc42 activates by causing conformational changes[6] in p21-activated kinases PAK1 and PAK2, which in turn initiate actin reorganization and regulate cell adhesion, migration, and invasion.[7]

Structure edit

Cdc42 is a homodimer with A and B chains.[8] Its total length is 191 amino acids and its theoretical weight is 21.33 kDa.[8] Its sequence domains include a P-loop containing nucleoside triphosphate hydrolase and a small GTP-binding protein domain.[8]

Cdc42 cycles between an active GTP-bound state and an inactive GDP-bound state. This process is regulated by guanine nucleotide exchange factors (GEFs) which promote the exchange of bound GDP for free GTP, GTPase activating proteins (GAPs) which increase GTP hydrolysis activity, and GDP dissociation inhibitors which inhibit the dissociation of the nucleotide from the GTPase.[9]

Role in cancer edit

Recently, Cdc42 has been shown to actively assist in cancer progression. Several studies have established the basis for this and hypothesized about the underlying mechanisms.

Cdc42 is overexpressed in non-small cell lung cancer, colorectal adenocarcinoma, melanoma, breast cancer, and testicular cancer.[10] Elevated levels of the protein have been correlated with negative patient survival. Cdc42 has also been shown to be required for both G1-S phase progression and mitosis, and it also modulates the transcription factors SRF, STAT3, and NFkB.[10] It has been hypothesized that targeting Cdc42 in conjunction with chemotherapy may be an effective cancer treatment strategy.

In one study studying the role of Cdc42 in cervical cancer, immunohistochemistry was used to detect Cdc42 expression in three types of tissues: normal cervical tissues, cervical intraepithelial neoplasia (CIN) I or below, CIN II or above, and cervical cancer tissues.[11] Cdc42 expression was gradually increased showing significant difference and was significantly higher in HeLa cells than in regular cells. The migration ability of HeLa cells transfected with Cdc42 was higher than that of non-transfected cells.[11] It was proposed that the overexpression of Cdc42 can promote filopodia formation in HeLa cells. Cdc42 overexpression significantly improved the ability of cervical cancer cells to migrate, possibly due to improved pseudopodia formation.[11]

Another study found that Cdc42 drives the process of initiating a metastatic tumor in a new tissue by promoting the expression of β1 integrin, an adhesion receptor known to be involved in metastasis.[12] Levels of β1 integrin were reduced in Cdc42-deficient cells. β1 integrin is important for adhesion to the extracellular matrix, and could be important for the initial attachment to endothelial cells as well. Knocking down β1 integrin inhibited cancer cell migration, whereas overexpressing the integrin in Cdc42-deficient cells restored endothelial invasion.[12] Cdc42 promoted β1 integrin expression by activating a transcription factor called SRF. A continually active form of the transcription factor was also capable of restoring endothelial insertion to cancer cells lacking Cdc42.

Normal cancer cells and Cdc42-deficient cancer cells have also been compared in vivo. When both types of cells were injected into mouse tail veins, control cells spread out more on the vessel endothelium within minutes, suggesting that Cdc42 assists in cell migration.[12] After six weeks, the control cells had generated more metastases than the Cdc42-deficient cells. Invading cancer cells send out protrusions that reach down between neighboring endothelial cells to contact the underlying basement membrane. The cancer cells then spread out on this extracellular matrix so that the endothelial cells retract, and allow the invaders to insert themselves between them.[12] In the absence of Cdc42, cancer cells failed to spread out on the basement membrane, and Cdc42-deficient cells showed reduced adhesion to extracellular matrix-coated coverslips.[12] Cdc42 therefore promotes the attachment of cancer cells to both endothelial cells and the underlying basement membrane during transendothelial migration.

The small molecular inhibitor AZA197 has been used to inhibit Cdc42 in the treatment of KRAS mutant colorectal cancers.[13] There was evidence that Cdc42 inhibition by AZA197 treatment suppresses proliferative and pro-survival signaling pathways via PAK1-ERK signaling and reduces colon cancer cell migration and invasion.[13] In mice, systemic AZA197 treatment in vivo reduced primary tumor growth and prolonged survival.[13] Therapy targeting Rho GTPase Cdc42 signaling pathways may be effective for treatment of patients with advanced colon cancer overexpressing Cdc42, and particularly those with KRAS-mutant disease.

Takenouchi-Kosaki syndrome edit

Mutations in the CDC42 gene are responsible for the Takenouchi-Kosaki syndrome, an autosomal-dominant complex congenital developmental disorder associated with thrombocytopenia.[14] Alleic variants that are associated with the syndrome include mutations in the CDC42 gene that are expressed at the protein level as Ile21Thr, Tyr64Cys, Arg66Gly, Cys81Phe, Ser83Pro, or Glu171Lys.[15]

Interactions edit

CDC42 has been shown to interact with:

See also edit

References edit

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External links edit

 
Wikimedia Commons has media related to CDC42.

January 01, 1970
cdc42, cell, division, control, protein, homolog, cdc42, protein, that, humans, encoded, gene, cdc42, involved, regulation, cell, cycle, originally, identified, cerevisiae, yeast, mediator, cell, division, known, influence, variety, signaling, events, cellular. Cell division control protein 42 homolog Cdc42 or CDC42 is a protein that in humans is encoded by the CDC42 gene Cdc42 is involved in regulation of the cell cycle It was originally identified in S cerevisiae yeast as a mediator of cell division 3 4 and is now known to influence a variety of signaling events and cellular processes in a variety of organisms from yeast to mammals CDC42Available structuresPDBHuman UniProt search PDBe RCSBList of PDB id codes4YDH 1A4R 1AJE 1AM4 1AN0 1CEE 1CF4 1DOA 1E0A 1EES 1GRN 1GZS 1KI1 1KZ7 1KZG 1NF3 2ASE 2DFK 2KB0 2NGR 2ODB 2QRZ 2WM9 2WMN 2WMO 3GCG 3QBV 3VHL 4DID 4ITR 4JS0 4YC7 5FI1IdentifiersAliasesCDC42 CDC42Hs G25K TKS cell division cycle 42External IDsOMIM 116952 HomoloGene 123986 GeneCards CDC42Gene location Human Chr Chromosome 1 human 1 Band1p36 12Start22 052 627 bp 1 End22 101 360 bp 1 RNA expression patternBgeeHumanMouse ortholog Top expressed inmonocyteislet of Langerhansrectumganglionic eminencegallbladdersmooth muscle tissueAchilles tendonstromal cell of endometriumlymph nodeBrodmann area 23n aMore reference expression dataBioGPSMore reference expression dataGene ontologyMolecular functionRho GDP dissociation inhibitor binding ubiquitin protein ligase activity apolipoprotein A I receptor binding GTP dependent protein binding GTPase activity mitogen activated protein kinase kinase kinase binding protein binding thioesterase binding protein kinase binding nucleotide binding GTP binding identical protein binding protein serine threonine kinase activity GBD domain bindingCellular componentcytoplasm cytosol membrane cell cell junction focal adhesion microtubule organizing center spindle midzone neuron projection storage vacuole cytoskeleton cell projection myelin sheath extracellular exosome filopodium plasma membrane spindle apical part of cell secretory granule neuronal cell body cytoplasmic ribonucleoprotein granule mitotic spindle leading edge membrane cell periphery endoplasmic reticulum membrane Golgi membrane midbody centrosome cell cortex Golgi transport complex protein containing complex dendritic spineBiological processcardiac conduction system development positive regulation of protein phosphorylation negative regulation of epidermal growth factor receptor signaling pathway positive regulation of muscle cell differentiation nuclear migration keratinization positive regulation of JNK cascade establishment of Golgi localization actin filament bundle assembly positive regulation of neuron apoptotic process vascular endothelial growth factor receptor signaling pathway hair follicle morphogenesis heart contraction regulation of protein stability neuron fate determination substantia nigra development Fc gamma receptor signaling pathway involved in phagocytosis actin filament organization negative regulation of protein containing complex assembly epithelial mesenchymal cell signaling actin filament branching negative regulation of gene expression positive regulation of peptidyl serine phosphorylation establishment or maintenance of cell polarity positive regulation of cell growth regulation of protein metabolic process establishment or maintenance of apical basal cell polarity regulation of protein kinase activity regulation of attachment of spindle microtubules to kinetochore regulation of small GTPase mediated signal transduction positive regulation of hair follicle cell proliferation positive regulation of MAPK cascade regulation of mitotic nuclear division hair follicle placode formation positive regulation of intracellular protein transport cell differentiation positive regulation of epithelial cell proliferation involved in lung morphogenesis regulation of protein heterodimerization activity Golgi organization positive regulation of synapse structural plasticity multicellular organism growth epidermis morphogenesis nucleus localization epithelial cell cell adhesion sprouting angiogenesis nervous system development macrophage differentiation dendritic cell migration positive regulation of cytokinesis positive regulation of DNA replication Wnt signaling pathway planar cell polarity pathway keratinocyte development regulation of protein catabolic process canonical Wnt signaling pathway adherens junction organization organelle transport along microtubule actin cytoskeleton organization regulation of filopodium assembly endocytosis ephrin receptor signaling pathway filopodium assembly T cell costimulation blood coagulation positive regulation of phosphatidylinositol 3 kinase activity positive regulation of substrate adhesion dependent cell spreading positive regulation of gene expression positive regulation of pseudopodium assembly submandibular salivary gland formation viral RNA genome replication small GTPase mediated signal transduction protein ubiquitination positive regulation of catalytic activity protein phosphorylation phagocytosis engulfment integrin mediated signaling pathway Rho protein signal transduction regulation of cell shape regulation of lamellipodium assembly positive regulation of lamellipodium assembly cell projection assembly Cdc42 protein signal transduction regulation of actin cytoskeleton organization cell junction assembly interleukin 12 mediated signaling pathway neuropilin signaling pathway establishment of epithelial cell apical basal polarity positive regulation of filopodium assembly regulation of stress fiber assembly positive regulation of stress fiber assembly dendritic spine morphogenesis modification of synaptic structure positive regulation of actin cytoskeleton reorganizationSources Amigo QuickGOOrthologsSpeciesHumanMouseEntrez998n aEnsemblENSG00000070831n aUniProtP60953n aRefSeq mRNA NM 044472NM 001039802NM 001791n aRefSeq protein NP 001034891NP 001782NP 426359n aLocation UCSC Chr 1 22 05 22 1 Mbn aPubMed search 2 n aWikidataView Edit Human Contents 1 Function 2 Structure 3 Role in cancer 4 Takenouchi Kosaki syndrome 5 Interactions 6 See also 7 References 8 External linksFunction editHuman Cdc42 is a small GTPase of the Rho family which regulates signaling pathways that control diverse cellular functions including cell morphology cell migration endocytosis and cell cycle progression 5 Rho GTPases are central to dynamic actin cytoskeletal assembly and rearrangement that are the basis of cell cell adhesion and migration Activated Cdc42 activates by causing conformational changes 6 in p21 activated kinases PAK1 and PAK2 which in turn initiate actin reorganization and regulate cell adhesion migration and invasion 7 Structure editCdc42 is a homodimer with A and B chains 8 Its total length is 191 amino acids and its theoretical weight is 21 33 kDa 8 Its sequence domains include a P loop containing nucleoside triphosphate hydrolase and a small GTP binding protein domain 8 Cdc42 cycles between an active GTP bound state and an inactive GDP bound state This process is regulated by guanine nucleotide exchange factors GEFs which promote the exchange of bound GDP for free GTP GTPase activating proteins GAPs which increase GTP hydrolysis activity and GDP dissociation inhibitors which inhibit the dissociation of the nucleotide from the GTPase 9 Role in cancer editRecently Cdc42 has been shown to actively assist in cancer progression Several studies have established the basis for this and hypothesized about the underlying mechanisms Cdc42 is overexpressed in non small cell lung cancer colorectal adenocarcinoma melanoma breast cancer and testicular cancer 10 Elevated levels of the protein have been correlated with negative patient survival Cdc42 has also been shown to be required for both G1 S phase progression and mitosis and it also modulates the transcription factors SRF STAT3 and NFkB 10 It has been hypothesized that targeting Cdc42 in conjunction with chemotherapy may be an effective cancer treatment strategy In one study studying the role of Cdc42 in cervical cancer immunohistochemistry was used to detect Cdc42 expression in three types of tissues normal cervical tissues cervical intraepithelial neoplasia CIN I or below CIN II or above and cervical cancer tissues 11 Cdc42 expression was gradually increased showing significant difference and was significantly higher in HeLa cells than in regular cells The migration ability of HeLa cells transfected with Cdc42 was higher than that of non transfected cells 11 It was proposed that the overexpression of Cdc42 can promote filopodia formation in HeLa cells Cdc42 overexpression significantly improved the ability of cervical cancer cells to migrate possibly due to improved pseudopodia formation 11 Another study found that Cdc42 drives the process of initiating a metastatic tumor in a new tissue by promoting the expression of b1 integrin an adhesion receptor known to be involved in metastasis 12 Levels of b1 integrin were reduced in Cdc42 deficient cells b1 integrin is important for adhesion to the extracellular matrix and could be important for the initial attachment to endothelial cells as well Knocking down b1 integrin inhibited cancer cell migration whereas overexpressing the integrin in Cdc42 deficient cells restored endothelial invasion 12 Cdc42 promoted b1 integrin expression by activating a transcription factor called SRF A continually active form of the transcription factor was also capable of restoring endothelial insertion to cancer cells lacking Cdc42 Normal cancer cells and Cdc42 deficient cancer cells have also been compared in vivo When both types of cells were injected into mouse tail veins control cells spread out more on the vessel endothelium within minutes suggesting that Cdc42 assists in cell migration 12 After six weeks the control cells had generated more metastases than the Cdc42 deficient cells Invading cancer cells send out protrusions that reach down between neighboring endothelial cells to contact the underlying basement membrane The cancer cells then spread out on this extracellular matrix so that the endothelial cells retract and allow the invaders to insert themselves between them 12 In the absence of Cdc42 cancer cells failed to spread out on the basement membrane and Cdc42 deficient cells showed reduced adhesion to extracellular matrix coated coverslips 12 Cdc42 therefore promotes the attachment of cancer cells to both endothelial cells and the underlying basement membrane during transendothelial migration The small molecular inhibitor AZA197 has been used to inhibit Cdc42 in the treatment of KRAS mutant colorectal cancers 13 There was evidence that Cdc42 inhibition by AZA197 treatment suppresses proliferative and pro survival signaling pathways via PAK1 ERK signaling and reduces colon cancer cell migration and invasion 13 In mice systemic AZA197 treatment in vivo reduced primary tumor growth and prolonged survival 13 Therapy targeting Rho GTPase Cdc42 signaling pathways may be effective for treatment of patients with advanced colon cancer overexpressing Cdc42 and particularly those with KRAS mutant disease Takenouchi Kosaki syndrome editMutations in the CDC42 gene are responsible for the Takenouchi Kosaki syndrome an autosomal dominant complex congenital developmental disorder associated with thrombocytopenia 14 Alleic variants that are associated with the syndrome include mutations in the CDC42 gene that are expressed at the protein level as Ile21Thr Tyr64Cys Arg66Gly Cys81Phe Ser83Pro or Glu171Lys 15 Interactions editCDC42 has been shown to interact with ARHGAP1 16 17 18 19 ARHGDIA 20 21 BAIAP2 22 23 24 BNIP2 18 25 26 BNIPL 27 CDC42EP2 28 29 CDC42EP3 28 30 ERRFI1 31 GDI1 32 IQGAP1 19 33 34 35 36 IQGAP2 37 ITSN1 38 39 MAP3K10 16 MAP3K11 16 40 PAK1 19 41 PAK2 19 42 43 PAK4 20 43 44 PAK7 44 45 PARD6A 46 47 48 PARD6B 46 47 49 Phospholipase D1 50 RICS 51 52 53 TRIP10 54 55 WASL 56 57 Wiskott Aldrich syndrome protein 55 58 59 60 See also editROP GTPaseReferences edit a b c GRCh38 Ensembl release 89 ENSG00000070831 Ensembl May 2017 Human PubMed Reference National Center for Biotechnology Information U S National Library of Medicine Adams AE Johnson DI Longnecker RM Sloat BF Pringle JR July 1990 CDC42 and CDC43 two additional genes involved in budding and the establishment of cell polarity in the yeast Saccharomyces cerevisiae The Journal of Cell Biology 111 1 131 142 doi 10 1083 jcb 111 1 131 PMC 2116161 PMID 2195038 Johnson DI Pringle JR July 1990 Molecular characterization of CDC42 a Saccharomyces cerevisiae gene involved in the development of cell polarity The Journal of Cell Biology 111 1 143 152 doi 10 1083 jcb 111 1 143 PMC 2116164 PMID 2164028 Qadir MI Parveen A Ali M October 2015 Cdc42 Role in Cancer Management Chemical Biology amp Drug Design 86 4 432 9 doi 10 1111 cbdd 12556 PMID 25777055 S2CID 33006765 Bishop AL Hall A June 2000 Rho GTPases and their effector proteins The Biochemical Journal 348 2 241 255 doi 10 1042 bj3480241 PMC 1221060 PMID 10816416 Guo Y Kenney SR Muller CY Adams S Rutledge T Romero E Murray Krezan C Prekeris R Sklar LA Hudson LG Wandinger Ness A October 2015 R Ketorolac Targets Cdc42 and Rac1 and Alters Ovarian Cancer Cell Behaviors Critical for Invasion and Metastasis Molecular Cancer Therapeutics 14 10 2215 27 doi 10 1158 1535 7163 MCT 15 0419 PMC 4596774 PMID 26206334 a b c PDB 1a4r structure summary Protein Data Bank in Europe EMBL EBI Retrieved 2016 04 22 CDC42 cell division cycle 42 GTP binding protein 25kDa atlasgeneticsoncology org Archived from the original on 2016 03 31 Retrieved 2016 04 22 a b Stengel K Zheng Y September 2011 Cdc42 in oncogenic transformation invasion and tumorigenesis Cellular Signalling 23 9 1415 23 doi 10 1016 j cellsig 2011 04 001 PMC 3115433 PMID 21515363 a b c Ye H Zhang Y Geng L Li Z February 2015 Cdc42 expression in cervical cancer and its effects on cervical tumor invasion and migration International Journal of Oncology 46 2 757 63 doi 10 3892 ijo 2014 2748 PMID 25394485 a b c d e Wilson JM Menkhaus P Gustin BW May 1987 Volume and outcome of coronary artery bypass graft surgery JAMA 257 18 2434 5 doi 10 1001 jama 1987 03390180052010 PMID 3494856 a b c Zins K Gunawardhana S Lucas T Abraham D Aharinejad S 2013 01 01 Targeting Cdc42 with the small molecule drug AZA197 suppresses primary colon cancer growth and prolongs survival in a preclinical mouse xenograft model by downregulation of PAK1 activity Journal of Translational Medicine 11 295 doi 10 1186 1479 5876 11 295 PMC 4222769 PMID 24279335 Santoro C Gaudino G Torella A Piluso G Perrotta S Miraglia Del Giudice E Nigro V Grandone A December 2021 Intermittent macrothrombocytopenia in a novel patient with Takenouchi Kosaki syndrome and review of literature European Journal of Medical Genetics 64 12 104358 doi 10 1016 j ejmg 2021 104358 PMID 34624555 S2CID 238529349 CDC42 Allelic Variants Online Mendelian Inheritance in Man OMIM a b c Nagata K Puls A Futter C Aspenstrom P Schaefer E Nakata T Hirokawa N Hall A January 1998 The MAP kinase kinase kinase MLK2 co localizes with activated JNK along microtubules and associates 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1996PNAS 93 5615K doi 10 1073 pnas 93 11 5615 PMC 39296 PMID 8643625 Symons M Derry JM Karlak B Jiang S Lemahieu V Mccormick F Francke U Abo A March 1996 Wiskott Aldrich syndrome protein a novel effector for the GTPase CDC42Hs is implicated in actin polymerization Cell 84 5 723 34 doi 10 1016 S0092 8674 00 81050 8 PMID 8625410 S2CID 17838931 External links edit nbsp Wikimedia Commons has media related to CDC42 cdc42 GTP Binding Protein at the U S National Library of Medicine Medical Subject Headings MeSH CDC42 Info with links in the Cell Migration Gateway Human CDC42 genome location and CDC42 gene details page in the UCSC Genome Browser Retrieved from https en wikipedia org w index php title CDC42 amp oldid 1215560838, wikipedia, wiki, book, books, library,

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