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Cyclin-dependent kinase 2

October 15, 2023

"CDK2" redirects here. For the airport with the Transport Canada identifier CDK2, see Diavik Airport.

Cyclin-dependent kinase 2, also known as cell division protein kinase 2, or Cdk2, is an enzyme that in humans is encoded by the CDK2 gene.[5][6] The protein encoded by this gene is a member of the cyclin-dependent kinase family of Ser/Thr protein kinases. This protein kinase is highly similar to the gene products of S. cerevisiae cdc28, and S. pombe cdc2, also known as Cdk1 in humans. It is a catalytic subunit of the cyclin-dependent kinase complex, whose activity is restricted to the G1-S phase of the cell cycle, where cells make proteins necessary for mitosis and replicate their DNA. This protein associates with and is regulated by the regulatory subunits of the complex including cyclin E or A. Cyclin E binds G1 phase Cdk2, which is required for the transition from G1 to S phase while binding with Cyclin A is required to progress through the S phase.[7] Its activity is also regulated by phosphorylation. Multiple alternatively spliced variants and multiple transcription initiation sites of this gene have been reported.[8] The role of this protein in G1-S transition has been recently questioned as cells lacking Cdk2 are reported to have no problem during this transition.[9]

CDK2
Available structures
PDBOrtholog search: PDBe RCSB
Identifiers
AliasesCDK2, cyclin-dependent kinase 2, A630093N05Rik, CDKN2, p33(CDK2), cyclin dependent kinase 2
External IDsOMIM: 116953 MGI: 104772 HomoloGene: 74409 GeneCards: CDK2
Orthologs
SpeciesHumanMouse
Entrez

1017

12566

Ensembl

ENSG00000123374

ENSMUSG00000025358

UniProt

P24941

P97377

RefSeq (mRNA)

NM_001290230
NM_001798
NM_052827

NM_016756
NM_183417

RefSeq (protein)

NP_001277159
NP_001789
NP_439892

NP_058036
NP_904326

Location (UCSC)Chr 12: 55.97 – 55.97 MbChr 10: 128.53 – 128.54 Mb
PubMed search[3][4]
Wikidata
View/Edit HumanView/Edit Mouse

Dispensability in normally functioning tissue Edit

Original cell-culture based experiments demonstrated cell cycle arrest at the G1-S transition resulting from the deletion of Cdk2.[10] Later experiments showed that Cdk2 deletions lengthened the G1 phase of the cell cycle in mouse embryo fibroblasts. However, they still entered S phase after this period and were able to complete the remaining phases of the cell cycle.[11] When Cdk2 was deleted in mice, the animals remained viable despite a reduction in body size. However, meiotic function of both male and female mice was inhibited. This suggests that Cdk2 is non-essential for the cell cycle of healthy cells, but essential for meiosis and reproduction.[10] Cells in Cdk2 knockout mice likely undergo fewer divisions, contributing to the reduction in body size. Germ cells also stop dividing at prophase of meiosis, leading to reproductive sterility.[11] Cdk1 is now believed to compensate for many aspects of Cdk2 deletion, except for meiotic function.[10]

Mechanism of activation Edit

Cyclin-dependent kinase 2 is structured in two lobes. The lobe beginning at the N-terminus (N-lobe) contains many beta sheets, while the C-terminus lobe (C-lobe) is rich in alpha helices.[7] Cdk2 is capable of binding to many different cyclins, including cyclins A, B, E, and possibly C.[10] Recent studies suggest Cdk2 binds preferentially to cyclins A and E, while Cdk1 prefers cyclins A and B.[12]

 
Cdk2 (blue) and its binding partner, cyclin A (red).[13]

Cdk2 becomes active when a cyclin protein (either A or E) binds at the active site located between the N and C lobes of the kinase. Due to the location of the active site, partner cyclins interact with both lobes of Cdk2. Cdk2 contains an important alpha helix located in the C lobe of the kinase, called the C-helix or the PSTAIRE-helix. Hydrophobic interactions cause the C-helix to associate with another helix in the activating cyclin. Activation induces a conformational change where the helix rotates and moves closer to the N-lobe.[citation needed] This allows the glutamic acid located on the C-helix to form an ion pair with a nearby lysine side chain. The significance of this movement is that it brings the side chain of Glu 51, which belongs to a triad of catalytic site residues conserved in all eukaryotic kinases, into the catalytic site. This triad (Lys 33, Glu 51 and Asp 145) is involved in ATP phosphate orientation and magnesium coordination, and is thought to be critical for catalysis. This conformational change also relocates the activation loop to the C-lobe, revealing the ATP binding site now available for new interactions. Finally, the Threonine-160 residue is exposed and phosphorylated as the C-lobe activation segment is displaced from the catalytic site and the threonine residue is no longer sterically hindered. The phosphorylated threonine residue creates stability in the final enzyme conformation. It is important to note that throughout this activation process, cyclins binding to Cdk2 do not undergo any conformational change.[14][7]

 
Cdk2 (blue) and its binding partner cyclin E (orange).[15]

Role in DNA replication Edit

The success of the cell division process is dependent on the precise regulation of processes at both cellular and tissue levels. Complex interactions between proteins and DNA within the cell allow genomic DNA to be passed to daughter cells. Interactions between cells and extracellular matrix proteins allow new cells to be incorporated into existing tissues. At the cellular level, the process is controlled by different levels of cyclin-dependent kinases (Cdks) and their partner cyclins. Cells utilize various checkpoints as a means of delaying cell cycle progression until it can repair defects.[16]

Cdk2 is active during G1 and S phase of the cell cycle, and therefore acts as a G1-S phase checkpoint control. Prior to G1 phase, levels of Cdk4 and Cdk6 increase along with cyclin D. This allows for the partial phosphorylation of Rb, and partial activation of E2F at the beginning of G1 phase, which promotes cyclin E synthesis and increased Cdk2 activity. At the end of G1 phase, the Cdk2/Cyclin E complex reaches maximum activity and plays a significant role in the initiation of S phase.[17] Other non-Cdk proteins also become active during the G1-S phase transition. For example, the retinoblastoma (Rb) and p27 proteins are phosphorylated by Cdk2 – cyclin A/E complexes, fully deactivating them.[18] This allows E2F transcription factors to express genes that promote entry into S phase where DNA is replicated prior to division.[19][20][18] Additionally, NPAT, a known substrate of the Cdk2-Cyclin E complex, functions to activate histone gene transcription when phosphorylated.[21] This increases the synthesis of histone proteins (the major protein component of chromatin), and subsequently supports the DNA replication stage of the cell cycle. Finally, at the end of S phase, the ubiquitin proteasome degrades cyclin E.[11]

Cancer cell proliferation Edit

Although Cdk2 is mostly dispensable in the cell cycle of normally functioning cells, it is critical to the abnormal growth processes of cancer cells. The CCNE1 gene produces cyclin E, one of the two major protein binding partners of Cdk2. Overexpression of CCNE1 occurs in many tumor cells, causing the cells to become dependent on Cdk2 and cyclin E.[12] Abnormal cyclin E activity is also observed in breast, lung, colorectal, gastric, and bone cancers, as well as in leukemia and lymphoma.[17] Likewise, abnormal expression of cyclin A2 is associated with chromosomal instability and tumor proliferation, while inhibition leads to decreased tumor growth.[22] Therefore, CDK2 and its cyclin binding partners represent possible therapeutic targets for new cancer therapeutics.[12] Pre-clinical models have shown preliminary success in limiting tumor growth, and have also been observed to reduce side effects of current chemotherapy drugs.[23][24][25]

Identifying selective Cdk2 inhibitors is difficult due to the extreme similarity between the active sites of Cdk2 and other Cdks, especially Cdk1.[12] Cdk1 is the only essential cyclin dependent kinase in the cell cycle, and inhibition could lead to unintended side effects.[26] Most CDK2 inhibitor candidates target the ATP binding site and can be divided into two main subclasses: type I and type II. Type I inhibitors competitively target the ATP binding site in its active state. Type II inhibitors target CDK2 in its unbound state, either occupying the ATP binding site or hydrophobic pocket within the kinase. Type II inhibitors are believed to be more selective.[24] Recently, the availability of new CDK crystal structures led to the identification of a potential allosteric binding site near the C-helix. Inhibitors of this allosteric site are classified as type III inhibitors.[27] Another possible target is the T-loop of CDK2. When cyclin A binds to CDK2, the N-terminal lobe rotates to activate the ATP binding site and switch the position of the activation loop, called the T-loop.[28]

Inhibitors Edit

Interpretation of dynamic simulations and binding free energy studies unveiled that Ligand2 (Out of 17 in-house synthesized pyrrolone-fused benzosuberene (PBS) compounds) has a stable and equivalent free energy to Flavopiridol, SU9516, and CVT-313 inhibitors. Ligand2 scrutinized as a selective inhibitor of CDK2 without off-target binding (CDK1 and CDK9) based on ligand efficiency and binding affinity. [29]

 
Graphical abstract of CDK2 [29]


Known CDK inhibitors are p21Cip1 (CDKN1A) and p27Kip1 (CDKN1B).[30]

Drugs that inhibit Cdk2 and arrest the cell cycle, such as GW8510 and the experimental cancer drug seliciclib, may reduce the sensitivity of the epithelium to many cell cycle-active antitumor agents and, therefore, represent a strategy for prevention of chemotherapy-induced alopecia.[31]

Rosmarinic acid methyl ester is a plant-derived Cdk2 inhibitor, which was shown to suppress proliferation of vascular smooth muscle cells and to reduce neointima formation in mouse restenosis model.[32]

See also the PDB gallery below showing interactions with many inhibitors (inc Purvalanol B)

Gene regulation Edit

In melanocytic cell types, expression of the CDK2 gene is regulated by the Microphthalmia-associated transcription factor.[33][34]

Interactions Edit

Cyclin-dependent kinase 2 has been shown to interact with:

 
Overview of signal transduction pathways involved in apoptosis.

References Edit

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Further reading Edit

  • Kaldis P, Aleem E (November 2005). "Cell cycle sibling rivalry: Cdc2 vs. Cdk2". Cell Cycle. 4 (11): 1491–4. doi:10.4161/cc.4.11.2124. PMID 16258277.
  • Moore NL, Narayanan R, Weigel NL (February 2007). "Cyclin dependent kinase 2 and the regulation of human progesterone receptor activity". Steroids. 72 (2): 202–9. doi:10.1016/j.steroids.2006.11.025. PMC 1950255. PMID 17207508.

External links Edit

October 15, 2023
cyclin, dependent, kinase, cdk2, redirects, here, airport, with, transport, canada, identifier, cdk2, diavik, airport, also, known, cell, division, protein, kinase, cdk2, enzyme, that, humans, encoded, cdk2, gene, protein, encoded, this, gene, member, cyclin, . CDK2 redirects here For the airport with the Transport Canada identifier CDK2 see Diavik Airport Cyclin dependent kinase 2 also known as cell division protein kinase 2 or Cdk2 is an enzyme that in humans is encoded by the CDK2 gene 5 6 The protein encoded by this gene is a member of the cyclin dependent kinase family of Ser Thr protein kinases This protein kinase is highly similar to the gene products of S cerevisiae cdc28 and S pombe cdc2 also known as Cdk1 in humans It is a catalytic subunit of the cyclin dependent kinase complex whose activity is restricted to the G1 S phase of the cell cycle where cells make proteins necessary for mitosis and replicate their DNA This protein associates with and is regulated by the regulatory subunits of the complex including cyclin E or A Cyclin E binds G1 phase Cdk2 which is required for the transition from G1 to S phase while binding with Cyclin A is required to progress through the S phase 7 Its activity is also regulated by phosphorylation Multiple alternatively spliced variants and multiple transcription initiation sites of this gene have been reported 8 The role of this protein in G1 S transition has been recently questioned as cells lacking Cdk2 are reported to have no problem during this transition 9 CDK2Available structuresPDBOrtholog search PDBe RCSBList of PDB id codes1AQ1 1B38 1B39 1BUH 1CKP 1DI8 1DM2 1E1V 1E1X 1E9H 1F5Q 1FIN 1FQ1 1FVT 1FVV 1G5S 1GIH 1GII 1GIJ 1GY3 1GZ8 1H00 1H01 1H07 1H08 1H0V 1H0W 1H1P 1H1Q 1H1R 1H1S 1H24 1H25 1H26 1H27 1H28 1HCK 1HCL 1JST 1JSU 1JSV 1JVP 1KE5 1KE6 1KE7 1KE8 1KE9 1OGU 1OI9 1OIQ 1OIR 1OIT 1OIU 1OIY 1OKV 1OKW 1OL1 1OL2 1P2A 1P5E 1PF8 1PKD 1PW2 1PXI 1PXJ 1PXK 1PXL 1PXM 1PXN 1PXO 1PXP 1PYE 1QMZ 1R78 1URC 1URW 1V1K 1VYW 1VYZ 1W0X 1W8C 1W98 1WCC 1Y8Y 1Y91 1YKR 2A0C 2A4L 2B52 2B53 2B54 2B55 2BHE 2BHH 2BKZ 2BPM 2BTR 2BTS 2C4G 2C5N 2C5O 2C5V 2C5X 2C5Y 2C68 2C69 2C6I 2C6K 2C6L 2C6M 2C6O 2C6T 2CCH 2CCI 2CJM 2CLX 2DS1 2DUV 2EXM 2FVD 2G9X 2I40 2IW6 2IW8 2IW9 2J9M 2JGZ 2R3F 2R3G 2R3H 2R3I 2R3J 2R3K 2R3L 2R3M 2R3N 2R3O 2R3P 2R3Q 2R3R 2R64 2UUE 2UZB 2UZD 2UZE 2UZL 2UZN 2UZO 2V0D 2V22 2VTA 2VTH 2VTI 2VTJ 2VTL 2VTM 2VTN 2VTO 2VTP 2VTQ 2VTR 2VTS 2VTT 2VU3 2VV9 2W05 2W06 2W17 2W1H 2WEV 2WFY 2WHB 2WIH 2WIP 2WMA 2WMB 2WPA 2WXV 2X1N 2XMY 2XNB 3BHT 3BHU 3BHV 3DDP 3DDQ 3DOG 3EID 3EJ1 3EOC 3EZR 3EZV 3F5X 3FZ1 3IG7 3IGG 3LE6 3LFN 3LFQ 3LFS 3MY5 3NS9 3PJ8 3PXF 3PXQ 3PXR 3PXY 3PXZ 3PY0 3PY1 3QHR 3QHW 3QL8 3QQF 3QQG 3QQH 3QQJ 3QQK 3QQL 3QRT 3QRU 3QTQ 3QTR 3QTS 3QTU 3QTW 3QTX 3QTZ 3QU0 3QWJ 3QWK 3QX2 3QX4 3QXO 3QXP 3QZF 3QZG 3QZH 3QZI 3R1Q 3R1S 3R1Y 3R28 3R6X 3R71 3R73 3R7E 3R7I 3R7U 3R7V 3R7Y 3R83 3R8L 3R8M 3R8P 3R8U 3R8V 3R8Z 3R9D 3R9H 3R9N 3R9O 3RAH 3RAI 3RAK 3RAL 3RJC 3RK5 3RK7 3RK9 3RKB 3RM6 3RM7 3RMF 3RNI 3ROY 3RPO 3RPR 3RPV 3RPY 3RZB 3S00 3S0O 3S1H 3S2P 3SQQ 3SW4 3SW7 3TI1 3TIY 3TIZ 3TNW 3ULI 3UNJ 3UNK 4ACM 4BCK 4BCM 4BCN 4BCO 4BCP 4BCQ 4BGH 4EK3 4EK4 4EK5 4EK6 4EK8 4EOI 4EOJ 4EOK 4EOL 4EOM 4EON 4EOO 4EOP 4EOQ 4EOR 4EOS 4ERW 4EZ3 4EZ7 4FKG 4FKI 4FKJ 4FKL 4FKO 4FKP 4FKQ 4FKR 4FKS 4FKT 4FKU 4FKV 4FKW 4FX3 4GCJ 4I3Z 4II5 3WBL 4BZD 4CFM 4CFN 4CFU 4CFV 4CFW 4CFX 4D1X 4D1Z 4KD1 4LYN 4NJ3 4RJ3 5A14 5CYI 5D1J 5FP6 5FP5 5K4J 5IF1 5AND 5ANG 5ANI 5ANK 5ANE 5IEX 5IEV 5ANJ 5ANO 5IEYIdentifiersAliasesCDK2 cyclin dependent kinase 2 A630093N05Rik CDKN2 p33 CDK2 cyclin dependent kinase 2External IDsOMIM 116953 MGI 104772 HomoloGene 74409 GeneCards CDK2Gene location Human Chr Chromosome 12 human 1 Band12q13 2Start55 966 781 bp 1 End55 972 789 bp 1 Gene location Mouse Chr Chromosome 10 mouse 2 Band10 10 D3Start128 533 808 bp 2 End128 540 900 bp 2 RNA expression patternBgeeHumanMouse ortholog Top expressed inganglionic eminenceleft uterine tubegastric mucosastromal cell of endometriumskin of abdomenright lungplacentaupper lobe of left lungrectumappendixTop expressed inspermatocytethymusyolk sacabdominal wallmaxillary prominencedermisatriummedial ganglionic eminenceendocardial cushionrenal corpuscleMore reference expression dataBioGPSMore reference expression dataGene ontologyMolecular functiontransferase activity protein kinase activity nucleotide binding cyclin dependent protein serine threonine kinase activity histone kinase activity metal ion binding protein binding ATP binding kinase activity protein serine threonine kinase activity cyclin binding cyclin dependent protein kinase activity protein domain specific binding magnesium ion bindingCellular componentcytoplasm endosome Cajal body cyclin dependent protein kinase holoenzyme complex transcription regulator complex X chromosome Y chromosome microtubule organizing center telomere cytoskeleton condensed chromosome nucleus cytosol cyclin A1 CDK2 complex cyclin A2 CDK2 complex cyclin E1 CDK2 complex cyclin E2 CDK2 complex nucleoplasm centrosomeBiological processDNA damage response signal transduction by p53 class mediator resulting in cell cycle arrest phosphorylation centrosome duplication cellular response to DNA damage stimulus cell division positive regulation of transcription DNA templated DNA replication potassium ion transport G2 M transition of mitotic cell cycle positive regulation of DNA dependent DNA replication initiation peptidyl serine phosphorylation mitotic G1 DNA damage checkpoint signaling cell cycle cellular response to nitric oxide Ras protein signal transduction centriole replication regulation of signal transduction by p53 class mediator DNA repair negative regulation of transcription by RNA polymerase II multicellular organism development positive regulation of cell population proliferation response to organic substance regulation of G2 M transition of mitotic cell cycle protein phosphorylation meiosis G1 S transition of mitotic cell cycle anaphase promoting complex dependent catabolic processSources Amigo QuickGOOrthologsSpeciesHumanMouseEntrez101712566EnsemblENSG00000123374ENSMUSG00000025358UniProtP24941P97377RefSeq mRNA NM 001290230NM 001798NM 052827NM 016756NM 183417RefSeq protein NP 001277159NP 001789NP 439892NP 058036NP 904326Location UCSC Chr 12 55 97 55 97 MbChr 10 128 53 128 54 MbPubMed search 3 4 WikidataView Edit HumanView Edit Mouse Contents 1 Dispensability in normally functioning tissue 2 Mechanism of activation 3 Role in DNA replication 4 Cancer cell proliferation 5 Inhibitors 6 Gene regulation 7 Interactions 8 References 9 Further reading 10 External linksDispensability in normally functioning tissue EditOriginal cell culture based experiments demonstrated cell cycle arrest at the G1 S transition resulting from the deletion of Cdk2 10 Later experiments showed that Cdk2 deletions lengthened the G1 phase of the cell cycle in mouse embryo fibroblasts However they still entered S phase after this period and were able to complete the remaining phases of the cell cycle 11 When Cdk2 was deleted in mice the animals remained viable despite a reduction in body size However meiotic function of both male and female mice was inhibited This suggests that Cdk2 is non essential for the cell cycle of healthy cells but essential for meiosis and reproduction 10 Cells in Cdk2 knockout mice likely undergo fewer divisions contributing to the reduction in body size Germ cells also stop dividing at prophase of meiosis leading to reproductive sterility 11 Cdk1 is now believed to compensate for many aspects of Cdk2 deletion except for meiotic function 10 Mechanism of activation EditCyclin dependent kinase 2 is structured in two lobes The lobe beginning at the N terminus N lobe contains many beta sheets while the C terminus lobe C lobe is rich in alpha helices 7 Cdk2 is capable of binding to many different cyclins including cyclins A B E and possibly C 10 Recent studies suggest Cdk2 binds preferentially to cyclins A and E while Cdk1 prefers cyclins A and B 12 nbsp Cdk2 blue and its binding partner cyclin A red 13 Cdk2 becomes active when a cyclin protein either A or E binds at the active site located between the N and C lobes of the kinase Due to the location of the active site partner cyclins interact with both lobes of Cdk2 Cdk2 contains an important alpha helix located in the C lobe of the kinase called the C helix or the PSTAIRE helix Hydrophobic interactions cause the C helix to associate with another helix in the activating cyclin Activation induces a conformational change where the helix rotates and moves closer to the N lobe citation needed This allows the glutamic acid located on the C helix to form an ion pair with a nearby lysine side chain The significance of this movement is that it brings the side chain of Glu 51 which belongs to a triad of catalytic site residues conserved in all eukaryotic kinases into the catalytic site This triad Lys 33 Glu 51 and Asp 145 is involved in ATP phosphate orientation and magnesium coordination and is thought to be critical for catalysis This conformational change also relocates the activation loop to the C lobe revealing the ATP binding site now available for new interactions Finally the Threonine 160 residue is exposed and phosphorylated as the C lobe activation segment is displaced from the catalytic site and the threonine residue is no longer sterically hindered The phosphorylated threonine residue creates stability in the final enzyme conformation It is important to note that throughout this activation process cyclins binding to Cdk2 do not undergo any conformational change 14 7 nbsp Cdk2 blue and its binding partner cyclin E orange 15 Role in DNA replication EditThe success of the cell division process is dependent on the precise regulation of processes at both cellular and tissue levels Complex interactions between proteins and DNA within the cell allow genomic DNA to be passed to daughter cells Interactions between cells and extracellular matrix proteins allow new cells to be incorporated into existing tissues At the cellular level the process is controlled by different levels of cyclin dependent kinases Cdks and their partner cyclins Cells utilize various checkpoints as a means of delaying cell cycle progression until it can repair defects 16 Cdk2 is active during G1 and S phase of the cell cycle and therefore acts as a G1 S phase checkpoint control Prior to G1 phase levels of Cdk4 and Cdk6 increase along with cyclin D This allows for the partial phosphorylation of Rb and partial activation of E2F at the beginning of G1 phase which promotes cyclin E synthesis and increased Cdk2 activity At the end of G1 phase the Cdk2 Cyclin E complex reaches maximum activity and plays a significant role in the initiation of S phase 17 Other non Cdk proteins also become active during the G1 S phase transition For example the retinoblastoma Rb and p27 proteins are phosphorylated by Cdk2 cyclin A E complexes fully deactivating them 18 This allows E2F transcription factors to express genes that promote entry into S phase where DNA is replicated prior to division 19 20 18 Additionally NPAT a known substrate of the Cdk2 Cyclin E complex functions to activate histone gene transcription when phosphorylated 21 This increases the synthesis of histone proteins the major protein component of chromatin and subsequently supports the DNA replication stage of the cell cycle Finally at the end of S phase the ubiquitin proteasome degrades cyclin E 11 Cancer cell proliferation EditAlthough Cdk2 is mostly dispensable in the cell cycle of normally functioning cells it is critical to the abnormal growth processes of cancer cells The CCNE1 gene produces cyclin E one of the two major protein binding partners of Cdk2 Overexpression of CCNE1 occurs in many tumor cells causing the cells to become dependent on Cdk2 and cyclin E 12 Abnormal cyclin E activity is also observed in breast lung colorectal gastric and bone cancers as well as in leukemia and lymphoma 17 Likewise abnormal expression of cyclin A2 is associated with chromosomal instability and tumor proliferation while inhibition leads to decreased tumor growth 22 Therefore CDK2 and its cyclin binding partners represent possible therapeutic targets for new cancer therapeutics 12 Pre clinical models have shown preliminary success in limiting tumor growth and have also been observed to reduce side effects of current chemotherapy drugs 23 24 25 Identifying selective Cdk2 inhibitors is difficult due to the extreme similarity between the active sites of Cdk2 and other Cdks especially Cdk1 12 Cdk1 is the only essential cyclin dependent kinase in the cell cycle and inhibition could lead to unintended side effects 26 Most CDK2 inhibitor candidates target the ATP binding site and can be divided into two main subclasses type I and type II Type I inhibitors competitively target the ATP binding site in its active state Type II inhibitors target CDK2 in its unbound state either occupying the ATP binding site or hydrophobic pocket within the kinase Type II inhibitors are believed to be more selective 24 Recently the availability of new CDK crystal structures led to the identification of a potential allosteric binding site near the C helix Inhibitors of this allosteric site are classified as type III inhibitors 27 Another possible target is the T loop of CDK2 When cyclin A binds to CDK2 the N terminal lobe rotates to activate the ATP binding site and switch the position of the activation loop called the T loop 28 Inhibitors EditInterpretation of dynamic simulations and binding free energy studies unveiled that Ligand2 Out of 17 in house synthesized pyrrolone fused benzosuberene PBS compounds has a stable and equivalent free energy to Flavopiridol SU9516 and CVT 313 inhibitors Ligand2 scrutinized as a selective inhibitor of CDK2 without off target binding CDK1 and CDK9 based on ligand efficiency and binding affinity 29 nbsp Graphical abstract of CDK2 29 Known CDK inhibitors are p21Cip1 CDKN1A and p27Kip1 CDKN1B 30 Drugs that inhibit Cdk2 and arrest the cell cycle such as GW8510 and the experimental cancer drug seliciclib may reduce the sensitivity of the epithelium to many cell cycle active antitumor agents and therefore represent a strategy for prevention of chemotherapy induced alopecia 31 Rosmarinic acid methyl ester is a plant derived Cdk2 inhibitor which was shown to suppress proliferation of vascular smooth muscle cells and to reduce neointima formation in mouse restenosis model 32 See also the PDB gallery below showing interactions with many inhibitors inc Purvalanol B Gene regulation EditIn melanocytic cell types expression of the CDK2 gene is regulated by the Microphthalmia associated transcription factor 33 34 Interactions EditCyclin dependent kinase 2 has been shown to interact with BRCA1 35 36 37 CDK2AP1 38 CDKN1B 39 40 41 42 43 CDKN3 44 45 46 CEBPA 47 Cyclin A1 48 49 50 51 Cyclin E1 39 52 53 54 55 56 Flap structure specific endonuclease 1 57 ORC1L 58 P21 43 46 53 59 60 PPM1B 61 PPP2CA 61 Retinoblastoma like protein 1 52 62 Retinoblastoma like protein 2 52 63 and SKP2 40 59 64 nbsp Overview of signal transduction pathways involved in apoptosis References Edit a b c GRCh38 Ensembl release 89 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cdk 2 and cyclin E cdk 2 complexes Oncogene 14 20 2395 406 doi 10 1038 sj onc 1201085 PMID 9188854 Marti A Wirbelauer C Scheffner M Krek W May 1999 Interaction between ubiquitin protein ligase SCFSKP2 and E2F 1 underlies the regulation of E2F 1 degradation Nature Cell Biology 1 1 14 9 doi 10 1038 8984 PMID 10559858 S2CID 8884226 Further reading EditKaldis P Aleem E November 2005 Cell cycle sibling rivalry Cdc2 vs Cdk2 Cell Cycle 4 11 1491 4 doi 10 4161 cc 4 11 2124 PMID 16258277 Moore NL Narayanan R Weigel NL February 2007 Cyclin dependent kinase 2 and the regulation of human progesterone receptor activity Steroids 72 2 202 9 doi 10 1016 j steroids 2006 11 025 PMC 1950255 PMID 17207508 External links EditCyclin Dependent Kinase 2 at the U S National Library of Medicine Medical Subject Headings MeSH CDK2 human gene location in the UCSC Genome Browser CDK2 human gene details in the UCSC Genome Browser Portal nbsp Biology Retrieved from https en wikipedia org w index php title Cyclin dependent kinase 2 amp oldid 1176278850, wikipedia, wiki, book, books, library,

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