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Target Concepts:
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Query: EC:2.7.11.22 (
cdc2
)
8,319
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The RAS-activated
RAF
-->MEK-->extracellular signal-regulated kinase (ERK) and phosphatidylinositol 3'-kinase (PI3'-kinase)-->PDK1-->AKT signaling pathways are believed to cooperate to promote the proliferation of normal cells and the aberrant proliferation of cancer cells. To explore the mechanisms that underlie such cooperation, we have derived cells harboring conditionally active, steroid hormone-regulated forms of
RAF
and AKT. These cells permit the assessment of the biological and biochemical effects of activation of these protein kinases either alone or in combination with one another. Under conditions where activation of neither
RAF
nor AKT alone promoted S-phase progression, coactivation of both kinases elicited a robust proliferative response. Moreover, under conditions where high-level activation of
RAF
induced G(1) cell cycle arrest, activation of AKT bypassed the arrest and promoted S-phase progression. At the level of the cell cycle machinery,
RAF
and AKT cooperated to induce cyclin D1 and repress p27(Kip1) expression. Repression of p27(Kip1) was accompanied by a dramatic reduction in KIP1 mRNA and was observed in primary mouse embryo fibroblasts derived from mice either lacking SKP2 or expressing a T187A mutated form of p27(Kip1). Consistent with these observations, pharmacological inhibition of MEK or PI3'-kinase inhibited the effects of activated RAS on the expression of p27(Kip1) in NIH 3T3 fibroblasts and in a panel of bona fide human pancreatic cancer cell lines. Furthermore, we demonstrated that AKT activation led to sustained activation of cyclin/
cdk2
complexes that occurred concomitantly with the removal of
RAF
-induced p21(Cip1) from cyclin E/
cdk2
complexes. Cumulatively, these data strongly suggest that the
RAF
-->MEK-->ERK and PI3'K-->PDK-->AKT signaling pathways can cooperate to promote G(0)-->G(1)-->S-phase cell cycle progression in both normal and cancer cells.
...
PMID:Cooperative regulation of the cell division cycle by the protein kinases RAF and AKT. 1557 89
Protein kinases have emerged as one of the most promising targets for rational drug discovery. In a similar manner to imatinib mesylate (Gleevec), hematological malignancies offer multiple pharmacologic opportunities for manipulation of kinase-induced tumor cell proliferation. Certain kinases have been validated as targets for drug discovery in hematological malignancies (such as BCR-ABL and FLT3); other novel kinases hold considerable interest for targeted intervention: myeloid leukemias (KDR, KIT, CSF-1R, RAS and
RAF
), lymphoid leukemias (JAK2 fusion protein, TIE-1,
CDK
modulators), lymphoma (ALK,
CDK
modulators, mTOR), myeloproliferative disorders (PDGF-R or FGF-R fusion gene products, FGF-R1) and myeloma (FGF-R3, STAT3). Over the past five years, the number of kinase-targeted drug therapies undergoing clinical development has increased exponentially. This review will focus on novel kinase targets currently undergoing preclinical and clinical investigation.
...
PMID:Kinases as drug discovery targets in hematologic malignancies. 1630 89
MAPK signaling is required for retinoic acid (RA)-triggered G(0) cell cycle arrest and cell differentiation, but the mechanism is not well defined. In this study, RA is found to cause MAPK activation with sustained association of
RAF
to MEK or ERK, leading to a MAPK-dependent accumulation of p21(Waf1/Cip1) and binding to CDK2 blocking G(1)/S transition. BLR1, a chemokine receptor, was found to function as a critical component of RA-triggered MAPK signaling. Unlike wild-type parental cells, RA-treated BLR1 knock-out cells failed to show
RAF
and consequential MEK and ERK phosphorylation, failed to accumulate
CDK
inhibitors that control G(1)/S transition, and failed to differentiate and arrest in response to RA, whereas ectopically overexpressing BLR1 enhanced MAPK signaling and caused accelerated RA-induced differentiation and arrest. Ectopic overexpression of
RAF
enhanced BLR1 expression in response to RA, whereas inhibition of
RAF
or MEK by inhibitors or knockdown of
RAF
by short interfering RNA diminished RA-induced BLR1 expression and attenuated differentiation and growth arrest. Ectopic expression of the
RAF
CR3, the catalytically active domain, in the BLR1 knock-out restored RA-induced MAPK activation and the ability to differentiate and arrest, indicating that
RAF
effects MAPK signaling by BLR1 to propel differentiation/arrest. Taken together, RA induces cell differentiation and growth arrest through activation of a novel MAPK pathway with BLR1 as a critical component in a positive feedback mechanism that may contribute to the prolonged MAPK signaling propelling RA-induced cell cycle arrest and differentiation.
...
PMID:A MAPK-positive feedback mechanism for BLR1 signaling propels retinoic acid-triggered differentiation and cell cycle arrest. 1800 4
LFM-A13 (alpha-cyano-beta-hydroxy-beta-methyl-N-(2,5-dibromophenyl)propenamide) has recently been identified as an inhibitor of Polo-like kinases (Plk). LFM-A13 does not inhibit other serine/threonine kinases including
CDK
, CHK,
RAF
, DAPK, IKK, IRAK, JNK, MAPK, PKC and SAPK. LFM-A13-treated human cancer cells develop abnormal mitotic spindles and G(2)/M-arrest during cell cycle progression. LFM-A13 was not toxic to rodents or dogs at daily dose levels as high as 100 mg/kg. Notably, at a low dose level of 10 mg/kg, which does not result in delayed tumor progression in the MMTV/neu transgenic mouse model of HER2 positive breast cancer, LFM-A13 markedly enhanced the anti-cancer activity of the mitotic spindle poison paclitaxel. These results indicate that LFM-A13 may be useful in the treatment of cancer patients.
...
PMID:Chemosensitizing anti-cancer activity of LFM-A13, a leflunomide metabolite analog targeting polo-like kinases. 1807 37
Definition of cell cycle control proteins that modify tumor cell resistance to estrogen (E2) signaling antagonists could inform clinical choice for estrogen receptor positive (ER+) breast cancer (BC) therapy. Cyclin G2 (CycG2) is upregulated during cell cycle arrest responses to cellular stresses and growth inhibitory signals and its gene, CCNG2, is directly repressed by E2-bound ER complexes. Our previous studies showed that blockade of HER2, PI3K and mTOR signaling upregulates CycG2 expression in HER2+ BC cells, and that CycG2 overexpression induces cell cycle arrest. Moreover, insulin and insulin-like growth factor-1 (IGF-1) receptor signaling strongly represses CycG2. Here we show that blockade of ER-signaling in MCF7 and T47D BC cell lines enhances the expression and nuclear localization of CycG2. Knockdown of CycG2 attenuated the cell cycle arrest response of E2-depleted and fulvestrant treated MCF7 cells. These muted responses were accompanied by sustained inhibitory phosphorylation of retinoblastoma (RB) protein, expression of cyclin D1, phospho-activation of ERK1/2 and MEK1/2 and expression of cRaf. Our work indicates that CycG2 can form complexes with CDK10, a
CDK
linked to modulation of
RAF
/MEK/MAPK signaling and tamoxifen resistance. We determined that metformin upregulates CycG2 and potentiates fulvestrant-induced CycG2 expression and cell cycle arrest. CycG2 knockdown blunts the enhanced anti-proliferative effect of metformin on fulvestrant treated cells. Meta-analysis of BC tumor microarrays indicates that CCNG2 expression is low in aggressive, poor-prognosis BC and that high CCNG2 expression correlates with longer periods of patient survival. Together these findings indicate that CycG2 contributes to signaling networks that limit BC.
...
PMID:Cyclin G2 promotes cell cycle arrest in breast cancer cells responding to fulvestrant and metformin and correlates with patient survival. 2775 29
Combinatorial inhibition of MEK1/2 and CDK4/6 is currently undergoing clinical investigation in NRAS-mutant melanoma. To prospectively map the landscape of resistance to this investigational regimen, we utilized a series of gain- and loss-of-function forward genetic screens to identify modulators of resistance to clinical inhibitors of MEK1/2 and CDK4/6 alone and in combination. First, we identified NRAS-mutant melanoma cell lines that were dependent on NRAS for proliferation and sensitive to MEK1/2 and CDK4/6 combination treatment. We then used a genome-scale ORF overexpression screen and a CRISPR knockout screen to identify modulators of resistance to each inhibitor alone or in combination. These orthogonal screening approaches revealed concordant means of achieving resistance to this therapeutic modality, including tyrosine kinases,
RAF
, RAS, AKT, and PI3K signaling. Activated KRAS was sufficient to cause resistance to combined MEK/
CDK
inhibition and to replace genetic depletion of oncogenic NRAS. In summary, our comprehensive functional genetic screening approach revealed modulation of resistance to the inhibition of MEK1/2, CDK4/6, or their combination in NRAS-mutant melanoma. SIGNIFICANCE: These findings reveal that NRAS-mutant melanomas can acquire resistance to genetic ablation of
NRAS
or combination MEK1/2 and CDK4/6 inhibition by upregulating activity of the RTK-RAS-
RAF
and RTK-PI3K-AKT signaling cascade.
...
PMID:A Functional Landscape of Resistance to MEK1/2 and CDK4/6 Inhibition in NRAS-Mutant Melanoma. 3081 66
