Gene/Protein
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Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
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Drug
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Target Concepts:
Gene/Protein
Disease
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Enzyme
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Query: EC:2.7.12.2 (
MEK
)
18,161
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
The molecular genetic profiles that characterize pancreatic ductal neoplasia have taken shape recently with the help of immunohistochemistry and the establishment of the nomenclature describing pancreatic ductal tumorigenesis. K-ras mutations frequently occur early, changes in the expression and genetic integrity of the p16 gene appear in intermediate lesions, and the inactivation of the p53, DPC4, and BRCA2 genes occur late in the neoplastic progression. Tumor-suppressor genes inactivated in pancreatic cancer such as ALK5, TGFBR2,
MKK4
, and
STK11
/LKB1 have been identified, although their roles in tumor progression are not yet well defined. Additional discoveries in this tumor system may be on the horizon, will further refine the molecular genetic profiles for the disease, and should suggest some clinical uses for this fund of knowledge.
...
PMID:Molecular genetics of ductal pancreatic neoplasia. 1703 Nov 13
LKB1/
STK11
is a multitasking tumour suppressor kinase. Germline inactivating mutations of the gene are responsible for the Peutz-Jeghers hereditary cancer syndrome. It is also somatically inactivated in approximately 30% of non-small-cell lung cancer (NSCLC). Here, we report that LKB1/KRAS mutant NSCLC cell lines are sensitive to the
MEK
inhibitor CI-1040 shown by a dose-dependent reduction in proliferation rate, whereas LKB1 and KRAS mutations alone do not confer similar sensitivity. We show that this subset of NSCLC is also sensitised to the mTOR inhibitor rapamycin. Importantly, the data suggest that LKB1/KRAS mutant NSCLCs are a genetically and functionally distinct subset and further suggest that this subset of lung cancers might afford an opportunity for exploitation of anti-MAPK/mTOR-targeted therapies.
...
PMID:LKB1/KRAS mutant lung cancers constitute a genetic subset of NSCLC with increased sensitivity to MAPK and mTOR signalling inhibition. 1916 1
Activating mutations of oncogenic RAS genes are frequently detected in human cancers. The studies in genetically engineered mouse models (GEMMs) reveal that Kras-activating mutations predispose mice to early onset tumors in the lung, pancreas, and gastrointestinal tract. Nevertheless, most of these tumors do not have metastatic phenotypes. Metastasis occurs when tumors acquire additional genetic changes in other cancer driver genes. Studies on clinical specimens also demonstrated that KRAS mutations are present in premalignant tissues and that most of KRAS mutant human cancers have co-mutations in other cancer driver genes, including TP53,
STK11
, CDKN2A, and KMT2C in lung cancer; APC, TP53, and PIK3CA in colon cancer; and TP53, CDKN2A, SMAD4, and MED12 in pancreatic cancer. Extensive efforts have been devoted to develop therapeutic agents that target enzymes involved in RAS posttranslational modifications, that inhibit downstream effectors of RAS signaling pathways, and that kill RAS mutant cancer cells through synthetic lethality. Recent clinical studies have revealed that sorafenib, a pan-RAF and VEGFR inhibitor, has impressive benefits for KRAS mutant lung cancer patients. Combination therapy of
MEK
inhibitors with either docetaxel, AKT inhibitors, or PI3K inhibitors also led to improved clinical responses in some KRAS mutant cancer patients. This review discusses knowledge gained from GEMMs, human cancer cells, and patient-related studies on RAS-mediated tumorigenesis and anti-RAS therapy. Emerging evidence demonstrates that RAS mutant cancers are heterogeneous because of the presence of different mutant alleles and/or co-mutations in other cancer driver genes. Effective subclassifications of RAS mutant cancers may be necessary to improve patients' outcomes through personalized precision medicine.
...
PMID:RAS signaling and anti-RAS therapy: lessons learned from genetically engineered mouse models, human cancer cells, and patient-related studies. 2635 96
Most non-small cell lung cancers (NSCLC) contain nontargetable mutations, including
KRAS, TP53
, or
STK11
/LKB1
alterations. By coupling
ex vivo
drug sensitivity profiling with
in vivo
drug response studies, we aimed to identify drug vulnerabilities for these NSCLC subtypes. Primary adenosquamous carcinoma (ASC) or adenocarcinoma (AC) cultures were established from
Kras
G12D/+
;Lkb1
fl/fl
(KL) tumors or AC cultures from
Kras
G12D/+
;p53
fl/fl
(KP) tumors. Although
p53
-null cells readily propagated as conventional cultures,
Lkb1
-null cells required conditional reprograming for establishment. Drug response profiling revealed short-term response to
MEK
inhibition, yet long-term clonogenic assays demonstrated resistance, associated with sustained or adaptive activation of receptor tyrosine kinases (RTK): activation of ERBBs in KL cultures, or FGFR in AC cultures. Furthermore, pan-ERBB inhibition reduced the clonogenicity of KL cultures, which was exacerbated by combinatorial
MEK
inhibition, whereas combinatorial
MEK
and FGFR inhibition suppressed clonogenicity of AC cultures. Importantly,
in vivo
studies confirmed KL-selective sensitivity to pan-ERBB inhibition, which correlated with high ERBB ligand expression and activation of ERBB receptors, implying that ERBB network activity may serve as a predictive biomarker of drug response. Interestingly, in human NSCLCs, phosphorylation of EGFR or ERBB3 was frequently detected in ASCs and squamous cell carcinomas. We conclude that analysis of
in situ
ERBB signaling networks in conjunction with
ex vivo
drug response profiling and biochemical dissection of adaptive RTK activities may serve as a valid diagnostic approach to identify tumors sensitive to ERBB network inhibition.
...
PMID:Receptor Tyrosine Kinase Signaling Networks Define Sensitivity to ERBB Inhibition and Stratify
Kras
-Mutant Lung Cancers. 3132 Apr 2
