Src family kinases (SFKs) have a critical role in cell adhesion, invasion, proliferation, survival, and angiogenesis during tumor development. SFKs comprise nine family members that share similar structure and function. Overexpression or high activation of SFKs occurs frequently in tumor tissues and they are central mediators in multiple signaling pathways that are important in oncogenesis. SFKs can interact with tyrosine kinase receptors, such as EGFR and the VEGF receptor. SFKs can affect cell proliferation via the Ras/ERK/MAPK pathway and can regulate gene expression via transcription factors such as STAT molecules. SFKs can also affect cell adhesion and migration via interaction with integrins, actins, GTPase-activating proteins, scaffold proteins, such as p130(CAS) and paxillin, and kinases such as focal adhesion kinases. Furthermore, SFKs can regulate angiogenesis via gene expression of angiogenic growth factors, such as fibroblast growth factor, VEGF, and interleukin 8. On the basis of these important findings, small-molecule SFK inhibitors have been developed and are undergoing early phase clinical testing. In preclinical studies these agents can suppress tumor growth and metastases. The agents seem to be safe in humans and could add to the therapeutic arsenal against subsets of cancers.
We describe a strategy to comprehend signaling pathways active in lung cancer cells and targeted by dasatinib employing chemical proteomics to identify direct interacting proteins combined with immunoaffinity purification of tyrosine phosphorylated peptides corresponding to activated tyrosine kinases. We identified nearly 40 different kinase targets of dasatinib. These include SFK members (LYN, SRC, FYN, LCK, YES), non-receptor tyrosine kinases (FRK, BRK, ACK), and receptor tyrosine kinases (Ephrin receptors, DDR1, EGFR). Using quantitative phosphoproteomics we identified peptides corresponding to autophosphorylation sites of these tyrosine kinases that are inhibited in a concentration-dependent manner by dasatinib. Using drug resistant gatekeeper mutants, we show that SFK kinases, particularly SRC and FYN, as well as EGFR are relevant targets for dasatinib action. The combined mass spectrometry based approach described here provides a system-level view of dasatinib action in cancer cells and suggests both functional targets and rationale combinatorial therapeutic strategies.
Mutations of the epidermal growth factor receptor (EGFR) selectively activate Akt and signal transducer and activator of transcription (STAT) pathways that are important in lung cancer cell survival. Src family kinases can cooperate with receptor tyrosine kinases to signal through downstream molecules, such as phosphatidylinositol 3-kinase/PTEN/Akt and STATs. Based on the importance of EGFR signaling in lung cancer, the known cooperation between EGFR and Src proteins, and evidence of elevated Src activity in human lung cancers, we evaluated the effectiveness of a novel orally bioavailable Src inhibitor dasatinib (BMS-324825) in lung cancer cell lines with defined EGFR status. Here, we show that cell fate (death versus growth arrest) in lung cancer cells exposed to dasatinib is dependent on EGFR status. In cells with EGFR mutation that are dependent on EGFR for survival, dasatinib reduces cell viability through the induction of apoptosis while having minimal apoptotic effect on cell lines with wild-type (WT) EGFR. The induction of apoptosis in these EGFR-mutant cell lines corresponds to down-regulation of activated Akt and STAT3 survival proteins. In cell lines with WT or resistant EGFR mutation that are not sensitive to EGFR inhibition, dasatinib induces a G 1 cell cycle arrest with associated changes in cyclin D and p27 proteins, inhibits activated FAK, and prevents tumor cell invasion. Our results show that dasatinib could be effective therapy for patients with lung cancers through disruption of cell growth, survival, and tumor invasion. Our results suggest EGFR status is important in deciding cell fate in response to dasatinib.
Purpose: Signal transducers and activators of transcription 3 (Stat3), a member of the STAT family of transcription factors, regulates multiple oncogenic pathways, including pathways regulating tumor cell survival.We evaluated Stat3 activation in early stage non^small cell lung cancers (NSCLC) and how this relates to upstream epidermal growth factor receptor (EGFR) activation, tumor apoptosis, and prognosis. Experimental Design: High-density tissue microarrays using tissues from 176 surgically resected NSCLC were evaluated for expression of phosphorylated Stat3 (pStat3) and epidermal growth factor receptor (pEGFR) along with tumor apoptosis. Using NSCLC cell lines, we evaluated how pStat3 expression relates to EGFR mutations and sensitivity of cells to gefitinib. Results: We identified nuclear pStat3 expression in 54% of tumors. pStat3 expression was correlated with smaller tumors (P < 0.0001) and with limited smoking history (P = 0.02).We identified a trend toward higher pStat3 expression in adenocarcinomas compared with other tumor histology (P = 0.09). No relationship was found between pStat3 and prognosis following surgical resection. Importantly, we found a strong positive correlation between pEGFR expression and pStat3 expression (P <0.0001) and an inverse correlation between pStat3 and apoptosis (P = 0.01) consistent with less apoptosis in tumors expressing high amounts of pStat3. Cell lines with mutant EGFR have increased levels of pStat3 compared with cell lines without mutant EGFR and this correlates with their sensitivity to gefitinib. Finally, antisense-mediated knockdown of Stat3 induces apoptosis in EGFR mutant lung cancer cells. Conclusions: Early-stage NSCLC tumors have activated EGFR-Stat3 signaling with low apoptosis. Our findings suggest that pStat3 expression may be helpful in identifying patients appropriate for treatment with EGFR tyrosine kinase inhibitors.
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