MKP1/CL100 controls tumor growth and sensitivity to cisplatin in non-small-cell lung cancer.

Non-small-cell lung cancer (NSCLC) represents the most frequent and therapy-refractive sub-class of lung cancer. Improving apoptosis induction in NSCLC represents a logical way forward in treating this tumor. Cisplatin, a commonly used therapeutic agent in NSCLC, induces activation of N-terminal-c-Jun kinase (JNK) that, in turn, mediates induction of apoptosis. In analysing surgical tissue samples of NSCLC, we found that expression of MKP1/CL100, a negative regulator of JNK, showed a strong nuclear staining for tumor cells, whereas, in normal bronchial epithelia, MKP1 was localized in the cytoplasm as well as in nuclei. In the NSCLC-derived cell lines H-460 and H-23, we found that MKP1 was constitutively expressed. Expressing a small-interfering RNA (siRNA) vector for MKP1 in H-460 cells resulted in a more efficient activation by cisplatin of JNK and p38 than in the parental cells, and this correlated with a 10-fold increase in sensitivity to cisplatin. A similar response was also observed in H-460 and H-23 cells when treated with the MKP1 expression inhibitor RO-31-8220. Moreover, expression of a siRNA-MKP2, an MKP1-related phosphatase, had no effect on H-460 cell viability response to cisplatin. Tumors induced by H-460 cells expressing MKP1 siRNA grew slower in nu(-)/nu(-) mice and showed more susceptibility to cisplatin than parental cells, and resulted in an impaired growth of the tumor in mice. On the other hand, overexpression of MKP1 in the H-1299 NSCLC-derived cell line resulted in further resistance to cisplatin. Overall, the results showed that inhibition of MKP1 expression contributes to a slow down in cell growth in mice and an increase of cisplatin-induced cell death in NSCLC. As such, MKP1 can be an attractive target in sensitizing cells to cisplatin to increase the effectiveness of the drug in treating NSCLC.

New insights in beta-tubulin sequence analysis in non-small cell lung cancer.

Scarce data are available regarding the molecular mechanisms implicated in paclitaxel resistance. There is controversial data about beta-tubulin mutations role in paclitaxel resistance. We have conducted this trial to address the influence of beta-tubulin mutations in paclitaxel resistance in advanced non-small cell lung cancer (NSCLC). A group of 15 patients were biopsied and diagnosed of stages IIIB and IV NSCLC. Tumor specimens were used for DNA isolation and exon 4 of HM40 beta-tubulin isotype was amplified and automatically sequenced, using both intronic and exonic primers. Next, the chemotherapy schedule consisted of weekly paclitaxel (100 or 150 mg/m(2) x 6) followed 2 weeks later by cisplatin 100 mg/m(2) on day 1, gemcitabine 1000 mg/m(2) on days 1 and 14, and vinorelbine 25 mg/m(2) on days 1 and 14, every 28 days. Using exonic primers, gene sequence alterations were found in 13/15 (87%) patients, including transitions (codons 180 and 182) and one silent transversion (codon 195). Also, three transversions (codons 231, 234, and 235) were found in all patients and controls. All alterations disappeared when sequenced with intronic primers. Our results suggest that point mutations demonstrated with exonic primers but not with intronic ones are probably due to beta-tubulin pseudogenes present in advanced NSCLC specimens. Even so, when these beta-tubulin pseudogenes are found there is a clear relation with clinical response. Although these changes could be relevant in paclitaxel resistance, this observation must be proven in future clinical trials to resolve "the tubulin dilemma".

Stimulation of c-Src by prolactin is independent of Jak2.

Interaction of prolactin (PRL) with its receptor (PRLR) leads to activation of Jak and Src family tyrosine kinases. The PRL/growth hormone/cytokine receptor family conserves a proline-rich sequence in the cytoplasmic juxtamembrane region (Box 1) required for association and subsequent activation of Jaks. In the present work, we studied the mechanisms underlying c-Src kinase activation by PRL and the role that Jak2 plays in this process. PRL addition to chicken embryo fibroblasts (CEF) expressing the rat PRLR long form resulted in activation of c-Src and Jak2 and in tyrosine phosphorylation of the receptor. Receptor phosphorylation was due to associated Jak2, since in cells expressing either a Box 1 mutated PRLR (PRLR(4P-A)), which is unable to interact with Jak2, or a kinase-domain-deleted Jak2 (Jak2Deltak), PRL did not stimulate receptor phosphorylation. Interestingly, addition of PRL to cells expressing PRLR(4P-A) resulted in an activation of c-Src equivalent to that observed with the wild-type receptor. These findings indicate that PRL-mediated stimulation of c-Src was independent of Jak2 activation and of receptor phosphorylation. Our results suggest that PRL-activated Src could send signals to downstream cellular targets independently of Jak2.

Prolactin receptor is associated with c-src kinase in rat liver.

The mechanism of action of the pituitary hormone PRL was studied in hepatocytes of lactating rats. PRL receptor immune complexes obtained from liver lysates have an associated tyrosine kinase activity. The tyrosine kinase has been identified in isolated hepatocytes as pp60c-src. Incubation of hepatocytes with PRL induces the association of PRL receptor with pp60c-src and the resultant stimulation of its tyrosine kinase activity. Furthermore, PRL stimulates the gene expression of c-fos, c-jun, and c-src. All of these findings support the idea that the pp60c-src tyrosine kinase participates in the early steps of the PRL intracellular signaling that promotes cell growth in liver cells.