KRAS GTPases are activated in one-third of cancers and KRAS G12C is the most common activating alteration in lung adenocarcinoma 1,2 . KRAS G12C inhibitors 3,4 are in Phase-I clinical trials and early data show partial responses in ~50% of lung cancer patients. How cancer cells bypass inhibition, to prevent maximal response to therapy, is not understood. Because KRAS G12C cycles between an active and inactive conformation [4][5][6] , and the inhibitors only bind to the latter, we tested if isogenic cell populations respond non-uniformly by studying the effect of treatment at Reprints and permissions information is available at www.nature.com/reprints.
Although antitubulin drugs are used widely to treat human cancer, many patients display intrinsic or acquired drug resistance that imposes major obstacles to successful therapy. Mounting evidence argues that cancer cell apoptosis triggered by antitubulin drugs relies upon activation of the cell-cycle kinase Cdk1; however, mechanistic connections of this event to apoptosis remain obscure. In this study, we identified the antiapoptotic protein YAP, a core component of the Hippo signaling pathway implicated in tumorigenesis, as a critical linker coupling Cdk1 activation to apoptosis in the antitubulin drug response. Antitubulin drugs activated Cdk1, which directly phosphorylated YAP on five sites independent of the Hippo pathway. Mutations in these phosphorylation sites on YAP relieved its ability to block antitubulin drug-induced apoptosis, further suggesting that YAP was inactivated by Cdk1 phosphorylation. Notably, we found that YAP was not phosphorylated and inactivated after antitubulin drug treatment in taxol-resistant cancer cells. Our findings suggest YAP and its phosphorylation status as candidate prognostic markers in predicting antitubulin drug response in patients. Cancer Res; 74(16); 4493-503. Ó2014 AACR.
Chemotherapy is one of the major treatments for cancer patients. Although chemotherapeutic drugs can sometimes effectively suppress tumor growth in cancer patients, a significant proportion of patients are either intrinsically resistant or later develop resistance to primary chemotherapy, leading to disease relapse and patient mortality. The best way to conquer the resistance is the better understanding of the molecular network in cancer cells in response to drugs. Therefore, identification of signaling pathways and molecules involved in drug resistance is essential for successful treatment of cancers. The Hippo pathway is an emerging signaling pathway that plays important roles in tumorigenesis, stem cell self‐renewal and differentiation, organ size control as well as many other biological processes. Therefore, exploring novel roles of the Hippo pathway in various biological functions has become one of the cutting‐edge research areas in cancer and other biomedical research. Recently, we and others have provided new evidence that the Hippo pathway is involved in the resistance of different types of cancer cells to various chemotherapeutic drugs. In this review, we will discuss the specific roles of the Hippo pathway in chemotherapy, potential applications for studying this network in response to drugs as well as the future direction in identification of therapeutic targets.
Breast cancer is a leading cause of death in women worldwide. Active mutations of PI3K catalytic subunit PIK3CA (e.g., H1047R) and amplification of its homolog PIK3CB are observed in a large number of breast cancers. In recent years, aberrant activation of Transcriptional coactivator with PDZ binding motif (TAZ) and its paralog Yes-associated protein (YAP) have also been found to be important for breast cancer development and progression. However, whether PI3K interacts with YAP/TAZ during mammary tumorigenesis is unknown. Through a systematic gain-of-function screen for kinases involved in mammary tumorigenesis, we identified PIK3CB as a transformation-inducing kinase in breast cells. We further determined that PIK3CB positively regulates YAP and TAZ to promote transformation and inhibit mammary cell death PIK3CB coexpression with TAZ, rather than PIK3CB or TAZ alone, in human MCF10A nontumorigenic mammary cells is sufficient for tumor formation in mice Interestingly, we also determined that PIK3CA-H1047R enhances YAP and TAZ activity in mammary tumorigenesis Mechanistically, the regulation of YAP/TAZ by both PIK3CA and PIK3CB occurs through multiple signaling pathways including LATS-dependent and LATS-independent pathways. Therefore, in this study, we determine that PI3K and YAP/TAZ interact to promote breast cancer cell transformation. This study provides the first evidence that the Hippo pathway effectors TAZ and YAP are critical mediators of PI3K-induced mammary tumorigenesis and synergistically function together with PI3K in transformation of mammary cells. These findings may provide a novel rationale for targeting YAP/TAZ alone or in combination with PI3K inhibitors for breast cancer therapy in the future. .
The biotrophic maize head smut fungus Sporisorium reilianum is a close relative of the tumour-inducing maize smut fungus Ustilago maydis with a distinct disease aetiology. Maize infection with S. reilianum occurs at the seedling stage, but spores first form in inflorescences after a long endophytic growth phase. To identify S. reilianum-specific virulence effectors, we defined two gene sets by genome comparison with U. maydis and with the barley smut fungus Ustilago hordei. We tested virulence function by individual and cluster deletion analysis of 66 genes and by using a sensitive assay for virulence evaluation that considers both disease incidence (number of plants with a particular symptom) and disease severity (number and strength of symptoms displayed on any individual plant). Multiple deletion strains of S. reilianum lacking genes of either of the two sets (sr10057, sr10059, sr10079, sr10703, sr11815, sr14797 and clusters uni5-1, uni6-1, A1A2, A1, A2) were affected in virulence on the maize cultivar 'Gaspe Flint', but each of the individual gene deletions had only a modest impact on virulence. This indicates that the virulence of S. reilianum is determined by a complex repertoire of different effectors which each contribute incrementally to the aggressiveness of the pathogen.
Antitubulin drugs are commonly used for the treatment of numerous cancers. However, either the intrinsic or acquired resistances of patients to these drugs result in the failure of the treatment and high mortality of cancers. Therefore, identifying genes or signalling pathways involved in antitubulin drug resistances is critical for future successful treatment of cancers.TAZ (Transcriptional coactivator with PDZ-binding motif), which is a core component of the Hippo pathway, is overexpressed in various cancers. We have recently shown that high levels of TAZ in cancer cells result in Taxol resistance through up-regulation of downstream targets Cyr61 and CTGF. However, how TAZ is regulated in response to Taxol is largely unknown. In this study, we found that Cdk1 (Cyclin-dependent kinase 1) directly phosphorylated TAZ on six novel sites independent of the Hippo pathway, which further resulted in TAZ degradation through proteasome system. Phosphorylation-mimicking TAZ mutant was unstable, and therefore abolished TAZ-induced antitubulin drug resistances. This study provides first evidence that Cdk1 is a novel kinase phosphorylating and regulating TAZ stability and suggests that Cdk1-TAZ signalling is a critical regulator of antitubulin drug response in cancer cells and may be a potential target for the treatment of antitubulin-drug resistant cancer patients.
Paving the way for KRAS inhibitors KRAS is a key oncogene in multiple cancer types, but existing inhibitors target only a mutant form of KRAS containing the G12C mutation, and their function presents a mechanistic conundrum. It is known that KRAS G12C inhibitors bind to the oncoprotein in its inactive form; however, KRAS mutations such as G12C interfere with the action of proteins that normally help it hydrolyze GTP to achieve the inactive state. Li et al . have now identified a protein that enhances GTP hydrolysis by mutant KRAS, helping to explain the clinical activity of current drugs targeting this oncoprotein (see the Perspective by Cox and Der). —YN
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