XAF1 directs glioma response to temozolomide through apoptotic transition of autophagy by activation of ATM-AMPK signaling.

Background: X-linked inhibitor of apoptosis-associated factor 1 (XAF1) is a tumor suppressor that is commonly inactivated in multiple human cancers. However, its role in the pathogenesis and therapeutic response of glioma is poorly characterized. Methods: XAF1 activation by temozolomide (TMZ) and its effect on TMZ cytotoxicity were defined using luciferase reporter, flow cytometry, and immunofluorescence assays. Signaling mechanism was analyzed using genetic and pharmacologic experiments. In vivo studies were performed in mice to validate the role of XAF1 in TMZ therapy. Results: Epigenetic alteration of XAF1 is frequent in cell lines and primary tumors and contributes to cancer cell growth. XAF1 transcription is activated by TMZ via JNK-IRF-1 signaling to promote apoptosis while it is impaired by promoter hypermethylation. In tumor cells expressing high O 6-methylguanine-DNA methyltransferase (MGMT), XAF1 response to TMZ is debilitated. XAF1 facilitates TMZ-mediated autophagic flux to direct an apoptotic transition of protective autophagy. Mechanistically, XAF1 is translocated into the mitochondria to stimulate reactive oxygen species (ROS) production and ataxia telangiectasia mutated (ATM)-AMP-activated protein kinase (AMPK) signaling. A mutant XAF1 lacking the zinc finger 6 domain fails to localize in the mitochondria and activate ROS-ATM-AMPK signaling and autophagy-mediated apoptosis. XAF1-restored xenograft tumors display a reduced growth rate and enhanced therapeutic response to TMZ, which is accompanied with activation of ATM-AMPK signaling. XAF1 expression is associated with overall survival of TMZ treatment patients, particularly with low MGMT cancer. Conclusions: This study uncovers an important role for the XAF1-ATM-AMPK axis as a linchpin to govern glioma response to TMZ therapy.

Cooperativity of E-cadherin and Smad4 loss to promote diffuse-type gastric adenocarcinoma and metastasis.

UNLABELLED: Loss of E-cadherin (CDH1), Smad4, and p53 has been shown to play an integral role in gastric, intestinal, and breast cancer formation. Compound conditional knockout mice for Smad4, p53, and E-cadherin were generated to define and compare the roles of these genes in gastric, intestinal, and breast cancer development by crossing with Pdx-1-Cre, Villin-Cre, and MMTV-Cre transgenic mice. Interestingly, gastric adenocarcinoma was significantly more frequent in Pdx-1-Cre;Smad4(F/F);Trp53(F/F);Cdh1(F) (/+) mice than in Pdx-1-Cre;Smad4(F/F);Trp53(F/F);Cdh1(+/+) mice, demonstrating that Cdh1 heterozygosity accelerates the development and progression of gastric adenocarcinoma, in combination with loss of Smad4 and p53. Pdx-1-Cre;Smad4(F/F);Trp53(F/F);Cdh1(F) (/+) mice developed gastric adenocarcinomas without E-cadherin expression. However, intestinal and mammary adenocarcinomas with the same genetic background retained E-cadherin expression and were phenotypically similar to mice with both wild-type Cdh1 alleles. Lung metastases were identified in Pdx-1-Cre;Smad4(F/F);Trp53(F/F);Cdh1(F) (/+) mice, but not in the other genotypes. Nuclear ß-catenin accumulation was identified at the invasive tumor front of gastric adenocarcinomas arising in Pdx-1-Cre;Smad4(F/F);Trp53(F/F);Cdh1(F) (/+) mice. This phenotype was less prominent in mice with intact E-cadherin or Smad4, indicating that the inhibition of ß-catenin signaling by E-cadherin or Smad4 downregulates signaling pathways involved in metastases in Pdx-1-Cre;Smad4(F/F);Trp53(F/F);Cdh1(F) (/+) mice. Knockdown of ß-catenin significantly inhibited the migratory activity of Pdx-1-Cre;Smad4(F/F);Trp53(F/F);Cdh1(F) (/+) cell lines. Thus, loss of E-cadherin and Smad4 cooperates with p53 loss to promote the development and metastatic progression of gastric adenocarcinomas, with similarities to human gastric adenocarcinoma. IMPLICATIONS: This study demonstrates that inhibition of ß-catenin is a converging node for the antimetastatic signaling pathways driven by E-cadherin and Smad4 in Pdx-1-Cre;Smad4(F/F);Trp53(F/F);Cdh1(F) (/+) mice, providing novel insights into mechanisms for gastric cancer metastasis.

miR-592 and miR-552 can distinguish between primary lung adenocarcinoma and colorectal cancer metastases in the lung.

BACKGROUND/AIM: Distinguishing between primary and metastatic adenocarcinomas in the lung may sometimes be difficult by conventional histopathological methods. In addition, novel biomarkers are needed for the more accurate subtyping of primary lung carcinomas. MATERIALS AND METHODS: MicroRNA microarrays were performed on 26 primary lung adenocarcinomas, 3 squamous cell carcinomas, 6 small cell lung cancers (SCLCs), and 2 colorectal cancer metastases in the lung. RESULTS: Forty-four microRNAs differentially expressed between three histological subtypes at p<10(-6) predicted histology with 100% accuracy in 100 randomly drawn datasets. Prominent among differentially expressed genes were miR-375, miR-217 and miR-216a, which were found overexpressed in SCLC compared to lung adenocarcinomas. Lung adenocarcinomas overexpressed miR-29b-1, miR-375, miR-2110, miR-29c-star, 199b-5p, and 146b-3p and underexpressed miR-617, miR-205-star, and miR-1246 compared to squamous cell carcinomas. In primary vs. metastatic lung adenocarcinomas, miR-552 and miR-592 were differentially expressed at p<10(-6); the level of expression of miR-552 in colorectal cancer metastases was 39-times higher and that of miR-592 was six-times higher. Furthermore, microRNA profiles of primary colorectal cancer in our database indicated that these two microRNAs were overexpressed in primary colorectal cancer relative to primary lung adenocarcinomas. CONCLUSION: MicroRNA profiles predict the histology of primary lung carcinomas, and differentiate between primary lung adenocarcinomas and colorectal cancer metastases.