Project description:N6-methyladenosine (m6A) modification is the most abundant internal mRNA modification in eukaryotes. Hypoxia induces reprogramming of m6A epitranscriptome, but the detail underlying regulator mechanism remains elusive in breast cancer. Here we reported that hypoxia induced elevated m6A modification involved in tumor progression. m6A- sequencing (m6A-seq) combined with RNA sequencing (RNA-seq) identified RIPOR3 as a key target gene of m6A modification under hypoxic stress. Hypoxia-induced increased of RIPOR3 m6A levels promoted its mRNA stability and expression, thereby facilitating the progression and metastasis of breast cancer. Besides, RIPOR3 was overexpressed in breast cancer cells and breast tumor tissues, and elevation of RIPOR3 expression was associated with poor prognosis. Mechanistically, RIPOR3 bound to EGFR and the interaction was enhanced under hypoxia, promoting the activation of the EGFR downstream PI3K-AKT signaling pathway. Altogether, our studies reveal that RIPOR3 responds to hypoxic stress to promote EGFR-PI3K-AKT signal pathway, facilitating breast cancer progression and metastasis, thus presenting itself as a potential therapeutic target.

Project description:Recently, many studies have focused on the epigenetics such as histone modification and DNA methylation upon hypoxic stress. However, little is known about the the m6A epitranscriptome in response to hypoxia. In this study, we report that hypoxia systematically inhibit the m6A pathway through reducing the total m6A level and the expression of m6A readers. Deep m6A transcriptome sequencing revealed a drastic reprogramming of m6A epitranscriptome during cellular hypoxia. Integration m6A epitranscriptome with RNA-Seq or LC-MS/MS based proteome analysis of cells upon hypoxic stress revealed that the reprogramming of m6A epitranscriptome remodels the transcriptome and proteome to support the efficient generation of energy for adaption to hypoxia. Taken together, our studies indicated that the crosstalk between m6A and HIF1 pathway was essential for the cellular response to hypoxia, and provided profound insights into the molecular mechanism underlying the hypoxic responsive process.

Project description:N6-methyladenosine (m6A) is a type of nucleotide modification abundant in mRNA, which regulates mRNA stability, splicing and translation. However, its physiological role in intratumoral microenvironment and drug resistancehave not been fully understood. We demonstrated that METTL3,a primary m6A methyltransferase, was significantly down-regulated in human sorafenib-resistant hepatocellular carcinoma (HCC). Depletion of METTL3 under hypoxia promoted sorafenib-resistance and angiogenesis and exacerbated progression by activating autophagy-associated pathway. Mechanistically, we identified FOXO3 as a key downstream target of the METTL3-mediated m6A modification. The m6A modification of FOXO3 at the 3'-untranslated region increased FOXO3 mRNA stability. Analysis of clinical samples showed that METTL3levels aretightly correlated with FOXO3levels in patients with HCC, and suppression of FOXO3 predicted poor clinical outcomes. Importantly, METTL3-depletion significantly enhanced sorafenib-resistance of HCC via a METTL3-FOXO3 axis, whereasoverexpression of FOXO3 restored the m6A-dependent sorafenib-sensitivity. Collectively, our work revealedthe critical function of the METTL3-mediated m6A modification in HCC in hypoxic tumor microenvironment, and provided insights into the molecular mechanism of the m6A modification in the resistance of HCC to sorafenib therapy.

Project description:DEAD-box RNA-binding proteins (RBPs) play a significant role in RNA metabolism to achieve cellular homeostasis, including miRNA biogenesis and transcription. Hypoxia induces stemness cell-like characteristics in cancer cells and promotes malignant progression. Despite the fact that hypoxia can induce the changes in protein and RNA modification, thereby regulating downstream gene expressions, how modifications at different molecular layers interplay with each other are poorly understood. Here we show that hypoxia induces HectH9-mediated K63-linked polyubiquitination of the DEAD-box protein DDX17 as well as reduces N6-methyladenosine (m6A) marks in pri-miRNAs. While m6A potentiates DDX17 binding to pri-miRNAs, decreased m6A modifications of pri-miRNAs and increased polyubiquitination of DDX17 under hypoxia lead to decreased DDX17 binding to pri-miRNAs binding. These events enhance the association of DDX17 with the ubiquitin receptor p300 and lead to a decrease in miRNA biogenesis, especially for miRNAs regulating stemness and stemness-related genes. In addition, polyubiquitinated DDX17 together with p300 upregulates H3K56Ac levels on the stemness and stemness-related genes, resulting in enhancement of tumor initiating ability. Post-transcriptionally, decreased miRNA production, including those targeting stemness genes or stemness-related genes, also facilitates tumor initiation. Together, hypoxia triggers DDX17 poly-ubiquitination, which orchestrates dual mechanisms to increase tumor initiating ability and promote tumor progression.

Project description:N6-methyladenosine (m6A) is a type of nucleotide modification abundant in mRNA, which regulates mRNA stability, splicing and translation. However, its physiological role in intratumoral microenvironment and drug resistancehave not been fully understood. We demonstrated that METTL3,a primary m6A methyltransferase, was significantly down-regulated in human sorafenib-resistant hepatocellular carcinoma (HCC). Depletion of METTL3 under hypoxia promoted sorafenib-resistance and angiogenesis and exacerbated progression by activating autophagy-associated pathway. Mechanistically, we identified FOXO3 as a key downstream target of the METTL3-mediated m6A modification. The m6A modification of FOXO3 at the 3'-untranslated region increased FOXO3 mRNA stability. Analysis of clinical samples showed that METTL3levels aretightly correlated with FOXO3levels in patients with HCC, and suppression of FOXO3 predicted poor clinical outcomes. Importantly, METTL3-depletion significantly enhanced sorafenib-resistance of HCC via a METTL3-FOXO3 axis, whereasoverexpression of FOXO3 restored the m6A-dependent sorafenib-sensitivity. Collectively, our work revealedthe critical function of the METTL3-mediated m6A modification in HCC in hypoxic tumor microenvironment, and provided insights into the molecular mechanism of the m6A modification in the resistance of HCC to sorafenib therapy.

Project description:Dynamic N6-methyladenosine (m6A) modification was previously identified as a ubiquitous post-transcriptional regulation that affected mRNA homeostasis. However, the m6A-related epitranscriptomic alterations and functions remain elusive in human diseases such as cancer. Here we show that hypoxia regulates the ‘reader’ protein YTH domain family 2 (YTHDF2), to eventually stabilize the methylated oncogene mRNAs in inflammation-associated liver cancer. YTHDF2 silenced in human cancer cells or depleted in mouse hepatocytes evoked pro-inflammatory responses and accelerated tumor growth and metastatic progression. Under hypoxia, YTHDF2 processed the decay of m6A-containing interleukin 11 (IL11) and serpin family E member 2 (SERPINE2) mRNAs, which were responsible for the inflammation-mediated malignancy. Reciprocally, YTHDF2 transcription succumbed to hypoxia-inducible factor-2α (HIF-2α). Administration of a HIF-2α antagonist (PT2385) restored YTHDF2-programed epigenetic machinery and repressed liver cancer. Hence, our findings provide a new insight into the mechanism by which hypoxia adapts m6A-mRNA editing to promote cancer.

Project description:Background: Post-transcriptional modification of tumor-associated factors plays a pivotal role in breast cancer progression. However, the underlying mechanism remains unknown. Modifications to m6A are dynamic and reversible in cancer cells and have been found to impact tumor initiation and progression through various mechanisms. In this study, we explored the regulatory mechanism of m6A methylation in the Hippo pathway, a key pathway involved in cell proliferation and metabolism. Methods: First, a combination of MeRIP-seq, RNA-seq and metabolomics-seq was utilized to reveal the map of m6A modifications in breast cancer tissues and cells. Secondly, we identified the relationship between m6A proteins and LATS1 in m6A regulation in breast cancer cells by performing RNA pull-down assays, RIP-qPCR, MeRIP-qPCR, and RNA stability analysis. The expression and biological functions of METTL3 and YTHDF2 were confirmed in breast cancer cell lines in vitro and in vivo. Furthermore, we investigated the phosphorylation levels and localization of YAP/TAZ to reveal that the activity of the Hippo pathway could be affected by m6A regulation of LATS1 in breast cancer cells. Results: We demonstrated that m6A regulation plays an important role in proliferation and glycolytic metabolism in breast cancer through the Hippo pathway factor, LATS1. METTL3 was identified as the m6A writer, with YTHDF2 as the reader protein of LATS1 mRNA, which plays a positive role in promoting both tumorigenesis and glycolysis in breast cancer. High levels of m6A modification were induced by METTL3 in LATS1 mRNA. YTHDF2 identified m6A sites in LATS1 mRNA and reduced its stability. Knockout of the protein expression of METTL3 or YTHDF2 increased the expression of LATS1 mRNA and suppressed breast cancer tumorigenesis by activating YAP/TAZ in the Hippo pathway. Conclusions: In summary, we discovered that the METTL3-LATS1-YTHDF2 pathway plays an important role in the progression of breast cancer by activating YAP/TAZ in the Hippo pathway.

Project description:Hypoxia is an important driver of cancer progression, and rapidly growing tumors often result in intratumoral hypoxic regions. Hypoxia is associated with metabolic reprogramming and angiogenesis, resulting in enhanced tumor progression. Here, we aimed to study breast cancer hypoxia responses at the proteomic level, and we wanted to identify differences in protein secretion from luminal-like and basal-like cell lines before and after hypoxia.

Project description:N6-methyladenosine (m6A) is a widespread reversible chemical modification of RNAs, implicated in many aspects of RNA metabolism. Little quantitative information exists as to either how many transcript copies of particular genes are m6A modified (“m6A levels”), or the relationship of m6A modification(s) to alternative RNA isoforms. To deconvolute the m6A epitranscriptome, we developed m6A level and isoform-characterization sequencing (m6A-LAIC-seq). We found that cells exhibit a broad range of non-stoichiometric m6A levels with cell type specificity. At the level of isoform characterization, we discovered widespread differences in use of tandem alternative polyadenylation (APA) sites by methylated and nonmethylated transcript isoforms of individual genes. Strikingly, there is a strong bias for methylated transcripts to be coupled with proximal APA sites, resulting in shortened 3’ untranslated regions (3’-UTRs), while nonmethylated transcript isoforms tend to use distal APA sites. m6A-LAIC-seq yields a new perspective on transcriptome complexity and links APA usage to m6A modifications. m6A-LAIC-seq of H1-ESC and GM12878 cell lines, each cell line has two replicates

Project description:Our understanding of posttranscriptional modifications that decorate RNA, a regulatory layer positioned between DNA and proteins, is in its infancy. N6-methyladenosine (m6A) is the most prevalent internal modification in messenger RNAs that is installed and erased by m6A methyltransferases and demethylases. The importance of these enzymes in cancer is rapidly emerging, yet information of their specific mode of actions during disease progression remain largely unknown. In the present study, we report that the m6A RNA demethylase FTO controls EMT and invasion in cancer through regulation of the Wnt pathway. We find that loss of FTO, in contrast to acute myeloid leukemia, is frequent in many cancer types, including breast and prostate cancers. Knockdown of FTO promotes tumor progression – specifically migration and invasion – in breast and prostate cancer cells. Furthermore, implantation of these cells accelerates tumor progression in recipient mice in vivo. In these tumors, FTO depletion leads to m6A-dependent activation of Wnt signaling, which drives an enhanced EMT program and invasion, thus leading to poor clinical outcome. However, loss of FTO also sensitizes cancers cells to Wnt inhibition, offering a rationale for the therapeutic targeting of Wnt for cancer patients with low FTO levels. Together, our work reveals FTO as a novel regulator of EMT and an unexpected mechanism by which Wnt signals are dysregulated in tumors, providing a rationale to stratify cancer patients treated with Wnt inhibitor. These data uncover a previously unrecognized relationship between RNA modification and EMT in cancer.