Project description:Single nucleotide polymorphisms in the FTO gene encoding a m6A demthylase are associated with obesity and cancer development. However, the functional role of FTO in the developemnt of progression of hepatocellular carcinoma (HCC) as a proteotypic obesity-associated cancer remains unclear. Here, we have generated mice with hepatic FTO deficiency (FTOL-KO) and subjected them to DEN induced HCC-development. FTOL-KO mice exhibit increased HCC burden. While control mice exhibit a dynamic regulation of FTO upon induction of liver damage, this response is abrogated in mice lacking FTO. Proteomic analyses revealed that liver damage-induced increases in FTO expression promotes m6A-demethylation of CUL4A reducing its protein expression. Functionally, knockdown of CUL4A restores the increased hepatocyte proliferation observed upon loss of FTO. Collectively, our study reveals a protective role for FTO-dependent dynamic m6A mRNA demethylation of CUL4A in the initiation of HCC development.

Project description:FTO, an N6-methyladenosine (m6A) demethylase, can promote cervical cancer cell proliferation and migration. RNA-sequencing of SiHa cells with FTO knockdown was conducted to dissect the differentially expressed genes and the potential mechanism of FTO in cervical cancer.

Project description:Here we use MeRIP-Seq to analyze global adenosine methylation (m6A) in mRNAs in the midbrain and striatum of Fto-deficient mice. We find that Fto deficiency leads to increased methylation within a subset of mRNAs important for neuronal signaling, including many within the dopaminergic signaling pathway. Collectively, our results show that Fto regulates demethylation of specific mRNAs in vivo, and this activity relates to control of dopaminergic transmission. Profiling of m6A in midbrain and striatum from FTO knockout mice

Project description:Multifunctional N6-methyladenosine (m6A) has been revealed to be an important epigenetic component in various physiological and pathological processes, but its role in female ovarian aging remains unclear. Thus, we demonstrated m6A demethylase FTO downregulation and the ensuing increased m6A in granulosa cells (GCs) of human aged ovaries, while FTO-knockdown GCs showed faster aging-related phenotypes mediated. Using the m6A-RNA-sequence technique (m6A-seq), increased m6A was found in the FOS-mRNA-3'UTR, which is suggested to be an erasing target of FTO that slows the degradation of FOS-mRNA to upregulate FOS expression in GCs, eventually resulting in GC-mediated ovarian aging. FTO acts as a senescence-retarding protein via m6A, and FOS knockdown significantly alleviates the aging of FTO-knockdown GCs.

Project description:Reversible RNA modification of N6-methyladenosine (m6A) plays a critical role in post-transcriptional gene regulation1-13. Although the fat mass and obesity-associated protein (FTO) has been previously shown to function as an m6A demethylase in nuclear RNA1,14, its exact function in disease pathogenesis remains a mystery. Here, we demonstrate that FTO suppresses the activation of Rho GTPase signaling via both its demethylation activity and specific interaction with Rho effector, Rhotekin (RTKN)15. The knockdown of FTO activates RhoA and RhoC, induces stress fibres, and accelerates cell migration. Endogenous RTKN is highly expressed in certain cancer and cancer-derived cell lines16,17 with overexpression of RTKN leading to moderate activation of Rho18. We further found that overexpression of RTKN blocks nuclear import of FTO and traps FTO in the cytoplasm to mediate m6A demethylation of cytosolic mRNA, thereby changing gene expression by preventing m6A-dependent mRNA decay and translation. Our results illustrate how FTO represses Rho activation through m6A demethylation and direct interaction with RTKN, and shed new light on FTO-dependent post-transcriptional gene regulation in RTKN overexpressed cancers, which may provide a new direction for developing anti-cancer therapies.

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.

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.

Project description:The m6A RNA demethylase Fat mass and obesity-associated protein (FTO) is aberrantly upregulated in numerous cancers and promotes tumor development and therapeutic resistance. Here, using public datasets and screening, we show that FTO is ubiquitinated at lysine 162 by its E3 ligase DTX2, followed by recognition by UFD1, leading to degradation in the proteasomes. Furthermore, we identified vitamin E succinate (VES) as a natural first-in-class degrader for FTO by binding to FTO and DTX2, thus enhancing FTO-DTX2 interaction, leading to increased FTO ubiquitination and degradation and enhanced anti-tumor immunity and response to immunotherapy. Genetic or pharmacological FTO knockdown by VES increased m6A methylation in the LIF gene and thus decreased LIF mRNA decay, and thus sensitized tumor cells to T cell-mediated cytotoxicity. Taken together, our findings elucidated the underlying molecular mechanism for FTO protein degradation and the first natural FTO degrader that reprograms the anti-tumor immunity.

Project description:Zinc-finger homeobox 3 (ZFHX3, also known as ATBF1) suppresses prostatic tumorigenesis. ZFHX3 is frequently found to have numerous deletions in human prostate cancer (PCa). However, the underlying molecular function of ZFHX3 during prostatic tumorigenesis is not well understood. N6-methyladenosine (m6A) modification in RNA plays a critical role in the development of cancers; however, the relationship between ZFHX3 and m6A modification is largely unknown in PCa. In this study, we found that ZFHX3 knockdown decreased total m6A levels through enhancing the transcriptional activity of FTO in PCa cells. Importantly, FTO inhibition suppressed cell proliferation and rescued the promoting function of ZFHX3 knockdown on cell proliferation. In vivo, we verified that FTO was upregulated and ZFHX3 was decreased in PCa patients and that a high level of ZFHX3 is indispensable for low FTO expression and is correlated with better patient survival. Through transcriptome sequencing and Me-RIP sequencing, we revealed that E2F2 and CDKN2C were the direct targets of FTO-mediated m6A modification and ZFXH3 was required for the regulation of FTO on E2F2 and CDKN2C expression. Unexpectedly, we uncovered that ZFHX3 expression was in return regulated by FTO in a m6A-dependent way. These findings establish a novel crosstalk mechanism between ZFHX3 and FTO in prostatic tumorigenesis.

Project description:RNA methylation plays an important role fine tuning translation and subsequently regulating cellular responses and cell fate. The fat mass- and obesity-associated protein (FTO) was recognized as an m6A demethylase and described as an oncogenic factor in leukemia and brain tumors. FTO expression levels are suppressed in ovarian tumors and ovarian cancer stem cells (CSCs). FTO induce cyclic AMP activity through targeting PDE4B and PDE1C by down-regulation of m6A levels in the mRNA transcript. In all or findings point to a tumor suppressor function of FTO in high grade serous OC. FTO induce cyclic AMP activity through targeting PDE4B and PDE1C by down-regulation of m6A levels in the mRNA transcript. In all or findings point to a tumor suppressor function of FTO in high grade serous OC