SummaryReprogrammed cellular metabolism is a common characteristic observed in various cancers1,2. However, whether metabolic changes directly regulate cancer development and progression remains poorly understood. Here we show that BCAT1, a cytosolic aminotransferase for the branched-chain amino acids (BCAAs), is aberrantly activated and functionally required for chronic myeloid leukemia (CML). BCAT1 is up-regulated during CML progression and promotes BCAA production in leukemia cells by aminating the branched-chain keto acids. Blocking BCAT1 expression or enzymatic activity induces cellular differentiation and impairs the propagation of blast crisis CML (BC-CML) both in vitro and in vivo. Stable isotope tracer experiments combined with NMR-based metabolic analysis demonstrate the intracellular production of BCAAs by BCAT1. Direct supplementation with BCAAs ameliorates the defects caused by BCAT1 knockdown, indicating that BCAT1 exerts its oncogenic function via BCAA production in BC-CML cells. Importantly, BCAT1 expression not only is activated in human BC-CML and de novo acute myeloid leukemia but also predicts disease outcome in patients. As an upstream regulator of BCAT1 expression, we identified Musashi2 (MSI2), an oncogenic RNA binding protein that is required for BC-CML. MSI2 is physically associated with the BCAT1 transcript and positively regulates its protein expression in leukemia. Taken together, this work reveals that altered BCAA metabolism activated through the MSI2-BCAT1 axis drives cancer progression in myeloid leukemia.
Focal adhesion kinase (FAK) has been implicated in the development of cancers, including those of the breast. Nevertheless, the molecular and cellular mechanisms by which FAK promotes mammary tumorigenesis in vivo are not well understood. Here, we show that targeted deletion of FAK in mouse mammary epithelium significantly suppresses mammary tumorigenesis in a well-characterized breast cancer model. Ablation of FAK leads to the depletion of a subset of bipotent cells in the tumor that express both luminal marker keratin 8/18 and basal marker keratin 5. Using mammary stem/progenitor markers, including aldehyde dehydrogenase, CD24, CD29, and CD61, we further revealed that ablation of FAK reduced the pool of cancer stem/progenitor cells in primary tumors of FAK-targeted mice and impaired their selfrenewal and migration in vitro. Finally, through transplantation in NOD-SCID mice, we found that cancer stem/progenitor cells isolated from FAK-targeted mice have compromised tumorigenicity and impaired maintenance in vivo. Together, these results show a novel function of FAK in maintaining the mammary cancer stem/progenitor cell population and provide a novel mechanism by which FAK may promote breast cancer development and progression. [Cancer Res 2009;69(2):466-74]
Focal adhesion kinase family interacting protein of 200 kD (FIP200) has been shown to regulate diverse cellular functions such as cell size, proliferation, and migration in vitro. However, the function of FIP200 in vivo has not been investigated. We show that targeted deletion of FIP200 in the mouse led to embryonic death at mid/late gestation associated with heart failure and liver degeneration. We found that FIP200 knockout (KO) embryos show reduced S6 kinase activation and cell size as a result of increased tuberous sclerosis complex function. Furthermore, FIP200 KO embryos exhibited significant apoptosis in heart and liver. Consistent with this, FIP200 KO mouse embryo fibroblasts and liver cells showed increased apoptosis and reduced c-Jun N-terminal kinase phosphorylation in response to tumor necrosis factor (TNF) α stimulation, which might be mediated by FIP200 interaction with apoptosis signal–regulating kinase 1 (ASK1) and TNF receptor–associated factor 2 (TRAF2), regulation of TRAF2–ASK1 interaction, and ASK1 phosphorylation. Together, our results reveal that FIP200 functions as a regulatory node to couple two important signaling pathways to regulate cell growth and survival during mouse embryogenesis.
Although an important role for excessive proinflammatory cytokines in compromise of pregnancy has been established, an immunological basis for malaria-induced fetal loss remains to be demonstrated. In this study, the roles of IFN-γ and TNF in Plasmodium chabaudi AS-induced fetal loss in mice were directly investigated. Pregnant IFN-γ−/− mice experienced a more severe course of infection compared with intact C57BL/6 mice, characterized by high parasitemia, severe anemia, and marked weight loss. However, fetal loss was delayed in these mice relative to intact controls. Because IFN-γ−/− mice exhibited sustained levels of plasma TNF, the role of this cytokine was examined. Whereas splenic tnf expression in C57BL/6 mice was highest 3 days before peak parasitemia, increased placental expression relative to uninfected mice was sustained, indicating that locally produced TNF may be important in malaria-induced pregnancy failure. Indeed, Ab neutralization of TNF resulted in preservation of embryos until day 12 of gestation, at which point all embryos were lost in untreated mice. Histological analysis revealed that TNF ablation preserved placental architecture whereas placentae from untreated infected mice had widespread hemorrhage and placental disruption, with fibrin thrombi in some maternal blood sinusoids. Consistent with a role for cytokine-driven thrombosis in fetal loss, expression of procoagulant tissue factor was significantly increased in the placentae of infected C57BL/6 mice but was reduced in mice treated with anti-TNF Ab. Together, these results suggest that IFN-γ contributes to malaria-induced fetal loss and TNF is a critical factor that acts by inducing placental coagulopathy.
It has long been appreciated that most autoimmune disorders are characterized by increased prevalence in females, suggesting a potential role for sex hormones in the etiology of autoimmunity. To study how estrogen receptor α (ERα) contributes to autoimmune diseases, we generated mice in which ERα was deleted specifically in T lymphocytes. We found that ERα deletion in T cells reduced their pathogenic potential in a mouse model of colitis and correlated with transcriptomic changes that affected T cell activation. ERα deletion in T cells contributed to multiple aspects of T cell function, including reducing T cell activation and proliferation and increasing the expression of , which encodes a critical transcription factor for the differentiation and function of regulatory T cells. Thus, these data demonstrate that ERα in T cells plays an important role in inflammation and suggest that ERα-targeted immunotherapies could be used to treat autoimmune disorders.
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