Project description:The decline in sperm function is a major cause of human male infertility. Glutaminase, a mitochondrial enzyme that catalyzes the hydrolysis of glutamine to generate glutamate, takes part in many diverse biological processes such as neurotransmission, metabolism, and cellular senescence. Here we report a role of glutaminase in regulating sperm function. By generating a triple mutant that harbors a loss-of-function allele for each of all three mammalian glutaminase orthologs, we found that glutaminase gene activity is required for optimal C. elegans sperm function. Tissue-specific gene manipulations showed that germline glutaminase activity plays an important role. Moreover, transcriptional profiling and antioxidant treatment suggested that glutaminase promotes sperm function by maintaining cellular redox homeostasis. As maintaining a low level of ROS is crucial to human sperm function, it is very likely that glutaminase plays a similar role in humans and therefore can be a potential target for treating human male infertility.

Project description:The gene GLS generates the phosphate activated glutaminase C (GAC) isoform by alternative splicing. GAC, compared to the other isoform, kidney-type glutaminase (KGA), has been characterized as more active and particularly important for cancer cell growth. Very little is known about post-translational modifications regulating GAC function. Hereby we describe the identification of a phosphorylation on the serine 95, located at the GLS N-terminus, a domain shared by both isoforms. A GAC phosphomimetic mutant (S95D) ectopically expressed in breast cancer cells presented decreased enzymatic activity, and its expression impacted on cell’s glutamine uptake, glutamate release and intracellular glutamate levels (compared to expressing wild type GAC) without changing GAC sub-cellular localization. Curiously, replacing S95 by an alanine in the ectopically expressed GAC (S95A) increased cell proliferation and migration. Taken together, these results reveal that GAC is post-translationally regulated by phosphorylation, which impacts on cancer phenotype.

Project description:Activated T cells differentiate into functional subsets which require distinct metabolic programs. Glutaminase (GLS) converts glutamine to glutamate to provide substrate for the tricarboxylic acid cycle and epigenetic reactions and here we identify a key role for GLS in T cell activation and specification. Though GLS-deficiency diminished T cell activation, proliferation and impaired differentiation of Th17 cells, loss of GLS also increased Tbet and Interferon-γ expression and CD4 Th1 and CD8 CTL effector cell differentiation. These changes were mediated by differentially altered gene expression and chromatin accessibility, leading to increased sensitivity of Th1 cells to IL-2 mediated mTORC1 signaling. In vivo, GLS-null T cells failed to drive a Th17 mediated Graft-vs-Host Disease model. Transient inhibition of GLS, however, increased Th1 and CTL T cell numbers in viral and chimeric antigen receptor models. Glutamine metabolism thus has distinct roles to promote Th17 but constrain Th1 and CTL effector cell differentiation.

Project description:Autism spectrum disorder (ASD) is a heterogeneous group of disorders with shared diagnostic phenotypes, such as reduced interest in social interaction and communication, and increased stereotyped or restricted interests and behaviors. Little is known about the involvement of alterations of glutaminase 1 (Gls1, an enzyme that catalyzes the hydrolysis of glutamine into glutamate) in the pathogenesis of ASD. To investigate the role of Gls1 in forebrain neurons , we generated conditional mouse mutants with loss of Gls1 in forebrain CamKIIα-Cre positive neurons by crossing Gls1flox/flox mice with CamKIIαcre mice.

Project description:Autism spectrum disorder (ASD) is a heterogeneous group of disorders with shared diagnostic phenotypes, such as reduced interest in social interaction and communication, and increased stereotyped or restricted interests and behaviors. Little is known about the involvement of alterations of glutaminase 1 (Gls1, an enzyme that catalyzes the hydrolysis of glutamine into glutamate) in the pathogenesis of ASD. To investigate the role of Gls1 in forebrain neurons , we generated conditional mouse mutants with loss of Gls1 in forebrain CamKIIα-Cre positive neurons by crossing Gls1flox/flox mice with CamKIIαcre mice.

Project description:Many cases of advanced hepatocellular carcinoma (HCC) are resistant to the widely used drug sorafenib, which worsens prognosis. While many studies have explored how acquired resistance emerges during drug exposure, the mechanism underlying primary resistance before treatment still remain elusive. Here, we performed single-cell lineage tracing and RNA sequencing to identify sorafenib-resistant lineages in HCC, and demonstrated that high expression of S100A14 was positively associated with primary sorafenib resistance. Knocking down S100A14 rendered xenograft tumors in mice significantly more sensitive to sorafenib. Mechanistic studies indicated that S100A14 binds to glutaminase and blocks its phosphorylation at residues Y308 and S314, which in turn inhibits its ubiquitination and subsequent degradation. This stabilization of glutaminase reduces oxidative stress in HCC cells and thereby antagonizes the ability of sorafenib to induce apoptosis. Inhibiting glutaminase with telaglenastat (CB-839) significantly improved sorafenib efficacy against xenograft tumors in vivo. These results suggest that S100A14 can contribute to primary sorafenib resistance in HCC by stabilizing glutaminase. Thus, analyzing the expression of S100A14 may be useful for predicting primary sorafenib resistance, and inhibiting S100A14 or glutaminase may be effective for preventing or overcoming such resistance.

Project description:Cancer cells can metabolize glutamine to replenish TCA cycle intermediates, leading to a dependence on glutaminolysis for cell survival. However, a mechanistic understanding of the role that glutamine metabolism has on the survival of glioblastoma (GBM) brain tumor stem cells (BTSCs) has not yet been elucidated. Here we report that, across a panel of twenty glioblastoma BTSC lines, glutaminase (GLS) inhibition showed a variable response – from complete blockade of cell growth to absolute resistance. Surprisingly, BTSC sensitivity to GLS inhibition was a result of reduced intracellular glutamate triggering the amino acid deprivation response (AADR) and not due to the contribution of glutaminolysis to the TCA cycle. Moreover, BTSC sensitivity to GLS inhibition negatively correlated with the expression of the astrocytic glutamate transporters EAAT1 and EAAT2. Blocking glutamate transport in BTSCs with high EAAT1/EAAT2 expression rendered these cells susceptible to GLS inhibition, triggering the AADR, and limiting cell growth. These findings uncover a unique metabolic vulnerability in BTSCs, support the therapeutic targeting of the upstream activators and downstream effectors of the AADR pathway in GBM, and demonstrate that gene expression patterns reflecting the cellular hierarchy of the tissue of origin can alter the metabolic requirements of the cancer stem cell population.

Project description:Metabolic dysregulation, including perturbed glutamine-glutamate homeostasis, is common in atherosclerotic cardiovascular disease. Here, we reveal that modulation of glutaminolysis or glutamate availability in culture media is critical for smooth muscle cell line (MOVAS) phenotypic switching. Cells were treated for 24 hours with glutaminase inhibitors (50mM DON, Sigma-SML0601) in presence or absence of 2mM glutamate suplementation (Gibco-35050061). High-throughput transcriptional profiling revealed that modulation of glutamine and glutamate homeostasis impacted genes involved in protein and extracellular matrix organization, cell motility and microtubule. Thus, we uncovered a novel role for glutamine metabolism in the phenotypic switch in SMCs, a hallmark of vascular remodelling.

Project description:Metabolic dysregulation, including perturbed glutamine-glutamate homeostasis, is common in atherosclerotic cardiovascular disease. Here, we reveal that modulation of glutaminolysis or glutamate availability in culture media is critical for smooth muscle cell line (MOVAS) phenotypic switching. Cells were treated for 24 hours with glutaminase inhibitors (50mM DON, Sigma-SML0601) in presence or absence of 2mM glutamate suplementation (Gibco-35050061). High-throughput transcriptional profiling revealed that modulation of glutamine and glutamate homeostasis impacted genes involved in protein and extracellular matrix organization, cell motility and microtubule. Thus, we uncovered a novel role for glutamine metabolism in the phenotypic switch in SMCs, a hallmark of vascular remodelling.

Project description:The tumor microenvironment (TME) contains a rich source of nutrients that sustain cell growth and ultimately facilitate tumor progression. The availability of glucose and glutamine in the TME are essential for the development and activation of effector T cells that exert anti-tumor function. Recently, inhibition of glutaminase, the enzyme that hydrolyzes glutamine to glutamate, has garnered interest as an approach to both decrease tumor metabolism and growth, while increasing available glutamine in the TME for effector T cells. Checkpoint blockade immunotherapy unleashes anti-tumor effector capabilities of T cells, and although there are good responses in many solid tumors, a significant proportion of patients respond poorly. In lung adenocarcinoma, response to immunotherapy is reported to be impaired in KRAS-mutant patients harboring concurrent KEAP1 and STK11/Lkb1 mutations. To investigate the metabolism and immune microenvironment of KRAS-mutant lung adenocarcinoma, we generated a series of murine models that reflect the KEAP1 and STK11/Lkb1 mutational landscape seen in patients. Here we show increased glutamate abundance in the Lkb1-deficient TME associated with CD8 T cell activation in response to anti-PD1 checkpoint immunotherapy. Combination treatment with the glutaminase inhibitor CB-839 inhibited clonal expansion and cytotoxic activation of tumor-infiltrating CD8 T cells. Thus, CD8 T cells exposed to checkpoint immunotherapy have a dependence on glutamine and reliance on glutaminase activity and are negatively impacted by the glutaminase inhibitor in this highly activated state. Therefore, we discern that the combination of immunotherapy and glutaminase inhibition is not efficacious for CD8 T cell activation in the tumor microenvironment.