Your search keyword '"William C. Comb"' showing total 12 results

1. Quantitative modelling of amino acid transport and homeostasis in mammalian cells

Author

Gregory Gauthier-Coles, Jade Vennitti, Zhiduo Zhang, William C. Comb, Shuran Xing, Kiran Javed, Angelika Bröer, and Stefan Bröer

Subjects

Science

Abstract

Cytosolic amino acid concentrations are carefully maintained, but how homeostasis occurs is unclear. Here, the authors show that amino acid transporters primarily determine intracellular amino acid levels and develop a model that predicts a perturbation response similar to experimental data.

Published

2021

2. Disruption of the Rag-Ragulator Complex by c17orf59 Inhibits mTORC1

Author

Lawrence D. Schweitzer, William C. Comb, Liron Bar-Peled, and David M. Sabatini

Subjects

Biology (General), QH301-705.5

Abstract

mTORC1 controls key processes that regulate cell growth, including mRNA translation, ribosome biogenesis, and autophagy. Environmental amino acids activate mTORC1 by promoting its recruitment to the cytosolic surface of the lysosome, where its kinase is activated downstream of growth factor signaling. mTORC1 is brought to the lysosome by the Rag GTPases, which are tethered to the lysosomal membrane by Ragulator, a lysosome-bound scaffold. Here, we identify c17orf59 as a Ragulator-interacting protein that regulates mTORC1 activity through its interaction with Ragulator at the lysosome. The binding of c17orf59 to Ragulator prevents Ragulator interaction with the Rag GTPases, both in cells and in vitro, and decreases Rag GTPase lysosomal localization. Disruption of the Rag-Ragulator interaction by c17orf59 impairs mTORC1 activation by amino acids by preventing mTOR from reaching the lysosome. By disrupting the Rag-Ragulator interaction to inhibit mTORC1, c17orf59 expression may represent another mechanism to modulate nutrient sensing by mTORC1.

Published

2015

3. Zonated leucine sensing by Sestrin-mTORC1 in the liver controls the response to dietary leucine

Author

Andrew L. Cangelosi, Anna M. Puszynska, Justin M. Roberts, Andrea Armani, Thao P. Nguyen, Jessica B. Spinelli, Tenzin Kunchok, Brianna Wang, Sze Ham Chan, Caroline A. Lewis, William C. Comb, George W. Bell, Aharon Helman, and David M. Sabatini

Subjects

Mice, Multidisciplinary, Liver, Leucine, Adipose Tissue, White, Sestrins, Animals, Mechanistic Target of Rapamycin Complex 1, Article, Diet, Signal Transduction

Abstract

The mechanistic target of rapamycin complex 1 (mTORC1) kinase controls growth in response to nutrients, including the amino acid leucine. In cultured cells, mTORC1 senses leucine through the leucine-binding Sestrin proteins, but the physiological functions and distribution of Sestrin-mediated leucine sensing in mammals are unknown. We find that mice lacking Sestrin1 and Sestrin2 cannot inhibit mTORC1 upon dietary leucine deprivation and suffer a rapid loss of white adipose tissue (WAT) and muscle. The WAT loss is driven by aberrant mTORC1 activity and fibroblast growth factor 21 (FGF21) production in the liver. Sestrin expression in the liver lobule is zonated, accounting for zone-specific regulation of mTORC1 activity and FGF21 induction by leucine. These results establish the mammalian Sestrins as physiological leucine sensors and reveal a spatial organization to nutrient sensing by the mTORC1 pathway.

Published

2022

4. A unified model of amino acid homeostasis in mammalian cells

Author

Kiran Javed, Jade Vennitti, Gregory Gauthier-Coles, Zhiduo Zhang, Angelika Bröer, Stefan Bröer, and William C. Comb

Subjects

chemistry.chemical_classification, Cytosol, Amino acid homeostasis, Biochemistry, Chemistry, In silico, Transporter, Metabolism, Intracellular, Homeostasis, Amino acid

Abstract

Homeostasis is one of the fundamental concepts in physiology. Despite remarkable progress in our molecular understanding of amino acid transport, metabolism and signalling, it remains unclear by what mechanisms cytosolic amino acid concentrations are maintained. We propose that amino acid transporters are the primary determinants of intracellular amino acid levels. We show that a cell’s endowment with amino acid transporters can be deconvoluted by a logical series of experiments. This was used to computationally simulate amino acid translocation across the plasma membrane. For two different cancer cell lines and human myotubes, transport simulation generates cytosolic amino acid concentrations that are close to those observed in vitro. Perturbations of the system were replicated in silico and could be applied to systems where only transcriptomic data are available. The methodology developed in this study is widely applicable to other transport processes and explain amino acid homeostasis at the systems-level.

Published

2021

5. Quantitative modelling of amino acid transport and homeostasis in mammalian cells

Author

Kiran Javed, Zhiduo Zhang, Angelika Bröer, William C. Comb, Jade Vennitti, Gregory Gauthier-Coles, Stefan Bröer, and Shuran Xing

Subjects

Amino Acid Transport Systems, In silico, Science, General Physics and Astronomy, Gene Expression, General Biochemistry, Genetics and Molecular Biology, Article, 03 medical and health sciences, Xenopus laevis, 0302 clinical medicine, Amino acid homeostasis, Cell Line, Tumor, Membrane proteins, Animals, Homeostasis, Humans, Metabolomics, Computer Simulation, Amino Acids, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, Multidisciplinary, Models, Statistical, Cell Membrane, Transporter, Biological Transport, General Chemistry, Metabolism, Amino acid, Cytosol, Kinetics, chemistry, Membrane protein, Biochemistry, A549 Cells, 030220 oncology & carcinogenesis, Computer modelling, Oocytes, Neuroglia, Intracellular

Abstract

Homeostasis is one of the fundamental concepts in physiology. Despite remarkable progress in our molecular understanding of amino acid transport, metabolism and signaling, it remains unclear by what mechanisms cytosolic amino acid concentrations are maintained. We propose that amino acid transporters are the primary determinants of intracellular amino acid levels. We show that a cell’s endowment with amino acid transporters can be deconvoluted experimentally and used this data to computationally simulate amino acid translocation across the plasma membrane. Transport simulation generates cytosolic amino acid concentrations that are close to those observed in vitro. Perturbations of the system are replicated in silico and can be applied to systems where only transcriptomic data are available. This work explains amino acid homeostasis at the systems-level, through a combination of secondary active transporters, functionally acting as loaders, harmonizers and controller transporters to generate a stable equilibrium of all amino acid concentrations., Cytosolic amino acid concentrations are carefully maintained, but how homeostasis occurs is unclear. Here, the authors show that amino acid transporters primarily determine intracellular amino acid levels and develop a model that predicts a perturbation response similar to experimental data.

Published

2020

6. Lysosomal amino acid transporter SLC38A9 signals arginine sufficiency to mTORC1

Author

Roberto Zoncu, David M. Sabatini, William C. Comb, Bernardo L. Sabatini, Lynne Chantranupong, Rachel L. Wolfson, Molly Plovanich, Zhi-Yang Tsun, Shuyu Wang, Choah Kim, Christoph Straub, Kuang Shen, Tony D. Jones, Liron Bar-Peled, Timothy C. Wang, Gregory A. Wyant, Jiwon Park, and Elizabeth D. Yuan

Subjects

chemistry.chemical_classification, Multidisciplinary, biology, Arginine, GTPase, mTORC1, Amino acid, Protein structure, Biochemistry, chemistry, biology.protein, Amino acid transporter, biological phenomena, cell phenomena, and immunity, Peptide sequence, RHEB

Abstract

Sensing amino acids at the lysosome The mTORC1 protein kinase is a complex of proteins that functions to regulate growth and metabolism. Activity of mTORC1 is sensitive to the abundance of amino acids, but how the sensing of amino acids is coupled to the control of mTORC1 has been unclear. Wang et al. searched for predicted membrane proteins that interacted with regulators of mTORC1. They identified a protein currently known only as SLC38A9. Interaction of SLC38A9 with mTORC1 regulators was sensitive to the presence of amino acids. SLC38A9 has sequence similarity to amino acid transporters. Effects of modulation of SLC38A9 in cultured human cells indicate that it may be the sensor that connects the abundance of arginine and leucine to mTORC1 activity. Science , this issue p. 188

Published

2015

7. IKK-dependent, NF-κB-independent control of autophagic gene expression

Author

Patricia C. Cogswell, Raquel Sitcheran, William C. Comb, and Albert S. Baldwin

Subjects

Cancer Research, ATG5, Regulator, Gene Expression, IκB kinase, Biology, environment and public health, Article, Mice, chemistry.chemical_compound, Gene expression, Autophagy, Genetics, Animals, skin and connective tissue diseases, CHUK, Molecular Biology, NF-kappa B, NF-κB, Fibroblasts, NFKB1, I-kappa B Kinase, Cell biology, enzymes and coenzymes (carbohydrates), chemistry, Starvation, Cancer research, biological phenomena, cell phenomena, and immunity

Abstract

The induction of mammalian autophagy, a cellular catabolic bulk-degradation process conserved from humans to yeast, was recently shown to require IκB kinase (IKK), the upstream regulator of the nuclear factor (NF)-κB pathway. Interestingly, it was shown that this response did not involve NF-κB. Thus, the mechanism by which IKK promotes stimulus-induced autophagy is largely unknown. Here, we investigate the role of IKK/NF-κB in response to nutrient deprivation, the well-understood autophagy-inducing stimulus. IKK and both the classic and non-canonical pathways of NF-κB are robustly induced in response to cellular starvation. Notably, cells lacking either catalytic subunit of IKK (IKK-α or IKK-β) fail to induce autophagy in response to cellular starvation. Importantly, we show that IKK activity but not NF-κB controls basal expression of the proautophagic gene LC3. We further demonstrate that starvation induces the expression of LC3 and two other essential autophagic genes ATG5 and Beclin-1 in an IKK-dependent manner. These results indicate that the IKK complex is a central mediator of starvation-induced autophagy in mammalian cells, and suggest that this requirement occurs at least in part through the regulation of autophagic gene expression. Interestingly, NF-κB subunits are dispensable for both basal and starvation-induced expression of proautophagic genes. However, starvation-induced activation of NF-κB is not inconsequential, as increases in expression of antiapoptotic NF-κB target genes such as Birc3 are observed in response to cellular starvation. Thus, IKK likely has multiple roles in response to starvation by regulating NF-κB-dependent antiapoptotic gene expression as well as controlling expression of autophagic genes through a yet undetermined mechanism.

Published

2010

8. Disruption of the Rag-Ragulator Complex by c17orf59 Inhibits mTORC1

Author

Liron Bar-Peled, William C. Comb, David M. Sabatini, Lawrence D. Schweitzer, Massachusetts Institute of Technology. Department of Biology, Schweitzer, Lawrence David, Bar-Peled, Liron, and Sabatini, David

Subjects

Ribosome biogenesis, mTORC1, Nutrient sensing, GTPase, Biology, Mechanistic Target of Rapamycin Complex 1, General Biochemistry, Genetics and Molecular Biology, Article, Lysosome, medicine, Humans, lcsh:QH301-705.5, Adaptor Proteins, Signal Transducing, Monomeric GTP-Binding Proteins, TOR Serine-Threonine Kinases, Autophagy, Signal transducing adaptor protein, Ragulator complex, Cell biology, medicine.anatomical_structure, HEK293 Cells, Biochemistry, lcsh:Biology (General), Multiprotein Complexes, biological phenomena, cell phenomena, and immunity, Lysosomes, HeLa Cells, Protein Binding

Abstract

mTORC1 controls key processes that regulate cell growth, including mRNA translation, ribosome biogenesis, and autophagy. Environmental amino acids activate mTORC1 by promoting its recruitment to the cytosolic surface of the lysosome, where its kinase is activated downstream of growth factor signaling. mTORC1 is brought to the lysosome by the Rag GTPases, which are tethered to the lysosomal membrane by Ragulator, a lysosome-bound scaffold. Here, we identify c17orf59 as a Ragulator-interacting protein that regulates mTORC1 activity through its interaction with Ragulator at the lysosome. The binding of c17orf59 to Ragulator prevents Ragulator interaction with the Rag GTPases, both in cells and in vitro, and decreases Rag GTPase lysosomal localization. Disruption of the Rag-Ragulator interaction by c17orf59 impairs mTORC1 activation by amino acids by preventing mTOR from reaching the lysosome. By disrupting the Rag-Ragulator interaction to inhibit mTORC1, c17orf59 expression may represent another mechanism to modulate nutrient sensing by mTORC1., United States. National Institutes of Health (R01 CA129105), United States. National Institutes of Health (R37 AI047389), United States. National Institutes of Health (R01 CA103866), United States. National Institutes of Health (R21 AG042876-01A1), United States. Department of Defense (W81XWH-07-0448), United States. National Institutes of Health (F31 CA167872), American Cancer Society (PF-13-356-01-TBE)

Published

2015

9. Nutrient Sensing Mechanisms and Pathways

Author

William C. Comb, David M. Sabatini, Alejo Efeyan, Massachusetts Institute of Technology. Department of Biology, Whitehead Institute for Biomedical Research, Koch Institute for Integrative Cancer Research at MIT, Efeyan, Alejo, Comb, William C., and Sabatini, David M.

Subjects

Multidisciplinary, Anabolism, Autophagy, Nutrient sensing, Metabolism, Carbohydrate metabolism, Biology, Lipid Metabolism, Article, Glucose, Biochemistry, Metabolic Diseases, Extracellular, Animals, Homeostasis, Humans, Amino Acids, Intracellular

Abstract

The ability to sense and respond to fluctuations in environmental nutrient levels is a requisite for life. Nutrient scarcity is a selective pressure that has shaped the evolution of most cellular processes. Different pathways that detect intracellular and extracellular levels of sugars, amino acids, lipids and surrogate metabolites are integrated and coordinated at the organismal level through hormonal signals. During food abundance, nutrient-sensing pathways engage anabolism and storage, whereas scarcity triggers homeostatic mechanisms, such as the mobilization of internal stores through autophagy. Nutrient-sensing pathways are commonly deregulated in human metabolic diseases., National Institutes of Health (U.S.) (Grant R01 CA129105), National Institutes of Health (U.S.) (Grant R01 CA103866), National Institutes of Health (U.S.) (Grant R01 AI047389), National Institutes of Health (U.S.) (Grant R21 AG042876), American Federation for Aging Research, Starr Foundation, David H. Koch Institute for Integrative Cancer Research at MIT (Frontier Research Program), Ellison Medical Foundation, Charles A. King Trust, American Cancer Society (Ellison Medical Foundation Postdoctoral Fellowship PF-13-356-01-TBE)

Published

2015

10. P85α SH2 Domain Phosphorylation by IKK Promotes Feedback Inhibition of PI3K and Akt in Response to Cellular Starvation

Author

Jessica E. Hutti, Lewis C. Cantley, Albert S. Baldwin, William C. Comb, and Patricia C. Cogswell

Subjects

Cell, IκB kinase, macromolecular substances, Biology, SH2 domain, environment and public health, Cell Line, src Homology Domains, Mice, Phosphatidylinositol 3-Kinases, Leucine, medicine, Animals, Humans, Amino Acid Sequence, Amino Acids, Phosphorylation, Phosphotyrosine, CHUK, Molecular Biology, Protein kinase B, Conserved Sequence, PI3K/AKT/mTOR pathway, Feedback, Physiological, Autophagy, Cell Biology, Fibroblasts, I-kappa B Kinase, Class Ia Phosphatidylinositol 3-Kinase, Mice, Inbred C57BL, enzymes and coenzymes (carbohydrates), medicine.anatomical_structure, Biochemistry, Starvation, biological phenomena, cell phenomena, and immunity, Proto-Oncogene Proteins c-akt

Abstract

The IκB kinase (IKK) pathway is an essential mediator of inflammatory, oncogenic, and cell stress pathways. Recently IKK was shown to be essential for autophagy induction in mammalian cells independent of its ability to regulate NF-κB, but the mechanism by which this occurs is unclear. Here we demonstrate that the p85 regulatory subunit of PI3K is an IKK substrate, phosphorylated at S690 in vitro and in vivo in response to cellular starvation. Cells expressing p85 S690A or inhibited for IKK activity exhibit increased Akt activity following cell starvation, demonstrating that p85 phosphorylation is required for starvation-induced PI3K feedback inhibition. S690 is in a conserved region of the p85 cSH2 domain, and IKK-mediated phosphorylation of this site results in decreased affinity for tyrosine-phosphorylated proteins and decreased PI3K membrane localization. Finally, leucine deprivation is shown to be necessary and sufficient for starvation-induced, IKK-mediated p85 phosphorylation and PI3K feedback inhibition.

Published

2012

11. Essential role for epidermal growth factor receptor in glutamate receptor signaling to NF-kappaB

Author

Raquel Sitcheran, Albert S. Baldwin, Patricia C. Cogswell, and William C. Comb

Subjects

Transcriptional Activation, Receptor, Metabotropic Glutamate 5, Glycine, Intracellular Space, Glutamic Acid, Biology, Receptors, Metabotropic Glutamate, Cell Line, Mice, Animals, Humans, Calcium Signaling, Phosphorylation, Molecular Biology, Cell Proliferation, Phenylacetates, Cell Nucleus, Metabotropic glutamate receptor 5, Metabotropic glutamate receptor 7, Metabotropic glutamate receptor 6, Transcription Factor RelA, Cell Biology, Articles, Cell biology, I-kappa B Kinase, ErbB Receptors, Receptors, Glutamate, Metabotropic glutamate receptor, NMDA receptor, Metabotropic glutamate receptor 1, I-kappa B Proteins, Metabotropic glutamate receptor 3, Metabotropic glutamate receptor 2, Neuroglia, Protein Processing, Post-Translational, Signal Transduction

Abstract

Glutamate is a critical neurotransmitter of the central nervous system (CNS) and also an important regulator of cell survival and proliferation. The binding of glutamate to metabotropic glutamate receptors induces signal transduction cascades that lead to gene-specific transcription. The transcription factor NF-kappaB, which regulates cell proliferation and survival, is activated by glutamate; however, the glutamate receptor-induced signaling pathways that lead to this activation are not clearly defined. Here we investigate the glutamate-induced activation of NF-kappaB in glial cells of the CNS, including primary astrocytes. We show that glutamate induces phosphorylation, nuclear accumulation, DNA binding, and transcriptional activation function of glial p65. The glutamate-induced activation of NF-kappaB requires calcium-dependent IkappaB kinase alpha (IKKalpha) and IKKbeta activation and induces p65-IkappaBalpha dissociation in the absence of IkappaBalpha phosphorylation or degradation. Moreover, glutamate-induced IKK preferentially targets the phosphorylation of p65 but not IkappaBalpha. Finally, we show that the ability of glutamate to activate NF-kappaB requires cross-coupled signaling with the epidermal growth factor receptor. Our results provide insight into a glutamate-induced regulatory pathway distinct from that described for cytokine-induced NF-kappaB activation and have important implications with regard to both normal glial cell physiology and pathogenesis.

Published

2008

12. Dihydropyrimidine Accumulation Is Required for the Epithelial-Mesenchymal Transition

Author

David M. Sabatini, Jason R. Cantor, Michael B. Yaffe, William C. Comb, Dohoon Kim, Walter W. Chen, Robert A. Weinberg, Elizaveta Freinkman, Prathapan Thiru, Michael E. Pacold, Wai Leong Tam, Yoav D. Shaul, Brian Bierie, Ferenc Reinhardt, Richard Possemato, Naama Kanarek, Massachusetts Institute of Technology. Department of Biological Engineering, Massachusetts Institute of Technology. Department of Biology, Whitehead Institute for Biomedical Research, Ludwig Center for Molecular Oncology (Massachusetts Institute of Technology), Koch Institute for Integrative Cancer Research at MIT, Shaul, Yoav, Kim, Dohoon, Pacold, Michael E, Chen, Walter W., Possemato, Richard, Reinhardt, Ferenc, Weinberg, Robert A, Yaffe, Michael B, and Sabatini, David

Subjects

Epithelial-Mesenchymal Transition, Cell, Biology, General Biochemistry, Genetics and Molecular Biology, Article, Mesoderm, Mice, Cell Line, Tumor, Dihydropyrimidine dehydrogenase, medicine, Animals, Humans, Epithelial–mesenchymal transition, RNA, Small Interfering, Dihydrouracil Dehydrogenase (NADP), Biochemistry, Genetics and Molecular Biology(all), Cell growth, Gene Expression Profiling, Mesenchymal stem cell, Carcinoma, Gene signature, Flow Cytometry, Molecular biology, 3. Good health, medicine.anatomical_structure, Pyrimidines, Cancer cell, Cancer research, DPYD

Abstract

It is increasingly appreciated that oncogenic transformation alters cellular metabolism to facilitate cell proliferation, but less is known about the metabolic changes that promote cancer cell aggressiveness. Here, we analyzed metabolic gene expression in cancer cell lines and found that a set of high-grade carcinoma lines expressing mesenchymal markers share a unique 44 gene signature, designated the “mesenchymal metabolic signature” (MMS). A FACS-based shRNA screen identified several MMS genes as essential for the epithelial-mesenchymal transition (EMT), but not for cell proliferation. Dihydropyrimidine dehydrogenase (DPYD), a pyrimidine-degrading enzyme, was highly expressed upon EMT induction and was necessary for cells to acquire mesenchymal characteristics in vitro and for tumorigenic cells to extravasate into the mouse lung. This role of DPYD was mediated through its catalytic activity and enzymatic products, the dihydropyrimidines. Thus, we identify metabolic processes essential for the EMT, a program associated with the acquisition of metastatic and aggressive cancer cell traits., United States. National Institutes of Health (RO1 CA103866), United States. National Institutes of Health (AI047389), United States. National Institutes of Health (K99 CA168940), American Cancer Society (PF-12-099-01-TGB), American Cancer Society (PF-13-356-01-TBE), United States. Department of Defense (BC123066), United States. National Institutes of Health (CA112967), United States. National Institutes of Health (ES015339)