Supporting Aspartate Biosynthesis Is an Essential Function of Respiration in Proliferating Cells

SummaryMitochondrial respiration is important for cell proliferation; however, the specific metabolic requirements fulfilled by respiration to support proliferation have not been defined. Here, we show that a major role of respiration in proliferating cells is to provide electron acceptors for aspartate synthesis. This finding is consistent with the observation that cells lacking a functional respiratory chain are auxotrophic for pyruvate, which serves as an exogenous electron acceptor. Further, the pyruvate requirement can be fulfilled with an alternative electron acceptor, alpha-ketobutyrate, which provides cells neither carbon nor ATP. Alpha-ketobutyrate restores proliferation when respiration is inhibited, suggesting that an alternative electron acceptor can substitute for respiration to support proliferation. We find that electron acceptors are limiting for producing aspartate, and supplying aspartate enables proliferation of respiration deficient cells in the absence of exogenous electron acceptors. Together, these data argue a major function of respiration in proliferating cells is to support aspartate synthesis

Environment Dictates Dependence on Mitochondrial Complex I for NAD+ and Aspartate Production and Determines Cancer Cell Sensitivity to Metformin

Metformin use is associated with reduced cancer mortality, but how metformin impacts cancer outcomes is controversial. Although metformin can act on cells autonomously to inhibit tumor growth, the doses of metformin that inhibit proliferation in tissue culture are much higher than what has been described in vivo. Here, we show that the environment drastically alters sensitivity to metformin and other complex I inhibitors. We find that complex I supports proliferation by regenerating nicotinamide adenine dinucleotide (NAD)+, and metformin's anti-proliferative effect is due to loss of NAD+/NADH homeostasis and inhibition of aspartate biosynthesis. However, complex I is only one of many inputs that determines the cellular NAD+/NADH ratio, and dependency on complex I is dictated by the activity of other pathways that affect NAD+ regeneration and aspartate levels. This suggests that cancer drug sensitivity and resistance are not intrinsic properties of cancer cells, and demonstrates that the environment can dictate sensitivity to therapies that impact cell metabolism. Keywords: cancer metabolism; metformin; biguanide; NAD+/NADH ratio; drug sensitivity; complex I; mitochondria; aspartateNational Institutes of Health (U.S.) (Grant P30CA1405141)National Institutes of Health (U.S.) (Grant GG006413)National Institutes of Health (U.S.) (Grant R01 CA168653)National Institutes of Health (U.S.) (Grant R01 CA201276

Tissue of origin dictates branched-chain amino acid metabolism in mutant Kras-driven cancers

Tumor genetics guides patient selection for many new therapies, and cell culture studies have demonstrated that specific mutations can promote metabolic phenotypes. However, whether tissue context defines cancer dependence on specific metabolic pathways is unknown. Kras activation and Trp53 deletion in the pancreas or the lung result in pancreatic ductal adenocarinoma (PDAC) or non-small cell lung carcinoma (NSCLC), respectively, but despite the same initiating events, these tumors use branched-chain amino acids (BCAAs) differently. NSCLC tumors incorporate free BCAAs into tissue protein and use BCAAs as a nitrogen source, whereas PDAC tumors have decreased BCAA uptake. These differences are reflected in expression levels of BCAA catabolic enzymes in both mice and humans. Loss of Bcat1 and Bcat2, the enzymes responsible for BCAA use, impairs NSCLC tumor formation, but these enzymes are not required for PDAC tumor formation, arguing that tissue of origin is an important determinant of how cancers satisfy their metabolic requirements.National Institutes of Health (U.S.) (Grant F30CA183474)National Institutes of Health (U.S.) (Grant T32GM007753

Defining the contributors to mammalian cell mass

Thesis: Ph. D., Massachusetts Institute of Technology, Department of Biology, 2017.Cataloged from PDF version of thesis. Vita.Includes bibliographical references.Proliferation can be thought of as the sum of many biosynthetic processes. To proliferate, a cell must not only physically divide but must also newly synthesize each of its components as it progresses through the cell cycle. Metabolism allows a cell to meet these demands. Metabolic alterations associated with proliferating cells have been characterized, and increasing research interest seeks to provide mechanistic and teleological insight into these metabolic alterations. The following dissertation provides a framework for understanding how proliferating mammalian cells use the nutrients available to them to synthesize macromolecule precursors that are ultimately used to synthesize new cell mass. Substantial research efforts have focussed on the abilities of glucose and glutamine to serve as sources of biosynthetic material for cell growth, especially since proliferating cells avidly consume these nutrients. Many other nutrients are consumed at much lower rates, and we have quantified how each contributes to biosynthesis, demonstrating that amino acids are the primary contributors to mammalian cell mass. Although glucose consumption does not directly relate to its contribution to cell mass, glycolytic flux is important to sustain cell growth, and activation of this pathway is thought to promote biosynthesis. To better understand regulation of this pathway, we have explored the biochemical properties of two glycolytic enzymes, pyruvate kinase and enolase. Although pyruvate kinase isoform M2 (PKM2) expression enables proliferation in some contexts, we demonstrate that this is not because of its putative activity as a protein kinase. We additionally characterize a novel modification of enolase by its substrate, phosphoenolpyruvate, which can covalently modify a catalytic residue and inhibit enzyme activity. These studies collectively contribute to an understanding of how metabolism can support rapid proliferation in mammalian cells, and lay the foundation for future studies to understand proliferative metabolism.by Aaron M. Hosios.Ph. D

The redox requirements of proliferating mammalian cells

Cell growth and division require nutrients, and proliferating cells use a variety of sources to acquire the amino acids, lipids, and nucleotides that support macromolecule synthesis. Lipids are more reduced than other nutrients, whereas nucleotides and amino acids are typically more oxidized. Cells must therefore generate reducing and oxidizing (redox) equivalents to convert consumed nutrients into biosynthetic precursors. To that end, redox cofactor metabolism plays a central role in meeting cellular redox requirements. In this Minireview, we highlight the biosynthetic pathways that involve redox reactions and discuss their integration with metabolism in proliferating mammalian cells

Acetate metabolism in cancer cells

Macromolecule biosynthesis is required to duplicate cell components and support proliferation. Studies examining the nutrients used by cancer cells have focused on the contribution of glucose and glutamine carbon for biosynthesis, but the importance of other metabolic fuels is becoming apparent. Labeling of two-carbon units in newly synthesized lipids has been used to infer the nutrients that contribute to the acetyl-CoA pools in cells. Glucose- and glutamine-derived carbon are known to contribute extensively to de novo lipid biosynthesis, and in this issue Kamphorst et al. find that extracellular acetate can also contribute substantially to this process [1]

The mTORC1-mediated activation of ATF4 promotes protein and glutathione synthesis downstream of growth signals

The mechanistic target of rapamycin complex 1 (mTORC1) stimulates a coordinated anabolic program in response to growth-promoting signals. Paradoxically, recent studies indicate that mTORC1 can activate the transcription factor ATF4 through mechanisms distinct from its canonical induction by the integrated stress response (ISR). However, its broader roles as a downstream target of mTORC1 are unknown. Therefore, we directly compared ATF4-dependent transcriptional changes induced upon insulin-stimulated mTORC1 signaling to those activated by the ISR. In multiple mouse embryo fibroblast and human cancer cell lines, the mTORC1-ATF4 pathway stimulated expression of only a subset of the ATF4 target genes induced by the ISR, including genes involved in amino acid uptake, synthesis, and tRNA charging. We demonstrate that ATF4 is a metabolic effector of mTORC1 involved in both its established role in promoting protein synthesis and in a previously unappreciated function for mTORC1 in stimulating cellular cystine uptake and glutathione synthesis.ISSN:2050-084