ABSTRACT
Cancer cells adapt their metabolic processes to support rapid proliferation, but less is known about how cancer cells alter metabolism to promote cell survival in a poorly vascularized tumour microenvironment. Here we identify a key role for serine and glycine metabolism in the survival of brain cancer cells within the ischaemic zones of gliomas. In human glioblastoma multiforme, mitochondrial serine hydroxymethyltransferase (SHMT2) and glycine decarboxylase (GLDC) are highly expressed in the pseudopalisading cells that surround necrotic foci. We find that SHMT2 activity limits that of pyruvate kinase (PKM2) and reduces oxygen consumption, eliciting a metabolic state that confers a profound survival advantage to cells in poorly vascularized tumour regions. GLDC inhibition impairs cells with high SHMT2 levels as the excess glycine not metabolized by GLDC can be converted to the toxic molecules aminoacetone and methylglyoxal. Thus, SHMT2 is required for cancer cells to adapt to the tumour environment, but also renders these cells sensitive to glycine cleavage system inhibition.
Subject(s)
Brain Neoplasms/metabolism , Brain Neoplasms/pathology , Glioblastoma/metabolism , Glioblastoma/pathology , Glycine Hydroxymethyltransferase/metabolism , Glycine/metabolism , Ischemia/metabolism , Acetone/analogs & derivatives , Acetone/metabolism , Acetone/toxicity , Animals , Brain Neoplasms/blood supply , Brain Neoplasms/enzymology , Cell Hypoxia , Cell Line, Tumor , Cell Survival , Female , Glioblastoma/blood supply , Glioblastoma/enzymology , Glycine Dehydrogenase (Decarboxylating)/antagonists & inhibitors , Glycine Dehydrogenase (Decarboxylating)/metabolism , Humans , Ischemia/enzymology , Ischemia/pathology , Mice , Necrosis , Oxygen Consumption , Pyruvaldehyde/metabolism , Pyruvaldehyde/toxicity , Pyruvate Kinase/metabolism , Tumor Microenvironment , Xenograft Model Antitumor AssaysABSTRACT
Mitochondria must maintain adequate amounts of metabolites for protective and biosynthetic functions. However, how mitochondria sense the abundance of metabolites and regulate metabolic homeostasis is not well understood. In this work, we focused on glutathione (GSH), a critical redox metabolite in mitochondria, and identified a feedback mechanism that controls its abundance through the mitochondrial GSH transporter, SLC25A39. Under physiological conditions, SLC25A39 is rapidly degraded by mitochondrial protease AFG3L2. Depletion of GSH dissociates AFG3L2 from SLC25A39, causing a compensatory increase in mitochondrial GSH uptake. Genetic and proteomic analyses identified a putative iron-sulfur cluster in the matrix-facing loop of SLC25A39 as essential for this regulation, coupling mitochondrial iron homeostasis to GSH import. Altogether, our work revealed a paradigm for the autoregulatory control of metabolic homeostasis in organelles.
Subject(s)
ATP-Dependent Proteases , ATPases Associated with Diverse Cellular Activities , Glutathione , Mitochondria , Mitochondrial Proteins , Phosphate Transport Proteins , Glutathione/metabolism , Homeostasis , Iron/metabolism , Mitochondria/metabolism , Mitochondrial Membrane Transport Proteins/metabolism , Proteomics , Feedback, Physiological , Mitochondrial Proteins/metabolism , Phosphate Transport Proteins/metabolism , Humans , Iron-Sulfur Proteins/metabolism , Proteolysis , HEK293 Cells , ATP-Dependent Proteases/genetics , ATP-Dependent Proteases/metabolism , ATPases Associated with Diverse Cellular Activities/genetics , ATPases Associated with Diverse Cellular Activities/metabolismABSTRACT
As oxygen is essential for many metabolic pathways, tumour hypoxia may impair cancer cell proliferation1-4. However, the limiting metabolites for proliferation under hypoxia and in tumours are unknown. Here, we assessed proliferation of a collection of cancer cells following inhibition of the mitochondrial electron transport chain (ETC), a major metabolic pathway requiring molecular oxygen5. Sensitivity to ETC inhibition varied across cell lines, and subsequent metabolomic analysis uncovered aspartate availability as a major determinant of sensitivity. Cell lines least sensitive to ETC inhibition maintain aspartate levels by importing it through an aspartate/glutamate transporter, SLC1A3. Genetic or pharmacologic modulation of SLC1A3 activity markedly altered cancer cell sensitivity to ETC inhibitors. Interestingly, aspartate levels also decrease under low oxygen, and increasing aspartate import by SLC1A3 provides a competitive advantage to cancer cells at low oxygen levels and in tumour xenografts. Finally, aspartate levels in primary human tumours negatively correlate with the expression of hypoxia markers, suggesting that tumour hypoxia is sufficient to inhibit ETC and, consequently, aspartate synthesis in vivo. Therefore, aspartate may be a limiting metabolite for tumour growth, and aspartate availability could be targeted for cancer therapy.
Subject(s)
Aspartic Acid/metabolism , Cell Proliferation , Energy Metabolism , Neoplasms/metabolism , Tumor Hypoxia , Tumor Microenvironment , Adult , Aged , Aged, 80 and over , Animals , Antineoplastic Agents/pharmacology , Biological Transport , Cell Line, Tumor , Cell Proliferation/drug effects , Electron Transport Chain Complex Proteins/metabolism , Energy Metabolism/drug effects , Excitatory Amino Acid Transporter 1/genetics , Excitatory Amino Acid Transporter 1/metabolism , Humans , Metabolomics/methods , Mice, Inbred NOD , Mice, SCID , Middle Aged , Mitochondria/metabolism , Neoplasms/drug therapy , Neoplasms/genetics , Neoplasms/pathology , Signal Transduction , Time Factors , Tumor Burden , Xenograft Model Antitumor Assays , Young AdultABSTRACT
In the version of this Letter originally published, the competing interests statement was missing. The authors declare no competing interests; this statement has now been added in all online versions of the Letter.