Rebecca A. Kohnz scite author profile

Adenosine monophosphate-activated protein kinase (AMPK) is a conserved sensor of intracellular energy activated in response to low nutrient availability and environmental stress. In a screen for conserved substrates of AMPK, we identified ULK1 and ULK2, mammalian orthologs of the yeast protein kinase Atg1, which is required for autophagy. Genetic analysis of AMPK or ULK1 in mammalian liver and C. elegans revealed a requirement for these kinases in autophagy. In mammals, loss of AMPK or ULK1 resulted in aberrant accumulation of the autophagy adaptor p62 and defective mitophagy. Reconstitution of ULK1-deficient cells with a mutant ULK1 that cannot be phosphorylated by AMPK revealed that such phosphorylation is required for mitochondrial homeostasis and cell survival following starvation. These findings uncover a conserved biochemical mechanism coupling nutrient status with autophagy and cell survival.

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Inhibition of fatty acid oxidation as a therapy for MYC-overexpressing triple-negative breast cancer

Camarda

Zhou

Kohnz

et al. 2016

Nat Med

427

347

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Expression of the oncogenic transcription factor MYC is disproportionately elevated in triple-negative breast cancer (TNBC) compared to estrogen, progesterone and human epidermal growth factor 2 receptor-positive (RP) breast tumors1,2. We and others have shown that MYC alters metabolism during tumorigenesis3,4. However, the role of MYC in TNBC metabolism remains largely unexplored. We hypothesized that MYC-dependent metabolic dysregulation is essential for MYC-overexpressing (MO) TNBC and may thus identify novel therapeutic targets for this clinically challenging subset of breast cancer. Using a targeted metabolomics approach, we identified fatty acid oxidation (FAO) intermediates as being dramatically upregulated in a MYC-driven model of TNBC. A lipid metabolism gene signature was identified in patients with TNBC from The Cancer Genome Atlas (TCGA) database and multiple other clinical datasets, implicating FAO as a dysregulated pathway critical for TNBC metabolism. We find that MO-TNBC displays increased bioenergetic reliance upon fatty acid oxidation (FAO), and that pharmacologic inhibition of FAO catastrophically decreases energy metabolism of MO-TNBC, blocks growth of a MYC-driven transgenic TNBC model and that of MO-TNBC patient-derived xenografts. Our results demonstrate that inhibition of FAO is a novel therapeutic strategy against MO-TNBC.

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Mitochondrial DNA Replication Defects Disturb Cellular dNTP Pools and Remodel One-Carbon Metabolism

et al. 2016

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Mitochondrial dysfunction affects cellular energy metabolism, but less is known about the consequences for cytoplasmic biosynthetic reactions. We report that mtDNA replication disorders caused by TWINKLE mutations-mitochondrial myopathy (MM) and infantile onset spinocerebellar ataxia (IOSCA)-remodel cellular dNTP pools in mice. MM muscle shows tissue-specific induction of the mitochondrial folate cycle, purine metabolism, and imbalanced and increased dNTP pools, consistent with progressive mtDNA mutagenesis. IOSCA-TWINKLE is predicted to hydrolyze dNTPs, consistent with low dNTP pools and mtDNA depletion in the disease. MM muscle also modifies the cytoplasmic one-carbon cycle, transsulfuration, and methylation, as well as increases glucose uptake and its utilization for de novo serine and glutathione biosynthesis. Our evidence indicates that the mitochondrial replication machinery communicates with cytoplasmic dNTP pools and that upregulation of glutathione synthesis through glucose-driven de novo serine biosynthesis contributes to the metabolic stress response. These results are important for disorders with primary or secondary mtDNA instability and offer targets for metabolic therapy.

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Lipid Biosynthesis Coordinates a Mitochondrial-to-Cytosolic Stress Response

Kim

Grant

Simić

et al. 2016

Cell

188

155

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SUMMARY Defects in mitochondrial metabolism have been increasingly linked with age-onset protein-misfolding dieases such as Alzheimer’s, Parkinson’s, and Huntington’s. In response to protein-folding stress, compartment-specific unfolded protein responses (UPRs) within the ER, mitochondria, and cytosol work in parallel to ensure cellular protein homeostasis. While perturbation of individual compartments can make other compartments more susceptible to protein stress, the cellular conditions that trigger cross-communication between the individual UPRs remain poorly understood. We have uncovered a conserved, robust mechanism linking mitochondrial protein homeostasis and the cytosolic folding environment through changes in lipid homeostasis. Metabolic restructuring caused by mitochondrial stress or small-molecule activators trigger changes in gene expression coordinated uniquely by both the mitochondrial and cytosolic UPRs, protecting the cell from disease-associated proteins. Our data suggest an intricate and unique system of communication between UPRs in response to metabolic changes that could unveil new targets for diseases of protein misfolding.

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Rebecca A. Kohnz

Phosphorylation of ULK1 (hATG1) by AMP-Activated Protein Kinase Connects Energy Sensing to Mitophagy

Inhibition of fatty acid oxidation as a therapy for MYC-overexpressing triple-negative breast cancer

Mitochondrial DNA Replication Defects Disturb Cellular dNTP Pools and Remodel One-Carbon Metabolism

Lipid Biosynthesis Coordinates a Mitochondrial-to-Cytosolic Stress Response

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