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Viruses hijack host cell metabolism to acquire the building blocks required for replication. Understanding how SARS-CoV-2 alters host cell metabolism may lead to potential treatments for COVID-19. Here we profile metabolic changes conferred by SARS-CoV-2 infection in kidney epithelial cells and lung air-liquid interface (ALI) cultures, and show that SARS-CoV-2 infection increases glucose carbon entry into the TCA cycle via increased pyruvate carboxylase expression. SARS-CoV-2 also reduces oxidative glutamine metabolism while maintaining reductive carboxylation. Consistent with these changes, SARS-CoV-2 infection increases the activity of mTORC1 in cell lines and lung ALI cultures. Lastly, we show evidence of mTORC1 activation in COVID-19 patient lung tissue, and that mTORC1 inhibitors reduce viral replication in kidney epithelial cells and lung ALI cultures. Our results suggest that targeting mTORC1 may be a feasible treatment strategy for COVID-19 patients, although further studies are required to determine the mechanism of inhibition and potential efficacy in patients. The pandemic of COVID-19, caused by SARS-CoV-2 infection, warrants immediate investigation for therapy options. Here the authors show, using epithelial and air-liquid interface cultures, that SARS-CoV-2 hijacks host cell metabolism to facilitate viral replication, and that inhibition of mTORC1, a master metabolic regulator, suppresses viral replication.

Renal oncocytoma (RO) is a benign renal neoplasm characterized by dense accumulation of dysfunctional mitochondria possibly resulting from increased mitochondrial biogenesis and decreased mitophagy; however, the mechanisms controlling these mitochondrial changes are unclear. ROs harbor recurrent inactivating mutations in mitochondrial genes encoding the Electron Transport Chain (ETC) Complex I, and we hypothesize that Complex I loss in ROs directly impairs mitophagy. Our analysis of ROs and normal kidney (NK) tissues shows that a significant portion (8 out of 17) of ROs have mtDNA Complex I loss-of-function mutations with high variant allele frequency (>50%). ROs indeed exhibit reduced Complex I expression and activity. Analysis of the various steps of mitophagy pathway demonstrates that AMPK activation in ROs leads to induction of mitochondrial biogenesis, autophagy, and formation of autophagosomes. However, the subsequent steps involving lysosome biogenesis and function are defective, resulting in an overall inhibition of mitophagy. Inhibiting Complex I in a normal kidney cell line recapitulated the observed lysosomal and mitophagy defects. Our data suggest Complex I loss in RO results in defective mitophagy due to lysosomal loss and dysfunction.

Objective To evaluate the fecal metabolome in patients with early systemic sclerosis (SSc) compared with unaffected controls and to determine if altered metabolites are associated with specific bacterial genera in patients with early SSc. Methods Stool samples and clinical data were collected from 106 patients with early SSc and 79 unaffected control patients. Targeted metabolomics was performed on fecal samples using liquid chromatography mass spectrometry, and 16S ribosomal RNA gene sequencing was used to determine the microbial composition of fecal samples. Results Compared with unaffected controls, patients with early SSc had higher levels of nicotinamide, 5’‐methylthioadenosine, and several short‐chain fatty acids (SCFAs) including valeric acid, propionic acid, and caproic acid. Conversely, patients with early SSc had lower levels of xylonic acid, orotate, methionine sulfoxide, and sarcosine. SCFAs were associated with unique bacterial genera, several of which were more abundant in patients with SSc compared with unaffected controls. Conclusion The fecal metabolome is altered in patients with early SSc, with a shift toward increased SCFAs.

Background: mTORC1 activity is dependent on the presence of micronutrients, including Asparagine (Asn), to promote anabolic cell signaling in many cancers. We hypothesized that targeting Asn metabolism would inhibit tumor growth by reducing mTORC1 activity in well-differentiated (WD)/dedifferentiated (DD) liposarcoma (LPS). Methods: Human tumor metabolomic analysis was utilized to compare abundance of Asn in WD vs. DD LPS. Gene set enrichment analysis (GSEA) compared relative expression among metabolic pathways upregulated in DD vs. WD LPS. Proliferation assays were performed for LPS cell lines and organoid models by using the combination treatment of electron transport chain (ETC) inhibitors with Asn-free media. 13C-Glucose-labeling metabolomics evaluated the effects of combination treatment on nucleotide synthesis. Murine xenograft models were used to assess the effects of ETC inhibition combined with PEGylated L-Asparaginase (PEG-Asnase) on tumor growth and mTORC1 signaling. Results: Asn was enriched in DD LPS compared to WD LPS. GSEA indicated that mTORC1 signaling was upregulated in DD LPS. Within available LPS cell lines and organoid models, the combination of ETC inhibition with Asn-free media resulted in reduced cell proliferation. Combination treatment inhibited nucleotide synthesis and promoted cell cycle arrest. In vivo, the combination of ETC inhibition with PEG-Asnase restricted tumor growth. Conclusions: Asn enrichment and mTORC1 upregulation are important factors contributing to WD/DD LPS tumor progression. Effective targeting strategies require limiting access to extracellular Asn and inhibition of de novo synthesis mechanisms. The combination of PEG-Asnase with ETC inhibition is an effective therapy to restrict tumor growth in WD/DD LPS.

Liver cancer is a leading cause of cancer-related death world-wide in part due to the shortage of effective therapies, and MYC overexpression defines an aggressive and especially difficult to treat subset of patients. Given MYC's ability to reprogram cancer cell metabolism, and the liver's role as a coordinator of systemic metabolism, we hypothesized that MYC induces metabolic dependencies that could be targeted to attenuate liver tumor growth. We discovered that MYC-driven liver cancers catabolize alanine in a GPT2-dependent manner to sustain their growth. GPT2 is the predominant alanine-catabolizing enzyme expressed in MYC-driven liver tumors and genetic ablation of GPT2 limited MYC-driven liver tumorigenesis. isotope tracing studies uncovered a role for alanine as a substrate for a repertoire of pathways including the tricarboxylic acid cycle, nucleotide production, and amino acid synthesis. Treating transgenic MYC-driven liver tumor mouse models with L-Cycloserine, a compound that inhibits GPT2, was sufficient to diminish the frequency of mouse tumor formation and attenuate growth of established human liver tumors. Thus, we identify a new targetable metabolic dependency that MYC-driven liver tumors usurp to ensure their survival.

As cancer cells evade therapeutic pressure and adopt alternate lineage identities not commonly observed in the tissue of origin, they likely adopt alternate metabolic programs to support their evolving demands. Targeting these alternative metabolic programs in distinct molecular subtypes of aggressive prostate cancer may lead to new therapeutic approaches to combat treatment-resistance. We identify the poorly studied metabolic enzyme Oxoglutarate Dehydrogenase-Like (OGDHL), named for its structural similarity to the tricarboxylic acid (TCA) cycle enzyme Oxoglutarate Dehydrogenase (OGDH), as an unexpected regulator of tumor growth, treatment-induced lineage plasticity, and DNA Damage in prostate cancer. While OGDHL has been described as a tumor-suppressor in various cancers, we find that its loss impairs prostate cancer cell proliferation and tumor formation. Loss of OGDHL profoundly alters Androgen Receptor inhibition-induced plasticity, including suppressing the neuroendocrine markers DLL3 and HES6, induces accumulation of the DNA damage response marker ƔH2AX, and reduces nucleotide synthesis. Our data suggest that OGDHL has minimal impact on TCA cycle activity, and that mitochondrial localization is not required for its regulation of prostate cancer plasticity and nucleotide metabolism. Finally, we demonstrate that OGDHL expression is tightly correlated with neuroendocrine differentiation in clinical prostate cancer. These findings underscore the importance of investigating poorly characterized metabolic genes as potential regulators of distinct molecular subtypes of aggressive cancer.

Characterization of cell type emergence during human cortical development, which enables unique human cognition, has focused primarily on anatomical and transcriptional characterizations. Metabolic processes in the human brain that allow for rapid expansion, but contribute to vulnerability to neurodevelopmental disorders, remain largely unexplored. We performed a variety of metabolic assays in primary tissue and stem cell derived cortical organoids and observed dynamic changes in core metabolic functions, including an unexpected increase in glycolysis during late neurogenesis. By depleting glucose levels in cortical organoids, we increased outer radial glia, astrocytes, and inhibitory neurons. We found the pentose phosphate pathway (PPP) was impacted in these experiments and leveraged pharmacological and genetic manipulations to recapitulate these radial glia cell fate changes. These data identify a new role for the PPP in modulating radial glia cell fate specification and generate a resource for future exploration of additional metabolic pathways in human cortical development.

Cells regularly adapt their metabolism in response to changes in their microenvironment or biosynthetic needs. Prostate cancer cells leverage this metabolic plasticity to evade therapies targeting the androgen receptor (AR) signaling pathway. For example, nucleotide metabolism plays a critical role in treatment-resistant prostate cancer by supporting DNA replication, DNA damage response and cell fate decisions. Identifying novel regulators of nucleotide metabolism in treatment-resistant cancer that are dispensable for the health of normal cells may lead to new therapeutic approaches less toxic than commonly used chemotherapies targeting nucleotide metabolism. We identify the metabolic enzyme Oxoglutarate Dehydrogenase-Like (OGDHL), named for its structural similarity to the tricarboxylic acid (TCA) cycle enzyme Oxoglutarate Dehydrogenase (OGDH), as a regulator of nucleotide metabolism, tumor growth, and treatment-induced plasticity in prostate cancer. While OGDHL is a tumor-suppressor in various cancers, we find that its loss impairs prostate cancer cell proliferation and tumor formation while having minimal impact on TCA cycle activity. Loss of OGDHL profoundly decreases nucleotide metabolite pools, induces the DNA damage response marker Ɣ2AX, and alters androgen receptor inhibition-induced plasticity, including suppressing the neuroendocrine markers DLL3 and HES6. Finally, OGDHL is highly expressed in neuroendocrine prostate cancer (NEPC). These findings support an unexpected role of OGDHL in prostate cancer, where it functions to sustain nucleotide pools for proliferation, DNA repair, and AR inhibition-induced plasticity.Cells regularly adapt their metabolism in response to changes in their microenvironment or biosynthetic needs. Prostate cancer cells leverage this metabolic plasticity to evade therapies targeting the androgen receptor (AR) signaling pathway. For example, nucleotide metabolism plays a critical role in treatment-resistant prostate cancer by supporting DNA replication, DNA damage response and cell fate decisions. Identifying novel regulators of nucleotide metabolism in treatment-resistant cancer that are dispensable for the health of normal cells may lead to new therapeutic approaches less toxic than commonly used chemotherapies targeting nucleotide metabolism. We identify the metabolic enzyme Oxoglutarate Dehydrogenase-Like (OGDHL), named for its structural similarity to the tricarboxylic acid (TCA) cycle enzyme Oxoglutarate Dehydrogenase (OGDH), as a regulator of nucleotide metabolism, tumor growth, and treatment-induced plasticity in prostate cancer. While OGDHL is a tumor-suppressor in various cancers, we find that its loss impairs prostate cancer cell proliferation and tumor formation while having minimal impact on TCA cycle activity. Loss of OGDHL profoundly decreases nucleotide metabolite pools, induces the DNA damage response marker Ɣ2AX, and alters androgen receptor inhibition-induced plasticity, including suppressing the neuroendocrine markers DLL3 and HES6. Finally, OGDHL is highly expressed in neuroendocrine prostate cancer (NEPC). These findings support an unexpected role of OGDHL in prostate cancer, where it functions to sustain nucleotide pools for proliferation, DNA repair, and AR inhibition-induced plasticity.

Mounting evidence supports an instructive role for metabolism in stem cell fate decisions. However, much is yet unknown about how fetal metabolism changes during mammalian development and how altered maternal metabolism shapes fetal metabolism. Here, we present a descriptive atlas of in vivo fetal murine metabolism during mid-to-late gestation in normal and diabetic pregnancy. Using 13C-glucose and LC-MS, we profiled the metabolism of fetal brains, hearts, livers, and placentas harvested from pregnant dams between embryonic days (E)10.5 and 18.5. Comparative analysis of our large metabolomics dataset revealed metabolic features specific to fetal tissues developed under a hyperglycemic environment as well as metabolic signatures that may denote developmental transitions during euglycemic development. We observed sorbitol accumulation in fetal tissues and altered neurotransmitter levels in fetal brains isolated from dams with maternal hyperglycemia. Tracing 13C-glucose revealed disparate nutrient sourcing in fetuses depending on maternal glycemic states. Regardless of glycemic state, histidine-derived metabolites accumulated during late development in fetal tissues and maternal plasma. Our rich dataset presents a comprehensive overview of in vivo fetal tissue metabolism and alterations occurring as a result of maternal hyperglycemia.

The tricarboxylic citric acid cycle enzyme fumarate hydratase (FH) is a tumor suppressor. When lost in cells, its substrate fumarate accumulates to mM levels and drives oncogenic signaling and transformation. Germline alterations lead to an autosomal dominant condition known as hereditary leiomyomatosis and renal cell cancer (HLRCC) where patients are predisposed to various benign tumors and an aggressive form of kidney cancer. FH alterations of unclear significance are frequently observed with germline testing; thus, there is an unmet need to classify FH variants by their cancer-associated risk, allowing for screening, early diagnosis and treatment. Here we quantify catalytic efficiency of 74 FH variants of uncertain significance. Over half were enzymatically inactive which is strong evidence of pathogenicity. We generated a panel of HLRCC cell lines expressing FH variants with a range of catalytic activities, then correlated fumarate levels with metabolic features. We found that fumarate accumulation blocks purine biosynthesis, rendering FH-deficient cells reliant on purine salvage to maintain purine nucleotide pools. Genetic or pharmacologic inhibition of the purine salvage pathway reduced HLRCC tumor growth in vivo. Together, these findings suggest pathogenicity of many patient-associated FH variants and reveal purine salvage as a targetable vulnerability in FH-deficient tumors.Competing Interest StatementThe authors have declared no competing interest.Footnotes* Addition of many pieces of in vitro and in vivo data supporting the conclusion that FH-deficient cells rely on purine salvage to maintain purine nucleotide levels and tumor growth.