Project description:Besides being building blocks for protein synthesis, amino acids serve a wide variety of cellular functions, including acting as metabolic intermediates for ATP generation and for redox homeostasis. Upon amino acid deprivation, free uncharged tRNAs trigger GCN2-ATF4 to mediate the well-characterized transcriptional amino acid response (AAR). However, it is not clear whether the deprivation of different individual amino acids triggers identical or distinct AARs. Here, we characterized the global transcriptional response upon deprivation of one amino acid at a time. With the exception of glycine, which was not required for the proliferation of MCF7 cells, we found that the deprivation of most amino acids triggered a shared transcriptional response that included the activation of ATF4, p53 and TXNIP. However, there was also significant heterogeneity among different individual AARs. The most dramatic transcriptional response was triggered by methionine deprivation, which activated an extensive and unique response in different cell types. We uncovered that the specific methionine-deprived transcriptional response required creatine biosynthesis. This dependency on creatine biosynthesis was caused by the consumption of S-Adenosyl-L-methionine (SAM) during creatine biosynthesis that helps to deplete SAM under methionine deprivation and reduces histone methylations. As such, the simultaneous deprivation of methionine and sources of creatine biosynthesis (either arginine or glycine) abolished the reduction of histone methylation and the methionine-specific transcriptional response. Arginine-derived ornithine was also required for the complete induction of the methionine-deprived specific gene response. Collectively, our data identify a previously unknown set of heterogeneous amino acid responses and reveal a distinct methionine-deprived transcriptional response that results from the crosstalk of arginine, glycine and methionine metabolism via arginine/glycine-dependent creatine biosynthesis. RNA was extracted by RNAeasy kits (Qiagen) from the MCF7 or PC3 cells which exposed to the control full DMEM or deprived one (or all) amino acid media for 24 or 48 hours.

Project description:Under stress conditions, cells elicit integrated stress response (ISR) to cope with intracellular and extracellular disturbances. However, its role in ischemic heart disease remains to be elucidated. Here, we show that oxygen deprivation in cardiomyocytes triggers significant changes in protein translation. Importantly, ischemia and ischemia/reoxygenation leads to suppression of protein synthesis, which is caused by activation of the PERK/eIF2α axis of ISR. At the functional level, cardiac specific elimination of PERK exacerbates cardiac response to ischemia/reperfusion whereas selective activation of PERK in the heart confers cardioprotection against reperfusion injury. Mechanistically, PERK-mediated improvement in cardiomyocyte survival depends on suppression of protein synthesis and consequently relieves energetic demand on mitochondria. We went further to show that mitochondrial complex components are targeted by protein translation suppression, which significantly diminishes mitochondria-associated production of reactive oxygen species. Indeed, pharmacological activation of ISR protects the heart from ischemia/reperfusion damage, even after the release of occluded coronary artery, highlighting clinical significance for myocardial infarction. Taken together, these findings suggest that ISR improves cell survival through selectively suppressing mitochondrial protein synthesis and reducing oxidative stress in ischemic heart disease.

Project description:Besides being building blocks for protein synthesis, amino acids serve a wide variety of cellular functions, including acting as metabolic intermediates for ATP generation and for redox homeostasis. Upon amino acid deprivation, free uncharged tRNAs trigger GCN2-ATF4 to mediate the well-characterized transcriptional amino acid response (AAR). However, it is not clear whether the deprivation of different individual amino acids triggers identical or distinct AARs. Here, we characterized the global transcriptional response upon deprivation of one amino acid at a time. With the exception of glycine, which was not required for the proliferation of MCF7 cells, we found that the deprivation of most amino acids triggered a shared transcriptional response that included the activation of ATF4, p53 and TXNIP. However, there was also significant heterogeneity among different individual AARs. The most dramatic transcriptional response was triggered by methionine deprivation, which activated an extensive and unique response in different cell types. We uncovered that the specific methionine-deprived transcriptional response required creatine biosynthesis. This dependency on creatine biosynthesis was caused by the consumption of S-Adenosyl-L-methionine (SAM) during creatine biosynthesis that helps to deplete SAM under methionine deprivation and reduces histone methylations. As such, the simultaneous deprivation of methionine and sources of creatine biosynthesis (either arginine or glycine) abolished the reduction of histone methylation and the methionine-specific transcriptional response. Arginine-derived ornithine was also required for the complete induction of the methionine-deprived specific gene response. Collectively, our data identify a previously unknown set of heterogeneous amino acid responses and reveal a distinct methionine-deprived transcriptional response that results from the crosstalk of arginine, glycine and methionine metabolism via arginine/glycine-dependent creatine biosynthesis.

Project description:Dietary methionine restriction is associated with a reduction in tumor growth in preclinical studies and an increase in lifespan in animal models. The mechanism by which methionine restriction inhibits tumor growth while sparing normal cells is incompletely understood, except for the observation that normal cells can utilize methionine or homocysteine interchangeably (methionine independence) while most cancer cells are strictly dependent on methionine availability. Here, we compared a typical methionine dependent and a rare methionine independent melanoma cell line. We found that replacing methionine with homocysteine generally induced hypomethylation in gene promoters. We isolated nuclear proteins and submitted it for tandem mass tag (TMT) proteomics. This analysis revealed that several proteins involved in the mitochondrial integrated stress response (ISR) were upregulated in response to the replacement of methionine to homocysteine in both cell lines, but to a much greater degree in the methionine dependent cell line. Consistent with the ISR signature, a proteomic analysis of a subcellular fraction enriched for mitochondrial content revealed a strong enrichment for proteins involved in oxidative phosphorylation. Analysis of cellular bioenergetics confirmed that homocysteine induces a decrease in ATP production from oxidative phosphorylation and glycolysis, but to a similar extent in methionine dependent and methionine independent cells. The mitochondrial integrated stress response shared a signature with ferroptosis. Methionine dependent cells displayed a strong ferroptotic signature, which was decreased by half in methionine independent cells. Consistent with ferroptosis, malonaldehyde was increased in methionine independent cells grown in homocysteine, and viability could be rescued with the inhibitor ferrostatin. Therefore, we propose that methionine stress induces ferroptotic cell death in methionine dependent cancer cells.

Project description:Renal ischemia-reperfusion injury (IRI) is a leading cause of acute kidney injury (AKI) and presents significant challenges during kidney transplantation. Due to the detrimental effects of IRI on kidney function and the lack of effective intervention strategies, we conduct a multi-omics study on surgically induced mouse IRI, revealing a modulatory role for the metabolite S-adenosylmethionine (SAM) in AKI development. Our metabolic analysis of clinical samples establishes a link between various AKI conditions and marked elevations in serum SAM, underlying its potential as a biomarker for diagnosis. Furthermore, we find that short-term dietary methionine deprivation, which reduces circulating methionine and kidney SAM levels, effectively enhances renal resilience against IRI. In vivo isotopic tracing demonstrates that this diet preconditions kidney metabolic programs, enhancing glucose and fatty acid oxidation in preparation for IRI. Particularly, the activation of pyruvate dehydrogenase, which produces acetyl-CoA to fuel the tricarboxylic acid (TCA) cycle, highlights an energy-efficient strategy of glucose metabolism that is essential for the protective effects of dietary methionine deprivation.

Project description:Mutations in several translation initiation factors are closely associated with premature ovarian insufficiency (POI). Here, we demonstrate that the conditional knockout of eukaryotic translation initiation factor 5 (Eif5) in both mouse primordial and growing oocytes resulted in the apoptosis of oocytes within the early growing follicles. The further studies revealed that Eif5 deletion in oocytes downregulated the levels of mitochondrial fission-related proteins (FIS1, MFF, MTFR2 and p-DRP1) and upregulated the levels of the integrated stress response (ISR)-related proteins (SLC7A1, SHMT2 and AARS1) and genes (Atf4, Ddit3 and Fgf21). Consistent with this, Eif5 deletion in oocytes resulted in mitochondrial dysfunction characterized by elongated form, aggregated distribution beneath the oocyte membrane, decreased ATP content and mtDNA copy number, and excessive accumulation of reactive oxygen species (ROS) and mitochondrial superoxide. Meanwhile, Eif5 deletion in oocytes led to a significant increase in the levels of DNAdamageresponse proteins (γH2AX, p-CHK2, and p53) and proapoptotic proteins (PUMA and BAX), as well as a significant decrease in the levels of anti-apoptotic protein BCL-xL. Collectively, these findings indicate that Eif5 deletion in mouse oocytes results in the apoptosis of oocytes within the early growing follicles via mitochondrial fission defect and excessive ROS-induced DNA damage. This study provides new insights into pathogenesis and genetic diagnosis for POI.

Project description:Renal ischemia-reperfusion injury (IRI) is a leading cause of acute kidney injury (AKI) and presents significant challenges during kidney transplantation. Due to the detrimental effects of IRI on kidney function and the lack of effective intervention strategies, we conduct a multi-omics study on surgically induced mouse IRI, revealing a modulatory role for the metabolite S-adenosylmethionine (SAM) in AKI development. Our metabolic analysis of clinical samples establishes a link between various AKI conditions and marked elevations in serum SAM, underlying its potential as a biomarker for diagnosis. Furthermore, we find that short-term dietary methionine deprivation, which reduces circulating methionine and kidney SAM levels, effectively enhances renal resilience against IRI. In vivo isotopic tracing demonstrates that this diet preconditions kidney metabolic programs, enhancing glucose and fatty acid oxidation in preparation for IRI. Particularly, the activation of pyruvate dehydrogenase, which produces acetyl-CoA to fuel the tricarboxylic acid (TCA) cycle, highlights an energy-efficient strategy of glucose metabolism that is essential for the protective effects of dietary methionine deprivation.

Project description:Pyrroloquinoline quinone (PQQ) is a naturally occurring compound and known to improve growth and reproductive performance when added to diets of PQQ-deprived rodents. To understand its mechanism of action, changes in hepatic gene expression were measured in rats fed diets with or without added PQQ. Of the ~10,000 genes and ESTs analyzed, 4.7% of the transcripts were sensitive to changes in PQQ dietary status. PQQ deprivation generally caused downregulation of genes associated with mitochondriogenesis, cell differentiation, and immune function. These gene expression changes provide the basis for most of the previously published functional observations associated with PQQ deficiency and PQQ administered in pharmacological amounts. To assess PQQ’s potential functions, we used gene expression profiling through microarray technology as part of a comprehensive approach to identify potential pathways and mechanisms. Given that the systemic effects of PQQ deprivation are influenced at levels of dietary intake in the micromolar range, highly purified diets were used to reduce expression from other bioactive factors and xenobiotics, such as those found in typical rodent chow diets. Dietary conditions were also chosen to clarify the response to PQQ deprivation. A goal was to determine if specific changes in dietary protocol or patterns could be used to identify genes important to the function of PQQ. Because it has been observed that mitochondrial-related functions are influenced by PQQ, we hypothesized that changes in genes important to fatty acid and amino acid metabolism and mitochondrial function would be likewise affected by dietary levels of PQQ. The overall study was carried out using two experiments. In this specific experiment, PQQ depletion and repletion was studied to understand the effect of PQQ on gene expression.

Project description:Cardiomyopathy and heart failure are common manifestations in mitochondrial disease caused by deficiencies in the oxidative phosphorylation system of mitochondria (OXPHOS). Here, we demonstrate that the cardiac-specific loss of the assembly factor Cox10 of the cytochrome c oxidase causes mitochondrial cardiomyopathy in mice, which is associated with OXPHOS deficiency, lysosomal defects and an aberrant mitochondrial morphology and ultrastructure. We demonstrate activation of the mitochondrial peptidase Oma1 in Cox10-/- mice, which results in mitochondrial fragmentation and induction of the integrated stress response (ISR) along the Oma1-Dele1-Atf4 signalling axis. Ablation of Oma1 or Dele1 in Cox10-/- mice aggravates cardiomyopathy. ISR inhibition impairs the cardiac glutathione metabolism, decreases the levels of the glutathione peroxidase Gpx4 and increases lipid peroxidation in the heart, ultimately culminating in ferroptosis. Our results demonstrate a protective role of the Oma1-mediated ISR in mitochondrial cardiomyopathy and link ferroptosis to OXPHOS deficiency and mitochondrial disease.

Project description:Methionine, a sulfur-containing essential amino acid, is a key component of dietary proteins important for protein synthesis, sulfur metabolism, antioxidant defense, and signaling. However, the role of methionine in cancer progression remains inconclusive. On one hand, dietary methionine restriction is known to repress cancer growth and improve cancer therapy in xenografted tumors. On the other hand, methionine is also critical for T cell activation and differentiation, making it a potential tumor suppression nutrient by enhancing T cell-mediated anti-tumor immunity. Here we investigated the interaction between dietary methionine, immune cells, and cancer cells by allografting CT26.WT mouse colon carcinoma cells into immunocompetent Balb/c mice or immunodeficient NSG mice, then analyzed how dietary methionine contents affect their growth. Our results show that dietary methionine restriction suppresses tumor growth in immunodeficient NSG mice but promotes tumor progression in immunocompetentt Balb/c mice.