Your search keyword '"Michael R. Martino"' showing total 9 results

1. Hepatic pyruvate and alanine metabolism are critical and complementary for maintenance of antioxidant capacity and resistance to oxidative insult in mice

Author

Nicole K.H. Yiew, Joel H. Vazquez, Michael R. Martino, Stefanie Kennon-McGill, Jake R. Price, Felicia D. Allard, Eric U. Yee, Laura P. James, Kyle S. McCommis, Brian N. Finck, and Mitchell R. McGill

Abstract

Pyruvate is a critical intermediary metabolite in gluconeogenesis, lipogenesis, as well as NADH production. As a result, there is growing interest in targeting the mitochondrial pyruvate carrier (MPC) complex in liver and metabolic diseases. However, recent in vitro data indicate that MPC inhibition diverts glutamine/glutamate away from glutathione synthesis and toward glutaminolysis to compensate for loss of pyruvate oxidation, possibly sensitizing cells to oxidative insult. Here, we explored this using the clinically relevant acetaminophen (APAP) overdose model of acute liver injury, which is driven by oxidative stress. We report that MPC inhibition does indeed sensitize the liver to APAP-induced injury in vivo, but only with concomitant loss of alanine aminotransferase 2 (ALT2). Pharmacologic and genetic manipulation of neither MPC2 nor ALT2 alone affected APAP toxicity, but liver-specific double knockout (DKO) of these proteins significantly worsened the liver damage. Further investigation confirmed that DKO impaired glutathione synthesis and increased urea cycle flux, consistent with increased glutaminolysis. Furthermore, APAP toxicity was exacerbated by inhibition of both the MPC and ALT in vitro. Thus, increased glutaminolysis and susceptibility to oxidative stress requires loss of both the MPC and ALT2 in vivo and exacerbates them in vitro. Finally, induction of ALT2 reduced APAP-induced injury.

Published

2022

2. Silencing alanine transaminase 2 in diabetic liver attenuates hyperglycemia by reducing gluconeogenesis from amino acids

Author

Michael R. Martino, Manuel Gutiérrez-Aguilar, Nicole K.H. Yiew, Andrew J. Lutkewitte, Jason M. Singer, Kyle S. McCommis, Daniel Ferguson, Kim H.H. Liss, Jun Yoshino, M. Katie Renkemeyer, Gordon I. Smith, Kevin Cho, Justin A. Fletcher, Samuel Klein, Gary J. Patti, Shawn C. Burgess, and Brian N. Finck

Subjects

Alanine, Gluconeogenesis, Alanine Transaminase, Mice, Inbred Strains, General Biochemistry, Genetics and Molecular Biology, Mice, Inbred C57BL, Mice, Glucose, Liver, Hyperglycemia, Diabetes Mellitus, Animals, Humans, Obesity, Amino Acids

Abstract

Hepatic gluconeogenesis from amino acids contributes significantly to diabetic hyperglycemia, but the molecular mechanisms involved are incompletely understood. Alanine transaminases (ALT1 and ALT2) catalyze the interconversion of alanine and pyruvate, which is required for gluconeogenesis from alanine. We find that ALT2 is overexpressed in the liver of diet-induced obese and db/db mice and that the expression of the gene encoding ALT2 (GPT2) is downregulated following bariatric surgery in people with obesity. The increased hepatic expression of Gpt2 in db/db liver is mediated by activating transcription factor 4, an endoplasmic reticulum stress-activated transcription factor. Hepatocyte-specific knockout of Gpt2 attenuates incorporation of

Published

2022

3. Silencing alanine transaminase 2 in diabetic liver attenuates hyperglycemia by reducing gluconeogenesis from amino acids

Author

Jason M. Singer, Kevin Cho, Kyle S. McCommis, Justin A. Fletcher, Gordon I. Smith, Shawn C. Burgess, Brian N. Finck, Nicole K.H. Yiew, Gary J. Patti, Michael R. Martino, Samuel Klein, Andrew J. Lutkewitte, and Manuel Gutiérrez-Aguilar

Subjects

Alanine, chemistry.chemical_classification, medicine.medical_specialty, Gene knockdown, biology, Chemistry, Endoplasmic reticulum, Activating Transcription Factor 4, medicine.disease, Amino acid, Endocrinology, Alanine transaminase, Gluconeogenesis, Internal medicine, Diabetes mellitus, medicine, biology.protein

Abstract

SUMMARYHepatic gluconeogenesis from amino acids contributes significantly to diabetic hyperglycemia, but the molecular mechanisms involved are incompletely understood. Alanine transaminases (ALT1 and ALT2) catalyze the interconversion of alanine and pyruvate, which is required for gluconeogenesis from alanine. We found that ALT2 was overexpressed in liver of diet-induced obese and db/db mice and that the expression of the gene encoding ALT2 (GPT2) was downregulated following bariatric surgery in people with obesity. The increased hepatic expression of Gpt2 in db/db liver was mediated by activating transcription factor 4; an endoplasmic reticulum stress-activated transcription factor. Hepatocyte-specific knockout of Gpt2 attenuated incorporation of 13C-alanine into newly synthesized glucose by hepatocytes. In vivo Gpt2 knockdown or knockout in liver had no effect on glucose concentrations in lean mice, but Gpt2 suppression alleviated hyperglycemia in db/db mice. These data suggest that ALT2 plays a significant role in hepatic gluconeogenesis from amino acids in diabetes.

Published

2021

4. Multiple antisense oligonucleotides targeted against monoacylglycerol acyltransferase 1 (Mogat1) improve glucose metabolism independently of Mogat1

Author

Jason M. Singer, Angela M. Hall, Brian N. Finck, Mai He, Andrew J. Lutkewitte, Michael R. Martino, and Trevor M. Shew

Subjects

0301 basic medicine, Male, medicine.medical_specialty, Transgene, Interferon alpha/beta receptor 1, 030209 endocrinology & metabolism, Receptor, Interferon alpha-beta, Carbohydrate metabolism, Diet, High-Fat, Diglycerides, 03 medical and health sciences, Mice, 0302 clinical medicine, Insulin resistance, Monoacylglycerol acyltransferase, Internal medicine, Glucose Intolerance, medicine, Glucose homeostasis, Animals, Obesity, Molecular Biology, Diacylglycerol kinase, Mice, Knockout, Gene knockdown, Antisense oligonucleotides, Chemistry, Cell Biology, Oligonucleotides, Antisense, medicine.disease, RC31-1245, Monoacylglycerol lipase, Fatty Liver, Mice, Inbred C57BL, 030104 developmental biology, Endocrinology, Glucose, Phenotype, Liver, Knockout mouse, Carbohydrate Metabolism, Female, Original Article, Transcriptome, Acyltransferases

Abstract

Objective Monoacylglycerol acyltransferase (MGAT) enzymes catalyze the synthesis of diacylglycerol from monoacylglycerol. Previous work has suggested the importance of MGAT activity in the development of obesity-related hepatic insulin resistance. Indeed, antisense oligonucleotide (ASO)-mediated knockdown of Mogat1 mRNA, which encodes MGAT1, reduced hepatic MGAT activity and improved glucose tolerance and insulin resistance in high-fat diet (HFD)-fed mice. However, recent work has suggested that some ASOs may have off-target effects on body weight and metabolic parameters via activation of the interferon alpha/beta receptor 1 (IFNAR-1) pathway. Methods Mice with whole-body Mogat1 knockout or a floxed allele for Mogat1 to allow for liver-specific Mogat1-knockout (by either a liver-specific transgenic or adeno-associated virus-driven Cre recombinase) were generated. These mice were placed on an HFD, and glucose metabolism and insulin sensitivity were assessed after 16 weeks on diet. In some experiments, mice were treated with control scramble or Mogat1 ASOs in the presence or absence of IFNAR-1 neutralizing antibody. Results Genetic deletion of hepatic Mogat1, either acutely or chronically, did not improve hepatic steatosis, glucose tolerance, or insulin sensitivity in HFD-fed mice. Furthermore, constitutive Mogat1 knockout in all tissues actually exacerbated HFD-induced obesity, insulin sensitivity, and glucose intolerance on an HFD. Despite markedly reduced Mogat1 expression, liver MGAT activity was unaffected in all knockout mouse models. Mogat1 overexpression in hepatocytes increased liver MGAT activity and TAG content in low-fat-fed mice but did not cause insulin resistance. Multiple Mogat1 ASO sequences improved glucose tolerance in both wild-type and Mogat1 null mice, suggesting an off-target effect. Hepatic IFNAR-1 signaling was activated by multiple Mogat1 ASOs, but its blockade did not prevent the effects of either Mogat1 ASO on glucose homeostasis. Conclusion These results indicate that genetic loss of Mogat1 does not affect hepatic MGAT activity or metabolic homeostasis on HFD and show that multiple Mogat1 ASOs improve glucose metabolism through effects independent of targeting Mogat1 or activation of IFNAR-1 signaling., Graphical abstract Image 1, Highlights • Mogat1 liver-specific KO or KD does not improve metabolism in HFD-fed mice. • Whole-body Mogat1 deletion impairs insulin tolerance in HFD-fed mice. • Mogat1 ASOs improve whole-body metabolism independently of gene knockdown. • Blockade of the INFAR1 response does not prevent off-target effects of Mogat1 ASOs.

Published

2021

5. Antisense oligonucleotides against monoacylglycerol acyltransferase 1 (Mogat1) improve glucose metabolism independently of Mogat1

Author

Angela M. Hall, Trevor M. Shew, Michael R. Martino, Brian N. Finck, Jason M. Singer, and Andrew J. Lutkewitte

Subjects

medicine.medical_specialty, Gene knockdown, Chemistry, Transgene, Carbohydrate metabolism, medicine.disease, Monoacylglycerol lipase, Endocrinology, Insulin resistance, Internal medicine, Acyltransferase, Knockout mouse, medicine, Glucose homeostasis

Abstract

ObjectiveMonoacylglycerol acyltransferase (MGAT) enzymes catalyze the synthesis of diacylglycerol from monoacylglycerol. Previous work has suggested the importance of MGAT activity in the development of obesity-related hepatic insulin resistance. Indeed, antisense oligonucleotide (ASO)-mediated knockdown of the gene encoding MGAT1, Mogat1, reduced hepatic MGAT activity and improved glucose tolerance and insulin resistance in high fat diet (HFD) fed mice. However, recent work has suggested that some ASOs may have off-target effects on body weight and metabolic parameters via activation of the interferon alpha/beta receptor 1 (IFNAR-1) pathway.MethodsMice with whole-body Mogat1 knockout or a floxed allele for Mogat1 to allow for liver-specific Mogat1-knockout (by either a liver-specific transgenic or adeno-associated virus-driven Cre recombinase) were generated. These mice were placed on a high fat diet and glucose metabolism and insulin sensitivity was assessed after 16 weeks on diet. In some experiments, mice were treated with control or Mogat1 or control ASOs in the presence or absence of IFNAR-1 neutralizing antibody.ResultsGenetic deletion of hepatic Mogat1, either acutely or chronically, did not improve hepatic steatosis, glucose tolerance, or insulin sensitivity in HFD-fed mice. Furthermore, constitutive Mogat1 knockout in all tissues actually exacerbated HFD-induced weight gain, insulin resistance, and glucose intolerance on a HFD. Despite markedly reduced Mogat1 expression, liver MGAT activity was unaffected in all knockout mouse models. Mogat1 overexpression hepatocytes increased liver MGAT activity and TAG content in low-fat fed mice, but did not cause insulin resistance. Interestingly, Mogat1 ASO treatment improved glucose tolerance in both wild-type and Mogat1 null mice, suggesting an off target effect. Inhibition of IFNAR-1 did not block the effect of Mogat1 ASO on glucose homeostasis.ConclusionThese results indicate that genetic loss of Mogat1 does not affect hepatic MGAT activity or metabolic homeostasis on HFD and show that Mogat1 ASOs improve glucose metabolism through effects independent of targeting Mogat1 or activation of IFNAR-1 signaling.Abstract FigureHighlightsMogat1 liver-specific KO or KD does not improve metabolism in HFD fed mice.Whole-body Mogat1-deletion impairs insulin tolerance in HFD fed mice.Mogat1 ASOs improves whole body metabolism independently of gene knockdown.Blockade of the INFR response does not prevent off-target effects of Mogat1 ASOs.

Published

2020

6. 1860-P: Alanine Transaminase 2 Is Induced in Diabetic Liver and Contributes to Gluconeogenesis from Amino Acids

Author

Kyle S. McCommis, Jun Yoshino, Michael R. Martino, Brian N. Finck, and Manuel Gutierrez Aguilar

Subjects

Alanine, chemistry.chemical_classification, medicine.medical_specialty, biology, Endocrinology, Diabetes and Metabolism, Amino acid, Glutamine, Endocrinology, Gluconeogenesis, Alanine transaminase, chemistry, Valine, Internal medicine, Internal Medicine, medicine, biology.protein, Leucine, Diet-induced obese

Abstract

Gluconeogenesis from amino acids contributes significantly to hepatic glucose production and hyperglycemia in diabetes. Alanine transaminases (ALT) catalyze the bi-directional interconversion of alanine to pyruvate with concomitant interconversion of α-ketoglutarate to glutamate. ALT1 is cytosolic while ALT2 is localized to the mitochondrial matrix. The mRNA expression and protein abundance of ALT1 and 2 was significantly increased in liver of db/db or diet induced obese mice compared to lean controls. The expression of ALT2 was also increased in obese humans compared to lean controls and was downregulated following bariatric surgery. The increase in hepatic ALT2 expression in diabetic mice was caused by endoplasmic reticulum stress and mediated by activating transcription factor 4 (ATF4). Indeed, inhibition of ATF4 reduced ALT2 expression in liver of db/db mice. Consistent with enhanced use of amino acids in gluconeogenesis, db/db and diet-induced obese mice had elevated blood glucose concentrations following IP administration of L-alanine or glutamine. ALT2 silencing in liver had no effect on glucose concentrations in lean mice, but alleviated alanine-induced hyperglycemia in db/db mice; likely by reducing the incorporation of alanine and/or glutamine into newly synthesized glucose. Plasma alanine tended to rise and glutamate significantly increased in db/db mice with ALT2 silencing whereas concentrations of the branched chain amino acids isoleucine, leucine, and valine decreased or tended to decrease. In summary, our results are consistent with a significant role for ALT2 in hepatic gluconeogenesis from amino acids and in the regulation of blood glucose levels in obesity and diabetes. Disclosure M.R. Martino: None. M. Gutierrez Aguilar: None. K.S. McCommis: None. J. Yoshino: None. B.N. Finck: Advisory Panel; Self; Cirius Therapeutics. Stock/Shareholder; Self; Cirius Therapeutics. Funding National Institutes of Health (R01DK117657)

Published

2020

7. NADPH and Glutathione Redox Link TCA Cycle Activity to Endoplasmic Reticulum Homeostasis

Author

Kyle S. McCommis, Erica R. Gansemer, Abdul Qaadir King-McAlpin, Eric B. Taylor, Michael R. Martino, Brian N. Finck, Matthew J. Potthoff, and D. Thomas Rutkowski

Subjects

0301 basic medicine, Multidisciplinary, Endoplasmic reticulum, biological sciences, Glutathione reductase, 02 engineering and technology, Glutathione, Oxidative phosphorylation, 021001 nanoscience & nanotechnology, Redox, Article, Cell biology, Citric acid cycle, 03 medical and health sciences, chemistry.chemical_compound, 030104 developmental biology, chemistry, cell biology, Unfolded protein response, lcsh:Q, functional aspects of cell biology, 0210 nano-technology, lcsh:Science, Homeostasis

Abstract

Summary Many metabolic diseases disrupt endoplasmic reticulum (ER) homeostasis, but little is known about how metabolic activity is communicated to the ER. Here, we show in hepatocytes and other metabolically active cells that decreasing the availability of substrate for the tricarboxylic acid (TCA) cycle diminished NADPH production, elevated glutathione oxidation, led to altered oxidative maturation of ER client proteins, and attenuated ER stress. This attenuation was prevented when glutathione oxidation was disfavored. ER stress was also alleviated by inhibiting either TCA-dependent NADPH production or Glutathione Reductase. Conversely, stimulating TCA activity increased NADPH production, glutathione reduction, and ER stress. Validating these findings, deletion of the Mitochondrial Pyruvate Carrier—which is known to decrease TCA cycle activity and protect the liver from steatohepatitis—also diminished NADPH, elevated glutathione oxidation, and alleviated ER stress. Together, our results demonstrate a novel pathway by which mitochondrial metabolic activity is communicated to the ER through the relay of redox metabolites., Graphical Abstract, Highlights • Inhibiting nutrient catabolism alleviates ER stress in metabolically active cells • NADPH production and glutathione redox link TCA activity to ER homeostasis • ER client protein oxidation, maturation, and ERAD respond to metabolic activity • Cells lacking the Mitochondrial Pyruvate Carrier are resistant to ER stress, biological sciences; cell biology; functional aspects of cell biology

Published

2020

8. High‐fat‐diet‐induced remission of diabetes in a subset of K ATP ‐GOF insulin‐secretory‐deficient mice

Author

Michael R. Martino, Brian N. Finck, Maria S. Remedi, M. Fortunato, Zihan Yan, Zeenat A. Shyr, Mariana Alisio, Hannah Conway, and Alecia Welscher

Subjects

0301 basic medicine, endocrine system, medicine.medical_specialty, Endocrinology, Diabetes and Metabolism, medicine.medical_treatment, Carbohydrate metabolism, 03 medical and health sciences, Endocrinology, Insulin resistance, Internal medicine, Diabetes mellitus, Internal Medicine, medicine, Deficient mouse, geography, geography.geographical_feature_category, business.industry, Insulin, High fat diet, Islet, medicine.disease, Obesity, 030104 developmental biology, business, hormones, hormone substitutes, and hormone antagonists

Abstract

Aims To examine the effects of a high-fat-diet (HFD) on monogenic neonatal diabetes, without the confounding effects of compensatory hyperinsulinaemia. Methods Mice expressing KATP channel gain-of-function (KATP -GOF) mutations, which models human neonatal diabetes, were fed an HFD. Results Surprisingly, KATP -GOF mice exhibited resistance to HFD-induced obesity, accompanied by markedly divergent blood glucose control, with some KATP -GOF mice showing persistent diabetes (KATP -GOF-non-remitter [NR] mice) and others showing remission of diabetes (KATP -GOF-remitter [R] mice). Compared with the severely diabetic and insulin-resistant KATP -GOF-NR mice, HFD-fed KATP -GOF-R mice had lower blood glucose, improved insulin sensitivity, and increased circulating plasma insulin and glucagon-like peptide-1 concentrations. Strikingly, while HFD-fed KATP -GOF-NR mice showed increased food intake and decreased physical activity, reduced whole body fat mass and increased plasma lipids, KATP -GOF-R mice showed similar features to those of control littermates. Importantly, KATP -GOF-R mice had restored insulin content and β-cell mass compared with the marked loss observed in both HFD-fed KATP -GOF-NR and chow-fed KATP -GOF mice. Conclusion Together, our results suggest that restriction of dietary carbohydrates and caloric replacement by fat can induce metabolic changes that are beneficial in reducing glucotoxicity and secondary consequences of diabetes in a mouse model of insulin-secretory deficiency.

Published

2018

9. NADPH and glutathione redox link TCA cycle activity to endoplasmic reticulum stress

Author

Kyle S. McCommis, Eric B. Taylor, Erica R. Gansemer, D. Thomas Rutkowski, Brian N. Finck, Abdul Qaadir King-McAlpin, Matthew J. Potthoff, and Michael R. Martino

Subjects

Citric acid cycle, chemistry.chemical_compound, Chemistry, Endoplasmic reticulum, Glutathione reductase, Unfolded protein response, Glutathione, Metabolism, Mitochondrion, Homeostasis, Cell biology

Abstract

Endoplasmic reticulum (ER) stress is associated with dysregulated metabolism, but little is known about how the ER responds to metabolic activity. Here, working primarily in mouse hepatocytes, we show that decreasing the availability of substrate for the TCA cycle diminished NADPH production and attenuated ER stress in a manner that depended on glutathione oxidation. ER stress was also alleviated by impairing either TCA-dependent NADPH production or Glutathione Reductase. Conversely, stimulating TCA activity favored NADPH production, glutathione reduction, and ER stress. Validating these findings, we show that deletion of the mitochondrial pyruvate carrier, which is known to decrease TCA cycle activity and protect the liver from diet-induced injury, also diminished NADPH, elevated glutathione oxidation, and alleviated ER stress. These results provide independent genetic evidence that mitochondrial oxidative metabolism is linked to ER homeostasis. Our results demonstrate a novel pathway of communication between mitochondria and the ER, through relay of redox metabolites.

Published

2019