Your search keyword '"Jurczak, Michael J"' showing total 14 results

1. A big-data approach to understanding metabolic rate and response to obesity in laboratory mice.

Author

Corrigan, June K, Corrigan, June K, Ramachandran, Deepti, He, Yuchen, Palmer, Colin J, Jurczak, Michael J, Chen, Rui, Li, Bingshan, Friedline, Randall H, Kim, Jason K, Ramsey, Jon J, Lantier, Louise, McGuinness, Owen P, Mouse Metabolic Phenotyping Center Energy Balance Working Group, Banks, Alexander S, Corrigan, June K, Corrigan, June K, Ramachandran, Deepti, He, Yuchen, Palmer, Colin J, Jurczak, Michael J, Chen, Rui, Li, Bingshan, Friedline, Randall H, Kim, Jason K, Ramsey, Jon J, Lantier, Louise, McGuinness, Owen P, Mouse Metabolic Phenotyping Center Energy Balance Working Group, and Banks, Alexander S

Abstract

Maintaining a healthy body weight requires an exquisite balance between energy intake and energy expenditure. To understand the genetic and environmental factors that contribute to the regulation of body weight, an important first step is to establish the normal range of metabolic values and primary sources contributing to variability. Energy metabolism is measured by powerful and sensitive indirect calorimetry devices. Analysis of nearly 10,000 wild-type mice from two large-scale experiments revealed that the largest variation in energy expenditure is due to body composition, ambient temperature, and institutional site of experimentation. We also analyze variation in 2329 knockout strains and establish a reference for the magnitude of metabolic changes. Based on these findings, we provide suggestions for how best to design and conduct energy balance experiments in rodents. These recommendations will move us closer to the goal of a centralized physiological repository to foster transparency, rigor and reproducibility in metabolic physiology experimentation.

Published

2020

2. A big-data approach to understanding metabolic rate and response to obesity in laboratory mice.

Author

Corrigan, June K, Corrigan, June K, Ramachandran, Deepti, He, Yuchen, Palmer, Colin J, Jurczak, Michael J, Chen, Rui, Li, Bingshan, Friedline, Randall H, Kim, Jason K, Ramsey, Jon J, Lantier, Louise, McGuinness, Owen P, Mouse Metabolic Phenotyping Center Energy Balance Working Group, Banks, Alexander S, Corrigan, June K, Corrigan, June K, Ramachandran, Deepti, He, Yuchen, Palmer, Colin J, Jurczak, Michael J, Chen, Rui, Li, Bingshan, Friedline, Randall H, Kim, Jason K, Ramsey, Jon J, Lantier, Louise, McGuinness, Owen P, Mouse Metabolic Phenotyping Center Energy Balance Working Group, and Banks, Alexander S

Abstract

Maintaining a healthy body weight requires an exquisite balance between energy intake and energy expenditure. To understand the genetic and environmental factors that contribute to the regulation of body weight, an important first step is to establish the normal range of metabolic values and primary sources contributing to variability. Energy metabolism is measured by powerful and sensitive indirect calorimetry devices. Analysis of nearly 10,000 wild-type mice from two large-scale experiments revealed that the largest variation in energy expenditure is due to body composition, ambient temperature, and institutional site of experimentation. We also analyze variation in 2329 knockout strains and establish a reference for the magnitude of metabolic changes. Based on these findings, we provide suggestions for how best to design and conduct energy balance experiments in rodents. These recommendations will move us closer to the goal of a centralized physiological repository to foster transparency, rigor and reproducibility in metabolic physiology experimentation.

Published

2020

3. Adipocyte JAK2 Regulates Hepatic Insulin Sensitivity Independently of Body Composition, Liver Lipid Content, and Hepatic Insulin Signaling.

Author

Corbit, Kevin C, Corbit, Kevin C, Camporez, João Paulo G, Edmunds, Lia R, Tran, Jennifer L, Vera, Nicholas B, Erion, Derek M, Deo, Rahul C, Perry, Rachel J, Shulman, Gerald I, Jurczak, Michael J, Weiss, Ethan J, Corbit, Kevin C, Corbit, Kevin C, Camporez, João Paulo G, Edmunds, Lia R, Tran, Jennifer L, Vera, Nicholas B, Erion, Derek M, Deo, Rahul C, Perry, Rachel J, Shulman, Gerald I, Jurczak, Michael J, and Weiss, Ethan J

Abstract

Disruption of hepatocyte growth hormone (GH) signaling through disruption of Jak2 (JAK2L) leads to fatty liver. Previously, we demonstrated that development of fatty liver depends on adipocyte GH signaling. We sought to determine the individual roles of hepatocyte and adipocyte Jak2 on whole-body and tissue insulin sensitivity and liver metabolism. On chow, JAK2L mice had hepatic steatosis and severe whole-body and hepatic insulin resistance. However, concomitant deletion of Jak2 in hepatocytes and adipocytes (JAK2LA) completely normalized insulin sensitivity while reducing liver lipid content. On high-fat diet, JAK2L mice had hepatic steatosis and insulin resistance despite protection from diet-induced obesity. JAK2LA mice had higher liver lipid content and no protection from obesity but retained exquisite hepatic insulin sensitivity. AKT activity was selectively attenuated in JAK2L adipose tissue, whereas hepatic insulin signaling remained intact despite profound hepatic insulin resistance. Therefore, JAK2 in adipose tissue is epistatic to liver with regard to insulin sensitivity and responsiveness, despite fatty liver and obesity. However, hepatocyte autonomous JAK2 signaling regulates liver lipid deposition under conditions of excess dietary fat. This work demonstrates how various tissues integrate JAK2 signals to regulate insulin/glucose and lipid metabolism.

Published

2018

4. Adipocyte JAK2 Regulates Hepatic Insulin Sensitivity Independently of Body Composition, Liver Lipid Content, and Hepatic Insulin Signaling.

Author

Corbit, Kevin C, Corbit, Kevin C, Camporez, João Paulo G, Edmunds, Lia R, Tran, Jennifer L, Vera, Nicholas B, Erion, Derek M, Deo, Rahul C, Perry, Rachel J, Shulman, Gerald I, Jurczak, Michael J, Weiss, Ethan J, Corbit, Kevin C, Corbit, Kevin C, Camporez, João Paulo G, Edmunds, Lia R, Tran, Jennifer L, Vera, Nicholas B, Erion, Derek M, Deo, Rahul C, Perry, Rachel J, Shulman, Gerald I, Jurczak, Michael J, and Weiss, Ethan J

Abstract

Disruption of hepatocyte growth hormone (GH) signaling through disruption of Jak2 (JAK2L) leads to fatty liver. Previously, we demonstrated that development of fatty liver depends on adipocyte GH signaling. We sought to determine the individual roles of hepatocyte and adipocyte Jak2 on whole-body and tissue insulin sensitivity and liver metabolism. On chow, JAK2L mice had hepatic steatosis and severe whole-body and hepatic insulin resistance. However, concomitant deletion of Jak2 in hepatocytes and adipocytes (JAK2LA) completely normalized insulin sensitivity while reducing liver lipid content. On high-fat diet, JAK2L mice had hepatic steatosis and insulin resistance despite protection from diet-induced obesity. JAK2LA mice had higher liver lipid content and no protection from obesity but retained exquisite hepatic insulin sensitivity. AKT activity was selectively attenuated in JAK2L adipose tissue, whereas hepatic insulin signaling remained intact despite profound hepatic insulin resistance. Therefore, JAK2 in adipose tissue is epistatic to liver with regard to insulin sensitivity and responsiveness, despite fatty liver and obesity. However, hepatocyte autonomous JAK2 signaling regulates liver lipid deposition under conditions of excess dietary fat. This work demonstrates how various tissues integrate JAK2 signals to regulate insulin/glucose and lipid metabolism.

Published

2018

5. The H19/let-7 double-negative feedback loop contributes to glucose metabolism in muscle cells

Author

Gao, Yuan, Wu, Fuju, Zhou, Jichun, Yan, Lei, Jurczak, Michael J., Lee, Hui-Young, Yang, Lihua, Mueller, Martin, Zhou, Xiao-Bo, Dandolo, Luisa, Szendroedi, Julia, Roden, Michael, Flannery, Clare, Taylor, Hugh, Carmichael, Gordon G., Shulman, Gerald I., Huang, Yingqun, Gao, Yuan, Wu, Fuju, Zhou, Jichun, Yan, Lei, Jurczak, Michael J., Lee, Hui-Young, Yang, Lihua, Mueller, Martin, Zhou, Xiao-Bo, Dandolo, Luisa, Szendroedi, Julia, Roden, Michael, Flannery, Clare, Taylor, Hugh, Carmichael, Gordon G., Shulman, Gerald I., and Huang, Yingqun

Abstract

The H19 lncRNA has been implicated in development and growth control and is associated with human genetic disorders and cancer. Acting as a molecular sponge, H19 inhibits microRNA (miRNA) let-7. Here we report that H19 is significantly decreased in muscle of human subjects with type-2 diabetes and insulin resistant rodents. This decrease leads to increased bioavailability of let-7, causing diminished expression of let-7 targets, which is recapitulated in vitro where H19 depletion results in impaired insulin signaling and decreased glucose uptake. Furthermore, acute hyperinsulinemia downregulates H19, a phenomenon that occurs through PI3K/AKT-dependent phosphorylation of the miRNA processing factor KSRP, which promotes biogenesis of let-7 and its mediated H19 destabilization. Our results reveal a previously undescribed double-negative feedback loop between sponge lncRNA and target miRNA that contributes to glucose regulation in muscle cells

Published

2017

6. PKM2 Isoform-Specific Deletion Reveals a Differential Requirement for Pyruvate Kinase in Tumor Cells

Author

Massachusetts Institute of Technology. Department of Biology, Koch Institute for Integrative Cancer Research at MIT, Israelsen, William James, Dayton, Talya L., Davidson, Shawn M., Fiske, Brian Prescott, Hosios, Aaron Marc, Bellinger, Gary, Yu, Yimin, Jacks, Tyler E., Vander Heiden, Matthew G., Li, Jie, Sasaki, Mika, Horner, James W., Burga, Laura N., Xie, Jianxin, Jurczak, Michael J., DePinho, Ronald A., Clish, Clary B., Kibbey, Richard G., Wulf, Gerburg M., Di Vizio, Dolores, Mills, Gordon B., Cantley, Lewis C., Massachusetts Institute of Technology. Department of Biology, Koch Institute for Integrative Cancer Research at MIT, Israelsen, William James, Dayton, Talya L., Davidson, Shawn M., Fiske, Brian Prescott, Hosios, Aaron Marc, Bellinger, Gary, Yu, Yimin, Jacks, Tyler E., Vander Heiden, Matthew G., Li, Jie, Sasaki, Mika, Horner, James W., Burga, Laura N., Xie, Jianxin, Jurczak, Michael J., DePinho, Ronald A., Clish, Clary B., Kibbey, Richard G., Wulf, Gerburg M., Di Vizio, Dolores, Mills, Gordon B., and Cantley, Lewis C.

Abstract

The pyruvate kinase M2 isoform (PKM2) is expressed in cancer and plays a role in regulating anabolic metabolism. To determine whether PKM2 is required for tumor formation or growth, we generated mice with a conditional allele that abolishes PKM2 expression without disrupting PKM1 expression. PKM2 deletion accelerated mammary tumor formation in a Brca1-loss-driven model of breast cancer. PKM2 null tumors displayed heterogeneous PKM1 expression, with PKM1 found in nonproliferating tumor cells and no detectable pyruvate kinase expression in proliferating cells. This suggests that PKM2 is not necessary for tumor cell proliferation and implies that the inactive state of PKM2 is associated with the proliferating cell population within tumors, whereas nonproliferating tumor cells require active pyruvate kinase. Consistent with these findings, variable PKM2 expression and heterozygous PKM2 mutations are found in human tumors. These data suggest that regulation of PKM2 activity supports the different metabolic requirements of proliferating and nonproliferating tumor cells., National Institutes of Health (U.S.) (Grant R01CA168653), National Institutes of Health (U.S.) (Grant 5P01CA117969), National Institutes of Health (U.S.) (Grant P30CA147882), National Institutes of Health (U.S.) (Grant 5P30CA14051), National Institutes of Health (U.S.) (Grant 5K08CA136983), National Institutes of Health (U.S.) (Grant DK059635), National Institutes of Health (U.S.) (Grant R01DK092606), National Institutes of Health (U.S.) (Grant R00CA131472), National Institutes of Health (U.S.) (Grant R01GM056203), American Diabetes Association (Grant 7-12-BS-09), Smith Family Foundation, Burroughs Wellcome Fund, Damon Runyon Cancer Research Foundation, Stern Family

Published

2017

7. Hypophosphatemia promotes lower rates of muscle ATP synthesis

Author

Pesta, Dominik H, Tsirigotis, Dimitrios N, Befroy, Douglas E, Caballero, Daniel, Jurczak, Michael J, Rahimi, Yasmeen, Cline, Gary W, Dufour, Sylvie, Birkenfeld, Andreas L, Rothman, Douglas L, Carpenter, Thomas O, Insogna, Karl, Petersen, Kitt Mia Falck, Bergwitz, Clemens, Shulman, Gerald I., Pesta, Dominik H, Tsirigotis, Dimitrios N, Befroy, Douglas E, Caballero, Daniel, Jurczak, Michael J, Rahimi, Yasmeen, Cline, Gary W, Dufour, Sylvie, Birkenfeld, Andreas L, Rothman, Douglas L, Carpenter, Thomas O, Insogna, Karl, Petersen, Kitt Mia Falck, Bergwitz, Clemens, and Shulman, Gerald I.

Abstract

Hypophosphatemia can lead to muscle weakness and respiratory and heart failure, but the mechanism is unknown. To address this question, we noninvasively assessed rates of muscle ATP synthesis in hypophosphatemic mice by using in vivo saturation transfer [(31)P]-magnetic resonance spectroscopy. By using this approach, we found that basal and insulin-stimulated rates of muscle ATP synthetic flux (VATP) and plasma inorganic phosphate (Pi) were reduced by 50% in mice with diet-induced hypophosphatemia as well as in NaPi2a knockout mice (NaPi2a(-/-)) compared with their wild-type littermate controls. Rates of VATP normalized in both hypophosphatemic groups after restoring plasma Pi concentrations. Furthermore, VATP was directly related to cellular and mitochondrial Pi uptake in L6 and RC13 rodent myocytes and isolated muscle mitochondria. Similar findings were observed in a patient with chronic hypophosphatemia as a result of a mutation in SLC34A3 who had a 50% reduction in both serum Pi content and muscle VATP After oral Pi repletion and normalization of serum Pi levels, muscle VATP completely normalized in the patient. Taken together, these data support the hypothesis that decreased muscle ATP synthesis, in part, may be caused by low blood Pi concentrations, which may explain some aspects of muscle weakness observed in patients with hypophosphatemia.-Pesta, D. H., Tsirigotis, D. N., Befroy, D. E., Caballero, D., Jurczak, M. J., Rahimi, Y., Cline, G. W., Dufour, S., Birkenfeld, A. L., Rothman, D. L., Carpenter, T. O., Insogna, K., Petersen, K. F., Bergwitz, C., Shulman, G. I. Hypophosphatemia promotes lower rates of muscle ATP synthesis.

Published

2016

8. Metformin suppresses gluconeogenesis by inhibiting mitochondrial glycerophosphate dehydrogenase

Author

Madiraju, Anila K, Erion, Derek M, Rahimi, Yasmeen, Zhang, Xian-Man, Braddock, Demetrios T, Albright, Ronald A, Prigaro, Brett J, Wood, John L, Bhanot, Sanjay, MacDonald, Michael J, Jurczak, Michael J, Camporez, Joao-Paulo, Lee, Hui-Young, Cline, Gary W, Samuel, Varman T, Kibbey, Richard G, Shulman, Gerald I., Madiraju, Anila K, Erion, Derek M, Rahimi, Yasmeen, Zhang, Xian-Man, Braddock, Demetrios T, Albright, Ronald A, Prigaro, Brett J, Wood, John L, Bhanot, Sanjay, MacDonald, Michael J, Jurczak, Michael J, Camporez, Joao-Paulo, Lee, Hui-Young, Cline, Gary W, Samuel, Varman T, Kibbey, Richard G, and Shulman, Gerald I.

Abstract

Metformin is considered to be one of the most effective therapeutics for treating type 2 diabetes because it specifically reduces hepatic gluconeogenesis without increasing insulin secretion, inducing weight gain or posing a risk of hypoglycaemia. For over half a century, this agent has been prescribed to patients with type 2 diabetes worldwide, yet the underlying mechanism by which metformin inhibits hepatic gluconeogenesis remains unknown. Here we show that metformin non-competitively inhibits the redox shuttle enzyme mitochondrial glycerophosphate dehydrogenase, resulting in an altered hepatocellular redox state, reduced conversion of lactate and glycerol to glucose, and decreased hepatic gluconeogenesis. Acute and chronic low-dose metformin treatment effectively reduced endogenous glucose production, while increasing cytosolic redox and decreasing mitochondrial redox states. Antisense oligonucleotide knockdown of hepatic mitochondrial glycerophosphate dehydrogenase in rats resulted in a phenotype akin to chronic metformin treatment, and abrogated metformin-mediated increases in cytosolic redox state, decreases in plasma glucose concentrations, and inhibition of endogenous glucose production. These findings were replicated in whole-body mitochondrial glycerophosphate dehydrogenase knockout mice. These results have significant implications for understanding the mechanism of metformin's blood glucose lowering effects and provide a new therapeutic target for type 2 diabetes.

Published

2014

9. Metformin suppresses gluconeogenesis by inhibiting mitochondrial glycerophosphate dehydrogenase

Author

Madiraju, Anila K, Erion, Derek M, Rahimi, Yasmeen, Zhang, Xian-Man, Braddock, Demetrios T, Albright, Ronald A, Prigaro, Brett J, Wood, John L, Bhanot, Sanjay, MacDonald, Michael J, Jurczak, Michael J, Camporez, Joao-Paulo, Lee, Hui-Young, Cline, Gary W, Samuel, Varman T, Kibbey, Richard G, Shulman, Gerald I., Madiraju, Anila K, Erion, Derek M, Rahimi, Yasmeen, Zhang, Xian-Man, Braddock, Demetrios T, Albright, Ronald A, Prigaro, Brett J, Wood, John L, Bhanot, Sanjay, MacDonald, Michael J, Jurczak, Michael J, Camporez, Joao-Paulo, Lee, Hui-Young, Cline, Gary W, Samuel, Varman T, Kibbey, Richard G, and Shulman, Gerald I.

Abstract

Metformin is considered to be one of the most effective therapeutics for treating type 2 diabetes because it specifically reduces hepatic gluconeogenesis without increasing insulin secretion, inducing weight gain or posing a risk of hypoglycaemia. For over half a century, this agent has been prescribed to patients with type 2 diabetes worldwide, yet the underlying mechanism by which metformin inhibits hepatic gluconeogenesis remains unknown. Here we show that metformin non-competitively inhibits the redox shuttle enzyme mitochondrial glycerophosphate dehydrogenase, resulting in an altered hepatocellular redox state, reduced conversion of lactate and glycerol to glucose, and decreased hepatic gluconeogenesis. Acute and chronic low-dose metformin treatment effectively reduced endogenous glucose production, while increasing cytosolic redox and decreasing mitochondrial redox states. Antisense oligonucleotide knockdown of hepatic mitochondrial glycerophosphate dehydrogenase in rats resulted in a phenotype akin to chronic metformin treatment, and abrogated metformin-mediated increases in cytosolic redox state, decreases in plasma glucose concentrations, and inhibition of endogenous glucose production. These findings were replicated in whole-body mitochondrial glycerophosphate dehydrogenase knockout mice. These results have significant implications for understanding the mechanism of metformin's blood glucose lowering effects and provide a new therapeutic target for type 2 diabetes.

Published

2014

10. Reversal of Hypertriglyceridemia, Fatty Liver Disease, and Insulin Resistance by a Liver-Targeted Mitochondrial Uncoupler

Author

Perry, Rachel J., Kim, Taehan, Zhang, Xian-Man, Lee, Hui-Young, Pesta, Dominik, Popov, Violeta B., Zhang, Dongyan, Rahimi, Yasmeen, Jurczak, Michael J., Cline, Gary W., Spiegel, David A., Shulman, Gerald I., Perry, Rachel J., Kim, Taehan, Zhang, Xian-Man, Lee, Hui-Young, Pesta, Dominik, Popov, Violeta B., Zhang, Dongyan, Rahimi, Yasmeen, Jurczak, Michael J., Cline, Gary W., Spiegel, David A., and Shulman, Gerald I.

Published

2013

11. Reversal of Hypertriglyceridemia, Fatty Liver Disease, and Insulin Resistance by a Liver-Targeted Mitochondrial Uncoupler

Author

Perry, Rachel J., Kim, Taehan, Zhang, Xian-Man, Lee, Hui-Young, Pesta, Dominik, Popov, Violeta B., Zhang, Dongyan, Rahimi, Yasmeen, Jurczak, Michael J., Cline, Gary W., Spiegel, David A., Shulman, Gerald I., Perry, Rachel J., Kim, Taehan, Zhang, Xian-Man, Lee, Hui-Young, Pesta, Dominik, Popov, Violeta B., Zhang, Dongyan, Rahimi, Yasmeen, Jurczak, Michael J., Cline, Gary W., Spiegel, David A., and Shulman, Gerald I.

Published

2013

12. Reversal of Hypertriglyceridemia, Fatty Liver Disease, and Insulin Resistance by a Liver-Targeted Mitochondrial Uncoupler

Author

Perry, Rachel J., Kim, Taehan, Zhang, Xian-Man, Lee, Hui-Young, Pesta, Dominik, Popov, Violeta B., Zhang, Dongyan, Rahimi, Yasmeen, Jurczak, Michael J., Cline, Gary W., Spiegel, David A., Shulman, Gerald I., Perry, Rachel J., Kim, Taehan, Zhang, Xian-Man, Lee, Hui-Young, Pesta, Dominik, Popov, Violeta B., Zhang, Dongyan, Rahimi, Yasmeen, Jurczak, Michael J., Cline, Gary W., Spiegel, David A., and Shulman, Gerald I.

Published

2013

13. Reversal of Hypertriglyceridemia, Fatty Liver Disease, and Insulin Resistance by a Liver-Targeted Mitochondrial Uncoupler

Author

Perry, Rachel J., Kim, Taehan, Zhang, Xian-Man, Lee, Hui-Young, Pesta, Dominik, Popov, Violeta B., Zhang, Dongyan, Rahimi, Yasmeen, Jurczak, Michael J., Cline, Gary W., Spiegel, David A., Shulman, Gerald I., Perry, Rachel J., Kim, Taehan, Zhang, Xian-Man, Lee, Hui-Young, Pesta, Dominik, Popov, Violeta B., Zhang, Dongyan, Rahimi, Yasmeen, Jurczak, Michael J., Cline, Gary W., Spiegel, David A., and Shulman, Gerald I.

Published

2013

14. The H19/let-7 double-negative feedback loop contributes to glucose metabolism in muscle cells

Author

Gao, Yuan, Wu, Fuju, Zhou, Jichun, Yan, Lei, Jurczak, Michael J., Lee, Hui-Young, Yang, Lihua, Mueller, Martin, Zhou, Xiao-Bo, Dandolo, Luisa, Szendroedi, Julia, Roden, Michael, Flannery, Clare, Taylor, Hugh, Carmichael, Gordon G., Shulman, Gerald I., Huang, Yingqun, Gao, Yuan, Wu, Fuju, Zhou, Jichun, Yan, Lei, Jurczak, Michael J., Lee, Hui-Young, Yang, Lihua, Mueller, Martin, Zhou, Xiao-Bo, Dandolo, Luisa, Szendroedi, Julia, Roden, Michael, Flannery, Clare, Taylor, Hugh, Carmichael, Gordon G., Shulman, Gerald I., and Huang, Yingqun

Abstract

The H19 lncRNA has been implicated in development and growth control and is associated with human genetic disorders and cancer. Acting as a molecular sponge, H19 inhibits microRNA (miRNA) let-7. Here we report that H19 is significantly decreased in muscle of human subjects with type-2 diabetes and insulin resistant rodents. This decrease leads to increased bioavailability of let-7, causing diminished expression of let-7 targets, which is recapitulated in vitro where H19 depletion results in impaired insulin signaling and decreased glucose uptake. Furthermore, acute hyperinsulinemia downregulates H19, a phenomenon that occurs through PI3K/AKT-dependent phosphorylation of the miRNA processing factor KSRP, which promotes biogenesis of let-7 and its mediated H19 destabilization. Our results reveal a previously undescribed double-negative feedback loop between sponge lncRNA and target miRNA that contributes to glucose regulation in muscle cells