Your search keyword '"James G. Burchfield"' showing total 31 results

1. Akt phosphorylates insulin receptor substrate to limit PI3K-mediated PIP3 synthesis

Author

Alison L Kearney, Dougall M Norris, Milad Ghomlaghi, Martin Kin Lok Wong, Sean J Humphrey, Luke Carroll, Guang Yang, Kristen C Cooke, Pengyi Yang, Thomas A Geddes, Sungyoung Shin, Daniel J Fazakerley, Lan K Nguyen, David E James, and James G Burchfield

Subjects

insulin, phosphorylation, plasma membrane, signal transduction, Akt, PI3K, Medicine, Science, Biology (General), QH301-705.5

Abstract

The phosphoinositide 3-kinase (PI3K)-Akt network is tightly controlled by feedback mechanisms that regulate signal flow and ensure signal fidelity. A rapid overshoot in insulin-stimulated recruitment of Akt to the plasma membrane has previously been reported, which is indicative of negative feedback operating on acute timescales. Here, we show that Akt itself engages this negative feedback by phosphorylating insulin receptor substrate (IRS) 1 and 2 on a number of residues. Phosphorylation results in the depletion of plasma membrane-localised IRS1/2, reducing the pool available for interaction with the insulin receptor. Together these events limit plasma membrane-associated PI3K and phosphatidylinositol (3,4,5)-trisphosphate (PIP3) synthesis. We identified two Akt-dependent phosphorylation sites in IRS2 at S306 (S303 in mouse) and S577 (S573 in mouse) that are key drivers of this negative feedback. These findings establish a novel mechanism by which the kinase Akt acutely controls PIP3 abundance, through post-translational modification of the IRS scaffold.

Published

2021

2. Mitochondrial CoQ deficiency is a common driver of mitochondrial oxidants and insulin resistance

Author

Daniel J Fazakerley, Rima Chaudhuri, Pengyi Yang, Ghassan J Maghzal, Kristen C Thomas, James R Krycer, Sean J Humphrey, Benjamin L Parker, Kelsey H Fisher-Wellman, Christopher C Meoli, Nolan J Hoffman, Ciana Diskin, James G Burchfield, Mark J Cowley, Warren Kaplan, Zora Modrusan, Ganesh Kolumam, Jean YH Yang, Daniel L Chen, Dorit Samocha-Bonet, Jerry R Greenfield, Kyle L Hoehn, Roland Stocker, and David E James

Subjects

Insulin resistance, Mitochondria, Oxidants, Coenzyme Q, Insulin, Ubiquinone, Medicine, Science, Biology (General), QH301-705.5

Abstract

Insulin resistance in muscle, adipocytes and liver is a gateway to a number of metabolic diseases. Here, we show a selective deficiency in mitochondrial coenzyme Q (CoQ) in insulin-resistant adipose and muscle tissue. This defect was observed in a range of in vitro insulin resistance models and adipose tissue from insulin-resistant humans and was concomitant with lower expression of mevalonate/CoQ biosynthesis pathway proteins in most models. Pharmacologic or genetic manipulations that decreased mitochondrial CoQ triggered mitochondrial oxidants and insulin resistance while CoQ supplementation in either insulin-resistant cell models or mice restored normal insulin sensitivity. Specifically, lowering of mitochondrial CoQ caused insulin resistance in adipocytes as a result of increased superoxide/hydrogen peroxide production via complex II. These data suggest that mitochondrial CoQ is a proximal driver of mitochondrial oxidants and insulin resistance, and that mechanisms that restore mitochondrial CoQ may be effective therapeutic targets for treating insulin resistance.

Published

2018

3. A high-content endogenous GLUT4 trafficking assay reveals new aspects of adipocyte biology

Author

Alexis Diaz-Vegas, Dougall M Norris, Sigrid Jall-Rogg, Kristen C Cooke, Olivia J Conway, Amber S Shun-Shion, Xiaowen Duan, Meg Potter, Julian van Gerwen, Harry JM Baird, Sean J Humphrey, David E James, Daniel J Fazakerley, James G Burchfield, Diaz-Vegas, Alexis [0000-0001-5227-4482], Cooke, Kristen C [0000-0002-3534-1660], Humphrey, Sean J [0000-0002-2666-9744], James, David E [0000-0001-5946-5257], Fazakerley, Daniel J [0000-0001-8241-2903], Burchfield, James G [0000-0002-6609-6151], and Apollo - University of Cambridge Repository

Subjects

Mice, Glucose Transporter Type 4, Glucose, Ecology, rab GTP-Binding Proteins, Health, Toxicology and Mutagenesis, 3T3-L1 Cells, Adipocytes, Animals, Insulin, Plant Science, Biochemistry, Genetics and Molecular Biology (miscellaneous), Biology

Abstract

Funder: Wellcome-MRC, Institute of Metabolic Science, Metabolic Research Laboratories, Imaging Core, Insulin-induced GLUT4 translocation to the plasma membrane in muscle and adipocytes is crucial for whole-body glucose homeostasis. Currently, GLUT4 trafficking assays rely on overexpression of tagged GLUT4. Here we describe a high-content imaging platform for studying endogenous GLUT4 translocation in intact adipocytes. This method enables high fidelity analysis of GLUT4 responses to specific perturbations, multiplexing of other trafficking proteins and other features including lipid droplet morphology. Using this multiplexed approach we showed that Vps45 and Rab14 are selective regulators of GLUT4, but Trarg1, Stx6, Stx16, Tbc1d4 and Rab10 knockdown affected both GLUT4 and TfR translocation. Thus, GLUT4 and TfR translocation machinery likely have some overlap upon insulin-stimulation. In addition, we identified Kif13A, a Rab10 binding molecular motor, as a novel regulator of GLUT4 traffic. Finally, comparison of endogenous to overexpressed GLUT4 highlights that the endogenous GLUT4 methodology has an enhanced sensitivity to genetic perturbations and emphasises the advantage of studying endogenous protein trafficking for drug discovery and genetic analysis of insulin action in relevant cell types.

Published

2022

4. Trafficking regulator of GLUT4-1 (TRARG1) is a GSK3 substrate

Author

Xiaowen Duan, Dougall M. Norris, Sean J. Humphrey, Pengyi Yang, Kristen C. Cooke, Will P. Bultitude, Benjamin L. Parker, Olivia J. Conway, James G. Burchfield, James R. Krycer, Frances M. Brodsky, David E. James, Daniel J. Fazakerley, Fazakerley, Daniel J [0000-0001-8241-2903], and Apollo - University of Cambridge Repository

Subjects

animal structures, Glucose Transporter Type 4, Cell Membrane, glucose transport, Cell Biology, macromolecular substances, trafficking regulator of GLUT4-1, insulin signalling, Biochemistry, glycogen synthase kinase, Glycogen Synthase Kinase 3, Mice, Phosphatidylinositol 3-Kinases, Glucose, Adipocytes, Serine, Animals, Humans, Insulin, Phosphorylation, Molecular Biology, Proto-Oncogene Proteins c-akt

Abstract

Trafficking regulator of GLUT4-1, TRARG1, positively regulates insulin-stimulated GLUT4 trafficking and insulin sensitivity. However, the mechanism(s) by which this occurs remain(s) unclear. Using biochemical and mass spectrometry analyses we found that TRARG1 is dephosphorylated in response to insulin in a PI3K/Akt-dependent manner and is a novel substrate for GSK3. Priming phosphorylation of murine TRARG1 at serine 84 allows for GSK3-directed phosphorylation at serines 72, 76 and 80. A similar pattern of phosphorylation was observed in human TRARG1, suggesting that our findings are translatable to human TRARG1. Pharmacological inhibition of GSK3 increased cell surface GLUT4 in cells stimulated with a submaximal insulin dose, and this was impaired following Trarg1 knockdown, suggesting that TRARG1 acts as a GSK3-mediated regulator in GLUT4 trafficking. These data place TRARG1 within the insulin signaling network and provide insights into how GSK3 regulates GLUT4 trafficking in adipocytes.

Published

2022

5. Regulation of hepatic insulin signaling and glucose homeostasis by sphingosine kinase 2

Author

Li Rui, Yu Huang, Mei Li Ng, Tian Lan, Collin Tran, Qi Chen, Mathew A. Vadas, Anthony S. Don, Yanfei Qi, Sishan Yan, Min Li, Yufei Li, Long Hoa Chung, Philip J. Hogg, Carol Wadham, James G. Burchfield, Pu Xia, Gulibositan Aji, Wei Wang, Jinbiao Chen, Timothy A. Couttas, Xin Gao, Da Liu, and Jennifer R. Gamble

Subjects

Male, Ceramide, Medical Sciences, Mice, Phosphatidylinositol 3-Kinases, chemistry.chemical_compound, Insulin resistance, insulin resistance, Cell Line, Tumor, hepatocyte, medicine, Animals, Homeostasis, Humans, Insulin, Glucose homeostasis, ceramide, Mice, Knockout, Sphingolipids, Multidisciplinary, Sphingosine, biology, Sphingosine Kinase 2, Biological Sciences, medicine.disease, Sphingolipid, Cell biology, Phosphotransferases (Alcohol Group Acceptor), SPHK2, Insulin receptor, Glucose, Liver, chemistry, Hepatocytes, biology.protein, Female, type 2 diabetes

Abstract

Significance Hepatic insulin resistance is a chief pathogenic determinant in the development of type 2 diabetes, which is often associated with abnormal hepatic lipid regulation. Sphingolipids are a class of essential lipids in the liver, where sphingosine kinase 2 (SphK2) is a key enzyme in their catabolic pathway. However, roles of SphK2 and its related sphingolipids in hepatic insulin resistance remain elusive. Here we generate liver-specific Sphk2 knockout mice, demonstrating that SphK2 in the liver is essential for insulin sensitivity and glucose homeostasis. We also identify sphingosine as a bona fide endogenous inhibitor of hepatic insulin signaling. These findings provide physiological insights into SphK2 and sphingosine, which could be therapeutic targets for the management of insulin resistance and diabetes., Sphingolipid dysregulation is often associated with insulin resistance, while the enzymes controlling sphingolipid metabolism are emerging as therapeutic targets for improving insulin sensitivity. We report herein that sphingosine kinase 2 (SphK2), a key enzyme in sphingolipid catabolism, plays a critical role in the regulation of hepatic insulin signaling and glucose homeostasis both in vitro and in vivo. Hepatocyte-specific Sphk2 knockout mice exhibit pronounced insulin resistance and glucose intolerance. Likewise, SphK2-deficient hepatocytes are resistant to insulin-induced activation of the phosphoinositide 3-kinase (PI3K)-Akt-FoxO1 pathway and elevated hepatic glucose production. Mechanistically, SphK2 deficiency leads to the accumulation of sphingosine that, in turn, suppresses hepatic insulin signaling by inhibiting PI3K activation in hepatocytes. Either reexpressing functional SphK2 or pharmacologically inhibiting sphingosine production restores insulin sensitivity in SphK2-deficient hepatocytes. In conclusion, the current study provides both experimental findings and mechanistic data showing that SphK2 and sphingosine in the liver are critical regulators of insulin sensitivity and glucose homeostasis.

Published

2020

6. Mitochondrial oxidants, but not respiration, are sensitive to glucose in adipocytes

Author

Daniel J. Fazakerley, Alexis Díaz-Vegas, Sarah D. Elkington, Gregory J. Cooney, David E. James, Kelsey H. Fisher-Wellman, James G. Burchfield, James R. Krycer, and Kristen C. Cooke

Subjects

Male, 0301 basic medicine, medicine.medical_specialty, Glucose uptake, medicine.medical_treatment, Cell Respiration, Adipose tissue, Type 2 diabetes, Bioenergetics, Mitochondrion, Biochemistry, Rats, Sprague-Dawley, Mice, 03 medical and health sciences, chemistry.chemical_compound, Insulin resistance, Internal medicine, Adipocyte, Adipocytes, medicine, Animals, Insulin, Glucose homeostasis, Molecular Biology, Cells, Cultured, 030102 biochemistry & molecular biology, Chemistry, 3T3 Cells, Cell Biology, medicine.disease, Mitochondria, Rats, Oxygen, Oxidative Stress, Glucose, 030104 developmental biology, Endocrinology, Insulin Resistance

Abstract

Insulin action in adipose tissue is crucial for whole-body glucose homeostasis, with insulin resistance being a major risk factor for metabolic diseases such as type 2 diabetes. Recent studies have proposed mitochondrial oxidants as a unifying driver of adipose insulin resistance, serving as a signal of nutrient excess. However, neither the substrates for nor sites of oxidant production are known. Because insulin stimulates glucose utilization, we hypothesized that glucose oxidation would fuel respiration, in turn generating mitochondrial oxidants. This would impair insulin action, limiting further glucose uptake in a negative feedback loop of “glucose-dependent” insulin resistance. Using primary rat adipocytes and cultured 3T3-L1 adipocytes, we observed that insulin increased respiration, but notably this occurred independently of glucose supply. In contrast, glucose was required for insulin to increase mitochondrial oxidants. Despite rising to similar levels as when treated with other agents that cause insulin resistance, glucose-dependent mitochondrial oxidants failed to cause insulin resistance. Subsequent studies revealed a temporal relationship whereby mitochondrial oxidants needed to increase before the insulin stimulus to induce insulin resistance. Together, these data reveal that (a) adipocyte respiration is principally fueled from nonglucose sources; (b) there is a disconnect between respiration and oxidative stress, whereby mitochondrial oxidant levels do not rise with increased respiration unless glucose is present; and (c) mitochondrial oxidative stress must precede the insulin stimulus to cause insulin resistance, explaining why short-term, insulin-dependent glucose utilization does not promote insulin resistance. These data provide additional clues to mechanistically link nutrient excess to adipose insulin resistance.

Published

2020

7. Akt phosphorylates insulin receptor substrate to limit PI3K-mediated PIP3 synthesis

Author

Sean J. Humphrey, James G. Burchfield, Milad Ghomlaghi, David E. James, Kristen C. Cooke, Thomas A Geddes, Luke Carroll, Guang Yang, Pengyi Yang, Lan K. Nguyen, Sung-Young Shin, Daniel J. Fazakerley, Dougall M. Norris, Martin Kin Lok Wong, Alison L Kearney, Kearney, Alison L [0000-0002-5736-3393], Ghomlaghi, Milad [0000-0001-9047-1049], Nguyen, Lan K [0000-0003-4040-7705], James, David E [0000-0001-5946-5257], Burchfield, James G [0000-0002-6609-6151], Apollo - University of Cambridge Repository, Humphrey, Sean J [0000-0002-2666-9744], and Fazakerley, Daniel [0000-0001-8241-2903]

Subjects

0301 basic medicine, Mouse, medicine.medical_treatment, plasma membrane, PI3K, Mice, Phosphatidylinositol 3-Kinases, computational biology, 0302 clinical medicine, Insulin receptor substrate, Biology (General), biology, Chemistry, phosphorylation, General Neuroscience, systems biology, General Medicine, Cell biology, 030220 oncology & carcinogenesis, Medicine, Signal transduction, signal transduction, Research Article, Computational and Systems Biology, Human, Cell signaling, insulin, QH301-705.5, Science, Mechanistic Target of Rapamycin Complex 1, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Antigens, CD, Negative feedback, medicine, Animals, Humans, Protein kinase B, PI3K/AKT/mTOR pathway, General Immunology and Microbiology, Insulin, Akt, Cell Membrane, Cell Biology, Receptor, Insulin, Insulin receptor, Glucose, 030104 developmental biology, Insulin Receptor Substrate Proteins, biology.protein, Phosphatidylinositol 3-Kinase, Proto-Oncogene Proteins c-akt

Abstract

The phosphoinositide 3-kinase (PI3K)-Akt network is tightly controlled by feedback mechanisms that regulate signal flow and ensure signal fidelity. A rapid overshoot in insulin-stimulated recruitment of Akt to the plasma membrane has previously been reported, which is indicative of negative feedback operating on acute timescales. Here, we show that Akt itself engages this negative feedback by phosphorylating insulin receptor substrate (IRS) 1 and 2 on a number of residues. Phosphorylation results in the depletion of plasma membrane-localised IRS1/2, reducing the pool available for interaction with the insulin receptor. Together these events limit plasma membrane-associated PI3K and phosphatidylinositol (3,4,5)-trisphosphate (PIP3) synthesis. We identified two Akt-dependent phosphorylation sites in IRS2 at S306 (S303 in mouse) and S577 (S573 in mouse) that are key drivers of this negative feedback. These findings establish a novel mechanism by which the kinase Akt acutely controls PIP3 abundance, through post-translational modification of the IRS scaffold., eLife digest For the body to work properly, cells must constantly ‘talk’ to each other using signalling molecules. Receiving a chemical signal triggers a series of molecular events in a cell, a so-called ‘signal transduction pathway’ that connects a signal with a precise outcome. Disturbing cell signalling can trigger disease, and strict control mechanisms are therefore in place to ensure that communication does not break down or become erratic. For instance, just as a thermostat turns off the heater once the right temperature is reached, negative feedback mechanisms in cells switch off signal transduction pathways when the desired outcome has been achieved. The hormone insulin is a signal for growth that increases in the body following a meal to promote the storage of excess blood glucose (sugar) in muscle and fat cells. The hormone binds to insulin receptors at the cell surface and switches on a signal transduction pathway that makes the cell take up glucose from the bloodstream. If the signal is not engaged diseases such as diabetes develop. Conversely, if the signal cannot be adequately switched of cancer can develop. Determining exactly how insulin works would help to understand these diseases better and to develop new treatments. Kearney et al. therefore set out to examine the biochemical ‘fail-safes’ that control insulin signalling. Experiments using computer simulations of the insulin signalling pathway revealed a potential new mechanism for negative feedback, which centred on a molecule known as Akt. The models predicted that if the negative feedback were removed, then Akt would become hyperactive and accumulate at the cell’s surface after stimulation with insulin. Further manipulation of the ‘virtual’ insulin signalling pathway and studies of live cells in culture confirmed that this was indeed the case. The cell biology experiments also showed how Akt, once at the cell surface, was able to engage the negative feedback and shut down further insulin signalling. Akt did this by inactivating a protein required to pass the signal from the insulin receptor to the rest of the cell. Overall, this work helps to understand cell communication by revealing a previously unknown, and critical component of the insulin signalling pathway.

Published

2021

8. Serine 474 phosphorylation is essential for maximal Akt2 kinase activity in adipocytes

Author

Dougall M. Norris, Kristen C. Cooke, James G. Burchfield, Daniel J. Fazakerley, Armella Zadoorian, Alison L Kearney, David E. James, and James R. Krycer

Subjects

inorganic chemicals, 0301 basic medicine, FOXO1, Mechanistic Target of Rapamycin Complex 2, mTORC1, Serine threonine protein kinase, Mechanistic Target of Rapamycin Complex 1, environment and public health, Biochemistry, mTORC2, Mice, 03 medical and health sciences, 3T3-L1 Cells, Tuberous Sclerosis Complex 2 Protein, Adipocytes, Serine, Akt Inhibitor MK2206, Animals, Insulin, Phosphorylation, Protein kinase A, Molecular Biology, Protein kinase B, Cell Nucleus, Glucose Transporter Type 4, 030102 biochemistry & molecular biology, Forkhead Box Protein O1, Chemistry, Cell Biology, Cell biology, enzymes and coenzymes (carbohydrates), Glucose, 030104 developmental biology, Protein Biosynthesis, Mutagenesis, Site-Directed, bacteria, Heterocyclic Compounds, 3-Ring, Proto-Oncogene Proteins c-akt, hormones, hormone substitutes, and hormone antagonists, Signal Transduction

Abstract

The Ser/Thr protein kinase Akt regulates essential biological processes such as cell survival, growth, and metabolism. Upon growth factor stimulation, Akt is phosphorylated at Ser(474); however, how this phosphorylation contributes to Akt activation remains controversial. Previous studies, which induced loss of Ser(474) phosphorylation by ablating its upstream kinase mTORC2, have implicated Ser(474) phosphorylation as a driver of Akt substrate specificity. Here we directly studied the role of Akt2 Ser(474) phosphorylation in 3T3-L1 adipocytes by preventing Ser(474) phosphorylation without perturbing mTORC2 activity. This was achieved by utilizing a chemical genetics approach, where ectopically expressed S474A Akt2 was engineered with a W80A mutation to confer resistance to the Akt inhibitor MK2206, and thus allow its activation independent of endogenous Akt. We found that insulin-stimulated phosphorylation of four bona fide Akt substrates (TSC2, PRAS40, FOXO1/3a, and AS160) was reduced by ∼50% in the absence of Ser(474) phosphorylation. Accordingly, insulin-stimulated mTORC1 activation, protein synthesis, FOXO nuclear exclusion, GLUT4 translocation, and glucose uptake were attenuated upon loss of Ser(474) phosphorylation. We propose a model where Ser(474) phosphorylation is required for maximal Akt2 kinase activity in adipocytes.

Published

2019

9. Signaling Heterogeneity is Defined by Pathway Architecture and Intercellular Variability in Protein Expression

Author

James G. Burchfield, Sung-Young Shin, Pengyi Yang, Lan K. Nguyen, Alison L Kearney, Daniel J. Fazakerley, Hani Jieun Kim, Alistair M. Senior, David E. James, Thomas A Geddes, Dougall M. Norris, Fazakerley, Daniel [0000-0001-8241-2903], and Apollo - University of Cambridge Repository

Subjects

0301 basic medicine, medicine.medical_treatment, Glucose uptake, Population, Cell, 02 engineering and technology, Experimental Models in Systems Biology, Article, 03 medical and health sciences, Mathematical Biosciences, medicine, education, lcsh:Science, Protein kinase B, PI3K/AKT/mTOR pathway, education.field_of_study, Multidisciplinary, biology, Chemistry, Insulin, Systems Biology, Cell Biology, 021001 nanoscience & nanotechnology, Cell biology, Insulin receptor, 030104 developmental biology, medicine.anatomical_structure, biology.protein, lcsh:Q, 0210 nano-technology, GLUT4

Abstract

Summary Insulin's activation of PI3K/Akt signaling, stimulates glucose uptake by enhancing delivery of GLUT4 to the cell surface. Here we examined the origins of intercellular heterogeneity in insulin signaling. Akt activation alone accounted for ~25% of the variance in GLUT4, indicating that additional sources of variance exist. The Akt and GLUT4 responses were highly reproducible within the same cell, suggesting the variance is between cells (extrinsic) and not within cells (intrinsic). Generalized mechanistic models (supported by experimental observations) demonstrated that the correlation between the steady-state levels of two measured signaling processes decreases with increasing distance from each other and that intercellular variation in protein expression (as an example of extrinsic variance) is sufficient to account for the variance in and between Akt and GLUT4. Thus, the response of a population to insulin signaling is underpinned by considerable single-cell heterogeneity that is largely driven by variance in gene/protein expression between cells., Graphical Abstract, Highlights • Insulin signaling is heterogeneous between cells in the same population • The temporal response of signaling components within a cell is highly reproducible • Upstream responses (Akt) can only partially predict downstream response (GLUT4) • Protein expression variance is a driver of intercellular signaling heterogeneity, Cell Biology; Mathematical Biosciences; Systems Biology; Experimental Models in Systems Biology

Published

2021

10. Trafficking regulator of GLUT4-1 (TRARG1) is a GSK3 substrate

Author

Kristen C. Cooke, Daniel J. Fazakerley, Xiaowen Duan, WP Bultitude, Frances M. Brodsky, James G. Burchfield, Pengyi Yang, Olivia J. Conway, James R. Krycer, David E. James, Dougall M. Norris, Benjamin L. Parker, and Sean J. Humphrey

Subjects

biology, Chemistry, Insulin, medicine.medical_treatment, Regulator, macromolecular substances, Cell biology, Serine, Dephosphorylation, Insulin receptor, medicine, biology.protein, Phosphorylation, GLUT4, PI3K/AKT/mTOR pathway

Abstract

Trafficking regulator of GLUT4-1, TRARG1, positively regulates insulin-stimulated GLUT4 trafficking and insulin sensitivity. However, the mechanism(s) by which this occurs remain(s) unclear. Using biochemical and mass spectrometry analyses we found that TRARG1 is dephosphorylated in response to insulin in a PI3K/Akt-dependent manner and is a novel substrate for GSK3. Priming phosphorylation of mouse TRARG1 at serine 84 allows for GSK3-directed phosphorylation at serines 72, 76 and 80. A similar pattern of phosphorylation was observed in human TRARG1, suggesting that our findings are translatable to human TRARG1. Pharmacological inhibition of GSK3 increased cell surface GLUT4 in cells stimulated with a submaximal insulin dose, and this was impaired following Trarg1 knockdown, suggesting that TRARG1 acts as a GSK3-mediated regulator in GLUT4 trafficking. TRARG1 dephosphorylation in response to insulin or GSK3 inhibition regulated its protein-protein interactions, decreasing the interaction between TRARG1 and BCL9L, JAGN1, PYGO2 and HSD17B12. Knock-down of Bcl9l promoted GLUT4 translocation to the plasma membrane. These data place TRARG1 within the insulin signaling network and provide insights into how TRARG1 regulates GLUT4 trafficking in adipocytes.

Published

2020

11. The role of the Niemann-Pick disease, type C1 protein in adipocyte insulin action

Author

James G. Burchfield, James R. Krycer, Rachael Fletcher, Xuiquan Ma, Kristen C. Thomas, Christopher Gribben, Daniel J. Fazakerley, David E. James, Fazakerley, Daniel [0000-0001-8241-2903], and Apollo - University of Cambridge Repository

Subjects

Cell signaling, Transcription, Genetic, medicine.medical_treatment, Cell Membranes, lcsh:Medicine, Type 2 diabetes, Biochemistry, Gene Knockout Techniques, Mice, hemic and lymphatic diseases, Cricetinae, Molecular Cell Biology, Adipocytes, Insulin, AKT signaling cascade, lcsh:Science, Liver X Receptors, Multidisciplinary, Glucose Transporter Type 4, biology, Intracellular Signaling Peptides and Proteins, Signaling cascades, Orphan Nuclear Receptors, Lipids, Sterols, Protein Transport, Phenotype, lipids (amino acids, peptides, and proteins), Androstenes, Cellular Structures and Organelles, Research Article, Signal Transduction, Cell biology, Cell Physiology, medicine.medical_specialty, congenital, hereditary, and neonatal diseases and abnormalities, CHO Cells, Insulin signaling cascade, Insulin resistance, Cricetulus, Niemann-Pick C1 Protein, Internal medicine, 3T3-L1 Cells, medicine, Animals, Liver X receptor, Biology and life sciences, lcsh:R, Membrane Proteins, nutritional and metabolic diseases, Proteins, medicine.disease, Hormones, IRS2, Transmembrane Proteins, Enzyme Activation, Insulin receptor, Endocrinology, Glucose, Membrane Trafficking, biology.protein, lcsh:Q, NPC1, Proto-Oncogene Proteins c-akt, GLUT4, Gene Deletion

Abstract

The Niemann-Pick disease, type C1 (NPC1) gene encodes a transmembrane protein involved in cholesterol efflux from the lysosome. SNPs within NPC1 have been associated with obesity and type 2 diabetes, and mice heterozygous or null for NPC1 are insulin resistant. However, the molecular mechanism underpinning this association is currently undefined. This study aimed to investigate the effects of inhibiting NPC1 function on insulin action in adipocytes. Both pharmacological and genetic inhibition of NPC1 impaired insulin action. This impairment was evident at the level of insulin signalling and insulin-mediated glucose transport in the short term and decreased GLUT4 expression due to reduced liver X receptor (LXR) transcriptional activity in the long-term. These data show that cholesterol homeostasis through NPC1 plays a crucial role in maintaining insulin action at multiple levels in adipocytes.

Published

2020

12. A co-receptor that represses beta-cell insulin action

Author

David E. James and James G. Burchfield

Subjects

medicine.medical_specialty, Co-receptor, Chemistry, Endocrinology, Diabetes and Metabolism, Insulin, medicine.medical_treatment, Cell Biology, Endocytosis, medicine.disease, medicine.anatomical_structure, Endocrinology, Insulin resistance, Physiology (medical), Internal medicine, Internal Medicine, medicine, Beta cell, Pancreas, Insulin signalling, Function (biology)

Abstract

Exhaustion of pancreatic beta cells in the face of prolonged insulin resistance results in the development of type II diabetes. Ansarullah et al. now describe an inhibitor of beta-cell insulin signalling that, on removal, increases beta-cell mass and improves beta-cell function, with potential as a new way to address beta-cell failure.

Published

2021

13. High dietary fat and sucrose results in an extensive and time-dependent deterioration in health of multiple physiological systems in mice

Author

P. Tess Whitworth, Ee Cheng Khor, Kyle L. Hoehn, Xiuquan Ma, James Cantley, Belinda Yau, Christopher C. Meoli, James G. Burchfield, Natalie K.Y. Wee, Jacqueline Stöckli, James R. Krycer, Shi-Xlong Tan, Annabel Y. Minard, Paul A. Baldock, Nolan J. Hoffman, Daniel J. Fazakerley, Marin E. Nelson, Trevor J. Biden, Gregory J. Cooney, Amanda L. Wright, Ronaldo F. Enriquez, Melkam A. Kebede, Kristen C. Thomas, David E. James, and Bryce Vissel

Subjects

0301 basic medicine, Male, Sucrose, obesity, Time Factors, muscle, medicine.medical_treatment, Adipose tissue, Biochemistry, deposition, Mice, Hyperinsulinemia, Glucose homeostasis, Western diet, glucose, diabetes, Leptin, neurodegeneration, secretion, nutrition, medicine.medical_specialty, Biochemistry & Molecular Biology, insulin, glucose metabolism, Carbohydrate metabolism, leptin, diseases, 03 medical and health sciences, Insulin resistance, Metabolic Diseases, Diabetes mellitus, Internal medicine, medicine, Dietary Carbohydrates, Animals, Bone, deterioration, Molecular Biology, business.industry, Insulin, beta cell(B-cell), Telomere Homeostasis, Cell Biology, medicine.disease, Dietary Fats, 030104 developmental biology, Endocrinology, business, metabolism, medical problems

Abstract

© 2018 by The American Society for Biochemistry and Molecular Biology, Inc. Obesity is associated with metabolic dysfunction, including insulin resistance and hyperinsulinemia, and with disorders such as cardiovascular disease, osteoporosis, and neurodegen-eration. Typically, these pathologies are examined in discrete model systems and with limited temporal resolution, and whether these disorders co-occur is therefore unclear. To address this question, here we examined multiple physiological systems in male C57BL/6J mice following prolonged exposure to a high-fat/high-sucrose diet (HFHSD). HFHSD-fed mice rapidly exhibited metabolic alterations, including obesity, hyperleptinemia, physical inactivity, glucose intolerance, peripheral insulin resistance, fasting hyperglycemia, ectopic lipid deposition, and bone deterioration. Prolonged exposure to HFHSD resulted in morbid obesity, ectopic triglyceride deposition in liver and muscle, extensive bone loss, sarcopenia, hyperinsulinemia, and impaired short-term memory. Although many of these defects are typically associated with aging, HFHSD did not alter telomere length in white blood cells, indicating that this diet did not generally promote all aspects of aging. Strikingly, glucose homeostasis was highly dynamic. Glucose intolerance was evident in HFHSD-fed mice after 1 week and was maintained for 24 weeks. Beyond 24 weeks, however, glucose tolerance improved in HFHSD-fed mice, and by 60 weeks, it was indistinguishable from that of chow-fed mice. This improvement coincided with adaptive -cell hyperplasia and hyperinsulinemia, without changes in insulin sensitivity in muscle or adipose tissue. Assessment of insulin secretion in isolated islets revealed that leptin, which inhibited insulin secretion in the chow-fed mice, potentiated glucose-stimulated insulin secretion in the HFHSD-fed mice after 60 weeks. Overall, the excessive calorie intake was accompanied by deteriorating function of numerous physiological systems.

Published

2018

14. Mitochondrial CoQ deficiency is a common driver of mitochondrial oxidants and insulin resistance

Author

Kyle L. Hoehn, Jerry R. Greenfield, Warren Kaplan, Ganesh Kolumam, James G. Burchfield, David E. James, Nolan J. Hoffman, Daniel L. T Chen, Jean Yh Yang, Ciana Diskin, Kelsey H. Fisher-Wellman, Sean J. Humphrey, Ghassan J. Maghzal, Kristen C. Thomas, Benjamin L. Parker, James R. Krycer, Zora Modrusan, Rima Chaudhuri, Roland Stocker, Daniel J. Fazakerley, Pengyi Yang, Dorit Samocha-Bonet, Christopher C. Meoli, Mark J. Cowley, Fazakerley, Daniel J [0000-0001-8241-2903], James, David E [0000-0001-5946-5257], and Apollo - University of Cambridge Repository

Subjects

0301 basic medicine, Mitochondrial Diseases, Mouse, Ubiquinone, medicine.medical_treatment, Respiratory chain, Adipose tissue, Mitochondrion, Mice, chemistry.chemical_compound, Adipocytes, Insulin, Glucose homeostasis, Biology (General), Muscle Weakness, Chemistry, Superoxide, Muscles, General Neuroscience, human biology, food and beverages, General Medicine, Oxidants, Mitochondria, 3. Good health, Adipose Tissue, Medicine, Research Article, Human, medicine.medical_specialty, QH301-705.5, Science, Sensitivity and Specificity, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Insulin resistance, Internal medicine, medicine, Animals, Humans, Human Biology and Medicine, General Immunology and Microbiology, Coenzyme Q, Cell Biology, medicine.disease, 030104 developmental biology, Endocrinology, Coenzyme Q – cytochrome c reductase, Ataxia

Abstract

Insulin resistance in muscle, adipocytes and liver is a gateway to a number of metabolic diseases. Here, we show a selective deficiency in mitochondrial coenzyme Q (CoQ) in insulin-resistant adipose and muscle tissue. This defect was observed in a range of in vitro insulin resistance models and adipose tissue from insulin-resistant humans and was concomitant with lower expression of mevalonate/CoQ biosynthesis pathway proteins in most models. Pharmacologic or genetic manipulations that decreased mitochondrial CoQ triggered mitochondrial oxidants and insulin resistance while CoQ supplementation in either insulin-resistant cell models or mice restored normal insulin sensitivity. Specifically, lowering of mitochondrial CoQ caused insulin resistance in adipocytes as a result of increased superoxide/hydrogen peroxide production via complex II. These data suggest that mitochondrial CoQ is a proximal driver of mitochondrial oxidants and insulin resistance, and that mechanisms that restore mitochondrial CoQ may be effective therapeutic targets for treating insulin resistance., eLife digest After we eat, our blood sugar levels increase. To counteract this, the pancreas releases a hormone called insulin. Part of insulin’s effect is to promote the uptake of sugar from the blood into muscle and fat tissue for storage. Under certain conditions, such as obesity, this process can become defective, leading to a condition known as insulin resistance. This condition makes a number of human diseases more likely to develop, including type 2 diabetes. Working out how insulin resistance develops could therefore unveil new treatment strategies for these diseases. Mitochondria – structures that produce most of a cell’s energy supply – appear to play a role in the development of insulin resistance. Mitochondria convert nutrients such as fats and sugars into molecules called ATP that fuel the many processes required for life. However, ATP production can also generate potentially harmful intermediates often referred to as ‘reactive oxygen species’ or ‘oxidants’. Previous studies have suggested that an increase in the amount of oxidants produced in mitochondria can cause insulin resistance. Fazakerley et al. therefore set out to identify the reason for increased oxidants in mitochondria, and did so by analysing the levels of proteins and oxidants found in cells grown in the laboratory, and mouse and human tissue samples. This led them to find that concentrations of a molecule called coenzyme Q (CoQ), an essential component of mitochondria that helps to produce ATP, were lower in mitochondria from insulin-resistant fat and muscle tissue. Further experiments suggested a link between the lower levels of CoQ and the higher levels of oxidants in the mitochondria. Replenishing the mitochondria of the lab-grown cells and insulin-resistant mice with CoQ restored ‘normal’ oxidant levels and prevented the development of insulin resistance. Strategies that aim to increase mitochondria CoQ levels may therefore prevent or reverse insulin resistance. Although CoQ supplements are readily available, swallowing CoQ does not efficiently deliver CoQ to mitochondria in humans, so alternative treatment methods must be found. It is also of interest that statins, common drugs taken by millions of people around the world to lower cholesterol, also lower CoQ and have been reported to increase the risk of developing type 2 diabetes. Further research is therefore needed to investigate whether CoQ might provide the link between statins and type 2 diabetes.

Published

2018

15. Mitochondrial oxidative stress causes insulin resistance without disrupting oxidative phosphorylation

Author

Daniel J, Fazakerley, Annabel Y, Minard, James R, Krycer, Kristen C, Thomas, Jacqueline, Stöckli, Dylan J, Harney, James G, Burchfield, Ghassan J, Maghzal, Stuart T, Caldwell, Richard C, Hartley, Roland, Stocker, Michael P, Murphy, and David E, James

Subjects

Male, Paraquat, insulin, muscle, hydrogen peroxide, adipocyte, Oxidative Phosphorylation, Electron Transport, Myoblasts, Mice, Oxygen Consumption, Superoxides, 3T3-L1 Cells, insulin resistance, Adipocytes, Animals, Protein Isoforms, oxidative stress, superoxide ion, Glucose Transporter Type 4, Herbicides, Adenylate Kinase, Peroxiredoxins, Mitochondria, adipose tissue, Mice, Inbred C57BL, Glucose, Metabolism, Mitochondrial dysfunction

Abstract

Mitochondrial oxidative stress, mitochondrial dysfunction, or both have been implicated in insulin resistance. However, disentangling the individual roles of these processes in insulin resistance has been difficult because they often occur in tandem, and tools that selectively increase oxidant production without impairing mitochondrial respiration have been lacking. Using the dimer/monomer status of peroxiredoxin isoforms as an indicator of compartmental hydrogen peroxide burden, we provide evidence that oxidative stress is localized to mitochondria in insulin-resistant 3T3-L1 adipocytes and adipose tissue from mice. To dissociate oxidative stress from impaired oxidative phosphorylation and study whether mitochondrial oxidative stress per se can cause insulin resistance, we used mitochondria-targeted paraquat (MitoPQ) to generate superoxide within mitochondria without directly disrupting the respiratory chain. At ≤10 μm, MitoPQ specifically increased mitochondrial superoxide and hydrogen peroxide without altering mitochondrial respiration in intact cells. Under these conditions, MitoPQ impaired insulin-stimulated glucose uptake and glucose transporter 4 (GLUT4) translocation to the plasma membrane in both adipocytes and myotubes. MitoPQ recapitulated many features of insulin resistance found in other experimental models, including increased oxidants in mitochondria but not cytosol; a more profound effect on glucose transport than on other insulin-regulated processes, such as protein synthesis and lipolysis; an absence of overt defects in insulin signaling; and defective insulin- but not AMP-activated protein kinase (AMPK)-regulated GLUT4 translocation. We conclude that elevated mitochondrial oxidants rapidly impair insulin-regulated GLUT4 translocation and significantly contribute to insulin resistance and that MitoPQ is an ideal tool for studying the link between mitochondrial oxidative stress and regulated GLUT4 trafficking.

Published

2017

16. Proteomic Analysis of GLUT4 Storage Vesicles Reveals Tumor Suppressor Candidate 5 (TUSC5) as a Novel Regulator of Insulin Action in Adipocytes*

Author

Christopher C. Meoli, James G. Burchfield, Sheyda Naghiloo, Matthew J. Prior, Daniel J. Fazakerley, Benjamin L. Parker, Jacqueline Stöckli, Rima Chaudhuri, David E. James, Beverley A. Murrow, Geoffrey D. Holman, James R. Krycer, Kristen C. Thomas, Francoise Koumanov, Fazakerley, Daniel [0000-0001-8241-2903], and Apollo - University of Cambridge Repository

Subjects

Male, Proteomics, medicine.medical_specialty, insulin, Glucose uptake, medicine.medical_treatment, Peroxisome proliferator-activated receptor, adipocyte, Biochemistry, 03 medical and health sciences, Mice, 0302 clinical medicine, Insulin resistance, Internal medicine, Insulin receptor substrate, insulin resistance, 3T3-L1 Cells, medicine, Adipocytes, tumor suppressor candidate 5 (TUSC5), Animals, glucose transporter type 4 (GLUT4), Rats, Wistar, Molecular Biology, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, Glucose Transporter Type 4, biology, Insulin, membrane trafficking, Tumor Suppressor Proteins, Glucose transporter, Cell Biology, medicine.disease, Rats, Insulin receptor, Endocrinology, chemistry, biology.protein, 030217 neurology & neurosurgery, GLUT4

Abstract

Background: We searched for novel regulators of insulin-stimulated glucose transport in adipocytes. Results: Tumor suppressor candidate 5 (TUSC5) colocalized with GLUT4, and manipulation of TUSC5 expression levels affected insulin-regulated glucose transport. Conclusion: TUSC5 is a novel regulator of insulin-stimulated glucose transport. Significance: TUSC5 contributes to insulin-sensitizing effects of PPARγ agonists in adipocytes., Insulin signaling augments glucose transport by regulating glucose transporter 4 (GLUT4) trafficking from specialized intracellular compartments, termed GLUT4 storage vesicles (GSVs), to the plasma membrane. Proteomic analysis of GSVs by mass spectrometry revealed enrichment of 59 proteins in these vesicles. We measured reduced abundance of 23 of these proteins following insulin stimulation and assigned these as high confidence GSV proteins. These included established GSV proteins such as GLUT4 and insulin-responsive aminopeptidase, as well as six proteins not previously reported to be localized to GSVs. Tumor suppressor candidate 5 (TUSC5) was shown to be a novel GSV protein that underwent a 3.7-fold increase in abundance at the plasma membrane in response to insulin. siRNA-mediated knockdown of TUSC5 decreased insulin-stimulated glucose uptake, although overexpression of TUSC5 had the opposite effect, implicating TUSC5 as a positive regulator of insulin-stimulated glucose transport in adipocytes. Incubation of adipocytes with TNFα caused insulin resistance and a concomitant reduction in TUSC5. Consistent with previous studies, peroxisome proliferator-activated receptor (PPAR) γ agonism reversed TNFα-induced insulin resistance. TUSC5 expression was necessary but insufficient for PPARγ-mediated reversal of insulin resistance. These findings functionally link TUSC5 to GLUT4 trafficking, insulin action, insulin resistance, and PPARγ action in the adipocyte. Further studies are required to establish the exact role of TUSC5 in adipocytes.

Published

2015

17. Improved Akt reporter reveals intra- and inter-cellular heterogeneity and oscillations in signal transduction

Author

David E. James, James G. Burchfield, Pengyi Yang, Dougall M. Norris, Daniel J. Fazakerley, and James R. Krycer

Subjects

0301 basic medicine, Recombinant Fusion Proteins, medicine.medical_treatment, Green Fluorescent Proteins, AKT2, Biology, Green fluorescent protein, Mice, 03 medical and health sciences, Genes, Reporter, 3T3-L1 Cells, medicine, Animals, Tissue Distribution, Protein kinase B, PI3K/AKT/mTOR pathway, Protein Stability, Insulin, Cell Biology, Molecular Imaging, Cell biology, Protein Transport, 030104 developmental biology, Signalling, Biochemistry, Phosphorylation, Signal transduction, Proto-Oncogene Proteins c-akt, Signal Transduction

Abstract

Akt is a key node in a range of signal transduction cascades and play a critical role in diseases such as cancer and diabetes. Fluorescently-tagged Akt reporters have been used to discern Akt localisation, yet it has not been clear how well these tools recapitulate the behaviour of endogenous Akt proteins. Here, we observed that fusion of eGFP to Akt2 impaired both its insulin-stimulated plasma membrane recruitment and its phosphorylation. Endogenous-like responses were restored by replacing eGFP with TagRFP-T. The improved response magnitude and sensitivity afforded by TagRFP-T–Akt2 over eGFP–Akt2 enabled monitoring of signalling outcomes in single cells at physiological doses of insulin with subcellular resolution and revealed two previously unreported features of Akt biology. In 3T3-L1 adipocytes, stimulation with insulin resulted in recruitment of Akt2 to the plasma membrane in a polarised fashion. Additionally, we observed oscillations in plasma membrane localised Akt2 in the presence of insulin with a consistent periodicity of 2 min. Our studies highlight the importance of fluorophore choice when generating reporter constructs and shed light on new Akt signalling responses that may encode complex signalling information. This article has an associated First Person interview with the first author of the paper.

Published

2017

18. Systemic VEGF-A Neutralization Ameliorates Diet-Induced Metabolic Dysfunction

Author

James G. Burchfield, Sofianos Andrikopoulos, Lindsay E. Wu, David E. James, David G. Le Couteur, Chrysovalantou E. Xirouchaki, Myung Jin Kang, Elizabeth E. Powter, Ganesh Kolumam, Daniel J. Fazakerley, Salvatore P. Mangiafico, Nicholas van Bruggen, Mashani Mohamad, Victoria C. Cogger, Jacqueline Stöckli, Himani Pant, A. Stefanie Mikolaizak, Jennifer R. Gamble, Gregory J. Cooney, and Christopher C. Meoli

Subjects

Male, Vascular Endothelial Growth Factor A, medicine.medical_specialty, Angiogenesis, Endocrinology, Diabetes and Metabolism, medicine.medical_treatment, Adipose tissue, Carbohydrate metabolism, Antibodies, Mice, chemistry.chemical_compound, Insulin resistance, Internal medicine, Genetic model, Internal Medicine, medicine, Animals, Homeostasis, Insulin, Obesity, Adiposity, biology, medicine.disease, Animal Feed, Dietary Fats, Vascular endothelial growth factor, Insulin receptor, Glucose, Endocrinology, Liver, chemistry, Immunoglobulin G, biology.protein, Insulin Resistance, Signal Transduction

Abstract

The vascular endothelial growth factor (VEGF) family of cytokines are important regulators of angiogenesis that have emerged as important targets for the treatment of obesity. While serum VEGF levels rise during obesity, recent studies using genetic models provide conflicting evidence as to whether VEGF prevents or accelerates metabolic dysfunction during obesity. In the current study, we sought to identify the effects of VEGF-A neutralization on parameters of glucose metabolism and insulin action in a dietary mouse model of obesity. Within only 72 h of administration of the VEGF-A–neutralizing monoclonal antibody B.20-4.1, we observed almost complete reversal of high-fat diet–induced insulin resistance principally due to improved insulin sensitivity in the liver and in adipose tissue. These effects were independent of changes in whole-body adiposity or insulin signaling. These findings show an important and unexpected role for VEGF in liver insulin resistance, opening up a potentially novel therapeutic avenue for obesity-related metabolic disease.

Published

2014

19. DOC2 isoforms play dual roles in insulin secretion and insulin-stimulated glucose uptake

Author

Alexander J. Groffen, James G. Burchfield, James Cantley, Himani Pant, P.T. Whitworth, David E. James, Jia Li, Christopher C. Meoli, Rima Chaudhuri, Jacqueline Stöckli, Matthijs Verhage, Functional Genomics, Neuroscience Campus Amsterdam - Brain Mechanisms in Health & Disease, Human genetics, and NCA - Brain mechanisms in health and disease

Subjects

Male, medicine.medical_specialty, Endocrinology, Diabetes and Metabolism, Glucose uptake, medicine.medical_treatment, Nerve Tissue Proteins, Exocytosis, Mice, SDG 3 - Good Health and Well-being, Internal medicine, Insulin Secretion, Adipocytes, Internal Medicine, medicine, Animals, Insulin, Glucose homeostasis, Mice, Knockout, biology, Calcium-Binding Proteins, Biological Transport, Intracellular vesicle, Insulin receptor, Glucose, Endocrinology, biology.protein, Beta cell, GLUT4

Abstract

Glucose-stimulated insulin secretion (GSIS) and insulin-stimulated glucose uptake are processes that rely on regulated intracellular vesicle transport and vesicle fusion with the plasma membrane. DOC2A and DOC2B are calcium-sensitive proteins that were identified as key components of vesicle exocytosis in neurons. Our aim was to investigate the role of DOC2 isoforms in glucose homeostasis, insulin secretion and insulin action.DOC2 expression was measured by RT-PCR and western blotting. Body weight, glucose tolerance, insulin action and GSIS were assessed in wild-type (WT), Doc2a (-/-) (Doc2aKO), Doc2b (-/-) (Doc2bKO) and Doc2a (-/-)/Doc2b (-/-) (Doc2a/Doc2bKO) mice in vivo. In vitro GSIS and glucose uptake were assessed in isolated tissues, and exocytotic proteins measured by western blotting. GLUT4 translocation was assessed by epifluorescence microscopy.Doc2b mRNA was detected in all tissues tested, whereas Doc2a was only detected in islets and the brain. Doc2aKO and Doc2bKO mice had minor glucose intolerance, while Doc2a/Doc2bKO mice showed pronounced glucose intolerance. GSIS was markedly impaired in Doc2a/Doc2bKO mice in vivo, and in isolated Doc2a/Doc2bKO islets in vitro. In contrast, Doc2bKO mice had only subtle defects in insulin secretion in vivo. Insulin action was impaired to a similar degree in both Doc2bKO and Doc2a/Doc2bKO mice. In vitro insulin-stimulated glucose transport and GLUT4 vesicle fusion were defective in adipocytes derived from Doc2bKO mice. Surprisingly, insulin action was not altered in muscle isolated from DOC2-null mice.Our study identifies a critical role for DOC2B in insulin-stimulated glucose uptake in adipocytes, and for the synergistic regulation of GSIS by DOC2A and DOC2B in beta cells.

Published

2014

20. Direction pathway analysis of large-scale proteomics data reveals novel features of the insulin action pathway

Author

Shi-Xiong Tan, James G. Burchfield, Yee Hwa Yang, Christopher Gribben, Matthew J. Prior, David E. James, Daniel J. Fazakerley, Pengyi Yang, and Ellis Patrick

Subjects

Proteomics, Statistics and Probability, Proteome, Proto-Oncogene Proteins c-akt, medicine.medical_treatment, Cell, Biology, Biochemistry, Cell membrane, Phosphatidylinositol 3-Kinases, Adipocytes, medicine, Insulin, Molecular Biology, Protein kinase B, Kinase, Cell Membrane, fungi, Biological Transport, Original Papers, Computer Science Applications, Cell biology, Computational Mathematics, medicine.anatomical_structure, Computational Theory and Mathematics, Software

Abstract

Motivation: With the advancement of high-throughput techniques, large-scale profiling of biological systems with multiple experimental perturbations is becoming more prevalent. Pathway analysis incorporates prior biological knowledge to analyze genes/proteins in groups in a biological context. However, the hypotheses under investigation are often confined to a 1D space (i.e. up, down, either or mixed regulation). Here, we develop direction pathway analysis (DPA), which can be applied to test hypothesis in a high-dimensional space for identifying pathways that display distinct responses across multiple perturbations. Results: Our DPA approach allows for the identification of pathways that display distinct responses across multiple perturbations. To demonstrate the utility and effectiveness, we evaluated DPA under various simulated scenarios and applied it to study insulin action in adipocytes. A major action of insulin in adipocytes is to regulate the movement of proteins from the interior to the cell surface membrane. Quantitative mass spectrometry-based proteomics was used to study this process on a large-scale. The combined dataset comprises four separate treatments. By applying DPA, we identified that several insulin responsive pathways in the plasma membrane trafficking are only partially dependent on the insulin-regulated kinase Akt. We subsequently validated our findings through targeted analysis of key proteins from these pathways using immunoblotting and live cell microscopy. Our results demonstrate that DPA can be applied to dissect pathway networks testing diverse hypotheses and integrating multiple experimental perturbations. Availability and implementation: The R package ‘directPA’ is distributed from CRAN under GNU General Public License (GPL)-3 and can be downloaded from: http://cran.r-project.org/web/packages/directPA/index.html Contact: jean.yang@sydney.edu.au Supplementary Information: Supplementary data are available at Bioinformatics online.

Published

2013

21. Novel Systems for Dynamically Assessing Insulin Action in Live Cells Reveals Heterogeneity in the Insulin Response

Author

Katarina Mele, Weiping Han, Michael Buckley, William E. Hughes, James G. Burchfield, Jinling Lu, Daniel J. Fazakerley, Yvonne Ng, Shi-Xiong Tan, and David E. James

Subjects

education.field_of_study, biology, Insulin, medicine.medical_treatment, Population, Cell, Cell Biology, Stimulus (physiology), medicine.disease, Biochemistry, 3T3 cells, Cell biology, medicine.anatomical_structure, Insulin resistance, Structural Biology, Genetics, medicine, biology.protein, education, Molecular Biology, Intracellular, GLUT4

Abstract

Regulated GLUT4 trafficking is a key action of insulin. Quantitative stepwise analysis of this process provides a powerful tool for pinpointing regulatory nodes that contribute to insulin regulation and insulin resistance. We describe a novel GLUT4 construct and workflow for the streamlined dissection of GLUT4 trafficking; from simple high throughput screens to high resolution analyses of individual vesicles. We reveal single cell heterogeneity in insulin action highlighting the utility of this approach - each cell displayed a unique and highly reproducible insulin response, implying that each cell is hard-wired to produce a specific output in response to a given stimulus. These data highlight that the response of a cell population to insulin is underpinned by extensive heterogeneity at the single cell level. This heterogeneity is pre-programmed within each cell and is not the result of intracellular stochastic events.

Published

2013

22. The amino acid transporter, SLC1A3, is plasma membrane-localised in adipocytes and its activity is insensitive to insulin

Author

Renae M. Ryan, James R. Krycer, Daniel J. Fazakerley, James G. Burchfield, Robert J. Vandenberg, Rosemary J. Cater, Sean J. Humphrey, Kristen C. Thomas, David E. James, and Sheyda Naghiloo

Subjects

0301 basic medicine, medicine.medical_treatment, Biophysics, Xenopus, Biochemistry, 03 medical and health sciences, chemistry.chemical_compound, Mice, Xenopus laevis, Structural Biology, Adipocyte, 3T3-L1 Cells, Genetics, medicine, Adipocytes, Animals, Humans, Insulin, Protein phosphorylation, Amino acid transporter, Amino Acid Sequence, Phosphorylation, Molecular Biology, biology, Catabolism, Cell Membrane, Cell Biology, biology.organism_classification, Excitatory Amino Acid Transporter 1, 030104 developmental biology, HEK293 Cells, chemistry, Oocytes, Heterologous expression

Abstract

The hormone insulin coordinates the catabolism of nutrients by protein phosphorylation. Phosphoproteomic analysis identified insulin-responsive phosphorylation of the Glu/Asp transporter SLC1A3/EAAT1 in adipocytes. The role of SLC1A3 in adipocytes is not well-understood. We show that SLC1A3 is localised to the plasma membrane and the major regulator of acidic amino acid uptake in adipocytes. However, its localisation and activity were unaffected by insulin or mutation of the insulin-regulated phosphosite. The latter was also observed using a heterologous expression system in Xenopus laevis oocytes. Thus, SLC1A3 maintains a constant import of acidic amino acids independent of nutritional status in adipocytes. This article is protected by copyright. All rights reserved.

Published

2016

23. Deletion of PKC Selectively Enhances the Amplifying Pathways of Glucose-Stimulated Insulin Secretion via Increased Lipolysis in Mouse -Cells

Author

James Cantley, Michael Leitges, Gemma L. Pearson, Carsten Schmitz-Peiffer, Trevor J. Biden, and James G. Burchfield

Subjects

Male, endocrine system, medicine.medical_specialty, Lipolysis, Endocrinology, Diabetes and Metabolism, medicine.medical_treatment, Protein Kinase C-epsilon, Biology, Mice, Downregulation and upregulation, Insulin-Secreting Cells, Internal medicine, Insulin Secretion, Internal Medicine, medicine, Animals, Insulin, Glucose homeostasis, Secretion, Crosses, Genetic, Protein kinase C, Mice, Knockout, Glucose, Endocrinology, Islet Studies, Lipotoxicity, Lipase inhibitors, Original Article, Female, Gene Deletion

Abstract

OBJECTIVE Insufficient insulin secretion is a hallmark of type 2 diabetes, and exposure of β-cells to elevated lipid levels (lipotoxicity) contributes to secretory dysfunction. Functional ablation of protein kinase C ε (PKCε) has been shown to improve glucose homeostasis in models of type 2 diabetes and, in particular, to enhance glucose-stimulated insulin secretion (GSIS) after lipid exposure. Therefore, we investigated the lipid-dependent mechanisms responsible for the enhanced GSIS after inactivation of PKCε. RESEARCH DESIGN AND METHODS We cultured islets isolated from PKCε knockout (PKCεKO) mice in palmitate prior to measuring GSIS, Ca2+ responses, palmitate esterification products, lipolysis, lipase activity, and gene expression. RESULTS The enhanced GSIS could not be explained by increased expression of another PKC isoform or by alterations in glucose-stimulated Ca2+ influx. Instead, an upregulation of the amplifying pathways of GSIS in lipid-cultured PKCεKO β-cells was revealed under conditions in which functional ATP-sensitive K+ channels were bypassed. Furthermore, we showed increased esterification of palmitate into triglyceride pools and an enhanced rate of lipolysis and triglyceride lipase activity in PKCεKO islets. Acute treatment with the lipase inhibitor orlistat blocked the enhancement of GSIS in lipid-cultured PKCεKO islets, suggesting that a lipolytic product mediates the enhancement of glucose-amplified insulin secretion after PKCε deletion. CONCLUSIONS Our findings demonstrate a mechanistic link between lipolysis and the amplifying pathways of GSIS in murine β-cells, and they suggest an interaction between PKCε and lipolysis. These results further highlight the therapeutic potential of PKCε inhibition to enhance GSIS from the β-cell under conditions of lipid excess.

Published

2016

24. The diverse roles of protein kinase C in pancreatic β-cell function

Author

James Cantley, Chris J. Mitchell, Trevor J. Biden, James G. Burchfield, Carsten Schmitz-Peiffer, Lee Carpenter, and Ebru Gurisik

Subjects

Mice, Knockout, Gene isoform, Cell type, Cell growth, Biology, Biochemistry, Cell biology, MAP2K7, Isoenzymes, Serine, Mice, Glucose, Diabetes Mellitus, Type 2, Cell surface receptor, Insulin-Secreting Cells, Animals, Insulin, Secretion, Protein Kinase C, Protein kinase C, Signal Transduction

Abstract

Members of the serine/threonine PKC (protein kinase C) family perform diverse functions in multiple cell types. All members of the family are activated in signalling cascades triggered by occupation of cell surface receptors, but the cPKC (conventional PKC) and nPKC (novel PKC) isoforms are also responsive to fatty acid metabolites. PKC isoforms are involved in various aspects of pancreatic β-cell function, including cell proliferation, differentiation and death, as well as regulation of secretion in response to glucose and muscarinic receptor agonists. Recently, the nPKC isoform, PKCϵ, has also been implicated in the loss of insulin secretory responsiveness that underpins the development of Type 2 diabetes.

Published

2008

25. Inhibition of PKCɛ Improves Glucose-Stimulated Insulin Secretion and Reduces Insulin Clearance

Author

Michael Leitges, Trevor J. Biden, Uschi Braun, James G. Burchfield, Gregory J. Cooney, David J. Pedersen, Ebru Gurisik, Sakura Narasimhan, D. Ross Laybutt, Chris J. Mitchell, and Carsten Schmitz-Peiffer

Subjects

medicine.medical_specialty, Physiology, medicine.medical_treatment, HUMDISEASE, Protein Kinase C-epsilon, Type 2 diabetes, Biology, Mice, Insulin-Secreting Cells, Diabetes mellitus, Internal medicine, Insulin receptor substrate, Insulin Secretion, medicine, Animals, Insulin, Secretion, Molecular Biology, Protein kinase C, Cell Biology, medicine.disease, Mice, Mutant Strains, Insulin oscillation, Glucose, Endocrinology, Diabetes Mellitus, Type 2, Gene Deletion, Intracellular

Abstract

In type 2 diabetes, pancreatic beta cells fail to secrete sufficient insulin to overcome peripheral insulin resistance. Intracellular lipid accumulation contributes to beta cell failure through poorly defined mechanisms. Here we report a role for the lipid-regulated protein kinase C isoform PKCepsilon in beta cell dysfunction. Deletion of PKCepsilon augmented insulin secretion and prevented glucose intolerance in fat-fed mice. Importantly, a PKCepsilon-inhibitory peptide improved insulin availability and glucose tolerance in db/db mice with preexisting diabetes. Functional ablation of PKCepsilon selectively enhanced insulin release ex vivo from diabetic or lipid-pretreated islets and optimized the glucose-regulated lipid partitioning that amplifies the secretory response. Independently, PKCepsilon deletion also augmented insulin availability by reducing both whole-body insulin clearance and insulin uptake by hepatocytes. Our findings implicate PKCepsilon in the etiology of beta cell dysfunction and highlight that enhancement of insulin availability, through separate effects on liver and beta cells, provides a rationale for inhibiting PKCepsilon to treat type 2 diabetes.

Published

2007

26. Using Total Internal Reflection Fluorescence Microscopy (TIRFM) to Visualise Insulin Action

Author

Jamie A. Lopez, James G. Burchfield, and William E. Hughes

Subjects

Total internal reflection fluorescence microscope, Chemistry, Insulin, medicine.medical_treatment, Microscopy, Analytical chemistry, Biophysics, medicine

Published

2012

27. Cluster Analysis of Insulin Action in Adipocytes Reveals a Key Role for Akt at the Plasma Membrane*

Author

Yvonne Ng, Jacqueline Stöckli, James G. Burchfield, Adelle C.F. Coster, David E. James, and Georg Ramm

Subjects

GTPase-activating protein, Detergents, Biology, Biochemistry, Models, Biological, Substrate-level phosphorylation, chemistry.chemical_compound, Mice, Membrane Microdomains, 3T3-L1 Cells, Adipocytes, Animals, Cluster Analysis, Hypoglycemic Agents, Insulin, Phosphatidylinositol, Phosphorylation, Protein kinase A, Molecular Biology, Protein kinase B, PI3K/AKT/mTOR pathway, Protein Kinase C, Glucose Transporter Type 4, Dose-Response Relationship, Drug, Mechanisms of Signal Transduction, Cell Membrane, GTPase-Activating Proteins, Cell Biology, Cell biology, chemistry, Solubility, Signal transduction, Proto-Oncogene Proteins c-akt, Signal Transduction

Abstract

The phosphatidylinositol 3-kinase/Akt pathway regulates many biological processes, including insulin-regulated GLUT4 insertion into the plasma membrane. However, Akt operates well below its capacity to facilitate maximal GLUT4 translocation. Thus, reconciling modest changes in Akt expression or activity as a cause of metabolic dysfunction is complex. To resolve this, we examined insulin regulation of components within the signaling cascade in a quantitative kinetic and dose-response study combined with hierarchical cluster analysis. This revealed a strong relationship between phosphorylation of Akt substrates and GLUT4 translocation but not whole cell Akt phosphorylation. In contrast, Akt activity at the plasma membrane strongly correlated with GLUT4 translocation and Akt substrate phosphorylation. Additionally, two of the phosphorylated sites in the Akt substrate AS160 clustered separately, with Thr(P)-642 grouped with other Akt substrates. Further experiments suggested that atypical protein kinase Czeta phosphorylates AS160 at Ser-588 and that these two sites are mutually exclusive. These data indicate the utility of hierarchical cluster analysis for identifying functionally related biological nodes and highlight the importance of subcellular partitioning of key signaling components for biological specificity.

Published

2009

28. Variations in the requirement for v-SNAREs in GLUT4 trafficking in adipocytes

Author

Wanjin Hong, Jamie A. Lopez, Lu Yang, James G. Burchfield, Tao Xu, Junmei Fan, David E. James, Li Bai, and Ping Zhao

Subjects

VAMP3, Mice, Knockout, Total internal reflection fluorescence microscope, Vesicle fusion, Glucose Transporter Type 4, VAMP2, Vesicle-Associated Membrane Protein 3, Vesicle-Associated Membrane Protein 2, Vesicle docking, Vesicle, Cell Membrane, Cell Biology, Biology, Transport protein, Cell biology, Vesicular transport protein, R-SNARE Proteins, Mice, Protein Transport, Adipocytes, Animals, Insulin, Cells, Cultured

Abstract

Vesicle transport in eukaryotic cells is regulated by SNARE proteins, which play an intimate role in regulating the specificity of vesicle fusion between discrete intracellular organelles. In the present study we investigated the function and plasticity of v-SNAREs in insulin-regulated GLUT4 trafficking in adipocytes. Using a combination of knockout mice, v-SNARE cleavage by clostridial toxins and total internal reflection fluorescence microscopy, we interrogated the function of VAMPs 2, 3 and 8 in this process. Our studies reveal that the simultaneous disruption of VAMPs 2, 3 and 8 completely inhibited insulin-stimulated GLUT4 insertion into the plasma membrane, due to a block in vesicle docking at the plasma membrane. These defects could be rescued by re-expression of VAMP2, VAMP3 or VAMP8 alone, but not VAMP7. These data indicate a plasticity in the requirement for v-SNAREs in GLUT4 trafficking to the plasma membrane and further define an important role for the v-SNARE proteins in pre-fusion docking of vesicles.

Published

2009

29. Identification of a distal GLUT4 trafficking event controlled by actin polymerization

Author

Pascal Vallotton, David E. James, Katarina Mele, James G. Burchfield, Jamie A. Lopez, Duncan H. Blair, William E. Hughes, and Yvonne Ng

Subjects

Recombinant Fusion Proteins, Green Fluorescent Proteins, Arp2/3 complex, Adipose tissue, Membrane Fusion, Exocytosis, Mice, 3T3-L1 Cells, Adipocytes, Glucose homeostasis, Animals, Insulin, Cystinyl Aminopeptidase, Transport Vesicles, Molecular Biology, Actin, Cytoskeleton, Glucose Transporter Type 4, biology, Tethering, Cell Membrane, Actin remodeling, Cell Biology, Articles, Actins, Cell biology, Microscopy, Fluorescence, Docking (molecular), biology.protein, Proto-Oncogene Proteins c-akt, GLUT4, Signal Transduction

Abstract

The insulin-stimulated trafficking of GLUT4 to the plasma membrane in muscle and fat tissue constitutes a central process in blood glucose homeostasis. The tethering, docking, and fusion of GLUT4 vesicles with the plasma membrane (PM) represent the most distal steps in this pathway and have been recently shown to be key targets of insulin action. However, it remains unclear how insulin influences these processes to promote the insertion of the glucose transporter into the PM. In this study we have identified a previously uncharacterized role for cortical actin in the distal trafficking of GLUT4. Using high-frequency total internal reflection fluorescence microscopy (TIRFM) imaging, we show that insulin increases actin polymerization near the PM and that disruption of this process inhibited GLUT4 exocytosis. Using TIRFM in combination with probes that could distinguish between vesicle transport and fusion, we found that defective actin remodeling was accompanied by normal insulin-regulated accumulation of GLUT4 vesicles close to the PM, but the final exocytotic fusion step was impaired. These data clearly resolve multiple steps of the final stages of GLUT4 trafficking, demonstrating a crucial role for actin in the final stage of this process.

Published

2009

30. Akt mediates insulin-stimulated phosphorylation of Ndrg2: evidence for cross-talk with protein kinase C theta

Author

James G, Burchfield, Alecia J, Lennard, Sakura, Narasimhan, William E, Hughes, Valerie C, Wasinger, Garry L, Corthals, Tomohiko, Okuda, Hisato, Kondoh, Trevor J, Biden, and Carsten, Schmitz-Peiffer

Subjects

Male, Molecular Sequence Data, Muscle Fibers, Skeletal, Protein Serine-Threonine Kinases, Nodal Signaling Ligands, Transfection, Substrate Specificity, Mice, Proto-Oncogene Proteins, Animals, Humans, Insulin, Amino Acid Sequence, Phosphorylation, Rats, Wistar, Muscle, Skeletal, Cells, Cultured, Protein Kinase C, Proteins, Receptor Cross-Talk, Rats, Isoenzymes, Protein Kinase C-theta, Proto-Oncogene Proteins c-akt, Sequence Alignment, Signal Transduction

Abstract

The protein kinase Akt mediates several metabolic and mitogenic effects of insulin, whereas activation of protein kinase C (PKC) isoforms has been implicated in the inhibition of insulin action. We have previously shown that both PKC and PKCepsilon are activated in skeletal muscle of insulin-resistant high fat-fed rats, and to identify potential substrates for these kinases, we incubated recombinant PKC isoforms with rat muscle fractions in vitro. PKC specifically phosphorylated a 48-kDa protein that was subsequently identified by mass spectrometry as Ndrg2. Ndrg2 is highly related to N-Myc downstream-regulated protein 1, which has been linked to stress responses, cell proliferation, and differentiation, although Ndrg2 itself is not repressed by N-Myc. Ndrg2 contains several potential phosphorylation sites, including three Akt consensus sequences. Ndrg2 phosphorylation was enhanced in [32P]orthophosphate-labeled C2C12 muscle cells co-overexpressing either PKC or Akt. Phosphorylation of Ndrg2 was examined further using a phospho (Ser/Thr) Akt substrate antibody. Insulin increased Ndrg2 phosphorylation in C2C12 cells in a wortmannin- and palmitate-inhibitable manner, whereas rapamycin, PD98059, and bisindoylmaleimide I had no effect, supporting a direct role for Akt. Mutation of Ndrg2 indicated that Thr-348 is the major phosphorylation site detected by the antibody and that Akt stimulates phosphorylation of this site, whereas PKC phosphorylates Ser-332. PKC overexpression, however, diminished the effect of insulin on Thr-348 phosphorylation without reducing Akt activation, suggesting that this is mediated through phosphorylation of Ndrg2 at Ser-332. Our data identify Ndrg2 as a novel insulin-dependent phosphoprotein and suggest that PKC may inhibit insulin action in part by reducing its phosphorylation by Akt.

Published

2004

31. Glucose Homeostasis in Mice Is Transglutaminase 2 Independent

Author

Robert M. Graham, Sara R. Holman, Gregory J. Cooney, Kristy Jackson, James G. Burchfield, Carsten Schmitz-Peiffer, Aimee Davenport, Mark Aplin, Trevor J. Biden, Ting W. Yiu, Chris J. Mitchell, Siiri E. Iismaa, Liam O’Reilly, and James Cantley

Subjects

Blood Glucose, Mouse, medicine.medical_treatment, lcsh:Medicine, Biochemistry, Mice, Endocrinology, 0302 clinical medicine, Insulin-Secreting Cells, Molecular Cell Biology, Homeostasis, Insulin, Signaling in Cellular Processes, Glucose homeostasis, lcsh:Science, Mice, Knockout, 2. Zero hunger, 0303 health sciences, Glucose tolerance test, Multidisciplinary, medicine.diagnostic_test, Animal Models, medicine.anatomical_structure, Medicine, Research Article, Signal Transduction, medicine.medical_specialty, Genotype, Clinical Research Design, Blood sugar, Carbohydrate metabolism, Biology, Glucose Signaling, Maturity onset diabetes of the young, Islets of Langerhans, 03 medical and health sciences, Model Organisms, GTP-Binding Proteins, Internal medicine, Diabetes mellitus, Diabetes Mellitus, Genetics, medicine, Animals, Protein Glutamine gamma Glutamyltransferase 2, Animal Models of Disease, 030304 developmental biology, Diabetic Endocrinology, Transglutaminases, Pancreatic islets, lcsh:R, Glucose Tolerance Test, Diabetes Mellitus Type 2, medicine.disease, Mice, Inbred C57BL, Glucose, Metabolism, Metabolic Disorders, lcsh:Q, Gene Function, Gene Deletion, 030217 neurology & neurosurgery

Abstract

Transglutaminase type 2 (TG2) has been reported to be a candidate gene for maturity onset diabetes of the young (MODY) because three different mutations that impair TG2 transamidase activity have been found in 3 families with MODY. TG2 null (TG2(-/-)) mice have been reported to be glucose intolerant and have impaired glucose-stimulated insulin secretion (GSIS). Here we rigorously evaluated the role of TG2 in glucose metabolism using independently generated murine models of genetic TG2 disruption, which show no compensatory enhanced expression of other TGs in pancreatic islets or other tissues. First, we subjected chow- or fat-fed congenic SV129 or C57BL/6 wild type (WT) and TG2(-/-) littermates, to oral glucose gavage. Blood glucose and serum insulin levels were similar for both genotypes. Pancreatic islets isolated from these animals and analysed in vitro for GSIS and cholinergic potentiation of GSIS, showed no significant difference between genotypes. Results from intraperitoneal glucose tolerance tests (GTTs) and insulin tolerance tests (ITTs) were similar for both genotypes. Second, we directly investigated the role of TG2 transamidase activity in insulin secretion using a coisogenic model that expresses a mutant form of TG2 (TG2(R579A)), which is constitutively active for transamidase activity. Intraperitoneal GTTs and ITTs revealed no significant differences between WT and TG2(R579A/R579A) mice. Given that neither deletion nor constitutive activation of TG2 transamidase activity altered basal responses, or responses to a glucose or insulin challenge, our data indicate that glucose homeostasis in mice is TG2 independent, and question a link between TG2 and diabetes.

Published

2013