Your search keyword '"Gross DN"' showing total 7 results

1. Insulin regulates adipocyte lipolysis via an Akt-independent signaling pathway.

Author

Choi SM, Tucker DF, Gross DN, Easton RM, DiPilato LM, Dean AS, Monks BR, and Birnbaum MJ

Subjects

3T3-L1 Cells, Animals, Base Sequence, Cells, Cultured, Cyclic AMP-Dependent Protein Kinases metabolism, Gene Knockdown Techniques, Insulin Resistance, Lipolysis physiology, Mice, Phosphatidylinositol 3-Kinases metabolism, Proto-Oncogene Proteins c-akt antagonists & inhibitors, Proto-Oncogene Proteins c-akt genetics, Proto-Oncogene Proteins c-akt metabolism, RNA, Small Interfering genetics, Signal Transduction, Adipocytes drug effects, Adipocytes metabolism, Insulin metabolism, Insulin pharmacology, Lipolysis drug effects

Abstract

After a meal, insulin suppresses lipolysis through the activation of its downstream kinase, Akt, resulting in the inhibition of protein kinase A (PKA), the main positive effector of lipolysis. During insulin resistance, this process is ineffective, leading to a characteristic dyslipidemia and the worsening of impaired insulin action and obesity. Here, we describe a noncanonical Akt-independent, phosphoinositide-3 kinase (PI3K)-dependent pathway that regulates adipocyte lipolysis using restricted subcellular signaling. This pathway selectively alters the PKA phosphorylation of its major lipid droplet-associated substrate, perilipin. In contrast, the phosphorylation of another PKA substrate, hormone-sensitive lipase (HSL), remains Akt dependent. Furthermore, insulin regulates total PKA activity in an Akt-dependent manner. These findings indicate that localized changes in insulin action are responsible for the differential phosphorylation of PKA substrates. Thus, we identify a pathway by which insulin regulates lipolysis through the spatially compartmentalized modulation of PKA.

Published

2010

2. The role of FOXO in the regulation of metabolism.

Author

Gross DN, Wan M, and Birnbaum MJ

Subjects

Adipose Tissue metabolism, Animals, Forkhead Transcription Factors metabolism, Humans, Hypothalamus metabolism, Insulin metabolism, Insulin-Secreting Cells metabolism, Liver metabolism, Muscle, Skeletal metabolism, Phosphorylation, Proto-Oncogene Proteins c-akt metabolism, Forkhead Transcription Factors physiology

Abstract

Forkhead box O (FOXO) transcription factors play an important role in modulating metabolic functions. FOXO is regulated by several modifications, but one of the most critical is phosphorylation and nuclear exclusion by Akt. Given the impact of insulin signaling on Akt-mediated phosphorylation of FOXO and the relatively high expression of Foxo1 in insulin-responsive tissues, this transcription factor is highly poised to regulate energy metabolism. When nutrient and insulin levels are low, Foxo1 promotes expression of gluconeogenic enzymes. Conversely, in the fed state, insulin levels rise and stimulate uptake of glucose primarily into skeletal muscle and other organs, including adipose tissue. Under certain pathophysiologic conditions, including insulin resistance, negative signaling to Foxo1 is compromised. Further clarification of the role of Foxo1 in insulin-responsive tissues will strengthen our understanding and allow us to better combat insulin resistance and diabetes mellitus.

Published

2009

3. The role of FoxO in the regulation of metabolism.

Author

Gross DN, van den Heuvel AP, and Birnbaum MJ

Subjects

Animals, Humans, Energy Metabolism physiology, Forkhead Transcription Factors physiology

Abstract

Forkhead proteins, and FoxO1 in particular, play a significant role in regulating whole body energy metabolism. Glucose homeostasis is achieved by adjusting endogenous glucose production as well as glucose uptake by peripheral tissues in response to insulin. In the fasted state, the liver is primarily responsible for maintaining glucose levels, with FoxO1 playing a key role in promoting the expression of gluconeogenic enzymes. Following feeding, pancreatic beta cells secrete insulin, which promotes the uptake of glucose by peripheral tissues including skeletal muscle and adipose tissue, and can in part suppress gluconeogenic enzyme expression in the liver. In addition to directly regulating metabolism, FoxO1 also plays a role in the formation of both adipose tissue and skeletal muscle, two major organs that are critical for maintaining energy homeostasis. The importance of FoxO1 in energy homeostasis is particularly striking under conditions of metabolic dysfunction or insulin resistance. In obese or diabetic states, FoxO1-dependent gene expression promotes some of the deleterious characteristics associated with these conditions, including hyperglycemia and glucose intolerance. In addition, the increase in pancreatic beta cell mass that normally occurs in response to a rise in insulin demand is blunted by nuclear FoxO1 expression. However, under these same pathophysiological conditions, FoxO1 expression may help drive the expression of genes involved in combating oxidative stress, thereby preserving cellular function. FoxO1 may also be involved in promoting the switch from carbohydrate to fatty acid as the major energy source during starvation.

Published

2008

4. When the usual insulin is just not enough.

Author

Gleason CE, Gross DN, and Birnbaum MJ

Subjects

Animals, Insulin Resistance, Insulin-Secreting Cells metabolism, Insulin-Secreting Cells pathology, Receptor, Insulin deficiency, Receptor, Insulin genetics, Receptor, Insulin metabolism, Signal Transduction, Insulin metabolism

Published

2007

5. Dynamics of lipid droplet-associated proteins during hormonally stimulated lipolysis in engineered adipocytes: stabilization and lipid droplet binding of adipocyte differentiation-related protein/adipophilin.

Author

Gross DN, Miyoshi H, Hosaka T, Zhang HH, Pino EC, Souza S, Obin M, Greenberg AS, and Pilch PF

Subjects

Adipocytes drug effects, Animals, CCAAT-Enhancer-Binding Protein-alpha genetics, CCAAT-Enhancer-Binding Protein-alpha metabolism, Carrier Proteins, Cysteine Proteinase Inhibitors pharmacology, Hormones pharmacology, Isoproterenol pharmacology, Leupeptins pharmacology, Lipid Metabolism, Mice, NIH 3T3 Cells, Perilipin-1, Perilipin-2, Phosphoproteins genetics, Phosphorylation, Proteasome Inhibitors, Adipocytes metabolism, Lipolysis, Membrane Proteins metabolism, Peptides metabolism, Phosphoproteins metabolism

Abstract

In mature adipocytes, triglyceride is stored within lipid droplets, which are coated with the protein perilipin, which functions to regulate lipolysis by controlling lipase access to the droplet in a hormone-regulatable fashion. Adipocyte differentiation-related protein (ADRP) is a widely expressed lipid droplet binding protein that is coexpressed with perilipin in differentiating fat cells but is minimally present in fully differentiated cultured adipocytes. We find that fibroblasts ectopically expressing C/EBPalpha (NIH-C/EBPalpha cells) differentiate into mature adipocytes that simultaneously express perilipin and ADRP. In response to isoproterenol, perilipin is hyperphosphorylated, lipolysis is enhanced, and subsequently, ADRP expression increases coincident with it surrounding intracellular lipid droplets. In the absence of lipolytic stimulation, inhibition of proteasomal activity with MG-132 increased ADRP levels to those of cells treated with 10 mum isoproterenol, but ADRP does not surround the lipid droplet in the absence of lipolytic stimulation. We overexpressed a perilipin A construct in NIH-C/EBPalpha cells where the six serine residues known to be phosphorylated by protein kinase A were changed to alanine (Peri A Delta1-6). These cells show no increase in ADRP expression in response to isoproterenol. We propose that ADRP can replace perilipin on existing lipid droplets or those newly formed as a result of fatty acid reesterification, under dynamic conditions of hormonally stimulated lipolysis, thus preserving lipid droplet morphology/structure.

Published

2006

6. p115 Interacts with the GLUT4 vesicle protein, IRAP, and plays a critical role in insulin-stimulated GLUT4 translocation.

Author

Hosaka T, Brooks CC, Presman E, Kim SK, Zhang Z, Breen M, Gross DN, Sztul E, and Pilch PF

Subjects

3T3-L1 Cells, Adipocytes metabolism, Amino Acid Sequence, Aminopeptidases chemistry, Aminopeptidases isolation & purification, Animals, Blotting, Western, COS Cells, Cell Culture Techniques, Cell Differentiation, Chlorocebus aethiops, Escherichia coli genetics, Fluorescent Antibody Technique, Indirect, Green Fluorescent Proteins metabolism, Mice, Protein Structure, Tertiary, Subcellular Fractions metabolism, Aminopeptidases metabolism, Biological Transport, Insulin pharmacology, Vesicular Transport Proteins metabolism

Abstract

Insulin-regulated aminopeptidase (IRAP) is an abundant cargo protein of Glut4 storage vesicles (GSVs) that traffics to and from the plasma membrane in response to insulin. We used the amino terminus cytoplasmic domain of IRAP, residues 1-109, as an affinity reagent to identify cytosolic proteins that might be involved in GSV trafficking. In this way, we identified p115, a peripheral membrane protein known to be involved in membrane trafficking. In murine adipocytes, we determined that p115 was localized to the perinuclear region by immunofluorescence and throughout the cell by fractionation. By immunofluorescence, p115 partially colocalizes with GLUT4 and IRAP in the perinuclear region of cultured fat cells. The amino terminus of p115 binds to IRAP and overexpression of a N-terminal construct results in its colocalization with GLUT4 throughout the cell. Insulin-stimulated GLUT4 translocation is completely inhibited under these conditions. Overexpression of p115 C-terminus has no significant effect on GLUT4 distribution and translocation. Finally, expression of the p115 N-terminus construct has no effect on the distribution and trafficking of GLUT1. These data suggest that p115 has an important and specific role in insulin-stimulated Glut4 translocation, probably by way of tethering insulin-sensitive Glut4 vesicles at an as yet unknown intracellular site.

Published

2005

7. Glut4 storage vesicles without Glut4: transcriptional regulation of insulin-dependent vesicular traffic.

Author

Gross DN, Farmer SR, and Pilch PF

Subjects

Adipocytes cytology, Adipocytes physiology, Aminopeptidases metabolism, Animals, CCAAT-Enhancer-Binding Protein-alpha genetics, Cell Differentiation physiology, Cell Membrane metabolism, Cystinyl Aminopeptidase, Deoxyglucose metabolism, Fibroblasts cytology, Fibroblasts physiology, Glucose Transporter Type 4, Mice, Monosaccharide Transport Proteins genetics, NIH 3T3 Cells, Protein Transport physiology, Receptor, Insulin metabolism, Receptors, Cytoplasmic and Nuclear genetics, Signal Transduction physiology, Transcription Factors genetics, CCAAT-Enhancer-Binding Protein-alpha metabolism, Cytoplasmic Vesicles metabolism, Insulin metabolism, Monosaccharide Transport Proteins metabolism, Muscle Proteins, Receptors, Cytoplasmic and Nuclear metabolism, Transcription Factors metabolism, Transcription, Genetic

Abstract

Two families of transcription factors that play a major role in the development of adipocytes are the CCAAT/enhancer-binding proteins (C/EBPs) and the peroxisome proliferator-activated receptors (PPARs), in particular PPAR gamma. Ectopic expression of either C/EBP alpha or PPAR gamma in NIH 3T3 fibroblasts results in the conversion of these cells to adipocyte-like cells replete with fat droplets. NIH 3T3 cells ectopically expressing C/EBP alpha (NIH-C/EBP alpha) differentiate into adipocytes and exhibit insulin-stimulated glucose uptake, whereas NIH 3T3 cells ectopically expressing PPAR gamma (NIH-PPAR gamma) differentiate but do not exhibit any insulin-stimulated glucose uptake, nor do they express any C/EBP alpha. The reason for the lack of insulin-responsive glucose uptake in the NIH-PPAR gamma cells is their virtual lack of the insulin-responsive glucose transporter, Glut4. The NIH-PPAR gamma cells express functionally active components of the insulin receptor-signaling pathway (the insulin receptor, IRS-1, phosphatidylinositol 3-kinase, and Akt2) at levels comparable to those in responsive cell lines. They also express components of the insulin-sensitive vesicular transport machinery, namely, VAMP2, syntaxin-4, and IRAP, the last of these being the other marker of insulin-regulated vesicular traffic along with Glut4. Interestingly, the NIH-PPAR gamma cells show normal insulin-dependent translocation of IRAP and form an insulin-responsive vesicular compartment as assessed by cell surface biotinylation and sucrose velocity gradient analysis, respectively. Moreover, expression of a Glut4-myc construct in the NIH-PPAR gamma cells results in its insulin-dependent translocation to the plasma membrane as assessed by immunofluorescence and Western blot analysis. Based on these data, we conclude that major role of C/EBP alpha in the context of the NIH-PPAR gamma cells is to regulate Glut4 expression. The differentiated cells possess a large insulin-sensitive vesicular compartment with negligible Glut4, and Glut4 translocation can be reconstituted on expression of this transporter.

Published

2004