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- All Subjects: Molecular Biology
Description
This dissertation investigates the condition of skeletal muscle insulin resistance using bioinformatics and computational biology approaches. Drawing from several studies and numerous data sources, I have attempted to uncover molecular mechanisms at multiple levels. From the detailed atomistic simulations of a single protein, to datamining approaches applied at the systems biology level, I provide new targets to explore for the research community. Furthermore I present a new online web resource that unifies various bioinformatics databases to enable discovery of relevant features in 3D protein structures.
ContributorsMielke, Clinton (Author) / Mandarino, Lawrence (Committee member) / LaBaer, Joshua (Committee member) / Magee, D. Mitchell (Committee member) / Dinu, Valentin (Committee member) / Willis, Wayne (Committee member) / Arizona State University (Publisher)
Created2013
Description
Objective: Isoforms of insulin-like growth factor-1 (IGF-1) gene encodes different IGF-1 isoforms by alternative splicing, and which are known to play distinct roles in muscle growth and repair. These isoforms in humans exist as IGF-1Ea, IGF-1Eb and IGF-1Ec (the latter is also known as mechano-growth factor). We sought to determine whether mRNA expression of any of these isoforms is impaired in skeletal muscle of humans with obesity, and given that humans with obesity display reduced protein synthesis in muscle. Methods: We studied 10 subjects (3 females/7 males) with obesity (body mass index: 34 ± 1 kg/m2) and 14 subjects (6 females/8 males) that were lean (body mass index: 24 ± 1 kg/m2) and served as controls. The groups represented typical populations of individuals that differed (P < 0.05) in body fat (obese: 32 ± 2; lean: 22 ± 2) and insulin sensitivity (Matsuda insulin sensitivity index, obese: 5 ± 1; lean 11 ± 2). Total RNA was extracted from 20-30 mg of tissue from muscle biopsies performed after an overnight fast. Isolated RNA was used to perform cDNA synthesis. Real-time PCR was performed using predesigned TaqMan® gene expression assays (Thermo Fisher Scientific Inc) for IGF-1Ea (assay ID: Hs01547657_m1), IGF-1Eb (assay ID: Hs00153126_m1) and IGF-1Ec (assay ID: Hs03986524_m1), as well as ACTB (assay ID: Hs01060665_g1), which was used to adjust the IGF-1 isoform mRNA expression. Responses for mRNA expression were calculated using the comparative CT method (2-ΔΔCT). Results: IGF-1Eb mRNA expression was lower in the subjects with obesity compared to the lean controls (0.67 ± 0.09 vs 1.00 ± 0.13; P < 0.05) but that of IGF-1Ea (0.99 ± 0.16 vs 1.00 ± 0.33) or IGF-1Ec (0.83 ± 0.14 vs 1.00 ± 0.21) were not different between groups (P > 0.05). Conclusions: Among the IGF-1 mRNA isoforms, IGF-1Eb mRNA is uniquely decreased in humans with obesity. Lower IGF-1Eb mRNA expression in muscle of humans with obesity may explain the lower protein synthesis observed in these individuals. Furthermore, these findings may have direct implications for muscle growth and repair in humans with obesity.
ContributorsSon, John Lee (Author) / Katsanos, Christos (Thesis director) / Gu, Haiwei (Committee member) / College of Health Solutions (Contributor) / Barrett, The Honors College (Contributor)
Created2019-05
Description
Free coenzyme A (CoASH) carries acyl groups for the tricarboxylic acid (TCA) cycle and fatty acid metabolism, and donates acyl groups for protein posttranslational modifications. Cellular de novo CoASH synthesis starts with a pantothenate kinase (PANK1-3) phosphorylating pantothenate (vitamin B5). Mutations in PANK2 cause a subtype of neurodegeneration with brain iron accumulation (NBIA). The PANKs have differential subcellular distribution and regulatory properties. However, the purpose of each PANK has remained obscure, with knockout mouse models presenting with mild phenotypes unless challenged with a high-fat diet. Based on PANK2’s known activation by palmitoylcarnitine, the PANK2-deficient cells were challenged with palmitic acid (PAL) added to glucose-containing media. The high nutrient mixture generated a surprising “starvation” profile of reduced proliferation, low ATP, AMPK activation, and autophagy upregulation in PANK2-deficient PAL-challenged cells. Further experiments showed that fatty acids accumulated and that PANK2-deficient cells had reduced respiration when provided with palmitoylcarnitine as a substrate, seemingly due to an impaired ability to oxidize fatty acids during PAL-induced Randle Cycle activation. Intriguingly, whole-cell CoASH levels remained stable despite the PAL-induced starvation phenotype, and increasing CoASH via PANK1β overexpression did not rescue the phenotype, demonstrating a unique role for PANK2 in fatty acid metabolism. Even though a direct CoASH deficiency was not detected, there were changes in short chain CoA-derivatives, including acetyl-CoA, succinyl-CoA, and butyryl-CoA, as well as evidence of impaired TCA cycle function. These impairments in both the TCA cycle and fatty acid oxidation implicate a role for PANK2 in regulating mitochondria CoA dynamics.
ContributorsNordlie, Sandra Maria (Author) / Kruer, Michael C (Thesis advisor) / Neisewander, Janet (Thesis advisor) / Padilla Lopez, Sergio (Committee member) / Katsanos, Christos (Committee member) / Arizona State University (Publisher)
Created2022
Description
Skeletal muscle (SM) mitochondria generate the majority of adenosine triphosphate (ATP) in SM, and help regulate whole-body energy expenditure. Obesity is associated with alterations in SM mitochondria, which are unique with respect to their arrangement within cells; some mitochondria are located directly beneath the sarcolemma (i.e., subsarcolemmal (SS) mitochondria), while other are nested between the myofibrils (i.e., intermyofibrillar (IMF) mitochondria). Functional and proteome differences specific to SS versus IMF mitochondria in obese individuals may contribute to reduced capacity for muscle ATP production seen in obesity. The overall goals of this work were to (1) isolate functional muscle SS and IMF mitochondria from lean and obese individuals, (2) assess enzyme activities associated with the electron transport chain and ATP production, (3) determine if elevated plasma amino acids enhance SS and IMF mitochondrial respiration and ATP production rates in SM of obese humans, and (4) determine differences in mitochondrial proteome regulating energy metabolism and key biological processes associated with SS and IMF mitochondria between lean and obese humans.
Polarography was used to determine functional differences in isolated SS and IMF mitochondria between lean (37 ± 3 yrs; n = 10) and obese (35 ± 3 yrs; n = 11) subjects during either saline (control) or amino acid (AA) infusions. AA infusion increased ADP-stimulated respiration (i.e., coupled respiration), non-ADP stimulated respiration (i.e., uncoupled respiration), and ATP production rates in SS, but not IMF mitochondria in lean (n = 10; P < 0.05). Neither infusion increased any of the above parameters in muscle SS or IMF mitochondria of the obese subjects.
Using label free quantitative mass spectrometry, we determined differences in proteomes of SM SS and IMF mitochondria between lean (33 ± 3 yrs; n = 16) and obese (32 ± 3 yrs; n = 17) subjects. Differentially-expressed mitochondrial proteins in SS versus IMF mitochondria of obese subjects were associated with biological processes that regulate: electron transport chain (P<0.0001), citric acid cycle (P<0.0001), oxidative phosphorylation (P<0.001), branched-chain amino acid degradation, (P<0.0001), and fatty acid degradation (P<0.001). Overall, these findings show that obesity is associated with redistribution of key biological processes within the mitochondrial reticulum responsible for regulating energy metabolism in human skeletal muscle.
Polarography was used to determine functional differences in isolated SS and IMF mitochondria between lean (37 ± 3 yrs; n = 10) and obese (35 ± 3 yrs; n = 11) subjects during either saline (control) or amino acid (AA) infusions. AA infusion increased ADP-stimulated respiration (i.e., coupled respiration), non-ADP stimulated respiration (i.e., uncoupled respiration), and ATP production rates in SS, but not IMF mitochondria in lean (n = 10; P < 0.05). Neither infusion increased any of the above parameters in muscle SS or IMF mitochondria of the obese subjects.
Using label free quantitative mass spectrometry, we determined differences in proteomes of SM SS and IMF mitochondria between lean (33 ± 3 yrs; n = 16) and obese (32 ± 3 yrs; n = 17) subjects. Differentially-expressed mitochondrial proteins in SS versus IMF mitochondria of obese subjects were associated with biological processes that regulate: electron transport chain (P<0.0001), citric acid cycle (P<0.0001), oxidative phosphorylation (P<0.001), branched-chain amino acid degradation, (P<0.0001), and fatty acid degradation (P<0.001). Overall, these findings show that obesity is associated with redistribution of key biological processes within the mitochondrial reticulum responsible for regulating energy metabolism in human skeletal muscle.
ContributorsKras, Katon Anthony (Author) / Katsanos, Christos (Thesis advisor) / Chandler, Douglas (Committee member) / Dinu, Valentin (Committee member) / Mor, Tsafrir S. (Committee member) / Arizona State University (Publisher)
Created2017
Description
Obesity impairs skeletal muscle maintenance and regeneration, a condition that can progressively lead to muscle loss, but the mechanisms behind it are unknown. Muscle is primarily composed of multinucleated cells called myotubes which are derived by the fusion of mononucleated myocytes. A key mediator in this process is the cellular fusion protein syncytin-1. This led to the hypothesis that syncytin-1 could be decreased in the muscle of obese/insulin resistant individuals. In contrast, it was found that obese/insulin resistant subjects had higher syncytin-1 expression in the muscle compared to that of the lean subjects. Across the subjects, syncytin-1 correlated significantly with body mass index, percent body fat, blood glucose and HbA1c levels, insulin sensitivity and muscle protein fractional synthesis rate. The concentrations of specific plasma fatty acids, such as the saturated fatty acid (palmitate) and monounsaturated fatty acid (oleate) are known to be altered in obese/insulin resistant humans, and also to influence the protein synthesis in muscle. Therefore, it was evaluated that the effects of palmitate and oleate on syncytin-1 expression, as well as 4E-BP1 phosphorylation, a key mechanism regulating muscle protein synthesis in insulin stimulated C2C12 myotubes. The results showed that treatment with 20 nM insulin, 300 µM oleate, 300 µM oleate +20 nM insulin and 300 µM palmitate + 300 µM oleate elevated 4E-BP1 phosphorylation. At the same time, 20 nM insulin, 300 µM palmitate, 300 µM oleate + 20 nM insulin and 300 µM palmitate + 300 µM oleate elevated syncytin-1 expression. Insulin stimulated muscle syncytin-1 expression and 4E-BP1 phosphorylation, and this effect was comparable to that observed in the presence of oleate alone. However, the presence of palmitate + oleate diminished the stimulatory effect of insulin on muscle syncytin-1 expression and 4E-BP1 phosphorylation. These findings indicate oleate but not palmitate increased total 4E-BP1 phosphorylation regardless of insulin and the presence of palmitate in insulin mediated C2C12 cells. The presence of palmitate inhibited the upregulation of total 4EB-P1 phosphorylation. Palmitate but not oleate increased syncytin-1 expression in insulin mediated C2C12 myotubes. It is possible that chronic hyperinsulinemia in obesity and/or elevated levels of fatty acids such as palmitate in plasma could have contributed to syncytin-1 overexpression and decreased muscle protein fractional synthesis rate in obese/insulin resistant human muscle.
ContributorsRavichandran, Jayachandran (Author) / Katsanos, Christos (Thesis advisor) / Coletta, Dawn (Committee member) / Dickinson, Jared (Committee member) / Arizona State University (Publisher)
Created2017