TGF-β Contributes to Impaired Exercise Response by Suppression of Mitochondrial Key Regulators in Skeletal Muscle

Böhm, Anja; Hoffmann, Christoph; Irmler, Martin; Schneeweiss, Patrick; Schnauder, Günter; Sailer, Corinna; Schmid, Vera; Hudemann, Jens; Machann, Jürgen; Schick, Fritz; Beckers, Johannes; Angelis, Martin Hrabé de; Staiger, Harald; Fritsche, Andreas; Stefan, Norbert; Nieß, Andreas M.; Häring, Hans‐Ulrich; Weigert, Cora

doi:10.2337/db15-1723

Cited by 68 publications

(87 citation statements)

References 40 publications

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“…(WG), Sears et al . (SEARS), Heritage (HERTG) and IDEAL (2,22,37,38,46,50–54,,56). The present project involved the production and analysis of 470 new samples profiled on the HTA 2.0 Affymetrix platform along with 144 new samples profiled on the Illumina 12 platform; and 466 of our previously published (22,37,53,54) U133+2 muscle RNA profiles and literature cohorts (where appropriate clinical data was available).…”

Section: Methodsmentioning

confidence: 99%

“…The HTA 2.0 gene-chip contains 6.9 million short ‘probes’ which are computationally combined into groups (probe-sets) representing individual RNA transcripts (or part of a transcript) using a ‘map’ named the chip definition file (CDF). The CDF combines probe signals irrespective of whether each probe represents an active ‘signal’ in the tissue or cell type being profiled or not (27,36,38,39), i.e. there is no probe-level filtering.…”

Section: Methodsmentioning

confidence: 99%

“…(WG) and in vivo drug treatment (SEARS) studies in Figure 1) (38,45,56). Further, a subset of 568 muscle gene-chip profiles were paired, from 284 individuals before and after distinct clinical interventions aimed at improving IS (MP, S1–2, S-PD, DRET, IDEAL, HERTG, SEARS and WG, Figure 1) (38,46–48,50,52,53,56–58). Sixty percent of these samples were not included in the baseline fasting CORE-IS analysis (see below), and thus represent entirely independent samples from those used to discover the CORE-IS genes.…”

Section: Methodsmentioning

confidence: 99%

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A coding and non-coding transcriptomic perspective on the genomics of human metabolic disease

Timmons

Atherton

Larsson

et al. 2018

Nucleic Acids Research

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Genome-wide association studies (GWAS), relying on hundreds of thousands of individuals, have revealed >200 genomic loci linked to metabolic disease (MD). Loss of insulin sensitivity (IS) is a key component of MD and we hypothesized that discovery of a robust IS transcriptome would help reveal the underlying genomic structure of MD. Using 1,012 human skeletal muscle samples, detailed physiology and a tissue-optimized approach for the quantification of coding (>18,000) and non-coding (>15,000) RNA (ncRNA), we identified 332 fasting IS-related genes (CORE-IS). Over 200 had a proven role in the biochemistry of insulin and/or metabolism or were located at GWAS MD loci. Over 50% of the CORE-IS genes responded to clinical treatment; 16 quantitatively tracking changes in IS across four independent studies (P = 0.0000053: negatively: AGL, G0S2, KPNA2, PGM2, RND3 and TSPAN9 and positively: ALDH6A1, DHTKD1, ECHDC3, MCCC1, OARD1, PCYT2, PRRX1, SGCG, SLC43A1 and SMIM8). A network of ncRNA positively related to IS and interacted with RNA coding for viral response proteins (P < 1 × 10−48), while reduced amino acid catabolic gene expression occurred without a change in expression of oxidative-phosphorylation genes. We illustrate that combining in-depth physiological phenotyping with robust RNA profiling methods, identifies molecular networks which are highly consistent with the genetics and biochemistry of human metabolic disease.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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A coding and non-coding transcriptomic perspective on the genomics of human metabolic disease

Timmons

Atherton

Larsson

et al. 2018

Nucleic Acids Research

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“…We focused on hsCRP, IL6, IL1Ra and adiponectin as pro-and anti-inflammatory biomarkers because of their well-established associations with incident type 2 diabetes in prospective studies (1, 2, 31). Based on experimental data and other epidemiological studies, cytokines such as IL1β (32,33,34), tumour necrosis factor (TNF)-α (35,36) and transforming growth factor (TGF)-β (37,38) and chemokines such as monocyte chemoattractant protein-1/chemokine (C-C motif) ligand 2 (MCP-1/CCL2) (39,40) undoubtedly represent interesting candidates because of their impact on insulin sensitivity and/or beta-cell function. However, circulating levels of IL1β are below the limit of detection for a large proportion of individuals in population-based studies with currently available assays, and experimental data on TNFα and insulin resistance do not appear to be translated into an association between circulating levels of this protein and risk of type 2 diabetes in cohort studies (41,42).…”

Section: Strengths and Limitationsmentioning

confidence: 99%

Biomarkers of subclinical inflammation and increases in glycaemia, insulin resistance and beta-cell function in non-diabetic individuals: the Whitehall II study

Herder

Færch

Carstensen‐Kirberg

et al. 2016

European Journal of Endocrinology

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Objective: Higher systemic levels of pro-inflammatory biomarkers and low adiponectin are associated with increased risk of type 2 diabetes, but their associations with changes in glycaemic deterioration before onset of diabetes are poorly understood. We aimed to study whether inflammation-related biomarkers are associated with 5-year changes in glucose and insulin, HbA1c, insulin sensitivity and beta-cell function before the diagnosis of type 2 diabetes and whether these associations may be bidirectional. Design and methods: We used multiple repeat measures (17 891 person-examinations from 7683 non-diabetic participants) from the Whitehall II study to assess whether circulating high-sensitivity C-reactive protein (hsCRP), interleukin-6 (IL6), IL1 receptor antagonist (IL1Ra) and adiponectin are associated with subsequent changes in glycaemia, insulin, insulin resistance and beta-cell function (based on oral glucose tolerance tests). We examined bidirectionality by testing if parameters of glucose metabolism at baseline are associated with changes in inflammation-related biomarkers. Results: Higher hsCRP and IL6 were associated with increases in fasting insulin, insulin resistance and, for IL6, with beta-cell function after adjustment for confounders. Higher adiponectin was associated with decreases in fasting glucose, HbA1c, fasting insulin, insulin resistance and beta-cell function. The reverse approach showed that 2-h glucose and insulin sensitivity were associated with changes in IL1Ra. Fasting insulin and insulin resistance showed inverse associations with changes in adiponectin. Conclusions: Subclinical inflammation is associated with development of increased glycaemia, insulin resistance and beta-cell function in non-diabetic individuals. These findings are consistent with the hypothesis that inflammationrelated processes may increase insulin resistance and lead to a compensatory upregulation of beta-cell function. European Journal of Endocrinology175:5 368 Clinical Study C Herder and others Inflammation and glucose metabolism

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“…sions of prevalent literature in this area, recent studies have uncovered novel insights into endurance exercise-regulated muscle transcriptomic network remodeling during recovery (Neubauer et al 2014), protein supplementation (Rowlands et al 2011(Rowlands et al , 2016, and impairments in endurance-trained subjects lacking metabolic responsiveness (i.e., training improvements in insulin sensitivity) (Bohm et al 2016). The human muscle resistance exercise training -responsive transcriptional networks in the settings of aging (Raue et al 2012), aging-associated muscle frailty , stress-induced immune activation (Gordon et al 2012), and combined aerobic training modes (Lundberg et al 2016) are also continuing to be unraveled using transcriptomics.…”

Section: Omics and Exercise Research Tracksmentioning

confidence: 99%

Omics and Exercise: Global Approaches for Mapping Exercise Biological Networks

Hoffman

2017

Cold Spring Harb Perspect Med

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The application of global "-omics" technologies to exercise has introduced new opportunities to map the complexity and interconnectedness of biological networks underlying the tissue-specific responses and systemic health benefits of exercise. This review will introduce major research tracks and recent advancements in this emerging field, as well as critical gaps in understanding the orchestration of molecular exercise dynamics that will benefit from unbiased omics investigations. Furthermore, significant research hurdles that need to be overcome to effectively fill these gaps related to data collection, computation, interpretation, and integration across omics applications will be discussed. Collectively, a cross-disciplinary physiological and omics-based systems approach will lead to discovery of a wealth of novel exercise-regulated targets for future mechanistic validation. This frontier in exercise biology will aid the development of personalized therapeutic strategies to improve athletic performance and human health through precision exercise medicine.T he dynamic human physiological responses to exercise have been widely studied in the context of metabolism and mechanical stress. Health benefits of exercise in prevention, delay, and/or treatment of pathophysiology associated with metabolic disorders and aging are widely appreciated. However, the intricacies of molecular networks and biological mechanisms underlying how humans adapt to exercise and acquire health benefits are not fully understood. In response to perturbations in whole-body homeostasis induced by physical activity and exercise, biological networks are stimulated in various cell types and organs to manage systemic metabolic and mechanical demands (Hawley et al. 2014). Targeted, reductionist-based approaches have laid the foundation for our understanding of distinct biological mechanisms regulating acute versus repeated exercise adaptations using a range of experimental models from cells to animals and humans. However, the complexity and integrated nature of the whole-body exercise response warrants global unbiased systems approaches to unravel the interwoven networks underlying the benefits of exercise in health and disease.In this early stage of the exercise and omics revolution, there is a wealth of molecular information now within reach to help build on our understanding of human metabolism and exercise physiology. There is tremendous potential for omics approaches to fill critical gaps in our

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TGF-β Contributes to Impaired Exercise Response by Suppression of Mitochondrial Key Regulators in Skeletal Muscle

Cited by 68 publications

References 40 publications

A coding and non-coding transcriptomic perspective on the genomics of human metabolic disease

A coding and non-coding transcriptomic perspective on the genomics of human metabolic disease

Biomarkers of subclinical inflammation and increases in glycaemia, insulin resistance and beta-cell function in non-diabetic individuals: the Whitehall II study

Omics and Exercise: Global Approaches for Mapping Exercise Biological Networks

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