TY - JOUR

T1 - Transcriptomics research in the clinical and experimental investigation of pathogenetic mechanisms of alimentary obesity

AU - Gmoshinski, I. V.

AU - Apryatin, S. A.

AU - Sharafetdinov, Kh Kh

AU - Nikitjuk, D. B.

AU - Tutelyan, V. A.

PY - 2018/1/1

Y1 - 2018/1/1

N2 - The review considers the significant role of changes in the transcriptome of organs and tissues for studying the molecular mechanisms of obesity development. Modern methods of transcriptomics including technologies for quantitative RT-PCR and DNA microarrays provided a new approach to the search for sensitive molecular markers as obesity predictors Differential gene expression profiles are mostly organo- and tissue-specific for adipose tissue, liver, brain, and other organs and tissues; can significantly differ in animal in vivo models with genetically determined and dietary induced obesity. At the same time, coordinated regulation is registered in the organs and tissues of expression of extensive groups of genes associated with lipid, cholesterol, and carbohydrate metabolism, the synthesis and circulation of neurotransmitters of dopamine and serotonin, peptide hormones, cytokines which induce systemic inflammation. For systemic regulation mechanisms causing a concerted change in the transcription of tens and hundreds of genes in obesity, the adipokines effects should be pointed out, primarily leptin, as well as pro-inflammatory cytokines, the micro-RNA (miRs) system and central effects developing at NPY/AgRP+ and POMC/CART+ neurons of the arcuate nucleus of the hypothalamus. Results of transcriptomic studies can be used in preclinical trials of new drugs and methods of dietary correction of obesity in animal's in vivo models, as well as in the search for clinical predictors and markers of metabolic abnormalities in patients with obesity receiving personalized therapy. The main problem of transcriptomic studies in in vivo models is incomplete consistency between the data obtained with full-transcriptional profiling and the results of quantitative RT-PCR expression of individual candidate genes, as well as metabolic and proteomic studies. The identification and elimination of the causes of such discrepancies can be one of the promising areas for improving transcriptomical research.

AB - The review considers the significant role of changes in the transcriptome of organs and tissues for studying the molecular mechanisms of obesity development. Modern methods of transcriptomics including technologies for quantitative RT-PCR and DNA microarrays provided a new approach to the search for sensitive molecular markers as obesity predictors Differential gene expression profiles are mostly organo- and tissue-specific for adipose tissue, liver, brain, and other organs and tissues; can significantly differ in animal in vivo models with genetically determined and dietary induced obesity. At the same time, coordinated regulation is registered in the organs and tissues of expression of extensive groups of genes associated with lipid, cholesterol, and carbohydrate metabolism, the synthesis and circulation of neurotransmitters of dopamine and serotonin, peptide hormones, cytokines which induce systemic inflammation. For systemic regulation mechanisms causing a concerted change in the transcription of tens and hundreds of genes in obesity, the adipokines effects should be pointed out, primarily leptin, as well as pro-inflammatory cytokines, the micro-RNA (miRs) system and central effects developing at NPY/AgRP+ and POMC/CART+ neurons of the arcuate nucleus of the hypothalamus. Results of transcriptomic studies can be used in preclinical trials of new drugs and methods of dietary correction of obesity in animal's in vivo models, as well as in the search for clinical predictors and markers of metabolic abnormalities in patients with obesity receiving personalized therapy. The main problem of transcriptomic studies in in vivo models is incomplete consistency between the data obtained with full-transcriptional profiling and the results of quantitative RT-PCR expression of individual candidate genes, as well as metabolic and proteomic studies. The identification and elimination of the causes of such discrepancies can be one of the promising areas for improving transcriptomical research.

KW - Fat tissue

KW - In vivo models

KW - Obesity

KW - RNA-microarrays

KW - Transcriptomics

UR - http://www.scopus.com/inward/record.url?scp=85050357458&partnerID=8YFLogxK

U2 - 10.15690/vramn973

DO - 10.15690/vramn973

M3 - Article

AN - SCOPUS:85050357458

VL - 73

SP - 172

EP - 180

JO - ВЕСТНИК РОССИЙСКОЙ АКАДЕМИИ МЕДИЦИНСКИХ НАУК

JF - ВЕСТНИК РОССИЙСКОЙ АКАДЕМИИ МЕДИЦИНСКИХ НАУК

SN - 0869-6047

IS - 3

ER -