Nardelli Carmela, Granata Ilaria, Iaffaldano Laura, D'Argenio Valeria, Del Monaco Valentina, Maruotti Giuseppe Maria, Omodei Daniela, Del Vecchio Luigi, Martinelli Pasquale, Salvatore Francesco, Guarracino Mario Rosario, Sacchetti Lucia, Pastore Lucio
1 CEINGE-Biotecnologie Avanzate S.C.a R.L. , Naples, Italy .
2 Dipartimento di Medicina Molecolare e Biotecnologie Mediche, Università degli Studi di Napoli Federico II , Naples, Italy .
Stem Cells Dev. 2017 Jan 1;26(1):4-14. doi: 10.1089/scd.2016.0127. Epub 2016 Nov 8.
Clinical findings and data obtained in animal models indicate that nutrient uptake and exposure to environmental agents during pregnancy may affect fetal/newborn gestational programming, thereby resulting in obesity and/or obesity-related disorders in offspring. Human amniotic mesenchymal stem cells (hA-MSCs) differentiate into adipocytes and are thus a suitable model to investigate adipocyte functions in obesity. The aim of this study was to elucidate the miRNome of hA-MSCs and its contribution to obesity in pregnancy. To this aim we used the following: (i) high-resolution small RNA sequencing to characterize the microRNA (miRNA) profiles of hA-MSCs of 13 obese (Ob-) and 7 control (Co-) pregnant women at delivery; (ii) multiple-method integrated bioinformatics to predict the metabolic pathways potentially miRNA deregulated in Ob-hA-MSCs; and (iii) microarray mRNA expression profiling to verify obese-associated mRNA alterations. In summary, 12 miRNAs were differentially expressed between Ob-hA-MSCs and Co-hA-MSCs, with a multiple-methods bioinformatic consensus on miR-138-5p and miR-222-3p, which were overexpressed in Ob-hA-MSCs versus Co-hA-MSCs. The top 20 significant pathways predicted to be deregulated through miR-138-5p and/or miR-222-3p/target interaction included fat cell differentiation and deposits, lipid/carbohydrate homeostasis, response to stress, metabolic syndrome, heart disease, and ischemia. In conclusion, our finding of miR-138-5p/miR-222-3p overexpression in Ob-hA-MSCs, together with the transcriptomic data, suggests that these miRNAs in obese pregnancy could derange metabolic pathways previously found impaired in tissues from obese adults or in obesity-associated disorders and concur to modify gestational programming as has been demonstrated in animal models. This raises the possibility of using diet-based strategies to normalize the perinatal miRNome in obesity.
临床研究结果以及在动物模型中获得的数据表明,孕期的营养摄取和环境因素暴露可能会影响胎儿/新生儿的孕期编程,进而导致后代肥胖和/或肥胖相关疾病。人羊膜间充质干细胞(hA-MSCs)可分化为脂肪细胞,因此是研究肥胖中脂肪细胞功能的合适模型。本研究的目的是阐明hA-MSCs的微小RNA组及其对孕期肥胖的作用。为此,我们采用了以下方法:(i)高分辨率小RNA测序,以表征13名肥胖(Ob-)孕妇和7名对照(Co-)孕妇分娩时hA-MSCs的微小RNA(miRNA)谱;(ii)多方法整合生物信息学,以预测在Ob-hA-MSCs中可能发生miRNA失调的代谢途径;(iii)微阵列mRNA表达谱分析,以验证肥胖相关的mRNA改变。总之,Ob-hA-MSCs和Co-hA-MSCs之间有12种miRNA差异表达,对于miR-138-5p和miR-222-3p存在多方法生物信息学共识,与Co-hA-MSCs相比,它们在Ob-hA-MSCs中过表达。预测通过miR-138-5p和/或miR-222-3p/靶标相互作用而失调的前20条重要途径包括脂肪细胞分化和沉积、脂质/碳水化合物稳态、应激反应、代谢综合征、心脏病和缺血。总之,我们在Ob-hA-MSCs中发现miR-138-5p/miR-222-3p过表达,连同转录组数据表明,肥胖孕期中的这些miRNA可能会扰乱先前在肥胖成年人组织或肥胖相关疾病中发现受损的代谢途径,并如动物模型中所证明的那样,有助于改变孕期编程。这增加了使用基于饮食的策略来使肥胖中的围产期微小RNA组正常化的可能性。