Maternal under-nutrition during pregnancy alters the molecular response to over-nutrition in multiple organs and tissues in nonhuman primate juvenile offspring.

IF 1.8 4区医学 Q3 PUBLIC, ENVIRONMENTAL & OCCUPATIONAL HEALTH Journal of Developmental Origins of Health and Disease Pub Date : 2024-11-07 DOI:10.1017/S2040174424000163

Laura A Cox, Sobha Puppala, Jeannie Chan, Angelica M Riojas, Kenneth J Lange, Shifra Birnbaum, Edward J Dick, Anthony G Comuzzie, Mark J Nijland, Cun Li, Peter W Nathanielsz, Michael Olivier

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Abstract

Previous studies in rodents suggest that mismatch between fetal and postnatal nutrition predisposes individuals to metabolic diseases. We hypothesized that in nonhuman primates (NHP), fetal programming of maternal undernutrition (MUN) persists postnatally with a dietary mismatch altering metabolic molecular systems that precede standard clinical measures. We used unbiased molecular approaches to examine response to a high fat, high-carbohydrate diet plus sugar drink (HFCS) challenge in NHP juvenile offspring of MUN pregnancies compared with controls (CON). Pregnant baboons were fed ad libitum (CON) or 30% calorie reduction from 0.16 gestation through lactation; weaned offspring were fed chow ad libitum. MUN offspring were growth restricted at birth. Liver, omental fat, and skeletal muscle gene expression, and liver glycogen, muscle mitochondria, and fat cell size were quantified. Before challenge, MUN offspring had lower body mass index (BMI) and liver glycogen, and consumed more sugar drink than CON. After HFCS challenge, MUN and CON BMIs were similar. Molecular analyses showed HFCS response differences between CON and MUN for muscle and liver, including hepatic splicing and unfolded protein response. Altered liver signaling pathways and glycogen content between MUN and CON at baseline indicate in utero programming persists in MUN juveniles. MUN catchup growth during consumption of HFCS suggests increased risk of obesity, diabetes, and cardiovascular disease. Greater sugar drink consumption in MUN demonstrates altered appetitive drive due to programming. Differences in blood leptin, liver glycogen, and tissue-specific molecular response to HFCS suggest MUN significantly impacts juvenile offspring ability to manage an energy rich diet.

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孕期母体营养不足会改变非人灵长类幼年后代多个器官和组织对营养过剩的分子反应。

以前对啮齿类动物的研究表明，胎儿期和出生后的营养不匹配会导致个体易患代谢性疾病。我们假设，在非人灵长类动物（NHP）中，母体营养不良（MUN）的胎儿编程会在出生后持续存在，膳食不匹配会改变代谢分子系统，这种改变先于标准临床措施。与对照组（CON）相比，我们采用无偏见的分子方法研究了MUN妊娠的NHP幼年后代对高脂肪、高碳水化合物饮食加糖饮料（HFCS）挑战的反应。妊娠狒狒从妊娠 0.16 期到哺乳期均自由进食（对照组）或减少 30% 热量进食；断奶后代自由进食饲料。MUN后代出生时生长受限。对肝脏、网膜脂肪和骨骼肌基因表达，以及肝糖原、肌肉线粒体和脂肪细胞大小进行了量化。挑战前，MUN 后代的体重指数（BMI）和肝糖原较低，并且比 CON 后代摄入更多的糖饮料。挑战 HFCS 后，MUN 和 CON 的体重指数相似。分子分析表明，CON 和 MUN 的肌肉和肝脏对 HFCS 的反应存在差异，包括肝脏剪接和未折叠蛋白反应。MUN和CON在基线时肝脏信号通路和糖原含量的改变表明，MUN幼体在子宫内的编程持续存在。在食用 HFCS 期间，MUN 的追赶生长表明肥胖、糖尿病和心血管疾病的风险增加。芒廷青少年摄入更多的糖类饮料，这表明他们的食欲驱动力会因编程而改变。血液瘦素、肝糖原和组织对 HFCS 的特异性分子反应的差异表明，MUN 会显著影响幼年后代管理高能量饮食的能力。

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来源期刊

Journal of Developmental Origins of Health and Disease PUBLIC, ENVIRONMENTAL & OCCUPATIONAL HEALTH-

CiteScore

3.80

自引率

0.00%

发文量

145

审稿时长

6-12 weeks

期刊介绍： JDOHaD publishes leading research in the field of Developmental Origins of Health and Disease (DOHaD). The Journal focuses on the environment during early pre-natal and post-natal animal and human development, interactions between environmental and genetic factors, including environmental toxicants, and their influence on health and disease risk throughout the lifespan. JDOHaD publishes work on developmental programming, fetal and neonatal biology and physiology, early life nutrition, especially during the first 1,000 days of life, human ecology and evolution and Gene-Environment Interactions. JDOHaD also accepts manuscripts that address the social determinants or education of health and disease risk as they relate to the early life period, as well as the economic and health care costs of a poor start to life. Accordingly, JDOHaD is multi-disciplinary, with contributions from basic scientists working in the fields of physiology, biochemistry and nutrition, endocrinology and metabolism, developmental biology, molecular biology/ epigenetics, human biology/ anthropology, and evolutionary developmental biology. Moreover clinicians, nutritionists, epidemiologists, social scientists, economists, public health specialists and policy makers are very welcome to submit manuscripts. The journal includes original research articles, short communications and reviews, and has regular themed issues, with guest editors; it is also a platform for conference/workshop reports, and for opinion, comment and interaction.