Maternal metabolic health drives mesenchymal stem cell metabolism and infant fat mass at birth.

Melissa L Erickson,Allison M Duensing,Kristen E Boyle,Zachary W Patinkin,Leanne M Redman,Dana Dabelea

doi:10.1172/jci.insight.146606

Abstract

Exposure to maternal obesity may promote metabolic dysfunction in offspring. We used infant mesenchymal stem cells (MSCs) to experimentally examine cellular mechanisms of intergenerational health transmission. Our earlier reports show MSCs collected from infants of mothers with obesity had a dichotomous distribution in metabolic efficiency; they were either efficient (Ef-Ob) or inefficient (In-Ob) with respect to fatty acid oxidation (FAO). Here, we sought to determine if this was due to a primary defect in FAO. Accordingly, we measured FAO in myogenic differentiating MSCs under 3 conditions: (a) myogenesis alone, (b) excess fatty acid exposure, and (c) excess fatty acid exposure plus a chemical uncoupler to increase metabolic rate. Compared with normal weight and Ef-Ob MSCs, In-Ob displayed lower FAO in myogenesis alone and after fatty acid plus uncoupler, indicating In-Ob were less metabolically flexible after increasing lipid availability and metabolic rate, demonstrating a primary deficit in FAO. MSC FAO was negatively associated with fasting maternal glucose and insulin and positively associated with fasting HDL-cholesterol. MSC FAO was negatively associated with infant fat mass. These data indicate a less favorable maternal metabolic milieu, independent of maternal BMI, reduces intrinsic MSC FAO and is linked to higher infant adiposity as early as birth.

Highlights

Childhood obesity is a global public health crisis in need of efficacious prevention strategies [1]
We observed that mesenchymal stem cells (MSCs) differentiating into myotubes collected from infants of mothers with obesity were phenotypically different than MSCs from infants of NW mothers, and further examination revealed a bimodal distribution of metabolically efficient and inefficient subtypes among MSCs from infants of mothers with obesity [11]
We sought to uncover whether differences in MSC metabolic efficiency reflected a primary defect in fatty acid oxidation (FAO) by assessing cellular metabolic flexibility

Summary

Introduction

Childhood obesity is a global public health crisis in need of efficacious prevention strategies [1]. Several observational studies in humans show that exposure to maternal obesity in utero is associated with obesity and metabolic disease risk later in life [2,3,4,5,6,7,8,9,10]. This is in alignment with the Developmental Origins of Health and Disease (DOHaD) hypothesis, which posits that the propensity for obesity may be affected during fetal development. Previous research by ourselves and others shows the innovative Wharton’s jelly–derived mesenchymal stem cell (MSC) model may overcome this limitation [11,12,13]

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Conclusion