Mapping the cord blood transcriptome of pregnancies affected by early maternal anemia to identify signatures of fetal programming

Objective Anemia during early pregnancy (EP) is common in developing countries and is associated with adverse health consequences for both mother and children. Offspring of women with EP anemia often have low birth-weight, the latter being a risk factor for cardiometabolic diseases including type 2 diabetes (T2D) later in life. Mechanisms underlying developmental programming of adult cardiometabolic disease include epigenetic and transcriptional alterations potentially detectable in umbilical cord blood (UCB) at time of birth. Methods We leveraged global transcriptome- and accompanying epigenome-wide changes in 48 UCB from newborns of EP-anemic Tanzanian mothers and 50 controls to identify differentially expressed genes (DEG) in UCB exposed to maternal EP-anemia. DEGs were assessed for association with neonatal anthropometry and cord insulin levels. These genes were further studied in expression data from human fetal pancreas and adult islets to understand their role in beta-cell development and/or function. Results The expression of 137 genes was altered in UCB of newborns exposed to maternal EP anemia. These putative signatures of fetal programming which included the birth-weight locus LCORL, were potentially mediated by epigenetic changes in 27 genes and associated with neonatal anthropometry. Among the DEGs were P2RX7, PIK3C2B, and NUMBL which potentially influence beta-cell development. Insulin levels were lower in EP anemia exposed UCB, supporting the notion of developmental programming of pancreatic beta-cell dysfunction and subsequently increased risk of T2D in offspring of EP anemic mothers. Conclusions Our data provide proof-of-concept on distinct transcriptional and epigenetic changes detectable in UCB from newborns exposed to maternal EP anemia.

Prenatal acoustic programming of mitochondrial function for high temperatures in an arid-adapted bird

Sound is an essential source of information in many taxa and can notably be used by embryos to programme their phenotypes for postnatal environments. While underlying mechanisms are mostly unknown, there is growing evidence for the involvement of mitochondria—main source of cellular energy (i.e. ATP)—in developmental programming processes. Here, we tested whether prenatal sound programmes mitochondrial metabolism. In the arid-adapted zebra finch, prenatal exposure to ‘heat-calls’—produced by parents incubating at high temperatures—adaptively alters nestling growth in the heat. We measured red blood cell mitochondrial function, in nestlings exposed prenatally to heat- or control-calls, and reared in contrasting thermal environments. Exposure to high temperatures always reduced mitochondrial ATP production efficiency. However, as expected to reduce heat production, prenatal exposure to heat-calls improved mitochondrial efficiency under mild heat conditions. In addition, when exposed to an acute heat-challenge, LEAK respiration was higher in heat-call nestlings, and mitochondrial efficiency low across temperatures. Consistent with its role in reducing oxidative damage, LEAK under extreme heat was also higher in fast growing nestlings. Our study therefore provides the first demonstration of mitochondrial acoustic sensitivity, and brings us closer to understanding the underpinning of acoustic developmental programming and avian strategies for heat adaptation.

Perinatal exposure to Bisphenol A and developmental programming of the cardiovascular changes in the offspring

: Bisphenol A (BPA) is an industrial ubiquitous compound, frequently used to produce synthetic polymers and epoxy resins. BPA is a well-recognized endocrine disruptor and xenoestrogen compound. Evidence from epidemiological and experimental studies suggests that perinatal BPA exposure (gestation and/or lactation) increases the risk of developing various diseases, including the cardiovascular system. Developmental programming refers to environmental insults during the critical window of development that affect the structure and physiology of body systems, causing permanent changes in later stages. BPA influences the developmental programming of non-communicable diseases in the offspring. In the present review, we discuss the developmental programming of cardiovascular diseases related to perinatal exposure to BPA, supported by epidemiological and experimental evidence from published literature. The majority of the reported studies found a positive association between perinatal BPA exposure and adverse cardiovascular repercussions in the fetal, neonatal, and adulthood stages. The possible underlying mechanisms include epigenetic modifications of genes involved in cardiac muscle development, autonomic tone, collagenous and non-collagenous extracellular matrix, cardiac remodeling and calcium homeostasis, and mitochondrial energy metabolism. Epigenetics can modify the outcome of any disease. Hence, in the present review, we also discuss the role of epigenetics in preventing cardiovascular diseases following perinatal exposure to BPA. We also highlight how future treatment and drug delivery related to cardiovascular involvement could be based on epigenetic markers.

130 Early Developmental Exposure to Stress and Programming of Lifelong Gut and Immune Function

Prenatal and early postnatal life represents critical periods of development across species for many organ systems including immune, nervous, reproductive, and gastrointestinal systems. A high level of plasticity exists during these periods, and thus maternal and environmental cues including stress, immune stimulation, and nutrition, can alter the normal developmental programming of the fetus and neonate and impact the trajectory for disease risk and productivity across the lifespan. This presentation will focus on the impact of and biological mechanisms by which prenatal and early postnatal stressors, including psychological immune and nutritional stressors, alter the normal developmental programming of the immune, gastrointestinal, and neuroendocrine stress axes in the offspring and how this may link to increased disease risk and reduced productivity across the lifespan in animals and humans. Further, specifically how host factors such as biological sex interact with early life stress to shape gut and systemic neuroimmune development and later life disease risk will be discussed.