Maternal CD8+ T-cell depletion alleviates intrauterine inflammation-induced perinatal brain injury.

We investigated the mechanisms by which CD8+ T-cell trafficking in placenta contributes to perinatal brain injury by studying effects of maternal CD8+ T-cell depletion (DEP) in a mouse model of intrauterine inflammation (IUI). Maternal CD8+ T cells were depleted with anti-CD8+ antibodies. IUI was induced with lipopolysaccharide (LPS). DEP was confirmed using flow cytometry. Preterm birth rate was evaluated. Offspring neurologic sequelae were assessed by Nissl staining, immune arrays, confirmatory individual TaqMan® gene assays, and neurobehavioral tests. DEP did not significantly prevent LPS-induced preterm birth but improved neurobehavioral performance (P < .001) and increased cortical neuronal density (P < .05) in LPS-exposed pups compared to controls. These changes were associated with decreased CCL3 and CXCL10 and increased CCL5 in DEP LPS-exposed mice. We demonstrate that DEP reduces perinatal brain injury following IUI. This supports a role for maternal CD8+ T-cell trafficking in placenta in mediating perinatal brain injury separate from preterm birth mechanisms.

Maternal Glucose Supplementation in a Murine Model of Chorioamnionitis Alleviates Dysregulation of Autophagy in Fetal Brain.

Fetal brain injury induced by intrauterine inflammation is a major risk factor for adverse neurological outcomes, including cerebral palsy, cognitive dysfunction, and behavioral disabilities. There are no adequate therapies for neuronal protection to reduce fetal brain injury, especially new strategies that may apply promptly and conveniently. In this study, we explored the effect of maternal glucose administration in a mouse model of intrauterine inflammation at term. Our results demonstrated that maternal glucose supplementation significantly increased survival birth rate and improved the neurobehavioral performance of pups exposed to intrauterine inflammation. Furthermore, we demonstrated that maternal glucose administration improved myelination and oligodendrocyte development in offspring exposed to intrauterine inflammation. Though the maternal blood glucose concentration was temporally prevented from decrease induced by intrauterine inflammation, the glucose concentration in fetal brain was not recovered by maternal glucose supplementation. The adenosine triphosphate (ATP) level and autophagy in fetal brain were regulated by maternal glucose supplementation, which may prevent dysregulation of cellular metabolism. Our study is the first to provide evidence for the role of maternal glucose supplementation in the cell survival of fetal brain during intrauterine inflammation and further support the possible medication with maternal glucose treatment.

Maternal Fructose Consumption Disrupts Brain Development of Offspring in a Murine Model of Autism Spectrum Disorder.

Objective The objective of this study was to localize by neuroimaging the altered structural brain development of these offspring using an autism model of transgenic mice lacking contactin-associated protein-like 2 (Cntnap2). Materials and Methods Pregnant dams were randomly allocated to fructose solution (10% W/V) as only drinking fluid or water. Cntnap2 heterozygous (+/-) offspring from each group were euthanized at 6 months of age and their whole brains evaluated by magnetic resonance imaging. T2-weighted images were acquired to evaluate the volumes of 29 regions of interest involved in autism spectrum disorder (ASD) pathogenesis. Whole brains were washed and processed for Nissl staining. Mann-Whitney U test and one-way analysis of variance were used for statistical analysis (significance: p < 0.05). Results The corpus callosum, anterior commissure, and caudate putamen were significantly smaller in Cntnap2 (+/-) male offspring exposed to fructose. No brain alterations were found in the female counterparts. Nissl staining of the caudate putamen revealed higher neuronal cell count in the male fructose offspring. Female group revealed an increase in caudate putamen neuronal cell count. Conclusion Metabolic dysregulation in pregnancy alters fetal brain development in genetically predisposed offspring. This is consistent with findings in human studies and supports the role of intrauterine factors in the etiology of autism.