Transcriptome analysis of the effects of maternal fructose exposure during gestation and lactation on the cytoskeleton of offspring hippocampus

Excessive fructose consumption poses a public health concern. Maternal fructose overconsumption impairs offspring hippocampal function, indicating hippocampal sensitivity to fructose. The hippocampus is the vital for spatial learning and memory, and the cytoskeletal structure is crucial for hippocampal neuronal plasticity. The Rho GTPase is a key regulator of neuronal cytoskeleton formation, with RhoA protein governing neuronal growth and development. The RhoA/ROCK2 pathway affects myosin light chain phosphorylation, leading to cytoskeletal reorganization, actin cytoskeleton changes, and neurite retraction. However, the effects of maternal fructose exposure during gestation and lactation on the offspring's neural cytoskeleton remain unclear. We established maternal fructose exposure models during gestation and lactation, assessing fasting blood glucose levels in offspring confirm model effectiveness. Whole transcriptome sequencing examined offspring hippocampal developmental programming. Immunofluorescence and Western blot analyses assessed RhoA/ROCK2 pathway expression changes in the hippocampus, with PCR validating transcriptome sequencing results. Transcriptome sequencing identified 193 and 298 differentially expressed genes in the control, 13% fructose, and 40% fructose groups, respectively. GO and KEGG analyses revealed significant changes related to neural development, learning memory, and cytoskeleton in both fructose-exposed groups. GSEA indicated substantial cytoskeleton-related alterations in the offspring. Immunofluorescence demonstrated significant CRMP2 protein down-regulation in both fructose-exposed groups. Western blotting showed significantly higher expression of RhoA, ROCK2, p-ROCK2, and p-MLC2 in the fructose-exposed groups (P < 0.05). Maternal high-fructose exposure significantly impacts gene expression in offspring. These alterations may influence hippocampal neurodevelopment by upregulating the RhoA/ROCK2 pathway, leading to cytoskeletal damage and axon growth inhibition.