c-Abl is involved in high glucose-induced apoptosis in embryonic E12.5 cortical neural progenitor cells from the mouse brain.

Hyperglycemia causes direct apoptosis of neural progenitor cells (NPCs) in diabetic-induced neural tube defects in embryos. However, the underlying mechanisms are poorly understood. The present study is aimed to investigate the specific cellular proteins that may be involved in NPCs apoptosis as well as mechanisms by which the proteins regulate the oxidative stress-induced NPCs apoptosis. Our present results have shown that the expression of c-Abl was up-regulated in NPCs exposed to high glucose in vitro. The increased c-Abl was localized mainly in the nucleus. High glucose also induced an increase in nuclear p53 protein levels and the p53-c-Abl complex in NPCs. Administration of reactive oxygen species scavengers decreased the protein level of c-Abl, p53 and NPCs apoptosis. Inhibition of c-Abl reduced NPCs apoptosis and the nuclear protein level of p53 in response to high glucose. These results demonstrate that c-Abl is involved in the reactive oxygen species-activated apoptotic pathways in NPCs apoptosis. Inhibition of c-Abl may protect NPCs against insults induced by high glucose via the modulation of NPCs apoptotic machinery.

Folic acid supplementation affects apoptosis and differentiation of embryonic neural stem cells exposed to high glucose.

Folic acid (FA) supplementation has been shown to be extremely effective in reducing the occurrence of neural tube defects (NTDs), one of the most common birth defects associated with diabetic pregnancy. However, the antiteratogenic mechanism of FA in diabetes-induced NTDs is unclear. This study investigated the neuroprotective mechanism of FA in neural stem cells (NSCs) exposed to high glucose in vitro. The undifferentiated or differentiated NSCs were cultured in normal D-glucose concentration (NG) or high D-glucose concentration (HG) with or without FA. FA supplementation significantly decreased apoptosis induced by HG and lowered the expression of p53 in the nucleus of undifferentiated NSCs exposed to HG. Administration of FA in differentiated NSCs did not alter their precocious differentiation induced by HG. The increased mRNA expression levels of the basic helix-loop-helix factors including Neurog1, Neurog2, NeuroD2, Mash1, Id1, Id2, and Hes5 in the presence of HG were not significantly affected by FA. The present results provided a cellular mechanism by which FA supplementation may have a potential role in prevention of NTDs in diabetic pregnancies. On the other hand, FA increased the mRNA expression levels of the above transcription factors and accelerated the differentiation of NSCs in the NG medium, suggesting that it may adversely affect the normal differentiation of NSCs. Therefore, the timing and dose of FA would be critical factors in considering FA supplementation in normal maternal pregnancy.