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Supplement May Block Brain Damage from Alcohol Consumption in Pregnancy
Alcohol consumption in early pregnancy increases levels of a little-known lipid called ceramide, significantly increasing suicide among cells critical to skull and brain formation, biochemist Dr. Erhard Bieberich reports.
Resulting neural crest damage includes the brain’s “skin” – the multi-layered meninges that provides protection and nourishment – producing less TGF-?1, a growth factor critical for brain and bone development. That finding may help explain the cranial bone and cognitive defects that can result in fetal alcohol syndrome.
“There is just a little window,” Bieberich said, about four weeks after conception when neural crest cells emerge for a few days before morphing into other cell types that help form numerous organs. This is often before a woman knows she is pregnant. The studies indicate the potential for lasting damage to the fetus if a woman drinks, for example, several glasses of wine within an hour during that window.
Researchers suspected ceramide, known to induce cell death and be activated by alcohol, as a culprit in the damage. They found high levels of ceramide both in mouse cells and pregnant mice exposed to alcohol along with a five-fold increase in apoptotic, or dying cells. “There is a clear correlation,” he said.
Researchers thought neural crest cells were tough cells whose function could be replaced if they happened to get injured. Instead they found that 25 percent of mouse embryos exposed to alcohol during that critical period had defects in the fibrous joints that connect the skull. “You get a snowball effect: The neural crest is damaged, the meninges doesn’t develop properly and tissue like bone and brain that are regulated by the meninges don’t develop properly either,” Bieberich said.
When they added ceramide-neutralizing CDP-choline to the mouse cells, cell death and ceramide levels were reduced. Alcohol prompts the body to produce more ceramide from the brain lipid sphingomyelin, a major component of cell membranes. They found that CDP-choline pushes back toward producing less ceramide, preventing damage providing the drinking stops.
“Ceramide can be bad or good,” notes Bieberich, who has shown, for example, ceramide’s role in helping early stem cells evolve into embryonic tissue. But alcohol upsets the natural balance.
Follow up studies include determining whether CDP-choline can rescue cells after the fact or whether it or a similar supplement would need to be taken preventively. “Hopefully we can rescue some of the cells by triggering or signaling the back reaction,” Bieberich said. He also wants to see if CDP-choline affords the same protection in pregnant mice that it does in laboratory cells.
1. G Wang, E Bieberich. Prenatal alcohol exposure triggers ceramide-induced apoptosis in neural crest-derived tissues concurrent with defective cranial development. Cell Death and Disease (2010) 1, e46; doi:10.1038/cddis.2010.22.
2. Image by brapps.