Mom’s Placenta Reflects Her Exposure to Stress

The mammalian placenta is more than just a filter through which nutrition and oxygen are passed from a mother to her unborn child. According to a new study by a research group from the University of Pennsylvania School of Veterinary Medicine, if a mother is exposed to stress during pregnancy, her placenta translates that experience to her fetus by altering levels of a protein that affects the developing brains of male and female offspring differently.

These findings suggest one way in which maternal-stress exposure may be linked to neurodevelopmental diseases such as autism and schizophrenia, which affect males more frequently or more severely than females.

“Most everything experienced by a woman during a pregnancy has to interact with the placenta in order to transmit to the fetus,” said Tracy L. Bale, senior author on the paper and an associate professor in the Department of Animal Biology at Penn Vet. “Now we have a marker that appears to signal to the fetus that its mother has experienced stress.”

Bale also holds an appointment in the Department of Psychiatry in Penn’s Perelman School of Medicine. Her coauthors include lead author and postdoctoral researcher Christopher L. Howerton, graduate student Christopher Morgan and former technician David B. Fischer, all of Penn Vet.

Published in the Proceedings of the National Academy of Sciences, the study builds on previous work by Bale and her colleagues which found that female mice exposed to stress during pregnancy gave birth to males who had heightened reactions to stress. Further research showed that the effect extended to the second generation: The sons of those male mice also had abnormal stress reactions.

Meanwhile, human studies conducted by other researchers have shown that males born to women who experience stress in the first trimester of pregnancy are at an increased risk of developing schizophrenia.

The Penn team hoped to find a biomarker that could account for these changes and risk factors. To be an effective signal of maternal stress, the researchers reasoned, a biomarker would need to show differences in expression between male and female offspring and would need to be different between stressed and unstressed mothers. They also wanted to find a marker that behaved similarly in humans.