Pregnant Women’s Immune Response to a Virus May Affect Fetal Brain Cells
In a study in mice, the mother’s natural anti-viral proteins disrupted the development of neural circuits in the fetus
When a pregnant woman is infected with a virus, her immune system’s response to the infection may harm her baby’s brain – even if the fetus is not infected with the virus itself. This finding emerges from a study by researchers at the Weizmann Institute of Science.
It's been long known that a viral infection during pregnancy may increase the risk of schizophrenia, autism and other neurodevelopmental and neuropsychiatric disorders in her offspring later in life, but the exact mechanism of this effect is unknown. In particular, it’s been unclear whether the baby’s brain is liable to be harmed by the virus itself or by the pregnant woman’s immune response to the virus.
Prof. Michal Schwartz of Neurobiology Department and her team, in collaboration with the team of Prof. Ido Amit of the Immunology Department, explored this question in a study in mice. The researchers had seen in their previous works that within the brain, large amounts of the interferon-beta protein – which, among its other functions, serves as the first line of defense against viral infection in mammals – can harm brain cells called microglia. These cells play an important role in embryonic development, helping to shape neuronal circuits; thus, the scientists designed a study focusing on microglia in the fetus.
They infected pregnant mice with a synthetic RNA molecule that mimics an infection caused by RNA viruses. The latter belong to a large family of viruses that induce diseases such as flu, measles, Ebola and COVID-19. When the mouse pups were born, it turned out that their brain’s immune cells, the microglia, were adversely affected and showed abnormal behavior.
The researchers then set out to check whether this adverse effect on the microglia was caused by the virus-mimicking molecules or by the mother’s immune response to the viral infection – that is, by the antiviral immune system’s protein, interferon-beta, whose levels rise sharply as a result of this infection. They exposed the pregnant mice to the virus-mimicking molecules but at the same time treated them with antibodies that neutralize the interferon-beta. The treatment reduced the adverse effect on the microglia of the pups, suggesting that this effect was due to the interferon-beta. Next, to double check this conclusion, the scientists – instead of infecting the pregnant mice with the virus-mimicking molecules – injected them with the interferon-beta. In this case, too, the microglia of the newborn pups displayed similar abnormal functioning. Moreover, the pups themselves were later shown to behave abnormally, in a manner similar to the one exhibited in neuropsychiatric disorders, and they were more prone to stress than those born to mothers that had not been exposed to high levels of interferon-beta.
These results show that even when the fetus is not directly exposed to a virus found in the mother’s body, the microglia in the fetal brain might be damaged by the interferon-beta that the mother secretes in large amounts in response to the viral infection. “Further research may find ways of protecting the fetus from the mother’s response to the virus – that is, from the interferon that rises during viral infection,” Schwartz says. “In the meantime, pregnant women would do well to exercise caution, so as to avoid becoming infected with viruses during pregnancy.”
The study was carried out by Dr. Hila Ben-Yehuda with the assistance of several former members of the two teams, including Dr. Alexander Kertser of the Neurobiology Department, and Dr. Orit Matcovitch-Natan and Amit Spinrad of the Neurobiology and Immunology Departments.
Prof. Ido Amit's research is supported by the Helen and Martin Kimmel Award for Innovative Investigation; the Sagol Institute for Longevity Research; the Kekst Family Institute for Medical Genetics; the Thompson Family Foundation Alzheimer's Research Fund; the Adelis Foundation; Richard andJacqui Scheinberg; the Ben B. and Joyce E. Eisenberg Foundation; the Anita James Rosen Foundation; the Lowy Foundation; the Wolfson Family Charitable Trust; the Vainboim Family; Lady Michelle Michels; Rosanne Cohen; Mauricio Gerson; Erika Mogyoros; Thomas Franklin Buchheim; Jeff Pinkner and Maya Iwanaga; the estate of Simon Saretzky; and the estate of Arthur Rath. Prof. Amit is the incumbent of the Eden and Steven Romick Professorial Chair.
Prof. Michal Schwartz's research is supported by the Sagol Institute for Longevity Research; the Thompson Family Foundation Alzheimer's Disease Research Fund; the Adelis Foundation; the Rowland and Sylvia Schaefer Family Foundation; Carla Hunter and Andre M. Schub; and Peggy and Paul Schachter.