The study evaluated how famine exposure—defined as 900 calories daily or less—during the Dutch Hunger Winter of 1944–1945 affected genome-wide DNA methylation levels. The researchers also studied the impact of short-term exposure, pre-conception and post-conception. The study used blood samples of 422 individuals exposed to the famine at any time during gestation and 463 controls without prenatal famine exposure.
The authors examined individuals born between February 1945 and March 1946 whose mothers were exposed to the famine during or immediately preceding pregnancy, individuals conceived between March and May 1945 at the time of extreme famine, and controls born in the same institutions whose mothers did not experience famine while pregnant as well as sibling controls who were also not exposed to famine in pregnancy.
The findings show associations between famine exposure during weeks 1–10 of gestation and DNA changes, but not later in pregnancy. DNA methylation changes were also seen among individuals conceived at the height of the famine between March and May 1945 who were not exposed to all 10 weeks of early gestation.
“The first ten weeks of gestation is a uniquely sensitive period when the blood methylome—or whole-genome DNA methylation—is especially sensitive to the prenatal environment,” said L.H. Lumey, MD, PhD, associate professor of Epidemiology at the Mailman School of Public Health, and last author. “This is the period when a woman may not even be aware that she is pregnant.”
Earlier studies in other populations in the Netherlands led by Dr. Lumey examined the long-term impact of famine exposure and identified early gestation as the most critically sensitive period. Their work among over 45,000 military recruits revealed that famine exposure in the first pregnancy trimester was associated with a 10-percent increase in mortality at age 63 years.
“Further analysis of health outcomes among men and women with famine exposure is now needed. We are therefore looking if DNA-methylation can make a difference for obesity and diabetes risk in this population,” said Lumey. “We are also interested in sex-specific effects, but for these questions larger studies may be needed.”
Co-authors are Elmar W. Tobi, Roderick C. Slieker, H. Eka D. Suchiman, P. Eline Slagboom, Erik W. van Zwet, andBastiaan T. Heijmans of Leiden University Medical Center, and Aryeh D. Stein, Emory University Rollins School of Public Health. DNA analyses were performed by Tobi and Heijmans and their colleagues from the Molecular Epidemiology group at Leiden University Medical Center.
The study was supported by the National Institutes of Health grants AG042190 and HL067914. There were no reported conflicts of interest.
About Columbia University’s Mailman School of Public Health
Founded in 1922, Columbia University’s Mailman School of Public Health pursues an agenda of research, education, and service to address the critical and complex public health issues affecting New Yorkers, the nation and the world. The Mailman School is the third largest recipient of NIH grants among schools of public health. Its over 450 multi-disciplinary faculty members work in more than 100 countries around the world, addressing such issues as preventing infectious and chronic diseases, environmental health, maternal and child health, health policy, climate change & health, and public health preparedness. It is a leader in public health education with over 1,300 graduate students from more than 40 nations pursuing a variety of master’s and doctoral degree programs. The Mailman School is also home to numerous world-renowned research centers including ICAP (formerly the International Center for AIDS Care and Treatment Programs) and the Center for Infection and Immunity. For more information, please visit www.mailman.columbia.edu.
Contact: Stephanie Berger, Columbia University’s Mailman School of Public Health, 212-305-4372, firstname.lastname@example.org