WASHINGTON – There is increasing evidence from human and animal studies that offspring of parents who were physically or psychologically stressed are at higher risk of developing obesity, and that these offspring may in turn "transmit" that increased risk to the next generation. Now research conducted at the University of Minnesota and Georgetown University suggests that a mother's nutritional or psychological stress during pregnancy and lactation may create a signature on her child's genes that put the child at increased risk for obesity later in life, especially if the child is female.
Ruijun Han at the University of Minnesota Medical School's Department of Integrative Biology and Physiology will discuss the team's findings at the at the Experimental Biology meeting (EB 2011), being held April 9-13, 2011 at the Walter E. Washington Convention Center, Washington, DC. The title of his presentation is "Stress-induced Epigenetic Programming for Adipogenesis: Role of Neuropeptide Y and Adipose Stem Cells."
Two-Tiered Research
The Minnesota team focused on the behavior of neuropeptide Y (NPY), a neurotransmitter found in the brain and autonomic nervous system that is associated with appetite stimulation and the storage of energy as fat. Building on prior research in the field, the team undertook two studies, one involving mice and the other involving mouse embryonic stem cells.
In the first study, the researchers sought to determine if prenatal and postnatal stress exerted long-term effects on the activation of NPY and its Y2 receptor (Y2R) that would result in the creation of fat cells and the promotion of obesity. First, they exposed pregnant mice to stress by feeding them a low-protein diet. The team found that this diet caused low birth weight in the offspring. Female offspring of the mice stressed during pregnancy and lactation grew faster after weaning when they were fed a high-fat diet, and within 2 months, they developed abdominal fat, prediabetes (impaired glucose tolerance) and increased upregulation of Y2R in their fat tissue. Although male offspring of stressed mothers also had low birth weight, they did not develop obesity and they had lower Y2R expression and better metabolic health, even when fed a high-fat diet.
"This indicates that maternal stress during pregnancy and lactation could induce gender-specific abdominal obesity and impaired glucose metabolism associated with increased plasma NPY and fat Y2R," says Dr. Han.
Stress may affect NPY and Y2R in several ways, says Dr. Zofia Zukowska, professor of physiology and the senior researcher of the study. "It could be that the mother's poor nutrition or other type of stress can affect fetal development by depriving the fetus of necessary nutrients or exposing it to levels of stress hormones such as cortisol, norepinephrine and epinephrine [adrenaline], which in turn up-regulate the NPY-Y2R system to affect metabolism and fat growth of the offspring."
The team sought to tease out these effects in the second study by observing how mice embryonic stem cells behave when over-exposed to stress hormones at a critical point in their differentiation. Embryonic stem cells that have been treated with insulin and dexamathasone (synthetic glucocorticoid) will differentiate into fat cells. The team exposed such cells with epinephrine in a test dish and saw that the cells increased fat-cell formation and NPY expression. The cells also decreased DNA methylation in the NPY promoter region, through an epigenetic (non-genetic) process that alters expression of this peptide in cells so that the cells "remember" their type (i.e., stem cells will remain committed to fat cell lineage and give rise to fat cells, instead of becoming or giving rise to another kind of cell).
"All of this data suggests that stress may induce epigenetic changes in NPY and its receptor genes and program [the offspring's DNA] for the future development of abdominal obesity and metabolic syndrome," says Dr. Han.
Implications
Although mice are not people, the Minnesota team's research has implications for tackling human obesity because it sheds light on the process by which fat cell volume and the number of fat cells are derived, says Dr. Han. "Adipocyte number before adolescence is a major determinant [of a person's risk of obesity], so intervention during pregnancy and childhood might be an efficient way to prevent adult obesity."
About Experimental Biology 2011
Experimental Biology is an annual gathering of six scientific societies that this year is expected to draw 13,000-plus independent scientists and exhibitors. The American Physiological Society (APS) is a co-sponsor of the meeting along with the American Association of Anatomists (AAA), American Society for Biochemistry and Molecular Biology (ASBMB), American Society for Investigative Pathology (ASIP), American Society for Nutrition (ASN) and the American Society for Pharmacology and Experimental Therapeutics (ASPET).
About the American Physiological Society
The American Physiological Society (APS) is a nonprofit scholarly association dedicated to fostering scientific research, education and dissemination of information about human and animal physiology. Founded in 1887 with 28 members, the APS now has more than 10,500 members, most of whom have doctoral degrees in physiology, medicine or other health sciences. The Society's national headquarters is in Bethesda, Maryland on the campus of the Federation of American Societies for Experimental Biology (FASEB).
NOTE TO EDITORS: To request an interview with Dr. Han or Zukowska please contact Donna Krupa at 301.634.7209 or dkrupa@the-aps.org.