Nutrigenomics and Nutrigenetics

Regulation of adipose cell mass is a critical homeostatic process in higher vertebrates. The conversion of fibroblasts into cells of the adipose lineage is induced by expression of the orphan nuclear receptor PPAR gamma. This suggests that an endogenous PPAR gamma ligand may be an important regulator of adipogenesis. By assaying arachidonate metabolites for their capacity to activate PPAR response elements, we have identified 15-deoxy-delta 12, 14-prostaglandin J2 as both a PPAR gamma ligand and an inducer of adipogenesis. Similarly, the thiazolidinedione class of antidiabetic drugs also bind to PPAR gamma and act as potent regulators of adipocyte development. Thus, adipogenic prostanoids and antidiabetic thiazolidinediones initiate key transcriptional events through a common nuclear receptor signaling pathway. These findings suggest a pivotal role for PPAR gamma and its endogenous ligand in adipocyte development and glucose homeostasis and as a target for intervention in metabolic disorders.

Genetic and environmental factors, including diet and life-style, both contribute to cardiovascular disease, cancers, and other major causes of mortality, but various lines of evidence indicate that environmental factors are most important. Overly enthusiastic expectations regarding the benefits of genetic research for disease prevention have the potential to distort research priorities and spending for health. However, integration of new genetic information into epidemiologic studies can help clarify causal relations between both life-style and genetic factors and risks of disease. Thus, a balanced approach should provide the best data to make informed choices about the most effective means to prevent disease.

The glycemic index concept is an extension of the fiber hypothesis, suggesting that fiber consumption reduces the rate of nutrient influx from the gut. The glycemic index has particular relevance to those chronic Western diseases associated with central obesity and insulin resistance. Early studies showed that starchy carbohydrate foods have very different effects on postprandial blood glucose and insulin responses in healthy and diabetic subjects, depending on the rate of digestion. A range of factors associated with food consumption was later shown to alter the rate of glucose absorption and subsequent glycemia and insulinemia. At this stage, systematic documentation of the differences that exist among carbohydrate foods was considered essential. The resulting glycemic index classification of foods provided a numeric physiologic classification of relevant carbohydrate foods in the prevention and treatment of diseases such as diabetes. Since then, low-glycemic-index diets have been shown to lower urinary C-peptide excretion in healthy subjects, improve glycemic control in diabetic subjects, and reduce serum lipids in hyperlipidemic subjects. Furthermore, consumption of low-glycemicindex diets has been associated with higher HDL-cholesterol concentrations and, in large cohort studies, with decreased risk of developing diabetes and cardiovascular disease. Case-control studies have also shown positive associations between dietary glycemic index and the risk of colon and breast cancers. Despite inconsistencies in the data, sufficient, positive findings have emerged to suggest that the dietary glycemic index is of potential importance in the treatment and prevention of chronic diseases.