Nutritional science is evolving to an enhanced emphasis on recent scientific and technological advancements supporting a transition to precision nutrition as a strategy for disease prevention and management across populations. The complexity of chronic disease, which afflicts 6 in 10 adult Americans, is highlighted in the diet-disease relation where it is apparent that there is no "one size fits all" approach to disease management. Precision nutrition is the study of how individuals respond differently to food and nutrients, and it leads to personalized or classified, evidence-based guidelines that represent the best approach for fighting chronic disease. Enhanced resources are imperative as we transition to a precision nutrition approach that will transform agriculture and nutritional science to support positive health outcomes. Both the USDA and the NIH recognize the need to prioritize research and funding on precision nutrition. Increased federal investment in this realm is critical as we look ahead; it will help lower health care costs, while supporting individual health and quality of life.

There is a large body of literature demonstrating the efficacy of maternal folic acid intake in preventing birth defects, as well as investigations into potential adverse consequences of consuming folic acid above the upper intake level (UL). Recently, two authoritative bodies convened expert panels to assess risks from high intakes of folic acid: the U.S. National Toxicology Program and the UK Scientific Advisory Committee on Nutrition. Overall, the totality of the evidence examined by these panels, as well as studies published since the release of their reports, have not established risks for adverse consequences resulting from existing mandatory folic acid fortification programs that have been implemented in many countries. Current folic acid fortification programs have been shown to support public health in populations, and the exposure levels are informed by and adherent to the precautionary principle. Additional research is needed to assess the health effects of folic acid supplement use when the current upper limit for folic acid is exceeded.

Folate-mediated one-carbon metabolism (FOCM) comprises a network of interconnected folate-dependent metabolic pathways responsible for serine and glycine interconversion, de novo purine synthesis, de novo thymidylate synthesis and homocysteine remethylation to methionine. These pathways are compartmentalized in the cytosol, nucleus and mitochondria. Individual enzymes within the FOCM network compete for folate cofactors because intracellular folate concentrations are limiting. Although there are feedback mechanisms that regulate the partitioning of folate cofactors among the folate-dependent pathways, less recognized is the impact of cell cycle regulation on FOCM. This review summarizes the evidence for temporal regulation of expression, activity and cellular localization of enzymes and pathways in the FOCM network in mammalian cells through the cell cycle. This article is categorized under: Biological Mechanisms > Metabolism Physiology > Mammalian Physiology in Health and Disease

Disruptions in folate-mediated one-carbon metabolism (FOCM) are associated with risk for several pathologies including developmental anomalies such as neural tube defects and congenital heart defects, diseases of aging including cognitive decline, neurodegeneration and epithelial cancers, and hematopoietic disorders including megaloblastic anemia. However, the causal pathways and mechanisms that underlie these pathologies remain unresolved. Because folate-dependent anabolic pathways are tightly interconnected and best described as a metabolic network, the identification of causal pathways and associated mechanisms of pathophysiology remains a major challenge in identifying the contribution of individual pathways to disease phenotypes. Investigations of genetic mouse models and human inborn errors of metabolism enable a more precise dissection of the pathways that constitute the FOCM network and enable elucidation of causal pathways associated with NTDs. In this overview, we summarize recent evidence that the enzyme MTHFD1 plays an essential role in FOCM in humans and in mice, and that it determines the partitioning of folate-activated one carbon units between the folate-dependent de novo thymidylate and homocysteine remethylation pathways through its regulated nuclear localization. We demonstrate that impairments in MTHFD1 activity compromise both homocysteine remethylation and de novo thymidylate biosynthesis, and provide evidence that MTHFD1-associated disruptions in de novo thymidylate biosynthesis lead to genome instability that may underlie folate-associated immunodeficiency and birth defects. (C) 2016 Elsevier B.V. and Societe Francaise de Biochimie et Biologie Moleculaire (SFBBM). All rights reserved.