Genes and Nutrition
Each of us is metabolically unique. Gene variations known as SNPs (single nucleotide polymorphisms) often are a factor in an individual’s ability to metabolize or use nutrients efficiently. Each of our specific nutrient needs is affected by which specific combination of SNPs we have, but with thousands known to impact nutrition metabolism, how do we know what those needs are?
NRI researchers are working to create a “catalog” of SNPs that alter our nutritional needs by understanding how genetic and other complex biological information can be used to better estimate individual nutrition requirements and intolerances. Our scientists use bioinformatics to extract such information from population and intervention studies, develop rules for predicting individual needs, and bring precision nutrition to health care providers and consumers with digital tools.
Publications
Genes and Nutrition Publications
2020
Genetic variants affecting bone mineral density and bone mineral content at multiple skeletal sites in Hispanic children. Voruganti VS
Precision (Personalized) Nutrition: Understanding Metabolic Heterogeneity. Zeisel S
2019
DNA methylation in mice is influenced by genetics as well as sex and life experience. French J
Cytosolic 10-formyltetrahydrofolate dehydrogenase regulates glycine metabolism in mouse liver. Krupenko S
Deleterious mutations in ALDH1L2 suggest a novel cause for neuro-ichthyotic syndrome. Krupenko S
Fine mapping and identification of serum urate loci in American Indians: The Strong Heart Family Study. Voruganti VS
Heterogeneity in Metabolic Responses to Dietary Fructose. Voruganti VS
Genetic analysis of hsCRP in American Indians: The Strong Heart Family Study. Voruganti VS
A trans-ancestral meta-analysis of genome-wide association studies reveals loci associated with childhood obesity. Voruganti VS
Healthy dietary patterns and risk and survival of breast cancer: a meta-analysis of cohort studies. Voruganti VS
Omega-3 Fatty Acids and Genome-Wide Interaction Analyses Reveal DPP10-Pulmonary Function Association. Voruganti VS
2018
C16-ceramide is a natural regulatory ligand of p53 in cellular stress response. Krupenko N
Nutritional Genomics of Cardiovascular Disease. Voruganti VS
Genetic determinants of BMI from early childhood to adolescence: the Santiago Longitudinal Study. Voruganti VS
Serum Lipid Concentrations and FADS Genetic Variants in Young Mexican College Students: The UP-AMIGOS Cohort Study. Voruganti VS
Arsenic-gene interactions and beta-cell function in the Strong Heart Family Study. Voruganti VS
Dietary Modulation of the Epigenome. Zeisel S
2017
Exome sequencing reveals novel genetic loci influencing obesity-related traits in Hispanic children. Voruganti VS
Genetic variation underlying renal uric acid excretion in Hispanic children: the Viva La Familia Study. Voruganti VS
Reduced brain volume and impaired memory in betaine homocysteine S-methyltransferase knockout mice. Zeisel S
Choline, Other Methyl-Donors and Epigenetics. Zeisel S
2016
CerS6 Is a Novel Transcriptional Target of p53 Protein Activated by Non-genotoxic Stress. Krupenko N
Genotype, B-vitamin status, and androgens affect spaceflight-induced ophthalmic changes. Zeisel S
Related News
Understanding Nutrigenomics
March 2, 2015 • Why “good” and “bad” are irrelevant when talking about genes and nutrition
From the desk of: Mihai Niculescu, M.D., Ph.D.
…“How to override your bad genes with food.” “Can Exercise Override Bad Genes?” “Good Nutrition Can Overcome Bad Genes”…
woman drawing dnaWe are bombarded by media with these kinds of messages. The main theme, of course, is that many of us may have “bad” genes that would put us at risk of a certain poor health outcome unless we eat less of “this” and more of “that.” Knowing myself as a bearer of several such genetic variations, I almost feel, at times, guilty that I am harboring such “bad” genes, albeit without my consent.
NRI Scientist Achieves New Role
March 2, 2015 • Natalia Surzenko, Ph.D., studies the connections between nutrients and brain and eye development. Her work in this area has been as Research Scientist in the Zeisel lab since joining the NRI in 2013. In recognition of the excellence she brings to her research, Dr. Surzenko has been promoted to Research Assistant Professor.
March 2015
Free Public Presentation Registration Required–Sign Up Today The NRI's popular public event series, Appetite for Life, continues on Tuesday, March 10 with a free presentation by Patrick Stover, Ph.D., on Keeping a Hungry World Healthy: Our Changing Food...
Series to help laypeople understand science
Saturday, February 14, 2015 • The following has been reprinted from Charlotte Observer, an article by Lisa Thornton. If Dr. Natalia Surzenko told you that choline produces increased hippocampal neurogenesis in Mus musculus, you probably wouldn’t understand. But if she said a nutrient called choline, naturally found in foods such as egg yolks, salmon and cocoa powder has been shown to regenerate brain cells responsible for increased memory in mice, that would be different. At the UNC Nutrition Research Institute in Kannapolis, where Surzenko, a neurobiologist, has her lab, a new series called “Appetite for Life” is intended to create clearer dialogue between researchers and laypeople about discoveries changing the way experts view nutrition.
Diet and Cancer Prevention
Dr. Stephen Hursting, Ph.D., M.P.H.
Choline: An Essential Nutrient
Makes Babies Smarter, Keeps Memory Keen and Prevents Disease, Yet Most Americans Are Missing Out
Choline was discovered in 1862, but scientists did not fully understand its importance—or what foods contained it—for another 136 years. They thought we could make our own choline, much like we make Vitamin D from sunlight and cholesterol, but only women who still produce estrogen can make enough choline—and only if they have the right genes. Forty-five percent of child-bearing women have a genetic variation called a SNP (pronounced “snip”) that prevents them from turning estrogen into choline.