APOA2 Gene, Diet, Inflammation and Gut Health

The primary objectives of this application are 1. To use a diet intervention setting to rigorously evaluate the mechanisms responsible for the previously observed effects, focusing on gut microbiota and markers of gut health and inflammation and 2. To prove that targeted dietary intervention based on genes can provide additional, tailored benefit to genetically vulnerable individuals. The overall hypothesis proposes that significant cross-talk between the human host genome, the microbiome, and the diet, defines the observed inter-individual variation in metabolic and physiological responses. Accordingly, the investigators propose the following specific aims and hypotheses.

AIM 1: To catalog the response of the plasma metabolome to diets differing in saturated fat and prebiotics content (animal-based diet versus plant-based diet) in individuals from the USA carrying CC (n=20) and TT (n=20) genotypes at the common APOA2 -265T>C SNP using a crossover, randomized dietary intervention study.

Our primary hypothesis states: A significant and biologically relevant proportion of the individual variation in changes in the plasma metabolome in response to dietary saturated fat and prebiotic intake will be due to APOA2-265T>C genotypes. Specifically, subjects homozygous (CC) for the less common C allele will respond to decreases in total dietary saturated fat and increases in prebiotics (i.e., plant-based diet) with significantly greater improvement of metabolites related to gut health, inflammation and other cardiometabolic traits than subjects homozygous (TT) for the common T allele.

AIM 2: To characterize differential impacts of low SFA/high prebiotic (plant-based) diet vs. high SFA/low prebiotic (animal-based) diets on gut microbiota patterns between CC and TT persons at APOA2-265T>C.

Our primary hypothesis states: CC subjects have a preference for high-fat and -protein foods and therefore high levels of Bacteroidetes, Actinobacteria and similar species in the gut are expected. Moreover, reducing intake of saturated fat and increasing prebiotics will be more effective in inducing a healthier gut microflora profile in CC subjects than in those with the TT genotype, with opposite effects observed when the diet is switched to one high in saturated fat.

AIM 3: To integrate the metabolomic and gut microflora taxonomic information generated in AIM1 and AIM2 in order to elucidate the physiological mechanism(s) by which diet impinges on metabolic pathways through APOA2 genotypes.

Our primary hypothesis states: A diet low in saturated fat and high in prebiotics induces beneficial changes in gut microbiota, metabolic processes and inflammation, which are significantly more pronounced in CC than in TT subjects.