Preliminary Investigation of Microbiome and Dietary Differences in Patients with Phenylketonuria on Enzyme Substitution Therapy Compared to Traditional Therapies.

BACKGROUND: Phenylketonuria (PKU) is an inborn error of metabolism that impairs the function of the enzyme phenylalanine hydroxylase. Historical treatment includes limiting dietary phenylalanine (Phe) consumption while supplementing with medical food; however, this treatment has been associated with complications, such as nutritional deficiencies and disruptions in the gut microbiota. OBJECTIVE: The study aim was to compare dietary and gut microbiome differences between adult patients on a traditional PKU diet with those receiving the enzyme substitution therapy Palynziq on a liberalized diet while controlling blood Phe levels to <600 µmol/L (to convert to mg/dL divide by 60.5). DESIGN: A cross-sectional study was conducted comparing patients on a traditional Phe-restricted diet with patients receiving Palynziq eating a liberalized diet. PARTICIPANTS/SETTING: Six patients eating a traditional Phe-restricted diet with medical food and 6 patients on Palynziq eating a liberalized diet without medical food intake for more than 3 years were selected from the University of Kentucky Metabolic Clinic from August to December 2019. MAIN OUTCOME MEASURES: Nutrient intake from 3-day diet records and fecal microbiome taxonomic abundances were analyzed. STATISTICAL ANALYSIS: Mann-Whitney U tests were used for dietary data analysis. Differential abundance analysis for microbiome taxa and pathway data was done using DESeq2 analysis. RESULTS: Dietary data showed patients receiving Palynziq consumed a lower percent of kilocalories from total protein and lower amounts of most micronutrients, but consumed greater amounts of intact protein and cholesterol (P < .05). Microbiome data revealed a greater abundance of the phylum Verrucomicrobia and genus Lachnobacterium in the Traditional group and a greater abundance of the genus Prevotella in the Palynziq group (P < .05). Pathway analysis depicted greater enrichment in carotenoid and amino acid metabolism pathways in the Traditional group (P < .05). Protein (% kcal), dietary fiber (g), fat (% kcal), linolenic acid (% Dietary Reference Intakes), and age were correlated with the underlying microbial community structure for both groups combined. CONCLUSIONS: Patients with PKU treated with Palynziq on a liberalized diet manifest significant differences in diet composition compared with those treated with traditional Phe-restricted diets. Several of these dietary differences may affect the microbiome architecture.

Dietary inulin decreases circulating ceramides by suppressing neutral sphingomyelinase expression and activity in mice.

Elevated circulating levels of ceramides (Cers) are associated with increased risk of cardiometabolic diseases, and Cers may play a causative role in metabolic dysfunction that precedes cardiac events, such as mortality as a result of coronary artery disease. Although the mechanisms involved are likely complex, these associations suggest that lowering circulating Cer levels could be protective against cardiovascular diseases. Conversely, dietary fibers, such as inulin, have been reported to promote cardiovascular and metabolic health. However, the mechanisms involved in these protective processes also are not well understood. We studied the effects of inulin on lipid metabolism with a model of atherosclerosis in LDL receptor-deficient mice using lipidomics and transcriptomics. Plasma and tissues were collected at 10 days and/or 12 weeks after feeding mice an atherogenic diet supplemented with inulin or cellulose (control). Compared with controls, inulin-fed mice displayed a decreased C16:0/C24:0 plasma Cer ratio and lower levels of circulating Cers associated with VLDL and LDL. Liver transcriptomic analysis revealed that Smpd3, a gene that encodes neutral SMase (NSMase), was downregulated by 2-fold in inulin-fed mice. Hepatic NSMase activity was 3-fold lower in inulin-fed mice than in controls. Furthermore, liver redox status and compositions of phosphatidylserine and FFA species, the major factors that determine NSMase activity, were also modified by inulin. Taken together, these results showed that, in mice, inulin can decrease plasma Cer levels through reductions in NSMase expression and activity, suggesting a mechanism by which fiber could reduce cardiometabolic disease risk.