People who eat diets low in choline should deplete their choline (Cho) stores, and measurements of Cho pool size using isotope dilution should reflect this depletion. Investigators will identify a biomarker panel that correlates well with measured Cho pool size across the range of different degrees of depletion.The investigators propose that, as body stores of Cho diminish, cells and organs will reach the point when metabolism/function in the cell is altered, and that this will result in a progression of changes in biomarkers that reflect Cho status.
Choline (Cho) is an essential nutrient and most Americans' diets do not achieve the recommended intake. Diets low in Cho are associated with liver and muscle disease and with suboptimal fetal development, while diets too high in choline may be associated with increased risk for heart disease. Cho is a required nutrient and in 1998, an Adequate Intake (AI) and a Tolerable Upper Limit (UL) for Cho was established In 2016, the US Food and Drug Administration (FDA) set a Recommended Daily Intake (RDI) for Cho based on the AIs as part of the new Nutrition Facts label for packaged foods (published in the Federal Register on May 27, 2016; FDA-2012-N-1210-0875, Federal Register Number:2016-11867). The AI/RDI varies by age and gender, but is 550 mg/d in adolescent and adult men and 425 mg/d in adult women (more in pregnant and lactating women) and 400 mg/day for adolescent women. There is no validated biomarker for choline status (the availability of the various forms of Cho needed to sustain optimal cellular function). Measurement of plasma Cho concentrations is not adequate as plasma choline is homeostatically regulated. Based on extensive preliminary and published data this group identified a panel of potential biomarkers that could be used to assess Cho status, and now the investigators propose to validate this biomarker panel against measures of Cho pool size using isotope dilution. The largest stores of Cho are located in the liver, and mass resonance spectroscopy (MRS) of liver has been used in the past to assess Cho status in humans. This method is not practical for use as a biomarker in clinical or public health practice as it is expensive and the availability of the instrumentation is limited. However, the MRS can be utilized to confirm correlations between the biomarker panel and the isotope dilution method. Liver biopsy is risky and not practical, making measurement of hepatic Cho and Cho metabolites concentrations a poor choice for assessing Cho status. Perhaps there is a panel of biomarkers that together will more accurately and reliably reflect Cho status. By making measurements in people fed 3 different dietary amounts of Cho for two weeks at a time, and comparing the biomarker measures to body total Cho pool size assessed using isotope dilution (a proxy for the availability of the various forms of Cho), investigators will be able to identify the combination of biomarkers and algorithm for calculating a Cho status score that best predicts total Cho pool size, and therefore predicts choline nutritional status (the availability of the various forms of Cho needed to sustain cellular function). People who eat diets low in choline should deplete their choline (Cho) stores, and measurement of Cho pool size using isotope dilution should reflect this depletion. The investigators will identify a biomarker panel that correlates well with measured Cho pool size across the range of different degrees of depletion. This study tests a method for using stable isotope dilution to measure body choline stores, and then asks how this measure correlates with a panel of biomarkers in plasma and with liver fat measured using Fibroscan®. Using isotope dilution can provide an estimate of the size of the body pool of Cho. The investigators' proposed method is conceptually similar to the method for measuring total body water from a bolus dose of labeled water. Similar methodology was used recently in studies of metabolic flux of Cho in pregnant women. Isotope dilution is a well-established method used to estimate pool size for other nutrients, such as vitamin A. Similar to vitamin A, the major storage pools for Cho are in the liver, and ingested Cho is rapidly absorbed and accumulated by liver. MRS/MRI scans will also be performed to investigate correlation between these "gold standard" measures and the other methods described above. Participants will consume meals provided in two week dietary intervals with 3 different levels of choline with a 2 week washout periods between those dietary intervals. Participants will receive 100% of the recommended intake (RDI) of Cho (550mg Cho/day); 50% of the RDI of Cho (275mg/day); and 25% of the RDI of Cho (137.5mg/day). The meal order will be randomly assigned and all participants will receive all diets at some point in the study. There will be a minimum of a two week washout between diet intervals. Both participants and researchers will be blinded to the diet order. Participants will have brief exercise challenges (Biodex) to assess muscle function as an additional predictor of choline status. Participants enrolled prior to 3/2020 completed MRI/MRS scans. We have determined that Fibroscan provides adequate measurement of liver fat such that we eliminated the added inconvenience to participants of travel to Winston-Salem for MR scanning. Saliva, stool, and urine samples will be collected.
Subjects will consume meals containing 25% of recommended intake of Choline for 2 weeks. On day 12 of the diet period, subjects will consume 250 mg of Cho in the form of Cho chloride (trimethyl-d9, 9%), Cambridge Isotope Laboratories, Tewksbury, Massachusetts, (USA), as a bolus.
Subjects will consume meals containing 50% of recommended intake of Choline for 2 weeks. On day 12 of the diet period, subjects will consume 250 mg of Cho in the form of Cho chloride (trimethyl-d9, 9%), Cambridge Isotope Laboratories, Tewksbury, Massachusetts, (USA), as a bolus.
Subjects will consume meals containing 100% of recommended intake of Choline for 2 weeks. On day 12 of the diet period, subjects will consume 250 mg of Cho in the form of Cho chloride (trimethyl-d9, 9%), Cambridge Isotope Laboratories, Tewksbury, Massachusetts, (USA), as a bolus.
UNC Chapel Hill Nutrition Research Institute
Kannapolis, North Carolina, United States
Ratio of Liver Choline Pool Size by Isotope Dilution
The liver choline pool determined by the dilution of the deuterated choline metabolites formed in liver and released to plasma as measured by isotopic enrichment ratio (IER). The IER for a given metabolite is defined as the concentration of a deuterated metabolite divided by the sum of deuterated and non-deuterated metabolite.
Time frame: 24 hours following administration of choline-d9 on day 12 of respective dietary intervention
Difference in Choline Deficiency Signature
Plasma choline metabolites (micromolar): choline, dimethylglycine, betaine, phosphatidylcholine, sphingomyelin, trimethylamine-oxide, and homocysteine measured by targeted metabolomic profiling. The signature for choline deficiency is defined by choline \<0.793 mmol/L or betaine \<34.9 mmol/L. The levels of these metabolites at the end of each intervention will be compared. The association between choline metabolites and choline pool size will be investigated.
Time frame: At the end of 2 weeks of respective Cho diet
Comparison of Choline Pool Size Between Participants With and Without Choline Metabolites Signature During Cho Depletion
The 25% Cho arm was selected because only at that intake level is sufficient depletion achieved. Participants with plasma choline \<0.793 mmol/L or betaine \<34.9 mmol/L were considered as choline depleted (showing signature), participants with plasma choline \>=0.793 mmol/L and betaine \>=34.9 mmol/L were considered as not choline depleted (not showing signature). Available choline pool size was determined by the dilution of the deuterated choline metabolites formed in liver and released to plasma as measured by isotopic enrichment ratio (IER). The IER for a given metabolite is defined as the concentration of a deuterated metabolite divided by the sum of deuterated and non-deuterated metabolite.
Time frame: 24 hours following administration of choline-d9 on day 12 of 25% Cho diet
Ion Abundance (Intensity) of Metabolites as Indicators of the Intake of 25%, 50%, or 100% Choline in the Diet. The Ratio of the Intensity of Metabolite Signals for Each Dietary Group Can be Calculated and Correlated With the Level of Choline in the Diet
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Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
SCREENING
Masking
TRIPLE
Enrollment
101
Metabolomics was conducted on plasma that was collected from individuals at the end of each 2-week diet period. UHPLC High Resolution Mass Spectrometry was used for differential profiling (PMID: 33415121). Supervised Orthogonal Partial Least Squares Discriminant Analysis was used to determine signals that differentiated the 25% choline dietary group from the 100% choline dietary group. Metabolites that differentiated the 25% and 100% choline dietary groups with variable importance to projection (VIP) \>1 and p-value \< 0.05 are reported. The signals for these metabolites were matched by retention time, exact mass, and MS/MS to standards run on the same platform. Because this is a differential profiling method (not quantitative), the mean and standard deviation of peak intensities detected on the untargeted platform are reported. Results are reported for the selected metabolites for the 25%, 50%, and 100% choline dietary groups. Ratios can be obtained by division of the intensity data.
Time frame: At the end of 2 weeks of respective Cho diet
Comparison of Choline Pool Size Between Participants With Different Genotypes in Phosphatidylethanolamine-N-methyltransferase (PEMT) Single Nucleotide Polymorphism (SNP rs12325817)
DNA was collected and evaluated for the presence of the PEMT SNP rs12325817. Genotypes was measured by real time polymerase chain reaction (RT-PCR). The magnitude of changes in choline pool size as measured by IER at the end of each dietary intervention was compared among subjects with different genotypes in the PEMT SNP. Linear mixed model with repeated measures was performed for each group (healthy males, pre- and postmenopausal females) separately to study the genotype effect and genotype x diet interaction effect on choline pool size.
Time frame: 24 hours following administration of choline-d9 on day 12 of respective dietary intervention
Change in Liver Fat Content Based on CAP Values
Controlled attenuation parameter (CAP) as measured by Fibroscan is an ultrasound-based technique to measure liver fat. This method will be used with other biomarkers to indicate functional signs of choline status.
Time frame: Day 1 and Day 15 of respective Cho diet
Validation of Isotope Dilution Method to Assess Choline Pool Size by Magnetic Resonance Spectroscopy (MRS)
MRS is a direct measurement of liver choline content. Changes in liver choline by MRS should correlate with changes in liver choline inferred by calculation of isotope enrichment ratio (IER) of plasma metabolites. Pearson correlation coefficient used to study the correlation between data generated from the two types of measurements.
Time frame: At the end of 2 weeks of respective Cho diet