Your search keyword '"Nelson S. Yew"' showing total 2 results

1. Excretion of excess nitrogen and increased survival by loss of <scp>SLC6A19</scp> in a mouse model of ornithine transcarbamylase deficiency

Author

Adam J. Belanger, Estelle Gefteas, Malgorzata Przybylska, Sarah Geller, Gülbenk Anarat‐Cappillino, Alla Kloss, and Nelson S. Yew

Subjects

Genetics, Genetics (clinical)

Abstract

Protein catabolism ultimately yields toxic ammonia, which must be converted to urea by the liver for renal excretion. In extrahepatic tissues, ammonia is temporarily converted primarily to glutamine for subsequent hepatic extraction. Urea cycle disorders (UCDs) are inborn errors of metabolism causing impaired ureagenesis, leading to neurotoxic accumulation of ammonia and brain glutamine. Treatment includes dietary protein restriction and oral "ammonia scavengers." These scavengers chemically combine with glutamine and glycine to yield excretable products, creating an alternate pathway of waste nitrogen disposal. The amino acid transporter SLC6A19 is responsible for95% of absorption and reabsorption of free neutral amino acids in the small intestine and kidney, respectively. Genetic SLC6A19 deficiency causes massive neutral aminoaciduria but is typically benign. We hypothesized that inhibiting SLC6A19 would open a novel and effective alternate pathway of waste nitrogen disposal. To test this, we crossed SLC6A19 knockout (KO) mice with spf

Published

2022

2. Comparison of Microflow and Analytical Flow Liquid Chromatography Coupled to Mass Spectrometry Global Metabolomics Methods Using a Urea Cycle Disorder Mouse Model

Author

Nelson S. Yew, Alla Kloss, Adam J. Belanger, Sarah Geller, Alexander R. Ivanov, and Harvey Lieberman

Subjects

Analyte, Chromatography, Urea cycle disorder, Chemistry, General Chemistry, medicine.disease, Mass spectrometry, Biochemistry, Mass Spectrometry, Article, Mice, Metabolomics, Liquid chromatography–mass spectrometry, Solvents, medicine, Mouse Urine, Animals, Urea Cycle Disorders, Inborn, METABOLIC FEATURES, Microscale chemistry, Chromatography, Liquid

Abstract

Microscale-based separations are increasingly being applied in the field of metabolomics for the analysis of small-molecule metabolites. These methods have the potential to provide improved sensitivity, less solvent waste, and reduced sample-size requirements. Ion-pair free microflow-based global metabolomics methods, which we recently reported, were further compared to analytical flow ion-pairing reagent containing methods using a sample set from a urea cycle disorder (UCD) mouse model. Mouse urine and brain homogenate samples representing healthy, diseased, and disease-treated animals were analyzed by both methods. Data processing was performed using univariate and multivariate techniques followed by analyte trend analysis. The microflow methods performed comparably to the analytical flow ion-pairing methods with the ability to separate the three sample groups when analyzed by partial least-squares analysis. The number of detected metabolic features present after each data processing step was similar between the microflow-based methods and the ion-pairing methods in the negative ionization mode. The observed analyte trend and coverage of known UCD biomarkers were the same for both evaluated approaches. The 12.5-fold reduction in sample injection volume required for the microflow-based separations highlights the potential of this method to support studies with sample-size limitations.

Published

2021