Transport of Dibasic Amino Acids, Cystine, and Tryptophan by Cultured Human Fibroblasts: Absence of a Defect in Cystinuria and Hartnup Disease

Overview

Journal J Clin Invest

Specialty General Medicine

Date 1972 Aug 1

PMID 5054467

Citations 10

Authors

U Groth

L E ROSENBERG

Affiliations

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Abstract

Transport of lysine, arginine, cystine, and tryptophan was studied in cultured skin fibroblasts from normal controls and from patients with cystinuria and Hartnup disease. Each of these amino acids was accumulated against concentration gradients by energy-dependent, saturable mechanisms. Lysine and arginine were each transported by two distinct processes which they shared with each other and with ornithine. In contrast, cystine was taken up by a different transport system with no demonstrable affinity for the dibasic amino acids. The time course and Michaelis-Menten kinetics of lysine and cystine uptake by cells from three cystinuric patients differed in no way from those found in control cells. Similarly, the characteristics of tryptophan uptake by cells from a child with Hartnup disease were identical to those noted in control cells. These findings indicate that the specific transport defects observed in gut and kidney in cystinuria and Hartnup disease are not expressed in cultured human fibroblasts, thus providing additional evidence of the important role that cellular differentiation plays in the regulation of expression of the human genome.

Citing Articles

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A candidate mouse model for Hartnup disorder deficient in neutral amino acid transport.

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Glycine transport by cultured skin fibroblasts from a patient with isolated hyperglycinuria.

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Studies on the pathway from ornithine to proline in cultured skin fibroblasts with reference to the defect in hyperornithinaemia with hyperammonaemia and homocitrullinuria.

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Uptake and utilization of exogenous cystine by cystinotic and normal fibroblasts.

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