BACKGROUND: Arginine is required for the detoxification of ammonia and the synthesis of proteins, nitric oxide, agmatine, creatine, and polyamines, and it may promote lymphocyte function. In suckling mammals, arginine is synthesized in the enterocytes of the small intestine, but this capacity is lost after weaning. OBJECTIVE: We investigated the significance of intestinal arginine production for neonatal development in a murine model of chronic arginine deficiency. DESIGN: Two lines of transgenic mice that express different levels of arginase I in their enterocytes were analyzed. RESULTS: Both lines suffer from a selective but quantitatively different reduction in circulating arginine concentration. The degree of arginine deficiency correlated with the degree of retardation of hair and muscle growth and with the development of the lymphoid tissue, in particular Peyer's patches. Expression of arginase in all enterocytes was necessary to elicit this phenotype. Phenotypic abnormalities were reversed by daily injections of arginine but not of creatine. The expression level of the very arginine-rich skin protein trichohyalin was not affected in transgenic mice. Finally, nitric oxide synthase-deficient mice did not show any of the features of arginine deficiency. CONCLUSIONS: Enterocytes are important for maintaining arginine homeostasis in neonatal mice. Graded arginine deficiency causes graded impairment of skin, muscle, and lymphoid development. The effects of arginine deficiency are not mediated by impaired synthesis of creatine or by incomplete charging of arginyl-transfer RNA.
BACKGROUND:Arginine is required for the detoxification of ammonia and the synthesis of proteins, nitric oxide, agmatine, creatine, and polyamines, and it may promote lymphocyte function. In suckling mammals, arginine is synthesized in the enterocytes of the small intestine, but this capacity is lost after weaning. OBJECTIVE: We investigated the significance of intestinal arginine production for neonatal development in a murine model of chronic arginine deficiency. DESIGN: Two lines of transgenic mice that express different levels of arginase I in their enterocytes were analyzed. RESULTS: Both lines suffer from a selective but quantitatively different reduction in circulating arginine concentration. The degree of arginine deficiency correlated with the degree of retardation of hair and muscle growth and with the development of the lymphoid tissue, in particular Peyer's patches. Expression of arginase in all enterocytes was necessary to elicit this phenotype. Phenotypic abnormalities were reversed by daily injections of arginine but not of creatine. The expression level of the very arginine-rich skin protein trichohyalin was not affected in transgenic mice. Finally, nitric oxide synthase-deficient mice did not show any of the features of arginine deficiency. CONCLUSIONS: Enterocytes are important for maintaining arginine homeostasis in neonatal mice. Graded arginine deficiency causes graded impairment of skin, muscle, and lymphoid development. The effects of arginine deficiency are not mediated by impaired synthesis of creatine or by incomplete charging of arginyl-transfer RNA.
Authors: Ibraim C Castro; Bruna B Oliveira; Jacek J Slowikowski; Bruna P Coutinho; Francisco Júlio W S Siqueira; Lourrany B Costa; Jesus Emmanuel Sevilleja; Camila A Almeida; Aldo A M Lima; Cirle A Warren; Reinaldo B Oriá; Richard L Guerrant Journal: Nutrition Date: 2012-01-20 Impact factor: 4.008
Authors: Carlos J Perez; Jean Jaubert; Jean-Louis Guénet; Kirstin F Barnhart; Catherine M Ross-Inta; Vicente C Quintanilla; Isabelle Aubin; Jimi L Brandon; Nancy W Otto; John DiGiovanni; Irma Gimenez-Conti; Cecilia Giulivi; Donna F Kusewitt; Claudio J Conti; Fernando Benavides Journal: Am J Pathol Date: 2010-08-19 Impact factor: 4.307
Authors: Vincent Marion; Selvakumari Sankaranarayanan; Chiel de Theije; Paul van Dijk; Patrick Lindsey; Marinus C Lamers; Heather P Harding; David Ron; Wouter H Lamers; S Eleonore Köhler Journal: J Biol Chem Date: 2011-01-14 Impact factor: 5.157
Authors: Wouter J de Jonge; Karin L Kwikkers; Anje A te Velde; Sander J H van Deventer; Martijn A Nolte; Reina E Mebius; Jan M Ruijter; Marinus C Lamers; Wouter H Lamers Journal: J Clin Invest Date: 2002-11 Impact factor: 14.808
Authors: W Wei; X Xiao; J Li; H Ding; W Pan; S Deng; W Yin; L Xue; Q Lu; Y Yue; Y Tian; M Wang; L Hao Journal: J Dent Res Date: 2019-08 Impact factor: 6.116
Authors: Ayelet Erez; Sandesh C S Nagamani; Oleg A Shchelochkov; Muralidhar H Premkumar; Philippe M Campeau; Yuqing Chen; Harsha K Garg; Li Li; Asad Mian; Terry K Bertin; Jennifer O Black; Heng Zeng; Yaoping Tang; Anilkumar K Reddy; Marshall Summar; William E O'Brien; David G Harrison; William E Mitch; Juan C Marini; Judy L Aschner; Nathan S Bryan; Brendan Lee Journal: Nat Med Date: 2011-11-13 Impact factor: 53.440
Authors: Vanesa Muncan; Jarom Heijmans; Stephen D Krasinski; Nikè V Büller; Manon E Wildenberg; Sander Meisner; Marijana Radonjic; Kelly A Stapleton; Wout H Lamers; Izak Biemond; Marius A van den Bergh Weerman; Dónal O'Carroll; James C Hardwick; Daniel W Hommes; Gijs R van den Brink Journal: Nat Commun Date: 2011-08-30 Impact factor: 14.919
Authors: Vincent Marion; Selvakumari Sankaranarayanan; Chiel de Theije; Paul van Dijk; Theo B M Hakvoort; Wouter H Lamers; Eleonore S Köhler Journal: PLoS One Date: 2013-06-13 Impact factor: 3.240