sar: a genetic mouse model for human sarcosinemia generated by ethylnitrosourea mutagenesis.

Harding, Cary O.; Williams, Phillip; Pflanzer, Denise M.; Colwell, Robert E.; Lyne, Paul; Wolff, Jon A.

doi:10.1073/pnas.89.7.2644

Cited by 21 publications

(9 citation statements)

References 24 publications

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“…5). The localization of the SDH gene to human chromosome 9q34 is consistent with genetic studies with a mouse model for sarcosinemia that map the mouse gene to a region of mouse chromosome 2 that is syntenic with human 9q33-q34 (Brunialti et al, 1996;Harding et al, 1992).…”

Section: Chromosomal Location and Organization Of The Sarcosine Dehydsupporting

confidence: 75%

“…SDH is defective in patients with sarcosinemia, a rare autosomal metabolic defect characterized by elevated levels of sarcosine in blood and urine (Scott, 1995). Genetic studies with a mouse model for sarcosinemia have mapped the gene to a region of mouse chromosome 2 syntenic with human chromosome 9q33-q34 (Brunialti et al, 1996;Harding et al, 1992).…”

Section: Introductionmentioning

confidence: 99%

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Cloning and Mapping of the cDNA for Human Sarcosine Dehydrogenase, a Flavoenzyme Defective in Patients with Sarcosinemia

Eschenbrenner

Jörns

1999

Genomics

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Section: Chromosomal Location and Organization Of The Sarcosine Dehydsupporting

confidence: 75%

Section: Introductionmentioning

confidence: 99%

Cloning and Mapping of the cDNA for Human Sarcosine Dehydrogenase, a Flavoenzyme Defective in Patients with Sarcosinemia

Eschenbrenner

Jörns

1999

Genomics

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“…Mutagenesis and Metabolic Screening Protocol-Male C57Bl/6J mice were treated with 50 mg/kg body weight ENU weekly for a total of three doses according to the method of King et al (14). Breeding and metabolic screening of potentially mutant progeny was carried out as described previously (13). Urine samples were collected on filter paper from all G 3 progeny after weaning (21-28 days of age) following an overnight fast.…”

Section: Methodsmentioning

confidence: 99%

“…To this end, we screen the progeny of ENU-treated mice for metabolic abnormalities using a variety of urine biochemical analyses. Using this protocol, we have previously isolated a mouse strain with recessively inherited sarcosine dehydrogenase deficiency (13). In this report, we describe a genetic mouse model of autosomal recessively inherited ␥-GT deficiency developed by random mutagenesis using ENU.…”

mentioning

confidence: 99%

Mice with Genetic γ-Glutamyl Transpeptidase Deficiency Exhibit Glutathionuria, Severe Growth Failure, Reduced Life Spans, and Infertility

Harding¹,

Williams²,

Wagner³

et al. 1997

Journal of Biological Chemistry

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A mouse mutant with glutathionuria was discovered by screening for amino acidurias in the progeny of ethylnitrosourea-mutagenized mice. Total glutathione concentration was increased in both blood and urine but decreased in liver homogenates from affected mice. Glutathionuric mice exhibited lethargy, severe growth failure, shortened life spans and infertility. ␥-Glutamyl transpeptidase activity was deficient in kidney homogenates of glutathionuric mice. The glutathionuric phenotype in these mice is inherited as an autosomal recessive trait. This mouse mutant will be a useful animal model for the study of ␥-glutamyl transpeptidase physiology and glutathione metabolism.GSH is the most abundant cellular thiol and functions as the principal reducing reagent in all cell types (1). A partial listing of the antioxidative functions of GSH include: protection against mitochondrial damage, protection against oxygen toxicity in the lung, protection against lipid peroxidation, detoxification of electrophilic compounds through conjugation, preservation of proper sulfide bonds in proteins, a postulated function in anticarcinogenesis, and a role in the immune system (2). GSH metabolism also provides a source of cysteine for cells (3). ␥-Glutamyl transpeptidase (␥-GT; EC 2.3.2.2) 1 catalyzes the initial step in the degradation of GSH (4). ␥-GT is a key step in the ␥-glutamyl cycle (5), a series of degradative and synthetic reactions that mediate cellular GSH metabolism. Several reviews of ␥-GT physiology and function have been published (4 -6), but despite intensive investigation, the exact role ␥-GT plays in GSH metabolism or its putative contribution to renal amino acid transport have not been definitively determined. Bound to secretory endothelial cell membranes in several organs but predominantly in proximal renal tubule cells, ␥-GT participates in the transmembrane transport of GSH and in interorgan GSH exchange ( Fig. 1) (7). Meister (8) proposed that ␥-GT also contributes to amino acid transport in the proximal renal tubule through transpeptidation of GSH and subsequent tubule cell uptake of ␥-glutamyl amino acids. In vivo model systems that have lost ␥-GT activity are an exquisitely powerful tool for the study of ␥-GT function and its relationship to GSH metabolism. Administration of chemical inhibitors of ␥-GT to animals results in both glutathionuria and glutathionemia (9), but chemically treated animal models are limited by several drawbacks including the temporary nature of inhibition and the difficulty of long-term continuous inhibitor administration. Also, the degree and specificity of enzyme inhibition in various tissues (particularly the brain) of these chemically treated animals is unknown. Genetic ␥-GT deficiency has been described in only five humans (6), and the effects of various different disease states or environmental influences upon ␥-GT deficient individuals cannot be adequately evaluated given the rarity of the disorder. A genetic animal model of total ␥-GT deficiency overcomes the limitations of previ...

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“…While this autosomal recessive defect does not significantly correlate with any severe symptom, it has been often detected in children displaying mental retardation and growth problems [13,15,16]. Recently, a mouse model for sarcosinemia has been developed [17]. Like in the human disease, the sar mouse strain is devoid of SarDH activity and displays high levels of sarcosine in plasma and urine.…”

mentioning

confidence: 99%

Molecular cloning and tissue distribution of rat sarcosine dehydrogenase

Bergeron

Otto

Blache

et al. 1998

European Journal of Biochemistry

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Sarcosine dehydrogenase (SarDH) is a mitochondrial flavoenzyme involved in the oxidative degradation of choline to glycine. The absence of SarDH activity in humans is genetically transmitted and is the cause of an amino acid metabolism disorder called sarcosinemia. Tryptic fragments of the purified enzyme from rat liver were subjected to Edman degradation and the sequences obtained were used to clone the cDNA encoding the full length protein. The deduced amino acid sequence of SarDH shares an overall similarity of 47% with dimethylglycine dehydrogenase (Me 2 GlyDH), another flavoenzyme involved in the mitochondrial choline catabolism with a similar FAD-binding domain. Covalent binding of FAD to SarDH was demonstrated by the observation of strong fluorescence at 530 nm under excitation at 450 nm of the enzyme immunoprecipitated under denaturing conditions from liver extracts. The localization of SarDH immunoreactivity in the mitochondrial matrix was confirmed by Western-blot analysis of purified mitochondrial fractions. Finally, the tissue distribution of SarDH was investigated by Northern-blot analysis of total RNA and Western-blot analysis of total protein from several rat tissues. A strong expression in the liver, but also in the lung, pancreas, kidney, thymus, and oviduct was observed. We therefore suggest that the enzymes of the choline catabolism pathway are important also for metabolism in nonhepatic tissues.

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sar: a genetic mouse model for human sarcosinemia generated by ethylnitrosourea mutagenesis.

Cited by 21 publications

References 24 publications

Cloning and Mapping of the cDNA for Human Sarcosine Dehydrogenase, a Flavoenzyme Defective in Patients with Sarcosinemia

Cloning and Mapping of the cDNA for Human Sarcosine Dehydrogenase, a Flavoenzyme Defective in Patients with Sarcosinemia

Mice with Genetic γ-Glutamyl Transpeptidase Deficiency Exhibit Glutathionuria, Severe Growth Failure, Reduced Life Spans, and Infertility

Molecular cloning and tissue distribution of rat sarcosine dehydrogenase

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