Your search keyword '"Cederbaum S"' showing total 14 results

1. Arginase activity in human breast cancer cell lines: N(omega)-hydroxy-L-arginine selectively inhibits cell proliferation and induces apoptosis in MDA-MB-468 cells.

Author

Singh R, Pervin S, Karimi A, Cederbaum S, and Chaudhuri G

Subjects

Arginase biosynthesis, Arginine pharmacology, Blotting, Western, Caspase 3, Caspases metabolism, Cell Cycle drug effects, Cell Division drug effects, DNA Fragmentation drug effects, Enzyme Inhibitors pharmacology, Flow Cytometry, Humans, In Situ Nick-End Labeling, Nitric Oxide metabolism, Nitric Oxide Synthase biosynthesis, Ornithine pharmacology, Reverse Transcriptase Polymerase Chain Reaction, Spermine metabolism, Tumor Cells, Cultured, Apoptosis drug effects, Arginase metabolism, Arginine analogs & derivatives, Breast Neoplasms enzymology

Abstract

L-Arginine is the common substrate for two enzymes, arginase and nitric oxide synthase (NOS). Arginase converts L-arginine to L-ornithine, which is the precursor of polyamines, which are essential components of cell proliferation. NOS converts L-arginine to produce NO, which inhibits proliferation of many cell lines. Various human breast cancer cell lines were initially screened for the presence of arginase and NOS. Two cell lines, BT-474 and MDA-MB-468, were found to have relatively high arginase activity and very low NOS activity. Another cell line, ZR-75-30, had the highest NOS activity and comparatively low arginase activity. The basal proliferation rates of MDA-MB-468 and BT-474 were found to be higher than the ZR-75-30 cell line. N-Hydroxy-L-arginine (NOHA), a stable intermediate product formed during conversion of L-arginine to NO, inhibited proliferation of the high arginase-expressing MDA-MB-468 cells and induced apoptosis after 48 h. NOHA arrested these cells in the S phase, increased the expression of p21, and reduced spermine content. These effects of NOHA were not observed in the ZR-75-30 cell line, which expresses high NOS and relatively low arginase. The effects of NOHA were antagonized in the presence of L-ornithine (500 microM), which suggests that in MDA-MB-468 cell line, the arginase pathway is very important for cell proliferation. Inhibition of the arginase pathway led to depletion of intracellular spermine and apoptosis as observed by terminal deoxynucleotidyl transferase (Tdt)-mediated nick end labeling assay and induction of caspase 3. In contrast, the ZR-75-30 cell line maintained its viability and its L-ornithine and spermine levels in the presence of NOHA. We conclude that NOHA has antiproliferative and apoptotic actions on arginase-expressing human breast cancer cells that are independent of NO.

Published

2000

2. Molecular basis of hyperargininemia: structure-function consequences of mutations in human liver arginase.

Author

Ash DE, Scolnick LR, Kanyo ZF, Vockley JG, Cederbaum SD, and Christianson DW

Subjects

Amino Acid Metabolism, Inborn Errors enzymology, Animals, Arginase chemistry, Binding Sites, Biopolymers, Humans, Molecular Structure, Rats, Amino Acid Metabolism, Inborn Errors genetics, Arginase genetics, Arginine blood, Liver enzymology, Mutation

Abstract

Hyperargininemia is a rare autosomal recessive disorder that results from a deficiency of hepatic type I arginase. At the genetic level, this deficiency in arginase activity is a consequence of random point mutations throughout the gene that lead to premature termination of the protein or to substitution mutations. Given the high degree of sequence homology between human liver and rat liver enzymes, we have mapped both patient and nonpatient mutations of the human enzyme onto the structure of the rat liver enzyme to rationalize the molecular basis for the low activities of these mutant arginases. Mutations identified in hyperargininemia patients affect the structure and function of the enzyme by compromising active-site residues, packing interactions in the protein scaffolding, and/or quaternary structure by destabilizing the assembly of the arginase trimer., (Copyright 1998 Academic Press.)

Published

1998

3. The human arginases and arginase deficiency.

Author

Iyer R, Jenkinson CP, Vockley JG, Kern RM, Grody WW, and Cederbaum S

Subjects

Amino Acid Metabolism, Inborn Errors genetics, Amino Acid Metabolism, Inborn Errors therapy, Amino Acid Sequence, Animals, Arginase blood, Arginase metabolism, Cell Line, Humans, Isoenzymes blood, Isoenzymes deficiency, Isoenzymes genetics, Molecular Sequence Data, Amino Acid Metabolism, Inborn Errors enzymology, Arginase genetics, Arginine blood, Hyperargininemia

Abstract

Arginase is the final enzyme in the urea cycle. Its deficiency is the least frequently described disorder of this cycle. It results primarily in elevated blood arginine, and less frequently in either persistent or acute elevations in blood ammonia. This appears to be due to a second arginase locus, expressed primarily in the kidney, which can be recruited to compensate, in part, for the deficiency of liver arginase. The liver arginase gene structure permitted study of the molecular pathology of patients with the disorder and the results of these studies and the inferences about the protein structure are presented. The conserved regions among all arginases allowed the cloning of AII, the second arginase isoform. It has been localized to the mitochondrion and is thought to be involved in ornithine biosynthesis. It shares the major conserved protein sequences, and structural features of liver arginase gene are also conserved. When AI and AII from various species are compared, it appears that the two diverged some time prior to the evolution of amphibians. The evidence for the role of AII in nitric oxide and polyamine metabolism is presented and this appears consonant with the data on the tissue distribution.

Published

1998

4. Arginase activity in endothelial cells: inhibition by NG-hydroxy-L-arginine during high-output NO production.

Author

Buga GM, Singh R, Pervin S, Rogers NE, Schmitz DA, Jenkinson CP, Cederbaum SD, and Ignarro LJ

Subjects

Animals, Arginine pharmacology, Cells, Cultured, Citrulline biosynthesis, Endothelium, Vascular cytology, Enzyme Induction, Male, Rats, Rats, Sprague-Dawley, Urea antagonists & inhibitors, Urea metabolism, Arginase antagonists & inhibitors, Arginase metabolism, Arginine analogs & derivatives, Endothelium, Vascular metabolism, Nitric Oxide biosynthesis

Abstract

Rat aortic endothelial cells were found to contain both constitutive and lipopolysaccharide (LPS)-inducible arginase activity. Studies were performed to determine whether induction of nitric oxide synthase (NOS) by LPS and cytokines is accompanied by sufficient arginase induction to render arginine concentrations rate limiting for high-output NO production. Unactivated cells contained abundant arginase activity accompanied by continuous urea formation. LPS induced the formation of both inducible NOS (iNOS) and arginase, and this was accompanied by increased production of NO, citrulline, and urea. Immunoprecipitation experiments revealed the constitutive presence of arginase-I in both unactivated and LPS-activated cells and arginase-II induction by LPS. Arginase-I and iNOS were verified by reverse transcriptase-polymerase chain reaction. Induction of large amounts of iNOS by LPS plus several cytokines resulted in large quantities of NO, citrulline, and NG-hydroxy-L-arginine (NOHA), but urea production was markedly diminished. Decreased urea production was attributed to increased formation of NOHA, the precursor to NO and citrulline and a potent inhibitor of arginase-I activity with an inhibitory constant of 10-12 microM. Inhibition of iNOS activity by NG-methyl-L-arginine decreased NO and NOHA production and increased urea production. This study reveals for the first time that substantial arginase activity is present constitutively in rat aortic endothelial cells, a different isoform of arginase is induced by LPS, and intracellular arginase activity can be markedly inhibited during cytokine induction of iNOS because of NOHA formation. The inhibition of arginase activity that occurs by NOHA during marked iNOS induction may be a mechanism to ensure sufficient arginine availability for high-output production of NO.

Published

1996

5. Identification of mutations (D128G, H141L) in the liver arginase gene of patients with hyperargininemia.

Author

Vockley JG, Tabor DE, Kern RM, Goodman BK, Wissmann PB, Kang DS, Grody WW, and Cederbaum SD

Subjects

Amino Acid Metabolism, Inborn Errors enzymology, Amino Acid Sequence, Conserved Sequence, Exons, Humans, Hyperargininemia, Molecular Sequence Data, Polymerase Chain Reaction, Sequence Analysis, DNA, Amino Acid Metabolism, Inborn Errors genetics, Arginase genetics, Arginine blood, Liver enzymology, Point Mutation

Published

1994

6. The pathobiochemistry of uremia and hyperargininemia further demonstrates a metabolic relationship between urea and guanidinosuccinic acid.

Author

Marescau B, De Deyn PP, Qureshi IA, De Broe ME, Antonozzi I, Cederbaum SD, Cerone R, Chamoles N, Gatti R, and Kang SS

Subjects

Adult, Aged, Aged, 80 and over, Arginine metabolism, Female, Guanidines metabolism, Humans, Kidney Diseases blood, Kidney Diseases metabolism, Male, Metabolism, Inborn Errors metabolism, Middle Aged, Succinates metabolism, Urea metabolism, Uremia metabolism, Arginine blood, Guanidines blood, Metabolism, Inborn Errors blood, Succinates blood, Urea blood, Uremia blood

Abstract

To better understand the biosynthesis of guanidinosuccinic acid, we determined urea, arginine, and guanidinosuccinic acid levels in nondialyzed uremic and hyperargininemic patients. These substances were also determined during several years of therapy in one hyperarginiemic patient. Interrelationships of guanidinosuccinic acid levels with their corresponding urea and arginine levels were assessed by linear correlation studies. In uremic patients, a significant positive linear correlation (r = .821, p less than .001) was found between serum urea and guanidinosuccinic acid levels A significant positive linear correlation was also found between serum urea levels and urinary guanidinosuccinic acid levels (r = .828, P less than .001), but not between serum arginine levels and urinary guanidinosuccinic acid levels in hyperargininemic patients. In the intrahyperargininemic patient study, a similar significant positive correlation was found between serum urea levels and the corresponding urinary guanidinosuccinic acid levels (r = .866, P less than .001); the correlation between serum arginine levels and the corresponding urinary guanidinosuccinic acid levels was smaller. The presented analytical findings in uremic and hyperargininemic patients clearly demonstrate a metabolic relationship between urea and guanidinosuccinic acid.

Published

1992

7. Guanidino compound analysis as a complementary diagnostic parameter for hyperargininemia: follow-up of guanidino compound levels during therapy.

Author

Marescau B, De Deyn PP, Lowenthal A, Qureshi IA, Antonozzi I, Bachmann C, Cederbaum SD, Cerone R, Chamoles N, and Colombo JP

Subjects

Adolescent, Adult, Amino Acid Metabolism, Inborn Errors blood, Amino Acid Metabolism, Inborn Errors cerebrospinal fluid, Amino Acid Metabolism, Inborn Errors urine, Arginine cerebrospinal fluid, Arginine urine, Child, Child, Preschool, Guanidines blood, Guanidines cerebrospinal fluid, Guanidines urine, Homoarginine blood, Homoarginine cerebrospinal fluid, Homoarginine urine, Humans, Infant, Amino Acid Metabolism, Inborn Errors diagnosis, Arginine blood, Guanidines analysis, Hyperargininemia

Abstract

The aim of this collaborative study was to investigate whether guanidino compound analyses in the biologic fluids can be used as a complementary diagnostic parameter for hyperargininemia. Guanidino compounds were determined in the biologic fluids of all known living hyperargininemic patients using a cation exchange chromatographic system with a fluorescence detection method. The serum arginine, homoarginine, alpha-keto-delta-guanidino-valeric acid, argininic acid, and N-alpha-acetylarginine levels of all the hyperargininemic patients are higher than the normal range. Similar increases were seen for the urinary excretion of alpha-keto-delta-guanidinovaleric acid and argininic acid. Untreated hyperargininemic patients have the highest guanidino compound levels in cerebrospinal fluid. However, even under therapy, the arginine, homoarginine, alpha-keto-delta-guanidinovaleric acid, and argininic acid levels in cerebrospinal fluid are still increased. Protein restriction alone is not sufficient to normalize the hyperargininemia, but protein restriction together with supplementation of essential amino acids with or without sodium benzoate decreases further the arginine levels. However, whereas the argininemia can be normalized, the catabolites of arginine are still increased. We conclude that the urinary amino acid levels may remain normal in hyperargininemia, whereas consistent increases of the guanidino compounds are observed. Thus, guanidino compound analyses can be used as a complementary biochemical diagnostic parameter for hyperargininemia. Although the argininemia can be normalized by therapy, the levels of the catabolites of arginine are still elevated.

Published

1990

8. Treatment of hyperargininaemia due to arginase deficiency with a chemically defined diet.

Author

Cederbaum SD, Moedjono SJ, Shaw KN, Carter M, Naylor E, and Walzer M

Subjects

Adolescent, Amino Acids administration & dosage, Amino Acids cerebrospinal fluid, Arginine cerebrospinal fluid, Child, Female, Humans, Male, Amino Acid Metabolism, Inborn Errors diet therapy, Arginine blood, Food, Formulated, Hyperargininemia

Abstract

A brother and sister aged 11 and 17 years have been reported previously to have hyperargininaemia and arginase deficiency: they were treated with a semi-synthetic diet consisting of fat, carbohydrate, minerals, vitamins and essential amino acids in amounts equivalent to 0.55-0.65 g protein kg-1 day-1 for 2 years. Plasma arginine levels fell from 0.50-0.90 mumol/1 to 0.13-0.30 mumol/1 (normal range 0.02-0.15). Increased concentrations of arginine in the cerebrospinal fluid (CSF) fell from 0.069-0.098 mumol/l to 0.040-0.056 mumol/l (normal mean +/- SD = 0.020 +/- 0.006). Dibasic aminoaciduria returned to normal within 1 week. Substitution of the keto-acid analogues of five essential amino acids in the formula lowered arginine concentrations further, but proved to be unpalatable. Urinary concentrations of orotic acid, uridine and uracil fell toward normal but remained increased, even when the plasma ammonia concentration was measured as normal. Both patients showed a stable clinical improvement.

Published

1982

9. Properties of arginase from liver of Macaca fascicularis; comparison of normals with red blood cell arginase deficient monkeys.

Author

Terasaki K, Spector EB, Hendrickson R, and Cederbaum SD

Subjects

Animals, Arginase genetics, Erythrocytes enzymology, Amino Acid Metabolism, Inborn Errors genetics, Arginase metabolism, Arginine blood, Liver enzymology, Macaca genetics, Macaca fascicularis genetics

Abstract

Deficiency of arginase (E.C. 3.5.3.1), the fifth enzyme of the urea cycle, was found in the red blood cells (RBCs) of Macaca fascicularis monkeys (less than 0.2 micromol arginine cleaved/g Hb/min; normal equals 49.2). Liver biopsies were obtained from two of these monkeys and from one monkey with normal levels of RBC arginase activity. Arginase from both groups of animals required Mn2+ for maximal enzyme activity and demonstrated a pH optimum of 10.2 in vitro. The activity of arginase in the livers of all three monkeys was 1.1 millimol arginine cleaved per g protein per min. The apparent Km for arginine of arginase in the livers of the RBC-deficient monkeys was 7.4 and 5.9 mM and in the normal monkey was 6.9 mM. Similar patterns of heat denaturation was seen at 69 C without Mn2+ present and 79 C in the presence of 20mM Mn2+. No difference in mobility on either RBC-deficient or normal monkeys was found. In addition, liver arginase from all three monkeys reacted similarly with anti-human liver arginase antibody. Liver arginases in RBC-deficient and normal monkeys were identical by ten criteria. These studies do not distinguish among several hypotheses for the genetic determination of arginase in different organs of this species and of man.

Published

1980

10. Immunologic studies of arginase in tissues of normal human adult and arginase-deficient patients.

Author

Spector EB, Rice SC, and Cederbaum SD

Subjects

Amino Acid Metabolism, Inborn Errors genetics, Arginase genetics, Brain enzymology, Chromosome Mapping, Digestive System enzymology, Erythrocytes enzymology, Genes, Humans, Hyperargininemia, Immunodiffusion, Kidney enzymology, Amino Acid Metabolism, Inborn Errors enzymology, Arginase immunology, Arginine blood

Abstract

Rabbit antibody to human liver arginase was used to examine the immunologic characteristics of arginase in red blood cells (RBC), liver, kidney, brain, and gastrointestinal tract from normal adults and from patients with hyperargininemia. Greater than 90% of the arginase in RBC and liver was precipitated by this antibody whereas only 50% of the arginase in kidney, brain, and gastrointestinal tract reacted with it. Two siblings and a third patient with hyperargininemia were found to have immunoreactive arginase protein in their RBC that was enzymatically inactive. The amount of arginase protein approximated that found in RBC from normal individuals. A kidney biopsy obtained from one of the patients with hyperargininemia had arginase activity 4-5-fold greater than that found in normal kidney biopsy material. Double immunodiffusion and precipitation-inhibition studies demonstrated two types of arginase protein in this patient's kidney: one enzymatically inactive and precipitated by the antibody, and one enzymatically active but not precipitated by the antibody. These data, in conjunction with biochemical data reported previously demonstrate that there are two gene loci determining arginase in man.

Published

1983

11. Differential expression of the two human arginase genes in hyperargininemia. Enzymatic, pathologic, and molecular analysis.

Author

Grody WW, Argyle C, Kern RM, Dizikes GJ, Spector EB, Strickland AD, Klein D, and Cederbaum SD

Subjects

Blotting, Southern, Humans, Infant, Liver pathology, Male, Arginase genetics, Arginine blood, Gene Expression Regulation, Isoenzymes genetics

Abstract

Previous studies in our laboratory and others have demonstrated in humans and other mammals two isozymes of arginase (AI and AII) that differ both electrophoretically and antigenically. AI, a cytosolic protein found predominantly in liver and red blood cells, is believed to be chiefly responsible for ureagenesis and is the one missing in hyperargininemic patients. Much less is known about AII because it is present in far smaller amounts and localized in less accessible deep tissues, primarily kidney. We now report the application of enzymatic and immunologic methods to assess the independent expression and regulation of these two gene products in normal tissue extracts, two cultured cell lines, and multiple organ samples from a hyperargininemic patient who came to autopsy after an unusually severe clinical course characterized by rapidly progressive hepatic cirrhosis. AI was totally absent (less than 0.1%) in the patient's tissues, whereas marked enhancement of AII activity (four times normal) was seen in the kidney by immunoprecipitation and biochemical inhibition studies. Immunoprecipitation-competition and Western blot analysis failed to reveal presence of even an enzymatically inactive cross-reacting AI protein, whereas Southern blot analysis showed no evidence of a substantial deletion in the AI gene. Induction studies in cell lines that similarly express only the AII isozyme indicated that its activity could be enhanced severalfold by exposure to elevated arginine levels. Our findings suggest that the same induction mechanism may well be operative in hyperargininemic patients, and that the heightened AII activity may be responsible for the persistent ureagenesis seen in this disorder. These data lend further support to the existence of two separate arginase gene loci in humans, and raise possibilities for novel therapeutic approaches based on their independent manipulation.

Published

1989

12. Hyperargininemia with arginase deficiency.

Author

Cederbaum SD, Shaw KN, Spector EB, Verity MA, Snodgrass PJ, and Sugarman GI

Subjects

Adolescent, Amino Acid Metabolism, Inborn Errors blood, Amino Acid Metabolism, Inborn Errors metabolism, Amino Acids cerebrospinal fluid, Amino Acids urine, Arginase blood, Child, Female, Humans, Male, Amino Acid Metabolism, Inborn Errors genetics, Arginine blood, Hyperargininemia

Published

1979

13. Hyperargininemia.

Author

Cederbaum SD, Shaw KN, and Valente M

Subjects

Amino Acid Metabolism, Inborn Errors cerebrospinal fluid, Arginine urine, Child, Chromatography, Dietary Proteins, Erythrocytes enzymology, Humans, Hyperargininemia, Male, Amino Acid Metabolism, Inborn Errors diagnosis, Arginine blood

Abstract

A 7 1/2-year-old boy had progressive psychomotor retardation, behavior disturbance, and spasticity, and had growth arrest from age three. Plasma arginine on a self-selected protein-poor diet was increased (4.05 mg/dl; nl 0.4 to 2.6), whereas urinary amino acid excretion was normal. Red blood cell arginase was less than 1% of normal in the patient and was half normal in both parents, in two normal siblings, and in his paternal grandfather. Three hours after a meal providing 2 gm protein/kg body weight, the plasma arginine value rose to 13.2 mg/dl, dibasic aminoaciduria was seen clearly for the only time, but blood ammonia concentration remained normal. We conclude that arginase deficiency in the red blood cells and probably in the liver is inherited in an autosomal recessive manner and is responsible for the clinical syndrome in this patient.

Published

1977

14. Argininosuccinic aciduria.

Author

Cederbaum SD, Shaw KN, Valente M, and Cotton ME

Subjects

Amino Acids blood, Amino Acids cerebrospinal fluid, Chromatography, Thin Layer, Citric Acid Cycle, Diet Therapy, Humans, Infant, Karyotyping, Male, Muscle Tonus, Nitrogen urine, Succinates urine, Urea urine, Amino Acid Metabolism, Inborn Errors therapy, Arginine urine, Intellectual Disability etiology, Muscular Diseases etiology, Seizures etiology

Published

1973