Your search keyword '"Cederbaum S"' showing total 39 results

1. AAV-based gene therapy prevents neuropathology and results in normal cognitive development in the hyperargininemic mouse.

Author

Lee EK, Hu C, Bhargava R, Ponnusamy R, Park H, Novicoff S, Rozengurt N, Marescau B, De Deyn P, Stout D, Schlichting L, Grody WW, Cederbaum SD, and Lipshutz GS

Subjects

Animals, Arginase metabolism, Dependovirus, Disease Models, Animal, Humans, Hyperammonemia genetics, Hyperammonemia pathology, Hyperammonemia therapy, Hyperargininemia pathology, Hyperargininemia therapy, Mice, Mice, Transgenic, Nervous System Diseases pathology, Nervous System Diseases therapy, Neurodegenerative Diseases pathology, Neurodegenerative Diseases therapy, Arginase genetics, Genetic Therapy, Hyperargininemia genetics, Nervous System Diseases genetics, Neurodegenerative Diseases genetics

Abstract

Complete arginase I deficiency is the least severe urea cycle disorder, characterized by hyperargininemia and infrequent episodes of hyperammonemia. Patients suffer from neurological impairment with cortical and pyramidal tract deterioration, spasticity, loss of ambulation and seizures, and is associated with intellectual disability. In mice, onset is heralded by weight loss beginning around day 15; gait instability follows progressing to inability to stand and development of tail tremor with seizure-like activity and death. Here we report that hyperargininemic mice treated neonatally with an adeno-associated virus (AAV)-expressing arginase and followed long-term lack any presentation consistent with brain dysfunction. Behavioral and histopathological evaluation demonstrated that treated mice are indistinguishable from littermates, and that putative compounds associated with neurotoxicity are diminished. In addition, treatment results in near complete resolution of metabolic abnormalities early in life; however, there is the development of some derangement later with decline in transgene expression. Ammonium challenging revealed that treated mice are affected by exogenous loading much greater than littermates. These results demonstrate that AAV-based therapy for hyperargininemia is effective and prevents development of neurological abnormalities and cognitive dysfunction in a mouse model of hyperargininemia; however, nitrogen challenging reveals that these mice remain impaired in the handling of waste nitrogen.

Published

2013

2. Arginase I suppresses IL-12/IL-23p40-driven intestinal inflammation during acute schistosomiasis.

Author

Herbert DR, Orekov T, Roloson A, Ilies M, Perkins C, O'Brien W, Cederbaum S, Christianson DW, Zimmermann N, Rothenberg ME, and Finkelman FD

Subjects

Animals, Arginase metabolism, Cell Differentiation, Cell Separation, Coculture Techniques, Enzyme-Linked Immunosorbent Assay, Female, Flow Cytometry, Immunohistochemistry, Inflammation metabolism, Interleukin-12 metabolism, Interleukin-23 metabolism, Intestinal Mucosa immunology, Intestinal Mucosa metabolism, Intestinal Mucosa pathology, Lymphocyte Activation immunology, Macrophage Activation immunology, Macrophages immunology, Macrophages metabolism, Male, Mice, Mice, Inbred BALB C, Receptors, Interleukin-4 immunology, Receptors, Interleukin-4 metabolism, Reverse Transcriptase Polymerase Chain Reaction, Schistosomiasis mansoni metabolism, T-Lymphocytes cytology, T-Lymphocytes immunology, T-Lymphocytes metabolism, Transplantation Chimera, Arginase immunology, Inflammation immunology, Interleukin-12 immunology, Interleukin-23 immunology, Schistosomiasis mansoni immunology

Abstract

Alternatively activated macrophages prevent lethal intestinal pathology caused by worm ova in mice infected with the human parasite Schistosoma mansoni through mechanisms that are currently unclear. This study demonstrates that arginase I (Arg I), a major product of IL-4- and IL-13-induced alternatively activated macrophages, prevents cachexia, neutrophilia, and endotoxemia during acute schistosomiasis. Specifically, Arg I-positive macrophages promote TGF-beta production and Foxp3 expression, suppress Ag-specific T cell proliferation, and limit Th17 differentiation. S. mansoni-infected Arg I-deficient bone marrow chimeras develop a marked accumulation of worm ova within the ileum but impaired fecal egg excretion compared with infected wild-type bone marrow chimeras. Worm ova accumulation in the intestines of Arg I-deficient bone marrow chimeras was associated with intestinal hemorrhage and production of molecules associated with classical macrophage activation (increased production of IL-6, NO, and IL-12/IL-23p40), but whereas inhibition of NO synthase-2 has marginal effects, IL-12/IL-23p40 neutralization abrogates both cachexia and intestinal inflammation and reduces the number of ova within the gut. Thus, macrophage-derived Arg I protects hosts against excessive tissue injury caused by worm eggs during acute schistosomiasis by suppressing IL-12/IL-23p40 production and maintaining the Treg/Th17 balance within the intestinal mucosa.

Published

2010

3. Arginase induction by sodium phenylbutyrate in mouse tissues and human cell lines.

Author

Kern RM, Yang Z, Kim PS, Grody WW, Iyer RK, and Cederbaum SD

Subjects

Animals, Cell Line, Enzyme Induction drug effects, Humans, Isoenzymes biosynthesis, Liver enzymology, Male, Mice, Mice, Inbred C57BL, Arginase biosynthesis, Phenylbutyrates pharmacology

Abstract

Hyperargininemia is a urea cycle disorder caused by mutations in the gene for arginase I (AI) resulting in elevated blood arginine and ammonia levels. Sodium phenylacetate and a precursor, sodium phenylbutyrate (NaPB) have been used to lower ammonia, conjugating glutamine to produce phenylacetylglutamine which is excreted in urine. The elevated arginine levels induce the second arginase (AII) in patient kidney and kidney tissue culture. It has been shown that NaPB increases expression of some target genes and we tested its effect on arginase induction. Eight 9-week old male mice fed on chow containing 7.5 g NaPB/kg rodent chow and drank water with 10 g NaPB/L, and four control mice had a normal diet. After one week all mice were sacrificed. The arginase specific activities for control and NaPB mice, respectively, were 38.2 and 59.4 U/mg in liver, 0.33 and 0.42 U/mg in kidney, and 0.29 and 1.19 U/mg in brain. Immunoprecipitation of arginase in each tissue with AI and AII antibodies showed the activity induced by NaPB is mostly AI. AII may also be induced in kidney. AI accounts for the fourfold increased activity in brain. In some cell lines, NaPB increased arginase activity up to fivefold depending on dose (1-5 mM) and exposure time (2-5 days); control and NaPB activities, respectively, are: erythroleukemia, HEL, 0.06 and 0.31 U/mg, and K562, 0.46 and 1.74 U/mg; embryonic kidney, HEK293, 1.98 and 3.58 U/mg; breast adenocarcinoma, MDA-MB-468, 1.11 and 4.06 U/mg; and prostate adenocarcinoma, PC-3, 0.55 and 3.20 U/mg. In MDA-MB-468 and HEK most, but not all, of the induced activity is AI. These studies suggest that NaPB may induce AI when used to treat urea cycle disorders. It is relatively less useful in AI deficiency, although it could have some effect in those patients with missense mutations.

Published

2007

4. Expression of arginase isozymes in mouse brain.

Author

Yu H, Iyer RK, Kern RM, Rodriguez WI, Grody WW, and Cederbaum SD

Subjects

Animals, Arginase genetics, Arginine metabolism, Brain Stem cytology, Brain Stem enzymology, Central Nervous System cytology, Cerebellum cytology, Cerebellum enzymology, DNA, Complementary, Glutamate Decarboxylase biosynthesis, Immunohistochemistry, Isoenzymes biosynthesis, Isoenzymes genetics, Isoenzymes metabolism, Male, Mice, Mice, Inbred C57BL, Precipitin Tests, Prosencephalon cytology, Prosencephalon enzymology, RNA, Messenger metabolism, Reverse Transcriptase Polymerase Chain Reaction, Spinal Cord cytology, Spinal Cord enzymology, Arginase metabolism, Central Nervous System enzymology, Gene Expression Regulation, Enzymologic physiology, Glutamic Acid metabolism, Neurons enzymology, Ornithine biosynthesis, gamma-Aminobutyric Acid metabolism

Abstract

The two forms of arginase (AI and AII) in man, identical in enzymatic function, are encoded in separate genes and are expressed differentially in various tissues. AI is expressed predominantly in the liver cytosol and is thought to function primarily to detoxify ammonia as part of the urea cycle. AII, in contrast, is predominantly mitochondrial, is more widely expressed, and is thought to function primarily to produce ornithine. Ornithine is a precursor in the synthesis of proline, glutamate, and polyamines. This study was undertaken to explore the cellular and regional distribution of AI and AII expression in brain using in situ hybridization and immunohistochemistry. AI and AII were detected only in neurons and not in glial cells. AI presented stronger expression than AII, but AII was generally coexpressed with AI in most cells studied. Expression was particularly high in the cerebral cortex, cerebellum, pons, medulla, and spinal cord neurons. Glutamic acid decarboxylase 65 and glutamic acid decarboxylase 67, postulated to be related to the risk of glutamate excitotoxic and/or gamma-aminobutyric acid inhibitoxic injury, were similarly ubiquitous in their expression and generally paralleled arginase expression patterns, especially in cerebral cortex, hippocampus, cerebellum, pons, medulla, and spinal cord. This study showed that AI is expressed in the mouse brain, and more strongly than AII, and sheds light on the anatomic basis for the arginine-->ornithine-->glutamate-->GABA pathway., (Copyright 2001 Wiley-Liss, Inc.)

Published

2001

5. 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

6. Induction of arginase II in human Caco-2 tumor cells by cyclic AMP.

Author

Wei LH, Morris SM Jr, Cederbaum SD, Mori M, and Ignarro LJ

Subjects

1-Methyl-3-isobutylxanthine pharmacology, 4-(3-Butoxy-4-methoxybenzyl)-2-imidazolidinone pharmacology, Arginase biosynthesis, Caco-2 Cells, Enzyme Induction, Enzyme Inhibitors pharmacology, Humans, Isoenzymes biosynthesis, Isoenzymes genetics, Isoquinolines pharmacology, Kinetics, Okadaic Acid pharmacology, Protein Biosynthesis drug effects, RNA, Messenger genetics, Transcription, Genetic drug effects, 8-Bromo Cyclic Adenosine Monophosphate pharmacology, Arginase genetics, Colforsin pharmacology, Cyclic AMP physiology, Gene Expression Regulation, Enzymologic drug effects, Sulfonamides

Abstract

The objective of this study was to elucidate the mechanism by which cyclic AMP increases arginase activity in cultured human Caco-2 tumor cells. Caco-2 cells were incubated for 24 h in the presence of 8-bromo cyclic AMP or forskolin, and the cells were harvested, lysed, and assayed for total arginase activity. Both test agents increased arginase activity by twofold, and this was attributed to the induction of the arginase II isoform. Both arginase II mRNA and protein showed increased expression in response to 8-bromo cyclic AMP and forskolin, and these effects were inhibited by H-89 (protein kinase A inhibitor), enhanced by okadaic acid (phosphatase inhibitor), and enhanced by 1-methyl-3-isobutylxanthine (cyclic nucleotide phosphodiesterase inhibitor). Cyclic GMP did not appear to be involved in arginase II induction. These observations indicate that cyclic AMP stimulates arginase II gene expression by mechanisms involving activation of protein kinase A and consequent activation of appropriate transcription factors., (Copyright 2000 Academic Press.)

Published

2000

7. 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

8. Cloning and characterization of the mouse and rat type II arginase genes.

Author

Iyer RK, Bando JM, Jenkinson CP, Vockley JG, Kim PS, Kern RM, Cederbaum SD, and Grody WW

Subjects

Amino Acid Sequence, Animals, Arginase chemistry, Arginase metabolism, DNA, Complementary, Escherichia coli metabolism, Female, Humans, Male, Mice, Mice, Inbred C57BL, Molecular Sequence Data, Phylogeny, Precipitin Tests, Rats, Rats, Sprague-Dawley, Sequence Homology, Amino Acid, Urea metabolism, Arginase genetics, Cloning, Molecular

Abstract

Two forms of arginase, both catalyzing the hydrolysis of arginine to ornithine and urea, are found in animals ranging from amphibians to mammals. In humans, inherited deficiency of hepatic or type I arginase results in hyperargininemia, a syndrome characterized by periodic episodes of hyperammonemia, spasticity, and neurological deterioration. In these patients, a second extrahepatic or type II arginase activity is significantly increased, an induction that may partially compensate for the lack of AI activity and apparently mitigates some of the clinical effects of the condition. Cloning and characterization of the human AII cDNA was recently accomplished. The cloning, sequencing, and partial characterization of the mouse and rat AII cDNAs are reported herein. The DNA sequences predicted polypeptides of 354 amino acids, including a N-terminal mitochondrial import signal. Sequence homology to the human type II arginase, arginase activity data, and immunoprecipitation with an anti-AII antibody confirm the identity of these cloned genes as rodent extrahepatic type II arginases.

Published

1998

9. 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

10. Cloning and characterization of the human type II arginase gene.

Author

Vockley JG, Jenkinson CP, Shukla H, Kern RM, Grody WW, and Cederbaum SD

Subjects

Amino Acid Sequence, Animals, Arginase classification, Base Sequence, Blotting, Northern, Cloning, Molecular, DNA, Complementary, Humans, Molecular Sequence Data, Sequence Homology, Amino Acid, Sequence Homology, Nucleic Acid, Arginase genetics

Abstract

There are two forms of arginase in humans, both catalyzing the hydrolysis of arginine to ornithine and urea. Recent studies in animal models and in Type I arginase-deficient patients suggest that Type II arginase is inducible and may play an important role in the regulation of extra-urea cycle arginine metabolism by modulating cellular arginine concentrations. We PCR amplified and cloned the human Type II arginase gene, the first nonliver arginase gene reported in mammals. While sequence homology to Type I arginase, arginase activity data, and immunoprecipitation with an anti-AII antibody confirm the identity of this gene, Northern blot analysis demonstrates its differential expression in the brain, prostate, and kidney. Type II arginase may be an important part of the arginine regulatory system affecting nitric oxide synthase, arginine decarboxylase, kyotorphin synthase, and arginine-glycine transaminase activities and polyamine and proline biosynthesis.

Published

1996

11. Delivery of cytosolic liver arginase into the mitochondrial matrix space: a possible novel site for gene replacement therapy.

Author

Wissmann PB, Goodman BK, Vockley JG, Kern RM, Cederbaum SD, and Grody WW

Subjects

Cell Line, Drug Delivery Systems, Humans, Mitochondria, Liver enzymology, Arginase genetics, Gene Transfer Techniques, Genetic Therapy, Mitochondria, Liver genetics

Abstract

As a toxic metabolic byproduct in mammals, excess ammonia is converted into urea by a series of five enzymatic reactions in the liver that constitute the urea cycle. A portion of this cycle takes place in the mitochondria, while the remainder is cytosolic. Liver arginase (L-arginine ureahydrolase, A1) is the fifth enzyme of the cycle, catalyzing the hydrolysis of arginine to ornithine and urea within the cytosol. Patients deficient in this enzyme exhibit hyperargininemia with episodic hyperammonemia and long-term effects of mental retardation and spasticity. However, the hyperammonemic effects are not so catastrophic in arginase deficiency as compared to other urea cycle defects. Earlier studies have suggested that this is due to the mitigating effect of a second isozyme of arginase (AII) expressed predominantly in the kidney and localized within the mitochondria. In order to explore the curious dual evolution of these two isozymes, and the ways in which the intriguing, aspects of AII physiology might be exploited for gene replacement therapy of AI deficiency, the cloned cDNA for human AI was inserted into an expression vector downstream from the mitochondrial targeting leader sequence for the mitochondrial enzyme ornithine transcarbamylase and transfected into a variety of recipient cell types. AI expression in the target cells was confirmed by northern blot analysis, and competition and immunoprecipitation studies showed successful translocation of the exogenous AI enzyme into the transfected cell mitochondria. Stability studies demonstrated that the translocated enzyme had a longer half-life than either native cytosolic AI or mitochondrial AII. Incubation of the transfected cells with increasing amounts of arginine produced enhanced levels of mitochondrial AI activity, a substrate-induced effect that we have previously seen with native AII but never AI. Along with exploring the basic biological questions of regulation and subcellular localization in this unique dual-enzyme system, these results suggest that the mitochondrial matrix space may be a preferred site for delivery of enzymes in gene replacement therapy.

Published

1996

12. 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

13. Loss of function mutations in conserved regions of the human arginase I gene.

Author

Vockley JG, Goodman BK, Tabor DE, Kern RM, Jenkinson CP, Grody WW, and Cederbaum SD

Subjects

Amino Acid Sequence, Animals, Base Sequence, Conserved Sequence, Humans, Manganese metabolism, Molecular Sequence Data, Mutagenesis, Site-Directed, Neurospora, Pedigree, Polymerase Chain Reaction, Polymorphism, Single-Stranded Conformational, Rats, Sequence Alignment, Xenopus, Arginase genetics

Abstract

We have utilized SSCP analysis to identify disease-causing mutations in a cohort with arginase deficiency. Each of the patient's mutations was reconstructed in vitro by site-directed mutagenesis to determine the effect of the mutations on enzyme activity. In addition we identified six areas of cross-species homology in the arginase protein, four containing conserved histidine residues thought to be important to Mn(2+)-dependent enzyme function. Mapping patient mutations in relationship to the conserved regions indicates that substitution mutations within the conserved regions and randomly occurring microdeletions and nonsense mutations have a significant effect on enzymatic function. In vitro mutagenesis was utilized to create nonpatient substitution mutations in the conserved histidine residues to verify their importance to arginase activity. As expected, replacement of histidine residues with other amino acids dramatically reduces arginase activity levels in our bacterial expression system.

Published

1996

14. Comparative properties of arginases.

Author

Jenkinson CP, Grody WW, and Cederbaum SD

Subjects

Amino Acid Sequence, Animals, Arginine metabolism, Biological Evolution, Humans, Invertebrates, Liver enzymology, Molecular Sequence Data, Plants enzymology, Urea metabolism, Vertebrates, Arginase chemistry, Arginase physiology

Abstract

Arginase is a primordial enzyme, widely distributed in the biosphere and represented in all primary kingdoms. It plays a critical role in the hepatic metabolism of most higher organisms as a cardinal component of the urea cycle. Additionally, it occurs in numerous organisms and tissues where there is no functioning urea cycle. Many extrahepatic tissues have been shown to contain a second form of arginase, closely related to the hepatic enzyme but encoded by a distinct gene or genes and involved in a host of physiological roles. A variety of functions has been proposed for the "extrahepatic" arginases over the last three decades. In recent years, interest in arginase has been stimulated by a demonstrated involvement in the metabolism of the ubiquitous and multifaceted molecule nitric oxide. Molecular biology has begun to furnish new clues to the disparate functions of arginases in different environments and organisms. Comparative studies of arginase sequences are also beginning to elucidate the comparative evolution of arginases, their molecular structures and the nature of their catalytic mechanism. Further studies have sought to clarify the involvement of arginase in human disease. This review presents an outline of the current state of arginase research by giving a comparative overview of arginases and their associated properties.

Published

1996

15. Co-induction of arginase and nitric oxide synthase in murine macrophages activated by lipopolysaccharide.

Author

Wang WW, Jenkinson CP, Griscavage JM, Kern RM, Arabolos NS, Byrns RE, Cederbaum SD, and Ignarro LJ

Subjects

Amino Acid Oxidoreductases metabolism, Animals, Antioxidants pharmacology, Arginase metabolism, Arginine metabolism, Cell Line, Enzyme Induction drug effects, Interferon-gamma pharmacology, Kinetics, Macrophages, Peritoneal drug effects, Mice, NF-kappa B metabolism, Nitrates metabolism, Nitric Oxide Synthase, Nitrites metabolism, Pyrrolidines pharmacology, Recombinant Proteins, Thiocarbamates pharmacology, Urea metabolism, Amino Acid Oxidoreductases biosynthesis, Arginase biosynthesis, Macrophages, Peritoneal enzymology

Abstract

In view of studies showing that not only nitric oxide synthase (NOS) activity but arginase activity is induced in rodent macrophages by lipopolysaccharide (LPS), the objective of this study was to investigate the co-induction of these two enzymes and to ascertain whether common mechanisms are involved. RAW 264.7 cells were activated by 2 micrograms LPS/ml and incubated for up to 48 hr. Inducible NOS (iNOS) and inducible arginase II (AII) activities were monitored, respectively, by measuring NO2-/NO3- accumulation in cell culture media and formation of urea (as CO2) from L-arginine by cell lysates. AII activity increased linearly up to at least 48 hr, whereas NO2-/NO3- formation reached a plateau well before 48 hr. Immunoprecipitation experiments revealed that AII accounted for 90-100% of arginase activity in LPS-activated macrophages. The inhibitor of NF-kappa B activation, pyrrolidine dithiocarbamate, inhibited the induction of iNOS but not AII. Moreover, whereas IFN-gamma caused iNOS induction, AII induction was nearly abolished by IFN-gamma, perhaps by inhibiting transcription of the AII gene. These observations indicate that co-induction of iNOS and AII occurs by distinct transcriptional mechanisms, AII induction could diminish NO production by decreasing L-arginine availability, and IFN-gamma can prevent AII induction.

Published

1995

16. Functional and molecular analysis of liver arginase promoter sequences from man and Macaca fascicularis.

Author

Goodman BK, Klein D, Tabor DE, Vockley JG, Cederbaum SD, and Grody WW

Subjects

3T3 Cells, Animals, Biological Evolution, Cell Line, DNA-Binding Proteins metabolism, Electrophoresis, Polyacrylamide Gel, Humans, Mice, Organ Specificity, Plasmids, Transcription, Genetic, Tumor Cells, Cultured, Arginase genetics, Liver enzymology, Macaca fascicularis genetics, Promoter Regions, Genetic

Abstract

Functional and DNA binding analyses were used to investigate transcriptional regulation of liver arginase, a mammalian urea cycle enzyme with marked tissue specificity. Reporter constructs containing the proximal 111 bp of the gene from man and Macaca fascicularis showed over sixfold background activity in HepG2 hepatoma cells, which express significant levels of liver arginase, and 12-fold background activity in minimally expressing HEK cells. Longer constructs, active in both cell lines, showed greater activity in the liver cell line. The constructs showed no activity in arginase-negative NIH 3T3 fibroblasts. A 54-bp dyad insert present in the human sequence and absent in M. fascicularis did not affect function. DNA binding analyses localized multiple liver-specific complexes as well as complexes shared among cell types. Little binding was evident in fibroblast extracts. Despite liver-specific binding, there was no evidence of a strong liver-specific enhancer. HEK and NIH 3T3 nuclear extracts showed strikingly different patterns of DNA binding. These studies demonstrate that molecular regulation of liver arginase transcription is complex and that control mechanisms differ among tissue types.

Published

1994

17. Subcellular location and differential antibody specificity of arginase in tissue culture and whole animals.

Author

Spector EB, Jenkinson CP, Grigor MR, Kern RM, and Cederbaum SD

Subjects

Animals, Antibody Specificity, Arginase genetics, Arginase immunology, Cell Line, Culture Techniques, Humans, Arginase metabolism, Subcellular Fractions enzymology

Abstract

Studies in man and other mammals have demonstrated the existence of two forms of arginase, a cytoplasmic form located primarily in liver and a mitochondrial form expressed in lesser amounts in a larger number of organs, but especially kidney. They appear to be encoded in different gene loci. Using a colloidal silica gradient separation technique, we have now located arginase in H4 cells, a rat hepatoma-derived line, to the cytoplasm and the arginase in human embryonic kidney-derived line, to the mitochondrion. Antibody prepared against A1 precipitates all the arginase from liver, 50% from kidney and none of the activity from human embryonic kidney (HEK) cells. An antibody prepared against partially purified All, by contrast, precipitates > 90% of arginase activity from HEK cells, half from kidney and virtually none from H4 cells or rat liver.

Published

1994

18. 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

19. Arginase deficiency manifesting delayed clinical sequelae and induction of a kidney arginase isozyme.

Author

Grody WW, Kern RM, Klein D, Dodson AE, Wissman PB, Barsky SH, and Cederbaum SD

Subjects

Adult, DNA analysis, Enzyme Induction, Humans, Male, RNA, Messenger analysis, Amino Acid Metabolism, Inborn Errors enzymology, Arginase analysis, Hyperargininemia, Isoenzymes analysis, Kidney enzymology, Liver enzymology

Abstract

Deficiency of liver arginase (AI) is characterized clinically by hyperargininemia, progressive mental impairment, growth retardation, spasticity, and periodic episodes of hyperammonemia. The rarest of the inborn errors of urea cycle enzymes, it has been considered the least life-threatening, by virtue of the typical absence of catastrophic neonatal hyperammonemia and its compatibility with a longer life span. This has been attributed to the persistence of some ureagenesis in these patients through the activity of a second isozyme of arginase (AII) located predominantly in the kidney. We have treated a number of arginase-deficient patients into young adulthood. While they are severely retarded and wheelchair-bound, their general medical care has been quite tractable. Recently, however, two of the oldest (M.U., age 20, and M.O., age 22) underwent rapid deterioration, ending in hyperammonemic coma and death, precipitated by relatively minor viral respiratory illnesses inducing a catabolic state with increased endogenous nitrogen load. In both cases, postmortem examination revealed severe global cerebral edema and aspiration pneumonia. Enzyme assays confirmed the absence of AI activity in the livers of both patients. In contrast, AII activity (identified by its different cation cofactor requirements and lack of precipitation with anti-AI antibody) was markedly elevated in kidney tissues, 20-fold in M.O. and 34-fold in M.U. Terminal plasma arginine (1500 mumols/l) and ammonia (1693 mmol/l) levels of M.U. were substantially higher than those of M.O. (348 mumols/l and 259 mumols/l, respectively). By Northern blot analysis, AI mRNA was detected in M.O.'s liver but not in M.U.'s; similarly, anti-AI crossreacting material was observed by Western blot in M.O. only. These findings indicate that, despite their more long-lived course, patients with arginase deficiency remain vulnerable to the same catastrophic events of hyperammonemia that patients with other urea cycle disorders typically suffer in infancy. Further, unlike those other disorders, an attempt is made to compensate for the primary enzyme deficiency by induction of another isozyme in a different tissue. Such substrate-stimulated induction of an enzyme may be unique in a medical genetics setting and raises novel options for eventual gene therapy of this disorder.

Published

1993

20. Genetic linkage group (ARG1-D6S33-MYB) on chromosome 6q containing the arginase-1 and MYB genes.

Author

Nguyen J, Charmley P, Grody WW, Cederbaum SD, King MC, and Gatti RA

Subjects

Chromosome Mapping, Genes, Humans, Lod Score, Polymorphism, Restriction Fragment Length, Arginase genetics, Chromosomes, Human, Pair 6, Genetic Linkage, Oncogenes

Published

1990

21. 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

22. 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

23. A PvuII RFLP for the human liver arginase (ARG1) gene.

Author

Kidd JR, Dizikes GJ, Grody WW, Cederbaum SD, and Kidd KK

Subjects

Humans, Arginase genetics, Liver enzymology, Polymorphism, Genetic, Polymorphism, Restriction Fragment Length

Published

1986

24. Isolation of human liver arginase cDNA and demonstration of nonhomology between the two human arginase genes.

Author

Dizikes GJ, Grody WW, Kern RM, and Cederbaum SD

Subjects

Cloning, Molecular, DNA genetics, DNA isolation & purification, Gene Expression Regulation, Genes, Humans, Kidney enzymology, RNA, Messenger genetics, Sequence Homology, Nucleic Acid, Arginase genetics, Liver enzymology

Abstract

A human liver cDNA library was screened by colony hybridization with a rat liver arginase cDNA. The number of positive clones detected was in agreement with the estimated abundance of arginase message in liver, and the identities of several of these clones were verified by hybrid-select translation, immunoprecipitation, and competition by purified arginase. The largest of these human liver arginase cDNAs was then used to detect arginase message on northern blots at levels consistent with the activities of liver arginase in the tissues and cells studied. The absence of a hybridization signal with mRNA from a cell line expressing only human kidney arginase demonstrated the lack of homology between the two human arginase genes and indicated considerable evolutionary divergence between these two loci.

Published

1986

25. 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

26. Human arginase isozymes.

Author

Grody WW, Dizikes GJ, and Cederbaum SD

Subjects

Animals, Arginase genetics, Arginine metabolism, Gene Expression Regulation, Humans, Hyperargininemia, Isoenzymes deficiency, Isoenzymes genetics, Liver enzymology, Mitochondria enzymology, Ornithine metabolism, Species Specificity, Urea metabolism, Arginase metabolism, Isoenzymes metabolism

Abstract

Studies in experimental animals and humans demonstrate the existence of two arginase isozymes. One, designated AI (or A1), has a high pI, is located in the cytosol, is most abundant in liver, and is thought to be primarily responsible for ammonia detoxification as urea. The gene coding for this isozyme is mutated in human hyperargininemia. A second isozyme, designated AII (or A4), has a neutral pI, is located in the mitochondrial matrix, and is thought to be involved primarily in the production of ornithine as a precursor of proline and glutamate. It appears to be expressed in most but not all tissues and in more nearly equal amounts. The two isozymes are immunologically distinct and are coded for by two separate genes. The great similarity in all measured kinetic and some physicochemical properties implies a high degree of structural similarity at the active site, but the lack of immunological cross-reactivity and DNA cross-hybridization implies substantial compositional differences in other parts of the enzyme molecules.

Published

1987

27. Regulation of glucocorticoids of arginase and argininosuccinate synthetase in cultured rat hepatoma cells.

Author

Haggerty DF, Spector EB, Lynch M, Kern R, Frank LB, and Cederbaum SD

Subjects

Animals, Cell Line, Cycloheximide pharmacology, Fluoxymesterone pharmacology, Kinetics, Protein Biosynthesis drug effects, Rats, Transcription, Genetic drug effects, Arginase genetics, Argininosuccinate Synthase genetics, Corticosterone pharmacology, Dexamethasone pharmacology, Hydrocortisone pharmacology, Ligases genetics, Liver Neoplasms, Experimental enzymology

Abstract

We have examined and characterized the regulation by glucocorticoids of the levels of arginase and argininosuccinate synthetase in two rat hepatoma cell lines (H4-II-E-C3 and MH1C1). Hydrocortisone elevates the activity of both enzymes in a time- and dose-dependent fashion. This effect was blunted markedly by small amounts of ethanol (0.1 to 0.9% [v/v]) and blocked substantially by a high molar excess of the "anti-inducer" steroid fluoxymesterone. The other "optimal" inducers dexamethasone and corticosterone were as effective as hydrocortisone in elevating the levels of these enzymes at saturating concentrations. Inhibition of these stimulations by cycloheximide indicated that ongoing cellular protein synthesis was required for both effects, and the admixture of extracts from fully stimulated and basal cells gave no evidence for the existence of direct inhibitors or activators of either enzyme. The results corroborate findings from earlier whole-animal studies and provide evidence for the following conclusions. (i) This stimulation by hydrocortisone of urea-cycle enzymes in the cultured hepatoma cells is mediated by a classical glucocorticoid mechanism involving initial binding to specific cytoplasmic steroid receptors and the eventual accumulation of new enzyme molecules. (ii) These cell lines thus constitute valid experimental models for use in further detailed studies on the molecular mechanism(s) through which glucocorticoids and intermediary metabolites effect a selective modulation of arginase and argininosuccinate-synthetase gene expression in the differentiated mammalian liver.

Published

1982

28. Cloning of rat liver arginase cDNA and elucidation of regulation of arginase gene expression in H4 rat hepatoma cells.

Author

Dizikes GJ, Spector EB, and Cederbaum SD

Subjects

Animals, Cell Line, DNA genetics, Liver Neoplasms, Experimental genetics, Nucleic Acid Hybridization, RNA, Messenger genetics, Rats, Rats, Inbred Strains, Arginase genetics, Cloning, Molecular, Gene Expression Regulation, Liver enzymology, Liver Neoplasms, Experimental enzymology

Abstract

In order to study the regulation of expression of the two arginase genes in mammalian tissues, we undertook to clone cDNA specific for rat liver arginase. mRNA was isolated from rat liver polysomes enriched for the arginase message by immunopurification and was used to produce an 800-member cDNA library carried in pBR322. Four arginase clones were identified by hybrid selection, and one was used to find two others following colony hybridization. Clonal identity was verified by its enrichment in the cDNA made from immunopurified mRNA; by hybrid selection, immunoprecipitation, and competition by purified arginase; hybridization on Northern analysis with liver-derived RNA (high in arginase) and its absence with mRNA from tissues low in arginase; and independent identification by hybrid selection and colony hybridization. Northern analysis of mRNA from H4-II-E-C3 (H4) rat hepatoma cells in which arginase activity was induced by hydrocortisone demonstrated equal, eightfold augmentation of both arginase activity and arginase mRNA levels. Southern blot analysis of DNA from these cells indicated that no change in arrangement or copy number accompanied induction. Southern analysis also suggested that the gene for rat liver arginase is present in a single copy, without pseudogenes, and that a high degree of homology exists between it and its mouse counterpart.

Published

1986

29. The gene for human liver arginase (ARG1) is assigned to chromosome band 6q23.

Author

Sparkes RS, Dizikes GJ, Klisak I, Grody WW, Mohandas T, Heinzmann C, Zollman S, Lusis AJ, and Cederbaum SD

Subjects

Chromosome Mapping, Cloning, Molecular, Humans, Hybrid Cells, Liver enzymology, Nucleic Acid Hybridization, Arginase genetics, Chromosomes, Human, 6-12 and X

Abstract

The human liver arginase gene, whose deficiency is responsible for argininemia (McKusick no. 20780), has been assigned to 6q23 through a combination of somatic cell hybrid analysis and in situ hybridization using a 1,550-base pair (bp) human DNA probe for this gene.

Published

1986

30. Differential expression of multiple forms of arginase in cultured cells.

Author

Spector EB, Kern RM, Haggerty DF, and Cederbaum SD

Subjects

Animals, Brain enzymology, Cell Line, Cell Transformation, Viral, Cells, Cultured, Humans, Immunodiffusion, Kidney enzymology, Liver Neoplasms, Experimental enzymology, Papillomaviridae, Polyomaviridae, Rabbits, Arginase biosynthesis, Isoenzymes biosynthesis

Abstract

Arginase (EC 3.5.3.1), the final enzyme in the urea cycle, catalyzes the cleavage of arginine to orthinine and urea. At least two forms of this enzyme, AI and AII, have been described and are probably encoded by discrete genetic loci. The expression of these separate genes has been studied in mammalian cells grown in culture. The permanent rat-hepatoma line H4-II-E-C3 contained exclusively the AI enzyme; the form in mammals comprising about 98% of the arginase activity in liver and erythrocytes but catalyzing only about one half of that reaction in kidney, gastrointestinal tract, and brain. By contrast, human-embryonic-kidney and -brain cells, after transformation with the human papovavirus BK, contained only the AII species of arginase, which form contributes the remaining half of that catalysis in those mammalian tissues in vivo. We report here the results of an extensive study on the properties of these two forms of arginase in the three cell lines, including Km values for arginine, behavior on polyacrylamide gels under non-denaturing conditions, and cross-reactivity with lapine antibodies against the arginases from either rat or human liver.

Published

1985

31. Properties of fetal and adult red blood cell arginase: a possible prenatal diagnostic test for arginase deficiency.

Author

Spector EB, Kiernan M, Bernard B, and Cederbaum SD

Subjects

Female, Genes, Hot Temperature, Humans, Hydrogen-Ion Concentration, Hyperargininemia, Pregnancy, Arginase blood, Erythrocytes enzymology, Fetal Blood enzymology, Prenatal Diagnosis

Abstract

Prenatal diagnosis of inborn errors of metabolism has been possible only if the enzyme affected is expressed in amniotic fluid cells grown in culture. Arginase is essentially undetectable in normal human fibroblasts, amniotic fluid, and amniotic fluid cells but is present in high amounts in red blood cells. It is absent in the red blood cells of patients with liver arginase deficiency. The properties of the enzyme in the red cells of healthy children and adults were compared to those of the enzyme obtained from cord blood red cells of 13--20-week fetuses obtained at hysterotomy. The activities, heavy metal requirements, heat stability, pH optimum, kinetic properties, and reaction with anti-arginase antibody were examined. Both enzyme species were either identical or substantially similar by all criteria. The adult and fetal enzymes are, therefore, probably determined by the same structural gene. Fetal red cells obtained during amniocentesis and amnioscopy should then be a suitable tissue to use to make the prenatal diagnosis of arginase deficiency.

Published

1980

32. Arginase activity in fibroblasts.

Author

Cederbaum SD and Spector EB

Subjects

Arginase blood, Humans, Liver enzymology, Metabolism, Inborn Errors blood, Skin enzymology, Arginase metabolism, Fibroblasts enzymology

Published

1978

33. Hollow-fiber reactors containing mammalian arginase: an approach to enzyme replacement therapy.

Author

Kanalas JJ, Spector EB, and Cederbaum SD

Subjects

Animals, Arginase therapeutic use, Drug Stability, Hydrogen-Ion Concentration, Hyperargininemia, Kinetics, Manganese physiology, Rabbits, Rats, Urea metabolism, Amino Acid Metabolism, Inborn Errors drug therapy, Arginase administration & dosage, Enzymes, Immobilized therapeutic use

Published

1982

34. Biochemical properties of arginase in human adult and fetal tissues.

Author

Spector EB, Rice SC, Moedjono S, Bernard B, and Cederbaum SD

Subjects

Arginase genetics, Brain enzymology, Digestive System enzymology, Electrophoresis, Polyacrylamide Gel, Female, Hot Temperature, Humans, Kidney enzymology, Kinetics, Liver enzymology, Pregnancy, Arginase metabolism, Fetus enzymology

Published

1982

35. Kinetics of inhibition of rat liver and kidney arginases by proline and branched-chain amino acids.

Author

Carvajal N and Cederbaum SD

Subjects

Animals, Isoleucine pharmacology, Kinetics, Leucine pharmacology, Rats, Valine pharmacology, Amino Acids, Branched-Chain pharmacology, Arginase antagonists & inhibitors, Kidney enzymology, Liver enzymology, Proline pharmacology

Abstract

The effects of proline, leucine, isoleucine and valine on kidney and liver arginases were studied. At pH 7.5 and at nearly physiological concentrations, the branched-chain amino acids caused a significant inhibition of liver arginase A1 and only minor effects on kidney arginase A4. Kidney arginase was, however, much more sensitive to inhibition by proline than the liver enzyme. The inhibition of liver and kidney arginases by branched-chain amino acids was partial, indicating the existence of allosteric sites on both enzymes. The function of kidney arginase in proline biosynthesis and a possible role of branched-chain amino acids in the hydrolysis of arginine in liver is discussed.

Published

1986

36. Comparison of arginase activity in red blood cells of lower mammals, primates, and man: evolution to high activity in primates.

Author

Spector EB, Rice SC, Kern RM, Hendrickson R, and Cederbaum SD

Subjects

Animals, Cats, Cebidae blood, Cercopithecidae blood, Dogs, Gorilla gorilla blood, Haplorhini blood, Hemolysis, Humans, Hyperargininemia, Macaca fascicularis blood, Mice, Papio blood, Pongo pygmaeus blood, Rabbits, Rats, Reference Values, Species Specificity, Arginase blood, Biological Evolution, Erythrocytes enzymology, Primates blood

Abstract

Arginase activity in red blood cells (RBC) of various mammalian species including man was determined. In nonprimate species, the activity generally fell below the level of detectability of the assay: less than 1.0 mumol urea/g hemoglobin per hr. Activities in higher nonhuman primates were equal to or of the same order of magnitude as those in man (approximately 950 mumol/g hemoglobin per hr). RBC arginase deficiency with normal liver arginase activity has been shown to segregate as an autosomal codominant trait in Macaca fascicularis established and bred in captivity. This study confirms the presence of this polymorphism in wild populations trapped in several geographic areas and demonstrates the absence of immunologically cross-reactive material in the RBC of RBC arginase-deficient animals. These data when taken together suggest that the expression of arginase in RBC is the result of a regulatory alteration, has evolved under positive selective pressure, and is not an example of the vestigial persistence of an arcane function. The expression of arginase in the RBC results in a marked drop in the arginine content of these cells.

Published

1985

37. Minimal ureagenesis is necessary for survival in the murine model of hyperargininemia treated by AAV-based gene therapy.

Author

Hu, C, Tai, D S, Park, H, Cantero, G, Chan, E, Yudkoff, M, Cederbaum, S D, and Lipshutz, G S

Subjects

GENE therapy, ARGINASE, HYPERAMMONEMIA, BRAIN diseases, PYRAMIDAL tract, SPASMS, LABORATORY mice, PATIENTS, THERAPEUTICS

Abstract

Hyperammonemia is less severe in arginase 1 deficiency compared with other urea cycle defects. Affected patients manifest hyperargininemia and infrequent episodes of hyperammonemia. Patients typically suffer from neurological impairment with cortical and pyramidal tract deterioration, spasticity, loss of ambulation, seizures and intellectual disability; death is less common than with other urea cycle disorders. In a mouse model of arginase I deficiency, the onset of symptoms begins with weight loss and gait instability, which progresses toward development of tail tremor with seizure-like activity; death typically occurs at about 2 weeks of life. Adeno-associated viral vector gene replacement strategies result in long-term survival of mice with this disorder. With neonatal administration of vector, the viral copy number in the liver greatly declines with hepatocyte proliferation in the first 5 weeks of life. Although the animals do survive, it is not known from a functional standpoint how well the urea cycle is functioning in the adult animals that receive adeno-associated virus. In these studies, we administered [1-13C] acetate to both littermate controls and adeno-associated virus-treated arginase 1 knockout animals and examined flux through the urea cycle. Circulating ammonia levels were mildly elevated in treated animals. Arginine and glutamine also had perturbations. Assessment 30 min after acetate administration demonstrated that ureagenesis was present in the treated knockout liver at levels as low at 3.3% of control animals. These studies demonstrate that only minimal levels of hepatic arginase activity are necessary for survival and ureagenesis in arginase-deficient mice and that this level of activity results in control of circulating ammonia. These results may have implications for potential therapy in humans with arginase deficiency. [ABSTRACT FROM AUTHOR]

Published

2015

38. Properties of fetal and adult red blood cell arginase: a possible prenatal diagnostic test for arginase deficiency

Author

Spector, E B, Kiernan, M, Bernard, B, and Cederbaum, S D

Subjects

Erythrocytes, Hot Temperature, Hyperargininemia, Arginase, Genes, Pregnancy, Prenatal Diagnosis, Humans, Female, Hydrogen-Ion Concentration, Fetal Blood, Research Article

Abstract

Prenatal diagnosis of inborn errors of metabolism has been possible only if the enzyme affected is expressed in amniotic fluid cells grown in culture. Arginase is essentially undetectable in normal human fibroblasts, amniotic fluid, and amniotic fluid cells but is present in high amounts in red blood cells. It is absent in the red blood cells of patients with liver arginase deficiency. The properties of the enzyme in the red cells of healthy children and adults were compared to those of the enzyme obtained from cord blood red cells of 13--20-week fetuses obtained at hysterotomy. The activities, heavy metal requirements, heat stability, pH optimum, kinetic properties, and reaction with anti-arginase antibody were examined. Both enzyme species were either identical or substantially similar by all criteria. The adult and fetal enzymes are, therefore, probably determined by the same structural gene. Fetal red cells obtained during amniocentesis and amnioscopy should then be a suitable tissue to use to make the prenatal diagnosis of arginase deficiency.

Published

1980

39. The gene for human liver arginase (ARG1) is assigned to chromosome band 6q23

Author

Sparkes, R S, Dizikes, G J, Klisak, I, Grody, W W, Mohandas, T, Heinzmann, C, Zollman, S, Lusis, A J, and Cederbaum, S D

Subjects

Chromosomes, Human, 6-12 and X, Arginase, Liver, Chromosome Mapping, Humans, Nucleic Acid Hybridization, Cloning, Molecular, Hybrid Cells, Research Article

Abstract

The human liver arginase gene, whose deficiency is responsible for argininemia (McKusick no. 20780), has been assigned to 6q23 through a combination of somatic cell hybrid analysis and in situ hybridization using a 1,550-base pair (bp) human DNA probe for this gene.

Published

1986