Isoenzyme pattern and immunological properties of arginase in normal and hyperargininemia fibroblasts

Arginase deficiency is an inborn error of the last step in the urea cycle and leads to profound hyperargininemia. The enzyme deficiency has been demonstrated in the liver and red blood cells. In cultured patient fibroblasts, the activity is normal. Arginase exists in multiple molecular forms only one of which is missing in hyperargininemic patients. In fibroblasts, three arginase isoenzymes can be demonstrated by DEAE-cellulose column chromatography, two by electrophoresis and by immunoprecipitation methods. From the present data, it is improbable that part of the A1 isoenzyme in fibroblasts originates from fetal calf serum arginase which supplements the culture media. None of the techniques for the separation and analyses of arginase isoenzyme allows to differentiate between the normal and the arginase-deficient phenotype. A possible explanation would be that the defect in A1 arginase observed in the liver is the result of a regulatory defect.     

Microinjection of arginase into enzyme-deficient cells with the isolated glycoproteins of Sendai virus as fusogen

A method of introducing enzymes into the cytoplasm of fibroblasts in culture is described. Erythrocytes obtained from normal and arginase-deficient individuals were loaded with arginase in vitro and fused to arginase-deficient mouse and human fibroblasts. Erythrocyte ghost-fibroblast fusion was quantified by a 14C-radioactive assay for arginase in solubilized fibroblasts. Fusion was successfully induced by Sendai virus and also by the isolated glycoproteins of Sendai virus. After fusion the arginase activity associated with the Fibroblasts was 700--1500 U of arginase/mg of cell protein; this enzyme activity was 5- to 10-times higher than that normally found in the fibroblasts. The enrichment in arginase activity indicated that between four and ten ghosts had fused per fibroblast. The use of isolated viral proteins to mediate the transfer of enzymes into cells in vivo might alleviate clinical complications inherent in the use of whole virions. The enzyme replacement technique described in this report for a hyperargininemic model cell system should be applicable to the group of inborn errors of metabolism characterized by deficiency of an enzyme normally localized in the cytoplasmic compartment of cells.     

Molecular genetic study of human arginase deficiency

We have explored the molecular pathology in 28 individuals homozygous or heterozygous for liver arginase deficiency (hyperargininemia) by a combination of Southern analysis, western blotting, DNA sequencing, and PCR. This cohort represents the majority of arginase-deficient individuals worldwide. Only 2 of 15 homozygous patients on whom red blood cells were available had antigenically cross-reacting material as ascertained by western blot analysis using anti-liver arginase antibody. Southern blots of patient genomic DNAs, cut with a variety of restriction enzymes and probed with a near-full-length (1,450-bp) human liver arginase cDNA clone, detected no gross gene deletions. Loss of a TaqI cleavage site was identified in three individuals: in a homozygous state in a Saudi Arabian patient at one site, at a different site in homozygosity in a German patient, and in heterozygosity in a patient from Australia. The changes in the latter two were localized to exon 8, through amplification of this region by PCR and electrophoretic analysis of the amplified fragment after treatment with TaqI; the precise base changes (Arg291X and Thr290Ser) were confirmed by sequencing. It is interesting that the latter nucleotide variant (Thr290Ser) was found to lie adjacent to the TaqI site rather than within it, though whether such a conservative amino acid substitution represents a true pathologic mutation remains to be determined. We conclude that arginase deficiency, though rare, is a heterogeneous disorder at the genotypic level, generally encompassing a variety of point mutations rather than substantial structural gene deletions.     

Rapid prenatal testing for human beta-glucuronidase deficiency (MPS VII)

Prenatal diagnosis for the lysosomal storage disorders is typically achieved by enzymatic analysis of the relevant lysosomal enzyme in cultured amniocytes or chorionic villi. While prenatal diagnosis of some genetic diseases can be done by analysis of pertinent metabolites in amniotic fluid, there are few data regarding prenatal diagnosis of lysosomal disorders by enzyme analysis of amniotic fluid. Prenatal diagnosis by enzyme analysis of amniotic fluid has the potential advantage of providing a more rapid prenatal test result. In this study we describe an assay for the prenatal diagnosis of the mucopolysaccharidosis beta-glucuronidase deficiency (MPS VII; MIM #253220) using amniotic fluid and we confirm its reliability in detecting an affected fetus in an at-risk pregnancy by enzyme analysis of cultured amniocytes and fetal fibroblasts. Because MPS VII is rare and few instances of prenatal diagnosis for this and nearly all other lysosomal disorders have been accomplished by enzyme analysis of amniotic fluid, confirmation of results obtained from enzyme analysis of amniotic fluid should be carried out by enzyme or mutation analysis using cultured amniocytes or chorionic villus specimens.     

Arginase-flotillin interaction brings arginase to red blood cell membrane

Flotillin-1 and arginase are both up-regulated in red blood cell membrane of type 2 diabetic patients. For studying why the soluble arginase can bind to the membrane and whether such binding would modify arginase activity, the arginase1 and related proteins were cloned and expressed. The results showed that flotillin-1 can interact with arginase1, and hence arginase activity was up-regulated by 26.8%. It was estimated that about 61% of arginase1 is bound to the membrane mediated by flotillin-1. The arginase activity in diabetic patients was significantly higher than that of the controls (752.4+/-38.5 U/mg protein vs 486.7+/-28.7 U/mg protein).     

Assay and kinetics of arginase

A sensitive colorimetric assay for arginase was developed. Urea produced by arginase was hydrolyzed to ammonia by urease, the ammonia was converted to indophenol, and the absorbance was measured at 570 nm. The assay is useful with low concentrations of arginase (0.5 munit or less than 1 ng rat liver arginase) and with a wide range of arginine concentrations (50 microM to 12.5 mM). Michaelis-Menten kinetics and a Km for arginine of 1.7 mM were obtained for Mn2+-activated rat liver arginase; the unactivated enzyme did not display linear behavior on double-reciprocal plots. The kinetic data for unactivated arginase indicated either negative cooperativity or two types of active sites on the arginase tetramer with different affinities for arginine. The new assay is particularly well suited for kinetic studies of activated and unactivated arginase.     

Properties of arginase from liver of Macaca fascicularis: Comparison of normals with red blood cell arginase deficient monkeys

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 (<0.2 µmol arginine cleaved/g Hb/min; normal =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 mmol arginine cleaved/g protein/min. The apparent K _m for arginine of arginase in the livers of the RBC-deficient monkeys was 7.4 and 5.9mm and in the normal monkey was 6.9mm. Similar patterns of heat denaturation were seen at 69 C without Mn²⁺ present and 79 C in the presence of 20mm Mn²⁺. No difference in mobility on either acidic or basic polyacrylamide gels for liver arginase from 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.     

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

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.     

Boronic acid-based arginase inhibitors in cancer immunotherapy

Arginase is an enzyme that converts l-arginine to l-ornithine and urea in the urea cycle. There are two isoforms of arginase in mammals: ARG-1 and ARG-2. l-Arginine level changes occur in patients with various types of affliction. An overexpression of arginase leads to the depletion of arginine and then to inhibition of the growth of T and NK cells, and in effect to the tumor escape of the immune response. Based on those observations, an inhibition of arginase is proposed as a method to improve anti-tumor immune responses (via an activation and proliferation of T and NK cells). Boronic acid derivatives as arginase inhibitors are leading, potential therapeutic agents for the treatment of several diseases. All these compounds are derived from the original 2-(S)-amino-6-boronohexanoic acid (ABH), the first boronic acid arginase inhibitor proposed by Christianson et al. This article focuses on the review of such sub-class of arginase inhibitors and highlights their SAR and PK properties. It covers molecules published until early 2020, including patent applications.     

An assay for arginase in chicken kidney.

1. The enzyme arginase in chicken kidney is associated with mitochondria and the mitochondrial membranes must be disrupted to obtain maximum activity. 2. When the membranes were disrupted by sonication, approximately 30% higher 2. When the membranes were disrupted by sonication, approximately 30% higher arginase activity was observed than with the nonsonicated samples. 3. The optimum pH for assay of chick kidney arginase was 9.7-9.8. Prior heat treatment with Mn2+ decreased arginase activity. 4. Highest enzyme activity was obtained by using sonicated preparations and measuring initial reaction velocity during the first 1-2 min of incubation.     

Prenatal Diagnosis of Tay-Sachs Genotypes

Hexosaminidase activity was determined in cultured and uncultured amniotic fluid cells taken from seven pregnant women who had previously given birth to infants with Tay-Sachs disease. Complete deficiency of hexosaminidase A was found in one case, indicating a Tay-Sachs fetus. The diagnosis was confirmed on examination of various tissues after therapeutic abortion. Of the other six cases three were considered heterozygous and three homozygous normal. These diagnoses were confirmed postnatally on examination of cord blood leucocytes, peripheral leucocytes, and urine. The activity of hexosaminidase A is appreciably decreased in dead cells and hence in uncultured amniotic fluid cells. Hence reliable identification in utero of the three genotypes may be achieved only by examining the cultured living amniotic cells.     

Purification and properties of arginase of rat kidney

l-Arginase from rat kidney was partially purified and some properties were compared with those of l-arginase of rat liver. The kidney enzyme was firmly bound to the mitochondrial fraction and after solubilization required arginine or an unknown factor in tissue extracts for stabilization after dialysis. The two enzymes differed also in stability with respect to acetone treatment, heating or freezing. In further contrast with liver arginase, arginase from kidney was not adsorbed to CM-cellulose at pH7.5 and its activity was not increased by incubation with Mn(2+). Other differences were seen in relative specificities for substrates, ratio of hydrolysis rates with high and low concentrations of arginine and effects of certain inhibitors. Antisera prepared to pure liver arginase did not cross-react with partially purified kidney arginase.     

Amniotic fluid arginase in women at term]

Study on 34 cases. A considerable arginasic activity is observed in amniotic fluid in women at the end of pregnancy. This activity is weak, but increased by Mn2+ (about 5 to 8 times). The total amniotic fluid is more active than the surpernatant, the deposit of which has been eliminated. An important part of arginasic activity results from the elements of the deposit (amniotic cells, foetal cells and eventualy erythrocytes in hemorragic amniotic fluid).     

Prenatal diagnosis of Sanfilippo disease type B

Summary The prenatal diagnosis of a fetus affected with Sanfilippo disease type B is described. The deficiency of -N-acetylglucosaminidase in the cultured amniotic fluid cells was shown by a microassay enabling early prenatal diagnosis. In addition an increased level of heparan sulphate was demonstrated in the amniotic fluid by two-dimensional electrophoresis of glycosaminoglycans. The latter result confirmed the value of this test as an adjunctive method in the prenatal diagnosis. The pregnancy was terminated and the prenatal diagnosis was confirmed by enzyme analysis of cultured fetal fibroblasts and fetal liver.     

Immunobiological methods in the prenatal diagnosis and evaluation of foetal neural tube defects

In cases of foetal neural tube defects (NTDs) macrophages are present in the amniotic fluid. These mononuclear cells were analysed with immunobiological methods: functional markers as Fc and C3b receptor-mediated phagocytosis and chemoluminescence have been studied. It was found that most of these pathognomic cells ingest haemolysin sensitized sheep red blood cells (sSRBCs) and zymosan (Mannozym) particles opsonized with fresh human serum. Amniotic fluid cell suspensions from pregnancies with and without foetal NTDs were stimulated by opsonized Mannozym; consistently higher chemoluminescence activities were found when open lesion was present. The evaluation of multiple functional markers is likely to provide a better basis for understanding the characteristics of amniotic fluid macrophages and may contribute to the prenatal diagnosis of NTDs.     

Functional heterogeneity among peritoneal macrophages: III. No evidence for the role of arginase in the inhibition of tumor cell growth by supernatants from macrophages or macrophage subpopulation cultures

The adherent population of peritoneal exudate cells (PE) obtained from rats and mice was analyzed for arginase activity in order to determine whether this enzyme has a role in tumor-growth-inhibitory activity. Freshly obtained tumor-growth-inhibitory rat PE cells had little or no arginase activity compared to the high levels of enzyme activity of mouse PE cells. Even after culturing, rat PE cells contained arginase activity 10 times less than that observed with comparable numbers of cultured or noncultured mouse cells. Subpopulations of mouse and rat PE macrophages, analyzed for arginase activity, showed that the light-density populations from cultured rat PE cells and noncultured mouse PE cells expressed arginase activities greater than that seen with heavy-density cells. However, the light-density rat PE cells expressed significantly less arginase activity than did the mouse cells. In attempts to test whether the inability of tumor cells to grow in supernatants or dialyzed supernatants from PE macrophage cultures is due to an arginine depletion, 200 μg/ml of the amino acid was added to the supernatants. The tumor-growth-inhibitory activities of such supernatants, as well as those from supernatants from highly active light-density rat PE macrophage cultures, were not abrogated by the addition of arginine. There was no correlation between the high levels of arginase activity of light-density PE macrophages and their antitumor activity and no evidence that the tumor-growth-inhibitory activity of rat or mouse PE macrophages in the macrophage-tumor models we studied was due to an arginine depletion.     

Purification and characterization of Helicobacter pylori arginase, RocF: unique features among the arginase superfamily.

The urea cycle enzyme arginase (EC 3.5.3.1) hydrolyzes l-arginine to l-ornithine and urea. Mammalian arginases require manganese, have a highly alkaline pH optimum and are resistant to reducing agents. The gastric human pathogen, Helicobacter pylori, also has a complete urea cycle and contains the rocF gene encoding arginase (RocF), which is involved in the pathogenesis of H. pylori infection. Its arginase is specifically involved in acid resistance and inhibits host nitric oxide production. The rocF gene was found to confer arginase activity to Escherichia coli; disruption of plasmid-borne rocF abolished arginase activity. A translationally fused His(6)-RocF was purified from E. coli under nondenaturing conditions and had catalytic activity. Remarkably, the purified enzyme had an acidic pH optimum of 6.1. Both purified arginase and arginase-containing H. pylori extracts exhibited optimal catalytic activity with cobalt as a metal cofactor; manganese and nickel were significantly less efficient in catalyzing the hydrolysis of arginine. Viable H. pylori or E. coli containing rocF had significantly more arginase activity when grown with cobalt in the culture medium than when grown with manganese or no divalent metal. His(6)-RocF arginase activity was inhibited by low concentrations of reducing agents. Antibodies raised to purified His(6)-RocF reacted with both H. pylori and E. coli extracts containing arginase, but not with extracts from rocF mutants of H. pylori or E. coli lacking the rocF gene. The results indicate that H. pylori RocF is necessary and sufficient for arginase activity and has unparalleled features among the arginase superfamily, which may reflect the unique gastric ecological niche of this organism.     

Genotyping and prenatal assessment of collagen lysyl hydroxylase deficiency in a family with Ehlers-Danlos syndrome type VI.

Collagen lysyl and prolyl hydroxylase activities were measured in cultured fibroblasts from a child with clinical features of Ehlers-Danlos syndrome. Lysyl-to-prolyl hydroxylase activity ratios in cells from the proband, mother, father, and control were .24, .86, .52, and 1.00, respectively, providing a biochemical diagnosis of Ehlers-Danlos syndrome type VI and indicating an autosomal recessive mode of inheritance in this family. Prenatal assessment of lysyl hydroxylase deficiency was requested and accomplished for the first time during a subsequent pregnancy in the family. A series of control cultures established lysyl hydroxylase activity to be similar in cultured amniotic fluid cells (AF and F cells) and in cultured dermal fibroblasts. Cultured F and AF cells from the monitored pregnancy had enzyme activity similar to controls, indicating that the fetus should not be affected by lysyl hydroxylase deficiency. This finding was confirmed by demonstration of normal lysyl hydroxylase activity in fibroblasts cultured from the newborn baby. These studies show that cells cultured from second trimester amniotic fluid have collagen lysyl hydroxylase activity similar to that in dermal fibroblasts, making prenatal diagnosis of lysyl hydroxylase deficiency possible.     

Induction of differentiation of cultured mouse myeloid leukemic cells by arginase.

Mouse myeloid leukemic cells (Ml) could be induced by a factor in ascitic fluid to phagocytize, migrate in agar, and change into forms that were morphologically similar to macrophages and granulocytes. Arginase also induced these differentiation-associated properties of the cells. The Ml cells did not differentiate in culture medium containing arginine, but they differentiated into macrophages and granulocytes during culture in arginine-deficient culture medium. Therefore, the effect of arginase may be attribute to arginase-mediated arginine depletion.     

Heterogeneity for adenosine deaminase deficiency: Expression of the enzyme in cultured skin fibroblasts and amniotic fluid cells.

Adenosine deaminase (ADA) could be quantitated and the isozyme pattern characterized in cultured amniotic fluid cells. In 20 amniotic fluid cell cultures the mean specific activity was 14.3 U/g protein +/- 6.7 (SD) and compared favorably with values of 14.6 U/g protein +/- 6.8 (SD) observed in 26 cultures of skin fibroblasts. In cultures of skin fibroblasts established from two obligate heterozygotes for ADA deficiency, the specific activity of ADA was 7.0 and 7.7 U/g protein. The ADA isozyme pattern that existed in cultures of amniotic fluid cells was the same as that observed in cultured skin fibroblasts. This identification of the same apparent enzyme may permit the prenatal diagnosis of that form of combined immunodeficiency disease caused by ADA deficiency. Residual enzyme activity of less than 1% and 10% of the mean of normal fibroblasts could be measured in cultured fibroblasts from two unrelated children with ADA deficiency and combined immunodeficiency disease. The tissue-specific enzyme from cultured skin fibroblasts from the child with 10% residual activity had a faster electrophoretic mobility and greater heat stability than normal ADA. This enzymatic evidence indicates that at least two mutant alleles exist at the locus for ADA which predispose to combined immunodeficiency disease when present in the homozygous state.