Five forms of arginase in human tissues

Five forms of arginase, A1, A2, A3, A4, and A5, were found to be present in human tissues. The molecular weight of all these forms is the same, 120,000, but they differ in the behavior on DEAE- and CM-cellulose, electrophoretic mobility, isoelectric point, and immunochemical properties. Forms A1 from kidney and A5 from liver show complete immunological incompatibility, whereas forms A2 from liver, A3 from salivary gland, and A4 from kidney exhibit partial incompatibility with respect to each other and to forms A1 and A5.     

Widespread expression of arginase I in mouse tissues. Biochemical and physiological implications.

Arginase I (AI), the fifth and final enzyme of the urea cycle, detoxifies ammonia as part of the urea cycle. In previous studies from others, AI was not found in extrahepatic tissues except in primate blood cells, and its roles outside the urea cycle have not been well recognized. In this study we undertook an extensive analysis of arginase expression in postnatal mouse tissues by in situ hybridization (ISH) and RT-PCR. We also compared arginase expression patterns with those of ornithine decarboxylase (ODC) and ornithine aminotransferase (OAT). We found that, outside of liver, AI was expressed in many tissues and cells such as the salivary gland, esophagus, stomach, pancreas, thymus, leukocytes, skin, preputial gland, uterus and sympathetic ganglia. The expression was much wider than that of arginase II, which was highly expressed only in the intestine and kidney. Several co-localization patterns of AI, ODC, and OAT have been found: (a) AI was co-localized with ODC alone in some tissues; (b) AI was co-localized with both OAT and ODC in a few tissues; (c) AI was not co-localized with OAT alone in any of the tissues examined; and (d) AI was not co-localized with either ODC or OAT in some tissues. In contrast, AII was not co-localized with either ODC or OAT alone in any of the tissues studied, and co-localization of AII with ODC and OAT was found only in the small intestine. The co-localization patterns of arginase, ODC, and OAT suggested that AI plays different roles in different tissues. The main roles of AI are regulation of arginine concentration by degrading arginine and production of ornithine for polyamine biosynthesis, but AI may not be the principal enzyme for regulating glutamate biosynthesis in tissues and cells.     

Microheterogeneity of molecular forms of arginase in mammalian tissues

Two isoforms of arginase, A1 and A2, were found in rat liver, submaxillary gland and kidney as well as beef kidney. In beef liver, however, A2 was the only detectable form. Two additional forms, A3 and A4, found only in rat kidney were probably artifactitious. A1 and A2 exhibited chromatographic and immunological microheterogeneity. While A1 in rat liver and submaxillary gland was excluded by DEAE-cellulose (pH 8.3) and retained on CM-cellulose (pH 7.5), that (A'1) in beef and rat kidneys was excluded by both ion-exchangers. A2 in all tissues was retained on DEAE-cellulose, but not on CM-cellulose. Both A1 and A2 in rat liver and beef kidney, A1 from rat submaxillary gland and A2 from beef liver were precipitated by antibodies to rat and beef liver arginases. None of the forms in rat kidney (A1, A2, A3 and A4) showed any cross-reactivity to either antibody. Rat submaxillary gland A2 was precipitated by anti-rat liver arginase, but activated by anti-beef liver arginase. While the major molecular forms were A1 in rat liver and submaxillary gland and A2 in beef liver and rat kidney, the two forms occurred in equal proportions in beef kidney. It appears that different isoforms might function as components of the urea cycle in the liver of different mammals and of the arginine catabolic pathway in different extrahepatic tissues.     

Crystallization and oligomeric structure of rat liver arginase.

Rat liver arginase, a manganese-metalloenzyme, has been crystallized from polyethylene glycol 8000 in N,N-bis(2-hydroxyethyl)glycine (Bicine) buffer at pH 8.5. Crystals form as either cubes or pyramids and belong to space group P3(1) (or P3(2)) with hexagonal unit cell dimensions a = b = 88.9 A, c = 114.8 A, or a = b = 88.5 A, c = 104.5 A; the variation along the c axis does not correlate with the external crystal morphology of cube or pyramid-shaped. X-ray diffraction data are measured to a limiting resolution of 2.4 A. Given the volume constraints of the unit cell it is likely that rat liver arginase is a trimer, with three 35,000 Da monomers in the asymmetric unit. This resolves a persistent ambiguity regarding the oligomeric structure of this enzyme.     

Hybridization of subunits of rat liver arginase A1 and rat kidney arginase A4

Recombination of subunits of rat liver arginase A1 and rat kidney arginase A4 yielded a product which in polyacrylamide gel electrophoresis and DEAE-cellulose chromatography separated into five proteins with arginase activity. Proteins I and V corresponded in polyacrylamide gel-electrophoresis, DEAE-cellulose chromatography and immunological properties to the parental forms A1 and A4, respectively. Formation of five arginase hybrids proved the tetrameric structure of native arginases.     

Chemical modification of rat liver arginase

Chemical modifications were used to search for catalytically important residues of rat liver arginase. The results of carbamoylation, nitration and diazotization suggest that lysyl and tyrosyl residues are not involved in the catalytic function of arginase. The modification of 5--6 tryptophanyl residues by N-bromosuccinimide or 2-hydroxy-5-nitrobenzyl bromide led to about 90% inhibition of the enzyme activity. Photooxidation of 21 histydyl residues also led to considerable inactivation of arginase. The modification of tryptophanyl and histidyl residues did not cause dissociation of the enzyme into subunits.     

A comparative polyacrylamide gel electrophoretic study of arginase in vertebrate tissues

The electrophoretic behaviour of arginase in the tissue extracts of rat, beef, lizard and frog was studied by bidirectional polyacrylamide gel electrophoresis. The enzyme from rat liver and submaxillary gland migrated to the cathode with the activity concentrated in a single peak. Arginase from beef liver emerged as a single peak of anodal migration with a significant shoulder in the sample gel. Frog liver and kidney enzymes also appeared as single peaks with a distinct anodal movement. The activity in mammalian kidney and lizard liver and kidney resolved into two peaks of anodal migration suggesting the presence of two isoenzymes of arginase in these tissues.     

Reactivation of the EDTA-treated arginase from rat and calf liver.

1. The anionic calf liver arginase, like the cationic rat liver enzyme, is inactivated by EDTA-treatment. The activity is fully restored by Mn2+. A smaller effect is observed with Cd2+, Ni2+ and Co2+. 2. The EDTA-inactivated calf liver arginase, unlike the rat liver enzyme, does not dissociate into subunits, and its mol.wt. (120 000) is unchanged. 3. The reactivation of rat liver arginase subunits (mol.wt. 30 000) by Ni2+ is accompanied, similarly as in the case of Mn2+, by reassociation to the form of mol.wt. 120 000, i.e. the same as for the native enzyme. 4. It is suggested that Mn2+ in arginase is bound at the active site and at the site responsible for maintenance of the oligomeric structure. In calf liver enzyme this binding site is inaccessible to the chelating agent.     

Circular dichroic properties of rat liver arginase

• 1.1. Rat liver arginase contains over 50% of the α-helical and about 10% of β-pleated structures.
• 2.2. The manganese ions do not cause the changes in the far ultraviolet CD spectra of the enzyme, whereas they induce the optical activity at 280 nm.
• 3.3. The circular dichroic changes at near ultraviolet region coincide with the activation of arginase.

     

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.