Immunohistochemical localization of arginase II and other enzymes of arginine metabolism in rat kidney and liver.

Arginine is a precursor for the synthesis of urea, polyamines, creatine phosphate, nitric oxide and proteins. It is synthesized from ornithine by argininosuccinate synthetase and argininosuccinate lyase and is degraded by arginase, which consists of a liver-type (arginase I) and a non-hepatic type (arginase II). Recently, cDNAs for human and rat arginase II have been isolated. In this study, immunocytochemical analysis showed that human arginase II expressed in COS-7 cells was localized in the mitochondria. Arginase II mRNA was abundant in the rat small intestine and kidney. In the kidney, argininosuccinate synthetase and lyase were immunostained in the cortex, intensely in proximal tubules and much less intensely in distal tubules. In contrast, arginase II was stained intensely in the outer stripes of the outer medulla, presumably in the proximal straight tubules, and in a subpopulation of the proximal tubules in the cortex. Immunostaining of serial sections of the kidney showed that argininosuccinate synthetase and arginase II were colocalized in a subpopulation of proximal tubules in the cortex, whereas only the synthetase, but not arginase II, was present in another subpopulation of proximal tubules. In the liver, all the enzymes of the urea cycle, i.e. carbamylphosphate synthetase I, ornithine transcarbamylase, argininosuccinate synthetase and lyase and arginase I, showed similar zonation patterns with staining more intense in periportal hepatocytes than in pericentral hepatocytes, although zonation of ornithine transcarbamylase was much less prominent. The implications of these results are discussed.

Purification of ornithine aminotransferase by immunoadsorption.

Ornithine aminotransferase was purified by conventional biochemical methods from rat kidney, rat liver, and human liver. Affinity-purified antibodies raised to the rat kidney enzyme were used to produce an immunoadsorbent enabling a one-step purification of ornithine aminotransferase to be made from crude human liver extracts. The harsh chemical conditions often required to desorb immunoadsorbents were avoided by isolating antibodies with low functional affinity and employing an electrophoretic desorption method which allowed the enzyme activity to be retained. The close structural similarity between human and rat ornithine aminotransferase was demonstrated by immunodiffusion reactions. It was therefore possible to purify the enzyme from human liver using immobilized antibodies raised against rat kidney ornithine aminotransferase. Furthermore, desorption was more readily achieved due to the lower affinity for the human enzyme.

Comparison of rat and mouse ornithine aminotransferase with respect to molecular properties and regulation of synthesis.

A comparative study of the synthesis patterns and molecular properties of mouse and rat ornithine aminotransferase (OAT) was conducted. The two enzymes were found to be very similar with respect to catalytic properties, two-dimensional electrophoresis patterns of tryptic digests, amino acid compositions, and antibody cross-reactivity. In vitro translation assays for OAT synthesis on free polysomes isolated from livers at different times of day showed similar circadian fluctuations in OAT synthesis for both species. However, hybridization measurements revealed no circadian changes in the levels of hybridizable OAT mRNA in these livers. These results demonstrate that the circadian cycling of OAT synthesis is regulated at the level of translation in both the rat and the mouse.

Crystallization and properties of human liver ornithine aminotransferase.

Ornithine aminotransferase [EC 2.6.1.13] was purified and crystallized from human liver by a procedure involving heat treatment, chromatographies on DEAE-cellulose, Octyl-Sepharose CL-4B and Sephadex G-200, and crystallization. The purified enzyme appeared to be homogeneous on polyacrylamide gel electrophoresis with and without sodium dodecyl sulfate. The molecular weight of the enzyme was estimated as 44,000 by sodium dodecyl sulfate electrophoresis and as 177,000 by sucrose density gradient centrifugation, indicating that the enzyme is tetrameric. Various properties of the enzyme from human liver are similar to those of the enzyme from rat liver, including its molecular weight, pH optimum, Km values for ornithine, alpha-ketoglutarate and pyridoxal phosphate and specificity for amino acceptor from ornithine. The amino acid compositions of the two enzymes also have certain similarities, but the enzymes differ in electrophoretic mobility and antigenicity: the human enzyme moved more slowly to the anode, and on immunodiffusion analysis, the single precipitin lines formed between anti-human enzyme serum or anti-rat liver enzyme and the enzyme from human liver or lymphoblastoid cells and the rat liver enzyme fused with spur formation.

An improved preparation of antibody-coated polystyrene beads for sandwich enzyme immunoassay.

An improved preparation of antibody-coated polystyrene beads for sandwich enzyme immunoassay of human thyroid-stimulating hormone (TSH) was described. Rabbit anti-TSH IgG was purified by eluting at pH 2.5 from a TSH-Sepharose column, diluted 3 or 9 fold with normal rabbit IgG and used for coating polystyrene beads by physical adsorption. In a sandwich enzyme immunoassay of TSH using rabbit (anti-TSH) Fab'-beta-D-galactosidase conjugate, beta-D-galactosidase activities specifically bound to thus prepared polystyrene beads in the presence of TSH was 2.8-6.3 fold higher than those bound to polystyrene beads coated with anti-TSH IgG before purification. A similar effect was observed when guinea pig anti-pork insulin IgG, rabbit (anti-human IgE) IgG and goat (anti-human IgE) IgG were treated at pH 2.5. This improvement may be based on a conformational change of Fc in IgG molecule which was caused by the treatment at pH 2.5. Other sandwich immunoassays such as fluoro- and radio-immunoassays may also be improved in the same way.

Use of rabbit antiboty IgG bound onto plain and aminoalkylsilyl glass surface for the enzyme-linked sandwich immunoassay.

Rabbit antibody IgG was bound onto aminoalkylsilyl or plain glass rods by simple adsorption. For comparison, rabbit antibody IgG was also bound onto glutaraldehyde-activated aminoalkylsilyl glass rods. These antibody-glass rods were tested by the sandwich procedure using Fab' fragments of rabbit antibody conjugated with beta-D-galactosidase from Escherichia coli. The glutaraldehyde-activated aminoalkylsilyl glass showed the largest capacity to bind antigen and the plain glass showed the smallest. However, the antibody-glass rods prepared by simple adsorption were as useful for the sandwich immunoassay of macromolecular antigens as those prepared with glutaraldehyde. With all the antibody-glass rods prepared, 0.1 to 10 fmol of ornithine delta-aminotransferase from rat liver and 2,4-dinitrophenyl human IgG were measurable. More than 10 fmol of the antigens may be measurable with larger amounts of the antibody-beta-D-galactosidase complexes, although the non-specific binding of the complexes to the solid phase increases to limit the sensitivity of the immunoassay.

Enzyme-linked sandwich immunoassay of ornithine delta-aminotransferase from rat liver using antibody-coupled glass rods as solid phase.

A macromolecular antigen, ornithine delta-aminotransferase [EC 2.6.1.13] from rat liver (OAT) was assayed by the sandwich procedure using rabbit (anti-OAT) Fab'-beta-D-galactosidase complex and rabbit (anti-OAT) IgG-coupled glass rods as a solid phase. The Fab' fragments of the rabbit (anti-OAT) IgG were conjugated with beta-D-galactosidase [EC 3.2.1.23] from Escherichia coli using N, N'-o-phenylenedimaleimide. The rabbit (anti-OAT) IgG was coupled to the aminoalkylsilyl glass rods using glutaraldehyde. The rabbit (anti-OAT) IgG-coupled glass rods were incubated with OAT and then with the rabbit (anti-OAT) Fab'-beta-D-galactosidase complex. The amount of OAT was determined from the activity of beta-D-galactosidase bound to the glass rods. A minimum of 0.03 fmoles of OAT could be determined by this method and use of the glass rods gave greater reproducibility, and was more sensitive and simpler than use of Sepharose 4B.

Preparation and properties of ornithine-oxo-acid aminotransferase of rat kidney. Comparison with the liver enzyme.

Ornithine-oxo-acid aminotransferase (EC 2.6.1.13) from rat kidney was prepared as a single homogeneous protein as judged by polyacrylamide gel electrophoresis, ultracentrifuge analysis and double diffusion precipitin test. Content of pyridoxal phosphate, light absorption spectra, circular dicroism spectra, Km values, inhibitors, and electrophoretic mobilities of the proteins after reactions with group modifying reagents were similar for the ornithine-oxo-acid aminotransferases of rat kidney and liver. Rates of reaction with group modifying reagents, stabilities to storage at -15 degrees C, and stabilities to temperatures above 55 degrees C differed significantly for the two enzymes. The liver enzyme contained two more cysteine residues than the kidney enzyme as determined by three different methods. Heating the liver enzyme at 66-67 degrees C at pH 5.9 for 1 h decreased the thiol groups titratable by 5,5'-dithio-bis(2-nitrobenzoic acid) (Nbs2). Uncer the same conditions titratable thiol groups of the kidney enzyme were not decreased. Amino acid analysis revealed probably significant differences in tyrosine and isoleucine content in addition to cysteine. It was concluded that the primary structures of ornithine-oxo-acid aminotransferases of rat liver and kidney are not fully identical.

Immunochemical studies of serine dehydratase and ornithine aminotransferase regulation in rat liver in vivo.

Previous studies of serine dehydratase (EC 4.2.1.13) and ornithine aminotransferase (EC 2.6.1.13) adaptation in rat liver showed that in rats on a high protein diet, glucocorticoid administration increased serine dehydratase activity while simultaneously reducing the activity of ornithine aminotransferase. The present study examines the role of enzyme synthesis in the expression of these and other dissimilar adaptive characteristics of the two enzymes. Both enzymes were purified to crystallinity and used to prepare specific antibodies. Changes in the rate of synthesis of each enzyme during adaptation were then measured immunochemically. In rats fed ad libitum, the synthetic rates for both enzymes exhibited circadian rhythm, although enzyme levels remained relatively constant. The circadian cycle for ornithine aminotransferase synthesis was in phase with the cycles for body weight and relative liver weight (maxima at 9 a.m., minima at 9 p.m.) but was approximately 12 hours out of phase with the cycle for serine dehydratase synthesis. 9alpha-Fluoro-11beta, 21-dihydroxy-16alpha, 17alpha-isopted at 9 a.m., increased serine dehydratase synthesis and simultaneously decreased the synthesis of ornithine aminotransferase. When triamcinolone was injected at 9 p.m., however, serine dehydratase synthesis was not stimulated, although the reduction of ornithine aminotransferase synthesis was still produced. These results suggest that: (a) circadian cycling of synthesis may be a general phenomenon in enzyme regulation even though for enzymes with relatively long half-lives, such cycling may not be reflected as fluctuations in enzyme levels; (b) such circadian rhythmicity may also involve cyclic changes in the responsiveness of the enzyme-forming system to regulatory stimuli; (c) whereas the adaptive behavior of serine dehydratase typifies that of amino acid-catabolizing enzymes in general, the responses of ornithine aminotransferase denote a functional association of this enzyme with anabolic processes. On this basis, the possibility that ornithine aminotransferase plays a pivotal role in the regulation of urea cycle activity and nitrogen balance is discussed.