Impact of suitable control on a uniform interpretation of units for arginase assay

The arginase catalyzes the conversion of arginine into ornithine and urea. The activity of arginase serves as a critical diagnostic marker for several pathophysiological conditions. However, a specific, sensitive, and universal assay system for arginase with suitable control is elusive. Mostly amount of either urea or ornithine is estimated but an interpretation of the activity of arginase needs to be re-evaluated considering the endogenous level and influence of the substrate. This report; has been intended to evaluate methods of arginase assay and suitable controls. A conversion factor has been suggested for uniform interpretation of units for arginase assay.     

以酶标免疫吸附法测定大鼠肝脏精氨酸酶含量

本文利用丙酮沉淀、凝胶过滤、离子交换层析等方法提纯了大鼠肝脏精氨酸酶,在SDS-PAGE中表现为单一的蛋白质带,其亚基分子量为37,000.建立了大鼠肝精氨酸酶的酶标免疫吸附测定法(ELISA),比较了两种常规的精氨酸酶活性测定法与ELISA法,并初步探讨了ELISA法在精氨酸酶测定方面的一些应用。     

Determination of δ-aminolevulinate dehydratase activity by a specific fluorometric coupled-enzyme assay

A coupled-enzyme assay for the specific and sensitive determination of δ-aminolevulinate dehydratase activity has been developed. The assay specifically measured picomole quantities of the product, porphobilinogen, by its enzymatic conversion to uroporphyrinogen I and the fluorometric detection of oxidized uroporphyrin I. The coupled-enzyme assay was linear with time and protein concentration and required less than 3 h for 20 individual determinations. Under the standard assay conditions, 10 to 100 pmol of uroporphyrin I was reliably measured, representing 0.085 to 0.850 nmol/h of δ-aminolevulinate dehydratase activity per assay. In addition, the fluorometric assay was more sensitive than either the standard or the semimicro colorimetric methods. The specificity, rapidity, and sensitivity of this new fluorometric method facilitates the reliable determination of low levels of aminolevulinate dehydratase activity in small amounts of crude tissue homogenates or in cultured cells.     

A fluorescence-based assay for indoleamine 2,3-dioxygenase

A rapid and sensitive fluorescence-based bioassay for determination of indoleamine 2,3-dioxygenase (IDO) activity has been developed. This assay relies on the quantification of the amount of kynurenine produced in the assay medium by fluorescence and complements the standard absorbance and high-performance liquid chromatography (HPLC) assay methods. The fluorescence method has limits of detection similar to those of the standard assay methods. Measured activities of IDO, including in the presence of tryptophan-based inhibitors, were in statistical agreement with the absorbance and HPLC assay methods. The fluorescence-based assay was also suitable for assessment of IDO inhibition by compounds that are incompatible with the absorbance method.     

A new method for differential determination of basic natural forms of indolyl-3-acetic acid

A new ELISA method is proposed for differential quantitative determination of free (indolyl-3-acetic acid; IAA) and bound (indolyl-3-acetyl-L-aspartate) forms of natural auxins. There is similarity in results obtained by this and some traditionally used methods. The standard error of determination of the active form of IAA by our method is 1.5-2.0 times less than that using the traditional method. The method of quantitative differential determination of the main natural auxins does not require preliminary sample preparation, and this shortens assay time. The developed method has been used for practical determination of different forms of endogenous IAA in wheat and dandelion ovaries subjected to minimal treatment. This method can be used to investigate changes in the ratio of various hormonal forms of auxins that differ in their physiological activity in reproductive organs of angiosperms at various stages of reproduction.     

Arginase as a useful factor for the diagnosis of colorectal cancer liver metastases

The present work is a continuation of studies on arginase as a marker in the diagnosis of colorectal cancer liver metastases (CRCLM). The purpose of the study was the evaluation of the arginase test in comparison with other colorectal cancer tests such as CEA, CA 19-9 and biochemical markers of liver function such as aspartate aminotransferase (AST) and alanine aminotransferase (ALT). The studies were conducted on blood serum from 85 patients with CRCLM obtained one to two days before tumor resection. The control group comprised 140 healthy blood donors and 81 patients with various non-malignant gastrointestinal diseases. Raised arginase activity was observed in serum of 85% of CRCLM patients, whereas elevated levels of CEA and CA 19-9 were found in 63% and 42% of patients, respectively. The combination of CEA or CA 19-9 with the arginase assay improved their sensitivity, but the sensitivity of the combined parameters was not higher than that of the arginase test itself. AST and ALT activities were increased in about 30% of CRCLM patients. The specificity of the arginase test calculated for 221 control subjects was 76%. It can thus be concluded that the determination of serum arginase activity can be helpful in the diagnosis of patients with colorectal cancer liver metastases.     

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.     

Measurement of sarcoplasmic reticulum Ca2+-ATPase activity and E-type Mg2+-ATPase activity in rat heart homogenates

The presence of a high and nonlinear Ca2+-independent (or basal) ATPase activity in rat heart preparations makes difficult the reliable measurement of sarcoplasmic reticulum (SR) Ca2+-ATPase activity by usual methods. A spectrophotometric assay for the accurate determination of SR Ca2+-ATPase activity in unfractionated homogenates from rat heart is described. The procedure is based on that reported by Simonides and van Hardeveld (1990, Anal. Biochem. 191, 321-331) for skeletal muscle homogenates. To avoid overestimation of the Ca2+-ATPase activity of cardiac homogenates that occurs when sequential measurements of total and basal ATPase activities are performed, two parallel and independent assays are required: one with low (micromolar) and other high (millimolar) calcium concentration. Addition of thapsigargin (0.2 microM) blocked totally the activity considered as Ca2+-ATPase activity. Using this method, the rat heart homogenate Ca2+-ATPase activity was 10.5 +/- 2.0 micromol. min-1 x g-1 tissue wet weight (n = 8). Likewise, a spectrophotometric assay for measuring E-type Mg2+-ATPase activity in cardiac total homogenates has been developed, comparing the following characteristics of the enzymatic activity in homogenate and a membrane-enriched fraction: first-order rate constant for ATP-dependent inactivation, Km for ATP, and effects of concanavalin A, Triton X-100, and specific inhibitors.     

pH-sensitive control of arginase by Mn(II) ions at submicromolar concentrations

The manganese dependence of arginase was reinvestigated with extracts of mouse liver to see whether more physiological properties were displayed than have been reported for the purified enzyme. In a preincubation with Mn(II) ions at 37 degrees C the enzyme underwent a slow and reversible activation. At least 90-95% of the activation achieved was dependent on Mn2+. However, no Mn2+ was required for catalytic activity in the assay. The activation showed little dependence upon pH over the range 6.5-9.5, whereas the catalytic activity increased 12-fold in apparent accord with the titration curve of an ionizable group of pKa 7.9. The Mn2+ dependence of arginase activation obeyed Michaelis-Menten kinetics, with Kd varying from 0.3 microM at pH 6.8 to 0.08 microns at pH 7.7. Free Mn2+ concentrations were established in these assays with a trimethylenediaminetetraacetate-Mn buffer. Vmax increased about three-fold over this range. The calculated arginase activity at 0.05 microM Mn2+ increases about nine-fold over this physiological pH range. An enzyme model is proposed to explain these findings. The activity of arginase at "physiological" [Mn2+] and the pronounced pH dependence conferred upon it are consistent with a recently revised role for the urea cycle in the control of bicarbonate and pH in the body. It appears possible that arginase loses Mn2+ sensitivity during the usual purification.     

Increased arginase activity during lymphocyte mitogenesis

A sensitive assay for arginase activity was developed using [guanidino-¹⁴C]arginine as substrate and measuring the production of ¹⁴CO₂ from [¹⁴C]urea in the presence of urease. Arginase activity was measured in bovine lymphocytes after activation by Concanavalin A. The specific enzymatic activity of arginase doubled in 6 hours and increased nearly 4-fold by 24 hours after stimulation. It is suggested that the role of arginase in these cells is to provide ornithine as substrate for the synthesis of putrescine, precursor of the polyamines spermidine and spermine.     

Determination of argininosuccinate lyase and arginase activities with an amino acid analyzer

The measurement of argininosuccinate lyase (ASase) and arginase, both in liver and erythrocytes, was developed by using a commercial amino acid analyzer. The method is based upon the use of two different substrates, argininosuccinate and arginine for ASase and arginase, respectively, and the measurement of only one final metabolite: ornithine. The use of ornithine as a marker of biological activity of ASase is related to the fact that in the urea cycle, the specific activity of arginase is much higher than that of ASase; thus, during in vitro determinations, arginine, which is the product of ASase, is rapidly converted to ornithine. The sensitivity of the methods is very high since we were able to detect both activities using very diluted rat liver homogenates (0.10 mg protein/ml) or few microliters of human blood. In rat liver the Vmax for ASase and arginase were respectively 0.54 and 140 mumol/h/mg protein; the apparent Km values 1.25 and 13.5 mM. In human erythrocytes the Vmax for the same enzymes were 7.2 and 170 nmol/h/mg Hb and the apparent Km values were 0.66 and 9.5 mM. In 10 healthy volunteers the specific activity of ASase and arginase determined in blood were respectively 8.60 +/- 0.46 and 124.1 +/- 14.5 nmol/h/mg Hb. The results obtained from 2 patients suffering from argininosuccinic aciduria were also reported. In these latter cases while ASase was not detectable in blood, arginase activity was at the lowest end of the confidence limits determined in healthy volunteers.     

Determination of peroxisomal fatty acyl-CoA oxidase activity using a lauroyl-CoA-based fluorometric assay

A simple, sensitive fluorometric method for the determination of peroxisomal fatty acyl-CoA oxidase (EC 1.3.99.3) activity has been developed. Studies of enzyme activity relative to subcellular distribution and to clofibrate induction indicate that this assay is specific for peroxisomal fatty acyl-CoA oxidase. The lauroyl-CoA-dependent production of H2O2 is quantitated by measuring the oxidation of 4-hydroxyphenyl-acetic acid to a fluorescent product in a horseradish peroxidase-coupled assay. Assays can be performed in either a fixed time or continuous mode. In either mode, H2O2 production is related to a change in fluorescence intensity through use of a standard curve generated with known amounts of H2O2. The use of lauroyl-CoA (12:0), rather than the more generally used substrate palmitoyl-CoA (16:0), provides significant advantages. Much of the substrate inhibition problem associated with palmitoyl-CoA has been avoided, and a greater than 4.5-fold higher specific activity has been achieved compared with a palmitoyl-CoA-based assay. In the fixed-time mode, linearity relative to time and to the amount of enzyme added has been established without resorting to the use of bovine serum albumin as a substrate binding medium. Sensitivity is estimated to be at least equal to that of the most sensitive methods reported, while reliability, versatility and range have been improved. Use of this method should greatly facilitate the study of peroxisomal beta-oxidation regulatory mechanisms in hepatocyte cell culture systems as well as in other circumstances where low activities or small samples must be assayed.     

Expression, purification and characterization of arginase from Helicobacter pylori in its apo form

Arginase, a manganese-dependent enzyme that widely distributed in almost all creatures, is a urea cycle enzyme that catalyzes the hydrolysis of L-arginine to generate L-ornithine and urea. Compared with the well-studied arginases from animals and yeast, only a few eubacterial arginases have been characterized, such as those from H. pylori and B. anthracis. However, these enzymes used for arginase activity assay were all expressed with LB medium, as low concentration of Mn(2+) was detectable in the medium, protein obtained were partially Mn(2+) bonded, which may affect the results of arginase activity assay. In the present study, H. pylori arginase (RocF) was expressed in a Mn(2+) and Co(2+) free minimal medium, the resulting protein was purified through affinity and gel filtration chromatography and the apo-form of RocF was confirmed by flame photometry analysis. Gel filtration indicates that the enzyme exists as monomer in solution, which was unique as compared with homologous enzymes. Arginase activity assay revealed that apo-RocF had an acidic pH optimum of 6.4 and exhibited metal preference of Co(2+)>Ni(2+)>Mn(2+). We also confirmed that heat-activation and reducing regents have significant impact on arginase activity of RocF, and inhibits S-(2-boronoethyl)-L-Cysteine (BEC) and Nω-hydroxy-nor-Arginine (nor-NOHA) inhibit the activity of RocF in a dose-dependent manner.     

Two continuous coupled assays for ornithine-δ-aminotransferase

We have developed two new continuous coupled assays for ornithine-δ-aminotransferase (OAT) that are more sensitive than previous methods, measure activity in real time, and can be carried out in multiwell plates for convenience and high throughput. The first assay is based on the reduction of Δ¹-pyrroline-5-carboxylate (P5C), generated from ornithine by OAT, using human pyrroline 5-carboxylate reductase 1 (PYCR1), which results in the concomitant oxidation of NADH (nicotinamide adenine dinucleotide, reduced form) to NAD⁺ (nicotinamide adenine dinucleotide, oxidized form). This procedure was found to be three times more sensitive than previous methods and is suitable for the study of small molecules as inhibitors or inactivators of OAT or as a method to determine OAT activity in unknown samples. The second method involves the detection of l-glutamate, produced during the regeneration of the cofactor pyridoxal 5’-phosphate (PLP) of OAT by an unamplified modification of the commercially available Amplex Red l-glutamate detection kit (Life Technologies). This assay is recommended for the determination of the substrate activity of small molecules against OAT; measuring the transformation of l-ornithine at high concentrations by this assay is complicated by the fact that it also acts as a substrate for the l-glutamate oxidase (GluOx) reporter enzyme.     

Biochemical and molecular characterization of mitochondrial membrane-bound arginase in <Emphasis Type="Italic">Heteropneustes fossilis</Emphasis>

The two predominant forms of arginase, cytosolic Arginase-I and mitochondrial Arginase-II, catalyze hydrolysis of arginine into ornithine and urea. Based on presence of arginase activity in extracts using potassium chloride (KCl), mitochondrial membrane-bound arginase has also been suggested. However, the activity of arginase in fractions obtained after KCl-treatment may be either due to leakage of mitochondrial arginase or release of adhered cytosolic arginase to cell organelles having altered net charge. Therefore, it has been intended to analyse impact of KCl on ultra-structural properties of mitochondria, and biochemical analysis of mitochondrial membrane-bound proteins and arginase of Heteropneustes fossilis. Liver of H. fossilis was used for isolating mitochondria for analysis of ultrastructural properties, preparing cytosolic, mitochondrial, and mitochondrial-membrane bound extracts after treatment of KCl. Extracts were analysed for arginase activity assay, protein profiling through SDS-PAGE and MALDI MS/MS. The KCl-mediated modulation in polypeptides and arginase were also evaluated by PANTHER, MitoProt and IPSORT servers. The effects of KCl on ultra-structural integrity of mitochondria, activity of arginase, modulation on mitochondrial proteins and enzymes including arginase were observed. The 48 kDa polypeptide of mitochondrial fraction, that showed KCl-dependent alteration matched with Myb binding protein and 30 kDa bands resembles to arginase after MALDI MS/MS analysis. Results indicate KCl-dependent ultrastructural changes in mitochondria and release of mitochondrial arginase. The proposed membrane bound mitochondrial arginase could be mitochondrial arginase-II or altered form of cytosolic arginase-I contributing to KCl-induced arginase activity in H. fossilis.     

A colorimetric 96-well microtiter plate assay for the determination of urate oxidase activity and its kinetic parameters

Urate oxidase (E.C.1.7.3.3; uricase, urate oxygen oxidoreductase) is an enzyme of the purine breakdown pathway that catalyzes the oxidation of uric acid in the presence of oxygen to allantoin and hydrogen peroxide. A 96-well plate assay measurement of urate oxidase activity based on hydrogen peroxide quantitation was developed. The 96-well plate method included two steps: an incubation step for the urate oxidase reaction followed by a step in which the urate oxidase activity is stopped in the presence of 8-azaxanthine, a competitive inhibitor. Hydrogen peroxide is quantified during the second step by a horseradish peroxidase-dependent system. Under the defined conditions, uric acid, known as a radical scavenger, did not interfere with hydrogen peroxide quantification. The general advantages of such a colorimetric assay performed in microtiter plates, compared to other methods and in particular the classical UV method performed with cuvettes, are easy handling of large amounts of samples at the same time, the possibility of automation, and the need for less material. The method has been applied to the determination of the kinetic parameters of rasburicase, a recombinant therapeutic enzyme.     

酵母全细胞苯丙氨酸鲜氨酶（PAL）活性的紫外分光光度测定法

本文报告以L-苯丙氨酸 (L-phe) 为底物,酵母全细胞作酶源,酶促生成产物反式-肉桂酸 (t-Ca)测定苯丙氨解氨酸 (PAP,EC_(4.3.1.5) 活性的紫外分光光度法。测定程序包括标准物质t-Ca的加样试验,绝对回收率试验,线性回归分析的整套定量分析研宄步骤,建立了一套经过修改的Kalghatgi和Subba Rao(1975) PAL 活性测定法。此法具有良好的准确度和精密度,已经用于评价具有PAL活性的酵母菌株在液体培养物中细胞生长和PAL活性形成的时间过程研究。     

A nonradioactive assay method for determination of enzymatic activity of D-ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco)

A sensitive and nonradioactive assay method for activity determination of Rubisco is described. The method is based on thin-layer chromatographic separation of 3-phosphoglycerate (3-PGA) and D-ribulose-1,5-bisphosphate (RuBP). This assay method allows the quantitative determination of Rubisco activity. Rates of carbon dioxide fixation on RuBP determined by this method were comparable to those obtained independently by other methods. This assay method is reproducible and relatively free from interference.     

Relationship among managanese, arginase, and nitric oxide in childhood asthma

It has been demonstrated that the lowest intakes of manganese (Mn) were associated with more than a fivefold increased risk of bronchial reactivity. It was also known that nitric oxide (NO) production was found to be significantly higher in asthmatics. There is a reciprocal pathway between arginase and nitric oxide synthase (NOS) for NO production, and Mn is required for arginase activity and stability. We investigated plasma NO, arginase, and its cofactor Mn levels to evaluate this reciprocal pathway in patients with childhood asthma. Arginase activities and Mn and NO levels were measured in plasma from 31 patients with childhood asthma and 22 healthy control subjects. Plasma arginase activities and Mn concentrations were found to be significantly lower and NO levels were significantly higher found to be significantly lower and NO levels were significantly higher in patients with childhood asthma as compared to the control subjects. There was a significantly positive correlation between plasma Mn and arginase and negative correlations between arginase and NO values and Mn and NO values in patients with childhood asthma. These data indicate that the lower concentration of Mn could cause lower arginase activity and this could also upregulate NO production by increasingl-arginine content in patients with childhood asthma.     

Production and characterization of monoclonal antibodies to rat liver arginase

Rat liver arginase was purified and five monoclonal antibodies were produced by fusion of spleen cells from a Balb/c mouse and the myeloma cell line P3-X36-Ag-U1. One, R2D19, of five antibodies belonged to the IgG2a subclass, the other four, R1D81, R1G11, R2E10, and R2G51, were of the IgG1 type. The R1D81 cross-reacted with human liver arginase. This antibody inhibited the arginase activity, competing with arginine. These results suggest that R1D81 binds to the catalytic site of arginase. The R2D19 also inhibited the enzyme activity but acted as a noncompetitive inhibitor. With the use of R1D81 and a polyclonal anti-human liver arginase antibody conjugated with alkaline phosphatase, a sandwich enzyme-linked immunosorbent assay (ELISA) was developed for the quantification of human arginase. Specificity of monoclonal antibodies for rat liver arginase was examined by means of the sandwich ELISA. Eight pairs of monoclonal antibodies could form a sandwich with the arginase. Only the R2E10 could be used for both the first and the second antibody in the sandwich system. In other cases, monoclonal antibodies could not be interchanged between solid and liquid phase.