Demonstration of plasma-membrane adenosine diphosphatase activity in rat lung

The adenosine diphosphatase (ADPase) activity of rat lung has been investigated. Subcellular fractionation of lung tissue homogenates by sucrose density gradient centrifugation has shown the ADPase activity to be associated with the plasma membrane. ADPase was solubilised from the membranes and fractionated by ammonium sulphate precipitation to separate a specific, low-Km ADPase from non-specific alkaline phosphatase activity. The solubilised ADPase has a Km of 50 microM at pH 7.5 and appears to be distinct from ATPase.     

Subcellular localization and properties of rat liver adenosine diphosphatase.

ADPase (adenosine diphosphatase) was assayed in rat liver homogenates with [beta-32P]ADP as substrate. The activity had a pH optimum of 8.0 and was strongly activated by Mg2+. The intracellular localization was determined by analytical subcellular fractionation with single-step sucrose-density-gradient centrifugation. Selective membrane perturbants were used to enhance the resolution of the various organelles. ADPase was localized to the mitochondria. Mitochondria were isolated by differential centrifugation and subfractionated by selective disruption of the inner and outer membranes. The intramitochondrial localization of ADPase was compared with various marker enzymes and was shown to be concentrated in the outer-membrane fractions. The effects of various inhibitors on the ADPase activity were determined and the possibility that the activity could be due to known enzyme systems was considered. It is concluded that ADP degradation is due to a hitherto unrecognized mitochondrial enzyme.     

Properties and subcellular localization of adenosine diphosphatase in rat heart

Some properties and subcellular localization of adenosine diphosphatase (ADPase) activity from rat heart have been investigated. The pH optimum was 7.4, maximal activity was found with 5 mM MgCl2, and the apparent Km was 20 microM. ADPase activity was strongly inhibited by NaF and AppNHp, and to a lesser extent by AMP and GppNHp. The enzyme was not inhibited by p-nitrophenylphosphate, beta-glycerophosphate, or pyridoxal phosphate. The distribution of ADPase activity in subcellular fractions obtained by differential centrifugation parallel ouabain-sensitive (Na+-K+)ATPase and 5'-nucleotidase activities, suggesting a plasma membrane-bound localization. The functional significance of ADPase in adenosine production and hemostasis is discussed.     

REGIONAL DISTRIBUTION AND PROPERTIES OF THE GLYCINE CLEAVAGE SYSTEM WITHIN THE CENTRAL NERVOUS SYSTEM OF THE RAT: EVIDENCE FOR AN ENDOGENOUS INHIBITOR DURING IN VITRO ASSAY

—The activity of the glycine cleavage system (GCS) was determined in homogenates from five specific regions of the rat CNS (telencephalon, midbrain, cerebellum, medulla-pons, and spinal cord). An inverse trend was noted between the glycine content and the specific activity of the GCS in the regions. A 25-fold range in the enzyme activities was found between the telencephalon (highest) and the spinal cord (lowest). The properties of the GCS activity in CNS homogenates agreed with those properties previously described for this system in partially purified preparations of liver and brain mitochondria (Kikuchi , 1973; Bruin et al., 1973). Within the CNS homogenates, the liberation of CO₂ from the carboxyl carbon of glycine was quantitatively coupled to the formation of serine. The presence of an endogenous inhibitor(s) within neural tissues was suggested by the non-additivity of the activities when homogenates from the various regions were combined. Moreover, homogenates of CNS tissue inhibited the GCS activity of liver homogenates, and an inverse relationship was found between the level of GCS activity in a given region of the CNS and its ability to inhibit the GCS activity of liver homogenates. This inhibition of liver activity was greatest when liver was incubated with homogenates of spinal cord (86%) and lowest when incubated with homogenates of telencephalon (20%). Because of this endogenous inhibition, the apparent activity of the GCS measured in vitro may not reflect the contribution of this enzyme system in the metabolism of glycine in vivo. Although the significance of this inhibition is not known, a possible role is discussed for the regulation of the levels in glycine and one-carbon pools within the CNS.     

Developmental Pattern for Deoxyhypusine Hydroxylase in Rat Brain

Deoxyhypusine hydroxylase catalyzes the formation of hypusine from deoxyhypusine in a precursor form of eukaryotic initiation factor 4D (eIF-4D). The enzymatic activity was examined in mammalian brain homogenates and the results were consistent with the existence of deoxyhypusine hydroxylase levels comparable to those occurring in other mammalian tissues. Interspecies differences in the enzyme distribution were quite limited, with the highest specific activity values observed in cow brain (1.82 units/ mg of protein). In the rat the enzyme was found to be unevenly distributed among various brain regions. The parietal cortex contained the highest specific activity (2.1 units/mg of protein). Rat brain deoxyhypusine hydroxylase was mainly present in the postmicrosomal supernatant (81% of the total activity). The highest specific activity (3 units/mg of protein) was observed in the rat brain during the first few days of life. Thereafter the activity started to decline, and continued to do so for 15 days, remaining throughout the rest of life at levels of less than one-half that of newborn.     

Studies on the nature of adenosine diphosphatase activity from rat liver mitochondria

Adenosine diphosphatase (ADPase) activity was studied in rat liver with [beta-32P]ADP as a substrate. Mitochondria and outer mitochondrial membrane fractions were isolated and assayed for ADPase and various marker enzymes. ADPase activity was strikingly reduced when the outer membranes were removed from the mitochondria whether by digitonin treatment or osmotic shock. Addition of the inter-membrane space subfraction to the purified outer membranes resulted in enhanced ADPase activity. Addition of the inter-mitochondrial membrane enzyme adenylate kinase to outer membranes also produced a large stimulation of activity. The ADPase activity could also be reconstituted in vitro with adenylate kinase and either mitoplast ATPase or ouabain-sensitive (Na+ + K+ + Mg2+)-ATPase. Chloroform-released ATPase, however, was not capable of producing an ADPase activity when combined with adenylate kinase. Gel permeation chromatography of Triton-solubilised outer mitochondrial membranes was unable to resolve ADPase activity from contaminating ATPase. These results suggest that the majority of ADPase activity in rat liver mitochondria consists of the coupled activity of adenylate kinase and ATPase.     

Distribution of ADPase activity in the lactating rat mammary gland and its possible role in an ATP cycle in the Golgi apparatus.

A Ca2+/Mg(2+)-stimulated ADPase has been found to occur in the lactating rat mammary gland. The enzyme is membrane associated and occurs in mitochondrial, microsomal, and Golgi apparatus fractions. The pH activity curves for the Golgi apparatus and microsomal fractions display two distinct maxima, one at pH 6.3 and one at pH 7.4. Studies with inhibitors and activators indicate that the enzyme is similar to ADPases found in other tissues and is distinct from the uridine nucleoside diphosphatase previously reported in the mammary Golgi apparatus. The occurrence of ADPase in the Golgi apparatus indicates a possible role for this enzyme in the milk secretory process, while the microsomal enzyme could be involved in extracellular activities.     

Pharmacologic properties of a phosphate ester of dopamine

The 3 or 4 phosphate ester of dopamine (PD) was hydrolyzed by homogenates of rat tissues to give inorganic phosphate (Pi) and dopamine. The rate of hydrolysis of PD by kidney homogenates was increased by exogenous MgCl2 but not CaCl2 or KCl. The activity of brain, heart or liver homogenates was insensitive to the added salts. Several lines of evidence indicate that alkaline phosphatase activity contributes to the high rate of PD hydrolysis by the kidney but not brain homogenate. The intravenous infusion of PD at 12 mumole/kg in one hr to anesthetized rats increased the dopamine content of the plasma, kidney and heart without altering brain or liver dopamine. The results suggest that PD may be more effective than dopamine for increasing dopamine levels of the kidney. In addition, the hydrolysis of PD by brain homogenates, which is independent of alkaline phosphatase activity, suggests that specific enzymes exist for the metabolism of PD.     

Subcellular localization and properties of adenosine diphosphatase activity in human polymorphonuclear leukocytes

Adenosine diphosphatase (ADPase) activities were studied in human polymorphonuclear leukocytes with a recently developed radio-assay. The neutrophils were homogenized in isotonic sucrose and subjected to analytical subcellular fractionation. The sucrose density gradient fractions were assayed for ADPase activity and for principal organelle marker enzymes. ADPase activity was distributed between the plasma membrane, specific granule and soluble fractions. The plasma membrane and specific granule activities had similar kinetic and inhibitor properties but the cytosolic enzyme was clearly different. Studies with the non-penetrating inhibitor diazotized sulphanilic acid and measurements of latent activity indicate that plasma membrane ADPase activity is located on the external aspect to the cell. Its possible role in inhibiting platelet aggregation is discussed. Neutrophils were isolated from control subjects, patients with chronic granulocytic leukaemia and patients in the third trimester of pregnancy. The specific activities (mU/mg protein) of ADPase activity, in contrast to those of alkaline phosphatase, were similar in all three groups. This result, together with fractionation experiments and inhibition studies strongly suggests that ADPase activity is not attributable to neutrophil alkaline phosphatase.     

Phospholipase C axis is the preferential pathway leading to PKC activation following PTH or PTHrP stimulation in human term placenta

In the present report we describe an NTPDase 1 (ATP diphosphohydrolase; ecto-apyrase; EC 3.6.1.5) in rat hippocampal slices. The effect of glutamate on the ATPase and ADPase activities in rat hippocampal slices of different ages was also studied since adenosine, the final product of an enzymatic chain that includes NTPDase 1 and 5'-nucleotidase, can act upon A1 receptors in turn decreasing the release of glutamate. Hippocampal slices from 7, 14, 20-23 and 60 day-old rats were prepared and ATPase and ADPase activities were measured. The parallelism of ATPase and ADPase activities in all parameters tested indicated the presence of an ATP diphosphohydrolase. In addition, a Chevillard plot indicated that ATP and ADP are hydrolyzed at the same active site on the enzyme. ATPase activity was significantly activated by glutamate in 20-23 and 60 day-old rats, but ADPase activity was not activated. These results could indicate distinct behavior of the ATPase and ADPase activities of NTPDase 1 in relation to glutamate or the simultaneous action of the ecto-ATPase. Activation of ATPase activity by glutamate may constitute an important role in this developmental period, possibly protecting against the neurotoxicity induced by ATP, as well as producing high levels of ADP, by increasing adenosine production, a neuroprotective compound.     

A radiochemical assay for N-acetyl-L-aspartate amidohydrolase (EC 3.5.1.15) and its occurrence in the tissues of the chicken

A simple and rapid radiochemical method for the determination of N-acetyl-L-aspartic acid amidohydrolase (EC 3.5.1.15) activity using ion exchange chromatography has been developed. The activity of this enzyme in the developing brain and some non-nervous tissues of the chicken has been determined. No activity of the enzyme could be detected in the brains of chick embroys prior to 14 days of gestation; activities gradually increased thereafter to adult levels which are about 60% of that found in the adult rat. In non-nervous system tissues of the adult chicken, activities varied from high levels in the kidney to low levels in heart and breast muscle. Treatment of the homogenates of the adult tissues with a detergent significantly increased the enzyme activity, suggesting that a portion of the enzyme is membrane bound.     

The Biological Reductive Capacity of Tissues is Decreased Following Exposure to Oxidative Stress: A Cyclic Voltammetry Study of Irradiated Rats

The reductive capacity of rat tissue homogenates and body fluids was determined by cyclic voltammetric measurements. The reductive capacity of rat lung, liver and kidney homogenates was significantly reduced four days after total body γ-ray irradiation with 5.5 Gy as compared to controls. In parallel, reduced ability of the irradiated organ homogenates to scavenge hydroxyl radicals and to destroy hydrogen peroxide was recorded. However, no difference in their superoxide dismutase activity was found. The possible use of cyclic voltammetry as a method for qualitative evaluation of the ability of biological tissues to cope with oxidative stress is discussed.     

A sensitive and specific assay for dipeptidyl-aminopeptidase II in serum and tissues by liquid chromatography-fluorometry

A highly sensitive and specific method for the assay of dipeptidyl-aminopeptidase II (DAP II) in crude enzyme preparations such as serum and tissue homogenates has been established by using a newly synthesized fluorogenic substrate, 7-Lys-Ala-4-methylcoumarinamide. The enzymatically formed 7-amino-4-methylcoumarin was determined by high-performance liquid chromatography with fluorescence detection. The activities of other aminopeptidases in human serum and rat brain homogenates were completely inhibited by o-phenanthroline without any effect on DAP II activity to permit specific determination of DAP II. The limit of sensitivity for DAP II activity was about 300 fmol/30 min. DAP II activity was found to be increased in sera from cancer patients, in contrast to the decrease in serum DAP IV activity. DAP II activity was found to be unequally distributed in rat brain regions, and the highest activity was found in the hypothalamus.     

A Radioimmunoassay for the Phosphoprotein B-50: Distribution in Rat Brain

A radioimmunoassay (RIA) for the B-50 protein was developed to determine B-50 in total homogenates of rat tissues. A tracer of purified B-50 was prepared at high activity (10-30 microCi/micrograms protein) by phosphorylating B-50 with carrier-free [gamma-32P]ATP, catalyzed by purified protein kinase C. The RIA was performed using affinity-purified anti-B-50 immunoglobulins G in a detergent containing medium and detected B-50 at levels of 0.1-10 ng. Specificity of the antibodies was ascertained by immunoprecipitation of B-50 from a crude mitochondrial membrane fraction from rat brain and by immunoblotting. For the B-50 content in rat brain the following distribution pattern was found: medulla spinalis less than cerebellum less than hippocampus; cerebral cortex less than periaqueductal gray less than septum. The septum contained 80 micrograms/g tissue weight. The level in liver homogenates was below detection. The regional distribution is in fair agreement with the pattern of the endogenous B-50 phosphorylation in rat brain synaptosomal plasma membranes previously reported.     

The determination of myeloperoxidase activity in liver

Myeloperoxidase (MPO) is an enzyme found in granulocytes of neutrophils, but not in mammalian tissues. Previous studies have directly correlated MPO activity with neutrophil accumulation in tissues. This study presents a method for determining MPO activity in liver. Neutrophil accumulation in rat liver was provoked by creating partial ischemia followed by reperfusion. Liver homogenates prepared by a standard procedure showed no MPO activity. The homogenate was applied to Sephadex G100 and DEAE Sepharose CL6B columns which separated MPO activity from inhibitory activity. The inhibitor was identified as catalase based upon its elution from the columns and removal with 3-amino- 1,2,4-triazole (AT), a catalase inhibitor. Based upon these findings, it was determined that full MPO activity can be assayed in unfractionated liver homogenates by first inactivating catalase with AT.     

Characterisation of a Myristoyl CoA:Glycylpeptide N-Myristoyl Transferase Activity in Rat Brain: Subcellular and Regional Distribution

Abstract: An enzyme activity in rat brain, capable of catalysing the transfer of myristic acid from myristoyl CoA to the amino terminus of synthetic peptides, has been characterised. The synthetic peptides used as substrates were one based on the N-terminal eight amino acids of cyclic AMP-dependent protein kinase and another hexadecapeptide based on the N-terminal sequence of p60^src. This N -myristoyl transferase (NMT) activity, which is both peptide dependent and heat labile, occurs in rat brain at levels at least three times those found in other rat tissues. In the presence of both ATP and CoA the enzyme catalysed the transfer of myristic acid, but not palmitic acid, specifically to the N-terminal glycine of the peptides. Both peptide substrates exhibited Mi-chaelis-Menten kinetics yielding K _m values of 100 μ M and 60 μ M , and V_max values of 5 and 14.8 pmol/min/mg for the cyclic AMP-dependent protein kinase peptide and sre-derived peptides, respectively. The majority of the NMT activity was present in the cytosol of the brain homogenates, and there was evidence of an NMT inhibitory activity in both the particulate fraction of brain homogenates and in brain cytosol. NMT activity could also be demonstrated in the 100,000 g supernatant of lysed synaptosomes, and the synaptosomal membranes also exhibited an inhibitory activity on the soluble enzyme. Different brain areas exhibited different levels of the N -myristoyl transferase activity and there was a fivefold difference in the activity found in the most active area, the hippocampus, compared to spinal cord.     

Evidence for the presence of a prostaglandin E 2 -9-keto reductase in rat organs

Antibodies directed toward PGF_2α which cross react with PGE₂ only slightly were used to detect conversion of PGE₂ to PGF_2α by homogenates of several rat tissues. This conversion by rat heart homogenates was demonstrated to be reversible, lost after trypsin digestion, and inhibited by several sulfhydryl blocking agents. The activity of the rat heart homogenate was precipitable by ammonium sulphate, was not dialyzable, and was 50% destroyed when the homogenate was incubated at 50° for 5 min. In the rat, the heart had the highest activity, followed by the kidney, brain, and liver. Negligible activity was found in smooth muscle, skeletal muscle, and whole blood of rat.     

Presence of D-aspartate oxidase in rat liver and mouse tissues

Rat liver D-aspartate oxidase activity, which had been reported to be undetectable, was found to be well detectable in dialyzed liver homogenate. The requirements of the enzyme for activity and its sensitivity to inhibitors were identical with the known properties of the enzyme from other sources. We also demonstrated for the first time the presence of the enzyme activity in mouse tissues and some other rat tissues using dialyzed tissue homogenates.     

Comparative ability of rat seminiferous tubules, interstitium, and whole testes to utilize cholesterol-1,5-3H as a substrate for testosterone synthesis and the intratesticular distribution of cholesterol side-chain cleavage enzyme.

Homogenates of rat seminiferous tubules, interstitium and intact testis tissues were assessed for their ability to convert cholesterol -1,2-3H to testosterone in vitro. While 3H-testosterone synthesis was observed in incubates of interstitial and whole testis homogenates, no synthesis was detectable in homogenates of seminiferous tubules. To determine whether cholesterol side-chain cleavage enzyme (CSCCE) was deficient or absent in tubules, mitochondria from tubules, interstitium and whole testes were analyzed for CSCCE activity by measuring conversion of cholesterol -26-14C to 14C-isocaproate (+pregnenolone). Interstitial mitochondrial preparations from each of six testes were found to be approximately 200 times more active in CSCCE than the corresponding tubule mitochondria, and 1600-1800 times more active on a specific activity basis. Although caution is required in extrapolation of in vitro data to the in vivo state, these findings suggest rat seminiferous tubules may be incapable of de novo testosterone biosynthesis and that this lack of synthetic ability may be due to a deficiency of CSCCE.     

Detection of protein disulphide-isomerase in sheep pancreas fractions

Conclusions The use of diethylpyrocarbonate to inhibit endogenous ribonuclease in sheep pancreas allows the detection of protein-disulphide-isomerase activity in homogenates, at specific activities of up to 4 units/g. This is higher than the specific activity in sheep liver homogenates (about 2 units/g) or in homogenates of other sheep tissues (16). It is thus evident that high levels of protein-disulphide-isomerase activity are present in sheep pancreas. This is consistent both with the postulated general role of protein disulphide-isomerase in protein biosynthesis (10,11) and with the in vitro action of the enzyme on its conventional substrate scrambled ribonuclease, since pancreas is the major site of ribonuclease synthesis.