Light microscopic localization of glycosyltransferase activities in cells and tissues

We describe an assay for light microscopic visualization of specific glycosyltransferases on tissue sections or on cells. The assay uses a sequence of enzyme reactions that yields two moles of NADH for each mole of the uridine-5'-diphosphate (UDP) released during transfer of a monosaccharide from a UDP sugar to an acceptor. When diaphorase and tetrazolium salts are present in the incubation mixture, the tetrazolium salts are reduced to colored diformazans, which precipitate at the sites of glycosyltransferase activity. The validity of the assay was established by applying the technique to spermatozoa and liver, in which some glycosyltransferases have previously been localized. When suspensions of mouse spermatozoa were assayed for galactosyltransferase (GalTase) activity, diformazan precipitates appeared on the plasma membranes overlying the anterior heads of the spermatozoa, in agreement with immunochemical localizations. In mouse liver slices assayed with bilirubin as acceptor for glucuronyltransferase (GluTase) activity, dense diformazan deposits appeared on the hepatocytes but not on endothelial cells, also in agreement with immunochemical data. In the absence of acceptor or UDP sugar donor, diformazan deposits were minimal and random in all tissues tested. The assay's versatility was tested by incubating tissues with different sugar donors and acceptors to localize other sites of transferase activity. In mouse frozen liver sections, GalTase activity occurred in both hepatocytes and endothelial cells; in sections of rat submaxillary glands, GalTase activity was detected in mast cells. In liver sections, GlcuTase activity with o-aminophenol as acceptor was located primarily on the endothelial cells. With the appropriate sugar donor and acceptor, this assay should detect any transferase, other than the glucosyltransferases, that utilizes UDP sugars.     

Arginine:glycine amidinotransferase. A comparative study in lizard and mouse tissues

Kidney transamidinase activity in the lizard (Calotes versicolor), like that in the mouse, showed the pH optimum at 7.4. The lizard enzyme was inhibited to a greater degree than the mouse enzyme at high concentrations (greater than 20 mM) of L-arginine and glycine. Kidney and liver in the lizard and kidney and pancreas in the mouse were the tissues with high transamidinase activity. While transamidinase activity was widely distributed in mouse tissues, the enzyme was found to be restricted only to a few tissues in the lizard. Hydrocortisone administration into male lizards did not significantly alter the transamidinase levels in kidney and liver.     

ARGINASES OF MOUSE BRAIN AND LIVER

The arginase present in mouse brain and liver was studied in order to determine if the activity in both tissues was due to the same enzyme. Mouse liver contains only one arginase enzyme whereas mouse brain contains two. One of the arginases in the brain is distinct from the liver enzyme as determined by fractionation on DEAE-cellulose, CM-cellulose and disc gel electrophoresis. The second enzyme from brain tissue has the same properties as the liver enzyme when subjected to these same fractionation techniques. However this arginase can be distinguished from the liver enzyme by its K_m for arginine heat lability and MnCl₂ activation curve. Thus both arginases in brain differ from the liver enzyme. No interconversion of the brain enzymes was detected, and the molecular weight of all the arginases appears to be the same. The observation of multiple distinct brain and liver arginases in mouse brain and liver was confirmed with bovine tissues.     

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.     

Purification and characterization of thymidylate synthetase in the liver of the mouse bearing Ehrlich ascites tumor

The activity of thymidylate synthetase in the liver of the ddY strain male mouse increased transitorily according to the increase in tumor cell number at maximum 7-9 days after ip transplantation of Ehrlich ascites tumor. The enzyme was able to be purified from the tumor host mouse liver or from the normal mouse liver in the same manner as from tumor cells using Affi-Gel blue and methotrexate-Sepharose 4B affinity column chromatography. The three enzyme preparations obtained were purified at 27,000-38,000-, and 8,000-fold, and yielded total activities of 11, 3, and 16% of these homogenates, respectively. These preparations were similar in molecular weight to the whole enzyme (67,000) and its subunit (34,000), optimum pH, and Km values either for deoxyuridine 5'-monophosphate or tetrahydrofolate in the presence of formaldehyde. Furthermore, the amount of 5-fluoro-2'-deoxyuridine 5'-monophosphate forming the ternary complex with the enzyme and tetrahydrofolate paralleled the enzyme activities in the cytosol fractions of the three tissues. The characteristics of the tumor host liver enzyme were similar to those of the proliferating tissues, the Ehrlich ascites tumor.     

Characterization of mouse liver alpha-L-fucosidase. Demonstration of unusual basic isoelectric forms of the enzyme that appear to be developmentally regulated.

Mouse tissues contain unusual basic isoelectric forms of alpha-L-fucosidase (with approximate isoelectric points of 8.3 and 9.0) in addition to the usual acidic and neutral forms previously described in tissues of other species. These unusual forms are very prominent in placenta and foetal tissues and comprise approx, 50-80% of total activity up to 11 days of postnatal development. By 15 days of postnatal development, the basic forms are diminished in amount and comprise not more than 25% of total activity. Neuraminidase treatment of adult mouse liver alpha-L-fucosidase led to significantly decreased amounts of acidic forms and increased amounts of the basic forms, suggesting that these forms are chemically related at least in part by sialic acid residues. Comparative kinetic studies on mouse liver, human liver and mouse placental alpha-L-fucosidases indicated that they have the same Km (0.05-0.06 mM) for 4-methylumbelliferyl alpha-L-fucopyranoside but different pH optima and thermostability properties. Mouse liver alpha-L-fucosidase has one pH optimum (5.5) and an acidic shoulder (centred around pH 4.0) compared with two distinct optima (4.3 and 6.8) for the human liver enzyme. Mouse placental alpha-L-fucosidase has a pH-activity curve comparable with that of the mouse liver enzyme except that the acidic shoulder is absent. Mouse liver alpha-L-fucosidase is considerably more thermolabile after preincubation at 50 degrees C than are the human liver and mouse placental enzymes, which gave similar thermodenaturation curves. Immunochemical studies indicated that mouse and human alpha-L-fucosidases are dissimilar antigenically but exhibit some cross-reactivity. The IgG fraction of antibody prepared in goat against human liver alpha-L-fucosidase was ineffective by itself in immunoprecipitating mouse liver alpha-L-fucosidase, but 63% and 72% of the mouse liver and placental enzymes respectively could be immunoprecipitated in the double-antibody experiments under conditions that immunoprecipitated 92% of the human liver enzyme.     

Monospecific antiserum to rat spermidine synthase and its application to rat tissues and several mammals

Monospecific antiserum to rat spermidine synthase was prepared by immunization of rabbits with purified enzyme protein from rat prostate, and its usefulness for analysis of spermidine synthase protein in not only rat tissues but also several other mammals was demonstrated by Western blotting and immunotitration of the enzyme activity. Application of the antiserum for elucidating the relationship between the enzyme activity and protein in normal rat tissues strongly suggested that marked difference in spermidine synthase activity among rat tissues depends solely on the difference in the amount of enzyme protein. Also, application of the antiserum for analyzing spermidine synthase from liver of mouse, rat, guinea pig, pig, and human, showed that the enzymes had a similar subunit molecular weight of 35,000 and a cross-reactivity with the antiserum, exhibiting almost the same immunoreactivity to mouse enzyme as to rat enzyme. Thus, it was suggested that the antiserum would be useful for further studies of mammalian spermidine synthase from the viewpoints of enzymology and molecular biology.     

Biosynthesis of galactosylsphingosine (Psychosine) in the twitcher mouse

In attempts to elucidate the origin of accumulated galactosylsphingosine in the twitcher mouse, a murine model of human globoid cell leukodystrophy (Krabbe's disease), UDP-galactose: sphingosine galactosyltransferase activity was assayed in tissues from normal and twitcher mice. Among several tissues from normal, 20 day postnatal mice, the highest galactosyltransferase activity was found in the brainstem and spinal cord, followed by cerebrum, kidney and liver, in that order. Chronologically, the enzyme activity in the central nervous tissue increased with age, reached a maximum at 25 postnatal days, and declined thereafter. In the kidney and liver, however, the activity remained much the same during development. In the twitcher mouse, developmental change in the enzyme activity was similar to that seen in control mouse, but the decrease in activity in the central nervous tissue after the 25 postnatal days was more rapid. The galactosyltransferase activity and the accumulation of galactosylsphingosine in the tissue of the twitcher mouse were closely related; where and when the enzyme activity was higher, the greater was the accumulation of galactosylsphingosine in the tissue of the twitcher mouse. These results strongly suggest that the accumulated galactosylsphingosine in the twitcher mouse is synthesized mainly by UDP-galactose: sphingosine galactosyltransferase.     

大白鼠DNA拓扑异构酶Ⅰ生物学性质的研究

对大白鼠组织作DNA拓扑弄构酶Ⅰ(拓扑酶Ⅰ)活力测定,见酶活力出现在胚胎早期,在胚胎发育过程及出生后不同年龄期,酶活力基本稳定;几种成年大鼠组织的酶活力彼此无显著差异;肝细胞再生及癌变,酶活力亦无显著变化。     

Pyridoxal kinase activity and pyridoxal-P concentration in mammalian tissues under normal and experimental conditions]

The activity and the distribution of pyridoxal kinase in rat and mouse tissues are studied. The data obtained testify the presence of a relative excess of pyridoxal kinase in all the organs studied, which probably causes a high rate of pyridoxalphosphate (PLP) biosynthesis under comparatively low vitamin B6 concentration. A correlation between the level of pyridoxal kinase activity and the content of PLP in rat brain and liver during ontogenesis is observed. The activity of pyridoxal kinase and the content of PLP are shown to be sharply increased in liver of rats received a protein-rich diet. Bilateral adrenalectomy resulted in the decrease of absolute and specific enzyme activities in rat liver by 20--30%. The content of PLP in mouse brain and liver was sharply decreased under experimental B6-avitaminosis while the content of pyridoxal kinase practically did not change. The injection of vitamin B6 rapidly normalized the PLP content in mouse tissues. The data obtained show that under physiological conditions the functional activity of pyridoxal kinase may be regulated in tissues by enzyme and substate contents. Some aspects of vitamin B6 metabolism in mammals are considered. It is concluded that in body the pyridoxal catabolism connected with its phosphorylation by pyridoxal kinase and the formation of pyridoxalphosphate.     

Monoclonal Antibodies to Mammalian Carnosine Synthetase

A set of mouse monoclonal antibodies has been generated against rabbit muscle carnosine synthetase. The immunoreactivity of these antibodies has been characterized using an immunoassay that permits the separation and direct measurement of the synthetase activity on a second antibody bead complex. Four IgG monoclonal antibodies bind the carnosine synthetase activity from muscle of all mammals tested (mouse, rat, rabbit, cow, dog, and monkey) but not that from chicken muscle. This indicates the mammalian enzymes share epitopes that are absent from the avian enzyme. In addition, relative tissue levels of synthetase activity can be quantified with this immunoassay. Thus, high levels of carnosine synthetase activity are immunoprecipitated from the olfactory tissues of both rat and rabbit. Synthetase activity is generally lower in other tissues (muscle, brain, heart, liver, and gut). Nevertheless, the cross-reactivity of the synthetase from several tissues (olfactory mucosa, muscle, brain, gut, heart, and liver) of a single species indicates the enzyme protein contains similar epitopes in these tissues. Immunoaffinity purification of this low-abundance, unstable enzyme should now be possible for subsequent studies of structure and regulation.     

Survey of normal appearing mouse strain which lacks enzyme and NAD+-linked glycerol phosphate dehydrogenase: Normal pancreatic beta cell function,but abnormal metabolite pattern in skeltal muscle

We studied a mouse doubly homozygous for mutations in the genes encoding malic enzyme (EC1.1.1.40) and cytosolic glycerol phosphate dehydrogenase (EC 1.1.1.8) (cGPD). This mouse, which we call the mmgg mouse and which is the product of intercrosses between the Mod-1 mouse and the BALB/cHeA mouse, lacks activity of both enzymes. Like both parental strains the mmgg mouse is completely normal in appearance. cGPD is one of the two enzymes that catalyze the reactions of the glycerol phosphate shuttle. The activity of the other enzyme of the glycerol phosphate shuttle, mitochondrial glycerol phosphate dehydrogenase (EC 1.1.99.5) (mGPD), is abundant in tissues, such as brain, skeletal muscle and the pancreatic islet, suggesting that the glycerol phosphate shuttle is important in these tissues which rapidly metabolize glucose. Cytosolic malic enzyme activity is important for shuttles which transport NADPH equivalents from mitochondria to the cytosol. The major finding of the study was a highly abnormal metabolite pattern in tissues of the mmgg mouse suggesting a block in the glycerol phosphate shuttle due to cGPD deficiency. The metabolite pattern did not suggest that malic enzyme deficiency caused an abnormality. Tissue levels of glycerol phosphate (low) and dihydroxyacetone phosphate (high) were only abnormal in skeletal muscle. Glycolytic intermediates, situated at or before the triose phosphates in the pathway, such as fructose bisphosphate and glyceraldehyde phosphate were increased depending on the tissue. Taken together with previous extensive data on the mouse deficient only in cGPD this suggests a block in glycolysis at the step catalyzed by glyceraldehyde phosphate dehydrogenase caused by an abnormally low NAD/NADH ratio resulting from a nonfunctional glycerol phosphate shuttle. Consistent with this idea the lactate/pyruvate ratio was high in skeletal muscle signifying a low cytosolic NAD/NADH ratio. The mmgg mouse was normal in all other factors studied including blood glucose and serum insulin levels, pancreatic islet mass, insulin release from isolated pancreatic islets, as well as the activities of five metabolic enzymes, including mGPD, in liver, kidney, skeletal muscle and pancreatic islets. cGPD enzyme activity was undetectable in pancreatic islets, 0.5% of normal in liver, and 2.1% of normal in kidney and skeletal muscle. Malic enzyme activity was undetectable in these same tissues.     

A comparison of the cytosolic and mitochondrial forms of asparagine/glyoxylate aminotransferase

Asparagine aminotransferase activity was measured in a variety of mouse tissues. The liver had the highest activity--nearly 20 times more than any of the other tissues tested. Hepatic asparagine aminotransferase was found to consist of cytosolic and mitochondrial forms. The mitochondrial form was found to be the predominant form in mouse tissue. Gel filtration chromatography indicated that the mouse enzyme forms have comparable molecular weights of approximately 70,000. While the substrate specificities of the two forms are very different, asparagine was the preferred amino donor for both forms. The relative contribution to the total activity of the hepatic enzyme forms varies with the animal source. Mouse had the highest level of enzyme activity of all animals tested. Ratios of the two enzyme forms also varied greatly not only with the animal source but also with the substrate used and the isolation conditions.     

Egasyn affects the processing of beta-glucuronidase in mouse liver.

Three differently modified forms of beta-glucuronidase are known to exist: a microsomal enzyme form (M) existing in tissues where egasyn, a second microsomal protein, is present; and an acidic (La; complex-type oligosaccharide) and a basic (Lb; non-complex type oligosaccharide) lysosomal form which occur in all mouse tissues. Lb predominates in tissues containing microsomal beta-glucuronidase, La in those lacking it. In pulse-labelling experiments using mouse strain C57BL/6 liver containing egasyn (Eg+/Eg+) and microsomal enzyme, about half of the newly synthesized beta-glucuronidase was processed to the microsomal enzyme form, which was evidently further processed to Lb, and about half directly to La. In contrast, in liver of the congenic line C57BL/6.YBR Es-1b Eg0 that lacks egasyn (Eg0/Eg0) and microsomal enzyme, most of the labelled beta-glucuronidase was processed to La, and only a minor portion to Lb. Newly synthesized enzyme appeared first in microsomal, then in light and heavy lysosomal fractions of Eg+/Eg+ liver. In Eg0/Eg0 liver, no labelled enzyme was measurable in the microsomes, but it appeared rapidly in both types of lysosomes. Taken together these findings indicate that the microsomal enzyme form serves as a precursor of Lb, and that La is synthesized independently. The apparent half-life of La is only two-thirds that of Lb; this fact accounts for the reduced beta-glucuronidase activity in Eg0/Eg0 liver, which contains La as the predominant form.     

Unique cathepsin D-type proteases in rat thoracic duct lymphocytes and in rat lymphoid tissues.

Two unique cathepsin D-type proteases apparently present only in rat thoracic duct lymphocytes and in rat lymphoid tissues are described. One, termed H enzyme, has an apparent molecular weight of similar to95,000; the other, termed L enzyme, has an apparent molecular weight of similar to45,000, in common with that of most cathepsins D from other tissues and species. Both enzymes differ from cathepsin D, however, by a considerably greater sensitivity to inhibition by pepstatin and by a smaller degree of inhibition by an antiserum which inhibits rat liver cathepsin D. H enzyme is converted to L enzyme by treatment with beta-mercaptoethanol; the relationship between the two enzymes remains unknown. H and L enzyme have been detected in rat lymphoid tissues and in mouse spleen, but they are not present in other rat tissues (liver, kidney, adrenals), rabbit tissues, calf thymus, bovine spleen, or human tonsils. As measured on acid-denatured bovine hemoglobin as substrate, both enzymes have pH activity curves identical with that of rat liver cathepsin D, with optimal activity at pH 3.6. Activity on human serum albumin is much less and also shows an optimum at pH 3.6; hence, neither enzyme has the properties of cathepsin E. Thiol-reactive inhibitiors have no effect on the activity of H and L enzyme; thus they do not belong to the B group of cathepsins. Additional information, discussed in this paper, leads us to conclude that partially purified H and L enzymes are cathepsin D-type proteases.     

Characterization of phosphatidylinositol phospholipase C activity in human melanoma

Phosphoinositide phospholipase C activity was investigated in human melanoma grown as solid tumor xenografts in nude mice. The enzyme was dependent on calcium for activity and was stimulated by the detergent deoxycholate. The pH optimum was 5.5 in the absence of detergent, and in the presence of deoxycholate two pH maxima were present, 5.5 and 7.2. Phospholipase C activity was inhibited by the sulfhydryl reagent dithionitrobenzoate with an IC50 in the micromolar range. Phospholipase C activity was distributed widely in mouse tissues. The enzyme showed a progressive increase in activity from heart, liver, lung, colon, spleen, to brain tissue. Mouse and human melanomas grown as solid tumors had higher phospholipase C activity than mouse brain. The relatively high activity of this enzyme in melanoma may suggest a biological role for phospholipase C in solid tumor growth.     

Biochemical characteristics of liver and brain monoamine oxidase from pacu

Monoamine oxidase (MAO) activity in the liver and brain of the pacu, Piaractus mesopotamicus was determined using a fluorescence assay with kynuramine as substrate. Apparent Michaelis constant values (20·33 μM for liver and 25·85 μM for brain) were similar in these tissues, but in terms of tissue protein MAO activity from liver was 4·5 times higher than from brain. The greater inhibitory effects of clorgyline than of deprenyl on MAO activity from liver and brain of this species suggest that pacu's MAO is a type A-like enzyme.     

Catalytic activity and substrate specificity of the flavin-containing monooxygenase in microsomal systems: characterization of the hepatic, pulmonary and renal enzymes of the mouse, rabbit, and rat

Inhibitory antibodies against NADPH-cytochrome P-450 reductase, detergent solubilization to dissociate functional interaction between the reductase and cytochrome P-450, and selective trypsin degradation have been used to characterize flavin-containing monooxygenase activity in microsomes from different tissues and species. A comparison of assay methods is reported. The native microsome-bound flavin-containing monooxygenase of mouse, rabbit, and rat liver, lung, and kidney can metabolize compounds containing thiol, sulfide, thioamide, secondary and tertiary amine, hydrazine, and phosphine substituents. Therefore, this enzyme from these common experimental animals has catalytic capabilities similar to those of the well-characterized porcine liver enzyme. True allosteric activation by n-octylamine does not appear to be a property of either the mouse, rabbit, or rat liver enzymes, but is a property of the pig liver and mouse lung enzymes. The microsomal pulmonary flavin-containing monooxygenase of the rabbit has some unique substrate preferences which differ from the mouse lung enzyme. Both the rabbit and mouse pulmonary enzymes have recently been shown to be distinct enzyme forms. However, the rat pulmonary flavin-containing monooxygenase appears to be catalytically identical to the rat liver enzyme, and does not have any of the unusual catalytic properties of either the rabbit or mouse lung enzymes. Enzyme activity of mouse, rabbit, and rat kidney microsomes is qualitatively similar to the hepatic activities. Substrates which saturate the microsome-bound flavin-containing monooxygenase at 1.0 mM, including thiourea, thioacetamide, methimazole, cysteamine, and thiobenzamide, are metabolized at common maximal velocities. This suggests that the kinetic mechanism of the native enzyme is similar to that established for the isolated porcine liver enzyme in that the rate-limiting step of catalysis occurs after substrate binding, and that all substrates capable of saturating the microsomal enzyme should be metabolized at a common maximal velocity.     

Polyamines and their biosynthetic decarboxylases in various tissues of the young rat during recovery from undernutrition.

1. Weanling male and female rats were undernourished for 4 weeks and then rehabilitated by allowing ad libitum feeding. 2. During rehabilitation polyamine-biosynthetic enzymes were examined in the liver, spleen and quadriceps and gastrocnemius muscles. 3. During the first few hours of rehabilitiation there was a marked increase in liver weight, accompanied by a very marked increase in ornithine decarboxylase activity. Increases in the activity of this enzyme in other tissues did not occur until between 2 and 7 days of rehabilitation, at which time there were further increases in enzyme activity in the liver. 4. S-Adenosylmethionine decarboxylase activity also showed marked fluctuations in activity in all the tissues examined. 5. Hepatic putrescine and spermidine concentrations also varied during rehabilitation, but permine concentration remained relatively constant. Both spermine and spermidine were at normal concentrations in the liver from the 10th days of rehabilitation onwards. 6. In all of the tissues examined there were marked sex differences in the parameters studied, particularly in splenic and muscular ornithine decarboxylase activity. 7. In the tissues of the male rats, changes in polyamine synthesis paralled changes in nucleic acid and protein synthesis.