Enzymes involved in the metabolism of flavin nucleotides in Streptomyces olivaceus

The work was aimed at studying enzymes involved in the metabolism of flavin nucleotides, namely, riboflavin kinase (EC 2.7.1.26) and FAD pyrophosphorylase (EC 2.7.7.2), as well as flavin mononucleotide hydrolysis by acid phosphatase (EC 3.1.3.2) and alkaline phosphatase (EC 3.1.3.1) in Streptomyces olivaceus actively producing vitamin B12. No correlation could be established between changes in the activity of the above enzymes during the culture growth and the qualitative composition of flavins. The enzyme activity was assayed using, as an enzyme preparation, both intact cells and a cell-free extract obtained by disintegrating the mycelium with different techniques. The screening effect of phosphatases exerted when the activity of riboflavin kinase was assayed could be partly eliminated by adding sodium fluoride to the incubation medium. The localisation of the above enzymes in the cytoplasm is discussed.     

Association of Matrix Acid and Alkaline Phosphatases with Mineralization of Cartilage and Endochondral Bone

The activities of acid and alkaline phosphatases were localized by enzyme histochemistry in the chondroepiphyses of 5 week old rabbits. Using paraformaldehyde-lysine-periodate as fixative, the activity of acid phosphatase was particularly well preserved and could be demonstrated not only in osteoclasts, but also in chondrocytes as well as in the cartilage and early endochondral matrices. The acid phosphatase in the chondrocytes and the matrix was tartrate-resistant, but inhibited by 2mM sodium fluoride, whereas for osteoclasts 50–100mM sodium fluoride were required for inhibition. Simultaneous localisation of both acid and alkaline phosphatase activities was possible in tissue that had been fixed in 85% ethanol and processed immediately. In the growth plates of the secondary ossification centre and the physis, there was a sequential localisation of the two phosphatases associated with chondrocyte maturation. The matrix surrounding immature epiphyseal chondrocytes or resting/proliferating growth plate chondrocytes contained weak acid phosphatase activity. Maturing chondrocytes were positive for alkaline phosphatase which spread to the matrix in the pre-mineralising zone, in a pattern that was consistent with the known location of matrix vesicles. The region of strong alkaline phosphatase activity was the precise region where acid phosphatase activity was reduced. With the onset of cartilage calcification, alkaline phosphatase activity disappeared, but strong acid phosphatase activity was found in close association with the early mineral deposition. Acid phosphatase activity was also present in the matrix of the endochondral bone, but was only found in early spicules which had recently mineralised. The results suggest that alkaline phosphatase activity is required in preparation of mineralization, whereas acid phosphatase activity might have a contributory role during the early progression of mineral formation.     

Ultrastructural localization of alkaline phosphatase in the eggs of Hydatigera taeniaeformis (Taenia taeniaeformis)

Freshly shed gravid proglottids from a three-month-old infection of Hydatigera taeniaeformis collected from the faecal droppings of infected cats were used for this study. They were treated for transmission electron microscopy (TEM) followed by incubation using the lead precipitate method. Control sections were incubated in a substrate-free medium, a substrate medium containing 1.0 mM sodium fluoride (NaF) (an inhibitor), and the last sections were denatured at 90 degrees C for 1 min prior to incubation. Intensive alkaline phosphatase activity in the embryophoric blocks and the outer embryophoric membrane was revealed. The reaction products were also indicated in the oncospheral membrane. However, no enzyme activity was seen in any other part of the egg. The enzyme was also absent in the control sections. The presence of alkaline phosphatase activity in the outer embryophoric and oncospheral membranes suggested that this enzyme may be involved in carbohydrate metabolism and nutritional absorption, and also may play a role in the transport of nutrients and other substances from the adult to the developing embryo, respectively.     

Alkaline phosphatases in fixed plant cells

Alkaline phosphatase activity in fixed plant cells has now been demonstrated cytochemically. Presumably cytochemical findings on plant alkaline phosphatases had been lacking because glycerophosphate, which is not hydrolyzed by fixed plant cells, had been used as the substrate.Alkaline phosphatase activity in the onion and corn nuclei has been compared with the activity in rat tissues. In the plant tissues, hydrolysis of phosphates was demonstrated when the substrates guanylic acid, adenosine diphosphate, adenosine triphosphoric acid, diphosphopyridine nucleotide, hexosediphosphates and inorganic pyrophosphate and metaphosphate were used. When the substrates glycerophosphate, adenylic acid and hexosemonophosphates were used, hydrolysis was not found. In the animal tissues however, hydrolysis was demonstrated of all organic phosphoesters employed and of sodium metaphosphate but not the hydrolysis of sodium pyrophosphate.One alkaline phosphatase found in the fixed plant tissues specifically hydrolyzed guanylic acid but no other nucleotide and one specifically hydrolyzed metaphosphate to orthophosphate.The enzymes in both plant and animal cells which hydrolyzed metaphosphates and pyrophosphates were found to require magnesium ions for their activity and to be inhibited by fluoride ions.“Alkaline, phosphatase,” so intimately associated with the chromatin in the nucleus, is postulated to be not just one enzyme but a number of enzymes.     

Acid and alkaline phosphatases activities in vascular smooth muscle: species differences and subcellular distribution

1. Acid and alkaline phosphatase activities were studied in rat and dog aortic muscle using p-nitrophenyl phosphate (p-NPP) as the substrate. Alkaline phosphatase activity was quite comparable to acid phosphatase activity in rat aortic microsomes as well as further purified plasma membranes, but considerably lower than acid phosphatase activity in dog aortic membranes. 2. Subcellular distribution of acid and alkaline phosphatase activities in these vascular muscles indicated that alkaline phosphatases and a large portion of acid phosphatase activities were primarily associated with plasma membranes and the distribution of acid phosphatase showed little resemblance to that of N-acetyl-beta-glucosaminidase, a lysosomal marker enzyme. 3. The rat aortic plasmalemmal acid and alkaline phosphatase activities responded very differently to magnesium, fluoride, vanadate and EDTA. The alkaline phosphatase was more susceptible to heat inactivation than acid phosphatase. 4. These results suggest that these two phosphatases are likely to be two different enzymes in the smooth muscle plasma membranes. The implication of the present findings is discussed in relation to the alteration of these phosphatases in hypertensive vascular diseases.     

Differences in phosphatidate hydrolytic activity of human alkaline phosphatase isozymes

Hydrolytic activities of human alkaline phosphatase isozymes were investigated using phosphatidases with various fatty acyl chains (egg phosphatidate and dioleoyl, distearoyl, dipalmitoyl, dimyristoyl and dilauroyl phosphatidates). In the presence of sodium deoxycholate, purified human placental and intestinal alkaline phosphatases hydrolyzed all the phosphatidates examined. The hydrolytic activity was maximal in the presence of 10 g/l sodium deoxycholate. Of the phosphatidates, dilauroyl phosphatidate was the best substrate. Using the same unit of the enzyme, the phosphatidate hydrolytic activity of placental alkaline phosphatase was 2- to 3-times higher than that of the intestinal enzyme. In contrast, liver alkaline phosphatase did not hydrolyze phosphatidates with long fatty acyl chains (C16-18) even in the presence of sodium deoxycholate. The liver enzyme hydrolyzed dimyristoyl and dilauroyl phosphatidates very slowly. These results show that the phosphatidates with long fatty acyl chains were useful to differentiate placental and intestinal alkaline phosphatases from the liver enzyme, and suggest that the former enzymes play a different physiological role from the liver enzyme.     

Induction of rat hepatic alkaline phosphatase and its appearance in serum: electrophoretic characterization of liver-membranous and serum-soluble forms

Simultaneous bile duct ligation and colchicine injection (2 mg/kg body weight) in rats caused a remarkable induction of alkaline phosphatase in the liver. Concomitantly, a marked elevation of the enzyme activity occurred in the serum, and three activity peaks (peaks I, II, and III) were separated by Sephadex G-200 gel filtration. By several criteria for alkaline phosphatase isoenzymes it was determined that the liver-derived enzyme was distributed in peak I (30% of total serum activity) as a vesicle-bound form and in peak II (65%) as a soluble form, while the intestinal enzyme was contained in peak III (5%). The serum alkaline phosphatase in peaks I and II was compared with the liver enzyme extracted from plasma membrane with n-butanol. Under non-reducing conditions, the soluble form of peak II showed an electrophoretic mobility different from that of the liver enzyme; in the presence of sodium dodecyl sulfate the serum-soluble form migrated a little more slowly than the liver one, while in the presence of Triton X-100 the former migrated much faster than the latter. The sedimentable fraction of peak I was found to contain two forms corresponding to the serum-soluble and liver-membranous forms. Neuraminidase treatment of these two forms reduced their mobilities but did not abolish the relative difference in their mobilities on gel electrophoresis in the presence of either Triton X-100 or sodium dodecyl sulfate. Under reducing conditions, however, each form (which was dissociated into single subunits) migrated with an identical mobility on sodium dodecyl sulfate gel electrophoresis. These results suggest that the hepatic alkaline phosphatase exists as conformationally different forms in the serum and the liver membrane (even solubilized), but the difference is no longer preserved after their denaturation into subunits.     

Ecto-phosphatase activity on the cell surface of Crithidia deanei

In the present work we have partially characterized an ecto-phosphatase activity in Crithidia deanei, using viable parasites. This enzyme hydrolyzed p-nitrophenylphosphate at a rate of 3.55 +/- 0.47 nmol Pi/h x 10(8) cells. The dependence on p-NPP concentration shows a normal Michaelis-Menten kinetics for this phosphatase activity and the value of the apparent Km for p-NPP was 5.35 +/- 0.89 mM. This phosphatase activity was inhibited by the product of the reaction, the inorganic phosphate. Experiments using classical inhibitors of acid phosphatases, such as ZnCl2 and sodium fluoride, as well as inhibitors of phosphotyrosine phosphatase, such as sodium orthovanadate and ammonium molybdate, showed a decrease in this phosphatase activity, with different patterns of inhibition.     

Fine structural localization of alkaline phosphatase in the granular pneumonocytes of hamster lung.

The fine structural localization of nonspecific alkaline phosphatase was studied in the granular pneumonocytes (type II alveolar epithelial cells) of hamster lung by incubating sections of glutaraldehyde-fixed tissues in a medium containing lead ions and sodium beta-glycerophosphate or alpha-naphthyl acid phosphate. The specificity of the reaction was tested by exposing the sections to inhibitors of alkaline phosphatase. The results showed that alkaline phosphatase activity was present in the inclusion bodies of granular pneumonocytes. The enzyme reaction was strong in the membrane lining the inclusion bodies and a weaker reaction was generally detectable in the inclusion contents. Although only a proportion of the inclusion bodies showed enzyme activity, there was no obvious correlation between the reactivity of the inclusions and their intracellular position or size. The other organelles were unreactive. The finding of alkaline phosphatase activity within the inclusion bodies of granular pneumonocytes is an enigma as these organelles are generally considered to be lyosomes.     

Comparative studies of acid and alkaline phosphatase activities in nonvascular smooth muscle membranes

Acid and alkaline phosphosphatase activities of subcellular fractions isolated from rat gastric muscle and vas deferens by differential centrifugation, sucrose density gradient and cation-induced aggregation methods were studied using p-nitrophenyl phosphate as the substrate. Alkaline phosphatase and a large portion of acid phosphatase activities were found to be of plasmalemmal origin. Acid and alkaline phosphatase activities were different in the effect of Mg2+, fluoride, vanadate, EDTA and resistance to heat inactivation suggesting that these two phosphatase activities were not expressed by the same enzyme.     

A possible role for dephosphorylation in glucocorticoid receptor transformation

Addition of bovine intestinal alkaline phosphatase to mouse AtT-20 cell cytosol increases the rate of glucocorticoid receptor transformation, as evidenced by a change in sedimentation rate from 9.1S to 5.2S. Acid phosphatases are completely ineffective in this regard. Alkaline phosphatase-promoted receptor transformation is both time- and dose-dependent. A variety of phosphatase inhibitors are effective in inhibiting this process, the most potent being transition metal oxyanions such as molybdate, tungstate, and arsenate. The ability of the various inhibitors to suppress alkaline phosphatase-promoted receptor transformation does not correspond well with their potencies for inhibiting para-nitrophenyl phosphate hydrolysis. However, a better correspondence between the inhibition of endogenous receptor transformation and total cytosolic phosphatase activity is observed, and both sodium fluoride and glucose-1-phosphate inhibit endogenous receptor transformation. The protease inhibitors phenyl-methylsulfonyl fluoride and antipain have no effect on receptor transformation. Surprisingly, leupeptin is effective in inhibiting alkaline phosphatase-promoted receptor transformation. Although this raises the possibility of a contaminating protease activity in the alkaline phosphatase enzyme preparation, treatment of covalently affinity-labeled receptor with the enzyme shows no proteolysis of the receptor or any other non-specifically labeled cytosolic protein. Thus, it is possible that a novel action of leupeptin, unrelated to its protease-inhibitory activity, may be involved in the suppression of receptor transformation. The studies presented here suggest that dephosphorylation of some component in cytosol is involved in the destabilization of receptor subunit interactions, resulting in glucocorticoid receptor transformation.     

Rapid purification of bovine kidney branched-chain 2-oxoacid dehydrogenase complex containing endogenous kinase activity

Acid and alkaline phosphatase activity, determined by the hydrolysis of p-nitrophenyl phosphate, was found in preparations of microtubules purified from bovine brain by temperature-dependent assembly-disassembly and ion-exchange chromatography. Phosphocellulose-purified tubulin contained an associated acid phosphatase activity, stimulated by Mg2+ and by Zn2+. Alkaline phosphatase activity with a pH optimum of 10.4 was measured in a fraction of microtubule-associated proteins (MAPs). Kinetics and the effects of sodium fluoride, sodium tartrate, sulfhydryl-blocking agents, EDTA and Zn2+ are reported.     

Light microscopic localization of alkaline phosphatase in fetal bovine bone using immunoperoxidase and immunogold-silver staining procedures

We localized alkaline phosphatase in the metaphyses of fetal bovine tibial bone by use of avidin-biotin-immunoperoxidase and immunogold-silver staining procedures. Low melting-point, paraffin-embedded sections of periodate lysine-paraformaldehyde-fixed undecalcified bone were used for immunostaining. We suggest that the combination of intact embryonic bone with this fixative and the immunohistochemical procedures used in this study may have helped to preserve antigenicity and thus to improve the efficiency of immunolabeling. Similar patterns of alkaline phosphatase localization were produced by the immunoperoxidase and immunogold-silver staining methods. The latter, although free of immunoreagents such as diaminobenzidine, must be monitored closely to avoid nonspecific staining during the silver enhancement procedure. Both methods revealed a concentration of the enzyme in osteoblasts and in areas of osteoid that lined the bone trabeculae. The results support the findings of earlier enzyme cytochemical studies in which osteoblasts were shown to have significant alkaline phosphatase activity.     

Phosphoprotein phosphatases from cell nuclei of the bovine spleen: physico-chemical properties

The physico-chemical properties of phosphoprotein phosphatase (EC 1.3.1.16) from bovine spleen cell nuclei were investigated. The enzyme was shown to possess a wide substrate specificity and to catalyze dephosphorylation of phosphocasein, ATP, ADP and p-nitrophenylphosphate (pNPP). The Km values for ATP, ADP and pNPP are 0.44, 0.43 and 1.25 mM, respectively. The molecular weight of the enzyme as determined by gel filtration on Sephadex G-75 and electrophoresis in polyacrylamide gel of different concentrations is approximately 33 000. SDS-polyacrylamide gel electrophoresis revealed two protein bands with Mr 12 000 and 18 000. The enzyme molecule predominantly contains acidic amino acid residues, two free SH-groups and two disulphide bonds. Phosphoprotein phosphatase is a glycoprotein with the carbohydrate content of about 22%, and has an additional absorption maximum at 560 nm. The enzyme is competitively inhibited by ammonium molybdate (Ki = 0.37 microM) and non-competitively by sodium fluoride (Ki = 1.3 mM). Incubation of phosphoprotein phosphatase with 2 mM phenylmethylsulfonylfluoride (PMSF) for 25 hours resulted in a approximately 46% loss of the enzyme activity. Ammonium molybdate, sodium fluoride and PMSF reversibly inhibit the enzyme. Modification of aminoacid SH-groups, NH2-groups and histidine led to a decrease of the enzyme activity. Incubation of phosphoprotein phosphatase with [gamma-33P]ATP resulted in the incorporation of 0.33 mol of 33P per mol of the enzyme. The mechanism of the enzyme-catalyzed hydrolysis of the phosphoester bond is discussed.     

Increased alkaline phophatase activity in HeLa cells mediated by aliphatic monocarboxylates and inhibitors of DNA synthesis

Alkaline phosphatese activity of HeLa cells is increased from 3- to 8-fold during growth in medium with certain aliphatic monocarboxylates. The four-carbon fatty acid salt, sodium butyrate, is the most effective “inducer” with propionate (C₃), pentanoate (C₅) and hexanoate (C₆) having lesser effects. Other straight-chain aliphatic monocarboxylates, branched-chain analogues of inducers, hydroxylated derivatives, and metabolytes structurally related to butyrate are ineffective in mediating an increase in enzyme activity, indicating stringent structural requirements for inducers. The kinetics of increase in alkaline phosphatase activity in HeLa cells shows a 20–30 h lag period after adding the aliphatic acid followed by a rapid linear increase of enzyme activity. Protein synthesis is required for “induction”. The isozyme of HeLa alkaline phosphatase induced by monocarboxylates is the carcinoplacental form of the enzyme as determined by stereospecific inhibition by the l-enantiomorphs of phenylalanine and tryptophan, heat stability, and immunoreactivity with antibody against the human placental enzyme.Monocarboxylates that mediate increased alkaline phosphatase activity inhibit HeLa cell multiplication. Inhibition of HeLa cell growth may be necessary for induction and this hypothesis is supported by the findings that three different inhibitors of DNA synthesis, i.e. hydroxyurea, 1-β-d-arabinfuranosyl cytosine and methotrexate, also increase alkaline phosphatase activity. These inhibitors are synergistic with butyrate in causing HeLa cells to assume a more spindle-like shape and in producing an up-to 25-fold increase of enzyme activity. Studies on the modulation of carcinoplacental alkaline phosphatase by monocarboxylates commonly used as antimicrobial food additives and by anti-neoplastic agents may provide methods to evoke “tumor markers” of human occult malignancies. These drug-induced elevations of fetal isozyme activity may further our understanding of gene expression in human cells.     

Treatment of CHO-K1 cells with 25-hydroxycholesterol produces a more rapid loss of 3-hydroxy-3-methylglutaryl-coenzyme A reductase activity than can be accounted for by enzyme turnover

A key enzyme in the regulation of mammalian cellular cholesterol biosynthesis is 3-hydroxy-3-methylglutaryl-coenzyme A reductase (HMG-CoA reductase). It is well established that treatment with the compound 25-hydroxycholesterol lowers HMG-CoA reductase activity in cultured Chinese hamster ovary (CHO-K1) cells. After brief incubation (0-4 h) with 25-hydroxycholesterol (0.5 microgram/ml), cellular HMG-CoA reductase activity is decreased to 40% of its original level. This also occurs in the presence of exogenous mevinolin, a competitive inhibitor of HMG-CoA reductase which has previously been shown to inhibit its degradation. The inhibition of HMG-CoA reductase activity by 25-hydroxycholesterol is complete after 2 h. Radio-immune precipitation analysis of the native enzyme under these conditions shows a degradation half-life which is considerably longer than that of the observed inhibition. Studies with sodium fluoride, phosphatase 2A, bacterial alkaline phosphatase and calf alkaline phosphatase indicate that the observed loss of activity is not due to phosphorylation. These data are not consistent with described mechanisms of HMG-CoA reductase activity regulation by phosphorylation or degradation but are consistent with a novel mechanism that regulates the catalytic efficiency of this enzyme.     

Assessment of a method for immunochemical detection of antigen on nitrocellulose membranes

Immunoblotting techniques are widely used for detection of antigen immobilized on nitrocellulose membranes. There are many immunolabeling methods and staining methods available to disclose the presence of antigen in such techniques. Five common staining methods each for alkaline phosphatase and horseradish peroxidase were examined. The staining methods with the highest sensitivity and the lowest background were selected for studies comparing five immunological labeling methods using human IgG as a model antigen. Results were evaluated on the basis of the least amount of detectable antigen and background staining. The most sensitive dot-blot method was then tested for its applicability to Western blots. For both dot-blots and Western blots, the immunoalkaline phosphatase methods are more sensitive than the corresponding immunoperoxidase methods. The use of biotinylated secondary antibodies and an avidin-enzyme conjugate is recommended. Disclosure of alkaline phosphate is best achieved with naphthol AS phosphate as substrate and fast blue BB as chromogen. Peroxidase is best stained using H2O2 and diaminobenzidine (DAB). Potential endogenous enzyme activities are demonstrable by blotting methods but can be inhibited by including levamisole in the disclosure reaction medium for calf intestinal alkaline phosphatase indicators, or by incubation of blots with sodium azide and hydrogen peroxide before immunolabeling when using horseradish peroxidase indicators.     

Artificial evolution of an enzyme active site: structural studies of three highly active mutants of Escherichia coli alkaline phosphatase

The crystal structure of three mutants of Escherichia coli alkaline phosphatase with catalytic activity (k(cat)) enhancement as compare to the wild-type enzyme is described in different states. The biological aspects of this study have been reported elsewhere. The structure of the first mutant, D330N, which is threefold more active than the wild-type enzyme, was determined with phosphate in the active site, or with aluminium fluoride, which mimics the transition state. These structures reveal, in particular, that this first mutation does not alter the active site. The second mutant, D153H-D330N, is 17-fold more active than the wild-type enzyme and activated by magnesium, but its activity drops after few days. The structure of this mutant was solved under four different conditions. The phosphate-free enzyme was studied in an inactivated form with zinc at site M3, or after activation by magnesium. The comparison of these two forms free of phosphate illustrates the mechanism of the magnesium activation of the catalytic serine residue. In the presence of magnesium, the structure was determined with phosphate, or aluminium fluoride. The drop in activity of the mutant D153H-D330N could be explained by the instability of the metal ion at M3. The analysis of this mutant helped in the design of the third mutant, D153G-D330N. This mutant is up to 40-fold more active than the wild-type enzyme, with a restored robustness of the enzyme stability. The structure is presented here with covalently bound phosphate in the active site, representing the first phosphoseryl intermediate of a highly active alkaline phosphatase. This study shows how structural analysis may help to progress in the improvement of an enzyme catalytic activity (k(cat)), and explains the structural events associated with this artificial evolution.