Biochemical and histochemical studies of alkaline and acid phosphatases in a digenetic trematode, Pegosomum egretti

The biochemistry and histochemistry of Pegosomum egretti have been studied using standard techniques. Phosphatases were analysed colorimetrically; the optimum pH for acid phosphatase activity was 5.0 and for alkaline phosphatase was 10.0. The results were compared with those of other trematodes. Histochemical localization of acid and alkaline phosphatases revealed differences in enzymes activity in various tissues. These differences in the site and pattern of distribution of the two enzymes have been discussed in relation to transport of raw materials and the metabolism of the cell concerned.     

Partial purification and biochemical properties of acid and alkaline phosphatases from Myxococcus coralloides D

F. GONZÁLEZ, M.E. FÁREZ-VIDAL, J.M. ARIAS AND E. MONTOYA. 1994. Acid phosphatase and alkaline phosphatase from vegetative cells of Myxococcus coralloides D were purified by two chromatographic steps. The molecular weights were estimated by gel filtration and SDS-PAGE. Optimum pH, stability, optimum temperature and thermal inactivation studies were made for both enzymes. EDTA and other chelating agents inhibited alkaline but not acid activity. Mg²⁺ activated the alkaline phosphatase, while the acid phosphatase was inhibited by fluoride. Both enzymes degraded a number of phosphomonoesters, but were unable to hydrolyse either polyphosphates or cAMP. The K _m values of the acid and alkaline phosphatases for p -nitrophenylphosphate were 5.0 times 10^-3 mol ***l^-1 and 1.5 times 10^-3 mol l^-1, respectively.     

Characterization and expression of uterine and placental alkaline phosphatases in the mouse.

Alkaline phosphatase (ALP) is rapidly induced in the uterine subepithelial stroma after a natural or artificial decidual stimulus. During gestation ALP-specific activity peaked at Day 7 to 8 (Day 1 is day of detection of the copulation plug) followed by a rapid decline to control levels by Day 9. This elevation in enzyme activity was preceded by an 8-fold induction of a 2.6 kilobase (kb) mRNA. This mRNA was not preferentially localized to implantation sites. ALP activity was detected in the placenta at Day 9 and reached maximum specific activity at Day 19. The placental ALP was also encoded by a 2.6 kb mRNA. Uterine and placental ALPs were inhibited to the same extent by levamisole, L-tryptophan and homoarginine. The calculated Ki values for these inhibitors were not statistically different between the uterine and placental forms. Km values towards the substrate p-nitrophenylphosphate, however, were statistically different between the uterine and placental forms. Both uterine and placental ALPs were stimulated 3-4-fold by addition of 2 mM-Mg2+. Electrophoretic mobilities on SDS polyacrylamide gel, where the enzyme migrated as a single band, were the same. The uterine form, however, could be distinguished from the placental isoenzyme by separation on non-denaturing polyacrylamide gels; the uterine form had a single zone of activity which migrated with an intermediate mobility between the two zones of activity detected for the placental enzyme. These differences in mobility could be ascribed to the sialic acid content of the enzyme because treatment with neuraminidase resulted in the uterine and placental forms migrating with comparable but slower mobilities in non-denaturing gels.(ABSTRACT TRUNCATED AT 250 WORDS)     

Comparative histochemical distribution of glycogen and alkaline phosphatases in the placenta

Summary The distribution of glycogen, non-specific alkaline phosphatase, and specific phosphatases acting on adenosine monophosphate, adenosine triphosphate, inosine triphosphate, thiamine pyrophosphate, uridine diphosphate, fructose-6-phosphate, fructose-1:6-diphosphate, and glucose-6-phosphate is described in the placentae and accessory structures of the horse, sheep, cat, dog, ferret, rat, rabbit, guinea pig, and man, and in the yolk-sac of the chick, the oviviparous fish Limia maculata, and man.Correlation between the distribution of these substances and placental function is sought, and the results are discussed with respect to the trophoblast, decidua, giant cells, yolk-sac, non-placental chorion and maternal epithelium and uterine secretion, and allantois. The significance of the presence of the enzymes in the carnivore interstitial matrix, the ferret thickened endoderm and the rodent spongy zone is also considered.     

Partial purification, characterisation and histochemical localisation of alkaline phosphatase from ascocarps of the edible desert truffle Terfezia claveryi Chatin

In the present paper, we confirmed that alkaline phosphatase (ALP) is the main phosphatase present in ascocarps of the edible mycorrhizal fungus Terfezia claveryi. The enzyme was partially purified by precipitation with polyethylene glycol. The purification achieved from a crude extract was fivefold, with 53% of the activity recovered, and acid phosphatase, most of the lipids and phenolic compounds were eliminated. Alkaline phosphatase was kinetically characterised at pH 10.0, the optimum for this enzyme, using p -nitrophenyl phosphate as substrate. The V_max and K_m values were 0.3 μmol·min⁻¹·mg⁻¹ protein and 9.0 m m , respectively. Orthovanadate was a competitive inhibitor of ALP, with a K_i of 42.5 μ m . The enzyme was histochemically localised in the peridium, the hypothecium and in the ascogenic hyphae of the gleba using both colour and fluorescent reactions. The results presented suggest that the ascocarp of T. claveryi, at some stages of its development, may become nutritionally autonomous and independent of the host plant.     

Heterogeneity of alkaline phosphatases in different HeLa lines

Alkaline phosphatase (ALP) components in 8 cell lines of HeLa were examined. Line to line heterogeneity in ALP expression was observed using the criteria of electrophoretic mobility before and after neuraminidase treatment, heat stability, L-phenylanine inhibition, and reactivity against antiplacental ALP antiserum. Six lines contained a placentallike ALP isozyme and varying amounts of a liverlike ALP isozyme. One line contained a liverlike ALP isozyme only. One line contained a new ALP form which was clearly distinguished from the placental, liver, bone, and intestinal ALPs. Thus, derepression of the placental ALP structural locus appeared to have occurred in 6 of the 8 lines. However, where expressed, the placentallike ALP varied electrophoretically from line to line, and in only one case was the mobility identical to that of a common placental ALP phenotype. This phenotypic heterogeneity of the "derepressed' placentallike ALP contrasts markedly with the phenotypic stability of other enzymes expressed in HeLa cells.     

Megaoesophagus in the mouse: histochemical and ultrastructural studies

Histochemical and ultrastructural studies of the muscle coat of the oesophagus from ICRC/HiCri mice (with megaoesophagus) and DBA/2fNCri mice (normal oesophagus) were carried out. The striking observation from histochemical studies was the presence of smooth muscle in the abdominal segment of the oesophagus from ICRC mouse in contrast to the control strain where smooth muscle was present only in the lowermost portion adjoining the stomach. Ultrastructural studies of the oesophageal wall from 5- and 10-day-old ICRC mice revealed an apparently normal muscle coat. In 3-month-old ICRC mice the upper abdominal segment of the oesophagus showed several abnormalities of smooth muscle fibres and paucity of plexus tissue accompanied by interstitial collagen deposition. The abnormalities were more severe in 1-year-old animals and were seen throughout the abdominal segment. From this study it is suggested that the primary cause of megaoesophagus in ICRC mice is neurogenic and not myogenic.     

Species and organ dependence of alkaline phosphatase activity in lymphatic tissues. A histochemical, biochemical and electrophoretic study

Synopsis Alkaline phosphatase activity in lymphatic tissues of guineapig, cat, cow, dog, rabbit, sheep, rat, mouse, hamster, chicken and man was studied with histochemical, biochemical and electrophoretic techniques. The thymus showed decreasing alkaline phosphatase activity from species to species in the order just given. Activity of alkaline phosphatase in other lymphatic tissues did not show such clear species and organ dependence. Spleens of the cat, cow and rabbit and lymph nodes of the cow and sheep gave, however, very characteristic patterns of alkaline phosphatase activity. In the chicken there was no difference between the alkaline phosphatase content of the thymus and that of the bursa of Fabricius. The lymphatic follicles of human tonsils and appendix and in the appendix of the rabbit exhibited alkaline phosphatase activity in the circular cell layer. This was also seen in some follicles in the lymph nodes of certain species. Electrophoretically, the main alkaline phosphatase fraction of the lymphatic tissues closely resembled the main fraction of blood, though it is probably not identical with it. Although the biological function of alkaline phosphatase is unknown, the greatly varying alkaline phosphatase content in different lymphatic organs of different species indicates that immunological studies with one species or with cells derived from a certain lymphatic tissue or with both are probably not directly comparable with studies using other species or cells from other lymphatic tissues.     

Purification and characterization of four different alkaline phosphatases from Spirographis spallanzanii

Alkaline phosphatases (APs) present in Spirographis spallanzanii were extracted by water homogenization of butanol treatment. The enzymes solubilized as above were purified by acetone fractionation and then by DEAE-cellulose and Sephadex G-200 chromatography; separation of four AP forms was achieved, which were characterized by studying their molecular and catalytic properties. The various APs differ in molecular weight, electrophoretic mobility, optimum pH, but show similar Km values and substrate inhibition pattern. Kinetic studies carried out with several inhibitors show, in particular, the existence in these APs of a second binding site and suggest a possible role for them in the metabolism of phosphoric esters of the sugars.     

Evidence on the presence of two distinct alkaline phosphatases in Serratia marcescens

Certain strains of Serratia marcescens synthesized two different types of alkaline phosphatase (APase), constitutive (CAPase) and inducible (IAPase) APases, in low phosphate medium. Synthesis of the IAPase was repressed in the presence of high phosphate. Purification and separation of these electrophoretically distinct APases was achieved by using fractional (NH(4))(2)SO(4) precipitation, adsorption on a DEAE-cellulose column and elution of enzymes by a linear sodium chloride gradient. Starch gel electrophoresis of certain fractions revealed the separation of not only IAPase from CAPase but its separation into four distinct isozymes. CAPase gave maximum enzyme activity around pH 9.5, whereas for IAPase a broad range of enzyme activity was found between pH 8.5 and 10.5. Reversible inactivation at low pH occurred for IAPase but very little with CAPase. CAPase was more thermolabile than IAPase at 95 degrees C. The two APases were found to be distinct in their kinetic as well as immunological properties, suggesting two distinct enzyme species.     

Characterization of heterodimeric alkaline phosphatases from Escherichia coli: an investigation of intragenic complementation

Escherichia coli alkaline phosphatase (EC 3.1.3.1) belongs to a rare group of enzymes that exhibit intragenic complementation. When certain mutant versions of alkaline phosphatase are combined, the resulting heterodimeric enzymes exhibit a higher level of activity than would be expected based upon the relative activities of the parental enzymes. Nine previously identified alkaline phosphatase complementation mutants were re-examined in this work in order to determine a molecular explanation of intragenic complementation in this experimental system. The locations of these mutations were determined by DNA sequence analysis after PCR amplification of the phosphatase-negative phoA gene. Most of the mutations involved ligands to metal-binding sites. Each of the mutant enzymes was re-created by site-specific mutagenesis, expressed, purified, and kinetically characterized. To investigate cooperativity between the two subunits, we analyzed heterodimeric forms of some of the site-specific mutant enzymes. To enable the isolation of the heterodimeric alkaline phosphatase in pure form, the overall charge of one subunit was altered by replacing the C-terminal Lys residue with three Asp residues. This modification had no effect on the kinetic properties of the enzyme. Heterodimeric alkaline phosphatases were created using two methods: (1) in vitro formation by dissociation at acid pH followed by reassociation at slightly alkaline pH conditions in the presence of zinc and magnesium ions; and (2) in vivo expression from a plasmid carrying two different phoA genes. Increases in k(cat), as well as a large reduction in the p-nitrophenyl phosphate K(m) were observed for certain combinations of mutant enzymes. These results suggest that the structural assembly of E. coli alkaline phosphatase into the dimer induces cooperative interactions between the monomers necessary for the formation of the functional form of the holoenzyme.