Localization of Acid and Alkaline Phosphatases in Staphylococcus aureus

The localization of acid and alkaline phosphatases in Staphylococcus aureus was studied by fractionation of cells after treatment with the L-11 enzyme and by electron microscopic histochemistry. The two enzyme activities were located in distinctly different positions at the surface of the cells. Acid phosphatase appeared to be localized around the cell membrane of the bacteria, because the enzyme was recovered exclusively in the membrane fraction and because deposition of lead phosphate was detected by electron microscopic histochemistry on the inner surface of the cell membrane of intact bacteria and spheroplasts. The highest specific activity of alkaline phosphatase was also associated with the membrane fraction. However, on electron microscopic histochemistry of intact cells, the deposition of lead phosphate was only seen on the outer surface of the cell wall.     

DIFFERENTIAL ACTIVITIES OF ACID PHOSPHATASE FROM ADAXIAL AND ABAXIAL REGIONS OF LUPINUS LUTEUS (FABACEAE) COTYLEDONS

Acid phosphatases of abaxial and adaxial regions in the cotyledons of the Lupinus luteus which possess structurally distinct protein bodies were examined. Acid phosphatase activity was investigated by enzyme assays and by gel electrophoresis and was localized by cytochemical methods in the cotyledons of Lupinus luteus L. during germination and seedling development. Acid phosphatase activity was significantly higher in the adaxial (heterogeneous protein body) region as compared to the abaxial (homogeneous protein body) region of the cotyledon. The pH optimum of acid phosphatase from the abaxial region and from the adaxial region was 4.5 and 5.0, respectively. There were significant differences in substrate specificity and isoenzymic composition of the enzyme between the two regions. Isoenzymic composition changed during the course of germination and seedling development. Acid phosphatase was localized in the matrix of the homogeneous protein bodies and in the globoids of the heterogeneous protein bodies at imbibition. After germination (d 3, d 4, d 7) acid phosphatase was localized primarily in the inner cell walls and intercellular spaces of both regions. These results show that different isoenzymes of acid phosphatase show differential localization and the rate of acid phosphatase activation or synthesis differs in cells from the two regions of the cotyledon.     

Alkaline and acid phosphatases of the marine diatoms Chaetoceros affinis var. willei (Gran) Hustedt and Skeletonema costatum (Grev.) Cleve

Alkaline phosphatase activity in cultures of the marine diatom Chaetoceros affinis var. willei (Gran) Hustedt was higher than in Skeletonema costatum (Grev.) Cleve. The enzyme activity was localized in coarse cell particles. Acid phosphatase activity was found in the cytoplasmic fraction. Induction of alkaline phosphatase depended on the $\text{N}\text{P}$ ratio in the culture medium. A $\text{N}\text{P}$ ratio > 40 in dilution/batch culture and > 30 in large scale batch culture, respectively, induced alkaline phosphatase.Cell phosphorus showed a critical value below which alkaline phosphatase was induced. Alkaline phosphatase in natural phytoplankton from the Trondheimsfjord is unlikely to occur except possibly in special situations.     

A model for acid and alkaline phosphatase activity in a small pond

Acid and alkaline phosphatase activity were determined in a small pond over a period of 24 months (64 samples). Activity of each phosphatase enzyme was positively correlated with chlorophyll concentration, viable bacterial count, total phosphate concentration, inorganic phosphate concentration, and temperature. Multiple regression analysis was used to formulate equations that described phosphatase activity in terms of these physical, chemical, and biotic factors. Corrected coefficients of determination were calculated, and the highest values were obtained when all parameters were included in the equation (r ²=0.776 and 0.659 for alkaline and acid phosphatase activity, respectively). However, there was little improvement in ther ² value obtained when only chlorophyll was used in the equation (r ²=0.654 and 0.624, respectively). Samples were then taken over a further 12 months (25 samples), and observed activity was compared with the activity predicted by application of the previously derived equations. For alkaline phosphatase, the best fit between observed and expected activity was seen with the equation containing all parameters, but for acid phosphatase the best fit was seen with the equation containing only chlorophyll and temperature as the determinants. In both cases there was a good fit between observed and expected data using the equation containing chlorophyll as the sole determinant. From this we have concluded that phytoplankton were the chief producers of phosphatase activity in this pond, although the influence of physical and chemical factors on enzyme activity could not be ignored.     

Electron-cytochemical localization of alkaline phosphatase to G cells of Necturus maculosus antrum

Summary Electron-cytochemical localization of alkaline phosphatase activity was performed on G cells of Necturus maculosus antral mucosa. Alkaline phosphatase activity was localized to the nuclear membrane, the Golgi/endoplasmic reticulum, and the limiting membranes of G cell peptide-secretion vesicles. There was no specific localization of alkaline phosphatase activity to the plasma membrane. Treatment of the tissues with levamisole (an alkaline phosphatase inhibitor) did not markedly reduce the specific alkaline phosphatase activity. Specific lead deposition was reduced by removal of the substrate from the reaction mixture. The results from this study on N. maculosus G cells demonstrate that alkaline phosphatase activity can be found in a non-mammalian gastric endocrine cell and that specific activity was localized primarily to those intracellular structures involved with protein biosynthesis.     

COMPARATIVE ALKALINE PHOSPHATASE CHARACTERISTICS OF THE ALGAL BLOOM DINOFLAGELLATES PROROCENTRUM DONGHAIENSE AND ALEXANDRIUM CATENELLA,AND THE DIATOM SKELETONEMA COSTATUM1

The alkaline phosphatase (AP) characteristics of three algal bloom species in the coastal waters of China [Prorocentrum donghaiense D. Lu, Alexandrium catenella (Whedon et Kof.) Balech, and Skeletonema costatum (Grev.) Cleve] were analyzed in a laboratory batch culture experiment using bulk assay and the single‐cell enzyme‐labeled fluorescence (ELF) method. Results showed that the AP of these three test species shared some common characteristics: AP was inducible in all three species and was expressed by algae under phosphorus (P)–stress conditions; no constitutive AP enzyme was detected in the three test species. Once AP was produced, all three test species gradually released the enzymes into the water, and the algae would reinduce AP production. There were also different specific AP characteristics among the three test species under severe P‐stressed conditions. In P. donghaiense, AP covered most of the cell, and the AP production sites were mainly on the cell surface, although some could be observed inside cells. AP also covered the whole cell of A. catenella, but the AP sites were mainly inside the cell with only some on the cell surface. Only one or two AP sites could be detected in S. costatum, and they were all on the cell surface.     

Extracytoplasmic phosphatases of selected species of Saccharomyces, Kluyveromyces and Rhodotorula

Phosphatase activities of yeasts belonging to the genera Saccharomyces, Kluyveromyces and Rhodotorula were studied. Rhodotorula rubra exhibited activities at acid, neutral and alkaline pH; the other yeasts only had activity at acid pH. Growing yeasts in a constant pH (4.5) medium decreased phosphatase activities in Saccharomyces and Kluyveromyces, while neutral activity was enhanced in Rhodotorula rubra which excreted more enzyme under these conditions. Washing cells with sucrose solutions lowered phosphatase activities in all yeasts, due to enzyme liberation. Acid phosphatase activities in isolated and purified cell walls were very small. Phosphatases thus appear not to be strongly bound to yeast cell walls.     

Localization of alkaline phosphatase inBacillus intermedius cells

Alkaline phosphatase, an enzyme secreted byBacillus intermedius S3-19 cells to the medium, was also detected in the cell wall, membrane, and cytoplasm. The relative content of alkaline phosphatase in these cell compartments depended on the culture age and cultivation medium. The vegetative growth ofB. intermedius on 0.3% lactate was characterized by increased activity of extracellular and membrane-bound phosphatases. The increase in lactate concentration to 3% did not affect the activity of membrane-bound phosphatase but led to a decrease in the activity of the extracellular enzyme. Na₂HPO₄ at a concentration of 0.01 % diminished the activity of membrane-bound and extracellular phosphatases. CoCl₂ at a concentration of 0.1 mM released membrane-bound phosphatase into the medium. By the onset of sporulation, phosphatase was predominantly localized in the medium and in the cell wall. As is evident from zymograms, the multiple molecular forms of phosphatase varied depending on its cellular localization and growth phase.     

Ultrastructure of the ventriculus of the honey bee,Apis mellifera (L.): cytochemical localization of acid phosphatase,alkaline phosphatase,and nonspecific esterase

Summary Ventriculi (midguts) from 5-day- and 30-day-old honey bees, Apis mellifera (L.), were examined ultrastructurally and cytochemically. Midgut epithelia were composed of regenerative cells, endocrine cells, and pleomorphic columnar cells. Regions of the midgut were encountered in which the cytogeny of the columnar cells, the content of discharged vesicles, and the structure of the peritrophic membrane varied. In 5-day-old bees, regional variation in the ultrastructure of the cells indicated that absorption occurred primarily in the middle of the gut and that regulated enzyme secretion appeared to be confined to the posterior midgut. In 30-day-old bees, reduced pollen consumption was accompanied by diminished cell activity in the posterior midgut. Our ultrastructural data suggest that the honey bee, like other insects, may rely on countercurrent flow to distribute enzymes and nutrients efficiently throughout the ectoperitrophic and endoperitrophic compartments. Acid phosphatase and nonspecific esterase activity were localized cytochemically in primary and secondary lysosomes. Alkaline phosphatase activity was localized on the elongate microvilli of the striated border and within large electron-lucent microbodies. The association of alkaline phosphatase activity with the peroxisomal microbodies and their relation to phospholipid metabolism are discussed.     

Phosphatase activity in the heterotrophic dinoflagellate Pfiesteria shumwayae

The ELF-97 phosphatase substrate was used to examine phosphatase activity in four strains of the estuarine heterotrophic dinoflagellate, Pfiesteria shumwayae. Acid and alkaline phosphatase activities also were evaluated at different pH values using bulk colorimetric methods. Intracellular phosphatase activity was demonstrated in P. shumwayae cells that were actively feeding on a fish cell line and in food limited cells that had not fed on fish cells for 3 days. All strains, whether actively feeding or food limited showed similar phosphatase activities. P. shumwayae cells feeding on fish cells showed ELF-97 activity near, or surrounding, the food vacuole. Relatively small, spherical ELF-97 deposits were also observed in the cytoplasm and sometimes near the plasma membrane. ELF-97 fluorescence was highly variable among cells, likely reflecting different stages in digestion and related metabolic processes. The location of enzyme activity and supporting colorimetric measurements suggest that, as in other heterotrophic protists, acid phosphatases predominate in P. shumwayae and have a general catabolic function.     

Seasonal activity of non-specific acid and alkaline phosphatases in beech (<Emphasis Type="Italic">Fagus sylvatica</Emphasis>) leaves

The activities of acid and alkaline phosphatases along with phosphorus content in leaves of European beech (Fagus sylvatica L.) were studied for a period from April to October. The phosphorus content of beech leaves was highest in April, at the beginning of the vegetation period; from May to October it was twofold lower than in April. Acid phosphatase activity (per unit fresh weight) in leaves collected from the middle part of the crown decreased significantly in May and July compared to the enzyme activity in April. In both the low and middle parts of the crown, the acid phosphatase activity had a peak in August, and thereafter decreased in September and October. No correlations between acid phosphatase activity and phosphorus concentrations were found. Alkaline phosphatase activity was very low and in some cases near the detection limit during the whole observation period.     

Phosphatases; origin,characteristics and function in lakes

Phosphatases catalyze the liberation of orthophosphate from organic phosphorus compounds. The total phosphatase activity in lake water results from a mixture of phosphatases localized on the cell surfaces of algae and bacteria and from dissolved enzymes supplied by autolysis or excretion from algae, bacteria and zooplankton. External lake water phosphatases usually have pH optima in the alkaline region. Acid phosphatases generally seem to be active in the internal cell metabolism. The synthesis of external alkaline phosphatases is often repressed at high phosphate concentrations and derepressed at low phosphate concentrations. Phosphatase activity has therefore been used as a phosphorus deficiency indicator in algae and in natural plankton populations. The possibilities for this interpretation of phosphatase activity in lake water are limited, however, and this is discussed. The in situ hydrolysis capacity, i.e. the rate by which orthophosphate is released from natural substrates, is unknown. However, we advocate that this process is important and that the rate of substrate supply, rather than phosphatase activity, limits the enzymatic phosphate regeneration.     

Properties and biosynthesis of cell wall-bound acid phosphatase in Aspergillus nigerx

Acid phosphatase (EC 3.1.3.2 [EC] ) of Aspergillus niger myceliumwas distributed exclusively in the cell wall and soluble fractions,whereas alkaline phosphatase was distributed in the solubleand particulate fractions but only slightly in the cell wallfraction. Cell wall-bound acid phosphatase was released by fungal-walllytic enzymes such as snail gut juice. Cell wall-bound, released,and soluble acid phosphatases showed very similar enzymaticproperties except that the bound enzyme was more stable to heatand detergents. By DEAE-cellulose chromatography, the releasedacid phosphatase was found to correspond to acid phosphatasesI A, IB and II in the soluble fraction. When phosphate in the medium was consumed, the acid phosphataseactivity of the soluble fraction increased more rapidly thanthat of the cell wall fraction. When phosphate was added tothe derepressed culture, the acid phosphatase activity of thesoluble fraction decreased after a short lag period, while thatof the cell wall fraction continued to increase. When labeledamino acid was added to the derepressed culture, it was incorporatedinto the soluble acid phosphatase without a lag period, whileit was incorporated into the cell wall phosphatase after a lagperiod. From these observations, acid phosphatase was consideredto be synthesized first as the soluble form and then integratedinto the cell wall. ¹ The present experiments were carried out, for the most part,at the Institute of Applied Microbiology of the University ofTokyo. (Received January 19, 1976; )     

Characterization ofZymomonas mobilis alkaline phosphatase activity inEscherichia coli

Zymomonas mobilis phoA gene encoding alkaline phosphatase was expressed inEscherichia coli CC118 carrying the recombinant plasmid pZAP1. The pH optimum for this enzyme was 9.0 and showed a peak activity at 42°C. This enzyme required Zn²⁺ for its catalytic activity; however, Mg²⁺ or Ca²⁺ significantly affected the activity. This enzyme was found to be ethanolabile, and ethanol inhibition was reversed by addition of Zn²⁺. Kinetics ofZ. mobilis alkaline phosphatase production inE. coli CC118 (pZAP1) showed that the enzyme activity was growth associated and localized in the cellular fraction, and the maximum activity was found in the stationary phase.     

Enzyme activity during the growth and aging of human cells in vitro

Acid phosphatase, alkaline phosphatase, and lactic dehydrogenase activities have been compared in normal human diploid cell strains and in SV₄₀-transformed heteroploid cell lines derived from them. A higher level of acid phosphatase activity was observed in diploid cultures derived from adult lung than in cultures derived from fetal lung of similar passage levels. The alkaline phosphatase activity of normal diploid fibroblasts was significantly higher than that of SV₄₀-transformed cell lines derived from them. Generally, the lactic dehydrogenase activities of all these cell cultures were similar. Human diploid cells in culture “age,” in the sense that their ability to proliferate decreases with time during serial subcultivation. Evaluation of the activities of these three enzymes during the “aging” process showed that, although alkaline phosphatase and lactic dehydrogenase activities were similar in “young” and “senescent” cells, acid phosphatase showed a small but significant increase in the senescent cells.     

Localization of some enzymes in the main venom glands of viperid snakes

Several secretory and nonsecretory enzymes were localized histochemically in the main venom gland of 13 viperid snakes. All secretory cells show the intracellular oxidative enzymes succinate dehydrogenase and monoamine oxidase. The granular reactions obtained for both enzymes resemble mitochondria in distribution. Distinctive cells with a very high succinate dehydrogenase activity are dispersed among the secretory cells of all species except Atractaspis. Nonspecific acid phosphatase activity is found in the supranuclear region of the secretory cells in species that do not secrete this enzyme and throughout the cytoplasm in snakes that secrete the enzyme. Nonspecific alkaline phosphatase activity occurs in the secretory cells of those snakes whose venom shows this activity. Leucine amino peptidase (aryl amidase) activity is found in the venom and in the secretory cells of all the species. In Vipera palaestinae both the venom and the secretory cells of the main venom gland contain nonspecific esterase, L-amino acid oxidase and phosphodiesterase activities. The localization of phosphodiesterase and L-amino acid oxidase do not show major differences between glands at different intervals from an initial milking. Adenosine-monophosphate phosphatase activity is localized in the supranuclear region of the secretory cells in the glands of Vipera palaestinae and Aspis cerastes. Its activity is found in the venom of Aspis only.     

Observations on acid phosphatase in Mayorella palestinensis

Acid phosphatase activity has been studied in the ameba Mayorella palestinensis. Optimum activity of the enzyme was found to be at a pH of 3.2. The enzyme is inhibited by fluoride ion, but is not sensitive to Mg⁺⁺. The activity was found to be correlated with age of culture. Two maxima have been obtained, one from cultures in the logarithmic phase, and the other during the period of maximal cell encystation. These results suggest that acid phosphatase play an important role in cell metabolism during growth and differentiation processes of this ameba.     

The response of alkaline phosphatase to osmoregulatory changes in the trout,Salmo gairdneri

Summary The relationship between alkaline phosphatase and environmental salinity was examined in the rainbow trout and the migratory rainbow (steelhead),Salmo gairdneri. The enzyme activity in tissues involved in osmoregulation was strongly correlated with the adaptation salinity and thus to the degree of salt and fluid transport in those tissues. After transfer from freshwater to seawater, the specific activity of the enzyme increased over 260% in the intestine, decreased by 50% in kidney, and was unchanged in the liver, an organ not directly involved in osmoregulation. The sea-run steelhead trout response was similar to the nonmigratory rainbow; although, the pre-migratory transformation (smoltification) had no effect on enzyme activity. Amino acid inhibitors of alkaline phosphatase significantly reduced fluid absorption in the isolated intestine of rainbow trout, reaffirming the relationship between the enzyme and fluid movement. Electrophoretic identification of trout alkaline phosphatase isozymes, clearly distinguishes the enzyme from different tissue origins. However, from the analysis of intestinal electrophoretic patterns, osmoregulatory adjustments are not associated with the induction of new alkaline phosphatase isozymes, or in the large scale preferential stimulation of one of the two existing intestinal isozymes over the other.     

Cytochemical localization of alkaline phosphatase in the cell membrane ofDictyostelium discoideum amebae

Summary We demonstrated that alkaline phosphatase was localized on the cell membrane ofDictyostelium discoideum amebae and on isolated plasma membranes. The enzyme activity was specifically inhibited by 0.01 M KCN or cysteine. The same method could also be applied to baker's yeast and MDCK cells (dog kidney cells in vitro).