Alkaline phosphatase in HeLa cells. Stimulation by phospholipase A2 and lysophosphatidylcholine.

Treatment of homogenates and plasma membrane preparations from HeLa cells with phospholipase A2 (EC 3.1.1.4) caused a 50% increase in activity of membrane-associated alkaline phosphatase. Lysophosphatidylcholine, dispersed in 0.15 M KCl, affected alkaline phosphatase in a similar fashion by releasing the enzyme from particulate fractions into the incubation medium and by elevating its specific activity. Higher concentrations of lysophosphatidylcholine solubilized additional protein from particulate fractions but did not further increase the specific activity of the released alkaline phosphatase. Particulate fractions from HeLa cells were exposed to the effects of liposomes prepared from lysophosphatidylcholine and cholesterol. The ratio of particulate protein/lysophosphatidylcholine (by weight) required for optimal activation of alkaline phosphatase was one. Kinetic studies indicated that phospholipase A2 and lysophosphatidylcholine enhanced the apparent V of the enzyme but did not significantly alter its apparent Km. The increased release of alkaline phosphatase from the particulate matrix by lysophosphatidylcholine was confirmed by disc electrophoresis. The release of the enzyme by either phospholipase A2 or by lysophosphatidylcholine appeared to be followed by the formation of micelles that contained lysophosphatidylcholine. The new complexes had relatively less cholesterol and more lysophosphatidylcholine than the native membranes. The possibility that lysophosphatidylcholine formed a lipoprotein complex with the solubilized alkaline phosphatase was indicated by a break point in the Arrhenius plot which was evident only in the lysophosphatidylcholine-solubilized enzyme but could not be demonstrated in alkaline phosphatase that had been released with 0.15 M KCl alone.     

Cell cycle variations in HeLa 65 plasma membrane alkaline phosphatase

HeLa plasma membranes from M, G₁, and S phase cells were isolated from growing synchronous cell cultures. It was found that the specific activity of plasma membrane alkaline phosphatase was over three times higher in the M phase cell than in the G₁ and S phase cell. However, sodium dodecyl sulfate (SDS) polyacrylamide disc gel electrophoresis showed that the S phase plasma membrane contained 5.5 times more alkaline phosphatase protein than did the plasma membrane from mitotic cells, and 11.0 times more than the G₁ phase plasma membrane. This would indicate that the high specific activity in mitosis was due to modification of the alkaline phosphatase protein resulting in increased enzymatic activity.     

Plasma membrane localization of alkaline phosphatase in HeLa cells.

The localization of alkaline phosphatase in HeLa cells was examined by electron microscopic histochemistry and subcellular fractionation techniques. Two monophenotypic sublines of HeLa cells which respectively produced Regan and non-Regan isoenzymes of alkaline phosphatase were used for this study. The electron microscopic histochemical results showed that in both sublines the major location of alkaline phosphatase is in the plasma membrane. The enzyme reaction was occasionally observed in some of the dense body lysosomes. This result was supported by data obtained from a subcellular fractionation study which showed that the microsomal fraction rich in plasma membrane fragments had the highest activity of alkaline phosphatase. The distribution of this enzyme among the subcellular fractions closely paralleled that of the 5'-nucleotidase, a plasma membrane marker enzyme. Characterization of the alkaline phosphatase present in each subcellular fraction showed identical enzyme properties, which suggests that a single isoenzyme exists among fractions obtained from each cell line. The results, therefore, confirm the reports suggesting that plasma membrane is the major site of alkaline phosphatase localization in HeLa cells. The absence of any enzyme reaction in the perimitochondrial space in these cultured tumor cells also indicates that the mitochondrial localization of the Regan isoenzyme reported in ovarian cancer may not be a common phenomenon in Regan-producing cancer cells.     

Induction of plasma membrane alkaline phosphatase in rat liver

We have determined alkaline phosphatase activity in total liver plasma membrane fractions from rats subjected to a partial hepatectomy and sham operated with or without manipulation of the liver. In all these cases, an increase of the enzyme activity was observed. Kinetic studies of alkaline phosphatase activity performed on plasma membrane fractions from rats subjected to a partial hepatectomy suggest that alkaline phosphatase increase is produced by de novo biosynthesis of enzyme molecules. Determination of alkaline phosphatase activity in purified plasma membrane subfractions corresponding to each of the three functional regions of the hepatocyte surface (blood sinusoidal, lateral and bile canalicular), indicates that the increase of the enzyme activity observed after partial hepatectomy is selectively induced in the bile canalicular domain of the hepatocyte plasma membrane.     

Biochemical localization of the alkaline phosphatase of Bacillus licheniformis as a function of culture age.

Biochemical localization of the enzyme as a function of age of cell culture showed the alkaline phosphatase (orthophosphoric monoester phosphohydrolase, EC 3.1.3.1) activity of Bacillus licheniformis MC14 predominantly in the particulate cell fraction in early- and mid-log cells. However, in late-log and stationary cells, increasing amounts of activity were found in the soluble fraction of lysed cells. Upon protoplast formation of these cells, the activity was released into the soluble fraction. No alkaline phosphatase activity was found in either the cytoplasmic fraction or in the cell medium during any phase of cell growth. The soluble fraction released on protoplast formation that contained alkaline phosphatase activity showed immunological cross-reactivity with antibody to the purified heat--salt-solubilized membrane alkaline phosphatase (F. M. Hulett-Cowling and L. L. Campbell, 1971). Theparticulate membrane fraction containing a firmly associated alkaline phosphatase also showed similar cross-reactivity. Further, the effectiveness of nonionic detergents, ionic detergents, bile salts, and various concentrations of magnesium and sodium as solubilizing agents for this membrane-bound alkaline phosphatase was investigated. Hexadecyl pyridinium chloride (0.03 M) and magnesium and sodium salts (above 0.2 M) were effective solubilizing agents. The substrate specificities of the various fractions were determined and compared to the substrate specificities of the purified membrane alkaline phosphatase.     

Glyceraldehyde-3-phosphate dehydrogenase,a glycolytic enzyme present in the periplasm of Aeromonas hydrophila

This is the first report describing the glycolytic enzyme, glyceraldehyde-3-phosphate dehydrogenase (GAPDH), as a protein associated with the cell envelope of a gram-negative bacterium (Aeromonas hydrophila). Dose-dependent GAPDH activity was detected in whole bacterial cells from exponentially growing cultures, indicating that an active form of GAPDH is located outside the plasma membrane. This activity represents roughly 10–20% of total cell activity, and it is not reduced by pretreatment of the cells with trypsin. Assays with soluble GAPDH indicate that the activity measured in intact cells does not originate by rebinding to intact cells of cytosolic enzyme released following cell lysis. GAPDH activity levels detected in intact cells varied during the growth phase. The relationship between GAPDH activity and cell culture density was not linear, showing this activity as a major peak in the late-logarithmic phase (A₆₀₀ = 1.1–1.3), and a decrease when cells entered the stationary phase. The late exponential growing cells showed a GAPDH activity 3 to 4-fold higher than early growing or stationary cells. No activity was detected in culture supernatants. Enzymatic and Western-immunoblotting analysis of subcellular fractions (cytosol, whole and outer membranes, and periplasm) showed that GAPDH is located in the cytosol, as expected, and also in the periplasm. These results place the periplasmic GAPDH of A. hydrophila into the family of multifunctional microbial cell wall-associated GAPDHs which retain their catalytic activity. This revised version was published online in June 2006 with corrections to the Cover Date.     

Distribution of alkaline phosphatase in vegetative dictyostelium cells in relation to the contractile vacuole complex

The structure of the contractile vacuole complex of Dictyostelium discoideum has long been a subject of controversy. A model that originated from the work of John Heuser and colleagues described this osmoregulatory organelle as an interconnected array of tubules and cisternae the membranes of which are densely populated with vacuolar proton pumps. A conflicting model described this same organelle as bipartite, consisting of a pump-rich spongiome and a pump-free bladder, the latter membranes being identified by their alkaline phosphatase activity. In the present study we have employed an antiserum specific for Dictyostelium alkaline phosphatase to examine the distribution of this enzyme in vegetative cells. The antiserum labels puncta, probably vesicles, that lie at or near the plasma membrane and are sometimes, but only rarely, enriched near contractile vacuole membranes. We conclude that alkaline phosphatase is not a suitable marker for contractile vacuole membranes. We discuss these results in relation to the two models of contractile vacuole structure and suggest that all data are consistent with the first model.     

Nuclear membrane fusion in electrofused mammalian cells

Fusion of nuclei was studied in electrofused cells using staining procedures and DNA flow cytometry. Homogeneous and heterogeneous electrofusion of Ehrlich ascites tumor cells. Muntjac cells and V79-S181 cells were performed in balanced-salt solutions at low temperature. Incubation of the cells subjected to electrofusion in fusion media for about 2 h was required to complete cell fusion and, in particular, nuclear membrane fusion. Under optimum electrofusion conditions it was found that fusion of nuclei is a very frequent event. Half of the fused cells (about 30 to 50% of the field-exposed cells) underwent nuclear membrane fusion. It is shown that the high frequency of nuclear membrane fusion in electrofused, unsynchronised cells resulted from intracellular dielectrophoresis occurring during cell alignment. In accordance with theory, maximum nuclear membrane fusion was observed using alignment fields of between 1 and 4 MHz (depending on the cell species), that is above the frequencies at which the plasmalemma capacity no longer shielded the cell interior from participation in the conduction process. In this frequency range a potential difference can be built up across the nuclear membrane leading to repositioning of the nuclei into the contact zone of the plasmalemmas of two attached cells. This intracellular dielectrophoresis apparently facilitated fusion of nuclei once intermingling of the plasma membranes had occurred. It was further demonstrated that exponentially growing cells showed higher cell fusion rates than cells taken from the unfed plateau phase. One, but not the only reason, might be the higher ATP content of exponentially growing cells compared to cells of the plateau phase. Addition of external ATP to plateau phase cells during electrofusion resulted, in accordance with this assumption, in an increase of fusion frequency, whereas ATP had apparently no effect on the fusion yield of exponentially growing cells. G1 cells obtained by mitotic selection after nocodazole-induced blockage in metaphase also showed higher cellular and nuclear membrane fusion yields than exponentially growing cells. Most importantly, it could be demonstrated both experimentally and theoretically that electrofusion of cells in a dielectrophoretically aligned chain is controlled by a simple law of probability resulting predominantly in fusion of two cells independent of the number of cells in the chain. The likelihood of fusion of various numbers of cells in a chain is given by the appropriate power of the probability of two-cell fusion.(ABSTRACT TRUNCATED AT 400 WORDS)     

The autorelease of alkaline phosphatase from the plasma membrane during the incubation of cultured liver cell homogenates

When a rat hepatoma cell (R-Y121B) homogenate was incubated at 37 degrees C, 30-70% of the total alkaline phosphatase was released into the supernatant fluid from the precipitate fractions. The release reached a plateau level after 10 h of incubation at 37 degrees C. The optimum pH value for the release was 7.4. Alkaline phosphatase activity increased during the incubation of the cell homogenates, but this increase was independent of the enzyme release. Serum increased not only alkaline phosphatase activity in the cultured cells but also enzyme release in their homogenates. In addition, we examined a rat liver homogenate and the following 11 cell lines: 3 hepatoma cell lines, including the R-Y121B cell line, 4 liver cell lines, 2 human urinary bladder carcinoma cell lines, a kidney cell line, and a mouse adrenal tumor cell line. Only in the cultured liver cell line and hepatoma cell lines, 30-60% of the total enzyme was released into the soluble fraction from the precipitate fractions; the release was not observed in the other cell lines, nor in the rat liver homogenate. The release of alkaline phosphatase took place in both heat-stable and heat-labile alkaline phosphatases. Alkaline phosphatase, extracted from cell homogenates, showed two bands during polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. The mobilities of the two bands changed inversely with or without sodium dodecyl sulfate. In general, the alkaline phosphatase which showed slow mobility with sodium dodecyl sulfate was more readily released from the plasma membrane.(ABSTRACT TRUNCATED AT 250 WORDS)     

Synthesis of acid phosphatase during dehydration of the yeast Saccharomyces cerevisiae

Summary During the dehydration of exponentially growing yeast cells for 24 h at 37° C, a 2–3 fold increase in the activity of acid phosphatase was observed. This increase is inhibited by cycloheximide and 2-deoxy-D-glucose and therefore is indicative of de novo synthesis. The presence of exogenous orthophosphate during drying does not affect the specific activity of this enzyme, thus indicating the constitutive character of the newly formed acid phosphatase.Freeze-etching showed some rearrangement of the plasmalemma structure of yeast cells during dehydration.     

Subcellular localization of gamma-glutamyltransferase in calf thymocytes.

The subcellular localization of gamma-glutamyltransferase in calf thymocytes was investigated and compared with that of alkaline phosphodiesterase I, alkaline nitrophenyl phosphatase, succinate-tetrazolium oxidoreductase (succinate-INT reductase) and lactate dehydrogenase after two different methods of cell disruption and differential centrifugation. Most of the activity was recovered in the crude membrane fractions (43.0%), but significant amounts co-pelleted with the large-granule (mitochondria) fractions (31%). The specific activity of the gamma-glutamyltransferase in the purified plasma membrane was 30-50 times that of the enzyme in the cell homogenate and had a similar subcellular distribution to the plasma-membrane markers, alkaline phosphodiesterase I and alkaline nitrophenyl phosphatase. It was concluded that gamma-glutamyltransferase was primary a plasma-membrane-bound enzyme, and that its location in other subcellular fractions was probably due to their contamination with plasma-membrane vesicles.     

A histochemical study about changes in rat liver plasma membrane enzyme activities after galactosamine administration.

In rats changes in plasma membrane enzyme activities due to Gal-N intoxication were studied by enzymehistochemical methods. The bile canalicular 5'-nucleotidase and nucleoside polyphosphatase activities decreased; the sinusoidal 5'-nucleotidase remained unchanged. The bile canalicular leucyl-beta-naphthyl-amidase showed an increase in activity; the alkaline phosphatase activity remained unchanged. In contrast to the spotty necrosis, changes in plasma membrane enzyme activities were seen in all liver cells, suggesting that changes of these activities, occurring after Gal-N treatment, do not correlate with cell death. The conclusion was drawn that the deviations of the enzyme activities might be due to changes in the lipid environment of the enzyme proteins in the membrane. With the exception of alkaline phosphatase, partial hepatectomy caused the same changes in enzyme activities as did Gal-N intoxication. Nevertheless Gal-N administration to partial hepatectomized rats did not lead to hepatic necrosis. Galactose given simultaneously or within two hours after Gal-N prevented both changes in plasma membrane enzyme activities and hepatocellular damage. This suggests an important role of galactolipids and galactoproteins in the plasma membrane alterations.     

Studies on the alkaline phosphatase and 5'-nucleotidase of Dictyostelium discoideum.

The alkaline phosphatase and 5′-nucleotidase activities of Dictyostelium discoideum are due to two distinct enzymes. Both enzymes are membrane bound, but over 90% of the 5′-nucleotidase activity is solubilized when the crude membrane fraction of the cell is treated with phospholipase C under conditions that release only 10% of the alkaline phosphatase.Part of the alkaline phosphatase activity can be detected in whole cells, suggesting that some of the enzyme molecules are located on the exterior surface of the plasma membrane. In contrast very low 5′-nucleotidase activity can be detected in whole cells. When membrane preparations, isolated from cells that had been surface labeled with ¹²⁵I, were subjected to sedimentation equilibrium on sucrose density gradients, the majority of the ¹²⁵I-radioactivity cosedimented with the alkaline phosphatase and 5′-nucleotidase activites, suggesting that both enzymes are plasma membrane components.The two enzymes have distinctly different pH optima, but otherwise their properties are remarkably similar. Both enzymes are inhibited by cyanide, sulfhydryl inhibitors and sulfhydryl reagents, although in each case the 5′-nucleotidase is slightly more susceptible. Both enzymes are inhibited by the levamisole analogue, R 8231, but the alkaline phosphatase is inhibited to a somewhat greater extent. Both enzymes are activated by incubation at 50 °C but inactivated by higher temperatures.The two enzymes increase in activity at identical times during differentiation, suggesting that they are under coordinate developmental control.     

Presence and activity of alkaline phosphatase in two human osteosarcoma cell lines

The presence and activity of alkaline phosphatase in SAOS-2 and TE-85 human osteosarcoma cells grown in culture were examined at the ultrastructural level. A monoclonal antibody raised against purified human bone osteosarcoma alkaline phosphatase was used to localize the enzyme in cultures of the osteosarcoma cells. Similar cultures were analyzed for alkaline phosphatase activity using an enzyme cytochemical method with cerium as the capture agent. Alkaline phosphatase was immunolocalized at the light microscopic level in an osteogenic sarcoma and ultrastructurally on the SAOS-2 cell membrane and the enclosing membrane of extracellular vesicular structures close to the cells. In contrast, the TE-85 cells were characterized by the absence of all but a few traces of immunolabeling at the cell surface. Enzyme cytochemical studies revealed strong alkaline phosphatase activity on the outer surface of the SAOS-2 cell membrane. Much lower enzyme activity was observed in the TE-85 cells. The results support biochemical data from previous studies and confirm that SAOS-2 cells have a significantly greater concentration of alkaline phosphatase at the plasma membrane.     

Cytochemical and biochemical determination of acid phosphatase activity in yeasts]

Optimal conditions of the cytochemical assay for acid phosphatase in protoplasts and whole cells of S. cerevisiae have been described. Dimethyl sulfoxide was used to increase the permeability of the yeast cell envelope. In the yeast cells, grown up to the end of the exponential phase, acid phosphatase is shown to be located mainly in the central vacuole and on the cell envelope surface. A considerable activity of acid phosphatase is demonstrable on the surface of the plasma membrane and within adjacent vesicles that represent, presumably, part of the endoplasmic reticulum. Acid phosphatase can be considered as a marker enzyme for yeast cell vacuoles.     

Effect of chilling temperatures on osmotic water permeability and aquaporin activity in the plasma membranes from pea roots

The osmotic water permeability of plasma membrane vesicles was examined after isolation from the roots of 7-day-old etiolated pea ( Pisum sativum, cv. Orlovchanin) seedlings grown at optimal temperature and those exposed to 1-day chilling at 8°C in the end of the growth period. The homogenization medium for obtaining plasma membranes was supplemented with either SH-reagents or protein phosphatase inhibitors. The plasmalemma vesicles were purified from the microsome fraction by means of two-phase polymer system. The osmotic water permeability of membrane vesicles was evaluated from the rate of their osmotically induced shrinkage. The lowering of growth temperature was accompanied by the increase in osmotic water permeability of plasmalemma. These changes occurred without the corresponding increase in aquaporin content or permeability of membrane lipid matrix. The membranes from cooled seedlings were markedly depleted in the content of SH-groups. Furthermore, the treatment of membrane samples with a thiol-reducing agent, tributylphosphine did not raise the SH-group content in membranes from chilled plants, unlike such changes in membranes from warm-grown plants. When the homogenization medium contained dithiothreitol and phenylarsine oxide (an inhibitor of tyrosine protein phosphatases), the osmotic permeability of plasmalemma in preparations from warm-grown seedlings also increased. Based on these results, it is supposed that aquaporin-mediated water permeability of membranes is regulated through different pathways under optimal and adverse conditions for plant growth. Direct action of endogenous SH redox regulators on aquaporin activity is likely under optimal growth conditions, while protein phosphatase might mediate changes in aquaporin activity under unfavorable growth conditions.     

Ultrastructural localization of phosphohydrolases in gametes, zygotes and zoospores of Ulva mutabilis Foyn.

Gametes, zoospores, and zygotes of the multicellular, green alga Ulva mutabilis showed acid phosphatase reaction product in Golgi vesicles and on the membrane lining the vacuole. In addition gametes and zoospores showed enzyme reaction product on the entire surface membrane including the flagellar membrane. The surface membrane enzyme activity disappears from the zygote shortly after copulation and at the same time lysosome-like bodies start to appear in the cytoplasm. No alkaline phosphatase activity could be detected. The distribution of acid phosphatase is discussed in relation to the events taking place during and shortly after fertilization.     

pH-dependent conversion of liver-membranous alkaline phosphatase to a serum-soluble form by n-butanol extraction

Alkaline phosphatase released from rat liver plasma membrane under usual conditions was electrophoretically not identical with a soluble form in serum which was derived from the liver. The liver-membranous alkaline phosphatase, however, was converted to the serum-soluble form when the liver plasma membrane was treated with n-butanol under the acidic conditions lower than pH 6.5. Such pH-dependent conversion of the enzyme was not observed in plasma membrane of rat ascites hepatoma AH-130 cells. The converting activity for alkaline phosphatase was detected not only in plasma membrane but also in lysosomal membrane of rat liver.     

Serologic Analyses of Cell-Surface Antigens of Acanthamoeba spp. with Plasma Membrane Antisera*†

SYNOPSIS. Antisera were raised against plasma membrane-enriched fractions of the species Acanthamoeba castellanii and Acanthamoeba culbertsoni to determine whether cell-surface antigens would facilitate species identification of Acanthamoeba isolated from the environment or in human infections. Acanthamoeba castellanii and A. culbertsoni plasma membranes were purified, after homogenization, by differential and isopycnic centrifugation. Electron microscopic examination of purified membrane samples showed an enrichment of membranes with a typical trilaminar structure. Occasionally, mitochondria were recognized in the electron microscope preparations. 5′-Nucleotidase, Mg²⁺-ATPase, and alkaline phosphatase were enriched 11-fold, 2-fold, and 7-fold, respectively, in the A. castellanii membranes, as determined from analyses of the enzyme activities in whole cell homogenates and membrane preparations. 5′-Nucleotidase was not detected in A. culbertsoni, but the activities of Mg²⁺-ATPase and alkaline phosphatase were increased 2- to 3-fold. Both membrane preparations showed no glucose-6-phosphatase activity and less than 5% contamination with succinic dehydrogenase. From assays of acid phosphatase activity, the most apparent contamination of the plasma membrane preparations was with membranes of phagocytic vacuoles. Acanthamoeba castellanii membrane antisera produced significant agglutination and fluorescence of homologous cells to titers of 1:8192 and 1:1024, respectively. Acanthamoeba polyphaga and Acanthamoeba rhysodes gave the most cross-reactions in heterologous tests. They were agglutinated to a titer of 1:128 and positively fluoresced to titers of 1:32 and 1:64, respectively. Antisera of A. culbertsoni membrane agglutinated homologous cells at a dilution up to 1:4096 and produced homologous fluorescent titers up to 1:512. Other than agglutination of A. polyphaga to a titer of 1:128, these antisera did not cross-react significantly with any remaining heterologous species. Three new isolates were identified with these plasma membrane antisera: 2 of them, contaminants from tumor tissue cultures, were identified as A. culbertsoni. Preliminary information is also given on the use of the membrane antisera for species identification of Acanthamoeba in several new cases of amebic encephalitis.     

Analysis of cell-growth-phase-related variations in hyaluronate synthase activity of isolated plasma-membrane fractions of cultured human skin fibroblasts.

Hyaluronate synthase activity is localized exclusively in plasma-membrane fractions of cultured human skin fibroblasts. The enzyme activity of plasma membranes prepared from exponential-growth-phase cells was about 6.5 times that of stationary-growth-phase cells. Hyaluronate synthase from exponential-growth-phase cells exhibited lower Km and higher Vmax. values for both UDP-N-acetylglucosamine and UDP-glucuronic acid and higher rate of elongation of hyaluronate chains compared with the enzyme from stationary-growth-phase cells. Hyaluronate synthase exhibited an extremely short half-life, 2.2 h and 3.8 h respectively when cells were treated with cycloheximide and actinomycin D. The cell-growth-phase-dependent variations in hyaluronate synthase activity appear to be due to its high turnover rate as well as due to some post-translational modification of the enzyme protein as cells progress from early exponential to stationary growth phase. The isolated plasma membranes contained a protein (Mr approx. 450,000) that was selectively autophosphorylated from [gamma-32P]ATP in vitro in the presence of hyaluronate precursors in the reaction mixture and that also exhibited some hyaluronate-synthesis-related properties. The 32P-labelled protein isolated from plasma membranes of exponentially growing cells expressed an efficient UDP-[14C]glucuronic acid- and UDP-N-acetyl[3H]glucosamine-binding activity and was able to synthesize oligosaccharides (Mr 5000) of [14C]glucuronic acid and N-acetyl[3H]glucosamine residues. The corresponding protein of stationary-growth-phase cells, which expressed much higher nucleotide-sugar-precursor-binding activity, appeared to have lost its oligosaccharide-synthesizing activity.