Naphthol AS-BI (7-bromo-3-hydroxy-2-naphtho-o-anisidine) phosphatase and naphthol AS-BI beta-D-glucuronidase in Chinese hamster ovary cells: biochemical and flow cytometric studies.

Conditions for the biochemical and flow cytometric assay of 7-bromo-3-hydroxy-2-naphtho-o-anisidine phosphatase and beta-D-glucuronidase activities in Chinese hamster ovary cells were studied. In the biochemical assay, the pH optimum for the phosphatase activity was pH 4.6 with a Km of 10(-5) M; the pH optimum for beta-D-glucuronidase activity was pH 5.0 with a Km of 2 x 10(-5) M. For intact cells the derived constants were 3 to 10 times higher. The rate of hydrolysis of both substrates was also examined by flow cytometry. Cellular fluorescence increased linearly for only about 15 min. Diffusion of the fluorescent product probably caused nonlinearity of the fluorescence increase and was demonstrated by mixing cells incubated with substrate with those that had not been incubated. After 15 min, cells that had not been exposed previously to product or substrate contained the fluorescent product. Cells fractionated into size classes by centrifugal elutriation also were analyzed by flow cytometry for beta-D-glucuronidase activity. The activity increased linearly with the increase in cell size corresponding to the progression from G1 through S and into G2-M phases of the cell cycle.     

Alkaline phosphatase and an acid arylamidase as marker enzymes for normal and transformed WI-38 cells

A survey of eleven enzyme activity levels in normal and SV40 transformed (VA-13) WI-38 cells revealed that the transformed cell enzymes differed by a quantitative and qualitative change of alkaline phosphatase and a quantitative loss of an arylamidase. Alkaline phosphatase activity was found to be elevated in the transformed cells at confluency but not in log phase cultures. This elevated activity was heat stable, L-homoarginine resistant and L-phenylalanine sensitive and is probably the term placental isoenzyme. In nontransformed WI-38 cells, the alkaline phosphatase was heat labile, L-homoarginine sensitive and L-phenylalanine resistant and so is probably the liver isoenzyme. While the arylamidase activity from both normal and transformed WI-38 cells had identical pH optima and Km values, the activity was approximately 20 times higher in confluent WI-38 cells than in confluent VA-13 cells. Cytochemical staining techniques for both activities are described that permit identification of fluorescent product within the cells, analysis of activity levels, and separation of cells with high and low activities. Mixtures of WI-38 cells and VA-13 cells separated by flow cytometry on the basis of arylamidase activity were subsequently evaluated for alkaline phosphatase isoenzyme and found to have been simultaneously separated into heat labile and heat stable samples.     

Human bone cell enzyme expression and cellular heterogeneity: correlation of alkaline phosphatase enzyme activity with cell cycle

Alkaline phosphatase, long implicated in biomineralization, is a feature of the osteoblast phenotype. Yet in cultured bone cells, only a fraction stain positive histochemically. To determine whether osteoblast enzyme expression reflects cellular heterogeneity with respect to cell cycle distribution or length of time in culture, the activities of alkaline phosphatase, tartrate-resistant and -sensitive acid phosphatases, and non-specific esterases were assayed kinetically and histochemically. In asynchronous subconfluent cultures, less than 15% of the cells stained positive and assayed activity was 0.04 IU/10(6) cells/cm2. After 1 week, the percent of alkaline phosphatase positive-staining cells increased 5-fold, while activity increased 10-fold. Non-specific esterases and tartrate-sensitive acid phosphatase were constitutive throughout time in culture, whereas tartrate-resistant acid phosphatase activity appeared after 2 weeks. Cell cycle analysis of human bone cells revealed a growth fraction of 80%, an S phase of 8.5 h, G2 + 1/2 M of 4 h, and a G1 of 25-30 h. In synchronous cultures induced by a thymidine-aphidicolin protocol, alkaline phosphatase activity dropped precipitously at M phase and returned during G1. A majority of the alkaline phosphatase activity lost from the cell surface at mitosis was recovered in the medium. Tartrate-sensitive acid phosphatase and non-specific esterase levels were relatively stable throughout the cell cycle, while tartrate-resistant acid phosphatase activity was not assayable at the density used in synchronous cultures. From these data, variations in alkaline phosphatase activity appear to reflect the distribution of cells throughout the cell cycle.     

Influence of low temperature on phosphatase in roots of Verbascum thapsus,a biennial weed

The temperature peak (15 °C) of acid and alkaline phosphatase in this study coincides with a peak in alpha-amylase as seen in an earlier study of roots of Verbascum thapsus. It is speculated that one of the results of higher phosphatase activities may be increased amount of orthophosphate which can be utilized in phosphorylation of soluble carbohydrates which in turn are in greater supply due to the higher activities of the starch-degrading enzymes.A second peak in activities of acid and alkaline phosphatase was seen in plants which were returned to the greenhouse following cold treatment. This increase in enzymatic activities is also similar to increases in activities of three starch degrading enzymes studied earlier. Alkaline phosphatase showed greater activities than did acid phosphatase at lower temperatures (10 and 4 °C) and under greenhouse conditions following cold treatment.     

Interrelationship between metabolic and genetic regulation of alkaline phosphatase and poly- and pyrophosphatases]

The effects of orthophosphate and mutations in the regulatory genes of alkaline phosphatase on the activities of pyrophosphatase and polyphosphatase of E. coli were studied. It was shown that orthophosphate represses the synthesis of alkaline phosphatase as well as that of polyphosphatase without having any effect on pyrophosphatase. The genes phoR and phoS are involved in the formation of a repressory complex both for alkaline phosphatase and polyphosphatase. The gene phoT is probably involved in a partial repression of pyrophosphatase synthesis.     

Mechanism of action of Zn2+ and Mg2+ on rat placenta alkaline phosphatase. II. Studies on membrane-bound phosphatase in tissue sections and in whole placenta.

Alkaline phosphatase (EC 3.1.3.1) bound to trophoblastic cells in rat placenta is activated by Mg2+ and inhibited by Zn2+ in the same way as is found with partially purified soluble alkaline phosphatase in the same tissue (PetitClerc, C., Delisle, M., Martel, M., Fecteau, C. & Brière, N. (1975) Can. J. Biochem. 53, 1089-1100). In studies done with tissue sections (6-10 micron), it is shown that alkaline phosphatase activity and labelling of active sites by orthophosphate are lost during incubation with ethanolamine at pH 9.0. Addition of Mg2+ causes total recovery of catalytic activity and active sites labelling. Zn2+ displaces and replaces at the Mg2+ binding sites. The affinity for both ions is similar, and dissociation of Zn2+ from the enzyme is a very slow process, even in the presence of Mg2+. The Zn2+-alkaline phosphatase and Mg2+-alkaline phosphatase, which only differ by the ion bound to an apparent modulator site, have the same catalytic activity at pH less than 7.0, but the Zn2+ species has little activity at alkaline pH. Phosphorylation of the enzyme by orthophosphate indicates that with both enzyme species phosphoryl intermediate does not accumulate at alkaline pH. These results suggest that with orthophosphate, the phosphorylation step is rate determining for both enzymes, and that Zn2+ affects this step to a much greater extent. It is proposed that Zn2+ and Mg2+ regulate alkaline phosphatase in rat placenta. The concentration of both ions in maternal serum and placenta suggest that such a mechanism could exist in vivo.     

Expression of glycolytic isoenzymes in activated human peripheral lymphocytes: cell cycle analysis using flow cytometry

Human peripheral lymphocytes activated with concanavalin A and phorbol myristate ester exhibit an increase in glycolysis on a time-course similar to that for DNA synthesis. Elevated glycolysis is accompanied by increased specific activities of the glycolytic enzymes. Increased enzyme activities are accounted for by the appearance of specific isoenzyme forms (muscle forms) normally expressed in rapidly growing tumor cells or in growth-stimulated cells. In the present study we analyzed the expression of the glycolytic isoenzymes during cell cycle progression of activated human lymphocytes using two-parameter (DNA and protein) flow cytometry. Time-course studies and analysis of subpopulations prepared by elutriation centrifugation showed that the inducible isoenzymes are expressed at low levels or not at all in G0 cells. They are expressed first during the G0 to G1 transition or in early G1. However, expression increases throughout G1, reaching a maximum in S-phase. Thus, induction of glycolytic isoenzymes provides an excellent marker of T-cell activation and progression toward DNA synthesis.     

Exogenous orthophosphate regulation of ATPase activity of E. coli cells]

The effect of exogenous orthophosphate and mutations in genes, regulating the Pi transport system, on the ATPase activity of E. coli subcellular fractions was studied. It was shown that the orthophosphate starvation resulted in the cessation of the increase in the ATPase activity of membranes and was accompanied by the increase in the analogous activity of a soluble fraction at the expense of the derepression of alkaline phosphatase possessing this activity. The disturbance, resulted from the mutation of protein components participating in the specific binding and transport of orthophosphate, changed the ATPase activity of subcellular fractions: increased the ATPase activity of soluble fraction (independently of the presence of orthophosphate in medium), did not affect significantly the activity of membrane--bound ATPase in the presence of orthophosphate and decreased this activity in the absence of orthophosphate. The data obtained point to the fact that components, binding exogenous orthophosphate and transporting it into a cell, affect the rigidity of the ATPase bound E. coli cytoplasmic membrane. Mutations resulting in the defect in these components relax this bound and lead to the detection of ATPase proper in the periplasm.     

Metabolic and genetic control of isoenzyme spectrum of alkaline phosphatase inEscherichia coli

Three proteins possessing alkaline phosphatase activity were detected in a fraction of periplasmic material ofEscherichia coli K-10 and its mutants with constitutive synthesis of alkaline phosphatase. They also showed acid phosphatase, pyrophosphatase and ATPase activities. Through the use of phosphatase-negative mutants it was shown that these proteins were the products of a single structural gene and therefore represented alkaline phosphatase isozymes. The numbers of enzyme isoforms and possibly the spectrum of their phosphohydrolase activities were controlled by exogenous orthophosphate and depended on the integrity of regulator genes for alkaline phosphatase.     

Cell cycle analysis of synchronized chinese hamster cells using bromodeoxyuridine labeling and flow cytometry

Summary Chinese hamster ovary cells were synchronized into purified populations of viable G1-, S-, G2-, and M-phase cells by a combination of methods, including growth arrest, aphidicolin block, cell cycle progression, mitotic shake-off, and centrifugal elutriation. The DNA content and bromodeoxyuridine (BrdUrd) labeling index were measured in each purified fraction by dual-parameter flow cytometry. The cell cycle distributions determined from the DNA measurements alone (single parameter) were compared with those calculated from both DNA and BrdUrd data (dual parameter). The results show that highly purified cells can be obtained using these methods, but the assessed purity depends on the method of cell cycle analysis. Using the single versus dual parameter measurement to determine cell cycle distributions gave similar results for most phases of the cell cycle, except for cells near the transition from G1- to S-phase and S- to G2-phase. There the BrdUrd labeling index determined by flow cytometry was more sensitive for detecting small amounts of DNA synthesis. As an alternative to flow cytometry, a simple method of measuring BrdUrd labeling index on cell smears was used and gave the same result as flow cytometry. Measuring both DNA content and DNA synthesis improves characterization of synchronized cell populations, especially at the transitions in and out of S-phase, when cells are undergoing dramatic shifts in biochemical activity.     

Thymidine as synchronizing agent. 3. Persistence of cell cycle patterns of phosphatase activities and elevation of nuclease activity during inhibition of DNA synthesis

Synchronous cultures of HeLa cells were obtained by selective detachment of cells in mitosis and fluctuations in enzyme activity were followed during the subsequent cell cycle. The enzymes measured were alkaline and acid phosphatases and a nuclease active on denatured DNA at alkaline pH (alkaline DNase). Each of these enzymes showed a different pattern of activity in the cell cycle, but a temporal relationship to the DNA synthetic phase was apparent in each case. Treatment of the cultures at the beginning of the cell cycle with 15 mM thymidine did not alter the subsequent pattern of fluctuations in activity of alkaline phosphatase or of acid phosphatase, although DNA synthesis was fully inhibited by this treatment. This indicates that the pattern of activity of some enzymes is not linked to DNA replication. On the other hand, the pattern of fluctuations in the activity of alkaline DNase was abolished by thymidine treatment, and elevation of the activity of this enzyme was observed. These results suggest complex and variable relationships between phases of the cell cycle and enzyme activity, and show that inhibition of DNA synthesis is not a suitable procedure for induction of culture synchrony if enzyme activities are to be studied.     

Site-specific inactivation of phosphatases by ferrate lon.

Ferrate ion, FeO₄^2?, an analog of orthophosphate ion, PO₄^3?, has been found to be a potent inactivator of phosphatase. All phosphatases tested, including acid and alkaline nonspecific monoesterases as well as some specific monoesterases and a diesterase, were inactivated by treatment with ferrate. Inactivation, which occurs rapidly and irreversibly, can be demonstrated with concentrations of ferrate ion of 1 to 10 μm. Protection against ferrate inactivation was afforded by phosphate and by specific competitive inhibitors. It is therefore postulated that ferrate ion interacts on a phosphate binding site in the inactivation of phosphatases. Phosphoglucomutase and alcohol dehydrogenase were inactivated by ferrate ion while several enzymes which do not utilize phosphate-containing substrates were unaffected.     

Lipid catabolism of cultivated treponemes

Treponema require long-chain fatty acids for growth in vitro. Serum, added to culture media, provides a source of long-chain fatty acids. These fatty acids, however, are esterified to triglycerides, phospholipids, and cholesterol. In this study, the major pathways of complex lipid catabolism in T. phagedenis, T. denticola, T. refringens, T. minutum, and T. vincentii were investigated. Lipase activity was demonstrated in five Treponema species using four lipid substrates. Chromatographic data demonstrated that, during growth, treponemes completely utilized lysophosphatidylcholine, present in serum-supplemented culture media, while phosphatidylcholine and phosphatidylinositol were not utilized. Phospholipase B and glycerophosphorylcholine diesterase activities were demonstrated in the five species of Treponema studied. Treponema phagedenis and T. denticola had phosphatase activity, while T. refringens, T. minutum, and T. vincentii did not have an acid phosphatase activity. Phospholipase A, C, and D and alkaline phosphatase activities were not found in five species of Treponema. Based on the enzymes demonstrated in this study, two pathways of phospholipid catabolism are proposed.     

Alkaline phosphatase activity of normal and transformed cultured human cells

A study was made of the relationship between the activity of alkaline phosphatase and the proliferation of cultured human cells with different replicative potentials. It is shown that alkaline phosphatase plays a role as one of endogenic stimulators of cellular proliferation. The ageing of diploid cells is accompanied by a decrease in the enzyme activity. Maximum activity was observed during a period of logarithmic cell growth. Addition of placental alkaline phosphatase to the synchronized diploid cells stimulated DNA synthesis in the S-phase of the cell cycle. Heteroploid cells with a high growth rate possessed a 30-100 times higher alkaline phosphatase activity than in the diploid cells. Under certain conditions alkaline phosphatase may presumably function as a proteinkinase.     

Multiple DNA repair activities for 3''-deoxyribose fragments in Escherichia coli.

Escherichia coli contains multiple enzymes that hydrolyze deoxyribose fragments (phosphoglycolaldehyde, PGA) from the 3' termini of a synthetic DNA substrate. The major such activities are the main bacterial apurinic endonucleases, exonuclease III and endonuclease IV. In a double mutant deficient in both of these oxidation repair enzymes, Mg++-dependent 3'-PGA diesterase was detected at 3% the level found in wild-type bacteria. Gel filtration fractionated this residual diesterase activity into two peaks of Mr 40,000-52,000 (Pool A) and Mr 22,000-30,000 (Pool B) with differing abilities to remove 3'-phosphates from DNA. These multiple repair activities were resolved in 3'-PGA diesterase activity gels. The exonuclease III and endonuclease IV bands were identified using the purified proteins and by their specific absence from strains defective for the respective structural genes. Gel filtration Pool B yielded two activity bands of apparent Mr 25,000 and 28,000, but Pool A did not form a new band in the activity gels. Incubation of activity gels in different transition metals or boiling of the samples before electrophoresis also served to distinguish the various activities. The possible identities of the novel E. coli 3'-PGA diesterases and the importance of multiple repair enzymes for 3' damages are discussed.     

Comparative analysis on the key enzymes of the glycerol cycle metabolic pathway in Dunaliella salina under osmotic stresses

The glycerol metabolic pathway is a special cycle way; glycerol-3-phosphate dehydrogenase (G3pdh), glycerol-3-phosphate phosphatase (G3pp), dihydroxyacetone reductase (Dhar), and dihydroxyacetone kinase (Dhak) are the key enzymes around the pathway. Glycerol is an important osmolyte for Dunaliella salina to resist osmotic stress. In this study, comparative activities of the four enzymes in D. salina and their activity changes under various salt stresses were investigated, from which glycerol metabolic flow direction in the glycerol metabolic pathway was estimated. Results showed that the salinity changes had different effects on the enzymes activities. NaCl could stimulate the activities of all the four enzymes in various degrees when D. salina was grown under continuous salt stress. When treated by hyperosmotic or hypoosmotic shock, only the activity of G3pdh in D. salina was significantly stimulated. It was speculated that, under osmotic stresses, the emergency response of the cycle pathway in D. salina was driven by G3pdh via its response to the osmotic stress. Subsequently, with the changes of salinity, other three enzymes started to respond to osmotic stress. Dhar played a role of balancing the cycle metabolic pathway by its forward and backward reactions. Through synergy, the four enzymes worked together for the effective flow of the cycle metabolic pathways to maintain the glycerol requirements of cells in order to adapt to osmotic stress environments.     

Soluble and membrane-bound polyphosphoinositide phosphohydrolases in mammalian erythrocytes

Phosphatases and phosphodiesterases that hydrolyse polyphosphoinositides are described in both membrane and cytosol fractions of human, pig, rat, rabbit, and sheep erythrocytes using exogenous substrates. With suitably optimized assay conditions, Ca2+-dependent phosphatidylinositol bisphosphate (PIP2) phosphodiesterase activity was found in the hemoglobin-free cytosol fraction, as well as the membrane. Membrane activity is completely dependent upon Triton X-100 and salt and inhibited by cetyltrimethylammonium bromide (CTAB), while the soluble activity requires CTAB and is inhibited by Triton. A low Ca2+-dependent PIP2 phosphatase activity, not present in other tissues, was also detected. The cation-independent phosphatidylinositol phosphate (PIP) phosphatase is localized in the membrane in most species, while the diesterase and the PIP2 phosphatases (both Mg2+ and Ca2+ dependent) are localized in the cytosol. Rat and rabbit erythrocytes are atypical in having a substantial proportion of their Mg2+-dependent PIP2 phosphatase activities in the membrane. All activities are lowest in sheep erythrocytes, except the PIP phosphatase, most of which is soluble in this species. Ca2+-dependent PIP2 phosphatase activity is not correlated with the activity or subcellular distribution of any of the other hydrolases and seems to be a separate enzyme. All the phosphoinositide hydrolase activities, particularly the diesterase, are orders of magnitude lower in erythrocytes than in other tissues. Both soluble and membrane diesterase activities are lost as erythrocytes age. Soluble polyphosphoinositide diesterase does not seem to be active with membrane-bound substrate, since pig and sheep erythrocytes that have negligible membrane activity do not respond to Ca2+ loading, yet have substantial diesterase activity in the cytosol. This supports the view that the diesterase is not physiologically functional in normal erythrocytes.     

环境因子对日本沼虾消化酶和碱性磷酸酶的影响

研究了水环境中不同Ca2 + 浓度 (2 0、35、6 0、80和 15 0mg·L-1)、盐度 (7、14和 2 0‰ )和 pH(7 6、8 8和 9 8)对日本沼虾 (Macrobrachiumnipponense)肝胰腺中消化酶 (胃蛋白酶和类胰蛋白酶 )和碱性磷酸酶的影响 .结果表明 ,Ca2 + 对日本沼虾的胃蛋白酶有促进作用 ,Ca2 + 浓度为 15 0mg·L-1时酶活力最高 ;高浓度的Ca2 + 对类胰蛋白酶有抑制作用 ,而在一定范围内 ,碱性磷酸酶活力随Ca2 + 浓度的增高而增高 .盐度为 14‰时 ,日本沼虾的胃蛋白酶、类胰蛋白酶和碱性磷酸酶活力均高于 7‰和 2 0‰组 .随着 pH值升高 ,蜕皮率和 3种酶活力也随之增高 ,pH9 8时均达到最高值 ,但增长率和增重率则降低 .     

Extracellular matrix components and proteolytic enzymes in uterine cervical carcinoma

The important components of mucopolysaccharides and collagen have been analyzed in tissues of control and carcinoma of uterine cervix. Among these components hyaluronic acid and chondroitin sulphate levels were found to be increased, whereas decreased level of collagen was observed in uterine cervical carcinoma. Serum cathepsin B, D and acid and alkaline phosphatases have also been analyzed in controls and carcinoma patients before and after treatments. The activities of these enzymes have been found to increase prominently in advanced stages. Among these enzymes cathepsin B and alkaline phosphatase have exhibited remarkable increase in activity in uterine cervical carcinoma. Different modes of treatment exerted reversion of the elevated activities of these enzymes. However, combined therapy type II (radiation combined with cisplatin and cyclophosphomide) seems to be more effective in reverting the activities of these enzymes to normal levels.