Francisella DnaK Inhibits Tissue-nonspecific Alkaline Phosphatase

Following pulmonary infection with Francisella tularensis, we observed an unexpected but significant reduction of alkaline phosphatase, an enzyme normally up-regulated following inflammation. However, no reduction was observed in mice infected with a closely related Gram-negative pneumonic organism (Klebsiella pneumoniae) suggesting the inhibition may be Francisella-specific. In similar fashion to in vivo observations, addition of Francisella lysate to exogenous alkaline phosphatase (tissue-nonspecific isozyme) was inhibitory. Partial purification and subsequent proteomic analysis indicated the inhibitory factor to be the heat shock protein DnaK. Incubation with increasing amounts of anti-DnaK antibody reduced the inhibitory effect in a dose-dependent manner. Furthermore, DnaK contains an adenosine triphosphate binding domain at its N terminus, and addition of adenosine triphosphate enhances dissociation of DnaK with its target protein, e.g. alkaline phosphatase. Addition of adenosine triphosphate resulted in decreased DnaK co-immunoprecipitated with alkaline phosphatase as well as reduction of Francisella-mediated alkaline phosphatase inhibition further supporting the binding of Francisella DnaK to alkaline phosphatase. Release of DnaK via secretion and/or bacterial cell lysis into the extracellular milieu and inhibition of plasma alkaline phosphatase could promote an orchestrated, inflammatory response advantageous to Francisella.     

Characterization of two Pseudomonas aeruginosa mutants with defective secretion of extracellular proteins and comparison with other mutants

We have isolated 2 new pleiotropic mutants of Pseudomonas aeruginosa strain PAO with defective secretion of extracellular proteins (Xcp mutants). One of these mutants was compared to 2 different, previously isolated secretion mutants. All had similar phenotypes and were unable to release at least 4 exoproteins (lipase, elastase, alkaline phosphatase, and phospholipase C), whilst alkaline protease was still secreted. The exoproteins appeared to be blocked in the periplasmic space. No difference in molecular weight was detected between cell-bound forms of elastase and alkaline phosphatase in the different mutants and the corresponding extracellular forms from the wild-type strain. Genetic mapping showed that the mutations were located in the 55′ region of the chromosome.     

Spatial Patterns of Alkaline Phosphatase Expression within Bacterial Colonies and Biofilms in Response to Phosphate Starvation

The expression of alkaline phosphatase in response to phosphate starvation was shown to be spatially and temporally heterogeneous in bacterial biofilms and colonies. A commercial alkaline phosphatase substrate that generates a fluorescent, insoluble product was used in conjunction with frozen sectioning techniques to visualize spatial patterns of enzyme expression in both Klebsiella pneumoniae and Pseudomonas aeruginosa biofilms. Some of the expression patterns observed revealed alkaline phosphatase activity at the boundary of the biofilm opposite the place where the staining substrate was delivered, indicating that the enzyme substrate penetrated the biofilm fully. Alkaline phosphatase accumulated linearly with time in K. pneumoniae colonies transferred from high-phosphate medium to low-phosphate medium up to specific activities of 50 μmol per min per mg of protein after 24 h. In K. pneumoniae biofilms and colonies, alkaline phosphatase was initially expressed in the region of the biofilm immediately adjacent to the carbon and energy source (glucose). In time, the region of alkaline phosphatase expression expanded inward until it spanned most, but not all, of the biofilm or colony depth. In contrast, expression of alkaline phosphatase in P. aeruginosa biofilms occurred in a thin, sharply delineated band at the biofilm-bulk fluid interface. In this case, the band of activity never occupied more than approximately one-sixth of the biofilm. These results are consistent with the working hypothesis that alkaline phosphatase expression patterns are primarily controlled by the local availability of either the carbon and energy source or the electron acceptor.     

Analysis of the regulation of Escherichia coli alkaline phosphatase synthesis using deletions and φ80 transducing phages

φ80 transducing phages for the proC², phoA and phoB genes of Escherichia coli have been obtained. Two mutants have been isolated, in which the brnQ, phoA, proC, phoB (and possibly phoR) genes have been deleted. Derivatives of a phoA, phoB deletion strain which are lysogenic for a φ80phoA transducing phage make only very low levels of alkaline phosphatase activity. These results are in agreement with a positive control mechanism for the regulation of alkaline phosphatase synthesis.     

Production of phosphatates by fungi isolated from desert soils

Twelve fungal cultures isolated from Indian desert soils belonging toAspergillus, Penicillium, Acrophialophora andAlternaria were found to produce both acid and alkaline phosphatases in liquid medium, their amounts varying from culture to culture. Maximum production of these enzymes was observed withA. niger. In general, acid phosphatase activity was much higher as compared to alkaline phosphatase. The optimum incubation period for the production of these enzymes was found to be 14 d and thereafter it started declining. There was a significant and positive correlation between biomass production and acid phosphatase activity but not with alkaline phosphatase.     

Co-Regulation in Escherichia coli of a Novel Transport System for sn-Glycerol-3-Phosphate and Outer Membrane Protein Ic (e, E) with Alkaline Phosphatase and Phosphate-Binding Protein

Mutants constitutive for the novel outer membrane protein Ic (e or E) contained a recently discovered binding protein for sn-glycerol-3-phosphate. The corresponding parental strains missing the outer membrane protein Ic (e, E) were negative or strongly reduced in the synthesis of the binding protein. In addition, strains that were previously isolated as mutants constitutive for the sn-glycerol-3-phosphate transport system (ugp⁺ mutants) and that produced the novel periplasmic proteins GP1 to GP4 also synthesized a new outer membrane protein with the same electrophoretic mobility on sodium dodecyl sulfate-polyacrylamide gels as protein Ic. Screening of different ugp⁺ mutants revealed the existence of three types in respect to the four novel periplasmic proteins GP1, -2, -3, and -4: (i) one containing all four proteins; (ii) one containing only proteins GP1, -2, and -3; (iii) one containing only proteins GP1, -2, and -4. In confirmation of the data presented in the accompanying paper by Tommassen and Lugtenberg (J. Bacteriol. 143:151–157, 1980), we found that purified GP1 is identical to alkaline phosphatase, whereas purified GP3 has binding activity of inorganic phosphate and is identical to the phosphate-binding protein. Moreover, growth conditions that lead in a wild-type strain to the derepression of alkaline phosphatase synthesis also derepressed the synthesis of the sn-glycerol-3-phosphate-binding protein as well as the corresponding transport system. Thus, the new sn-glycerol-3-phosphate transport system is part of the alkaline phosphatase regulatory system.     

Kinetic properties, and location of nonspecific phosphomonoesterases in subcellular fractions of fasciola hepatica

Optimal activity was recorded at pH 4.5–5 and pH 9.0–9.5 and specific activity was seen to be 0.013 μmoles of p-nitrophenyl phosphate/min/mg protein at 37 C at pH 4.5 and 0.00169 μmoles at pH 9.0. The ratio of acid to alkaline phosphatase was 7.7:1.0. The K_m for acid phosphatase (EC 3.1.3.2) was 0.5 mM with a V_max of 0.0128 units/mg protein and 0.2mM for alkaline phosphatase (EC 3.1.3.1) with a V_max of 0.00175 units/mg protein. Acid phosphatase activity was optimal at 60 C and alkaline at 37 C. Linearity of enzyme activity was observed with time after the first 15 min of incubation and with homogenate concentration. KCN at 20 mM inhibited 82% of activity at pH 9.0 but also 91.5% activity at pH 4.5. NaF at 10^?2M inhibited 92% of activity at pH 4.5 but had no effect at pH 9.0. The two flukicides rafoxanide and nitroxynil at 20mM had little effect on activity at pH 9.0 and pH 4.5. Enzyme activity at pH 4.5 was found to be greatest in the microsomal fraction with high activity in the lysosomal and soluble fractions. Histochemically, alkaline phosphatase was restricted to the excretory system, vitellaria, and uterus while acid phosphatase was found in the integument and gastrodermis.     

In Vivo Insertional Mutagenesis in Corynebacterium pseudotuberculosis: an Efficient Means To Identify DNA Sequences Encoding Exported Proteins

The reporter transposon-based system TnFuZ was used to identify exported proteins of the animal pathogen Corynebacterium pseudotuberculosis. Thirty-four out of 1,500 mutants had detectable alkaline phosphatase (PhoZ) activity. This activity was from 21 C. pseudotuberculosis loci that code for fimbrial and transport subunits and for hypothetical and unknown-function proteins.     

Effect of mutations in global regulator genes <Emphasis Type="Italic">grrS</Emphasis> and <Emphasis Type="Italic">rpoS</Emphasis> on synthesis of phosphatases in <Emphasis Type="Italic">Serratia plymuthica</Emphasis>

The participation of global regulators GrrS (sensor kinase GacA/GacS-like regulatory system) and sigma S subunit of RNA polymerase in the control of phosphatase synthesis in a soil bacterium Serratia plymuthica was shown. In cells of null mutants for genes grrS and rpoS synthesis of acid and alkaline phosphatases was markedly decreased.     

Mutants Affected in Alkaline Phosphatase Expression: Evidence for Multiple Positive Regulators of the Phosphate Regulon in ESCHERICHIA COLI

The expression of alkaline phosphatase (the product of the phoA gene) in Escherichia coli is believed to be subject to both positive control by the phoB gene product and negative control by the phoR gene product. We have isolated a large number of PhoA^- mutants in the phoR^- genetic background. Among mutants altered in the positive control of alkaline phosphatase, some were phoB mutants; others had a mutation in a new gene, designated phoM. We believe that the phoM gene codes for a positive regulator that acts together with the phoB gene product in phoA gene expressions.—The PhoM phenotype was found to be masked in phoR⁺ strains. This and other evidence support a positive regulatory role for the phoR gene product as well.—Our experiments demonstrate that phoA is under positive control by three different positive regulators: the products of the phoB, phoM and phoR genes. The phoB gene product is always needed together with either the phoR or phoM gene product. In addition, the phoR gene product acts as a negative regulator.—We describe a model for phoA gene expression consistent with this new evidence.     

Boophilus microplus: characterization of larval phosphomonoesterases and isolation of subcellular fractions with high phosphatase activity.

Phosphomonoesterase activity was determined for a 115,000g pellet and soluble fractions resulting from a subcellular fractioning of a homogenate of larval Boophilus microplus. Both fractions showed maximum phosphatase activity at pH 5.5 and 10. Acid phosphatase (EC 3.1.3.2) activity was found to be greatest in the soluble fraction. When the reaction rate was plotted against homogenate concentration, the soluble acid phosphatase deviated from the linear relationship. For both fractions different thermostability patterns were obtained, inactlvation beginning for the alkaline phosphatase (EC 3.1.3.1) at 45–55 C. When the effect of substrate concentration on activity was studied, deviations from the typical hyperbolic behavior were observed. Homogenization of larvae with 5 mm EDTA buffer failed to yield a low-speed pellet with high alkaline phosphatase activity, as it is expected if absorptive structures sediment. Moreover, total alkaline phosphatase activity recovered by this method is significantly lower than activity recovered when homogenization is carried out without EDTA. Alternately, homogenization with 10 mM Tris buffer and 0.25 M sucrose gave 27,000g and 115,000g fractions with high phosphatase activity when fractioned by centrifugation. Alkaline treatment of the 115,000g fraction with 10 mM Tris buffer, pH 7.8, failed to separate endoplasmic reticulum contaminants without loss of phosphatase activity. When the 115,000g fraction was centrifuged in a sucrose density gradient, two activity peaks, coincident for both acid and alkaline phosphatases, were obtained. Antigenic analysis showed the existence of similar antigenic determinants in both peaks “immunologically” presented in different ways.     

The extended N-terminal region of SphS is required for detection of external phosphate levels in Synechocystis sp. PCC 6803

A novel 47 amino acid extension at the N-terminus of the SphS histidine kinase has been identified in the cyanobacterium Synechocystis sp. PCC 6803. Here, we demonstrate this region is required for activation of the SphS-SphR phosphate-sensing two-component system under phosphate-limiting conditions and mutants lacking this extension do not show constitutive alkaline phosphatase activity when the negative regulator SphU is inactivated. We have also identified a putative membrane-associated domain within this region involved in control of the Pho regulon. In addition, there are two high-affinity ABC-type phosphate uptake systems in this organism. Our results demonstrate that the Pst1 system, but not the Pst2 system, is required for suppression of the Pho regulon under phosphate-sufficient conditions. Deletion of the pst1 operon and disruption of the membrane-spanning domain may both target the same control mechanism since constitutive alkaline phosphatase activity is similar in the double and single mutants.     

Escherichia coli alkaline phosphatase. Kinetic studies with the tetrameric enzyme

1. The stability of the tetrameric form of Escherichia coli alkaline phosphatase was examined by analytical ultracentrifugation. 2. The stopped-flow technique was used to study the hydrolysis of nitrophenyl phosphates by the alkaline phosphatase tetramer at pH7.5 and 8.3. In both cases transient product formation was observed before the steady state was attained. Both transients consisted of the liberation of 1mol of nitrophenol/2mol of enzyme subunits within the dead-time of the apparatus. The steady-state rates were identical with those observed with the dimer under the same conditions. 3. The binding of 2-hydroxy-5-nitrobenzyl phosphonate to the alkaline phosphatase tetramer was studied by the temperature-jump technique. The self-association of two dimers to form the tetramer is linked to a conformation change within the dimer. This accounts for the differences between the transient phases in the reactions of the dimer and the tetramer with substrate. 4. Addition of P_i to the alkaline phosphatase tetramer caused it to dissociate into dimers. The tetramer is unable to bind this ligand. It is suggested that the tetramer undergoes a compulsory dissociation before the completion of its first turnover with substrate. 5. On the basis of these findings a mechanism is proposed for the involvement of the alkaline phosphatase tetramer in the physiology of E. coli.     

Production of extracellular alkaline phosphatase by Escherichia coli K-12 periplasmic-leaky mutants carrying phoA + Plasmids

Summary Col E1 hybrid plasmids carrying the phoA ⁺ structural gene of alkaline phosphatase, a periplasmic enzyme of Escherichia coli K-12, were identified from the Clarke and Carbon genomic bank. Wild-type (lky ⁺) phoA ⁺ plasmid-bearing strains synthesized 14 times more intracellular enzyme than the haploid lky ⁺ strain. Phosphate-induced repression was maintained in transformed strains. PhoA ⁺ plasmids carrying the phoB and phoR regulatory genes were introduced into a periplasmic-leaky (lky) recipient strain able to release alkaline phosphatase into the extracellular medium. Transformed lky mutants excreted up to 90% of total enzyme activity which corresponded to 3.5 times the amount of intracellular alkaline phosphatase made by the haploid lky ⁺ strain. The protein composition analysis of periplasmic and extracellular fractions showed that: (i) wild-type phoA ⁺ hybrid plasmidbearing clones did not excrete alkaline phosphatase but had a modified periplasmic content; (ii) alkaline phosphatase was the major excreted protein by transformed lky mutants. The use of periplasmic-leaky phoA ⁺ hybrid plasmid-bearing mutants for an easier production and purification of alkaline phosphatase is discussed.     

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.     

Salinity-sensitive alkaline phosphatase activity in gills of the blue crab,Callinectes sapidus Rathbun

A levamisole-sensitive (K_i = 0.72 mM) alkaline phosphatase (pH optimum 9.1) and a levamisole-insensitive alkaline phosphatase (pH optimum 7.1) are present in gills of the blue crab Callinectes sapidus. Both enzymes are distinct from ouabain-sensitive ATPase. Specific activity for either phosphatase is greatest in the acinar tissue, which lines the branchial vessels. Histochemical localization of the enzymes confirmed this distribution. Activity of levamisole-sensitive alkaline phosphatase is affected by acclimation salinity. V_max of the levamisole-sensitive alkaline phosphatase is greater in high-salinity crabs than in low-salinity crabs; apparent K_m is not significantly different. The levamisole-sensitive alkaline phosphatase associated with the acinar tissue lining the branchial vessels may modulate the osmoregulatory response in blue crabs.     

Histochemical localization of acid and alkaline phosphatases and glucose-6-phosphatase of the hepatopancreas of the crab, Scylla serrata (Forskål)

Simultaneous histochemical localization of non-specific monophosphate esterases, acid and alkaline phosphatases, as well as a specific monophosphate esterase, glucose-6-phosphatase has been made on the hepatopancreas of the marine crab, Scylla serrata (Forskål). Maximum activity of the 3 enzymes was observed in the juvenile and mature absorptive cells. Lining cells of the main hepatopancreatic duct exhibited a moderate activity of the 3 enzymes whereas the embryonic and fibrillar cells and connective tissue of the gland showed negative reactions for the 3 enzymes. The secretory cells showed a positive reaction for these enzymes only at the brush border.Bilateral eyestalk removed evoked a rise in the activity of the 3 enzymes within 2–4 h. The same effect was observed after injection of eyestalk extract to both normal and eyestalkless animals followed by restoration to the normal level after 24 h.The present observations indicate that glucose-6-phosphatase and acid phosphatase may be under the direct influence of eyestalk hormone(s) while alkaline phosphatase activity appears to be related to changes in the substrate. The physiological significance of the various cell types and enzymes is discussed.     

Co-purification of type I alkaline phosphatase and type I phosphoprotein phosphatase from various animal tissues

A purification procedure, which included ethanol treatment as a step for dissociating the large molecular forms of type I phosphoprotein phosphatase, was employed for the studies of the alkaline phosphatase and phosphoprotein phosphatase activities in bovine brain, heart, spleen, kidney, and uterus, rabbit skeletal muscle and liver, and lobster tail muscle. The results indicate that the major phosphoprotein phosphatase (phosphorylase a as a substrate) and alkaline phosphatase (p-nitrophenyl phosphate as a substrate; Mg²⁺ and dithiothreitol as activators) activities in the extracts of all tissues studied were copurified as an entity of M_r = 35,000. The purified enzymes from different tissues exhibit similar physical and catalytic properties with respect to either the phosphoprotein phosphatase or the alkaline phosphatase activity. The present findings indicate that (a) the M_r = 35,000 species, which represents a catalytic entity of the large molecular forms of type I phosphoprotein phosphatase, is widespread in animal tissues, indicating that it is a multifunctional phosphatase; (b) the association of type I alkaline phosphatase activity with type I phosphoprotein phosphatase is a general phenomenon.     

Dynamics of water-extractable phosphorus during the degradation of Microcystis aeruginosa by four bacteria species

We carried out a laboratory experiment for studying the dynamics of water-extractable phosphorus release during the decomposition of dead Microcystis aeruginosa driven by the four bacteria strains. Our results showed that water-extractable phosphorus had significant correlation to alkaline phosphatase but without obvious correlation to acid phosphatase, suggesting that alkaline phosphatase was the primary enzyme decomposing organic phosphorus. Also, water-extractable phosphorus exhibited an obvious correlation to pH, indicating that the alkaline environment contributed to the release of water-extractable phosphorus. The quantity of bacteria hardly correlated to the release of water-extractable phosphorus for all species. This could result from decrease of bacterial quantity after consumption of substrate in closed system. Obvious variation in water-extractable phosphorus was observed across the strains in two water treatments. Sporolactobacillus sp. and Bacillus macerans had the strongest ability for decomposing organic phosphorus among five strain treatments in the lake water. In the distilled water, Bacillus sp. had the strongest ability to degrade organic phosphorus. In both water treatments, mixed species exhibited intermediate ability for decomposing organic phosphorus. It was true that water quality strongly affected the release of phosphorus by regulating phosphatase activity.