Alkaline Optimum Research Articles

Global analysis of soil bacterial genera and diversity in response to pH

Soil pH stands as a decisive factor in shaping bacterial diversity and community composition, yet predicting the pH preferences and traits of individual bacterial taxa is still incomplete. We surveyed 942 samples from seven biomes worldwide to unravel the responses of individual bacterial genus to soil pH. Our findings indicate that soil pH surpasses the influences of spatial and climatic factors (biomes) in affecting bacterial composition and diversity. We observed that a comparable proportion of genera had low pH optima (21%), high pH optima (18%), and neutral pH optima (18%). However, apart from genera with optima groups, only a small percentage of genera were low pH tolerant (0.8%) compared to those that were high pH tolerant (21%). This suggests that a greater number of non-extremophiles genera can tolerate alkaline conditions compared to acidic conditions. Bacterial richness forms unimodal relationship with soil pH, consistently increasing from acidic levels to neutral across all biomes. However, the decline in richness when pH rises beyond neutral was less pronounced. This can be attributed to the higher number of alkaline-tolerant genera compared to acidic-tolerant genera. As expected, genera with acidic optima are more prevalent in humid climates, such as tropical forests, arctic tundra, and boreal forests, whereas genera with alkaline optima are generally dominant in arid grasslands and drylands. Collectively, our results indicate that the probability of existence of at least 75% of genera in specific soil pH conditions can be predicted, irrespective of biome. The identification of the actual niche spaces occupied by individual soil bacterial genera forms the foundation for developing comprehensive hypotheses regarding the response of soil communities to changing soil conditions worldwide.

Antimicrobial Peptides with pH-Dependent Activity and Alkaline Optima: Their Origins, Mechanisms of Action and Potential Applications.

A number of disorders and diseases are associated with conditions of high pH, and many conventional antibiotics lose their efficacy under these pH conditions, generating a need for novel antimicrobials. A potential solution to fulfill this need is Antimicrobial Peptides (AMPs) with high pH optima. This review shows that a variety of anionic and cationic AMPs with this pH dependency are produced by creatures across the eukaryotic kingdom, including rabbits, cattle, sheep, fish, crabs and frog. These AMPs exhibit activity against viruses, bacteria, and fungi that involve membrane interactions and appear to be facilitated by a variety of mechanisms that generally promote passage across membranes to attack intracellular targets, such as DNA or protein synthesisand/or membrane lysis. Some of these mechanisms are unknown, but those elucidated include the use of bacterial pores and transporters, the self-promoted uptake pathway, and established models of membrane interaction, such as the carpet mechanism, toroidal pore formation, the adoption of tilted peptide, and the SHM model. A variety of potential roles have been proposed for these AMPs, including use as antivirals, antibacterials, antifungals, adjuvants to antimicrobial therapy, biomarkers of disease, and probes for pathogenic microbes. In this review, these properties are described and discussed, emphasizing the antimicrobial mechanisms used by these AMPs and the pH dependency of these mechanisms.

Linearized esculentin-2EM shows pH dependent antibacterial activity with an alkaline optimum

Here the hypothesis that linearized esculentin 2EM (E2EM-lin) from Glandirana emeljanovi possesses pH dependent activity is investigated. The peptide showed weak activity against Gram-negative bacteria (MLCs ≥ 75.0 μM) but potent efficacy towards Gram-positive bacteria (MLCs ≤ 6.25 μM). E2EM-lin adopted an α-helical structure in the presence of bacterial membranes that increased as pH was increased from 6 to 8 (↑ 15.5–26.9%), whilst similar increases in pH enhanced the ability of the peptide to penetrate (↑ 2.3–5.1 mN m−1) and lyse (↑ 15.1–32.5%) these membranes. Theoretical analysis predicted that this membranolytic mechanism involved a tilted segment, that increased along the α-helical long axis of E2EM-lin (1–23) in the N → C direction, with − < µH > increasing overall from circa − 0.8 to − 0.3. In combination, these data showed that E2EM-lin killed bacteria via novel mechanisms that were enhanced by alkaline conditions and involved the formation of tilted and membranolytic, α-helical structure. The preference of E2EM-lin for Gram-positive bacteria over Gram-negative organisms was primarily driven by the superior ability of phosphatidylglycerol to induce α-helical structure in the peptide as compared to phosphatidylethanolamine. These data were used to generate a novel pore-forming model for the membranolytic activity of E2EM-lin, which would appear to be the first, major reported instance of pH dependent AMPs with alkaline optima using tilted structure to drive a pore-forming process. It is proposed that E2EM-lin has the potential for development to serve purposes ranging from therapeutic usage, such as chronic wound disinfection, to food preservation by killing food spoilage organisms.

Unique properties of arginase purified from camel liver cytosol

Arginase (ARG) is an enzyme involved in urea cycle, where it catalyzes the hydrolysis of L-arginine into L-ornithine and urea. Since there is no information about the isolation and purification of ARG from camel liver, this investigation was designed to purify and characterize ARG from camel liver and compare its molecular and kinetic properties with that reported from other species. Camel liver arginase (CL-ARG) was purified to homogeneity using heat denaturation followed by ammonium sulphate precipitation with a combination of DEAE-cellulose, SP-Sepharose and Sephadex G 100-120 chromatography columns. The specific activity of CL-ARG was increased to 18,485 units/mg proteins with 23.5-fold purification over crude homogenate. It was observed that CL-ARG showed a similarity with other species such as behaviour on DEAE-cellulose column, kinetics of inhibition, necessity for metal ions as cofactor, and alkaline optimum pH. On the contrary, CL-ARG differed in its molecular weight (180kDa), oligomeric protein structure, slightly neutral-alkaline pI value (7.7), Km value (7.1mM), optimum pH (9, 10.7), and higher optimum temperature (70°C). In conclusion, this study investigated the properties of CL-ARG via a simple and reproducible purification procedure and provided valuable information for its production from available source in Egypt for medical and industrial purposes.

Biochemical characterization of a new nicotinamidase from an unclassified bacterium thriving in a geothermal water stream microbial mat community.

Nicotinamidases are amidohydrolases that convert nicotinamide into nicotinic acid, contributing to NAD+ homeostasis in most organisms. In order to increase the number of nicotinamidases described to date, this manuscript characterizes a nicotinamidase obtained from a metagenomic library fosmid clone (JFF054_F02) obtained from a geothermal water stream microbial mat community in a Japanese epithermal mine. The enzyme showed an optimum temperature of 90°C, making it the first hyperthermophilic bacterial nicotinamidase to be characterized, since the phylogenetic analysis of this fosmid clone placed it in a clade of uncultured geothermal bacteria. The enzyme, named as UbNic, not only showed an alkaline optimum pH, but also a biphasic pH dependence of its kcat, with a maximum at pH 9.5–10.0. The two pKa values obtained were 4.2 and 8.6 for pKes1 and pKes2, respectively. These results suggest a possible flexible catalytic mechanism for nicotinamidases, which reconciles the two previously proposed mechanisms. In addition, the enzyme showed a high catalytic efficiency, not only toward nicotinamide, but also toward other nicotinamide analogs. Its mutational analysis showed that a tryptophan (W83) is needed in one of the faces of the active site to maintain low Km values toward all the substrates tested. Furthermore, UbNic proved to contain a Fe2+ ion in its metal binding site, and was revealed to belong to a new nicotinamidase subgroup. All these characteristics, together with its high pH- and thermal stability, distinguish UbNic from previously described nicotinamidases, and suggest that a wide diversity of enzymes remains to be discovered in extreme environments.

Point mutation Gln121-Arg increased temperature optima of Bacillus lipase (1.4 subfamily) by fifteen degrees

Small molecular weight Bacillus lipases are industrially attractive because of its alkaline optimum pH, broad substrate specificity and production in high yield by overexpression both in Escherichia coli and Bacillus subtilis. Its major limitation of being mesophilic in nature is constantly targeted by laboratory evolution studies. Herein metagenomically isolated Bacillus LipJ was randomly evolved by error prone PCR and library of variants were screened for enhanced thermostability. Point mutant Gln121Arg was extensively characterized and it showed dramatic shift of Temp. opt to 50°C compared to 37°C for parent enzyme. Thermostability studies at 45°C and 50°C determined six fold increase in half life for point variant Gln121Arg compared to LipJ. Circular dichroism (CD) and tryptophan fluorescence study established enhanced thermostability of Gln121Arg. Specific activity of point variant Gln121Arg was comparable to wild type with increased substrate affinity (Km reduced). Reduced kcat for variant Gln121Arg infer that kinetic and catalytic efficiency of mutant was compromised. Structural implications by homolog modelling predicted Gln121 to be placed within longest loop of the structure at surface. Localization of loop due to additional polar interactions by Arg121 to protein core defines molecular basis of enhanced thermostability of random point variant Gln121Arg.

Point Mutation Ile137-Met Near Surface Conferred Psychrophilic Behaviour and Improved Catalytic Efficiency to Bacillus Lipase of 1.4 Subfamily.

Bacillus lipolytic enzymes of subfamily 1.4 are industrially attractive because of its alkaline optimum pH and broad substrate specificity. The activity and stability of these enzymes for a limited temperature range (30-50 °C) need attention for its industrial application. In the present study, Bacillus subtilis LipJ was rationally designed for low-temperature adaptation. Small amino acids with lower volume and without side chain branches have high occurrence among psychrophilic proteins. Met residue is reported to be preferred for cold adaptation as it is thermolabile in nature and undergoes oxidation at high temperature. Therefore, the Ile137 residue, three residues downstream the catalytic residue Asp133, was substituted by Met. Biochemical study demonstrated that variant Ile137Met was optimally active at 20 °C whereas parent enzyme was most active at 37 °C. The variant retained 70-80% relative activity at 10 °C where parent enzyme demonstrated low activity. Ile137Met was observed to be unstable at and above 30 °C. Kinetic study demonstrated increased K m and k cat values for variant referring improved catalytic efficiency but poor substrate affinity. Homolog modelling predicted lowered number of weak interactions by substituted Met137 as molecular basis of increased flexibility of variant. Hence, increased structure flexibility might be responsible for poor substrate affinity but increased molecular motion for higher catalysis at cold.

Crystallization and X-ray diffraction studies of a two-domain laccase from Streptomyces griseoflavus.

Laccase (EC 1.10.3.2) is one of the most common copper-containing oxidases; it is found in many organisms and catalyzes the oxidation of primarily phenolic compounds by oxygen. Two-domain laccases have unusual thermostability, resistance to inhibitors and an alkaline optimum of activity. The causes of these properties in two-domain laccases are poorly understood. A recombinant two-domain laccase (SgfSL) was cloned from the genome of Streptomyces griseoflavus Ac-993, expressed in Escherichia coli and purified to homogeneity. The crystals of SgfSL belonged to the monoclinic space group P21, with unit-cell parameters a = 74.64, b = 94.72, c = 117.40 Å, β = 90.672°, and diffraction data were collected to 2.0 Å resolution using a synchrotron-radiation source. Two functional trimers per asymmetric unit correspond to a Matthews coefficient of 1.99 Å(3) Da(-1) according to the monomer molecular weight of 35.6 kDa.

Structural and functional characterization of two-domain laccase from Streptomyces viridochromogenes.

Laccase (EC 1.10.3.2) is one of the most common copper-containing oxidases found in many organisms and catalyses oxidation of primarily phenolic compounds by oxygen. A recently found bacterial laccase whose molecule is formed by two domains - the so called two-domain laccase (2DLac) or small laccase - has unusual resistance to inhibitors and an alkaline optimum of activity. The causes of these properties, as well as the biological function of two-domain laccases, are poorly understood. We performed an enzymatic and structural characterization of 2DLac from Streptomyces viridochromogenes (SvSL). It was cloned and overproduced in Escherichia coli. Phenolic compounds were oxidized in the presence of the enzyme under alkaline but not acidic conditions. Conversely, nonphenolic compounds were oxidized at acidic but not alkaline pH. SvSL catalysed oxidation of nonphenolic compounds more efficiently than that of phenols. Moreover, this two-domain laccase displayed a cytochrome c oxidase activity and exhibited no ferroxidase activity. The enzyme was resistant to specific inhibitors of copper-containing oxidases, such as NaN3 and NaF. We succeeded in generating X-ray quality crystals and solved their structure to a resolution of 2.4Å. SvSL is a homotrimer in its native state. Comparison of its structure with that of a three-domain laccase revealed differences in the second coordination sphere of the T2/T3 centre and solvent channels. The role of these differences in the resistance of the enzyme to inhibitors and the activity at alkaline pH is under discussion.

Characterization of digestive enzymes from de-oiled mackerel (Scomber japonicus) muscle obtained by supercritical carbon dioxide and n-hexane extraction as a comparative study

The oil in mackerel muscle was extracted using an environmental friendly solvent, supercritical carbon dioxide (SC-CO2) at a semi-batch flow extraction process and an n-hexane. The SC-CO2 was carried out at temperature 45°C and pressures ranging from 15 to 25MPa. The flow rate of CO2 (27g/min) was constant at the entire extraction period of 2h. The highest oil extracted residues after SC-CO2 extraction was used for activity measurement of digestive enzymes. Four digestive enzymes were found in water soluble extracts after n-hexane and SC-CO2 treated samples. Amylase, lipase and trypsin activities were higher in water soluble extracts after SC-CO2 treated samples except protease. Among the four digestive enzymes, the activity of amylase was highest and the value was 44.57uM/min/mg of protein. The water soluble extracts of SC-CO2 and n-hexane treated mackerel samples showed same alkaline optimum pH and pH stability for each of the digestive enzymes. Optimum temperature of amylase, lipase, protease and trypsin was 40, 50, 60 and 30°C, respectively of both extracts. More than 80% temperature stability of amylase, lipase, protease and trypsin were retained at mentioned optimum temperature in water soluble extracts of both treated samples. Based on protein patterns, prominent protein band showed in water soluble extracts after SC-CO2 treated samples indicates no denaturation of protein than untreated and n-hexane.

Molecular mutagenesis at Tyr-101 of the amylomaltase transcribed from a gene isolated from soil DNA.

The wild-type (WT) amylomaltase gene was directly isolated from soil DNA and cloned into a pET19b vector to express in E. coli BL21(DE3). The ORF of this gene consisted of 1,572 bp, encoding an enzyme of 523 amino acids. Though showing 99% sequence identity to amylomaltse from Thermus thermophilus ATCC 33923, this enzyme is unique in its alkaline optimum pH. In order to alter amylomaltase with less coupling or hydrolytic activity to enhance cycloamylose (CA) formation through cyclization reaction, site-directed mutagenesis of the second glucan binding site involving in CA production was performed at Tyr-101. The result revealed that the mutated Y101S enzyme showed a small increase in cyclization activity while significantly decreased disproportionation, coupling and hydrolytic activities. Mutation also resulted in the change in substrate specificity for disproportionation reaction. The WT enzyme preferred maltotriose, while the activity of mutated enzyme was the highest with maltopentaose substrate. Product analysis by HPAEC-PAD demonstrated that the main CAs of the WT amylomaltase were CA29-CA37. Y101S mutation did not change the product pattern, however, the amount of CAs formed by the mutated enzyme tended to increase especially at long incubation time.

Function of aspartic acid residues in optimum pH control of l-arabinose isomerase from Lactobacillus fermentum

L-Arabinose isomerase (L-AI) catalyzes the isomerization of L-arabinose to L-ribulose and D-galactose to D-tagatose. Most reported L-AIs exhibit neutral or alkaline optimum pH, which is less beneficial than acidophilic ones in industrial D-tagatose production. Lactobacillus fermentum L-AI (LFAI) is a thermostable enzyme that can achieve a high conversion rate for D-galactose isomerization. However, its biocatalytic activity at acidic conditions can still be further improved. In this study, we report the single- and multiple-site mutagenesis on LFAI targeting three aspartic acid residues (D268, D269, and D299). Some of the lysine mutants, especially D268K/D269K/D299K, exhibited significant optimum pH shifts (from 6.5 to 5.0) and enhancement of pH stability (half-life time increased from 30 to 62h at pH6.0), which are more favorable for industrial applications. With the addition of borate, D-galactose was isomerized into D-tagatose by D268K/D269K/D299K at pH5.0, resulting in a high conversion rate of 62%. Based on the obtained 3.2-Å crystal structure of LFAI, the three aspartic acid residues were found to be distant from the active site and possibly did not participate in substrate catalysis. However, they were proven to possess similar optimum pH control ability in other L-AI, such as that derived from Escherichia coli. This study sheds light on the essential residues of L-AIs that can be modified for desired optimum pH and better pH stability, which are useful in D-tagatose bioproduction.

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 a β-1,3-glucanase active in the alkaline midgut of Spodoptera frugiperda larvae and its relation to β-glucan-binding proteins

Spodoptera frugiperda β-1,3-glucanase (SLam) was purified from larval midgut. It has a molecular mass of 37.5 kDa, an alkaline optimum pH of 9.0, is active against β-1,3-glucan (laminarin), but cannot hydrolyze yeast β-1,3-1,6-glucan or other polysaccharides. The enzyme is an endoglucanase with low processivity (0.4), and is not inhibited by high concentrations of substrate. In contrast to other digestive β-1,3-glucanases from insects, SLam is unable to lyse Saccharomyces cerevisae cells. The cDNA encoding SLam was cloned and sequenced, showing that the protein belongs to glycosyl hydrolase family 16 as other insect glucanases and glucan-binding proteins. Multiple sequence alignment of β-1,3-glucanases and β-glucan-binding protein supports the assumption that the β-1,3-glucanase gene duplicated in the ancestor of mollusks and arthropods. One copy originated the derived β-1,3-glucanases by the loss of an extended N-terminal region and the β-glucan-binding proteins by the loss of the catalytic residues. SLam homology modeling suggests that E228 may affect the ionization of the catalytic residues, thus displacing the enzyme pH optimum. SLam antiserum reacts with a single protein in the insect midgut. Immunocytolocalization shows that the enzyme is present in secretory vesicles and glycocalyx from columnar cells.

Purification and Characterization of a New Family 45 Endoglucanase, STCE1, from Staphylotrichum coccosporum and Its Overproduction in Humicola insolens

In the detergent industry, fungal endoglucanases have been used to release microfibrils (defibrillation) from the surface of dyed cellulosic fabrics to enhance color brightness. Although endoglucanases for laundry use must have various properties, such as a neutral or alkaline optimum pH, resistance to anionic surfactants and oxidizing agents (main components in detergents), and high defibrillation activity, all-purpose endoglucanases have not been obtained yet. As a result of screening of endoglucanases, a new family 45 endoglucanase (family 45 glycoside hydrolase), designated STCE1, was obtained and purified to apparent homogeneity from the culture supernatant of Staphylotrichum coccosporum NBRC 31817. The molecular mass of STCE1 was 49 kDa. The optimum pH for the carboxymethyl cellulase activity of STCE1 was 6.0, and the optimum temperature was 60 degrees C. STCE1 was highly resistant to an anionic surfactant and an oxidizing agent. Furthermore, the defibrillation activities on dyed cotton and lyocell fabrics of STCE1 were higher than those of the other representative endoglucanases tested. These results indicate that STCE1 is an all-purpose enzyme for laundry use. A gene encoding STCE1, designated the stce1 gene, was cloned from S. coccosporum, and the complete sequence was determined. STCE1 consisted of three distinct domains: an N-terminal catalytic domain (family 45), a linker domain, and a C-terminal carbohydrate-binding module (family 1). The amino acid sequences of the catalytic domain of STCE1 were phylogenetically close to those of the family 45 endoglucanases EGL3, EGL4, and EGV from a Humicola sp. Hence, the stce1 gene was transferred into Humicola insolens and expressed. As a result, extremely high levels (0.90 mg protein per ml of culture supernatant, 27% of the total proteins) of the recombinant STCE1 were secreted as a mature form in the culture supernatant.

Activation of biliverdin-IXα reductase by inorganic phosphate and related anions

The effect of pH on the initial-rate kinetic behaviour of BVR-A (biliverdin-IXalpha reductase) exhibits an alkaline optimum with NADPH as cofactor, but a neutral optimum with NADH as cofactor. This has been described as dual cofactor and dual pH dependent behaviour; however, no mechanism has been described to explain this phenomenon. We present evidence that the apparent peak of activity observed at neutral pH with phosphate buffer and NADH as cofactor is an anion-dependent activation, where inorganic phosphate apparently mimics the role played by the 2'-phosphate of NADPH in stabilizing the interaction between NADH and the enzyme. The enzymes from mouse, rat and human all exhibit this behaviour. This behaviour is not seen with BVR-A from Xenopus tropicalis or the ancient cyanobacterial enzyme from Synechocystis PCC 6803, which, in addition to being refractory to activation by inorganic phosphate, are also differentiated by an acid pH optimum with both nicotinamide nucleotides.

Proteolytic activity in Encephalitozoon cuniculi sporogonial stages: Predominance of metallopeptidases including an aminopeptidase-P-like enzyme

A fraction enriched in spore precursor cells (sporoblasts) of the microsporidian Encephalitozoon cuniculi, an intracellular parasite of mammals, was obtained by Percoll gradient centrifugation. Soluble extracts of these cells exhibited proteolytic activity towards azocasein, with an alkaline optimum pH range (9–10). Prevalence of some metallopeptidases was supported by the stimulating effect of Ca 2+, Mg 2+, Mn 2+ and Zn 2+ ions, and inhibition by two chelating agents (EDTA and 1,10-phenanthroline), a thiol reductant (dithiothreitol) and two aminopeptidase inhibitors (bestatin and apstatin). Zymographic analysis revealed four caseinolytic bands at about 76, 70, 55 and 50 kDa. Mass spectrometry of tryptic peptides from one-dimensional gel slices identified a cytosol (leucine) aminopeptidase homologue (M17 family) in 50-kDa band and an enzyme similar to aminopeptidase P (AP-P) of cytosolic type (M24B subfamily) in 70-kDa band. Multiple sequence alignments showed conservation of critical residues for catalysis and metal binding. A long insertion in a common position was found in AP-P sequences from E. cuniculi and Nosema locustae, an insect-infecting microsporidian. The expression of cytosolic AP-P in sporogonial stages of microsporidia may suggest a key role in the attack of proline-containing peptides as a prerequisite to long-duration biosynthesis of structural proteins destined to the sporal polar tube.

Serum Alkaline Phosphatase Activity As A Potential Biomarker For The Intergrity Of The Hepatic Drainage System In Acute Falciparum Malaria Infection

Introduction: The serum activity of the tissue-specific, membrane-bound enzyme alkaline phosphatase (Orthophosphoric monoester phosphohydrolase, alkaline optimum (E.C. 3.1.3.1))was assayed in the sera of 110 adult patients comprising of 50 males and 60 females (age range, 18 – 40 years) presenting with acute falciparum malaria infection and a control group of 48 healthy adults. Methods: Serum samples were collected from a randomly selected group of individuals confirmed to be infected with the falciparum malaria parasite by microscopic examination of Giemsa stained thin blood slides. Results:Serum alkaline phosphatase activity was significantly increased (6.35 ± 0.39 IU) in female patients relative to the normal females (4.33 ± 0.23 IU), p = 0.003. Serum alkaline phosphatase activity was also higher in male patients (5.85 ± 0.36 IU) when compared to the control activity of (4.83 ± 0.35 IU) in males, p = 0.001. Conclusion: The increased serum alkaline phosphatase activity among the patients indicates that the liver stage of falciparum malaria infection is accompanied by a perturbation of the host hepatocytes drainage pathways where alkaline phosphatase is localized on the membrane. This makes alkaline phosphatase a potentially important biomarker for the assessment of the integrity of the hepatic drainage system in acute falciparum malaria infection.

Expression, Purification, and Characterization of an Active RNase H Domain of the Hepatitis B Viral Polymerase

The replication of the hepatitis B viral DNA genome proceeds through a pregenomic RNA intermediate. This pregenomic RNA subsequently serves as the template for the formation of the viral DNA by the reverse transcriptase activity of the viral P gene product. The P gene product is believed to be a multifunctional enzyme with DNA-dependent DNA polymerase, RNA-dependent DNA polymerase, and RNase H activities. Detailed biochemical studies of this protein have not been performed because of the inability to obtain sufficient amounts of the enzyme from the virus and by the inability to produce the enzyme in heterologous expression systems. The RNase H activity is essential for viral replication and is believed to be responsible for the degradation of the RNA pregenomic intermediate as well as for generating the short RNA primer that is required for DNA second strand synthesis. We have assembled an expression vector which directs the synthesis of a protein that corresponds to the putative RNase H domain of the P gene product and having a carboxyl-terminal polyhistidine tag to facilitate purification. The protein has been expressed in Escherichia coli and purified to yield 1-2 mg of protein/liter of culture. This protein has RNase H activity as defined by its ability to degrade the RNA component of RNA-DNA hybrids but not the DNA component. The RNase H has a basic optimum pH, is active only in the presence of reducing agents, and is dependent on the presence of divalent cations, with magnesium being preferred over manganese.

Purification and characterization of a novel phosphoenolpyruvate carboxylase from banana fruit.

Phosphoenolpyruvate carboxylase (PEPC) from ripened banana (Musa cavendishii L.) fruits has been purified 127-fold to apparent homogeneity and a final specific activity of 32 mumol of oxaloacetate produced/min per mg of protein. Non-denaturing PAGE of the final preparation resolved a single protein-staining band that co-migrated with PEPC activity. Polypeptides of 103 (alpha-subunit) and 100 (beta-subunit) kDa, which stain for protein with equal intensity and cross-react strongly with anti-(maize leaf PEPC) immune serum, were observed following SDS/PAGE of the final preparation. CNBr cleavage patterns of the two subunits were similar, but not identical, suggesting that these polypeptides are related, but distinct, proteins. The enzyme's native molecular mass was estimated to be about 425 kDa. These data indicate that in contrast to the homotetrameric PEPC from most other sources, the banana fruit enzyme exists as an alpha 2 beta 2 heterotetramer. Monospecific rabbit anti-(banana PEPC) immune serum effectively immunoprecipitated the activity of the purified enzyme. Immunoblotting studies established that the 100 kDa subunit did not arise via proteolysis of the 103 kDa subunit after tissue extraction, and that the subunit composition of banana PEPC remains uniform throughout the ripening process. PEPC displayed a typical pH activity profile with an alkaline optimum and activity rapidly decreasing below pH 7.0. Enzymic activity was absolutely dependent on the presence of a bivalent metal cation, with Mg2+ or Mn2+ fulfilling this requirement. The response of the PEPC activity to PEP concentration and to various effectors was greatly influenced by pH and glycerol addition to the assay. The enzyme was activated by hexose-monophosphates and potently inhibited by malate, succinate, aspartate and glutamate at pH 7.0, whereas the effect of these metabolites was considerably diminished or completely abolished at pH 8.0. The significance of metabolite regulation of PEPC is discussed in relation to possible functions of this enzyme in banana fruit metabolism.