Expression of yeast mitochondrial aconitase in Bacillus subtilis

Expression of yeast mitochondrial aconitase (Aco1) in a Bacillus subtilis aconitase null mutant restored aconitase activity and glutamate prototrophy but only partially restored sporulation. Late sporulation gene expression in the Aco1-expressing strain was delayed.     

Immunological analysis of aconitase in pumpkin cotyledons: the absence of aconitase in glyoxysomes

Aconitase (EC 4.2.1.3) was purified by column chromatography and SDS-PAGE. Specific antibodies for aconitase were prepared after affinity purification of the antiserum with purified aconitase. The antibodies reacted with purified pumpkin aconitase, and with the 98 kDa protein band after electrophoretic fractionation of extracts of pumpkin cotyledons. Immunoblot analysis revealed a protein with similar molecular mass in extracts of several plants. The intensity of the 98 kDa band increased as pumpkin cotyledons developed in darkness, and decreased thereafter upon illumination. Aconitase activity showed a similar pattern. Anion exchange chromatography of a homogenate of pumpkin cotyledons, followed by western blotting, displayed the presence of immunoreactive protein bands only in fractions showing aconitase activity. The results indicate that the antibodies were specific for aconitase. When we investigated the presence of immunoreactive bands after sucrose gradient fractionation, aconitase was detected in the supernatant fractions and in mitochondria, while a very low amount was found in glyoxysomes. These data provide additional proof that aconitase is not localized in glyoxysomes.     

Purification and subunit structure of RNA polymerases I and II from Dictyostelium discoideum vegetative cells

Summary A purification procedure to obtain RNA polymerases I (or A) and II (or B) from Dictyostelium discoideum amoeba has been developed. The enzymes were solubilized from purified nuclei and separated by DEAF-Sephadex chromatography. RNA polymerases I and II were further purified by a second chromatography on DEAE-Sephadex followed by chromatographies on phosphocellulose and heparin-sepharose. The specific activities of purified RNA polymerases I and II are 92 units/ mg protein and 70 units/ mg protein, respectively. The subunit structure of both RNA polymerases were analyzed by polyacrylamide gel electrophoresis under denaturing conditions after glycerol gradient centrifugation of the enzymes. The putative subunits of RNA polymerase I have molecular weights of 180 000,125 000,43 000,40 000,34 000, 31 000, 25 000,19 000, 17 000 and 14 000. The putative subunits of RNA polymerase II have molecular weights of 200 000 (170 000), 130 000, 33 000, 25 000, 19 000, 17 000, 15 000, 13 000. There are three polypeptides with common molecular weight in Dictyostelium RNA polymerases I and 11. The subunit of 25 000 daltons of both enzymes has common immunological determinants with RNA polymerase II from crustacean Artemia.Abbreviations TLCK tosyl-lysine-chloromethyl-ketone - DPT diazophenylthioether     

Characterization of two forms of poly(ADP-ribose) glycohydrolase in guinea pig liver

A poly(ADP-ribose) glycohydrolase from guinea pig liver cytoplasm has been purified approximately 45,000-fold to apparent homogeneity. The cytoplasmic poly(ADP-ribose) glycohydrolase designated form II differed in several respects from the nuclear poly(ADP-ribose) glycohydrolase I (Mr = 75,500) previously purified from the same tissue (Tanuma et al., 1986a). The purified glycohydrolase II consists of a single polypeptide with Mr of 59,500 estimated by a sodium dodecyl sulfate-polyacrylamide gel. A native Mr of 57,000 was determined by gel permeation. Peptide analysis of partial proteolytic degradation of glycohydrolases II and I with Staphylococcus aureus V8 protease revealed that the two enzymes were structurally different. Amino acid analysis showed that glycohydrolase II had a relatively low proportion of basic amino acid residues as compared with glycohydrolase I. Glycohydrolase II and I were acidic proteins with isoelectric points of 6.2 and 6.6, respectively. The optimum pH for glycohydrolases II and I were around 7.4 and 7.0, respectively. The Km value for (ADP-ribose)n (average chain length n = 15) and the Vmax for glycohydrolase II were 4.8 microM and 18 mumol of ADP-ribose released from (ADP-ribose)n.min-1.(mg of protein)-1, respectively. The Km was about 2.5 times higher, and Vmax 2 times lower, than those observed with glycohydrolase I. Unlike glycohydrolase I, glycohydrolase II was inhibited by monovalent salts. ADP-ribose and cAMP inhibited glycohydrolase II more strongly than glycohydrolase I. These results suggest that eukaryotic cells contain two distinct forms of poly(ADP-ribose) glycohydrolase exhibiting differences in properties and subcellular localization.     

Characterization of the membrane beta-lactamase in Bacillus cereus 569/H/9

The membrane-bound beta-lactamase from Bacillus cereus, strain 569/H/9, has been purified to apparent homogeneity. Nonionic detergent (0.5% Triton X-100) is required to keep the enzyme (traditionally called gamma-penicillinase and now called beta-lactamase III) in solution. Antibodies to beta-lactamase III have been prepared, and the membrane-bound enzyme is immunochemically distinct from the extracellular enzymes. beta-Lactamase III has a molecular weight of 31 500, in contrast to the extracellular enzymes beta-lactamase I and beta-lactamase II which have molecular weights of 30 000 and 22 000, respectively. The isoelectric point of beta-lactamase III is pH 6.8, whereas beta-lactamase I and beta-lactamase II have isoelectric points about 8.6 and 8.3. The amino acid composition of beta-lactamase III differs from those of beta-lactamase I and beta-lactamase II; however, the difference index between the compositions of beta-lactamase I and beta-lactamase III (52%) suggests relatedness. beta-Lactamase III is inactivated by 6 beta-bromopenicillanic acid and by the sulfone of 6 alpha-chloropenicillanic acid, and cephalosporins are poorer substrates than penicillins. beta-Lactamase III may be a membrane-bound class A beta-lactamase.     

1,3-beta-D-glucanases from Pisum sativum seedlings. I. Isolation and purification.

Two buffer-soluble endo-1,3-beta-D-glucanases (EC 3.2.1.6) have been purified to within 1% of electrophoretic homogeneity from etiolated Pisum sativum stem tissues. Purified glucanase I and II differ in physical properties, such as electrophoretic mobility in sodium dodecyl sulfate polyacrylamide gels (Mr values were 22 000 and 37 000, respectively) and isoelectric focusing, (pI values were 5.4 and 6.8, respectively). Although the enzymes have similar pH optima (5.5--6.0), Km values for various substrates (0.6--7.4 mg/ml) and thermal inactivation profiles, they are localized in different tissues and they differ markedly in the rates with which they attack the internal linkages of long- vs. short-chain substrates. Glucanase I is concentrated in apical regions of the stem and is most effectively assayed reductometrically (as laminarinase), while glucanase II is localized in mature regions and is relatively more active in viscometric assays (as carboxymethyl-pachymanase).     

Resolution and Properties of Two High Affinity Cyclic Adenosine 3':5'-monophosphate-Binding Proteins from Wheat Germ

A high affinity cAMP-binding protein (cABP II) was purified to homogeneity from wheat germ. The apparent molecular weight of cABP II, as determined from gel exclusion chromatography, is 5.2 × 10⁵ (at low ionic strength) and 2.8 × 10⁵ (at high ionic strength). One polypeptide subunit (molecular weight, 80,000) was resolved by polyacrylamide gel electrophoresis of cABP II under subunit dissociating conditions. The purification protocol employed resolves cABP II from a distinct, less acidic cAMP-binding protein (cABP I). The K_d values for cAMP are about 10⁻⁶ molar and 10⁻⁷ molar for cABP II and cABP I, respectively. The cAMP-binding sites of cABP I and cABP II have a marked adenine-analog specificity, binding adenine, adenosine, adenine-derived nucleosides and nucleotides and a variety of adenine derivatives having cytokinin activity. While cABP II is phosphorylated in reactions catalyzed by endogenous protein kinases, there is no evidence for modulation of these cABP II-protein kinase interactions by cAMP.     

Purification and characterization of an extracellular polygalacturonase from Lactobacillus plantarum strain BA 11

Lactobacillus plantarum produced extracellular polygalacturonase in a medium containing 1.5% low methyl-pectin (w/v) and 0.5% glucose (w/v) as inducers. The enzyme was purified (approximately 70-fold) by ammonium sulphate fractionation, Sephadex G-100 gel filtration and DEAE-cellulose ion exchange chromatography. Two peaks (PG I and PG II) of enzymic activity were obtained from the DEAE-cellulose column. The molecular mass of PG I was similar to that of PG II (32 000 Da). The K _m values of PG I and PG II for sodium polypectate were calculated to be 1.63 mg/ml and 1.78 mg/ml respectively. Their isoelectric points were about pH 5.5. The pH optimum was 4.5, while the optimum temperature was 35°C for both PG I and PG II. The two purified enzymes had similar endo modes of action on polygalacturonic acid, as determined by comparison of viscosity reduction and reducing group release.     

Purification and characterization of a thermostable glucoamylase from a Myrothecium isolate

Two glucoamylases, gluc I and gluc II, were purified to homogeneity from the culture filtrate of a Myrothecium strain M1 by chromatography on DEAE-cellulose and concanavalin A-sepharose. Molecular masses deduced by SDS-PAGE were 72000 ± 2500 for gluc I and 96 000 ± 4000 for glue II. The temperature optima of the enzymes were both about 70°C and their pH optima were around 4.0. Both enzymes were glycoprotein and preferentially hydrolysed high molecular mass substrates. Hg²⁺ was a potent inhibitor of both glucoamylases. Glue II had higher debranching activity than gluc I.     

Characterization of endo-1,4-beta-D-glucanases purified from Trichoderma viride

Four electrophoretically distinct endo-1,4-beta-D-glucanases (EC 3.2.1.4) from Trichoderma viride have been identified and named as isozymes, Endoglucanases I, II, III and IV, according to their electrophoretic mobilities on polyacrylamide gels. Endoglucanases II, III and IV, the homogeneity of each of which was established by discontinuous gel electrophoresis and ultracentrifugation, had specific activities on CM-cellulose of 1010, 60 and 250 specific fluidity units/mg protein, respectively. These enzymes have similar pH optima (pH 4.0-4.5) and are labile at pH values greater than 8.0. The endoglucanases are high in acidic and hydroxylated amino acids and glycine, but low in basic amino acids. Values of 12.0, 10.3 and 13.1 have been determined for the epsilon 1%280 of purified Endoglucanases II, III and IV, respectively. Sedimentation equilibrium analysis has established the molecular weights of Endoglucanases II, III and IV to be 37 200, 52 000 and 49 500, respectively. The three endoglucanases contain mannose, galactose, glucose and glucosamine. Mannose is the principal neutral sugar in each enzyme. Endoglucanase II is distinguished by its low carbohydrate content, 4.5% (w/w), compared to Endoglucanases III and IV which contain 15.0% and 15.2% carbohydrate, respectively.     

Purification of Two Superoxide Dismutase Isozymes and Their Subcellular Localization in Needles and Roots of Norway Spruce (Picea abies L.) Trees

Two isozymes of superoxide dismutase (SOD; EC 1.15.1.1) were purified from Norway spruce (Picea abies L.) needles to apparent electrophoretic homogeneity. Purification factors were 354 for SOD I and 265 for SOD II. The native molecular mass of both purified enzymes was approximately 33 kD, as determined by gel filtration. The subunit molecular weights, as estimated by sodium dodecyl sulfate polyacrylamide gel electrophoresis, were 20,000 for SOD I and 16,000 for SOD II in the presence of 2-mercaptoethanol, and 15,800 and 15,000, respectively, in its absence. These results indicate that the native enzymes were homodimers whose subunits contained intrachain disulfide bonds. Isoelectric points determined by nondenaturing isoelectric focusing were 4.5 and 5.5 for SOD I and II, respectively. NH₂-terminal sequence analysis of the first 22 to 23 amino acids revealed 70 to 75% sequence identity with chloroplastic CuZn SODs from other plant species for SOD I, and 75% sequence identity with the cytosolic CuZn SOD from Scots pine for SOD II. SOD I was the major activity in needles and it was associated with chloroplasts. SOD II activity was dominant in roots.     

Purification and properties of aldehyde reductases from human placenta

Aldehyde reductases (alcohol: NADP⁺-oxidoreductases, EC 1.1.1.2) I and II from human placenta have been purified to homogeneity. Aldehyde reductase I, molecular weight about 74 000, is a dimer of two nonidentical subunits of molecular weigths of about 32 500 and 39 000, whereas aldehyde erductase II is a monomer of about 32 500. Aldehyde reductase I can be dissociated into subunits under high ionic concentrations. The isoelectric pH for aldehyde reductases I and II are 5.76 and 5.20, respectively. Amino acid compositions of the two enzymes are significantly different. Placenta aldehyde reductase I can utilize glucose with a lower affinity, whereas aldehyde reductase II is not capable to reducing aldo-sugars. Similarly, aldehyde reductase I does not catalyse the reduction of glucuronate while aldehyde reductase II has a high affinity for glucuronate. Both enzymes, however, exhibit strong affinity towards various other aldehydes such as glyceraldehyde, propionaldehyde, and pyridine-3-aldehyde. The pH optima for aldehyde reductases I and II are 6.0 and 7.0, respectively. Aldehyde reductaase I can use both NADH and NADPH as cofactors, whereas aldehyde reductase II activity is dependent on NADPH only. Both enzymes are susceptible to inhibition by sulfhydryl group reagents, aldose reductase inhibitors, lithium sulfate, and sodium chloride to varying degrees.     

Production and characterization of monoclonal antibodies specific for Shewanella colwelliana exopolysaccharide.

Six monoclonal antibodies were produced to whole cells of Shewanella colwelliana (Aco1 to Aco6) and two (Aco22 to Aco23) to purified exopolysaccharide (EPS). Aco1, -4 to -6, -22, and -23 bound to both the cell surface and the purified EPS, while Aco2 and -3 bound to cells only. The EPS of S. colwelliana was antigenically unique from those of nine other species of marine bacteria that were tested. Mapping studies revealed that all of the EPS-specific monoclonal antibodies bound to the same epitope. This EPS epitope was sensitive to cleavage of ester bonds, but neither pyruvate, acetate, nor terminal nonreducing sugars were required for antigenicity. When S. colwelliana was grown on rich media, most of its EPS was loosely associated with the cell surface.     

The identification and characterization of two separate carboxylesterases in guinea-pig serum.

The esterase activity of guinea-pig serum was investigated. A 3-fold purification was achieved by removing the serum albumin by Blue Sepharose CL-6B affinity chromatography. The partially purified enzyme preparation had carboxylesterase and cholinesterase activities of 1.0 and 0.22 mumol of substrate/min per mg of protein respectively. The esterases were labelled with [3H]di-isopropyl phosphorofluoridate (DiPF) and separated electrophoretically on sodium dodecyl sulphate/polyacrylamide gels. Two main labelled bands were detected: band I had Mr 80 000 and bound 18-19 pmol of [3H]DiPF/mg of protein, and band II had Mr 58 000 and bound 7 pmol of [3H]DiPF/mg of protein. Bis-p-nitrophenyl phosphate (a selective inhibitor of carboxylesterase) inhibited most of the labelling of bands I and II. The residual labelling (8%) of band I but not band II (4%) was removed by preincubation of partially purified enzyme preparation with neostigmine (a selective inhibitor of cholinesterase). Paraoxon totally prevented the [3H]DiPF labelling of the partially purified enzyme preparation. Isoelectrofocusing of [3H]DiPF-labelled and uninhibited partially purified enzyme preparation revealed that there were at least two separate carboxylesterases, which had pI3.9 and pI6.2, a cholinesterase enzyme (pI4.3) and an unidentified protein that reacts with [3H]DiPF and has a pI5.0. Sodium dodecyl sulphate/polyacrylamide-gel electrophoresis of these enzymes showed that the carboxylesterase enzymes at pI3.9 and pI6.2 corresponded to the 80 000-Mr subunit (band I) and 58 000-Mr subunit (band II). The cholinesterase enzyme was also composed of 80 000-Mr subunits (i.e. the residual labelling in band I after bis-p-nitrophenyl phosphate treatment). The unidentified protein at pI5.0 corresponded to the residual labelling in band II (Mr 58 000), which was insensitive to neostigmine and bis-p-nitrophenyl phosphate. These studies show that the carboxylesterase activity of guinea-pig serum is the result of at least two separate and distinct enzymes.     

The fungal α‐aminoadipate pathway for lysine biosynthesis requires two enzymes of the aconitase family for the isomerization of homocitrate to homoisocitrate

Fungi produce α‐aminoadipate, a precursor for penicillin and lysine via the α‐aminoadipate pathway. Despite the biotechnological importance of this pathway, the essential isomerization of homocitrate via homoaconitate to homoisocitrate has hardly been studied. Therefore, we analysed the role of homoaconitases and aconitases in this isomerization. Although we confirmed an essential contribution of homoaconitases from Saccharomyces cerevisiae and Aspergillus fumigatus, these enzymes only catalysed the interconversion between homoaconitate and homoisocitrate. In contrast, aconitases from fungi and the thermophilic bacterium Thermus thermophilus converted homocitrate to homoaconitate. Additionally, a single aconitase appears essential for energy metabolism, glutamate and lysine biosynthesis in respirating filamentous fungi, but not in the fermenting yeast S. cerevisiae that possesses two contributing aconitases. While yeast Aco1p is essential for the citric acid cycle and, thus, for glutamate synthesis, Aco2p specifically and exclusively contributes to lysine biosynthesis. In contrast, Aco2p homologues present in filamentous fungi were transcribed, but enzymatically inactive, revealed no altered phenotype when deleted and did not complement yeast aconitase mutants. From these results we conclude that the essential requirement of filamentous fungi for respiration versus the preference of yeasts for fermentation may have directed the evolution of aconitases contributing to energy metabolism and lysine biosynthesis.     

Increased expression of transglutaminase 2 drives glycolytic metabolism in renal carcinoma cells

Transglutaminase 2 (TGase 2) expression and glycolysis are increased in most renal cell carcinoma (RCC) cell lines compared to the HEK293 kidney cell line. Although increased glycolysis and altered tricarboxylic acid cycle are common in RCC, the detailed mechanism by which this phenomenon occurs remains to be elucidated. In the present study, TGase 2 siRNA treatment lowered glucose consumption and lactate levels by about 20–30 % in RCC cells; conversely, high expression of TGase 2 increased glucose consumption and lactate production together with decreased mitochondrial aconitase (Aco 2) levels. In addition, TGase 2 siRNA increased mitochondrial membrane potential and ATP levels by about 20–30 % and restored Aco 2 levels in RCC cells. Similarly, Aco 2 levels and ATP production decreased significantly upon TGase 2 overexpression in HEK293 cells. Therefore, TGase 2 leads to depletion of Aco 2, which promotes glycolytic metabolism in RCC cells.     

Purification and characteriazation of collagenase from guinea pig skin.

Guinea pig skin col-agenase, isolated from culture medium of whole skin, was separated into two enzymatically active fractions. These two fractions have been purified extensively. Peak II fraction has been purified to homogeneity as examined by polyacrylamide gel electrophoresis. Their molecular weights are approximately 130 000 (peak I) and 40 000 (peak II). Both guinea pig skin collagenase fractions are capable of degrading the native collagen fibrils and are inhibited by serum, cysteine and EDTA. They appear to be glycoproteins. Guinea pig skin (peak II) and human skin collagenase were compared. They are both glycoproteins and have similar molecular size (Mr = 40 000). Immunodiffusion assay showed that no cross-reactivity was seen between the enzymes, indicating species specificity among collagenases.     

Characterization of two DNA polymerases from the hyperthermophilic euryarchaeon Pyrococcus abyssi.

The complete genome sequence of the hyperthermophilic archaeon Pyrococcus abyssi revealed the presence of a family B DNA polymerase (Pol I) and a family D DNA polymerase (Pol II). To extend our knowledge about euryarchaeal DNA polymerases, we cloned the genes encoding these two enzymes and expressed them in Escherichia coli. The DNA polymerases (Pol I and Pol II) were purified to homogeneity and characterized. Pol I had a molecular mass of approximately 90 kDa, as estimated by SDS/PAGE. The optimum pH and Mg(2+) concentration of Pol I were 8.5-9.0 and 3 mm, respectively. Pol II is composed of two subunits that are encoded by two genes arranged in tandem on the P. abyssi genome. We cloned these genes and purified the Pol II DNA polymerase from an E. coli strain coexpressing the cloned genes. The optimum pH and Mg(2+) concentration of Pol II were 6.5 and 15-20 mm, respectively. Both P. abyssi Pol I and Pol II have associated 3'-->5' exonuclease activity although the exonuclease motifs usually found in DNA polymerases are absent in the archaeal family D DNA polymerase sequences. Sequence analysis has revealed that the small subunit of family D DNA polymerase and the Mre11 nucleases belong to the calcineurin-like phosphoesterase superfamily and that residues involved in catalysis and metal coordination in the Mre11 nuclease three-dimensional structure are strictly conserved in both families. One hypothesis is that the phosphoesterase domain of the small subunit is responsible for the 3'-->5' exonuclease activity of family D DNA polymerase. These results increase our understanding of euryarchaeal DNA polymerases and are of importance to push forward the complete understanding of the DNA replication in P. abyssi.     

Angiotensin I converting enzyme from human plasma.

The angiotensin I converting enzyme was purified 101 000-fold to homogeneity from human plasma by a combination of chromatographic and electrophoretic techniques. The enzyme is similar to other angiotensin I converting enzymes. It is an acidic glycoprotein consisting of a single polypeptide chain of molecular weight 140 000 with an isoelectric point of 4.6. The enzyme requires chloride ion for activity and is inhibited by ethylenediaminetetraacetic acid, angiotensin II, bradykinin, bradykinin potentiating factor nonapeptide, and 3-mercapto-2-D-methylpropanoyl-L-proline (SQ-14,225). The purified preparation cleaves bradykinin as well as angiotensin II and hippuryl-L-histidyl-L-leucine. Its specific activity with angiotensin I is 2.4 units per mg and with hippuryl-L-histidyl-L-leucine is 31.4 units per mg.     

Purification and partial characterization of two extracellular keratinases of Scopulariopsis brevicaulis

Two extracellular keratinases of Scopulariopsis brevicaulis were purified and partially characterized. The enzymes were isolated by the techniques of gel filtration chromatography and sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). These keratinases (K I & K II) were purified approximately 33 and 29 fold, respectively. SDS-PAGE of the products of gel filtration chromatography (K I & II) produced only one band each, suggesting homogeneity. The optimum pH for both keratinases was 7.8, while the optimum temperatures were 40°C (K I) and 35°C (K II). Estimated molecular weights were 40–45 KDa and 24–29 KDa for K I & K II respectively. Both keratinases were inhibited by phenylmethylsulfonyl fluoride which suggests a serine residue at or near an active site.