Escherichia coli signal peptidase recognizes and cleaves the signal sequence of α-amylase originating from Bacillus licheniformis

The gene encoding the α-amylase from Bacillus licheniformis was cloned, with and without the native signal sequence, and expressed in Escherichia coli, resulting in the production of the recombinant protein in the cytoplasm as insoluble but enzymatically active aggregates. Expression with a low concentration of the inducer at low temperature resulted in the production of the recombinant protein in soluble form in a significantly higher amount. The protein produced with signal sequence was exported to the extracellular medium, whereas there was no export of the protein produced from the gene without the signal sequence. Similarly, the α-amylase activity in the culture medium increased with time after induction in case of the protein produced with signal sequence. Molecular mass determinations by MALDI-TOF mass spectrometry and N-terminal amino acid sequencing of the purified recombinant α-amylase from the extracellular medium revealed that the native signal peptide was cleaved by E. coli signal peptidase between Ala28 and Ala29. It seems possible that the signal peptide of α-amylase from B. licheniformis can be used for the secretion of other recombinant proteins produced using the E. coli expression system.     

Transfer and expression of a Bacillus licheniformis α-amylase gene in Zymomonas mobilis

The gene from Bacillus licheniformis coding for a thermostable -amylase was subcloned into the broad-host-range plasmid pKT210 in Escherichia coli. The recombinant plasmid pGNB6 was transferred into Zymomonas mobilis ATCC 31821 by conjugation. Plasmid pGNB6 was stably maintained in E. coli and unstable in Z. mobilis. The amylase gene was expressed in Z. mobilis at a lower level (25%) than in E. coli and regulation of enzyme biosynthesis was different in the host cells. Almost all the -amylase activity was recovered in the culture medium of Z. mobilis. This enzyme localization seemed to be the result of protein secretion rather than cell lysis. Integration of the amylase gene into a cryptic plasmid of Z. mobilis was observed. The amylase gene was still expressed, although at a lower level, and the -amylase activity, associated with a protein of molecular mass 62,000 daltons, was immunologically identical in Z. mobilis, E. coli and B. licheniformis.     

Integration,amplification and expression of the Bacillus licheniformis α-amylase gene in Bacillus subtilis chromosome

We have introduced the α-amylase gene from Bacillus licheniformis (amy gene) in a non-replicative plasmid which can be conveniently integrated and amplified at a specific site of the B. subtilis chromosome. Although we were able to select spontaneous and stable gene amplification of about 20 integrated copies, the amylase secretion remained very low. A DNA fragment presenting a high promoter activity in B. subtilis was therefore inserted upstream from the amy gene coding sequence, leading to a significant increase of amylase production. However, the amplified structures obtained with this construction were found to contain no more than 12 copies of the amy gene and to be rather unstable when cells were grown under non-selective conditions.     

Biophysical characterization of Bacillus licheniformis and Escherichia coli γ-glutamyltranspeptidases: A comparative analysis

The oligomeric states of Bacillus licheniformis and Escherichia coli γ-glutamyltranspeptidases (BlGGT and EcGGT) in solution have been investigated by analytical ultracentrifugation. The results showed that BlGGT has a sedimentation coefficient of 5.12S, which can be transformed into an experimental molecular mass of approximately 62,680Da. The monomeric conformation is conserved in EcGGT. SDS-PAGE analysis and cross-linking studies further proved that the autocatalytically processed BlGGT and EcGGT form a heterodimeric association. Unfolding analyses using circular dichroism and tryptophan emission fluorescence revealed that these two proteins had a different sensitivity towards temperature- and guanidine hydrochloride (GdnHCl)-induced denaturation. BlGGT and EcGGT had a T(m) value of 59.5 and 49.2°C, respectively, and thermal unfolding of both proteins was found to be highly irreversible. Chemical unfolding of BlGGT was independent to the pH value ranging from 5 to 10, whereas the pH environment was found to significantly influence the GdnHCl-induced denaturation of EcGGT. Both enzymes did not reactivate from the completely unfolded states, accessible at 6M GdnHCl. BlGGT was active in the presence of 4M NaCl, whereas the activity of EcGGT was significantly decreased at the high-salt condition. Taken together, these findings suggest that the biophysical properties of the homologous GGTs from two mesophilic sources are quite different.     

Purification of α-amylase from Bacillus licheniformis by chromatofocusing and gel filtration chromatography

A combination of chromatofocusing and gel filtration chromatography resulted in a simple purification of -amylase from Bacillus licheniformis. The purification was approximately 77-fold. Identification of the purity was established by SDS–PAGE. Molecular weight and isoelectric point of the purified enzyme were 58 kDa and 7.18 respectively. Western blot analysis confirms the specificity of antibody raised against purified -amylase.     

The DsbA signal peptide-mediated secretion of a highly efficient raw-starch-digesting,recombinant α-amylase from Bacillus licheniformis ATCC 9945a

In this study, a new approach for extracellular production of recombinant α-amylase in Escherichia coli was investigated. A gene encoding a highly efficient raw-starch-digesting α-amylase from Bacillus licheniformis ATCC 9945a was cloned and expressed in E. coli. The gene encoding mature α-amylase was cloned into the pDAss expression vector, and secretion of the gene product was regulated by fusion to the signal peptide of DsbA, a well-characterized E. coli periplasmic protein. E. coli BL21 (DE3) carrying pDAss vector containing amylase gene had approximately 2.5-fold higher volumetric enzyme productivity than the natural system. The recombinant enzyme showed higher efficiency for digesting diverse raw starches when compared with the native enzyme and was similar to commercial α-amylase in its ability to hydrolyze raw starches. The properties of the recombinant enzyme demonstrate the potential of the DsbA signal peptide approach for the secretory production of the fully active, industrially important recombinant enzyme.     

Conformational destabilization of Bacillus licheniformis α-amylase induced by lysine modification and calcium depletion

Bacillus licheniformis α-amylase (BLA) was chemically modified using 100-fold molar excess of succinic anhydride over protein or 0.66 M potassium cyanate to obtain 42 % succinylated and 81 % carbamylated BLAs. Size and charge homogeneity of modified preparations was established by Sephacryl S-200 HR gel chromatography and polyacrylamide gel electrophoresis. Conformational alteration in these preparations was evident by the larger Stokes radii (3.40 nm for carbamylated and 3.34 nm for succinylated BLAs) compared to 2.43 nm obtained for native BLA. Urea denaturation results using mean residue ellipticity (MRE) as a probe also showed conformational destabilization based on the early start of transition as well as ΔG(D)(H(2)O) values obtained for both modified derivatives and Ca-depleted BLA. Decrease in ΔG(D)(H(2)O) value from 5,930 cal/mol (for native BLA) to 3,957 cal/mol (for succinylated BLA), 3,336 cal/mol (for carbamylated BLA) and 3,430 cal/mol for Ca-depleted BLA suggested reduced conformational stability upon modification of amino groups of BLA or depletion of calcium. Since both succinylation and carbamylation reactions abolish the positive charge on amino groups (both α- and ε- amino), the decrease in conformational stability can be ascribed to the disruption of salt bridges present in the protein which might have released the intrinsic calcium from its binding site.     

Significance of Tyr302, His235 and Asp194 in the α-amylase from Bacillus licheniformis

The calcium-binding residues, Tyr302 and His235, and the sodium-binding residue, Asp194, on the activity of Bacillus licheniformis α-amylase were investigated using site-directed mutagenesis. Tyr302 and His235 were replaced by Asn and Asp, respectively, to produce the mutants Y302N and H235D; Asp194 was replaced by Ala to produce D194A. The mutant amylases were purified to homogeneity; each was ~53?kDa. The specific activity of the D194A was 236?U?mg(-1), lower than the specific activity of the wild-type enzyme by 55%. No significant changes of thermostability, optimum temperature, and optimum pH level were observed in D194A. Mutant amylases with H235D and Y302N significantly improved their specific activity by 43% (754?U?mg(-1)) and 7% (563?U?mg(-1)), respectively, compared with the wild-type enzyme. H235D substitution decreased its optimum pH by approx. 0.5-1 pH unit.     

Surface display expression of Bacillus licheniformis lipase in Escherichia coli using Lpp’OmpA chimera

The lipase from Bacillus licheniformis ATCC14580 was displayed on the cell surface of Escherichia coli using Lpp’OmpA as the anchoring protein. The expressed Lpp’OmpA-lipase fusion protein has a molecular weight of approximately 35 kDa, which was confirmed by SDS-PAGE and western blot analysis. The Lpp’OmpA-lipase fusion protein was located on the cell surface, as determined by immunofluorescence confocal microscopy and flow cytometry. The enzyme activity of the surface-displayed lipase showed clear halo around the colony. The cell surface-displayed lipase showed the highest activity of 248.12 ± 9.42 U/g (lyophilized cell) at the optimal temperature of 37°C and pH 8.0. The enzyme exhibited the highest activity toward the substrate p-nitrophenyl caprylate (C8). These results suggest that E. coli, which displayed the lipase on its surface, could be used as a whole cell biocatalyst.     

Production of α-amylase in a low cost medium by Bacillus licheniformis TCRDC-B13

A low cost synthetic medium producing large quantities of α-amylase has been developed. Bacillus licheniformis TCRDC-B13 isolated from soil was used for α-amylase production. The α-amylase enzyme of this strain showed excellent stability at high temperatures and over a wide pH range. The low cost medium produced 5 times more enzyme than the high cost synthetic medium (using yeast extract and peptone) in shake flasks. In a 2.6-l fermentor, the enzyme production further doubled.     

The production of α-amylase in batch and chemostat culture by Bacillus stearothermophilus

The production of -amylase (-1,4-glucan 4-glucanohydrolase; EC. 3.2.1.1) by a strain of Bacillus stearothermophilus isolated from leaf litter was investigated in a tryptone-maltose medium at 55°C in batch and chemostat culture. Amylase production was growth-limited and restricted to the exponential phase in batch culture. The enzyme yield was reduced by 40% when the culture pH was maintained at pH 7.2. Amylase production in chemostat culture was influenced by the growth rate throughout the dilution rate range used.     

Synthesis of α3 phage DNA in replication mutants of Escherichia coli

Host functions for DNA replication of bacteriophage α3, a representative of group A microvirid phages, were studied using dna and rep mutants of Escherichia coli. In dna⁺ cells, conversion of phage α3 single-stranded DNA (SS) into the double-stranded replicative form (RF) was insensitive to 30–150 μg/ml of chloramphenicol, 200 μg/ml of rifampicin, 50 μg/ml of nalidixic acid, or 200 μg/ml of novobiocin. At 43°C, synthesis of the parental RF was inhibited in dnaG and dnaZ mutants, but not in dnaE and rep strains. Replication of phage α3 progeny RF was prevented by 50 μg/ml of mitomycin C (in hcr⁺ bacteria), 50 μg/ml of nalidixic acid or 200 μg/ml of novoviocin, but neither by 30 μg/ml of chloramphenicol nor by 200 μg/ml of rifampicin. Besides dnaG and dnaZ gene products, dnaE and rep functions were essential for the progeny RF synthesis. Host factor dependence of α3 was relatively simple and, in contrast with phages øX174 and G4, α3 did not require dnaB and dnaC(D) activities.     

Secretion of β-lactamase by Escherichia coli in vivo and in vitro: effect of cerulenin

The effect of cerulenin on the production of -lactamase and other periplasmic proteins was studied in Escherichia coli IA199 carrying plasmid pBR322. Cerulenin (10 to 25 g/ml) had almost no effect on the growth rate of E. coli but it decreased the amount of -lactamase and other periplamic proteins in shock fluid. Higher amounts of the antibiotic (40 to 100 g/ml)decreased turbidity and almost completely prevented synthesis of -lactamase and other periplasmic proteins. Cerulenin decreased incorporation of l-[³⁵S]methionine into membranes during growth as well. Spheroplasts secreted -lactamase into the external medium, but during a 3-h incubation in the presence of cerulenin (25 g/ml) this secretion was prevented by more than 90%. -Lactamase was secreted into the isolated membrane vesicles from E. coli IA199. However, only 5% of the total amount of pre--lactamase was secreted and processed by the membranes in vitro. Cerulenin did not prevent processing in vitro but the membranes prepared from the cells grown in the presence of cerulenin (25 g/ml) did not catalyze processing of pre--lactamase at all. Membrane preparations from Bacillus subtilis did not process pre--lactamase either in the absence or in the presence of cerulenin.     

Cloning of the thermostable α-amylase gene from Pyrococcus woesei in Escherichia coli

Pyrococcus woesei (DSM 3773) α-amylase gene was cloned into pET21d(+) and pYTB2 plasmids, and the pET21d(+)α-amyl and pYTB2α-amyl vectors obtained were used for expression of thermostable α-amylase or fusion of α-amylase and intein in Escherichia coli BL21(DE3) or BL21(DE3)pLysS cells, respectively. As compared with other expression systems, the synthesis of α-amylase in fusion with intein in E. coli BL21(DE3)pLysS strain led to a lower level of inclusion bodies formation—they exhibit only 35% of total cell activity—and high productivity of the soluble enzyme form (195,000 U/L of the growth medium). The thermostable α-amylase can be purified free of most of the bacterial protein and released from fusion with intein by heat treatment at about 75°C in the presence of thiol compounds. The recombinant enzyme has maximal activity at pH 5.6 and 95°C. The half-life of this preparation in 0.05 M acetate buffer (pH 5.6) at 90°C and 110°C was 11 h and 3.5 h, respectively, and retained 24% of residual activity following incubation for 2 h at 120°C. Maltose was the main end product of starch hydrolysis catalyzed by this α-amylase. However, small amounts of glucose and some residual unconverted oligosaccharides were also detected. Furthermore, this enzyme shows remarkable activity toward glycogen (49.9% of the value determined for starch hydrolysis) but not toward pullulan.     

The role of sulfhydryl groups in the action and structure of mammalian α-amylase

Hog pancreatic α-amylase contains 2 -SH groups and 1 tightly bound Ca²⁺ per enzyme molecule. We have prepared derivatives of this enzyme by using 5,5′-dithio-bis-(2-nitrobenzoic acid) (DTNB), iodoacetamidonaphthol, and Hg²⁺. These derivatives retain enzymatic activity thereby demonstrating that the -SH groups of this enzyme are not required for enzymatic activity. The pH profile of these derivatives is the same as that of the native enzyme although the specific activity at each pH is depressed to a varying extent, depending on the derivative. The reaction with DTNB and iodoacetamidonaphthol proceeds only after prior removal of the tightly bound Ca²⁺. The Hg²⁺ derivatives, however, may be formed without prior removal of the Ca²⁺. Upon reacting the amylase with one mole of Hg²⁺ an -S-Hg-S- bridge is formed. This leads us to conclude that the 2 -SH groups lie very close to each other. These derivatives may be useful for an X-ray crystallographic study of this enzyme.     

N-glycosylation deficiency enhanced heterologous production of a Bacillus licheniformis thermostable α-amylase in Saccharomyces cerevisiae

Expression of foreign enzymes in yeast is a traditional genetic engineering approach; however, useful secretory enzymes are not produced in every case. The hyperthermostable α-amylase encoded by the AmyL gene of Bacillus licheniformis was expressed in Saccharomyces cerevisiae; however, it was only weakly produced and was degraded by the proteasome. To determine the cause of low α-amylase production, AmyL was expressed in a panel of yeast mutants harboring knockouts in non-essential genes. Elevated AmyL production was observed in 44 mutants. The knockout genes were classified into six functional categories. Remarkably, all non-essential genes required for N-linked oligosaccharide synthesis and a gene encoding an oligosaccharyl transferase subunit were identified. Immunoblotting demonstrated that differently underglycosylated forms of AmyL were secreted from oligosaccharide synthesis-deficient mutants, while a fully glycosylated form was produced by wild-type yeast, suggesting that N-linked glycosylation of AmyL inhibited its secretion in yeast. Mutational analysis of six potential N-glycosylation sites in AmyL revealed that the N33Q and N309Q mutations remarkably affected AmyL production. To achieve higher AmyL production in yeast, all six N-glycosylation sites of AmyL were mutated. In wild-type yeast, production of the resulting non-glycosylated form of AmyL was threefold higher than that of the glycosylated form.