The antimicrobial effect of a structural variant of subtilin against outgrowing Bacillus cereus T spores and vegetative cells occurs by different mechanisms.

Subtilin is a ribosomally synthesized antimicrobial peptide that contains several unusual amino acids as a result of posttranslational modifications. Site-directed mutagenesis was employed to construct a structural variant of subtilin in which the unusual dehydroalanine (Dha) residue at position 5 was changed to alanine. Proton nuclear magnetic resonance spectroscopy, amino acid composition, and N-terminal sequence analysis established that the mutation did not disrupt posttranslational processing of the precursor peptide. This mutant subtilin was devoid of antimicrobial activity as assessed by its lack of inhibitory effects on outgrowth of Bacillus cereus T spores. However, this same mutant subtilin was fully active with respect to its ability to induce lysis of vegetative B. cereus T cells. Because an intact Dha-5 residue is required in the one instance but not in the other, it was concluded that the molecular mechanism by which subtilin inhibits (without lysis) spore outgrowth is not the same as the mechanism by which it inhibits (with lysis) vegetative cells.     

Structure-activity relationships in the peptide antibiotic nisin: role of dehydroalanine 5.

A mutant of the peptide antibiotic nisin in which the dehydroalanine residue at position 5 has been replaced by an alanine has been produced and structurally characterized. It is shown to have activity very similar to that of wild-type nisin in inhibiting growth of Lactococcus lactis and Micrococcus luteus but is very much less active than nisin as an inhibitor of the outgrowth of spores of Bacillus subtilis. These observations, which parallel those of W. Liu and J. N. Hansen (Appl. Environ. Microbiol. 59:648-651, 1993) on the corresponding mutant of the related antibiotic subtilin, are discussed in terms of the mechanism(s) of action of these antibiotics.     

Engineering dehydrated amino acid residues in the antimicrobial peptide nisin.

The small antimicrobial peptide nisin, produced by Lactococcus lactis, contains the uncommon amino acid residues dehydroalanine and dehydrobutyrine and five thio ether bridges. Since these structures are posttranslationally formed from Ser, Thr, and Cys residues, it is feasible to study their role in nisin function and biosynthesis by protein engineering. Here we report the development of an expression system for mutated nisin Z (nisZ) genes, using nisin A producing L. lactis as a host. Replacement by site-directed mutagenesis of the Ser-5 codon in nisZ by a Thr codon, led to a mutant with a dehydrobutyrine instead of a dehydroalanine residue at position 5, as shown by NMR. Its antimicrobial activity was 2-10-fold lower relative to wild-type nisin Z, depending on the indicator strain used. In another mutagenesis study a double mutation was introduced in the nisZ gene by replacing the codons for Met-17 and Gly-18 by codons for Gln and Thr, respectively, as in the third lanthionine ring of the related antimicrobial peptide subtilin from Bacillus subtilis. This resulted in the simultaneous production of two mutant species, one containing a Thr residue and the other containing a dehydrobutyrine residue at position 18, both having different bacteriocidal properties.     

Biosynthesis of nisin in the subtilin producer Bacillus subtilis ATCC6633

Summary Plasmids having the structural gene of nisin (nis A) combined with the subtilin or two hybrid subtilin-nisin leaders were integrated into the subtilin operon in the chromosome of a nisin-resistant and subtilin-producing strain of B. subtilis by single crossing over. Nisin was produced only when the leader consisted mainly of the nisin part. This indicates that nisin and its leader sequence might work as a couple that makes a recognizable conformation for the subtilin modification enzymes. Therefore recognition does not depend on the primary structure of the leader sequence itself.     

Engineering subtilisin E for enhanced stability and activity in polar organic solvents

We examined the effect of a novel disulfide bond engineered in subtilisin E from Bacillus subtilis based on the structure of a thermophilic subtilisin-type serine protease aqualysin I. Four sites (Ser163/Ser194, Lys170/Ser194, Lys170/Glu195, and Pro172/Glu195) in subtilisin E were chosen as candidates for Cys substitutions by site-directed mutagenesis. The Cys170/Cys195 mutant subtilisin formed a disulfide bond in B. subtilis, and showed a 5-10-fold increase in specific activity for an authentic peptide substrate for subtilisin, N-succinyl-L-Ala-L-Ala-L-Pro-L-Phe-p-nitroanilide, compared with the single-Cys mutants. However, the disulfide mutant had a 50% decrease in catalytic efficiency due to a smaller k(cat) and was thermolabile relative to the wild-type enzyme, whereas it was greatly stabilized relative to its reduced form. These results suggest that an electrostatic interaction between Lys170 and Glu195 is important for catalysis and stability in subtilisin E. Interestingly, the disulfide mutant was found to be more stable in polar organic solvents, such as dimethylformamide and ethanol, than the wild-type enzyme, even under reducing conditions; this is probably due to the substitution of uncharged Cys by charged surface residues (Lys170 and Glu195). Further, the amino-terminal engineered disulfide bond (Gly61Cys/Ser98Cys) and the mutation Ile31Leu were introduced to enhance the stability and catalytic activity. A prominent 3-4-fold increase in the catalytic efficiency occurred in the quintet mutant enzyme over the range of dimethylformamide concentration (up to 40%).     

Carboxyl residues in the active site of human phenol sulfotransferase (SULT1A1)

The carboxyl-specific amino acid modification reagent, Woodward's reagent K (WK), was utilized to characterize carboxyl residues (Asp and Glu) in the active site of human phenol sulfotransferase (SULT1A1). SULT1A1 was purified using the pMAL-c2 expression system in E. coli. WK inactivated SULT1A1 activity in a time- and concentration-dependent manner. The inactivation followed first-order kinetics relative to both SULT1A1 and WK. Both phenolic substrates and adenosine 3'-phosphate 5'-phosphosulfate (PAPS) protected against the inactivation, which suggests the carboxyl residue modification causing the inactivation took place within the active site of the enzyme. With partially inactivated SULT1A1, both V(max) and K(m) changed for PAPS, while for phenolic substrates, V(max) decreased and K(m) did not change significantly. A computer model of the three-dimensional structure of SULT1A1 was constructed based on the mouse estrogen sulfotransferase (mSULT1E1) X-ray crystal structure. According to the model, Glu83, Asp134, Glu246, and Asp263 are the residues likely responsible for the inactivation of SULT1A1 by WK. According to these results, five SULT1A1 mutants, E83A, D134A, E246A, D263A, and E151A, were generated (E151A as control mutant). Specific activity determination of the mutants demonstrated that E83A and D134A lost almost 100% of the catalytic activity. E246A and D263A also decreased SULT1A1 activity, while E151A did not change SULT1A1 catalytic activity significantly. This work demonstrates that carboxyl residues are present in the active site and are important for SULT1A1 catalytic activity. Glu83 and E134 are essential amino acids for SULT1A1 catalytic activity.     

台湾家白蚁内切葡聚糖酶活性中心氨基酸的饱和突变

对内切葡聚糖酶的功能改进一直是纤维素酶研究领域的焦点。本研究对台湾家白蚁内切葡聚糖酶(CfEG)的活性位点做了饱和突变。首先,以PDB数据库中高山象白蚁内切葡聚糖酶(NtEG)的三维结构(PDB id=1ks8)为模板,对CfEG进行三维结构同源建模,二者序列一致性高达79%。位于CfEG活性中心的D53、D56、E411,分别与NtEG的催化残基D54、D57、E412重合。用简并引物对CfEG的假定活性位点D53、D56、E411进行定点饱和突变。在位点D53、D56各筛选到羧甲基纤维素酶活有一定提高的突变子D53E、D56C,其中D56C的Km值减小为原始酶的三分之一。双突变子D53L/D56I的比活比原始酶提高了近2倍,同时Km值减小至原始酶的一半。而E411的饱和突变子库均没有活性,进一步将其替换为近似氨基酸的E411D、E411Q定点突变子也丧失了酶活。由突变结果可推断,位点E411为该酶行使功能的必需残基。     

Improved autoprocessing efficiency of mutant subtilisins E with altered specificity by engineering of the pro-region.

Modification of substrate specificity of an autoprocessing enzyme is accompanied by a risk of significant failure of self-cleavage of the pro-region essential for activation. Therefore, to enhance processing, we engineered the pro-region of mutant subtilisins E of Bacillus subtilis with altered substrate specificity. A high-activity mutant subtilisin E with Ile31Leu replacement (I31L) as well as the wild-type enzyme show poor recognition of acid residues as the P1 substrate. To increase the P1 substrate preference for acid residues, Glu156Gln and Gly166Lys/Arg substitutions were introduced into the I31L gene based upon a report on subtilisin BPN' [Wells et al. (1987) Proc. Natl. Acad. Sci. USA 84, 1219-1223]. The apparent P1 specificity of four mutants (E156Q/G166K, E156Q/G166R, G166K, and G166R) was extended to acid residues, but the halo-forming activity of Escherichia coli expressing the mutant genes on skim milk-containing plates was significantly decreased due to the lower autoprocessing efficiency. A marked increase in active enzyme production occurred when Tyr(-1) in the pro-region of these mutants was then replaced by Asp or Glu. Five mutants with Glu(-2)Ala/Val/Gly or Tyr(-1)Cys/Ser substitution showing enhanced halo-forming activity were further isolated by PCR random mutagenesis in the pro-region of the E156Q/G166K mutant. These results indicated that introduction of an optimum arrangement at the cleavage site in the pro-region is an effective method for obtaining a higher yield of active enzymes.     

A revised mechanism for the inactivation of bovine liver enoyl-CoA hydratase by (methylenecyclopropyl)formyl-CoA based on unexpected results with the C114A mutant

The compound (methylenecyclopropyl)formyl-CoA (MCPF-CoA) has been reported earlier as a potent active site-directed inactivator of bovine liver enoyl-CoA hydratase (ECH). It is believed that the mechanism of inactivation involves the attack of Cys114 at C-2' of MCPF-CoA, resulting in ring cleavage and permanent covalent modification of the enzyme. Here, we describe studies with the C114A mutant of bovine liver ECH, which was constructed and purified to determine the role of this residue in the catalytic mechanism of the enzyme. The C114A mutant, which is catalytically competent, shows an unexpected susceptibility to inactivation by MCPF-CoA, indicating that Cys114 is not the primary nucleophile responsible for the inactivation of the enzyme. To determine if catalytic residues Glu115 and Glu135 play a role in the inactivation of the enzyme, the E115Q and E135Q mutants were also constructed and purified. It was determined that these mutants did not react with MCPF-CoA, indicating a possible role for both residues in the inactivation of the wild-type enzyme. Pepsin digestion and subsequent LC-MS/MS analysis of the inactivated wild-type enzyme and C114A mutant revealed that Glu115 was modified in each case, supporting the hypothesis that this residue is the true nucleophile that traps MCPF-CoA and indicating that the covalent modification of Cys114 reported earlier may be a postinactivation artifact. We propose a modified mechanism of inactivation involving Glu115 and Glu135, and suggest that MCPF-CoA may be a mechanism-based inhibitor for bovine liver ECH.     

Nisin: a possible alternative or adjunct to nitrite in the preservation of meats.

Nisin at 75 ppm (75 microgram/g) was superior to 150 ppm of nitrite in inhibiting outgrowth of Clostridium sporogenes PA3679 spores in meat slurries, which had been heated to simulate the process used for cooked ham. The inhibitory activity of nisin decreased as the spore load or pH of the slurries increased. Unlike nitrite, inhibition by nisin was unaffected by high levels of iron either as a constituent of meats or when added as an iron salt. In slurries treated with 75 ppm of nisin, refrigerated storage for 56 days resulted in depletion of nisin to a level low enough to allow outgrowth within 3 to 10 days if the slurries were subsequently abused at 35 degrees C. In contrast, a combination of 40 ppm of nitrite and either 75 or 100 ppm of nisin almost completely inhibited outgrowth in these slurries. The nisin-nitrite combination appeared to have a synergistic effect, and the low concentration of nitrite was sufficient to preserve the color in meats similar to that of products cured with 150 ppm of nitrite.     

Identification of an amino acid residue involved in the substrate-binding site of rat liver uricase by site-directed mutagenesis.

Computer analysis has shown that a conserved amino acid sequence (Leu 160 to Lys 164) of rat liver uricase is also present in other enzymes with purine substrates. The significances of the amino acids in this sequence were studied by site-directed mutagenesis. Replacement of Lys 164 by Glu or Ile resulted in loss of uricase activity and decrease in binding of the competitive inhibitor xanthine. The far ultraviolet circular dichroic spectra of the mutant uricases were identical to that of the wild type protein, indicating that the replacement of Lys 164 by other amino acids did not result in serious modification of the conformation of uricase. These findings suggest that this amino acid is involved in the substrate-binding site of the enzyme.     

Development and application of a microtiter plate-based autoinduction bioassay for detection of the lantibiotic subtilin

Production of the lantibiotic subtilin in Bacillus subtilis ATCC 6633 is regulated in a quorum sensing-like mechanism with subtilin acting as autoinducer and signal transduction via the subtilin-specific two-component regulation system SpaRK. Here, we report the construction and application of a subtilin reporter strain in which subtilin induced lacZ gene expression in a B. subtilis ATCC 6633 spaS gene deletion mutant is monitored and visualized by the beta-galactosidase in a chromogenic plate assay. A quantitative microtiter plate subtilin bioassay was developed and optimized. Maximal sensitivity of the system was achieved after 6 h of incubation of the reporter strain together with subtilin in a medium containing 300 mM NaCl. This sensitive and unsusceptible method was applied to identify subtilin producing B. subtilis wild type strains from both, culture collections and soil samples. The B. subtilis lantibiotic ericin S with four amino acid exchanges compared to subtilin induces the subtilin reporter strain, in contrast to the structurally closely related Lactococcus lactis lantibiotic nisin. These observations suggest a certain substrate specificity of the histidine kinase SpaK, which however, also would allow the identification of subtilin-isoform producing microorganisms.     

Mutant firefly luciferase enzymes resistant to the inhibition by sodium chloride

Objectives

Firefly luciferase, one of the most extensively studied enzymes, has numerous applications. However, luciferase activity is inhibited by sodium chloride. This study was aimed at obtaining mutant luciferase enzymes resistant to the sodium chloride inhibition.

Results

We first obtained two mutant luciferase enzymes whose inhibition were alleviated and determined the mutations to be Val288Ile and Glu488Val. Under medical dialysis condition (140 mM sodium chloride), the wild type was inhibited to 44% of its original activity level. In contrast, the single mutants, Val288Ile and Glu488Val, retained 67% and 79% of their original activity, respectively. Next, we introduced Val288Ile and Glu488Val mutations into wild-type luciferase to create a double mutant using site-directed mutagenesis. Notably, the double mutant retained its activity more than 95% of that in the absence of sodium chloride.

Conclusions

The mutant luciferase, named luciferase CR, was found to retain its activity in various concentrations of sodium chloride. The luciferase CR may be extensively useful in any bioassay which includes firefly luciferase and is employed in the presence of sodium chloride.

     

Analysis of genes involved in biosynthesis of the lantibiotic subtilin.

Lantibiotics are peptide-derived antibiotics with high antimicrobial activity against pathogenic gram-positive bacteria. They are ribosomally synthesized and posttranslationally modified (N. Schnell, K.-D. Entian, U. Schneider, F. Götz, H. Zähner, R. Kellner, and G. Jung, Nature [London] 333:276-278, 1988). The most important lantibiotics are subtilin and the food preservative nisin, which both have a very similar structure. By using a hybridization probe specific for the structural gene of subtilin, spaS, the DNA region adjacent to spaS was isolated from Bacillus subtilis. Sequence analysis of a 4.9-kb fragment revealed several open reading frames with the same orientation as spaS. Downstream of spaS, no reading frames were present on the isolated XbaI fragment. Upstream of spaS, three reading frames, spaB, spaC, and spaT, were identified which showed strong homology to genes identified near the structural gene of the lantibiotic epidermin. The SpaT protein derived from the spaT sequence was homologous to hemolysin B of Escherichia coli, which indicated its possible function in subtilin transport. Gene deletions within spaB and spaC revealed subtilin-negative mutants, whereas spaT gene disruption mutants still produced subtilin. Remarkably, the spaT mutant colonies revealed a clumpy surface morphology on solid media. After growth on liquid media, spaT mutant cells agglutinated in the mid-logarithmic growth phase, forming longitudinal 3- to 10-fold-enlarged cells which aggregated. Aggregate formation preceded subtilin production and cells lost their viability, possibly as a result of intracellular subtilin accumulation. Our results clearly proved that reading frames spaB and spaC are essential for subtilin biosynthesis whereas spaT mutants are probably deficient in subtilin transport.     

Three residues in the common beta chain of the human GM-CSF, IL-3 and IL-5 receptors are essential for GM-CSF and IL-5 but not IL-3 high affinity binding and interact with Glu21 of GM-CSF.

The beta subunit (beta c) of the receptors for human granulocyte macrophage colony stimulating factor (GM-CSF), interleukin-3 (IL-3) and interleukin-5 (IL-5) is essential for high affinity ligand-binding and signal transduction. An important feature of this subunit is its common nature, being able to interact with GM-CSF, IL-3 and IL-5. Analogous common subunits have also been identified in other receptor systems including gp130 and the IL-2 receptor gamma subunit. It is not clear how common receptor subunits bind multiple ligands. We have used site-directed mutagenesis and binding assays with radiolabelled GM-CSF, IL-3 and IL-5 to identify residues in the beta c subunit involved in affinity conversion for each ligand. Alanine substitutions in the region Tyr365-Ile368 in beta c showed that Tyr365, His367 and Ile368 were required for GM-CSF and IL-5 high affinity binding, whereas Glu366 was unimportant. In contrast, alanine substitutions of these residues only marginally reduced the conversion of IL-3 binding to high affinity by beta c. To identify likely contact points in GM-CSF involved in binding to the 365-368 beta c region we used the GM-CSF mutant eco E21R which is unable to interact with wild-type beta c whilst retaining full GM-CSF receptor alpha chain binding. Eco E21R exhibited greater binding affinity to receptor alpha beta complexes composed of mutant beta chains Y365A, H367A and I368A than to those composed of wild-type beta c or mutant E366A. These results (i) identify the residues Tyr365, His367 and Ile368 as critical for affinity conversion by beta c, (ii) show that high affinity binding of GM-CSF and IL-5 can be dissociated from IL-3 and (iii) suggest that Tyr365, His367 and Ile368 in beta c interact with Glu21 of GM-CSF.     

Intramolecular relationships in cholinesterases revealed by oocyte expression of site-directed and natural variants of human BCHE.

Structure-function relationships of cholinesterases (CHEs) were studied by expressing site-directed and naturally occurring mutants of human butyrylcholinesterase (BCHE) in microinjected Xenopus oocytes. Site-directed mutagenesis of the conserved electronegative Glu441,Ile442,Glu443 domain to Gly441,Ile442,Gln443 drastically reduced the rate of butyrylthiocholine (BTCh) hydrolysis and caused pronounced resistance to dibucaine binding. These findings implicate the charged Glu441,Ile442,Glu443 domain as necessary for a functional CHE catalytic triad as well as for binding quinoline derivatives. Asp70 to Gly substitution characteristic of 'atypical' BCHE, failed to alter its Km towards BTCh or dibucaine binding but reduced hydrolytic activity to 25% of control. Normal hydrolytic activity was restored to Gly70 BCHE by additional His114 or Tyr561 mutations, both of which co-appear with Gly70 in natural BCHE variants, which implies a likely selection advantage for these double BCHE mutants over the single Gly70 BCHE variant. Gly70 BCHE variants also displayed lower binding as compared with Asp70 BCHE to cholinergic drugs, certain choline esters and solanidine. These effects were ameliorated in part by additional mutations or in binding solanidine complexed with sugar residues. These observations indicate that structural interactions exist between N' and C' terminal domains in CHEs which contribute to substrate and inhibitor binding and suggest a crucial involvement of both electrostatic and hydrophobic domains in the build-up of the CHE active center.     

Mutation of an essential glutamate residue in folylpolyglutamate synthetase and activation of the enzyme by pteroate binding

Site-directed mutagenesis was performed on Glu143, an essential amino acid in Lactobacillus casei folylpolyglutamate synthetase (FPGS) and the structurally equivalent residue, Glu146, in Escherichia coli FPGS. Glu143 is positioned near the P-loop and interacts with the Mg(2+) of Mg NTP-binding proteins. We have solved the structure of the E143A mutant of L. casei FPGS in the presence of AMPPCP and Mg(2+). The structure showed a water molecule at the place where Mg(2+) bound to the wild type enzyme. Mutant proteins E143A, and even E143D and E143Q with conservative mutations, lacked enzyme activity and failed to complement the methionine auxotrophy of the E. coli folC mutant SF4, showing that Glu143 is an essential residue. Both the L. casei and the E. coli FPGS mutant proteins bound methylene-tetrahydrofolate diglutamate and dihydropteroate normally. The E. coli E146Q mutant FPGS bound ADP with the same affinity as the wild type enzyme but bound ATP with much lower affinity and had higher ATPase activity than the wild type enzyme. The mutant enzyme was defective in forming the acyl-phosphate reaction intermediate from ATP and dihydropteroate. The E. coli FPGS requires activation by dihydropteroate or tetrahydrofolate binding to allow full activity. In the absence of a pteroate substrate, only 30% of the total enzyme binds ATP. We suggest that dihydropteroate causes a conformational change to allow increased ATP binding. The mutant enzyme was similarly activated by dihydropteroate resulting in increased ADP binding.     

The effect of nisin-sodium chloride interactions on the outgrowth of Bacillus licheniformis spores

The effect of salt (NaCl) on the efficacy of nisin in preventing outgrowth of Bacillus licheniformis spores was determined in Plate Count Agar (PCA). An equivalent liquid medium was used for heat activation. Nisin and salt were added to the heat-activation medium, the PCA, or both. The spores were extremely sensitive to nisin; outgrowth were completely inhibited in salt-free media when 10 iu/ml of nisin was present in both the heat-activation and the growth media or when 100 iu/ml nisin was present in either the heat-activation and the growth medium. In media supplemented with 1% salt, outgrowth occurred from 1% of spores exposed to 100 iu/ml nisin in either the heat-activation or the growth medium. A 3% salt supplement was necessary before detectable outgrowth occurred when both the heat-activation and the growth media contained 100 iu/ml nisin. Salt appears to antagonize the sporicidal action of nisin by interfering with nisin adsorption onto the spore.     

Conversion of Bacillus subtilis 168 to a subtilin producer by competence transformation.

Subtilin is a ribosomally synthesized peptide antibiotic produced by Bacillus subtilis ATCC 6633. B. subtilis 168 was converted to a subtilin producer by competence transformation with chromosomal DNA from B. subtilis ATCC 6633. A chloramphenicol acetyltransferase gene was inserted next to the subtilin structural gene as a selectable marker. The genes that conferred subtilin production were derived from a 40-kb region of the B. subtilis ATCC 6633 chromosome that had flanking homologies to the B. subtilis 168 chromosome. The subtilin produced by the mutant was identical to natural subtilin in its biological activity, chromatographic behavior, amino acid composition, and N-terminal amino acid sequence.     

Computer-aided design of the stability of pyruvate formate-lyase from Escherichia coli by site-directed mutagenesis

Using computer-aided design of single-site mutations, three amino acid residues determined by changes in folding free energy between wild-type (wt) and mutant proteins were exchanged to enhance the stability of pyruvate formate-lyase (PFL). The mutant enzymes were tested for properties such as optimum temperature, optimum pH, kinetic parameters, and stability to temperature. There were two mutant variants, Glu336Cys and Glu400Ile, that exhibited increased thermostability as compared to the wt enzyme. The melting temperatures (T(m), the temperature at which 50% inactivation occurs after heat treatment for 20 min) of Glu336Cys and Glu400Ile increased by 3.7 and 2.2 respectively. They also showed an increase in half life of about 1.80 and 2.21-fold, whereas Ala273Cys showed a slight decrease as compared with the wt enzyme.