Cloning and nucleotide sequence of the N-acetylmuramidase M1-encoding gene from Streptomyces globisporus

Ruminococcoides bili gen. nov., sp. nov., a bile-resistant bacterium from human bile with autolytic behavior

A strictly anaerobic, resistant starch-degrading, bile-tolerant, autolytic strain, IPLA60002^T, belonging to the family Ruminococcaceae, was isolated from a human bile sample of a liver donor without hepatobiliary disease. Cells were Gram-stain-positive cocci, and 16S rRNA gene and whole genome analyses showed that Ruminococcus bromii was the phylogenetically closest related species to the novel strain IPLA60002^T, though with average nucleotide identity values below 90 %. Biochemically, the new isolate has metabolic features similar to those described previously for gut R. bromii strains, including the ability to degrade a range of different starches. The new isolate, however, produces lactate and shows distinct resistance to the presence of bile salts. Additionally, the novel bile isolate displays an autolytic phenotype after growing in different media. Strain IPLA60002^T is phylogenetically distinct from other species within the genus Ruminococcus. Therefore, we propose on the basis of phylogenetic, genomic and metabolic data that the novel IPLA60002^T strain isolated from human bile be given the name Ruminococcoides bili gen. nov., sp. nov., within the new proposed genus Ruminococcoides and the family Ruminococcaceae. Strain IPLA60002^T (=DSM 110008^T=LMG 31505^T) is proposed as the type strain of Ruminococcoides bili.

Evidence of a bacterial receptor for lysozyme: binding of lysozyme to the anti-σ factor RsiV controls activation of the ecf σ factor σV

σ factors endow RNA polymerase with promoter specificity in bacteria. Extra-Cytoplasmic Function (ECF) σ factors represent the largest and most diverse family of σ factors. Most ECF σ factors must be activated in response to an external signal. One mechanism of activation is the stepwise proteolytic destruction of an anti-σ factor via Regulated Intramembrane Proteolysis (RIP). In most cases, the site-1 protease required to initiate the RIP process directly senses the signal. Here we report a new mechanism in which the anti-σ factor rather than the site-1 protease is the sensor. We provide evidence suggesting that the anti-σ factor RsiV is the bacterial receptor for the innate immune defense enzyme, lysozyme. The site-1 cleavage site is similar to the recognition site of signal peptidase and cleavage at this site is required for σ^V activation in Bacillus subtilis. We reconstitute site-1 cleavage in vitro and demonstrate that it requires both signal peptidase and lysozyme. We demonstrate that the anti-σ factor RsiV directly binds to lysozyme and muramidase activity is not required for σ^V activation. We propose a model in which the binding of lysozyme to RsiV activates RsiV for signal peptidase cleavage at site-1, initiating proteolytic destruction of RsiV and activation of σ^V. This suggests a novel mechanism in which conformational change in a substrate controls the cleavage susceptibility for signal peptidase. Thus, unlike other ECF σ factors which require regulated intramembrane proteolysis for activation, the sensor for σ^V activation is not the site-1 protease but the anti-σ factor.

All cells sense and respond to changes in their environments by transmitting information across the membrane. In bacteria, σ factors provide promoter specificity to RNA polymerase. Bacteria encode Extra-Cytoplasmic Function (ECF) σ factors, which often respond to extracellular signals. Activation of some ECF σ factors is controlled by stepwise proteolytic destruction of an anti-σ factor which is initiated by a site-1 protease. In most cases, the site-1 protease required to initiate the RIP process is thought to be the signal sensor. Here we report that the anti-σ factor RsiV, and not the site-1 protease, is the sensor for σ^V activation. Activation of the ECF σ factor σ^V is induced by lysozyme, an innate immune defense enzyme. We identify the site-1 protease as signal peptidase, which is required for general protein secretion. The anti-σ factor RsiV directly binds lysozyme. Binding of lysozyme to RsiV allows signal peptidase to cleave RsiV at site-1 and this leads to activation of σ^V. Thus, the anti-σ factor functions as a bacterial receptor for lysozyme. RsiV homologs from C. difficile and E. faecalis also bind lysozyme, suggesting they may utilize this receptor-ligand mechanism to control activation of σ^V to induce lysozyme resistance.

A lytic enzyme cocktail from Streptomyces sp. B578 for the control of lactic and acetic acid bacteria in wine

Beside yeasts, lactic acid bacteria (LAB) are the most abundant microbes in must during vinification. Whereas Oenococcos oeni is commercially used as a starter culture for the biological acid reduction in wines, other species are responsible for different types of wine spoilage. Members of the genera Pediococcus, Weissella, Leuconostoc, and Lactobacillus are producers of exopolysaccharide slimes, biogenic amines, acetic acid, and other off-flavors. In order to control microbial growth, different procedures such as heating of must and addition of sulfite or lysozyme from egg white are generally applied. Yet, because of health risks, the application of sulfite should be reduced and lysozyme is not effective against all LAB. In this study, we describe exoenzymes from a Streptomyces sp. strain B578 lysing nearly all wine-relevant strains of LAB and Gram-negative acetic acid bacteria. The lytic enzymes were active under wine-making conditions, such as the presence of sulfite and ethanol, low temperatures, and low pH values. The analysis of the exoenzyme composition revealed a synergistic action of different cell wall hydrolases. In conclusion, the lytic cocktail of Streptomyces sp. B578 is a promising tool for the control of wine-spoiling bacteria.

Mapping and comprehensive analysis of the extracellular and cell surface proteome of the human pathogen Corynebacterium diphtheriae

Secreted proteins of the human pathogen Corynebacterium diphtheriae might be involved in important pathogen-host cell interactions. Here, we present the first systematic reference map of the extracellular and cell surface proteome fractions of the type strain C. diphtheriae C7s(-)tox-. The analysis window of 2-DE covered the pI range from 3 to 10 along with a MW range from 8 to 150 kDa. Computational analysis of the 2-D gels detected almost 150 protein spots in the extracellular proteome fraction and about 80 protein spots of the cell surface proteome. MALDI-TOF-MS and PMF with trypsin unambiguously identified 107 extracellular protein spots and 53 protein spots of the cell surface, representing in total 85 different proteins of C. diphtheriae C7s(-)tox-. Several of the identified proteins are encoded by pathogenicity islands and might represent virulence factors of C. diphtheriae. Additionally, four solute-binding proteins (HmuT, Irp6A, CiuA, and FrgD) of different iron ABC transporters were identified, with the hitherto uncharacterized FrgD protein being the most abundant one of the cell surface proteome of C. diphtheriae C7s(-)tox-.

Cloning and expression of the N-acetylmuramidase gene from Streptomyces rutgersensis H-46

The N-acetylmuramidase SR1 gene from Streptomyces rutgersensis H-46 was cloned in Escherichia coli JM109 and expressed in E. coli BL21(DE3)pLysS. An open reading frame included the leader peptide region encoding a polypeptide of 65 amino acid residues and the mature SR1 enzyme region encoding a polypeptide of 209 amino acid residues. The overall G + C content of the mature enzyme gene was 67.6%, with 98.1% of G or C in the third position of the codons. The calculated molecular weight of the mature enzyme was 23,057 Da. The amino acid sequence of the mature enzyme showed a significant level of identity with bacteriolytic enzymes from Streptomyces globisporus (50.9% identity), Chalaropsis species (40.2% identity) and Saccharopolyspora erythraea (31.0% identity). The mature enzyme gene cloned into plasmid pET26b carrying a signal peptide, peIB, was expressed in E. coli BL21(DE3)pLysS. The signal peptide region was cleaved during the production of the enzyme. Specific activity of the enzyme purified from the transformant was almost identical to that of the native enzyme. Furthermore, the SR1 enzyme gene cloned with the leader peptide gene into plasmid pET28a was also expressed in E. coli. In this case, a proform-like protein was partially processed; 35 amino acid residues were cleaved but 30 amino acid residues remained. This proform like protein has approximately one-nineteenth the activity of the native enzyme. These results indicated that the native SR1 enzyme was produced in the following manner in the cells of S. rutgersensis H-46. The SR1 enzyme gene was translated to a pre-proform protein followed by the deletion of a signal peptide. Finally, the proform-like protein was processed by deletion of the remaining leader peptide.

Identification and characterization of an endolysin encoded by the Streptomyces aureofaciens phage mu 1/6

An open reading frame homologous to the genes encoding several cell-wall hydrolyzing enzymes was identified on the genome of actinophage mu 1/6. This open reading frame encoding the putative endolysin was amplified by polymerase chain reaction and cloned into the expression vector pET-21a. This gene consisted of 1182 bp encoding a 393 amino acid polypeptide with a molar mass of 42.1 kDa. The gene product was overexpressed in Escherichia coli, and then the lytic enzyme was purified by a two-step chromatographic procedure. When applied exogenously, the endolysin of phage mu 1/6 was active against all tested Streptomyces strains but did not affect other bacteria. The amino acid sequence showed a high homology with a putative amidase of the Streptomyces phase phi C31. Downstream of the endolysin gene, an open reading frame encoding an 88 amino acid protein was identified. Structural analysis of its sequence revealed features characteristics for holin.

Molecular cloning, expression and evolution of the Japanese flounder goose-type lysozyme gene, and the lytic activity of its recombinant protein

In this study, we cloned the goose-type (g-type) lysozyme gene from the Japanese flounder genomic DNA library, the first such data in fish and only the second after the chicken g-type lysozyme gene. The Japanese flounder g-type lysozyme gene was 1252 bp in length from the transcription site to the polyadenylation site, coded for 758 bp of mRNA and 195 deduced amino acids, which contain five exons and four introns. A phylogenetic analysis based on amino acid sequences showed that the flounder gene was closer to g-type lysozyme, followed by phage-type lysozyme and then chicken-type (c-type) lysozyme. Although exon 1 of the flounder gene differs from exons 1 and 2 of the chicken g-type lysozyme gene, three catalytic residues, as well as their neighboring amino acids were conserved between the Japanese flounder and the four avian g-type lysozymes. In a Southern blot analysis using the genomic DNA of homo-cloned Japanese flounder, the flounder g-type lysozyme gene showed a simple pattern, suggesting that it is encoded by a single copy gene. A Northern blot analysis showed that this gene was expressed in all tissues of Japanese flounder that we examined in this study and showed major differences from those expressed tissues of the chicken g-type gene. Japanese flounder g-type lysozyme mRNA levels in the intestine, heart and whole blood increased after injecting the fish with Edwardsiella tarda. Recombinant flounder g-type lysozyme, which has an optimal pH and temperature of pH 6.0 and 25 degrees C, possessed lytic activity against Micrococcus lysodeikticus and several fish pathogenic bacteria. This is the first report of a g-type lysozyme gene other than for reported avian species.

Cloning of genomic DNA of Lactococcus lactis that restores phage sensitivity to an unusual bacteriophage sk1-resistant mutant

An unusual, spontaneous, phage sk1-resistant mutant (RMSK1/1) of Lactococcus lactis C2 apparently blocks phage DNA entry into the host. Although no visible plaques formed on RMSK1/1, this host propagated phage at a reduced efficiency. This was evident from center-of-infection experiments, which showed that 21% of infected RMSK1/1 formed plaques when plated on its phage-sensitive parental strain, C2. Moreover, viable cell counts 0 and 4 h after infection were not significantly different from those of an uninfected culture. Further characterization showed that phage adsorption was normal, but burst size was reduced fivefold and the latent period was increased from 28.5 to 36 min. RMSK1/1 was resistant to other, but not all, similar phages. Phage sensitivity was restored to RMSK1/1 by transformation with a cloned DNA fragment from a genomic library of a phage-sensitive strain. Characterization of the DNA that restored phage sensitivity revealed an open reading frame with similarity to sequences encoding lysozymes (beta-1,4-N-acetylmuramidase) and lysins from various bacteria, a fungus, and phages of Lactobacillus and Streptococcus and also revealed DNA homologous to noncoding sequences of temperate phage of L. lactis, DNA similar to a region of phage sk1, a gene with similarity to tRNA genes, a prophage attachment site, and open reading frames with similarities to sun and to sequences encoding phosphoprotein phosphatases and protein kinases. Mutational analyses of the cloned DNA showed that the region of homology with lactococcal temperate phage was responsible for restoring the phage-sensitive phenotype. The region of homology with DNA of lactococcal temperate phage was similar to DNA from a previously characterized lactococcal phage that suppresses an abortive infection mechanism of phage resistance. The region of homology with lactococcal temperate phage was deleted from a phage-sensitive strain, but the strain was not phage resistant. The results suggest that the cloned DNA with homology to lactococcal temperate phage was not mutated in the phage-resistant strain. The cloned DNA apparently suppressed the mechanism of resistance, and it may do so by mimicking a region of phage DNA that interacts with components of the resistance mechanism.

Inactivated pbp4 in highly glycopeptide-resistant laboratory mutants of Staphylococcus aureus

Both vancomycin- and teicoplanin-resistant laboratory mutants of Staphylococcus aureus produce peptidoglycans of altered composition in which the proportion of highly cross-linked muropeptide species is drastically reduced with a parallel increase in the representation of muropeptide monomers and dimers (Sieradzki, K., and Tomasz, A. (1997) J. Bacteriol. 179, 2557-2566; and Sieradzki, K. , and Tomasz, A. (1998) Microb. Drug Resist. 4, 159-168). We now report that the distorted peptidoglycan composition is related to defects in penicillin-binding protein 4 (PBP4); no PBP4 was detectable by the fluorographic assay in membrane preparations from the mutants, and comparison of the sequence of pbp4 amplified from the mutants indicated disruption of the gene by two types of abnormalities, a 17-amino acid long duplication starting at position 305 of the pbp4 gene was detected in the vancomycin-resistant mutant, and a stop codon was found to be introduced into the pbp4 KTG motif at position 261 in the mutant selected for teicoplanin resistance. Additional common patterns of disturbances in the peptidoglycan metabolism of the mutants are indicated by the increased sensitivity of mutant cell walls to the M1 muramidase and decreased sensitivity to lysostaphin, which is a reversal of the susceptibility pattern of the parental cell walls. Furthermore, the results of high performance liquid chromatography analysis of lysostaphin digests of peptidoglycan suggest an increase in the average chain length of the glycan strands in the peptidoglycan of the glycopeptide-resistant mutants. The increased molar proportion of muropeptide monomers in the cell wall of the glycopeptide-resistant mutants should provide binding sites for the "capture" of vancomycin and teicoplanin molecules, which may be part of the mechanism of glycopeptide resistance in S. aureus.

Nucleotide sequence of the ermE distal flank of the erythromycin biosynthesis cluster in Saccharopolyspora erythraea

A 7023 nucleotide BamHI fragment immediately upstream of the eryK gene of the erythromycin (Er) biosynthesis cluster in Saccharopolyspora erythraea was sequenced. Computer-assisted analysis of this sequence reveals the existence of seven ORFs that display the codon preferences typical of actinomycete genes. Six of these show homology to known genes: an esterase, a transposase, a peptidyl-prolyl cis-trans isomerase, a subtilisin inhibitor-like protein, and two genes involved in bacterial cell wall biosynthesis. All the ORFs are transcribed toward the Er biosynthetic gene cluster (in the same direction as eryK). From the predicted functions of the putative ORF products none of these genes appear to be involved in the biosynthesis of Er. The eryK gene thus most likely defines one end of the Er biosynthetic gene cluster.

Molecular characterization of a germination-specific muramidase from Clostridium perfringens S40 spores and nucleotide sequence of the corresponding gene

The exudate of fully germinated spores of Clostridium perfringens S40 in 0.15 M KCI-50 mM potassium phosphate (pH 7.0) was found to contain another spore-lytic enzyme in addition to the germination-specific amidase previously characterized (S. Miyata, R. Moriyama, N. Miyahara, and S. Makino, Microbiology 141:2643-2650, 1995). The lytic enzyme was purified to homogeneity by anion-exchange chromatography and shown to be a muramidase which requires divalent cations (Ca2+, Mg2+, or Mn2+) for its activity. The enzyme was inactivated by sulfhydryl reagents, and sodium thioglycolate reversed the inactivation by Hg2+. The muramidase hydrolyzed isolated spore cortical fragments from a variety of wild-type organisms but had minimal activity on decoated spores and isolated cell walls. However, the enzyme was not capable of digesting isolated cortical fragments from spores of Bacillus subtilis ADD1, which lacks muramic acid delta-lactam in its cortical peptidoglycan. This indicates that the enzyme recognizes the delta-lactam residue peculiar to spore peptidoglycan, suggesting an involvement of the enzyme in spore germination. Immunochemical studies indicated that the muramidase in its mature form is localized on the exterior of the cortex layer in the dormant spore. A gene encoding the muramidase, sleM, was cloned into Escherichia coli, and the nucleotide sequence was determined. The gene encoded a protein of 321 amino acids with a deduced molecular weight of 36,358. The deduced amino acid sequence of the sleM gene indicated that the enzyme is produced in a mature form. It was suggested that the muramidase belongs to a separate group within the lysozyme family typified by the fungus Chalaropsis lysozyme. A possible mechanism for cortex degradation in C. perfringens S40 spores is discussed.

Phage lysozymes

Bacteriophage genomes encode lysozymes whose role is to favour the release of virions by lysis of the host cells or to facilitate infection. In this review, the evolutionary relationships between the phage lysozymes are described. They are grouped into several classes: the V-, the G-, the lambda- and the CH-type lysozymes. The results of structure determinations and of enzymological studies indicate that the enzymes belonging to the first two classes, and possibly the third, share common structural elements with C-type lysozymes (eg. hen egg white lysozyme). The proteins of the fourth class, on the other hand, are structurally similar to the S. erythraeus lysozyme. Several phage lysozymes feature a modular construction: besides the catalytic domain, they contain additional domains or repeated motifs presumed to be important for binding to the bacterial walls and for efficient catalysis. The mechanism of action of these enzymes is described and the role of the important amino acid residues is discussed on the basis of sequence comparisons and of mutational studies. The effects of mutations affecting the structure and of multiple mutations are also discussed, particularly in the case of the T4 lysozyme: from these studies, proteins appear to be quite tolerant of potentially disturbing modifications.

Bacterial lysozymes

Lysozymes are found in many bacteria that are surrounded by a murein-(peptidoglycan) containing cell wall. Their physiological function for the bacteria is still a matter of debate. On the one hand they can autolyse the cell, on the other hand they may have an essential role during enlargement and division of the cell wall by the controlled splitting of bonds in the murein sacculus. Both beta-1.4-N,6-O-diacetylmuramidase and beta-1.4-N-acetylmuramidases have been described in bacteria. In some cases a modular design of the enzyme has been demonstrated with a catalytic domain and a substrate (murein)-binding and recognition domain consisting of repeated motifs.

Genetic and biochemical characterization of the Lactobacillus delbrueckii subsp. lactis bacteriophage LL-H lysin

LL-H, a virulent phage of Lactobacillus delbrueckii subsp. lactis, produces a peptidoglycan-degrading enzyme, Mur, that is effective on L. delbrueckii, Lactobacillus acidophilus, Lactobacillus helveticus, and Pediococcus damnosus cell walls. In this study, the LL-H gene mur was cloned into Escherichia coli, its nucleotide sequence was determined, and the enzyme produced in E. coli was purified and biochemically characterized. Mur was purified 112-fold by means of ammonium sulfate precipitation and cation-exchange chromatography. The cell wall-hydrolyzing activity was found to be associated with a 34-kDa protein. The C-terminal domain of Mur is not essential for catalytic activity since it can be removed without destroying the lytic activity. The N-terminal sequence of the purified lysin was identical to that deduced from the nucleotide sequence, but the first methionine is absent from the mature protein. The N-terminal part of this 297-amino-acid protein had homology with several Chalaropsis-type lysozymes. Reduction of purified and Mur-digested L. delbrueckii cell wall material with labeled NaB3H4 indicated that the enzyme is a muramidase. The temperature optimum of purified Mur is between 30 and 40 degrees C, and the pH optimum is around 5.0. The LL-H lysin Mur is stable at temperatures below 60 degrees C.

Purification and molecular cloning of a major antibacterial protein of the protozoan parasite Entamoeba histolytica with lysozyme-like properties

A protein with potent antibacterial activity was purified to apparent homogeneity from pathogenic Entamoeba histolytica. It resembles lysozyme in that it is a basic protein which degrades cell walls of Micrococcus luteus, displays optimal activity at acidic pH, and shows a preference for Gram-positive bacteria. The protein has a molecular mass of approximately 23 kDa upon SDS/PAGE and is localized inside the cytoplasmic granules of the amoebae. The primary structure was elucidated by protein analysis and molecular cloning of the corresponding cDNA. It yielded a protein of 198 residues with structural similarity to the distinct class of lysozymes found in Streptomyces species and the fungus Chalaropsis.

Primary structure and functional analysis of the lysis genes of Lactobacillus gasseri bacteriophage phi adh

The lysis genes of the Lactobacillus gasseri bacteriophage phi adh were isolated by complementation of a lambda Sam mutation in Escherichia coli. Nucleotide sequencing of a 1,735-bp DNA fragment revealed two adjacent coding regions of 342 bp (hol) and 951 bp (lys) in the same reading frame which appear to belong to a common transcriptional unit. Proteins corresponding to the predicted gene products, holin (12.9 kDa) and lysin (34.7 kDa), were identified by in vitro and in vivo expression of the cloned genes. The phi adh holin is a membrane-bound protein with structural similarity to lysis proteins of other phage, known to be required for the transit of murein hydrolases through the cytoplasmic membrane. The phi adh lysin shows homology with mureinolytic enzymes encoded by the Lactobacillus bulgaricus phage mv4, the Streptococcus pneumoniae phage Cp-1, Cp-7, and Cp-9, and the Lactococcus lactis phage phi LC3. Significant homology with the N termini of known muramidases suggests that phi adh lysin acts by a similar catalytic mechanism. In E. coli, the phi adh lysin seems to be associated with the total membrane fraction, from which it can be extracted with lauryl sarcosinate. Either one of the phi adh lysis proteins provoked lysis of E. coli when expressed along with holins or lysins of phage lambda or Bacillus subtilis phage phi 29. Concomitant expression of the combined holin and lysin functions of phi adh in E. coli, however, did not result in efficient cell lysis.

Production of Bacteriolytic Enzymes by Streptomyces globisporus Regulated by Exogenous Bacterial Cell Walls

Mutanolysin biosynthesis and pigment production in Streptomyces globisporus ATCC 21553 were stimulated by adding bacterial cell walls to the medium. The increased bacteriolytic activity in the supernatant correlated with an increased de novo synthesis of mutanolysin and was between 4- and 20-fold higher than in cultures grown without bacterial cell walls. The increase in mutanolysin synthesis was brought about by enhanced transcription of the mutanolysin gene. The stimulation was only observed in medium which contained dextrin or starch as the carbon source. Glucose abolished the stimulation and also inhibited the low constitutive synthesis of mutanolysin. The induction of lytic activity was observed to require minimally 0.4 mg of bacterial cell walls per ml, whereas 0.6 mg of bacterial cell walls per ml yielded maximal lytic activity. Further supplements of bacterial cell walls did not result in enhanced lytic activity. The stimulation could be achieved independently of the phase of growth of the Streptomyces strain. Cultures grown in the presence of bacterial cell walls exhibited a higher growth yield. However, the accelerated growth was not the reason for the increased amount of mutanolysin produced. The growth of cultures with peptidoglycan monomers added to the medium instead of cell walls was similarly increased, but an effect on the biosynthesis of mutanolysin was not observed. All bacterial cell walls tested were capable of eliciting the stimulation of lytic activity, including cell walls of archaea, which contained pseudomurein.

Cloning and characterization of a gene encoding extracellular metalloprotease from Streptomyces lividans

The prt gene, encoding a protease (Prt) from Streptomyces lividans TK24, was cloned and sequenced. An S. lividans host with plasmid-borne prt secreted 200 micrograms/ml of a 22-kDa Prt into the culture medium. Prt is classified as a metalloprotease since its activity is significantly inhibited by 1,10-phenanthroline or EDTA. The region upstream from prt codes for an incomplete open reading frame (ORF) oriented opposite to prt. This ORF has a strong similarity to a gene family (lysR) whose members regulate the transcription of structural genes required for either biosynthesis or degradation.

A classification of glycosyl hydrolases based on amino acid sequence similarities

The amino acid sequences of 301 glycosyl hydrolases and related enzymes have been compared. A total of 291 sequences corresponding to 39 EC entries could be classified into 35 families. Only ten sequences (less than 5% of the sample) could not be assigned to any family. With the sequences available for this analysis, 18 families were found to be monospecific (containing only one EC number) and 17 were found to be polyspecific (containing at least two EC numbers). Implications on the folding characteristics and mechanism of action of these enzymes and on the evolution of carbohydrate metabolism are discussed. With the steady increase in sequence and structural data, it is suggested that the enzyme classification system should perhaps be revised.

Sequence of the lyc gene encoding the autolytic lysozyme of Clostridium acetobutylicum ATCC824: comparison with other lytic enzymes

The lyc gene, encoding an autolytic lysozyme from Clostridium acetobutylicum ATCC824, has been cloned. The nucleotide sequence of the lyc gene has been determined and found to encode a protein of 324 amino acids (aa) with a deduced Mr of 34,939. The lyc gene is preceded by two open reading frames with unknown functions, suggesting that this gene is part of an operon. Comparison between the deduced aa sequence of the lyc gene and the directly determined N-terminal sequence of the extracellular clostridial lysozyme suggests that the enzyme is synthesized without a cleavable signal peptide. Moreover, the comparative analyses between the clostridial lysozyme and other known cell-wall lytic enzymes revealed a significant similarity with the N-terminal portion of the lysozymes of Streptomyces globisporus, the fungus Chalaropsis, the Lactobacillus bulgaricus bacteriophage mv1, and the Streptococcus pneumoniae bacteriophages of the Cp family (CPL lysozymes). In addition, the analyses showed that the C-terminal half of the clostridial lysozyme was homologous to the N-terminal domain of the muramoyl-pentapeptide-carboxypeptidase of Streptomyces albus, suggesting a role in substrate binding. The existence of five putative repeated motifs in the C-terminal region of the autolytic lysozyme suggests that this region could play a role in the recognition of the polymeric substrate.

Increased yield of a lysozyme after self-cloning of the gene in Streptomyces coelicolor "Müller"

Streptomyces coelicolor "Müller" DSM3030 excretes a lysozyme comprising both beta-1,4-N-acetyl- and beta-1,4-N,6-O-diacetyl muramidase activities. The lysozyme is named Cellosyl. Gene libraries have been established using genomic DNA from the wild-type strain, S. coelicolor DSM3030, and from an overproducing mutant, S. coelicolor HP1, which exhibits about a twofold increase in lysozyme production. The lysozyme-encoding genes (cel) from both strains were detected by oligodeoxynucleotide hybridization. The nucleotide sequence of the cel genes isolated from both strains was shown to be identical. The different levels of lysozyme production could not be correlated with any mutations at the cel gene locus. The cel gene isolated from the wild-type strain could not be expressed in some other species of Streptomyces. However, self-cloning of the cel gene into S. coelicolor DSM3030 and HP1 resulted in a 2.5-fold increase in lysozyme production.