Resistance to bacteriocins produced by Gram-positive bacteria.

Bacteriocins are prokaryotic proteins or peptides with antimicrobial activity. Most of them exhibit a broad spectrum of activity, inhibiting micro-organisms belonging to different genera and species, including many bacterial pathogens which cause human, animal or plant infections. Therefore, these substances have potential biotechnological applications in either food preservation or prevention and control of bacterial infectious diseases. However, there is concern that continuous exposure of bacteria to bacteriocins may select cells resistant to them, as observed for conventional antimicrobials. Based on the models already investigated, bacteriocin resistance may be either innate or acquired and seems to be a complex phenomenon, arising at different frequencies (generally from 10(-9) to 10(-2)) and by different mechanisms, even amongst strains of the same bacterial species. In the present review, we discuss the prevalence, development and molecular mechanisms involved in resistance to bacteriocins produced by Gram-positive bacteria. These mechanisms generally involve changes in the bacterial cell envelope, which result in (i) reduction or loss of bacteriocin binding or insertion, (ii) bacteriocin sequestering, (iii) bacteriocin efflux pumping (export) and (iv) bacteriocin degradation, amongst others. Strategies that can be used to overcome this resistance are also addressed.

The gene cluster of aureocyclicin 4185: the first cyclic bacteriocin of Staphylococcus aureus.

Staphylococcus aureus 4185 was previously shown to produce at least two bacteriocins. One of them is encoded by pRJ101. To detect the bacteriocin-encoding gene cluster, an ~9160 kb region of pRJ101 was sequenced. In silico analyses identified 10 genes (aclX, aclB, aclI, aclT, aclC, aclD, aclA, aclF, aclG and aclH) that might be involved in the production of a novel cyclic bacteriocin named aureocyclicin 4185. The organization of these genes was quite similar to that of the gene cluster responsible for carnocyclin A production and immunity. Four putative proteins encoded by these genes (AclT, AclC, AclD and AclA) also exhibited similarity to proteins encoded by cyclic bacteriocin gene clusters. Mutants derived from insertion of Tn917-lac into aclC, aclF, aclH and aclX were affected in bacteriocin production and growth. AclX is a 205 aa putative protein not encoded by the gene clusters of other cyclic bacteriocins. AclX exhibits 50 % similarity to a permease and has five putative membrane-spanning domains. Transcription analyses suggested that aclX is part of the aureocyclicin 4185 gene cluster, encoding a protein required for bacteriocin production. The aclA gene is the structural gene of aureocyclicin 4185, which shows 65 % similarity to garvicin ML. AclA is proposed to be cleaved off, generating a mature peptide with a predicted Mr of 5607 Da (60 aa). By homology modelling, AclA presents four α-helices, like carnocyclin A. AclA could not be found at detectable levels in the culture supernatant of a strain carrying only pRJ101. To our knowledge, this is the first report of a cyclic bacteriocin gene cluster in the genus Staphylococcus.

Genes involved in immunity to and secretion of aureocin A53, an atypical class II bacteriocin produced by Staphylococcus aureus A53.

Aureocin A53 is an antimicrobial peptide produced by Staphylococcus aureus A53. The genetic determinants involved in aureocin A53 production and immunity to its action are organized in at least four transcriptional units encoded by the 10.4-kb plasmid pRJ9. One transcriptional unit carries only the bacteriocin structural gene, aucA. No immunity gene is found downstream of aucA, as part of the same transcriptional unit. Further downstream of aucA is found an operon which contains the three genes aucEFG, whose products seem to associate to form a dedicated ABC transporter. When aucEFG were expressed in RN4220, an aureocin A53-sensitive S. aureus strain, this strain became partially resistant to the bacteriocin. A gene disruption mutant in aucE was defective in aureocin A53 externalization and more sensitive to aureocin A53 than the wild-type strain, showing that aucEFG are involved in immunity to aureocin A53 by active extrusion of the bacteriocin. Full resistance to aureocin A53 was exhibited by transformants carrying, besides aucEFG, the operon formed by two genes, aucIB and aucIA, located between aucA and aucEFG and carried in the opposite strand. AucIA and AucIB share similarities with hypothetical proteins not found in the gene clusters of other bacteriocins. A gene disruption mutant in orf8, located upstream of aucA and whose product exhibits about 50% similarity to a number of hypothetical membrane proteins found in many Gram-positive bacteria, was strongly affected in aureocin A53 externalization but resistant to aureocin A53, suggesting that Orf8 is also involved in aureocin A53 secretion.

clpB, a class III heat-shock gene regulated by CtsR, is involved in thermotolerance and virulence of Enterococcus faecalis.

Here, we transcriptionally and phenotypically characterized the clpB gene from Enterococcus faecalis. Northern blot analysis identified a monocistronic mRNA strongly induced at 48 and 50 °C. In silico analysis identified that the clpB gene encodes a protein of 868 aa with a predicted molecular mass of approximately 98 kDa, presenting two conserved ATP-binding domains. Sequence analysis also identified a CtsR-binding box upstream of the putative -10 sequence, and inactivation of the ctsR gene resulted in an approximately 2-log increase in clpB mRNA expression, confirming ClpB as a member of the CtsR regulon. While expression of clpB was induced by heat stress, a ΔclpB strain grew relatively well under many different stressful conditions, including elevated temperatures. However, expression of ClpB appears to play a major role in induced thermotolerance and in pathogenesis, as assessed by using the Galleria mellonella virulence model.

Characterization of Enterococcus faecium E86 bacteriocins and their inhibition properties against Listeria monocytogenes and vancomycin-resistant Enterococcus.

In the present scenario of a major demand for new compounds with antimicrobial activity, bacteriocin and bacteriocin-like inhibitory substances (BLIS) are promising tools against deteriorating and pathogenic microorganisms, thus having potential applications in both the food industry and infectious disease control. In the present report, we describe the genetic and phenotypic characteristics of BLIS produced by Enterococcus faecium E86, a strain previously isolated and sequenced by our group, focusing on the structural genes of two bacteriocins identified: enterocin TW21 and enterocin P. Transcription of all four genes associated with the biosynthesis and immunity of enterocin P and enterocin TW21 were confirmed by RT-PCR. However, Sanger sequencing confirmed a truncation of the structural gene of enterocin TW21 due to one base pair deletion (A/T). Thus, although E. faecium E86 was shown to carry two bacteriocinogenic gene clusters, only one cluster encodes a functional bacteriocin, enterocin P. Enterocin P was able to inhibit different strains of Listeria monocytogenes and vancomycin-resistant enterococci (both Enterococcus faecalis and Enterococcus faecium), showing intense bacteriolytic activity, in most cases.

Draft genome sequence of Staphylococcus agnetis 4244, a strain with gene clusters encoding distinct post-translationally modified antimicrobial peptides.

OBJECTIVES: Here we report the draft genome sequence of Staphylococcus agnetis 4244, a strain involved in bovine mastitis, and its ability to inhibit different species of antibiotic-resistant Gram-positive bacteria owing to bacteriocin production. METHODS: An Illumina MiSeq platform was used for genome sequencing. De novo genome assembly was done using the A5-miseq pipeline. Genome annotation was performed by the RAST server, and mining of bacteriocinogenic gene clusters was done using the BAGEL4 and antiSMASH v.5.0 platforms. Investigation of the spectrum of activity of S. agnetis 4244 was performed on BHI agar by deferred antagonism assay. RESULTS: The total scaffold size was determined to be 2 511 708 bp featuring a G+C content of 35.6%. The genome contains 2431 protein-coding sequences and 80 RNA sequences. Genome analyses revealed three prophage sequences inserted in the genome as well as several genes involved in drug resistance and two bacteriocin gene clusters (encoding a thiopeptide and a sactipeptide) encoded on the bacterial chromosome. Staphylococcus agnetis 4244 was able to inhibit all 44 strains of antibiotic-resistant Gram-positive bacteria tested in this study, including vancomycin-resistant enterococci (VRE), methicillin-resistant Staphylococcus aureus (MRSA) and other antibiotic-resistant staphylococcal strains. CONCLUSION: This study emphasises the potential biotechnological application of this strain for production of bacteriocins that could be used in the food industry as biopreservatives and/or in medicine as alternative therapeutic options against VRE, MRSA, vancomycin-intermediate S. aureus and other antibiotic-resistant Gram-positive bacteria, including biofilm-forming isolates. It also provides some genetic features of the draft genome of S. agnetis 4244.

Aureocins 4185, bacteriocins produced by Staphylococcus aureus 4185: potential application in food preservation.

In the present study, the bacteriocins produced by Staphylococcus aureus 4185, a strain isolated from bovine mastitis, were purified and partially characterized. After purification by ammonium sulfate precipitation, cation-exchange chromatography, and five runs of high-performance liquid chromatography (HPLC), antimicrobial activity was recovered with 40% and 80% isopropanol, suggesting that more than one antimicrobial peptide, named aureocins 4185, is produced by S. aureus 4185. Mass spectrometry analyses revealed three peptides eluted with 40% isopropanol: peptide A (2,305.3 +/-1.5 Da), peptide B (2,327.3 +/-1.5 Da), and peptide C (3,005.5 +/-1.5 Da), and two peptides eluted with 80% isopropanol: peptide D (6,413.5 +/-1.5 Da) and peptide E (12,834.5 +/-1.5 Da). Although five peptides have been detected, only four small peptide sequences were obtained by matrix-assisted laser desorption/ionization time of flight (MALDI-TOF)/TOF mass spectrometry analyses: SLLEQFTGK (eluted with 40% isopropanol), ALLYDER, NNTSHNLPLGWFNVK, and NNLAQGTFNATK (eluted with 80% isopropanol). The sequences SLLEQFTGK and ALLYDER revealed identity with hypothetical peptides with unknown function. The sequences NNTSHNLPLGWFNVK and NNLAQGTFNATK showed similarity to a segment of a precursor of staphylococcal autolysins. The antimicrobial activity detected in the supernatant of strain 4185 proved to be resistant to heat treatment at 65°C; however, treatment at 80°C abolished completely its antimicrobial properties. The concentrated supernatant containing aureocins 4185 exhibited a strong bacteriolytic activity toward Micrococcus luteus ATCC 4698. Additionally, aureocins 4185 exhibited antagonistic activity against important foodborne pathogens, including Listeria monocytogenes, thus showing a potential application in food preservation.

Marine Pseudomonas putida: a potential source of antimicrobial substances against antibiotic-resistant bacteria.

Bacteria isolated from marine sponges found off the coast of Rio de Janeiro, Brazil, were screened for the production of antimicrobial substances. We report a new Pseudomonas putida strain (designated P. putida Mm3) isolated from the sponge Mycale microsigmatosa that produces a powerful antimicrobial substance active against multidrug-resistant bacteria. P. putida Mm3 was identified on the basis of 16S rRNA gene sequencing and phenotypic tests. Molecular typing for Mm3 was performed by RAPD-PCR and comparison of the results to other Pseudomonas strains. Our results contribute to the search for new antimicrobial agents, an important strategy for developing alternative therapies to treat infections caused by multidrug-resistant bacteria.

Identification of coagulase-negative staphylococci from bovine mastitis using RFLP-PCR of the groEL gene.

Coagulase-negative staphylococci (CNS) have become the predominant pathogens causing bovine mastitis in many countries. CNS infections are associated with damage to milk secretory tissue of the mammary gland by increased connective tissue stroma, moderate increases of somatic cells count in milk and significant production decreases. These consequences impose serious economic losses for the farmers and the dairy industry. Routine veterinary laboratories do not usually identify CNS at the species level. Thereby, the aims of this study were to identify the most common staphylococcal pathogens involved in bovine mastitis using PCR-restriction fragment length polymorphism (RFLP) analysis of a partial groEL gene sequence and to compare our results with the identification carried out by the conventional method. A total of 54 isolates of Staphylococcus, involved in bovine mastitis, were analyzed by this method. The size and number of the fragments obtained by either AluI or HindIII/PvuII digestions made possible to form clear patterns differentiating, among the isolates, 11 of the most common species of animal staphylococcal pathogens. Most of the isolates clustered together with the reference strain of Staphylococcus chromogenes (28) and the type strain of Staphylococcus epidermidis (8). Besides, some isolates clustered together with the type strain of Staphylococcus aureus (5). All patterns were confirmed by the conventional biochemical method, showing concordant results. Thus, the PCR-RFLP of the groEL gene constitutes a reliable and reproducible molecular method for identification of CNS species responsible for bovine mastitis.

Hyicin 4244, the first sactibiotic described in staphylococci, exhibits an anti-staphylococcal biofilm activity.

Hyicin 4244 is a small antimicrobial peptide with a broad spectrum of activity that was found in the culture supernatant of Staphylococcus hyicus 4244, the genome of which was then sequenced. The bacteriocin gene cluster (hyiSABCDEFG) was mined from its single chromosome and exhibited a genetic organization similar to that of subtilosin A. All genes involved in hyicin 4244 biosynthesis proved to be transcribed and encode proteins that share at least 42% similarity to proteins encoded by the subtilosin A gene cluster. Due to its resemblance to subtilosin A and the presence of three thioether bonds in its structure, hyicin 4244 is assumed to be a 35-amino acid circular sactibiotic, the first to be described in staphylococci. Hyicin 4244 inhibited 14 staphylococcal isolates from either human infections or bovine mastitis, all biofilm formers. Hyicin 4244 significantly reduced the number of colony-forming units (CFU) and the biofilm formation by two strong biofilm-forming strains randomly chosen as representatives of the strains involved in human infections and bovine mastitis. It also reduced the proliferation and viability of sessile cells in established biofilms. Therefore, hyicin 4244 proved not only to prevent biofilm formation by planktonic cells, but also to penetrate the biofilm matrix in vitro, exerting bactericidal activity against staphylococcal sessile cells. This bacteriocin has the potential to become an alternative antimicrobial for either prevention or treatment of biofilm-related infections caused by different staphylococcal species.

Species-level identification of clinical staphylococcal isolates based on polymerase chain reaction--restriction fragment length polymorphism analysis of a partial groEL gene sequence.

A pair of degenerate primers that amplified, by polymerase chain reaction (PCR), a partial groEL gene sequence (550 bp) was used for the identification of the 12 most common human staphylococcal pathogens. The amplified products were digested by AluI endonuclease, and distinctive PCR restriction fragment length polymorphism (RFLP) patterns for reference strains were obtained. This protocol was validated by the identification of 89 clinical staphylococcal isolates, and the results were compared with those obtained by the reference biochemical identification, showing 100% concordant results. Two species, Staphylococcus aureus and Staphylococcus lugdunensis, showed intraspecies polymorphisms on their PCR-RFLP patterns. All strains were also identified using the API Staph ID test (bioMérieux, Durham, NC) and the MicroScan WalkAway automated system (Dade Behring, West Sacramento, CA). When 17 Staphylococcus isolates were tested in a blind experiment by the PCR-RFLP of the groEL gene method, all strains were also correctly identified. We propose the PCR-RFLP of the groEL gene with AluI as a reliable and reproducible method for identification of Staphylococcus spp.

Insights into aureocin A70 regulation: participation of regulator AurR, alternative transcription factor σ(B) and phage ϕ11 regulator cI.

Aureocin A70 is a four-component bacteriocin produced by Staphylococcus aureus A70. Its locus encompasses three transcriptional units coding for: (i) structural peptides (aurABCD), (ii) an ABC transporter (aurT) and (iii) the dedicated immunity protein and a putative transcriptional regulator (aurRI). The data provided here showed that AurR is an HTH-containing protein that reduces aureocin A70 production on solid medium, but not in broth. AurR seems to work similarly to LtnR and CylR2, repressors of lantibiotics lacticin 3147 and cytolysin, respectively. At least two other factors play a role in aureocin A70 production: (i) the alternative σ(B) factor, as σ(B)-defective cells produce more bacteriocin than the restored σ(B+) cells, and (ii) the ϕ11 regulator cI, since a lysogenic strain for ϕ11 exhibited a significant reduction in aureocin A70 production on solid medium when compared with the non-lysogenic isogenic strain. Full aeration and ROS generation abolished the effect of the phage regulators on aureocin A70 production. Interestingly, the ϕ11 regulator cI seems to cooperate with AurR to abolish aureocin A70 production. This study therefore represents the first report showing that phage regulators may play a role in regulation of bacteriocin production.

Biochemical characterisation and genetic analysis of aureocin A53, a new, atypical bacteriocin from Staphylococcus aureus.

Aureocin A53 is produced by Staphylococcus aureus A53. It is encoded on a 10.4 kb plasmid, pRJ9, and is active against Listeria monocytogenes. Aureocin A53 is a highly cationic 51-residue peptide containing ten lysine and five tryptophan residues. Aureocin A53 was purified to homogeneity by hydrophobic-interaction, cation-exchange, and reverse-phase chromatography. MALDI-TOF mass spectrometry yielded a molecular mass of 6012.5 Da, which was 28 Da higher than predicted from the structural gene sequence of the bacteriocin. The mass increment resulted from an N-formylmethionine residue, indicating that the aureocin A53 is synthesised and secreted without a typical bacteriocin leader sequence or sec-dependent signal peptide. The structural identity of aureocin A53 was verified by Edman sequencing after de-blocking with cyanogen bromide and extensive mass spectrometry analysis of enzymatically and laser-generated fragments. The complete sequence of pRJ9 was determined and none of the open reading frames identified in the vicinity of the structural gene aucA showed similarity to genes that are typically found in bacteriocin gene clusters. Thus, neither a dedicated protease or transporter, nor modifying enzymes and regulatory elements seemed to be involved in the production of aureocin A53. Further unique features that distinguish aureocin A53 from other peptide bacteriocins include remarkable protease stability and a defined, rigid structure in aqueous solution.

Simultaneous detection of the mecA and ileS-2 genes in coagulase-negative staphylococci isolated from Brazilian hospitals by multiplex PCR.

Coagulase-negative Staphylococcus spp. (CNS) has been associated with primary bloodstream infections and implanted medical devices. Its importance is increasing due to the acquisition of resistance to oxacillin (Oxa) and, recently, resistance to mupirocin (Mup). Mupirocin, a topical antimicrobial, has been used in the prevention of staphylococci catheter colonization. Susceptibility to Oxa and Mup was analyzed by different testing methods in clinical CNS isolates. Among 112 CNS strains, 69 (61.6%) were Oxa(R) by the disk diffusion (DD) method and 72 (64.2%) grew on the oxacillin agar screen plate. S. epidermidis and S. haemolyticus presented high rates of oxacillin resistance, 75.4% and 96.1%, respectively. Twenty four (21.4%) strains were Mup(R) by the DD test and 21 of them (87.5%) were identified as S. epidermidis. The detection of the mecA and ileS-2 genes, determined by multiplex-PCR, showed that 72 (64.2%) CNS strains possessed the mecA gene, while 16 (14.3%) possessed the ileS-2 gene. Fifteen of these strains presented the two resistance genes simultaneously. The isolates containing the ileS-2 gene presented a minimum inhibitory concentration (MIC) >1024 microg/mL in the E-test, while low-level mupirocin resistance (MICs of 12-16 microg/mL) was observed in those strains without ileS-2. The resistances to high and low levels of mupirocin could not be distinguished when the DD test was used. The analysis of the Mup(R) S. epidermidis strains by Pulsed Field Gel Electrophoresis showed that 17 (80.9%) strains belonged to one of two patterns (A and B), which have been shown to be prevalent in hospitals in Rio de Janeiro. This report showed that the PCR method for detection of oxacillin and mupirocin resistance in CNS is necessary to determine accurate rates of these resistance, and will can help in the staphylococcal infections prevention and control policies in Brazil.

Immunity to the Staphylococcus aureus leaderless four-peptide bacteriocin aureocin A70 is conferred by AurI, an integral membrane protein.

Aureocin A70, which is produced by Staphylococcus aureus A70, is the only four-component bacteriocin described thus far. The genetic determinants responsible for its production are arranged as three transcriptional units encoded by the 7.9-kb plasmid pRJ6. While the transcriptional unit formed by the genes aurABCD encodes the bacteriocin structural peptides, a second divergent gene, aurT, codes for an ABC transporter involved in bacteriocin externalization. The third transcriptional unit is composed of two genes, orfAB, whose functions were hitherto unknown. RT-PCR analysis of orfAB expression revealed that they are arranged as an operon. When orfAB, either with or without the transcriptional terminator found downstream of orfB, was expressed in two different S. aureus strains sensitive to aureocin A70, all strains became immune to this bacteriocin. Cloning of orfB alone, with or without the transcriptional terminator, confirmed orfB participation in immunity, although full immunity was not observed. An increase in immunity was achieved when two copies of orfB were cloned oriented with the exogenous Plac promoter present in the expression vector pT181mcs. orfB (here referred to as aurI) was shown to be responsible for aureocin A70 immunity, but the full immunity phenotype seems to depend on translational coupling involving orfA, which encodes a putative transcriptional regulator, and aurI.

Revealing the latent mobilization capability of the staphylococcal bacteriocinogenic plasmid pRJ9.

Plasmid pRJ9 is a non-self-mobilizable bacteriocinogenic plasmid from Staphylococcus aureus. Despite this feature, DNA sequencing and RT-PCR experiments showed that it presents a Mob region with three genes (mobCAB), transcribed as an operon. In silico analysis of the Mob proteins encoded by pRJ9 showed that they present all the conserved functional features reported until present as being essential for plasmid mobilization. Moreover, they showed a high identity to Mob proteins encoded by mobilizable plasmids from Staphylococcus spp., especially to those encoded by plasmid pRJ6, which presents four mob genes (mobCDAB). A putative oriT region was also found upstream of the pRJ9 mob operon. pRJ9 could only be successfully mobilized by pGO1 when pRJ6 was present in the same strain. Further experiments showed that the pRJ9 oriT can be recognized by the pRJ6 Mob proteins, confirming its functionality. As pRJ9 does not possess a mobD gene while pRJ6 does, the absence of this gene was believed to be responsible for its lack of mobilization. However, conjugation experiments with a donor strain carrying also mobD cloned into an S. aureus vector showed that pRJ9 does not become mobilized even in the presence of the protein MobD encoded by pRJ6. Therefore, the reasons for pRJ9 failure to be mobilized are presently unknown.

Hyicin 3682, a bioactive peptide produced by Staphylococcus hyicus 3682 with potential applications for food preservation.

Bacteriocins are peptides produced by bacteria and having inhibitory activity against other bacteria. Many of these substances may be useful as antibacterial agents for practical applications. In this study, 21 Staphylococcus spp. isolated from pigs, dogs and bovine milk in different states of Brazil were investigated for staphylococcin production. Hyicin 3682, a bacteriocin produced by one such strain, inhibited almost all strains tested, including Bacillus cereus, Listeria monocytogenes and Staphylococcus aureus. PCR experiments showed that hyicin 3682 is lantibiotic-related, but not identical, to both epidermin and Bsa. The maximum production of hyicin 3682 (6,400 AU/ml) was observed after 24 h of growth in BHI medium at 37 °C. Hyicin 3682 proved to be a cationic, small antimicrobial peptide with a molecular mass of 2,139 Da. It exhibited resistance to low pH and to heating at 65 °C, and partial sensitivity to proteolytic enzymes. Taken together, these results suggest that hyicin 3682, the first bacteriocin characterized in Staphylococcus hyicus, has potential biotechnological applications as a food preservative. Moreover, hyicin 3682 was able to inhibit its producer strain, suggesting that an effective immune system for specific protection against hyicin 3682 is not found in its producer strain, a characteristic not described thus far for other staphylococcins.

Lysostaphin: A Staphylococcal Bacteriolysin with Potential Clinical Applications.

Lysostaphin is an antimicrobial agent belonging to a major class of antimicrobial peptides and proteins known as the bacteriocins. Bacteriocins are bacterial antimicrobial peptides which generally exhibit bactericidal activity against other bacteria. Bacteriocin production is a self-protection mechanism that helps the microorganisms to survive in their natural habitats. Bacteriocins are currently distributed into three main classes. Staphylococcins are bacteriocins produced by staphylococci, which are Gram-positive bacteria of medical and veterinary importance. Lysostaphin is the only class III staphylococcin described so far. It exhibits a high degree of antistaphylococcal bacteriolytic activity, being inactive against bacteria of all other genera. Infections caused by staphylococci continue to be a problem worldwide not only in healthcare environments but also in the community, requiring effective measures for controlling their spread. Since lysostaphin kills human and animal staphylococcal pathogens, it has potential biotechnological applications in the treatment of staphylococcal infections. In vitro and in vivo studies performed with lysostaphin have shown that this staphylococcin has potential to be used, solely or in combination with other antibacterial agents, to prevent or treat bacterial staphylococcal infectious diseases.

Nukacin 3299, a lantibiotic produced by Staphylococcus simulans 3299 identical to nukacin ISK-1.

Nukacin 3299 (formerly designated simulancin 3299), produced by a Staphylococcus simulans strain involved in bovine mastitis in Brazil, is the first peptide bacteriocin described in this staphylococcal species. With the intent to elucidate some aspects of its biology, nukacin 3299 was purified and characterized. The mass of the purified bacteriocin was shown to be 2957.3 Da, and the peptide N-terminal amino acids (KKKSGVI) were identified by Edman degradation. The nukacin 3299 structural gene, nukA, was detected by PCR and DNA sequencing, showing that this bacteriocin is identical to nukacin ISK-1, a 27-amino acid type-A (II) lantibiotic produced by Staphylococcus warneri ISK-1, isolated from a "nukadoko", in Japan. The genes involved in nukacin 3299 biosynthesis are located on plasmid pRJ97 (>27 kb). They have an organization similar to that of the nukacin ISK-1 gene cluster, excepted for the presence of an IS257/431 element (791 bp) present between the orf1 and nukA genes of the nukacin 3299 gene cluster. The presence of this insertion sequence is expected to affect the expression of orf1, whose function is presently unknown. Nukacin 3299 proved to be sensitive to proteolytic enzymes and relatively stable at different temperatures and between pH 3.0-9.0. Nukacin 3299 exhibited activity towards staphylococcal strains involved in bovine mastitis, showing a potential application on mastitis control, a disease with great economic impact.

Mobilization functions of the bacteriocinogenic plasmid pRJ6 of Staphylococcus aureus.

Plasmid pRJ6 is the first known bacteriocinogenic mobilizable (Mob) plasmid of Staphylococcus aureus. Its Mob region is composed of four mob genes (mobCDAB) arranged as an operon, a genetic organization uncommon among S. aureus Mob plasmids. oriT (pRJ6) was detected in a region of 431 bp, positioned immediately upstream of mobC. This region, when cloned into pCN37, was able to confer mobilization to the re-combinant plasmid only in the presence of pRJ6. The entire Mob region, including oriT (pRJ6), is much more similar to Mob regions from several coagulase-negative staphylococci plasmids, although some remarkable similarities with S. aureus Mob plasmids can also be noted. These similarities include the presence within oriT (pRJ6) of the three mcb (MobC binding sites), firstly described in pC221 and pC223, an identical nick site also found in these same plasmids, and a nearly identical sra(pC223) site (sequence recognized by MobA). pRJ6 was successfully transferred to S. epidermidis by conjugation in the presence of the conjugative plasmid pGOl. Altogether these findings suggest that pRJ6 might have been originally a coagulase-negative staphylococci plasmid that had been transferred successfully to S. aureus.