Transcription of the Toxin Genes Present within the Staphylococcal Phage {phi}Sa3ms Is Intimately Linked with the Phage's Life Cycle

${phi}$ Sa3ms, a lysogenic bacteriophage encoding the staphylococcalenterotoxins SEA, SEG, and SEK and the fibrinolytic enzyme staphylokinase(Sak), was identified in the unannotated genome sequence ofthe hypervirulent community-acquired Staphylococcus aureus strain476. We found that mitomycin C induction of ${phi}$ Sa3ms led to increasedtranscription of all four virulence factors. The increase insea and sak transcription was a result of read-through transcriptionfrom upstream latent phage promoters and an increase in phagecopy number. The majority of the seg2 and sek2 transcripts wereshown to initiate from the upstream phage cI promoter and hencewere regulated by factors influencing cI transcription. Thelysogeny module of ${phi}$ Sa3ms was shown to have some ${lambda}$ -like featureswith divergent cI and cro genes. Band shift assays were usedto identify binding sites for both CI and Cro within the regionbetween these genes, suggesting a mechanism of control for the ${phi}$ Sa3ms lytic-lysogenic switch. Our findings suggest that theproduction of phage-encoded virulence factors in S. aureus maybe regulated by processes that govern lysogeny.

INTRODUCTION

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Introduction

Staphylococcus aureus is a leading cause of nosocomial and community-acquiredinfections worldwide (42). S. aureus causes a wide range ofdiseases that vary in severity from mild skin infections, suchas boils and furuncles, to life-threatening diseases, like toxicshock syndrome and endocarditis. The ability of S. aureus tocause such a wide variety of diseases is thought to be due inpart to its elaboration of a large number of secreted and cell-surfaceassociated virulence factors (1, 5, 21, 36, 48).

Much of the variation between S. aureus strains appears to beattributable to mobile genetic elements, such as plasmids, bacteriophages,pathogenicity islands, transposons, insertion sequences, andthe staphylococcal chromosomal cassette (2, 27). The bacteriophagesand pathogenicity islands of S. aureus encode many virulencefactors (35). The known phage-encoded virulence factors includePanton-Valentine leukocidins (24, 33), exfoliative toxin typeA (47), and staphylococcal enterotoxins (SEs) (3). The SEs constitutea family of related proteins whose activities are associatedwith staphylococcal food poisoning, toxic shock syndrome, andpossibly several autoimmune disorders (17, 41). SEs are powerfulsuperantigens that activate subsets of T lymphocytes to liberatevarious cytokines, including gamma interferon and tumor necrosisfactor (41). In addition to these characterized phage-encodedvirulence factors, a number of putative S. aureus virulencefactors, such as staphylokinase (Sak), are also encoded in phagegenomes (25). Staphylokinase, a potent plasminogen activator,has been hypothesized to aid in the dissemination of S. aureusfrom fibrinous clots and abscesses (1).

The genome sequences of two S. aureus isolates derived fromlife-threatening community-acquired infections have been determined(2; unpublished data). The methicillin-resistant strain MW2(sequenced at Juntendo University, Tokyo, Japan) was isolatedin 1998 from North Dakota after it caused septic arthritis andfatal septicemia in a 16-month-old girl (2). Methicillin-sensitivestrain MSSA476 (sequenced at the Sanger Institute, Cambridge,United Kingdom) was isolated in 1998 from Oxford, United Kingdomafter it caused osteomyelitis and bacteremia in a 9-year-oldboy. By mining the unannotated MSSA476 genome for phage-likesequences, we identified a prophage that encodes the previouslycharacterized enterotoxins SEA, SEG, and SEK and the fibrinolyticenzyme Sak. Here we describe and characterize this phage, designated ${phi}$ Sa3ms, from MSSA476.

Although the physical linkage of S. aureus virulence factorswith phage genomes has been recognized for almost two decades(3), it is not known whether the life cycles of the phages influencethe expression of the virulence genes and thus S. aureus pathogenicity.Here we show that upon ${phi}$ Sa3ms prophage induction, transcriptionof sea, seg2, sek2, and sak are greatly increased. Phage-encodedfactors were found to be required for the increases in sea andsak transcription. Interestingly, the majority of seg2 and sek2transcripts initiated from the upstream ${phi}$ Sa3ms repressor (cI)promoter, indicating that factors that influence cI transcriptionalso influence virulence gene expression. Finally, the locationof the putative CI and Cro binding sites suggests a potentialmechanism for regulation of ${phi}$ Sa3ms lysogeny and hence virulencefactor expression.

MATERIALS AND METHODS

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Materials and Methods

Bacterial strains and plasmids. A list of the bacterial strains and plasmids used in this studyis shown in Table 1. Escherichia coli strains were grown inLuria-Bertani broth with ampicillin (100 µg/ml). S. aureusstrains were grown in Todd-Hewitt broth (Difco) containing 0.2%(wt/vol) yeast extract (Difco) (THY) or in trypic soy broth(TSB) (Becton Dickinson) as indicated below; media were supplementedwith 10 µg of chloramphenicol per ml when appropriate.

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TABLE 1. Bacterial strains and plasmids used in this study

Bioinformatic analyses. The currently unannotated MSSA476 genome sequence (producedby the S. aureus Sequencing Group at the Sanger Institute andavailable at www.sanger.ac.uk/Projects/S_aureus/) was minedfor phage-like sequences by performing BLAST searches (availableat www.ncbi.nlm.nih.gov/BLAST/) by using known phage-associatedsequences, including sequences encoding SEs and integrases.Overlapping regions of interest were obtained from the FTP site,and putative open reading frames (ORFs) were identified by usingFrameplot 3.0beta (available at www.nih.go.jp/ $~$ jun/cgi-bin/frameplot-3.0b.pl).BLAST searches were then performed with these putative ORFsto identify orthologues. The method of Dodd and Egan (18) wasused to identify putative helix-turn-helix motifs, and possibleN-terminal signal sequences were identified by using SignalPV2.0.b2 (available at www.cbs.dtu.dk/services/SignalP-2.0/).Protein sequences were scanned for sites or signatures againstthe PROSITE database by using PROSCAN (available at http://npsa-pbil.ibcp.fr).Conserved domains were identified using the National Centerfor Biotechnology Information conserved domain search program(available at www.ncbi.nlm.nih.gov/Structure/cdd/cdd.shtml).

Construction of a ror null mutant. PCR primers were created to amplify a central region of ror(5'-GCGGATCCTGGCTATTTAAAGAAAAGAG-3' and 5'-GCCTGCAGACATGAGGTTTGTATGTTTG-3'),which was cloned directly into pBT9 after restriction digestionof the PCR products at the sites underlined in the primers,creating plasmid pPS79. pBT9 is an E. coli-S. aureus shuttlevector that is temperature sensitive for replication in S. aureus(12). pPS79 was introduced into the restriction-deficient S.aureus strain RN4220 by transformation as previously described(28). pPS79 was then transduced from RN4220 into MSSA476 byusing phage 80 ${alpha}$ as previously described (34). Single crossoverswere selected by inoculating 2 ml of TSB containing chloramphenicolwith a single colony and incubating the culture for 8 h at 42°Cbefore streaking it onto TSA plates containing chloramphenicol.The plates were then incubated at 42°C overnight. The presenceof ror::pPS79 was confirmed by Southern blotting (data not shown).One caveat of this approach is that MS79 (ror::pPS79) must begrown at 42°C to maintain the integrated form of the plasmid.Therefore, in all experiments in which MS79 was utilized, boththis strain and wild-type strain MSSA476 were streaked and grownovernight at 42°C. However, after appropriate dilution ofovernight cultures, additional incubation was carried out at37°C. In each experiment an MSSA476 control which had beengrown exclusively at 37°C was also included. In all casesthere was no difference between the results for MSSA476 grownat 37°C and the results for MSSA476 grown at 42°C.

RNA extraction and Northern blotting. Total RNA was isolated from S. aureus cultures by using QiagenRNeasy mini kits (Qiagen, Valencia, Calif.) as recommended bythe manufacturer, except that lysostaphin was substituted forlysozyme. Overnight TSB cultures were diluted 1:200 (see Fig.2) or 1:400 (see Fig. 4) into fresh TSB and grown with shakingat 37°C to an optical density at 600 nm of 0.1 (see Fig.2) or 0.14 (see Fig. 4) before extraction of RNA from aliquots(time zero). Each culture was then split into two parts, andmitomycin C was added to one of the parts at a final concentrationof 0.3 µg/ml. The cultures were then incubated at 37°C,and RNA was extracted from aliquots of both cultures at severalsubsequent times. Total RNA was quantified by spectrophotometricanalysis (optical density at 260 nm), and equal amounts of RNAwere used for Northern blotting performed by using the AmbionNorthernMax-Gly protocol (Ambion, Austin, Tex.). Probes forNorthern blotting were created by using an Ambion Strip-EZ kit.

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FIG. 2. Treatment with the prophage-inducing agent mitomycin C increases sak and sea transcript levels. Mitomycin C (300 ng/ml) was added to one of two identical MSSA476 cultures, and RNA was extracted from both cultures every 30 min for 2.5 h. Six micrograms of total RNA was loaded in each lane and subsequently probed with sak (a), sea (b), or dnaN (c). The dnaN blot acted as a control for RNA loading.

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FIG. 4. Mitomycin C does not induce sak and sea transcription in MS79. Northern blots containing 5 µg of total RNA per lane were probed with sea (a), sak (b), or dnaN (c). The dnaN blot acted as a control for RNA loading. The lane indicated by an asterisk contained RNA from MSSA476 that was grown exclusively at 37°C to show that initial growth of this strain at 42°C had no effect on the subsequent transcription profiles of sea and sak.

Genomic DNA extraction and Southern blotting. Genomic DNA was isolated as previously described (34). Southernblotting was performed by using standard techniques, and theblots were probed with horseradish peroxidase-labeled probesgenerated by using an Amersham ECL direct labeling kit (Amersham,Little Chalfont, Buckinghamshire, England).

Phage DNA isolation. Phage DNA was isolated from supernatants of MSSA476 culturesas previously described (23). Isolated phage DNA was subjectedto restriction analysis and separated on standard agarose gelsstained with ethidium bromide.

Single-plaque purification of phage and plaque lifts. Single plaques were isolated by seeding 3 ml of soft THY (supplementedwith 5 mM CaCl₂) with 10 µl of an overnight RN4220 cultureand overlaying the resulting culture onto a plate containingTHY (supplemented with 5 mM CaCl₂) spread with dilutions ofMSSA476 culture supernatants. Plaque lifting was performed byusing standard procedures after incubation of the plates for18 h at 37°C.

Identification of transcriptional start sites by 5'-RACE. The Invitrogen 5' rapid amplification of cDNA ends (RACE) system(Invitrogen, Carlsbad, Calif.) was used to identify putativetranscriptional start sites for cI and cro according to themanufacturer's instructions. The following primers were usedfor these assays: CRORA (5'-TTGTTCCATTGTGTCCCTCC-3'), CROXR(5'-CGGGATCCTATAACATGAACTTTTTC-3'), MSREP2 (5'-GCGAATTCTCACTGTCTTTCCAACCAAC-3'),CISF (5'-CCACATGCAATATACGATAC-3'), and SEQR (5'-GAGTAGAAACTTTGTCTGTAG-3').Briefly, primer SEQR or CRORA was added to total RNA isolatedfrom MSSA476 and used to prime first-strand cDNA synthesis withreverse transcriptase. A poly(C) 3' tail was added to the cDNAby using terminal transferase, and each of the tailed cDNAswas used as template in a PCR performed with a downstream primer(relative to the directions of the SEQR and CRORA primers) anda primer that ended with a poly(G) sequence (primer AAP; Invitrogen).Control PCRs in which nontailed cDNAs were used as templateswere used as controls for AAP primer specificity. Products werevisualized on standard agarose gels stained with ethidium bromide.Bands were excised from the gels by using a Qiagen gel extractionkit and were sequenced at the Tufts University School of MedicineCore Sequencing Facility.

Cloning and overexpression of CI and Cro genes. cI and cro were amplified by PCR by using primers CIXF (CGCCATGGGCCGCGAAAAAGTTTCAAATCGCCTTAAACAC)and CIXR (GCGGATCCCAATACAACTTTGCCCATTAC) for cI and CROXF (CGCCATGGGCTGTTACGACTACTCACGTTTG)and CROXR (CGGGATCCTATAACATGAACTTTTTC) for cro. The PCR productswere cloned into the E. coli expression vector pQE-60 (Qiagen),creating pCIX and pCROX, respectively. To enable cloning intopQE-60, the PCR primers for amplifying both cI and cro containedan NcoI site overlapping the start codon and a BamHI site atthe 3' end of the gene. Ligation of the NcoI-BamHI-digestedPCR products into pQE-60 generated a six-His tag at the C terminusof each expressed protein. Proteins were expressed in E. colistrain XL1-Blue following standard isopropyl-ß-D-thiogalactopyranoside(IPTG) induction. Proteins were purified on Ni-agarose columns(Qiagen) by following the manufacturer's instructions.

Band shift assays. Three probes were generated by PCR by using 5'-radiolabeledprimers. Probe 1 was a 147-bp region of ${phi}$ Sa3ms from the regionbetween ORFs 49 and 50 and contained a putative CI binding half-site(primers 5'-CATCTACAACTTTATCTTGC-3' and 5'-AGTTGAACGTGTTGATGATG-3');probe 2 was a 99-bp region overlapping the 3' end of cro andcontained a complete CI binding site (primers 5'-TTGTTCCATTGTGTCCCTCC-3'and 5'-ATACAACTACTAGATATACC-3'); and probe 3 was a 209-bp regionoverlapping the region between cI and cro and contained twocomplete putative CI binding sites and a single putative Crobinding site (primers 5'-TTTCTACTATTTTCCCGCTC-3' and 5'-CTCTCATTTAGTGCACCTCC-3').After the primers were treated with kinase, unincorporated nucleotideswere removed by using a MicroSpin G-25 column (Amersham). Unincorporatedprimers were removed after PCR by using a Qiagen PCR purificationkit. Purified protein, either CI or Cro, was diluted in 1x bindingbuffer (20 mM Tris-HCl [pH 7.5], 1 mM MgCl₂, 5% glycerol, 50µg of bovine serum albumin per ml); 50 ng of sonicatedsalmon sperm DNA per µl and 4 mM dithiothreitol were includedin the binding reaction mixtures, which were incubated at roomtemperature for 10 min. Samples were loaded and run on Invitrogen6% polyacrylamide retardation gels. The gels were dried andthen exposed to BioMax MS film (Eastman Kodak Company, Rochester,N.Y.).

RESULTS

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Results

Identification and analysis of phage genomes within S. aureus MSSA476. Conserved phage genes (e.g., int) and known phage-encoded virulencegenes (e.g., sak) were used to search the unfinished MSSA476database (Sanger Institute) for phage-like sequences. Two putativephage genomes, designated ${phi}$ Sa3ms and ${phi}$ Sa4ms, were identified bythis method. The designations chosen were based on the classificationproposed by Baba et al. (2). ${phi}$ Sa4ms most closely resembles ${phi}$ 12from the prototypical S. aureus strain NCTC 8325 (22). However,unlike integration of ${phi}$ 12 in NCTC 8325, ${phi}$ Sa4ms is integrated intothe MSSA476 genome between the gene encoding a toxic anion resistanceprotein orthologue and an orthologue of htrA, which encodesa stress response serine protease implicated in the virulenceof a number of pathogenic bacteria (15, 37). The attB site islocated only 30 bases upstream of the htrA start codon, raisingthe possibility that ${phi}$ Sa4ms integration and excision affect thetranscription of htrA. Analysis of each individual ORF within ${phi}$ Sa4ms failed to identify any known or putative virulence factors,similar to what has been reported for ${phi}$ 12 (22).

The ${phi}$ Sa3ms genome is shown in Fig. 1. ${phi}$ Sa3ms encodes the SEs SEA,SEG, and SEK, along with the putative virulence factors SAKand a protein (Orf57) thought to be involved in expression ofa fibrinogen binding protein (4, 22). Remarkably, ${phi}$ Sa3mw, a phagerecently identified in the community-acquired methicillin-resistantS. aureus strain MW2 (2), differs from ${phi}$ Sa3ms at only 14 bp overthe entire 42,612-bp genome. The 14 bp of sequence divergenceresults in silent mutations at four sites, single amino acidchanges in the Sak, amidase, Orf49, tail, portal, and integraseproteins, and a 4-bp deletion within a putative antirepressorgene resulting in a truncated product in ${phi}$ Sa3ms compared to the ${phi}$ Sa3mw product. The 4-bp deletion in ${phi}$ Sa3ms was shown to be authenticand not a result of a sequencing error by resequencing thisregion of ${phi}$ Sa3ms (data not shown).

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FIG. 1. Genetic organization and ORF map of the 42,612-bp ${phi}$ Sa3ms genome. Putative ORFs are indicated by arrows that show the directions of transcription. The raised arrows indicate the approximate locations of the promoters mapped in this study. Enterotoxin genes are indicated by solid arrows, while other putative virulence factors are indicated by gray arrows. orf21, designated ror, which was inactivated in this study, is indicated by a cross-hatched arrow. Groups of genes whose protein products are functionally interrelated are indicated above the ORF map.

Table 2 shows the closest homologue of each ${phi}$ Sa3ms ORF identifiedby BLASTP searches of the GenBank database (to be more informative, ${phi}$ Sa3mw hits were omitted). Remarkably, the sequence encoded byevery ${phi}$ Sa3ms ORF exhibited at least 90% amino acid identity tothe sequences encoded by ORFs in other double-stranded DNA tailedS. aureus phages. The extensive similarity of ${phi}$ Sa3ms sequencesto the sequences found in other phages presumably reflects recombinationamong several other phages that occurred during the evolutionaryhistory of ${phi}$ Sa3ms (20). As is typical for phage genomes, ${phi}$ Sa3msgenes with similar functions are clustered together (Fig. 1).The putative ${phi}$ Sa3ms lysogeny module consists of divergent cIand cro homologues, suggesting that there is a mechanism forcontrol of the lysogenic-lytic decision similar to the mechanismin ${lambda}$ . The putative replication module includes homologues ofgenes encoding the recombination protein RecT, the Hollidayjunction resolvase Rus, a single-stranded binding protein, aDNA ligase (ORF 22), and the putative replisome organizer Ror(Table 2). ORF 21 was designated ror after BLASTP analysis identifiedthe origin-binding Ror protein from Bacillus subtilis phageSPP1 as the highest-scoring homologue with a defined function(32, 38). Further evidence that Ror has a role in replicationwas obtained from a National Center for Biotechnology Informationconserved domain search analysis that revealed that Ror is similarto the PriA primosome component DnaD (31). The head morphogenesisregion contains two terminase subunits, a characteristic ofphages that package their genomes via a head-full mechanism(pac-type phage) (29). ORF 31 encodes a putative homing nucleasebased on the similarity of the protein to a number of endonucleasesbelonging to the HNH family (16). The putative head-tail joining,tail morphogenesis, and host lysis regions are similar to thosefound in previously described S. aureus phages (22).

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TABLE 2. Putative ORFs in ${phi}$ Sa3ms

Integration of ${phi}$ Sa3ms disrupted the ß-hemolysin geneof MSSA476. Such negative conversion of a potential virulencegene has been observed after integration of a number of S. aureusphages (14). Studies of the regulation of integration and excisionof S. aureus phages have identified either xis homologues oran ORF adjacent to the integrase gene termed ORFC, which isthought to function like xis and facilitate phage excision (13).However, no such gene is present upstream of the putative ${phi}$ Sa3msint gene, raising the question of how ${phi}$ Sa3ms integration andexcision are controlled. ${phi}$ Sa3ms, like all previously describedS. aureus phages, contains a conserved hairpin loop upstreamof int (13). A number of S. aureus phages also contain a secondconserved hairpin sequence upstream of int (22). These putativehairpin sequences have been hypothesized to be important inint gene regulation (13, 22). The putative hairpin sequenceidentified by Carroll and colleagues (13) even occurs upstreamof both the staphylococcal pathogenicity island 1 (SaPI1) andSaPI3 int genes.

Both ${phi}$ Sa3ms and ${phi}$ Sa4ms form phage particles. We initially examined whether ${phi}$ Sa3ms and ${phi}$ Sa4ms were defectiveprophages by assaying supernatants of mitomycin C-treated MSSA476cultures for the presence of phage DNA. After the isolated phageDNA was subjected to restriction analysis, bands of the expectedsizes for ${phi}$ Sa3ms and ${phi}$ Sa4ms DNA were detected at nearly equalintensities (data not shown). Southern blot analysis of isolatedphage DNA performed with a ${phi}$ Sa3ms-specific sea probe providedfurther evidence that ${phi}$ Sa3ms was capable of producing phage particles(data not shown). No hybridizing signal was observed when achromosomally encoded gene was used as a probe (data not shown).Single-plaque purification of phage derived from mitomycin C-treatedMSSA476, followed by DNA isolation and restriction analysis,revealed that while ${phi}$ Sa4ms was capable of producing infectiousparticles (plaques), no ${phi}$ Sa3ms plaques were observed (data notshown). Plaque lift assays with the sea probe were also negative,suggesting either that ${phi}$ Sa3ms produces phage particles that arenoninfectious, that the indicator strain RN4220 lacks the necessary ${phi}$ Sa3ms receptor, or that the conditions used were not conducivefor ${phi}$ Sa3ms infection.

Prophage induction greatly increases transcription of sea and sak from their native promoters and from upstream latent phage promoters. Northern blot analyses of RNA isolated from MSSA476 culturesat various times after mitomycin C treatment were carried outto investigate the effects of prophage induction on sea andsak transcript levels. In the absence of mitomycin C, a singleapproximately 1.0-kb sak transcript was present at relativelyconstant levels during the course of the experiment (Fig. 2).The levels of the single $~$ 1.7-kb sea transcript in uninducedcultures also remained relatively constant during the experiment(Fig. 2). The 1.7-kb transcript likely originated from a previouslycharacterized promoter immediately upstream of sea (8). Ninetyminutes after mitomycin C treatment there were marked increasesin both the 1.7-kb sea and 1.0-kb sak transcripts (Fig. 2).Mitomycin C treatment also resulted in the production of twohigher-molecular-weight mRNAs for both genes (Fig. 2). The factthat the highest-molecular-weight bands for both sea and sakwere the same size (approximately 6.8 kb), as well as the relativeorganization of these two genes in the ${phi}$ Sa3ms genome, suggestedthat the 6.8-kb mRNA encodes both virulence factors.

Reprobing these Northern blots with a series of probes specificfor genes 5' of sea (orf47, orf49, and orf50) established thatthe 6.8-kb transcript likely initiates from a region betweenorf47 and orf49 (data not shown). The likely start site of the3-kb sea transcript also mapped to this region. A probe forthe ${phi}$ Sa3ms holin gene showed that the 2.7-kb transcript containingsak originates 5' of the phage holin gene (data not shown).These data confirm that sea and sak are expressed from theirown promoters in uninduced cultures. However, following prophageinduction, previously repressed phage promoters become activeand contribute to increased sea and sak expression. To our knowledge,this is the first demonstration that there is linkage betweenprophage induction and increased virulence factor transcriptionin S. aureus.

${phi}$ Sa3ms replication contributes to mitomycin C induction of sea and sak transcription. At least two processes may contribute to the large increasesin the amounts of the sea and sak transcripts observed aftermitomycin C treatment of MSSA476. First, the data presentedabove suggest that mitomycin C treatment leads to activationof latent prophage promoters that can initiate transcriptionof sea and sak. Second, mitomycin C treatment likely leads to ${phi}$ Sa3ms excision and replication, thereby increasing the amountof phage DNA template available for transcription. A replication-deficient ${phi}$ Sa3ms prophage was constructed (Fig. 3) to investigate the contributionof ${phi}$ Sa3ms replication to sea and sak transcription. To constructthe replication-deficient prophage, we insertionally inactivatedthe putative replisome organizer (ror) gene through homologousrecombination with pPS79 (Fig. 3a), a conditionally replication-defectiveplasmid containing a 719-bp internal fragment of ror.

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FIG. 3. Creation of replication-deficient ${phi}$ Sa3ms. (a) An internal fragment of ror was cloned into the temperature-sensitive shuttle vector pBT9, creating pPS79, and used to insertionally inactivate ror through plasmid integration into the MSSA476 chromosome. (b) Southern blot analysis comparing the amounts of ${phi}$ Sa3ms DNA (sea probe) and chromosomal DNA (dnaN probe) in MSSA476 and MS79 (ror::pPS79) in the absence and presence of mitomycin C.

Southern blot analyses revealed that mitomycin C treatment ofMSSA476 resulted in a large increase in the ${phi}$ Sa3ms copy number,as indicated by the increased intensity of the sea hybridizingband (Fig. 3b, lanes 1 and 2). A probe for a chromosomal gene,dnaN, was used as a loading control for these experiments. Insertionalinactivation of ror in MS79 eliminated the increase in ${phi}$ Sa3msreplication seen after mitomycin C treatment (Fig. 3b, lanes3 and 4). These results demonstrate that mitomycin C treatmentleads to ${phi}$ Sa3ms replication and that pPS79 integration into roreliminates ${phi}$ Sa3ms replication.

In marked contrast to the pronounced increases in sea and saktranscription in MSSA476, there were no detectable increasesin sea or sak transcription after mitomycin C treatment of MS79cultures (Fig. 4), suggesting that ${phi}$ Sa3ms replication is criticalfor the enhanced sea and sak transcription observed followingprophage induction. An alternative explanation is that the integrationof pPS79 into ror blocked the expression of an activator ofsea and sak transcription. The absence of any higher-molecular-weightsea or sak transcripts in mitomycin C-treated MS79 culturessuggests that in addition to the replication deficit in theMS79 ${phi}$ Sa3ms mutant, activation of latent phage promoters doesnot occur in this background. The relative contributions ofreplication and latent phage promoter activation to the increasesin sea and sak transcription that accompany prophage inductioncannot be determined from analysis of MS79. Presumably, bothprocesses contribute to the increases in sea and sak transcriptionthat occur upon ${phi}$ Sa3ms induction.

${phi}$ Sa3ms induction leads to increases in seg2 and sek2 transcripts. We also investigated whether mitomycin C treatment of MSSA476affected the levels of seg2 and sek2 transcripts. The directionof transcription of these two virulence factors is oppositethe direction of transcription of sea and sak, and seg2 andsek2 are located at the opposite end of the ${phi}$ Sa3ms prophage (Fig.1). Two seg2 hybridizing species and three sek2 hybridizingspecies were detected in Northern blots of RNA isolated fromuninduced MSSA476 cultures (Fig. 5a and b). Addition of mitomycinC to MSSA476 cultures increased the levels of all hybridizingspecies of both seg2 and sek2 (Fig. 5), although the magnitudeof the increase was not as great as the magnitude of the increaseobserved with sea and sak. Unlike the lack of an effect of mitomycinC on sea and sak transcription in MS79, mitomycin C treatmentelevated seg2 and sek2 transcript levels to similar degreesin MS79 and MSSA476 (Fig. 5a and b). These findings suggestthat the levels of seg2 and sek2 expression are not influencedby phage replication or latent promoter activation.

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FIG. 5. Enterotoxin genes seg2 and sek2 are cotranscribed with the ${phi}$ Sa3ms repressor gene cI. The Northern blot shown in Fig. 4 was stripped and reprobed with either seg2 (a), sek2 (b), or cI (c).

The Northern blots probed with seg2 and sek2 probes both showedthat 4.2- and 2.5-kb hybridizing fragments were present (Fig.5a and b). This observation, along with the fact that seg2 andsek2 are adjacent and are transcribed in the same direction,suggested that these two transcripts contain both enterotoxingenes. Since both genes together span only $~$ 1.6 kb, these twotranscripts are also likely to include either the upstream cIgene or the downstream int gene (or both in the case of the4.2-kb mRNA). To investigate these possibilities, the Northernblots described above were stripped and reprobed with a cI probe.As shown in Fig. 5c, 2.5- and 4.2-kb cI-encoding mRNAs weredetected, in addition to a new 1.5-kb transcript, suggestingthat there is transcriptional coupling of cI, seg2, and sek2.To further investigate this, 5' RACE was used to map the 5'transcriptional start site of seg2. We found that cDNA synthesizedwith a primer within seg2 (SEQR [Fig. 6a]) extended beyond the5' end of cI (Fig. 6b, lane 3), indicating that at least someof the transcription of seg2 initiates upstream of cI. The threecI transcripts that were different sizes, all of which presumablyinitiate from the same site, could arise by inefficient termination,antitermination of RNA polymerase, or posttranscriptional RNAprocessing. The relative locations of the 4.2- and 2.5-kb transcriptsare shown in Fig. 6a. The presence of a sek2 transcript thatdoes not contain seg2 (the 1.5-kb transcript [Fig. 5b]) impliesthat there is a functional promoter upstream of sek2. Sincethese data show that the enterotoxin genes seg2 and sek2 aremostly transcribed from the upstream cI promoter, it followsthat factors effecting transcription of cI also regulate seg2and sek2 transcription.

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FIG. 6. 5' RACE analysis of cro and seg2 transcription start sites. (a) Physical map showing the organization of the left end of ${phi}$ Sa3ms. The relative positions of the primers used in the gel shown in panel b are indicated, as are the positions of the 2.5- and 4.2-kb transcripts (Fig. 5) and probes 2 and 3 (Fig. 8). CRORA and SEQR were used in reverse transcription reactions to create cro and seg2-cI cDNA, respectively. (b) Ethidium bromide-stained gel showing the products of 5' RACE reactions. Lanes 1 and 2, PCRs performed with primers MSREP2 and AAP with cro cDNA as the template (tailed in lane 1 and not tailed in lane 2); lanes 3 and 4, PCRs performed with primers CISF and AAP with seg2-cI cDNA as the template (tailed in lane 3 and not tailed in lane 4); lane M, DNA size marker.

Mapping the cI and cro transcription initiation sites. As induction of ${phi}$ Sa3ms into the lytic cycle led to significantincreases in sea, sak, seg2, and sek2 transcription, we investigatedthe genetic switch controlling the ${phi}$ Sa3ms lytic-lysogenic cycle.We concentrated on the ${phi}$ Sa3ms cI and cro homologues, two criticalmediators of the ${lambda}$ genetic switch (39). In ${lambda}$ , CI production resultsin establishment of lysogeny and repression of the majorityof the ${lambda}$ genes. Conversely, ${lambda}$ Cro production results in repressionof cI expression, derepression of phage-encoded genes, and inductionof ${lambda}$ into lytic growth. As a first step toward understandinghow the ${phi}$ Sa3ms cI and cro homologues are regulated, we identifiedthe putative transcriptional start sites of cI and cro by 5'RACE. To identify the cI start site, the 450-bp PCR productdiscussed above (Fig. 6b, lane 3) was sequenced. The cro transcriptionalstart site was identified by sequencing the 200-bp PCR productfrom Fig. 6b, lane 1. Figure 7 shows the putative transcriptionalstart sites for cI and cro and their corresponding -10 and -35promoter sequences. The -10 and -35 sequences are consistentwith typical staphylococcal promoters (34).

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FIG. 7. Locations of putative CI and Cro binding sites with respect to the likely cI and cro transcriptional start sites and promoter regions. Coding sequences are indicated by gray type, and noncoding sequences are indicated by black type. The transcription start sites of the divergently transcribed cI and cro genes are indicated by boxes. Putative -10 and -35 promoter sequences are underlined. The putative Cro and CI inverted repeat binding sites are shaded and are below converging arrows, respectively.

CI and Cro binding sites are present in the region between cI and cro. Inspection of the sequence of the region between the divergentcI and cro genes resulted in identification of two differentinverted repeat sequences that might serve as CI and/or Crobinding sites (Fig. 7). One inverted repeat sequence is presentonce at the 3' end of cro and twice in the cI-cro intergenicregion; since one of these sequences overlaps the putative cropromoter, it was a good candidate CI operator for repressionof cro transcription. The putative Cro binding site occurs oncein the ${phi}$ Sa3ms genome and overlaps the -35 sequence of the cIpromoter, again suggesting a mechanism of action, this timefor Cro prevention of cI transcription.

${phi}$ Sa3ms CI and Cro were overexpressed and purified from E. colias C-terminal His-tagged fusion proteins and tested for theability to bind to different regions of the ${phi}$ Sa3ms genome inband shift assays. CI bound to a region of the ${phi}$ Sa3ms genomethat contained a single copy of the putative CI binding site(probe 2) but did not bind to a region containing only a half-sitefrom the orf49-orf50 intergenic region (probe 1) (Fig. 8a).Probe 3 consisted of the cI-cro intergenic region and thus containeda single putative Cro binding site and two putative CI bindingsites (Fig. 7). Figures 8b and c show that both CI and Cro boundto probe 3 but not to control probes lacking the correspondinginverted repeat sequences. Two different DNA-protein complexeswere seen when either CI or Cro was incubated with probe 3.Since probe 3 contained two putative CI binding sites, sequentialloading of CI complexes onto the probe could account for theobserved pattern. As there was only a single putative Cro invertedrepeat binding site in this probe, the presence of two shiftedcomplexes suggests that Cro monomers may be able to bind toindividual half-sites; alternatively there may be more thanone sequence to which Cro binds in this region. Supershift experimentsperformed with an anti-His antibody (Fig. 8b and data not shown)confirmed that the shifted DNA protein complexes were due toCI or Cro binding.

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FIG. 8. ${phi}$ Sa3ms CI and Cro specifically bind to specific regions of ${phi}$ Sa3ms DNA. Bandshift assays were performed to test binding of purified C-terminal His-tagged CI (a and b) and Cro (c) to three ${phi}$ Sa3ms-derived probes. Probe 1 was a 147-bp region of ${phi}$ Sa3ms from the region between ORFs 49 and 50 that lacked the putative inverted repeat binding sites of CI and Cro. Probe 2 was a 99-bp region of ${phi}$ Sa3ms that overlapped the 3' end of cro and contained a single putative CI binding site (see Fig. 6a). Probe 3 was a 209-bp region of ${phi}$ Sa3ms that overlapped the cI-cro intergenic region and contained two putative CI binding sites and one putative Cro binding site (see Fig. 6a). Anti-His antibody supershifted the cI-DNA binding complexes in panel b, whereas a negative control antibody (anti-SEA) did not.

DISCUSSION

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Discussion

Phage-encoded toxins were first recognized more than 50 yearsago (19); however, very little is known about the biology androle in pathogenesis of the many phages that encode virulencefactors. Here we identified and annotated a prophage genomein the incomplete genome of the methicillin-sensitive S. aureusstrain MSSA476, an organism that has caused severe community-acquiredS. aureus infections (Nick Day, personal communication). Thisphage, ${phi}$ Sa3ms, contains three enterotoxin genes, sea, seg2, andsek2, along with a gene encoding the fibrinolytic enzyme staphylokinase.The 42,612-bp ${phi}$ Sa3ms genome exhibits extensive similarity tothe genomes of other S. aureus-derived bacteriophages. ${phi}$ Sa3mswas inducible with mitomycin C, and its DNA was detected insupernatants of mitomycin C-treated MSSA476 cultures; however,we did not identify suitable conditions for infecting the nonlysogenicS. aureus strain RN4220.

Mitomycin C treatment of MSSA476 led to increased transcriptionof four ${phi}$ Sa3ms-encoded virulence factors. In the absence of prophageinduction, sea and sak were transcribed at low levels. Prophageinduction with mitomycin C led to marked increases in the amountsof these transcripts, as well as the appearance of new sea andsak transcripts from activation of latent upstream phage promoters.Putative sites for the two latent phage promoters were determined.One site was upstream of the ${phi}$ Sa3ms holin gene; the activationof this promoter led to transcriptional read-through of thedownstream sak gene (2.7-kb mRNA in Fig. 2). The second promoterwas in a region upstream of orf49 and downstream of orf47, theactivation of which led to production of two virulence factor-encodingmRNAs, a 6.8-kb transcript containing both sea and sak and a3-kb transcript containing only sea (Fig. 2). The mechanismsgoverning the production of transcripts of different sizes fromthese latent ${phi}$ Sa3ms promoters are unknown. The possible mechanismsinclude inefficient termination, transcriptional antitermination,and RNA processing. An interesting observation from Fig. 2 isthe presence of late gene phage-specific transcripts at timezero. This may be attributable to a stationary-phase-dependentdecrease in prophage stability, as previously described for ${phi}$ LC3 in lactococci and P22 in Salmonella enterica serovar Typhimurium(30, 40). Evidence in support of this hypothesis comes fromthe lack of phage transcripts at time zero in Fig. 4, as theRNA for this analysis was isolated from cultures that had undergonea greater number of doublings.

The role of ${phi}$ Sa3ms replication in virulence factor productionwas investigated by using MS79 (ror::pPS79). ror was chosenfor insertional inactivation because the Ror homologue in B.subtilis phage SPP1 is essential for replication (38). In contrastto the transcript levels in MSSA476, the sea and sak transcriptlevels were not affected by mitomycin C treatment of MS79. WhileMS79 had a ${phi}$ Sa3ms replication-deficient phenotype (Fig. 3b),the lack of ${phi}$ Sa3ms lytic cycle transcripts (Fig. 4) suggeststhat activation of latent lytic cycle promoters does not occurin MS79. We hypothesize that the pPS79 integration in ${phi}$ Sa3msmay have had a polar effect on expression of an activator (possiblyrinB, which has a role in activation of int transcription in ${phi}$ 11 [49]) required for late gene transcription. As ${phi}$ Sa3ms::pPS79is defective both in replication and in transcriptional activation,the relative contributions of each of these factors to sea andsak transcription cannot be deciphered from analysis of MS79.

While the majority of S. aureus phage-encoded virulence factorsare located downstream of phage lysis genes, ${phi}$ Sa3ms and ${phi}$ Sa3mware unique due to the positions of virulence factors betweenthe repressor and integrase genes of these phages. The increasesin seg2 and sek2 transcription following prophage inductionwere less pronounced than the increases in sea and sak transcription.The majority of the seg2 and sek2 transcripts were found toinitiate from the promoter upstream of the ${phi}$ Sa3ms repressor genecI, showing that cI, seg2, and sek2 are part of an operon. Thetranscript sizes and the orientation of genes downstream ofcI suggest that the 4.2-kb cI transcript also contains the downstreamint gene. The identical transcriptional profiles of cI, seg2,and sek2 from MSSA476 and MS79 cultures (Fig. 5) revealed thatneither ${phi}$ Sa3ms replication nor latent promoter activation playsa role in the transcription of these genes. Furthermore, thesedata suggest that factors which regulate cI transcription alsoregulate transcription of seg2, sek2, and int. Read-throughtranscription of SE genes and int from a repressor gene wassuggested by the work of Yarwood and colleagues (48) in whichthey showed by microarray analysis that int, seq, and sek ofSaPI3 have the same transcriptional profiles as the surroundinggenes, with the first gene in the operon encoding a CI-likerepressor (48). The constant transcription of int in a lysogenhas important implications for the regulation of ${phi}$ Sa3ms integrationand excision.

Since the life cycle of ${phi}$ Sa3ms determines transcription of itsencoded virulence factors so dramatically, the putative lysogenymodule of ${phi}$ Sa3ms was analyzed. The ${phi}$ Sa3ms CI and Cro proteinsbound the region between the divergently transcribed cI andcro genes (Fig. 8), and the locations of the putative CI andCro binding sites suggest that Cro binding prevents cI transcriptionand vice versa. This putative transcriptional repression throughCI or Cro binding may be similar to that described for phage ${lambda}$ (39). ${phi}$ Sa3ms appears to differ from ${lambda}$ , however, by the presenceof separate CI and Cro operator sequences and by the increasein ${phi}$ Sa3ms cI expression that occurs after mitomycin C treatment.The latter observation is difficult to reconcile with the increasesin cro levels that occur with prophage induction (data not shown).Further investigation is required to understand how the ${phi}$ Sa3mslytic switch functions; it appears that the molecular detailsof this switch differ from those of the ${lambda}$ switch.

The work described here showed that ${phi}$ Sa3ms prophage inductionleads to transcriptional up-regulation of four ${phi}$ Sa3ms-encodedvirulence factors. Whether the mitomycin C-stimulated increasesin sak, sea, seg2, and sek2 transcripts lead to increases inthe levels of the corresponding proteins is currently unknown.However, the results of initial experiments exploring SEA productionfollowing mitomycin C treatment did not reveal parallel dramaticincreases in SEA levels mirroring the increases observed insea transcripts after ${phi}$ Sa3ms induction (data not shown). Additionalevidence in support of the idea that posttranscriptional regulationinfluences SEA production comes from the work of Borst and Betley(6-8), who suggested that factors in addition to sea mRNA levelsaffected SEA production.

The list of phage-encoded virulence factors continues to grow(for reviews see references 9 and 45) as the number of sequencedbacterial genomes expands. Lagging behind this expanding genomicinformation is an understanding of the biology of these prophages.Given the recent discovery that at least in one case phage biologycan play an essential role in pathogenicity (45), this gap inour knowledge needs to be addressed. Studies with Shiga toxin-producingE. coli (44) and Streptococcus pyogenes (10) revealed that prophageinduction leads to an increase in production of phage-encodedvirulence factors. There is accumulating evidence that prophageinduction occurs in vivo (11, 43, 44, 46), raising the possibilitythat host factors that promote prophage induction may play animportant role in pathogenesis. The increased transcriptionof sea and sak upon prophage induction and the location of thesegenes interspersed with the lysis genes are similar to the increasedtranscription and location of the stxAB genes in Shiga toxin-producingE. coli. However, seg2 and sek2 differ from stx in both theirlocation within the phage genome and in their level of transcriptionalup-regulation upon phage induction. The different effects of ${phi}$ Sa3ms induction on transcription of sea and sak and on transcriptionof seg2 and sek2 may be explained by their relative insertionsites in the ${phi}$ Sa3ms genome. Insertion of seg2 and sek2 downstreamof the repressor gene guarantees constitutive expression ofthese genes during lysogeny due to the absence of an efficientterminator downstream of cI, while the clustering of sea andsak with the ${phi}$ Sa3ms lysis genes enables a burst of expressionupon ${phi}$ Sa3ms late gene transcription. It is tempting to speculatethat the sites of insertion of virulence genes in phage genomesmay be subject to selection that optimizes the phage controlof expression of the genes for pathogenicity.

ACKNOWLEDGMENTS

We thank Tim Foster, John Iandolo, Jean Lee, and Kimberly Jeffersonfor strains and plasmids. We also thank the NEMC GRASP DigestiveDisease Center for media, Anne Kane for purification of CI andCro, Nick Day for information about MSSA476, and the SangerCentre for release of the MSSA476 genome sequence before publication.Finally, we thank Harvey Kimsey and Anne Kane for critical commentson the manuscript.

This work was supported by NIH grant AI42347 and by the HowardHughes Medical Institute.

FOOTNOTES

* Corresponding author. Mailing address: Tufts Medical School, Department of Microbiology, 136 Harrison Ave., Boston, MA 02111. Phone: (617) 636-2730. Fax: (617) 636-2723. E-mail: matthew.waldor{at}tufts.edu.

Present address: Laboratory of Human Bacterial Pathogenesis,Rocky Mountain Laboratories, National Institute of Allergy andInfectious Diseases, National Institutes of Health, Hamilton,MT 59840.

REFERENCES

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