Occurrence of ssl genes in isolates of Staphylococcus aureus from animal infection

doi:10.1099/jmm.0.46878-0

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Occurrence of ssl genes in isolates of Staphylococcus aureus from animal infection

Davida S. Smyth¹^,, William J. Meaney², Patrick J. Hartigan³ and Cyril J. Smyth¹

¹ Department of Microbiology, Moyne Institute of Preventive Medicine, Trinity College, University of Dublin, Dublin 2, Ireland

² Teagasc, Dairy Production Research Centre, Moorepark, Fermoy, Co. Cork, Ireland

³ Department of Physiology, School of Medicine, Trinity College, University of Dublin, Dublin 2, Ireland

Correspondence
Cyril J. Smyth
csmyth{at}tcd.ie

Received 6 August 2006
Accepted 26 October 2006

The occurrence of 7 of the 11 known ssl genes that are foundwithin the vSa ${alpha}$ genomic island of Staphylococcus aureus and encodethe novel Ssl family of exoproteins was examined in isolatesfrom cows (42 isolates), goats (4 isolates), sheep (1 isolate),rabbits (3 isolates) and chickens (2 isolates). Based on sevenS. aureus genome sequences for human strains NCTC 8325, N315,Mu50, COL, MRSA 252, MW2 and MSSA-476, and bovine strain RF122,along with the ssl reference gene sequences from strains NCTC6571, FRI326 and NCTC 8325, ClustalW-generated alignments wereused to design PCR primers for unique regions of the ssl genesthat are present in the allelic variants of each, except forthe ssl4 gene for which specific primers for the set2 and set9allelic variants were designed individually. The genotypes ofisolates were determined using random amplified polymorphicDNA (RAPD) typing. All of the animal-associated S. aureus isolatescontained an ssl locus, but there were minor variations in thenumber of ssl genes present. Forty-nine of the animal isolatespossessed a vSa ${alpha}$ genomic island containing the ssl3 (set8), ssl5(set3/set10), ssl7 (set1/set11), ssl8 (set12), ssl9 (set5/set13)and ssl10 (set4/set14) genes. One bovine and one goat isolatelacked the ssl3 gene. The ssl9 gene was absent in one bovineisolate. The goat isolate lacking the ssl3 gene was the onlyanimal isolate that possessed the set2 allele of the ssl4 gene.PCR for the set9 allele of the ssl4 gene was inconclusive. Isolatesthat showed identical RAPD fingerprints had the same complementof ssl genes, but the ssl gene pattern was not RAPD-type specific.Southern blot hybridization showed similar ssl gene RFLPs inisolates of the same RAPD type.

Abbreviations: RAPD, random amplified polymorphic DNA.

${dagger}$ Present address: New York Medical College, Department of Microbiologyand Immunology, Valhalla, NY 10595, USA.

INTRODUCTION

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INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Staphylococcus aureus causes a wide variety of clinical syndromesranging from uncomplicated infections of the skin, such as boilsand carbuncles, to life-threatening infections, such as endocarditisand toxic shock syndrome (Murray, 2005; Todd, 2005). S. aureusis also an important pathogen of animals including cows, goats,sheep, rabbits and chickens (Rich, 2005; Barkema et al., 2006).Among the many known virulence factors of S. aureus are threegroups of staphylococcal exoproteins: the enzymes such as hyaluronidase,proteases and nucleases; the non-enzymic activators of plasmaclotting (coagulase) and fibrinolysis (staphylokinase); andthe exotoxins, namely, cytolytic toxins, exfoliative toxins,leukocidins, enterotoxins, enterotoxin-like proteins and toxicshock syndrome toxin no. 1 (TSST-1) (Ferry et al., 2005). Theenterotoxins, enterotoxin-like proteins and TSST-1 belong tothe superantigen (SAg) family (Proft & Fraser, 2003). Nineteenstaphylococcal enterotoxins (SEs) and staphylococcal enterotoxin-like(SEl) proteins, as well as a number of variants of some of these,have been described (Smyth et al., 2004; Thomas et al., 2006).

In addition to these superantigens, S. aureus also producesa family of exoproteins termed the staphylococcal exotoxin-like(Set) proteins (Williams et al., 2000), which have since beenrenamed staphylococcal superantigen-like (Ssl) proteins (Lina et al., 2004).The Ssl proteins are encoded by a cluster of genes (also termedgenomic island vSa ${alpha}$ ; Lindsay & Holden, 2004, 2006) that showsequence similarity of 36–67 % (Williams et al., 2000;Kuroda et al., 2001). The vSa ${alpha}$ island is flanked upstream bya putative transposase gene, and downstream by an incompleterestriction and modification system (the hsdS and hsdM genes)forming part of a three-component restriction/modification system(HsdS, HsdM and HsdR) that is believed to maintain the locusin the genome (Kuroda et al., 2001). Although the crystal structuresof the Ssl5 and Ssl7 proteins revealed that these had overallfolding characteristics and the classical two-domain structureof the SAg family, the major histocompatibility complex-bindingsite of superantigens had been lost, accounting for the inabilityof Ssl proteins to induce T-cell proliferation (Arcus et al., 2002;Al-Shangiti et al., 2004)

Microarray analysis using 63 isolates from humans, sheep, cowsand poultry (Fitzgerald et al., 2003) showed that the ssl locuswas present in all of the S. aureus isolates tested, but variedin size from 12 to 17 kb and displayed high levels of sequencevariation. It was theorized that horizontal gene transfer, recombinationevents, and loss of ssl genes had led to this diversity. RecentlyTsuru et al. (2006) compared whole genomic sequences of humanstrains of S. aureus and identified conserved sequences (45and 61 bp repeats flanking indels) between the ssl genesand at identical relative positions, which could be functionallyimportant in generating deletions by homologous recombinationin the variable region between the ssl3 and ssl9 genes.

At the start of this work very limited data were available onthe occurrence of individual ssl genes in S. aureus isolatesfrom animals (Fitzgerald et al., 2003). The aims of this studywere to develop a PCR-based screening method for ssl genes withinthe variable region of the vSa ${alpha}$ genomic island and to investigatethe occurrence of these genes in isolates of S. aureus of animalorigin.

METHODS

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INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Strains. Fifty-two isolates associated with animal S. aureus infections,namely, broiler chicken osteomyelitis (n=2), rabbit staphylococcosis(n=3) and mastitis (cows=42, sheep=1, goats=4), which includedanimal-associated clonal types previously identified by molecularfingerprinting techniques (Rodgers et al., 1999; Fitzgerald et al., 1997,2000; Hermans et al., 2000; Foschino et al., 2002), were examined.These were confirmed to belong to animal-associated clonal typesusing multiple locus sequence typing (Smyth, 2006). Six humancontrol strains, MRSA 252, NCTC 8325-4, MSSA-476, COL and NCTC6571, and one clinical human isolate (strain MSA 2335), werealso used. S. aureus isolates were routinely grown on eithertrypticase soy agar (TSA) (Oxoid) or trypticase soy broth (Oxoid)with shaking at 37 °C. The identification of S. aureus isolateswas verified by testing their ability to grow and produce acidon mannitol salt agar, a positive coagulase test, their abilityto produce acetoin, their ability to grow on TSA supplementedwith 7 µg acriflavin ml^–1 (Devriese, 1981),and a negative PCR for the Staphylococcus intermedius 16S rRNAgene.

Analysis of the S. aureus genome sequences using Artemis and BLASTN and translated amino acid sequences using BLASTX. Seven available S. aureus genome sequences for strains NCTC8325, N315, Mu50, COL, MRSA 252, MW2 and MSSA-476, the ssl referencegene sequences from strains NCTC 6571, FRI326 and NCTC 8325,and the ssl locus sequences of bovine strain RF122 and of threehuman-associated strains JH1, JH9 and USA300 (Table 1)were downloaded and analysed by Artemis, a freeware sequenceanalysis tool available at the Sanger Centre website (www.sanger.ac.uk)and BLASTN (http://www.ncbi.nlm.nih.gov/blast/) to determinethe composition of the ssl locus in each strain. Once a putativeidentity had been assigned to each ORF of each genome sequence,the ORFs from each genome were aligned with each other usingClustalW (www.ebi.ac.uk/clustalW) and ClustalX (ftp://ftp-igbmc.u-strasbg.fr/pub/ClustalX/).

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Table 1. S. aureus genomic sequences and ssl reference gene sequences examined using Artemis and BLASTN/BLASTX

From the analysis it was observed that the ssl genes of eachsequenced S. aureus strain varied in number and composition,and that there were a number of allelic variants of certainssl genes, namely, ssl3 (set8), ssl5 (set3/set10), ssl7 (set1/set11),ssl8 (set12), ssl9 (set5/set13) and ssl10 (set4/set14). A schematicof the ssl loci from 11 human-associated S. aureus strains andthe bovine strain RF122 is shown in Fig. 1

. Using BLASTXit was possible to compare the translated amino-acid sequencesof the ssl genes from the genome sequence of strain N315 withthe amino-acid sequences of the ssl proteins of NCTC 6571, thearchetypal set gene cluster strain, already in the NCBI proteindatabase (Williams et al., 2000). The output of BLASTX showedthat the ssl genes from strains N315 and NCTC 6571 have translatedamino-acid sequence similarities ranging from 29 to 66 % betweenindividual pairs of genes, whereas the tandem paralogues withinthese strains have higher degrees of similarity (76–89%). The translated amino-acid similarities of the ssl3 and ssl4genes in strains N315 and NCTC 6571 were high, with the set2allelic variant of the ssl3 gene (present in strain NCTC 6571)showing 87 % and 76 % translated amino-acid similarity to theset8 and set9 allelic variants of the ssl4 gene (present instrain N315), respectively.

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Fig. 1. Schematic of the ssl locus based on S. aureus genome and ssl locus sequences. The staphylococcal genomes show variation in the number and complement of ssl alleles. There is a central variable region that contains allelic variants of ssl genes, e.g. the ssl5 gene (formerly set3 and set10) and the ssl7 gene (formerly set1 and set11) have variants. Deletions of ssl genes also occur, e.g. the ssl6 gene is only present in strains NCTC 8325, MSSA-476, USA300 and MW2. Strain RF122 is a bovine strain, while the rest are of human origin. The ssl genes are numbered above the diagram. T, putative transposase gene; M, hsdM gene; S, hsdS gene of the restriction and modification system; 8325, NCTC 8325; 6571, NCTC 6571; MSSA, MSSA-476; MRSA, MRSA 252.

DNA isolation. Extraction of genomic DNA from S. aureus was performed as previouslydescribed with minor modifications (Fitzgerald et al., 1997).The procedure involves lysostaphin lysis, proteinase K treatment,addition of EDTA, sarkosyl and cetyltrimethylammonium bromide(CTAB), extraction with chloroform/isoamyl alcohol and phenol/chloroform/isoamylalcohol, and precipitation with ethanol.

Design of primers and PCR analysis. Using ClustalW/ClustalX-generated alignments it was possibleto locate unique regions of each ssl gene that were presentin their respective set allelic variants, except for the ssl4gene. These unique regions were used to design PCR primers forthe ssl alleles, and to amplify PCR products for use as probesin Southern blot hybridization experiments (Table 2). Eachset of primers used the same PCR mix comprising 10 pmolforward and reverse primers, 200 µM each of dATP,dTTP, dCTP and dGTP, 1xmagnesium-free buffer (Promega), 1.5 UTaq DNA polymerase (Promega), 3 mM MgCl₂, and 50–100 ngDNA. PCR tests also included appropriate ssl gene-positive and-negative controls (DNA from reference human strains NCTC 8325-4,MRSA 252, MSSA-476, COL and NCTC 6571).

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Table 2. Primers used in ssl (set) gene PCR

The PCRs used the following cycling parameters: 95 °C for10 min, 15 cycles of (95 °C for 1 min, 58 °Cfor 45 s and 72 °C for 1 min) and 16 cycles of(95 °C for 1 min, 54 °C for 45 s and 72 °Cfor 1 min). The reaction was terminated with a 10 minincubation at 72 °C. PCR products were resolved by electrophoresisin 1.5 % (w/v) agarose gel (0.5x Tris/boric acid/EDTA buffer)(Sambrook & Russell, 2001) at 90 V (constant voltage),stained with ethidium bromide, and visualized using UV light.Product sizes were determined by comparison with a 100 bpladder (Promega).

Southern blotting and ssl gene RFLP analysis. The presence of the ssl locus within isolates that were positiveby PCR was confirmed using Southern blotting of genomic DNAfrom a number of representative Irish and American bovine isolatesfrom the study of Fitzgerald et al. (1997) and human-associatedcontrol strains. Genomic DNA was digested with restriction endonucleaseHindIII, which cuts within the hsdM, hsdS genes of control strainMRSA 252. The resulting fragments were resolved by electrophoresisin 0.8 % agarose. Southern blot hybridization analysis was performedusing standard methods (Sambrook & Russell, 2001) and theDIG-labelling system (Roche). Probes were constructed usingthe PCR DIG-labelling mix (Roche) in PCRs that incorporatedDIG-labelled dUTP into the synthesized DNA. Probes were designedto target genes that were present in all isolates tested andtherefore would allow a comparison of RFLPs across all isolatesanalysed. Probes for the ssl7 and ssl5 genes were amplifiedusing genomic DNA from human strain NCTC 6571, and a probe forthe ssl8 gene using genomic DNA from bovine strain RF122.

Random amplified polymorphic DNA (RAPD) typing. RAPD typing was carried out as previously described (Fitzgerald et al., 1997;Smyth et al., 2006). Briefly it was performed in a final volumeof 25 µl consisting of 1 µl chromosomalDNA (approx. 100 ng), 2 µl 23-mer primer D11344(20 pmol µl^–1) (Akopyanz et al., 1992),2.5 U Taq DNA polymerase (Promega), 2.5 µl 10xbuffer (Promega), 3 µl 25 mM MgCl₂ buffer (Promega),and 0.2 mM dNTPs. The PCR program used was 4 cycles of(94 °C for 5 min, 40 °C for 5 min, 72 °Cfor 5 min) and then 30 cycles of (94 °C for 1 min,55 °C for 1 min, 72 °C for 2 min). Of thePCR products 5 µl was run on a 2 % (w/v) agarosegel. Strains that generated the same banding pattern were consideredto be of the same RAPD type.

RESULTS

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INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

PCR for ssl genes

PCR was done on strains NCTC 8325-4, MSSA-476, MRSA 252, COLand NCTC 6571, each of known genome sequence and ssl gene content,and on a clinical isolate (MSA 2335). The ssl genes tested forwere all amplifiable by PCR and the results for these strainswere consistent with their ssl genomic island sequences (Table 3,Fig. 1). PCR analysis of the animal-associated S. aureusisolates showed that, whereas all of them contained an ssl locus,there were minor variations in the number of ssl genes encoded(Table 3). The ssl5, ssl7, ssl8 and ssl10 genes were presentin all of the animal-associated isolates. The ssl9 gene waspresent in all isolates bar one bovine isolate, namely, isolateMSA1455. The ssl3 gene was present in 50 of the 52 animal-associatedisolates tested, except for one bovine (MSA1003) and one caprineisolate (St24).

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Table 3. Combinations of ssl genes in 52 isolates of S. aureus of animal origin and 6 control human strains

The set2 allelic variant of the ssl4 gene was found to be presentin 1 of the 52 animal-associated isolates (St24 from a goat).In contrast to PCR findings with strains NCTC 8325, MSSA-479and COL PCR, for each of which the set9 allelic variant of thessl4 gene was amplifiable using the designed primers (Fig. 1

,Table 2

), PCR for the ssl4 (set9) allele with the animalisolates was inconclusive. The primers for the set9 allelicvariant of the ssl4 gene generated multiple non-specific productswith the animal isolates, including strain RF122, which is knownto lack the ssl4 gene based on the genomic sequence data (Fig. 1

).This implies that the primers could anneal to other targets,possibly ssl-like sequences, in the animal isolates. While 5other isolates (RF102, RF108, RF110, FR120 and RF121) includedin this study are of the same RAPD type 33 as strain RF122 (seebelow and Table 3

), and thus might be surmised to lackthe ssl4 gene, it seems highly likely that a number of the other45 animal isolates might test positive for the set9 allelicvariant of the ssl4 gene with redesigned primers as it occupiesthe same position as the set2 variant. The PCR assay has asyet to be extended to screen animal isolates for the ssl6 gene(Fig. 1

, strains NCTC 8325, MSSA-476 and MW2).

RAPD typing

A total of 26 of the 42 bovine isolates (16 Irish and 10 American)together with the 10 isolates from rabbits, sheep, goats andchickens were RAPD typed. Although isolates that showed identicalRAPD fingerprints had the same complement of ssl genes (Table 3),the ssl gene pattern was not RAPD-type specific due to the highcommonality in the ssl locus in the tested animal isolates.

Southern blot hybridization for ssl genes

The ssl5, ssl7 and ssl8 probes appeared to be specific for theirtarget ssl genes. Southern blot hybridization experiments wereperformed on representative bovine isolates – isolatesRF103 and MSA1369 (RAPD type 11), isolates RF115, RF116 andRF117 (RAPD type 16), isolates RF108 and RF122 (RAPD type 33)and isolates MSA1058 and MSA1369 (RAPD type not determined)– and human isolates MSSA-476, MRSA 252, COL and NCTC6571. The clonally related isolates by RAPD typing showed similarssl gene RFLPs, whereas unrelated strains had dissimilar RFLPs(data not shown).

DISCUSSION

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INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

In the current study, the ssl locus was found to be presentin every animal-associated isolate, but showed minor variationsin gene content by PCR and polymorphisms in RFLP patterns inSouthern blots. The ssl locus had been reported in 49 S. aureusisolates from humans, 8 isolates from cows, 2 isolates fromsheep, 2 isolates from poultry and 2 isolates of unknown speciesorigin (Fitzgerald et al., 2003). However, no group had lookedfor the individual ssl genes with the exception of the set1allelic variant of the archetypal gene ssl7 (Williams et al., 2000).The combination of ssl genes and their RFLP patterns in isolatesof animal origin seem to reflect clonal relationships as revealedby RAPD typing, supporting the view that the locus is stablein the genome.

Twenty-nine of the isolates tested herein for ssl genes hadbeen previously analysed for mitogenicity (Smyth et al., 2005).Of these 12 were non-mitogenic and negative for 16 SAg and SAg-likegenes, and 14 were mitogenic and encoded SAg and SAg-like genes(Table 3). One isolate (RF103) was mitogenic and negativefor SAg and SAg-like genes (the selp, selr, selu, selu2 andselv genes had not been tested for). The remaining two isolatesexhibited borderline mitogenicity, one of which (isolate MSA17.1)possessed SAg and SAg-like genes, whereas the other (isolateMSA1468) did not. SAg and SAg-like gene-negative isolates (Table 3)that were shown to encode the ssl locus were non-mitogenic.The ability to stimulate T-cells in a Vß-restrictedmanner is a hallmark of SAg activity. While species-restrictedeffects cannot be ruled out given that the animal isolates weretested on human T-lymphocytes, Ssl proteins associated withisolates of animal origin would appear not to be mitogenic,and thus not superantigenic, on the basis of this correlativeanalysis, which is in agreement with previous authors (Arcus et al., 2002;Fitzgerald et al., 2003; Al-Shangiti et al., 2004, 2005).

Langley et al. (2005) demonstrated that immobilized Ssl7 proteinbound human IgA H-chain and L-chain, and human complement componentC5 ${alpha}$ and C5ß chains. Allelic variants of the Ssl7 proteinwere not altered in immunoglobulin- or complement-binding activities.These studies suggested that Ssl proteins are members of a muchlarger family of molecules with varied activities designed tobind serum components involved in host immunity. Thus, the Sslproteins are likely involved in the interaction with S. aureuswithin various environments in different animal species. Allelicvariation of the ssl gene cluster between animal-associatedstrains may confer an adaptive advantage to diverse conditionsduring infection of different animal tissues.

It has been demonstrated that strain COL expresses its ssl genesconcurrently and that multiple ssl genes are expressed duringhuman infection, as evidenced by Western immunoblotting usingsera from acute and convalescent patients (Arcus et al., 2002;Fitzgerald et al., 2003; Al-Shangiti et al., 2005). However,not all of the Ssl proteins are immunogenic. Expression of thessl genes in vitro has yet to be shown for isolates from animalinfection, and in vivo expression has not been demonstrated.Preliminary data using bovine sera from cows with and withoutmastitis has shown that the Ssl proteins, unlike proteins encodedby the egc (enterotoxin gene cluster) locus, are expressed inthe host (Smyth, 2006). If multiple ssl genes are concurrentlyexpressed during animal infection, the ssl genes may play animportant role in staphylococcal pathogenicity, a suggestiongiven credence by the fact that every isolate tested hereinhad an ssl locus. As has been described for staphylococcal enterotoxins,such as Sec-ovine and Sec-bovine, it is possible that animal-specificalleles of the ssl genes exist, the gene products of which mighthave particular functions in the infection of different animalhosts, e.g. recombinant Ssl7 protein from a bovine-associatedstrain might show higher affinity for bovine IgA. In vitro andin vivo expression studies of ssl genes of animal strains andaffinity studies of Ssl proteins from animal-associated strainsfor IgA and complement factor C5 of the same animal origin aremerited.

Aguiar-Alves et al. (2006) have newly described a genotypingmethod based on single nucleotide polymorphisms within sequencedPCR-amplified internal fragments of the set2, set5 and set7genes (ssl4, ssl9 and ssl2 genes, respectively). This methodwas applied to clinical meticillin-resistant and meticillin-susceptibleS. aureus isolates allowing differentiation of 61 isolates into22 distinct subgroups, designated exotoxin sequence types. Asindicated herein, RFLP patterns of selected ssl genes may haveuseful applications in epidemiology and typing, especially forlaboratories without sequencing capabilities.

ACKNOWLEDGEMENTS

Warmest thanks to Robert Foschino, José R. Penadés,John D. Rodgers, Tore Tollersrud, Dieter Vancraeynest and PetraWinter who originally donated animal-associated strains usedin this study, and to Keiichi Hiramatsu, Sean P. Nair, J. RossFitzgerald and John D. Fraser for providing helpful advice.Davida Smyth was supported by a Teagasc Walsh fellowship. Thisproject was supported by a Teagasc research project grant numberMKDC-0104-5067.

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