A Nonsense Mutation in agrA Accounts for the Defect in agr Expression and the Avirulence of Staphylococcus aureus 8325-4 traP::kan

TraP is a triply phosphorylated staphylococcal protein thathas been hypothesized to be the mediator of a second Staphylococcusaureus quorum-sensing system, "SQS1," that controls expressionof the agr system and therefore is essential for the organism'svirulence. This hypothesis was based on the loss of agr expressionand virulence by a traP mutant of strain 8325-4 and was supportedby full complementation of both phenotypic defects by the clonedtraP gene in strain NB8 (Y. Gov, I. Borovok, M. Korem, V. K.Singh, R. K. Jayaswal, B. J. Wilkinson, S. M. Rich, and N. Balaban,J. Biol. Chem. 279:14665-14672, 2004), in which the wild-typetraP gene was expressed in trans in the 8325-4 traP mutant.We initiated a study of the mechanism by which TraP activatesagr and found that the traP mutant strain used for this andother recently published studies has a second mutation, an adventitiousstop codon in the middle of agrA, the agr response regulator.The traP mutation, once separated from the agrA defect by outcrossing,had no effect on agr expression or virulence, indicating thatthe agrA defect accounts fully for the lack of agr expressionand for the loss of virulence attributed to the traP mutation.In addition, DNA sequencing showed that the agrA gene in strainNB8 (Gov et al., J. Biol. Chem., 2004), in contrast to thatin the agr-defective 8325-4 traP mutant strain, had the wild-typesequence; further, the traP mutation in that strain, when outcrossed,also had no effect on agr expression.

INTRODUCTION

Top

INTRODUCTION

Staphylococcal virulence is largely the province of a largeset of extracellular proteins that enable the organism to resisthost defenses, attach to the tissue matrix, degrade macromolecules,and lyse cellular elements. This constellation of functionsis known as the virulon. The production of staphylococcal virulencefactors is coordinately controlled by an intricate regulatorynetwork involving several two-component signaling modules anda family of homologous winged-helix transcription factors (1,3). Central to this regulatory network is the quorum-sensingagr two-component signaling module, which triggers expressionof the virulon in response to population density (12). We haverecently encountered attenuated clinical strains that possessthe wild-type agr sequence but do not express it (19), suggestingthat there may be genes extrinsic to the agr locus that stringentlycontrol its expression. As identification and characterizationof such genes would be basic to our understanding of virulenceregulation in staphylococci, we noted with great interest reportsthat the staphylococcal gene traP (not to be confused with theEscherichia coli conjugation gene, traP) is absolutely requiredfor agr expression (2, 5). Accordingly, we have initiated studiesto determine the role of this gene in agr activation. TraP isa phosphoprotein with three conserved histidine residues, whichmust all be phosphorylated for the protein to activate agr (5).TraP phosphorylation is induced by RAP, a secreted form of ribosomalprotein L2, and is inhibited by RIP, a synthetic heptapeptide,YSPWTNF (2). Rap-Trap is thus considered to represent a secondagr activation pathway, designated "SQS1" (8), which is superficiallysimilar to the second activating pathway in the competence-regulatingsystem of Bacillus subtilis, which uses the CSF peptide (10).

We were surprised to find, however, that TraP does not, in fact,have any role in agr activation and is not involved in virulence.Therefore, no second agr activation pathway has yet been identified.We find that the derivative of strain 8325-4 containing thetraP mutation used in recent studies (5) has an adventitiousstop codon in agrA that eliminates agr activation. This mutationis responsible for the failure of the traP mutant to expressagr, for its avirulence in the murine abscess model (5), andfor the identity of the traP transcriptome with that of agr(7). These findings are entirely consistent with two other reports(15, 20) demonstrating that traP mutations have no effect onagr expression or virulence.

MATERIALS AND METHODS

Top

MATERIALS AND METHODS

Bacterial strains and culture conditions. Bacterial strains are listed in Table 1. Several different versionsof the common laboratory strains COL and 8325-4 have been used;since both of these strains are known to vary in their agr expression,we considered it necessary to identify their sources, whichare indicated in parentheses. Thus, 8325-4(NB) was kindly providedby Naomi Balaban and 8325-4(BW) by Brian Wilkinson. 8325-4(RN)is our lab version of the same strain, and COL(BW) is BrianWilkinson's version of COL. "-s" after the parentheses indicatesthat a single colony was isolated from the original plate. Balabanand Wilkinson also have sent us four different isolates, eachcontaining a kanamycin resistance (Km^r) cassette (kan) insertedin the traP coding region, inactivating the gene. Although thetraP::kan loci of these four strains are apparently identical,we have numbered them sequentially, as they were analyzed separately.8325-4traP-1(BW) and COLtraP-2(BW) were provided by Wilkinson,while 8325-4traP-3(NB) and NB8, which is 8325-4traP-4 harboringpYG14, were provided by Balaban. We have transduced traP::kanfrom all four strains to different recipients. Transductantswere named by adding an indication of the donor traP::kan insertion(t1, t2, t3, or t4, referring to the above four traP isolates,respectively) to the recipient strain designation. Thus, 8325-4(RN)t3is the traP::kan derivative of 8325-4(RN) in which the traPmutation was transduced from 8325-4traP-3(NB), a strain providedby Balaban. These notations are used throughout the text, tables,and figures.

View this table:
[in this window]
[in a new window]

TABLE 1. S. aureus strains and plasmids

Bacterial cultures were stored at –80°C and were grownon GL agar (13) supplemented with antibiotics as required forplasmid selection (erythromycin, chloramphenicol, or tetracycline,all at 10 µg/ml), on commercial sheep blood agar (SBA)(from BBL), or in CY broth (13). Culture density was monitoredwith a Molecular Devices microtiter plate reader at 650 nm.Blood agar plates were photographed with an ${alpha}$ -Innotech imagerafter 18 h of growth at 37°C. Phage lysates were preparedand used for transduction as previously described (13).

Determination of hemolytic activities and protease production. Qualitative evaluation of ${alpha}$ -, ß-, and ${delta}$ -hemolysin productionwas evaluated on SBA as shown in Fig. 1. Protease productionwas evaluated on casein agar as described by Karlsson et al.(6).

View larger version (28K):
[in this window]
[in a new window]

FIG. 1. Schematic illustration of hemolytic activities on SBA. Bacteria to be tested (horizontal black bars) are streaked at a right angle to RN4220 (vertical black bar) and the plate incubated overnight. ß-Hemolysin forms a turbid zone of hemolysis surrounding the vertical streak of RN4220. ${delta}$ -Hemolysin and ß-hemolysin are synergistic, producing a zone of clear hemolysis where they intersect. Three such zones are shown. At the upper right is a strain producing only ${delta}$ -hemolysin. Below that is a strain producing all three hemolysins. The ${alpha}$ -hemolysin zone is more turbid than seen with ${alpha}$ -hemolysin alone because of inhibition by ß-hemolysin. In this case, ${delta}$ -hemolysin produces a narrow clear zone surrounding the streak owing to its interaction with ß-hemolysin. At the upper left is a nonhemolytic strain; next is a strain producing ${alpha}$ -hemolysin and ${delta}$ -hemolysin. The V-shaped zone is characteristic of the intersection of ${alpha}$ -hemolysin and ß-hemolysin zones, as ${alpha}$ -hemolysin and ß-hemolysin are mutually inhibitory. Within the region of intersection, ß-hemolysin and ${delta}$ -hemolysin interact to give a region of greater clearing than that seen with ${alpha}$ -hemolysin alone. At the lower left is a strain producing only ß-hemolysin.

Determination of exoprotein profiles. Cultures were grown for 6 h in CY broth without glucose; 1.5-mlaliquots were centrifuged to remove bacteria and then analyzedby sodium dodecyl sulfate-polyacrylamide gel electrophoresisaccording to the method of Laemmli (9), stained with Coomassiebrilliant blue, and photographed.

Plasmid screening. Whole-cell lysates for plasmid screening were prepared and analyzedas previously described (13).

PCRs and sequencing of agrA and traP. PCRs used the primer pairs listed in Table 2. Amplificationwas carried out using the following parameters: 30 s of denaturationat 94°C; 40 cycles of amplification at 94°C, 30 s ofannealing at 56°C, and 2 min of extension at 72°C; anda final extension of 10 min at 72°C. For traP, the sameset of primer pairs were used for both PCR and sequencing. ForagrA, primers agrA F and a14 R were used to sequence the PCRproduct amplified by primers agrA F and agrA R. Sequencing wasdone by dye terminator DNA sequencing chemistry (Skirball DNASequencing Core Facility). DNA sequences were analyzed withthe DNAStar sequence analysis suite.

View this table:
[in this window]
[in a new window]

TABLE 2. Primers

RNA preparation and Northern blot hybridization (New York). Cell pellets were treated with RNA Protect reagent (QIAGEN)and mechanically disrupted by agitation with glass beads usingthe Bio101 FastPrep apparatus. RNA was purified using the QIAGENRNeasy kit and its integrity checked by agarose gel electrophoresis.RNA samples corresponding to equal numbers of cells were separatedby gel electrophoresis through 1% denaturing agarose (MOPS [morpholinepropanesulfonicacid]-formaldehyde), vacuum blotted to Hybond N+ membranes (Amersham),and UV cross-linked. Blots were hybridized overnight to [ ${alpha}$ -³²P]dATP-labeled,PCR-generated probes. Washed blots were exposed to phosphorimagerscreens and were read with a Molecular Dynamics PhosphorImager.Primers (Integrated DNA Technologies, Coralville, IA) used forsynthesizing probes are listed in Table 2. Slightly differentmethods were used in Stockholm, as described by Tegmark et al.(17).

Analysis of virulence. Ten-week-old mice of the hairless strain (HRS/J-hr ES10^b/+ES10^b)(Charles River Laboratories) were injected subcutaneously inthe flank area with 10⁹ CFU of the test strain in 100 µlphosphate-buffered normal saline plus Cytodex beads and observeddaily for 5 days, at which time they were photographed and euthanatized.

RESULTS AND DISCUSSION

Top

RESULTS AND DISCUSSION

Some of the results described here were obtained in New Yorkand others were obtained independently in Stockholm, as notedin the figure legends.

Scoring of S. aureus phenotypes. We routinely score hemolytic activities of S. aureus strainson commercially available SBA plates (16) (18), using ${delta}$ -hemolysinand/or ${alpha}$ -hemolysin activity as a surrogate for agr function.It will be recalled that S. aureus produces at least four hemolytictoxins, ${alpha}$ , ß, ${delta}$ , and ${gamma}$ , of which the first three canbe scored directly on SBA and the fourth cannot, as it is inhibitedby agar. ß-Hemolysin, which produces a wide turbidzone, is only weakly regulated by agr, whereas ${alpha}$ - and ${delta}$ -hemolysinsare strongly up-regulated. Additionally, ${delta}$ -hemolysin has veryweak activity on SBA but is strongly synergistic with ß-hemolysin.Accordingly, we cross-streak strains to be tested against RN4220,which produces only ß-hemolysin (17). Since ß-hemolysinpartially inhibits ${alpha}$ -hemolysin, production of the latter is moreeasily detected in ${phi}$ 13 lysogens in which the ß-hemolysingene is insertionally inactivated. RN6734 is a ${phi}$ 13 lysogen, whereas8325-4 is not. These features of hemolysin scoring are illustrateddiagrammatically in Fig. 1. We routinely score protease activityon casein agar plates (6). Protease-positive strains producea white precipitate against a turbid background.

To begin a study of upstream genes required for agr activation,we sought to investigate the mechanism by which traP activatesagr, as revealed by hemolytic activity on SBA and protease activityon casein agar. Gov et al. (5) analyzed a traP mutation in whichthe gene was inactivated by the insertion of a Km^r cassette(5). During the course of these studies, we obtained three pairsof strains, each consisting of a parental traP⁺ strain and atraP::kan derivative with the Km^r cassette inserted in the uniqueEcoRI site of the traP gene (5). Brian Wilkinson provided uswith two pairs of strains: 8325-4(BW) and its traP::kan derivative,8325-4traP-1(BW), and COL(BW) and its traP::kan derivative,COLtraP-2(BW). Naomi Balaban provided us with parental traP⁺strain 8325-4(NB) and its traP::kan derivative, 8325-4traP-3(NB).All three strain pairs were scored on SBA for ${alpha}$ - and ${delta}$ -hemolysins.None of the traP::kan strains made ${alpha}$ - or ${delta}$ -hemolysin, suggestingthat agr was inactive, as reported previously (5). The 8325-4traP-3(NB)parent [8325-4(NB)] appeared normally hemolytic, but the 8325-4traP-1(BW)parent [8325-4(BW)] was only weakly hemolytic, and the COLtraP-2(BW)parent [COL(BW)] was totally nonhemolytic (which was not surprising,since most available COL derivatives are nonhemolytic [unpublishedobservations]). The 8325-4traP-3(NB) strain and its parent werealso scored on casein agar for protease activity. The mutantwas protease negative and the parent was protease positive,consistent with published reports. These observations are summarizedin Table 3.

View this table:
[in this window]
[in a new window]

TABLE 3. Phenotypes of donor and transductant strains

To confirm the role of traP in these strains, we transferredthe traP-inactivating Km^r cassette from each of the traP::kanderivatives to RN6734, our standard agr⁺ strain, and were surprisedto find that in each case all of 10 transductants had the samefully hemolytic phenotype as the recipient strain (Table 3).Typical results with traP-3 are shown in Fig. 2A, lanes 3 and4.

View larger version (74K):
[in this window]
[in a new window]

FIG. 2. Effects of traP-3 on hemolytic activity of S. aureus (experiments performed in New York). (A) Hemolytic patterns on SBA with RN4220 (black streak at top). (B) PCR products obtained with primers that would amplify either traP (0.3-kb band) or traP with the Km^r insert (1.8-kb band). Lanes: 1, 8325-4(NB) from N. Balaban; 2, 8325-4traP-3(NB), also from N. Balaban (note the faint turbid ß-hemolysin zone surrounding this streak); 3, RN6734 (standard agr⁺ traP⁺, ${phi}$ 13 lysogen); 4, RN6734t3 (Km^r traP-3 transductant of RN6734); 5, 8325-4(RN); 6, 8325-4(RN)t3 [Km^r traP-3 transductant of 8325-4(RN)]. (C) Single-colony hemolytic patterns on SBA of the 8325-4(NB) culture provided by N. Balaban, containing at least 3 types of colonies: +, showing zones for ß-hemolysin and ${delta}$ -hemolysin [one of these was isolated and used in further studies and was designated 8325-4(NB)-s ( ${alpha}$ -hemolysin is produced but is difficult to identify in such single colonies)]; n, producing only ß-hemolysin; i, possible intermediate type.

Confirmation of genotypes and phenotypes. At this point, it was clearly necessary to confirm the genotypesof these various strains and to test their phenotypes by moredefinitive means than simply scoring for hemolysis on SBA orproteolysis on casein agar. A PCR performed on each of the traP::kanmutants, the RN6734 transductants, and the corresponding traP⁺parental strains, with the primers as listed in Table 2, allgave the expected products: a 0.3-kb product corresponding totraP for the traP⁺ strains and a 1.8-kb product correspondingto the inserted Km^r cassette for the traP::kan strains. Typicalresults are shown in Fig. 2B. The traP locus for representativeexamples of these various parental and transductant strainswas sequenced, confirming either the native traP sequence orthe inserted Km^r cassette as expected (not shown).

Since the transductions described above were to RN6734, we soughtto rule out the possibility that strain variation could be responsiblefor the observed results, by backcrossing the traP-3 mutationto its 8325-4 parent [8325-4(NB)]. For this backcross, 8325-4traP-3(NB)and the parental strain 8325-4(NB) were restreaked on SBA fromthe confluent growth areas of the original agar plates kindlyprovided by Naomi Balaban. As reported previously (5), the 8325-4traP-3(NB)strain did not produce ${alpha}$ - and ${delta}$ -hemolysins or protease, and 8325-4(NB)produced both. However, as shown in Fig. 2C, the 8325-4(NB)culture was mixed, generating mostly strongly hemolytic colonies,some producing ß-hemolysin only, ( $~$ 20%), and probablyan intermediate type with reduced hemolytic activity ( $~$ 5%). Suchmixtures are typical of 8325-4 stock cultures, owing to thewell-known propensity of agr⁺ strains to throw agr-defectivemutants; indeed, our own 8325-4 stock culture has recently beenfound to contain such a mixture (18). Nevertheless, we consideredit necessary to guard against the possibility that these variantsrepresented contaminants introduced by ourselves. Therefore,to begin work with this strain, three different members of thelaboratory independently prepared similar SBA subcultures fromthe original plate. One of these is illustrated in Fig. 2C;the others were all similar (not shown). We note also that single-colonyisolates of all 8325-4 substrains tested, including a stronglyhemolytic single-colony isolate from the original 8325-4(NB)culture (Fig. 2C), designated 8325-4(NB)-s, breed true duringdaily handling but that agr mutants accumulate during storage(unpublished data). Accordingly, we used 8325-4(NB)-s, whichproduces all three hemolysins, for further study, routinelytesting it on SBA before any experiment, and we have not workedfurther with the other variants seen in Fig. 2C.

Transfer of the traP-3 mutation. Transduction of traP-3 to this single-colony hemolytic isolatewas performed as described above, with selection for Km^r. Allof the Km^r transductants were fully hemolytic and fully proteolytic,indistinguishable from the recipient strain [8325-4(NB)-s] onSBA or on casein agar, ruling out the possibility that the effectsof traP are strain specific. We note that in-frame traP deletionshave recently been constructed in several clinical strains aswell as in 8325-4(RN) by Tsang et al. (20) and that none ofthese had any effect on agr activity. Typical results are shownin Fig. 2A, lanes 5 and 6, and in Fig. 3B. These results suggestedstrongly that traP does not, in fact, control agr-regulatedhemolysins or proteases, and they led to a series of experimentsto test this possibility further. To be absolutely certain thatour traP-3 strains had the correct chromosomal configuration,we performed PCRs, as described above for traP-1 and -2, usingprimers specific for the traP-chromosomal junctions (Table 2).These results, also shown in Fig. 2B and 3A, fully confirmedthe expected genotypes. The traP⁺ strain had the predicted 0.3-kbproduct derived from within the traP gene (Fig. 2B, lane 1,and 3A, lane 5), and all of three traP-3 transductants testedhad the predicted 1.8-kb product generated by the insertionof the Km^r cassette into traP (Fig. 2B, lane 6, and 3A, lanes1 to 3). These findings were also confirmed by sequencing (notshown).

View larger version (54K):
[in this window]
[in a new window]

FIG. 3. Effect of traP-3 on protease production by S. aureus (experiments performed in Stockholm). (A) PCR analysis of traP with (lanes 1 to 4) and without (lane 5) the kan insertion. In lane 4 is 8325-4traP-3(NB) (N. Balaban's traP mutant), and lanes 1 to 3 represent Km^r transductants of 8325-4(RN) with 8325-4traP-3(NB) as the donor. Lane M, size marker; lane C, negative control without bacterial DNA. (B) Protease indicator plate (casein agar) with stabs of the strains shown in panel A. RN6911 is an agr-null strain; note that strain 8325-4traP-3(NB) (N. Balaban's traP-3 mutant) (lane 4), like RN6911, shows no protease activity, whereas the transductants (lanes 1 to 3) are fully active, as is the 8325-4(RN) recipient (lane 5).

Gene expression analysis. If TraP controls agr activation, since it does not control theproduction of agr-regulated hemolysins, perhaps it might affectthe synthesis of other agr-regulated proteins. If so, one wouldexpect clear differences in exoprotein profiles and in geneexpression between traP⁺ and traP::kan strains. Accordingly,we determined exoprotein profiles for several of the strainsdescribed above and performed Northern blotting for RNAIII,the regulatory RNA that is the effector of the agr response(14). In Fig. 4A are shown the exoprotein profiles and in Fig.4C the RNAIII blots, with PCR confirmation in Fig. 4B, as describedabove. Again, with one exception, both the exoprotein profilesand the RNAIII blots are consistent with full agr expressionin the absence as well as in the presence of an intact traPgene. Further confirmation was obtained in an experiment inwhich culture samples taken at the 4- and 6-h time points werealso Northern blotted with an RNAIII probe (Fig. 4C, lanes 7to 10). The exception was the nonhemolytic traP strain [8325-4traP-3(NB)]provided by Naomi Balaban (lane 2), which had an exoproteinprofile typical of agr-null strains (14) and did not producedetectable RNAIII. The apparent lack of any effect of traP-3in the other strains tested raises the question of the basisof the profound deficiency in hemolytic activity and exoproteinproduction seen with this strain.

View larger version (74K):
[in this window]
[in a new window]

FIG. 4. Effect of traP-3 on exoprotein profiles and agr-RNAIII production. (A) Six-hour culture supernatants were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis according to the method of Laemmli (9), stained with Coomassie brilliant blue, and photographed. (B) PCR analysis of chromosomal DNA as in Fig. 3. Lanes: 1, 8325-4(NB); 2, 8325-4traP-3(NB); 3, 8325-4(RN); 4, 8325-4(RN)t3 [Km^r transductant of 8325-4(RN)]; 5, RN6734; 6, RN6734t3 (Km^r transductant of RN6734). (C) Northern blot hybridization analysis of RNAIII. Lanes 7 and 8, 4-h culture samples; lanes 9 and 10, 6-h samples. The samples in lanes 7 and 9 are from an 8325-4(RN) culture; those in lanes 8 and 10 are from an 8325-4(RN)t3 culture. Results shown in lanes 1 to 6 are from experiments performed in New York; those in lanes 7 to 10 are from experiments performed in Stockholm.

The simplest explanation would be that there is an adventitiousagr mutation in the traP-3 derivative of 8325-4. Since suchmutations are common and often affect agrA, we introduced pRN6662,an agrA-expressing plasmid that we have previously used to complementagrA mutations (14), by transduction to the nonhemolytic traP-3derivative of 8325-4, 8325-4traP-3(NB), selecting for the chloramphenicolresistance (Cm^r) marker of the plasmid. All of the transductantscontained the agrA-expressing plasmid and were fully hemolytic,despite the continued presence of the traP-3 mutation, suggestingthat a mutation in agrA was responsible for the agr-defectivephenotype of this strain, rather than the traP-3 mutation. Hemolyticpatterns and confirmation of these genotypes by PCR and Northernblotting are shown in Fig. 5. To confirm the presence of anagrA mutation, we sequenced agrA from chromosomal DNA prepareddirectly from the nonhemolytic 8325-4traP-3(NB) bacteria onthe agar plate provided by Naomi Balaban and found a stop codonat amino acid position 124 (Fig. 6). This has been confirmedwith several other strains derived from this one. These resultsprovide unequivocal evidence that traP has no detectable rolein agr regulation and that, with one exception, the recentlyreported results for traP (5, 7) can all be accounted for byan adventitious mutation in agrA. The exception is the hemolyticstrain NB8, kindly provided by Naomi Balaban, described as atraP derivative of 8325-4(NB) containing pYG14, a traP-expressingplasmid. This plasmid was reported to complement the nonhemolyticand avirulent phenotype of the 8325-4traP-3(NB) strain (5).

View larger version (72K):
[in this window]
[in a new window]

FIG. 5. Complementation of 8325-4traP-3(NB) by cloned agrA but not by cloned traP. (A and B) Hemolytic patterns (A) and PCR analysis (B) as in Fig. 2. (C) Northern blot hybridization patterns using 16S RNA and agr-RNAIII probes as indicated. The same 6-h culture samples used for PCR were also used for whole-cell RNA extraction. RNA samples were separated on agarose and Northern blotted with ³²P-labeled oligonucleotides specific for 16S RNA and agr-RNAIII, respectively. Blots were developed with a phosphorimager. Lanes: 1, 8325-4traP-3(NB); 2, 8325-4traP-3(NB) containing cloned agrA; 3, 8325-4traP-3(NB) containing cloned traP; 4, 8325-4(RN); 5, NB8; 6, 8325-4(RN)t4 [Km^r transductant of 8325-4(RN) with NB8 as the donor].

View larger version (38K):
[in this window]
[in a new window]

FIG. 6. Sequencing of agrA. The electropherogram of the sequencing reaction for agrA in strain 8325-4traP-3(NB) is shown at the bottom, with the deduced nucleotide and amino acid sequences below. At the top is the agrA sequence for strain NB8 in comparison to the 8325-4(RN) agrA sequence from GenBank.

Complementation. How may we account for the hemolytic activity and virulenceof strain NB8? Although we could detect no phenotype for thetraP knockout, it was possible that the presence of traP ona high-copy plasmid might be responsible. We began by confirmingthe presence of both the traP mutation and the traP-expressingplasmid, pYG14, in NB8. As shown in Fig. 5B (lane 5), PCR productscorresponding to both the intact and insertionally inactivatedtraP were present, and the expected plasmid was readily detectablein screening gels (not shown). Moreover, a Km^r transductantof 8325-4(RN) with NB8 as the donor showed the traP-specific1.8-kb PCR product. However, like all other transductants, thistransductant [8325-4(RN)t4] was fully hemolytic and producednormal amounts of RNAIII (Fig. 5C, lane 6). We next determinedthe sequence of agrA in NB8, in comparison to that in the nonhemolytic8325-4traP-3(NB) strain, and found, again to our surprise, thatthe NB8 agrA sequence was the same as that previously determinedfor wild-type agrA (GenBank accession no. SAOUHSC_02265); i.e.,it did not contain the above-mentioned stop codon present inthe nonhemolytic traP strain 8325-4traP-3(NB) (Fig. 6). Additionally,we transduced the traP-containing plasmid from the hemolytictraP strain, NB8, to the nonhemolytic traP derivative of 8325-4,8325-4traP-3(NB), selecting for the erythromycin resistance(Em^r) marker of the plasmid. All of 10 Em^r transductants testedwere nonhemolytic and contained the plasmid (not shown). Theywere phenotypically indistinguishable from the recipient strain,indicating that the cloned traP does not restore hemolysin productionto this strain. PCR analysis confirmed that both intact andinactivated traP genes were present in the plasmid-containingstrains (Fig. 5B, lane 3). Finally, we also transduced the traP-4mutation from NB8 to the agr⁺ 8325-4(NB)-s, and again, all of10 Km^r transductants were fully hemolytic and indistinguishablefrom the recipient strain. As noted above, in-frame traP deletionmutations also had no detectable effect on agr expression (20),ruling out the possibility that a polar effect of the insertedkan cassette may have been responsible for the traP mutant phenotype.The reported complementation, therefore, is explainable by thelack of any agr defect in strain NB8.

Virulence. The results described above suggest that all of the in vitroproperties of the traP mutations containing the kanamycin resistancecassette are attributable to the agrA mutation, and they predictthat this mutation also accounts for the reported avirulenceof the 8325-4traP-3(NB) strain. This prediction was tested with10-week-old hairless immunocompetent mice. We used six strains:RN6734, RN6734t3 (our traP-3 derivative), RN7206 (an agr-nullderivative of RN6734), and RN7206t3 (a double traP-3 agr-nullderivative of RN6734), plus the hemolytic 8325-4(NB)-s and 8325-4(NB)-s-t3(our traP-3 transductant of this strain). Mice were injectedsubcutaneously with 10⁹ CFU plus Cytodex beads in a total volof 100 µl of normal saline, and the resulting lesionswere measured after 5 days.

Several of the mice died in this experiment, because the doseof bacteria that we used, in conformity with the dose used byGov et al. (5), was considerably higher than the 3 x 10⁸ CFUthat we normally use in this model. In this test, both of theagr⁺ traP-3 strains tested were highly virulent. Although, aslisted in Table 4, the lesions may have been slightly smallerthan those with the traP⁺ strain, there was considerable variationand the differences are clearly not significant. Typical lesionsare shown in Fig. 7. Neither the agr nor the agr traP-3 doublemutant caused any measurable lesion at this dosage.

View this table:
[in this window]
[in a new window]

TABLE 4. Effect of traP-3 on abscess formation

View larger version (102K):
[in this window]
[in a new window]

FIG. 7. Effects of traP on virulence in the murine subcutaneous abscess model. See text for details. Odd-numbered mice were infected with traP⁺ bacteria, and even-numbered mice were infected with traP-3. Strains: 1 and 2, 8325-4(NB)-s; 3 and 4, RN6734; 5 and 6, RN7206.

Conclusion. A possible explanation for the presence of an adventitious agrAmutation in the traP strain 8325-4traP-3(NB) is that a transductantwith this mutation was chosen accidentally when traP was initiallytransferred to 8325-4(NB), which we have observed to containnonhemolytic variants (Fig. 2C). This same traP, agrA-defectivestrain was apparently used for the testing of the plasmid-carriedphosphorylation-defective traP mutants (5), as well as for thereported transcriptional profiling (7), so that these resultswould also be due to the agrA mutation.

However, given the results presented above, we are unable toenvision any explanation either for the wild-type agrA sequencein strain NB8 or for the retention of hemolytic activity andvirulence by the same host strain with a traP plasmid containinga mutation in a nonphosphorylatable histidine (5) (Fig. 6 and7).

The results reported here unfortunately call into question theinitial report (2) in which the properties of traP were described.In that report, a traP-inactivating mutation was constructedand tested in the ${alpha}$ - and ${delta}$ -hemolysin-negative strain RN4220, inwhich we have recently demonstrated a partially inactivatingmutation in agrA (18). The reported effects of traP on RNAIIIsynthesis may also have resulted from an additional and adventitiousagr-defective mutation, which would not have been noticed sinceRN4220 produces neither ${alpha}$ - nor ${delta}$ -hemolysin, owing to its agrAdefect. Although it was reported that the primary traP mutationwas outcrossed to 8325-4 and its properties were conserved (2),no data were presented. Unfortunately, neither OU20, the traPmutant derivative of RN4220 used in that study, nor the traP8325-4 transductant are presently available.

ACKNOWLEDGMENTS

This work was supported by NIH research grant R01-AI30138 toR.P.N.

We thank Brian Wilkinson and Naomi Balaban for providing manyof the strains used in the study.

FOOTNOTES

* Corresponding author. Mailing address: Program in Molecular Pathogenesis, Skirball Institute, and Departments of Microbiology and Medicine, New York University Medical Center, New York, NY 10016. Phone: (212) 263-6290. Fax: (212) 263-5711. E-mail: novick{at}saturn.med.nyu.edu

Published ahead of print on 2 July 2007.

Editor: J. B. Bliska

REFERENCES

Top