INTRODUCTION

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Group A streptococci (GAS) may be carried asymptomatically or cause only mild self-limited disease on the skin or mucosal surfaces, but they may also invade deeper tissues and be extremely destructive. GAS infections involving the subcutaneous fascial planes (necrotizing fasciitis), muscles, deep pharyngeal spaces, lungs, or the bloodstream have dire and often fatal consequences. The hallmark of these invasive infections is aggressive spread through tissue and cellular necrosis. In many cases, systemic intoxication with a toxic shock syndrome accompanies local manifestations of infection. To produce these manifestations of invasive disease, GAS possess a large repertoire of known and suspected virulence factors, including M protein, hyaluronic acid capsule, pyrogenic exotoxins A, B (SpeB), and C, streptolysins S and O (SLS and SLO, respectively), streptococcal inhibitor of complement (SIC), C5a peptidase, proteins F and Cpa, streptokinase, hyaluronidase, DNAse, and many others.

With the application of genetic techniques to the analysis of GAS virulence in recent years, there has been considerable progress in understanding the roles that these factors play in streptococcal infection and disease. Some of these factors may be required for successful adherence and colonization of the host at various sites (e.g., lipoteichoic acid, capsule, and protein F). Some may protect GAS from constitutive host defenses (e.g., M protein, capsule, protein G, SIC, and C5a peptidase). Still others may function primarily to destroy tissues and allow streptococci to spread through the host (e.g., streptolysins and hyaluronidase). Thus, GAS possess a large and diverse armamentarium of defensive and offensive weapons which may be adaptive in certain situations. Given this diversity of function, it seems reasonable to assume that the bacteria must be able to sense their microenvironment and to deploy only those virulence factors that function to its advantage in that particular niche. In many pathogenic bacteria, this optimal deployment is accomplished by coordinately regulating the expression of sets of virulence-related factors.

The earliest coordinately regulated network of virulence factors described in GAS followed the discovery of a positive regulator of M protein expression (27, 31). This DNA-binding protein, now designated as Mga (33), contains sequences that are commonly conserved among the response regulators of two-component systems. It was subsequently shown that Mga also regulates the expression of SIC, C5a peptidase, and other potential virulence-associated proteins, but it does not affect the expression of hyaluronic acid capsule or streptokinase (9, 30). Another positive virulence regulator, designated rofA, was found to control expression of prtF, the gene encoding the fibronectin-binding adhesin, protein F (15). The rofA gene has limited homology with mga. Recently, we reported that a distinct, two-component regulatory system (designated mucRS) represses expression of the hyaluronic acid capsule in an M1 Streptococcus pyogenes strain (16a). Mutations that inactivate mucRS result in highly mucoid strains that are hypervirulent in a mouse model of soft tissue infection (5, 16). A virtually identical locus was identified in an M3 strain by Levin and Wessels; the DNA sequence was reported and designated csrRS (21). Mutations in csrRS also render mutant strains both hypermucoid and hypervirulent. Because of the striking degree of identity between mucRS and csrRS, we have adopted the gene designation of Levin and Wessels. Henceforth, the genes that we have characterized in the M1 background will also be designated as csrR and csrS.

In the present work, we demonstrate that csrRS also represses the expression of SLS and the cysteine protease, SpeB. We also demonstrate that although the increased mucoidy of csrRS mutants contributes to virulence, other factors regulated by this locus also contribute to the enhanced virulence of these mutants.

	MATERIALS AND METHODS

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Bacterial strains and plasmids. The streptococcal strains used for this study were derived from wild-type strain MGAS166 (Table 1). Strains were grown in Todd-Hewitt broth supplemented with 0.2% yeast extract (Difco, Detroit, Mich.) or on Todd-Hewitt agar plates (Difco). When antibiotic selection of streptococci was required, 0.02 µg of erythromycin per ml, 100 µg of streptomycin per ml, or 100 µg of spectinomycin (Sigma Laboratories, St. Louis, Mo.) per ml were added to the appropriate media. Escherichia coli JM109 or DH5 was used for cloning procedures. Ampicillin (50 µg/ml) or erythromycin (300 µg/ml) was added to Luria-Bertani media as needed for selection of clones.

Uronic acid assay. Isolates were grown in Todd-Hewitt broth (150 ml) to an absorbance at 600 nm (A₆₀₀) of 0.6 to 0.8. Aliquots of bacterial culture were removed hourly, washed once with sterile distilled water, and centrifuged. The pellet was resuspended in 0.5 ml of water. Chloroform (1.0 ml) was added, and the suspension was mixed vigorously at room temperature for 1 h. After centrifugation, the stain-all method of uronic acid quantitation was performed by using the aqueous phase (19). Hyaluronic acid from Streptococcus zooepidemicus (Sigma) was used as a standard. The peak uronic acid level obtained during the 6-h culture is reported.

Northern hybridization and immunoblotting. RNA was isolated by using the method of Cheung and colleagues (10) and the FastPrep system (Bio101, Vista, Calif.). Bacteria were shaken with beads for 45 s at 6,000 rpm to lyse cells in CRSR 455 (chaotropic RNA stabilizing reagent 455). After extraction and precipitation of the fraction containing RNA, samples were loaded immediately onto a 2% formaldehyde gel, electrophoresed, and transferred to nylon membranes by capillary action. The membrane was hybridized overnight at 55°C in high sodium dodecyl sulfate (SDS) buffer with digoxigenin-labeled DNA probes (Genius system; Boehringer Mannheim). Hybridizing RNA was visualized with anti-digoxigenin alkaline phosphatase conjugate. Probes were generated with the following primer sets: 5'-CGTTTCTCTTGAGCTGCAACCTG-3' and 5'-CAACATTAGTCTCAACGGCTTCATC-3' for csrR, 5'-AATTGAGCTAGCCTTGTCCTTGTT-3' and 5'-ATAACTTCCGCTACCACCTTGAGA-3' for sagA, 5'-CCAATGTACCGTTAAAAGCAAATG-3' and 5'-TGCATTTCCATACTAAGGTTTGA-3' for speB, and 5'-TTTTTAATGATCTTCGCTTTGGTAAC-3' and 5'-GTCATGTTTTCTTATCCTTATCGTGTG-3' for cpa.

SLS assay. Culture supernatants were collected at various times after inoculation and a series of twofold dilutions were added to equal volumes of 2% defibrinated, washed rabbit erythrocytes. After 60 min of incubation at 37°C, the samples were centrifuged and the absorbance at 540 nm was measured to determine the release of free hemoglobin. An equivalent amount of fully hemolyzed erythrocytes was used as a positive control. In some experiments, bacteria were initially grown in the presence of 10% horse serum to permit the release of cell-associated SLS. Cholesterol was added to some serum-free samples at a concentration of 10 µg/ml to inhibit SLO, and trypan blue was added to other samples to inhibit SLS.

Mouse infection model. Virulence of GAS strains was determined by using a dermonecrotic mouse model as previously described (7). Briefly, streptococci were harvested at mid-log phase and concentrated to produce various inocula in a 200-µl bacterial suspension. This volume was injected subcutaneously into the right flank of hairless, 4-week-old male crl:SKH1(hrhr) Br mice (Charles River, Wilmington, Mass.). Mice were weighed prior to inoculation every 24 h. Necrotic wounds were measured daily using the following equation: area = (L × W)/2, where L is the long axis and W is the short axis of the lesion.

	RESULTS

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Construction of csrR mutant strains. To test the role of the csrRS locus in the regulation of virulence-associated genes, we constructed derivatives of a clinical isolate, MGAS166, which have a defective expression of csrR. Two mutants were obtained by screening transposon mutants for colonial hypermucoidy. SBmuc5 and SBmuc7 are derivatives of MGAS166 that have insertions of Tn916 upstream of csrR. The insertions are in opposite orientations in the two strains; both interrupt the 35 consensus sequence of a putative promoter.

Transcriptional analysis of CsrRS-regulated genes. To assess the transcription of virulence-associated genes in csrR mutants, cultures of wild-type and mutant strains were grown to late exponential or early stationary phase for isolation of bacterial RNA. Northern hybridization analysis of MGAS166 and the three csrR mutants revealed that transcription of csrR was detected in the wild-type strain but not in the mutants (Fig. 1). csrR transcripts could be detected in the two Tn916 mutants after introduction of a plasmid carrying an intact csrR gene (pNLB2223) or the entire csrRS locus (pASH2477).

View larger version (35K): [in this window] [in a new window]   FIG. 1.   Northern hybridization analysis of virulence-associated genes in CsrR streptococcal strains. Bacterial RNAs from six strains were isolated in late exponential phase and hybridized with four different PCR-generated probes as indicated to the left of each panel. The source of each RNA sample is indicated above the respective lane. The fifth and sixth lanes in each panel contain RNA from derivatives of SBmuc5 and SBmuc7, respectively, into which a csrRS-bearing plasmid (pNLB2223) has been introduced. wt, wild type.

csrR csrS hasAB

View larger version (45K): [in this window] [in a new window]   FIG. 2.   Northern hybridization analysis of virulence-associated genes in CsrR streptococcal strains. Samples from early-stationary-phase cultures of three strains were hybridized to probes specific for sagA, speB, and cpa. Samples included RNA from MGAS166, UMAA2392 (csrR csrS), UMAA2526 (csrR csrS hasAB), and UMAA2392 with glucose added to a final concentration of 0.2% 2 h before RNA isolation.

Expression of SLS in CsrR mutants. Betschel and colleagues demonstrated that a Tn916 insertion in sagA results in a complete loss of SLS activity (6). We therefore hypothesized that increased sagA expression observed in csrR mutants would be associated with increased SLS activity. To confirm this hypothesis, we performed hemolytic assays of various mutants. Assays were performed on supernatants of cultures sampled at various intervals between mid-exponential and stationary phase (Fig. 3A). Activities of SLS and SLO were distinguished by assaying aliquots in the presence of either cholesterol (to inhibit SLO) or trypan blue (to inhibit SLS). Assays for SLS were performed with horse serum, which acts as a carrier and enhances release of cell-associated toxin (3). Our experiments showed that SLS is secreted during stationary phase in all of the pathogenic strains studied. However, CsrR strain UMAA2392 secreted large quantities of SLS 2 h earlier in broth culture than its parental CsrR⁺ strain, MGAS166. In mid- to late exponential phase, SLS activity was fourfold greater in csrR mutants than in the wild-type strain (Fig. 3B). This observation is consistent with the enhanced transcription of sagA during this point in the growth curve, as reported above. In contrast, the activity of SLO was comparable in the wild-type and csrR mutants at all time points measured (Fig. 3C).

View larger version (31K): [in this window] [in a new window]   FIG. 3.   Hemolytic activities of streptococcal supernatants during 11 h of broth culture. (A) Absorbance of cultures from which aliquots were assayed. (B) Assays for SLS, performed in the presence of cholesterol to inhibit SLO. (C) Assays for SLO, performed in the presence of trypan blue to inhibit SLS. Note the different scales used in panels B and C. Data points for strain MGAS166 (wild type) are represented by the circles; those for strain UMAA2392 (csrR csrS) are represented by squares. White (open) and black (closed) data points indicate that assays were done in the absence or presence of horse serum, respectively. Assays were also performed without cholesterol and trypan blue and were within ±10% of the sum of the SLS and SLO activities (data not shown).

Expression of SpeB in CsrR mutants. Just as the increased activity of SLS was shown to follow increased transcription of sagA, we wished to confirm that increased expression of SpeB would follow after derepression of speB. Expression of SpeB in the culture supernatants of wild-type and mutant strains was assessed by immunoblot analysis with a monospecific polyclonal antibody (Fig. 4). None of the strains tested produced detectable SpeB after 6 h of broth culture (mid-exponential phase). In contrast, by 12 h of culture (early stationary phase in this experiment), SpeB or precursor forms of SpeB were detected in the culture of the three csrR mutants but not in the wild type. Introduction of pNLB2333 (csrR⁺) into strains SBmuc5 and SBmuc7 abrogated expression of SpeB at this time point. Finally, by late stationary phase, all strains were expressing fully processed SpeB, with strain UMAA2392 (csrR csrS) expressing the greatest amount. The expression pattern of SpeB was therefore similar to that of SLS. Both proteins are expressed in the wild-type strain during stationary phase, but secretion of these proteins occurs earlier in the growth curve in CsrR strains.

View larger version (41K): [in this window] [in a new window]   FIG. 4.   Immunoblot analysis of streptococcal strains with a polyclonal antisera against SpeB. The three panels represent samples taken at different time intervals during growth in broth culture: mid-exponential (6 h of culture) (A), late exponential (12 h of culture) (B), and late stationary phase (48 h of culture) (C). Lanes were loaded with samples from the following strains: lane 1, MGAS166; lane 2, SBmuc5 (csrR::Tn916); lane 3, SBmuc7 (csrR::Tn916); lane 4, UMAA2392 (csrR csrS); lane 5, SBmuc5 (pNLB2223); and lane 6, SBmuc7 (pNLB2223). Lane M, molecular weight markers. The arrows indicate the mobility of 28-kDa proteins, corresponding to the molecular mass of fully processed SpeB. The slower-migrating bands that coexist in specimens containing specific SpeB bands are thought to represent unprocessed or complexed SpeB.

Virulence of CsrR mutants in mouse skin and soft tissue infection. Virulence in the hairless mouse model was assessed by four criteria: weight loss following inoculation, frequency of lesion development, frequency of lesional necrosis, and size of necrotic lesions. Strain MGAS166 is known to produce necrotic lesions in these mice when injected with Cytodex beads (Sigma) (7); without beads, this strain causes minimal or no erythema at the injection site. The three csrR mutants were capable of producing abscess, skin necrosis, or both in the absence of Cytodex (Table 3). Using an inoculum of 2 × 10⁶ CFU grown under aerated conditions, strain MGAS166 produced no manifestations of infection in six mice, whereas strain UMAA2392 (csrR csrS) yielded dermonecrotic lesions in all animals (P = 0.002, Fisher's exact test; experiment II [Table 3]). A similar inoculum of MGAS166 grown in static broth (a condition known to enhance the virulence of this strain) yielded subcutaneous abscesses in 4 of 12 animals but no necrotic lesions. In contrast, the csrR csrS mutant yielded necrotic lesions in all of 12 animals and was therefore significantly more likely to produce any lesion (P = 0.001) or a dermonecrotic lesion, specifically (P = 0.000007). At 10-fold lower inocula, the csrR csrS mutant produced necrotic lesions in half of the animals, regardless of the culture conditions used, although the difference from the less virulent wild-type strain was not statistically significant because of the small size of the experimental groups. However, these experiments suggest that the approximate dose of streptococci that produces lesional necrosis in 50% of the animals for the csrR csrS mutant is 2 × 10⁵ to 3 × 10⁵. The dose that produces lesional necrosis in 50% of the animals for MGAS166 is unknown, but it must be greater than 4 × 10⁶, at least 10-fold greater than the mutant.

View larger version (25K): [in this window] [in a new window]   FIG. 5.   Comparison of the size of necrotic lesions during the course of experiments II and IV (Table 3). In these experiments, necrotic lesions developed in all infected mice except in those inoculated with the wild-type strain, MGAS166 (no lesions), and in three of the mice inoculated with strain UMAA2526 (csrR csrS hasAB). One of six mice inoculated with UMAA2526 in experiment II (A) and two of six mice in experiment IV (B) had no skin necrosis and are excluded from the analysis of lesion size in this figure. Lesions were measured, and the area was calculated 24, 48, and 72 h after inoculation. The infecting strains were SBmuc5 (solid black columns), SBmuc7 (white columns), UMAA2392 (cross-hatched columns), and UMAA2526 (shaded columns).

	DISCUSSION

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We and others have previously shown that the csrRS locus represses the expression of hyaluronic acid capsule in GAS (16, 21). The data presented in this report show that csrRS also repress the expression of at least two other potential virulence factors, SLS and SpeB. Using a functional assay and an immunoassay, respectively, we were able to detect enhanced levels of both of these proteins in late exponential phase when csrR expression was disrupted. In addition, Northern hybridization analysis confirmed that csrR-mediated regulation occurs at least in part at the transcriptional level. Mutations in csrR had no effect on expression of cpa, mga, or the genes regulated by mga. Therefore, it appears that this two-component regulatory system, csrRS, controls expression of a subset of known virulence factors. While this paper was being reviewed, another laboratory published a description of a two-component regulatory system that was identified from the genomic sequence of GAS and was found to repress transcription of sagA, hasA, and the genes encoding streptokinase and mitogenic factor (14). This regulatory locus is the same gene tandem described in the present work.

Mutations affecting the expression of csrR and csrS also result in enhanced virulence in an animal model of skin and soft tissue infection. A strain with a deletion in csrR and a point mutation in the start codon of csrS was at least 10-fold more virulent than the parental strain. Like the transposon mutants that were previously described (16, 21), this mutant strain has increased quantities of uronic acid in broth-cultured bacteria and a mucoid appearance of colonies on agar plates. The mutant strain is more virulent, due in large part to the increased production of hyaluronic acid capsule. We demonstrated the importance of the capsule by infecting mice with a strain that contains both the csrR csrS mutations and a deletion of the capsular synthesis genes. The capacity of this strain to produce a necrotic skin lesion was intermediate between the wild type and the csrR deletion strain as measured by the occurrence of lesions, the frequency of necrosis, and the lesional size, when present. The csrR transposon mutants were not consistently as virulent as the strain carrying the csrR deletion, perhaps because these strains have insertions in the promoter of csrR rather than the open reading frame. The csrR mutation may be leaky in these strains.

Streptococcal capsule was first proposed to be a virulence factor by Kass and Seastone (18). Potential roles for the capsule in GAS virulence are suggested by studies demonstrating its capacity to prevent killing by phagocytes (24, 35), to prevent attachment of bacteria to macrophages (36), to shield the organism from oxygen metabolites (11), and, most recently, to act as a ligand for CD44 on human keratinocytes (32). The importance of capsule in the pathophysiology of streptococcal skin infection was recently demonstrated by Ashbaugh et al. (4). These authors demonstrated that GAS strains with deletions in either the capsular synthesis genes (hasABC) or the M protein gene (emm) cannot induce necrotic skin lesions in a murine infection model (4).

In our previous animal infection experiments with clinical strain MGAS166, it was necessary to include a suspension of Cytodex beads in the subcutaneous inoculum in order to induce necrotic skin lesions (7). The precise role of these particles in pathophysiology has never been clarified, but we have hypothesized that the beads may attenuate the effects of tissue-infiltrating phagocytic cells. In the present experiments, we found that csrR mutants induce necrotic skin lesions without the addition of Cytodex to the inoculum. This finding suggests that derepression of virulence genes by CsrR substitutes for the effects of Cytodex. We speculate that the augmented encapsulation in these strains may provide the protection from phagocytic cells afforded by Cytodex to the wild-type strain.

The partial attenuation of virulence in a csrR mutant by introduction of a hasAB deletion implies that capsule contributes to virulence in our animal model system. However, these experiments also suggest that csrR also controls important virulence factors other than capsule that contribute to necrotizing skin infection. SLS is one of the most toxic membrane-active cytolysins known (2). Owens et al. observed that a GAS strain that was SLS-negative after chemical mutagenesis was attenuated when given to mice by the intraperitoneal route (26). However, more concrete evidence for the role of SLS in infection was provided by Betschel et al., who reported that insertional inactivation of a gene designated sagA leads to a loss of SLS activity (6). It is quite likely that sagA actually encodes SLS. Its identity remains uncertain since the sequence of the SLS polypeptide is unknown and since sagA has not been cloned. However, a strain with a Tn916 insertion in sagA produces less weight loss and skin necrosis than the wild-type strain in murine infections (6). In invasive soft tissue infection, a potent cytolysin, such as SLS, may significantly impair inflammatory cells locally and facilitate the spread of streptococci in tissue.

In contrast to SLS, there is little direct evidence of a role for SpeB in necrotic skin infection. A proinflammatory effect has been attributed to SpeB in some experiments. For example, purified SpeB administered in conjunction with streptococcal cell wall can induce profound tissue inflammation in the lung (34). Two groups of investigators have reported that isogenic speB mutants are less virulent in intraperitoneal infection and after injection of air pouches in skin (20, 22). In contrast, Ashbaugh et al. found that there was no effect of a speB mutation on the occurrence of necrosis in a murine skin infection model (4). The specific role of SpeB in GAS virulence remains uncertain.

Our findings show that hyaluronic acid capsule is only partly responsible for the hypervirulence of csrR mutants. Although these mutants produce excessive amounts of SLS and SpeB, we have not proven that either of these toxins is responsible for the residual virulence observed when capsule production is eliminated. However, coinfection of the wild type and a csrR strain modified the tissue microenvironment in ways that enhanced the survival of the wild-type strain. This finding suggests that extrinsic factors, such as exotoxins, may play an important role in GAS virulence.

The elaboration of each of these factors may have more or less importance for colonization or disease, depending on the site and circumstances of infection. Therefore, it is reasonable to speculate that sets of GAS virulence factors may be coordinately regulated in response to specific environmental stimuli. mga is an example of one such regulatory locus; this locus controls the expression of M protein, SIC, and the C5 peptidase (9). These proteins are expressed during mid-exponential phase when the bacteria are growing vigorously. It is likely that this set of virulence factors is most important during rapid growth in the host. In contrast, CsrR appears to repress virulence factors during exponential growth. csrR mutants elaborate SLS and SpeB at the end of exponential phase, before the wild-type strain begins to express these proteins. We speculate that early secretion of these and perhaps other factors may confer an advantage to csrR mutant GAS in tissue. It is not known whether such mutants emerge spontaneously or whether they contribute to necrotizing fasciitis or other forms of rapidly invasive streptococcal disease. However, this is a testable hypothesis now that the control locus has been identified.