Molecular Interactions between Two Global Regulators, sar and agr, in Staphylococcus aureus*

Yueh-tyng ChienDagger and Ambrose L. Cheung§

From the Laboratory of Bacterial Pathogenesis and Immunology, The Rockefeller University, New York, New York 10021

    ABSTRACT
Top
Abstract
Introduction
Procedures
Results
Discussion
References

The expression of many virulence determinants in Staphylococcus aureus is controlled by regulatory loci such as agr and sar. We have previously shown that the SarA protein is required for optimal transcription of RNAII and RNAIII in the agr locus. To define the specific molecular interaction, we overexpressed SarA as a glutathione S-transferase (GST) fusion protein by cloning the 372-base pair (bp) sarA gene into the vector. The purified GST-SarA as well as cleaved SarA were able to bind specifically to the P2, P3, and the combined P2-P3 promoter fragments of agr in gel shift assays. Using monoclonal antibodies to SarA, we found that SarA is a part of the retarded protein-DNA complex as evidenced by the formation of a supershifted band. The SarA binding site on the agr promoter, mapped by DNase I footprinting assay, covered a 29-bp region between the P2 and P3 promoters devoid of any direct repeats. A synthetic 45-bp fragment encompassing the 29-bp sequence also bound the SarA protein in band shift assays. Serial in-frame deletion analysis of sarA revealed that, with the exception of 15 residues in the N terminus, almost all of SarA (residues 16-124) is essential for agr binding activity. Northern analysis confirmed that only the sar mutant clone containing a truncated sarA gene with a 15-residue deletion in the N terminus (SarA16-124) could activate agr transcription to a level approaching that of the full-length counterpart (SarA1-124). Taken together, these data indicated that SarA is a DNA-binding protein with binding specificity to the P2 and P3 interpromoter region of agr, thereby activating RNAII and RNAIII transcription.

    INTRODUCTION
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Abstract
Introduction
Procedures
Results
Discussion
References

Staphylococcus aureus is a major human pathogen with many clinical manifestations (1). Infections due to this organism can range from minor wound infections to severe sepsis. The capacity of S. aureus to cause various infections is probably related to the fact that this organism has an amazing ability to respond to changing environments. The adaptive response is highly coordinated and is generally modulated by regulatory elements via signal transduction pathways. The regulatory elements, in turn, control the transcription of a wide variety of unlinked genes, many of which are involved in pathogenesis (2, 3).

Temporal expression of many of the virulence determinants in S. aureus has been shown to be under the control of several genetic loci, agr (accessory gene regulator), sar (staphylococcal accessory regulator), and sae (3-5). The agr locus consists of two divergent transcripts, RNAII and RNAIII, driven by two distinct promoters, P2 and P3, respectively (3). RNAIII is the effector of the agr response that involves up-regulation of genes involved in exoprotein synthesis and down-regulation of genes encoding surface proteins (6, 7).

Another regulatory locus, designated sar, was uncovered in our laboratory (4). Unlike agr, the sar locus activates the synthesis of both extracellular (e.g. hemolysins) and cell wall-associated proteins (e.g. fibronectin-binding protein (8, 23)). The sar locus, encoded within a 1.2-kb1 DNA fragment, encompasses three overlapping transcripts (9). These transcripts, designated sarA (0.58 kb), sarB (0.8 kb), and sarC (1.2 kb), have common 3' ends but three distinct promoters. A major 372-bp ORF (sarA) together with extensive (approx 800 bp) upstream sequence is present within the largest transcript, sarB. Phenotypic analysis revealed that the sar locus is necessary for hemolysin production, probably mediated by the interaction of sar gene products with the P2 and, to a lesser extent, P3 promoter of agr (10, 11). The ensuing transcription of RNAII and RNAIII would lead to activation of exoprotein gene transcription (7).

In contrast to the RNAIII-mediated control of exoprotein synthesis in agr, we recently reported that the SarA protein likely modulates alpha -hemolysin production in S. aureus (10). Transcriptional and deletion analyses indicated that the intact SarA protein is required for full agr expression (i.e. RNAII and RNAIII) in S. aureus (10). In this report, we examined the binding of GST-SarA fusion protein as well as purified SarA to the agr promoters. Our results demonstrated that both of these proteins bind to the P2 and P3 promoters of agr in a dose- dependent fashion. The binding affinity of GST-SarA appears to be higher with the P2 than with the P3 promoter. DNase I footprinting analysis of SarA binding to the agr promoter region revealed that the SarA binding site resides in a 29-bp sequence between the P2 and P3 promoter region (-73 to -101 upstream of the P2 transcription start). Interestingly, the binding site excludes the 7-bp consensus repeat (AGTTAAG) within the P2-P3 interpromoter region previously reported by Morfeldt et al. (11). A labeled 45-bp DNA oligonucleotide probe encompassing the 29-bp binding site also bound the GST-SarA fusion protein in a gel retardation assay. In-frame deletion analysis of the SarA protein revealed that, with the exception of the 15 residues in the N terminus, almost all of the SarA protein (residues 16-124) is essential for binding activity to the agr promoter (P2-P3). Northern analysis also confirmed that only the sar mutant clones containing either the full-length SarA1-124 or the truncated form (SarA16-124) could activate RNAII and RNAIII transcription of the agr locus. Taken together, our data indicated that SarA is a DNA-binding protein with binding specificity to the interpromoter region between P2 and P3 of agr, thereby leading to activation of P2 (RNAII) and P3 (RNAIII) transcription.

    EXPERIMENTAL PROCEDURES
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Abstract
Introduction
Procedures
Results
Discussion
References

Bacterial Strains, Plasmids, and Growth Media-- The bacterial strains and plasmids used in this study are listed in Table I. Phage phi 11 was used as the transducing phage for S. aureus strains. CYGP, 0.3 GL, and tryptic soy broth media were used for the growth of S. aureus (4, 6) while Luria-Bertani (LB) was used for growing Escherichia coli. Antibiotics were used at the following concentrations: erythromycin at 5 µg/ml, chloramphenicol at 10 µg/ml, tetracycline at 5 µg/ml, and ampicillin at 50 µg/ml.

Construction and Purification of GST-SarA Fusion Proteins-- The intact 372-bp sarA gene (13) was amplified by PCR using a plasmid template (pALC70) and primers containing restriction sites (XhoI and BamHI) to facilitate cloning. Likewise, sarA gene fragments coding for the truncated SarA with in-frame deletions in the N and C termini were amplified by PCR. PCR products representing assorted sarA fragments were digested with XhoI and BamHI and ligated into GST vector pGEX-4T-1 (Pharmacia Biotech Inc., Piscataway, NJ). The resulting plasmids containing the entire or truncated sarA gene are listed in Table I. The GST-SarA fusion clones were verified by restriction digestion and DNA sequencing. Enhanced expression of various GST-SarA constructs was induced by adding isopropyl-1-thio-beta -D-galactopyranoside (IPTG) at 1 mM to a growing culture (30 °C) at an A600 of 0.7. Three h after induction, the cells were harvested by centrifugation (10,000 × g for 10 min), resuspended in phosphate-buffered saline (0.14 M NaCl, 2.7 mM KCl, 10.1 mM Na2HPO4, 1.8 mM KH2PO4, pH 7.3) and sonicated on ice. Cellular debris was removed by centrifugation (15,000 × g for 15 min), and the clarified supernatant was applied directly to the glutathione-Sepharose 4B column (Pharmacia). The affinity purification procedure was conducted following the instruction of the manufacturer. For some assays, the recombinant fusion protein was cleaved with thrombin to yield the full-length SarA protein. Purified SarA and GST fusion proteins were detected by anti-SarA monoclonal antibody (see below) on immunoblots, and the purity was analyzed by SDS-polyacrylamide gel electrophoresis. Purified SarA protein or homogeneous GST-SarA fusion proteins were used for the gel shift and footprinting assays.

Production of Anti-SarA Monoclonal Antibodies-- Purified SarA protein was authenticated by determining the 15 residues at the N terminus with protein sequencing. This protein was used to immunize BALB/c × SJL/J (F1 cross) mice to obtain monoclonal antibodies as described (14). Antibodies from limited dilutions were screened by enzyme-linked immunosorbent assay with immobilized SarA protein. Monoclonal antibodies 1D1, 1F7, 3H2, and 8F3 were purified from culture supernatants as described (14).

Site-directed Mutagenesis of the sarA Gene and Genetic Manipulations in S. aureus-- To introduce in-frame deletions within the sarA coding region, site-directed mutagenesis was performed with the Stratagene Quick Change mutagenesis kit. A 1.7-kb fragment encompassing the entire sar locus was cloned into pBluescript (ALC559) to serve as a template for mutagenesis. Two complimentary oligonucleotide pairs, (5'-848AATAGGGAGGTTTTAAACATG868 911GTCACTTATGCTGACAAATTA931-3') (9) and (5'-846CAAATAGGGAGGTTTTAAACATG868 941ATTAAAAAGGAATTTTCAATTAG963-3') (9), were designed for each mutagenesis (Table I). After constructing the mutations, the recombinant phagemid DNA was transformed into XL1-Blue competent cells (Strategene). The in-frame deletion within sarA in pBluescript was confirmed by DNA sequencing. DNA fragments containing the mutations were then gel purified and ligated into shuttle vector pSPT181. Electroporation of S. aureus RN4220 with recombinant pSPT181 containing the mutated sarA gene within the sar locus was performed as described previously (15). For transduction, phage phi 11 was used to produce phage lysates of strain RN4220 containing the recombinant pSPT181 shuttle vector with sar fragments. The phage lysate was then used to infect the sar mutant ALC136 as described (4). The presence of correct plasmids was confirmed by restriction mapping.

Immunoblot Analysis-- Proteins were resolved and transferred onto nitrocellulose membranes as described (16). Anti-SarA monoclonal antibodies diluted 1:5,000 were allowed to incubate with the membrane for 1 h followed by another h of incubation with a 1:10,000 dilution of goat anti-mouse alkaline phosphatase conjugate (Jackson ImmunoResearch, West Grove, PA). Immunoactive bands were detected as described (17). SeeBlue prestained protein standards (Novex, San Diego, CA) were used for molecular weight estimation.

Isolation of RNA and Northern Blot Hybridization-- Overnight cultures of S. aureus were diluted 1:50 in CYGP and grown to late log (OD650 = 1.1), and postexponential (OD650 = 1.7) phases. The cells were pelleted and processed with a FastRNA isolation kit (BIO 101 Inc., Vista, CA) in combination with 0.1-mm-diameter sirconia-silica beads and a FastPrep reciprocating shaker (BIO 101 Inc.) as described (18). Ten µg of each sample was electrophoresed through a 1.5% agarose, 0.66 M formaldehyde gel in MOPS running buffer (20 mM MOPS, 10 mM sodium acetate, 2 mM EDTA, pH 7.0). Blotting of RNA onto Hybond N+ membranes (Amersham Corp.) was performed with the Turboblotter alkaline transfer system (Schleicher & Schuell). For detection of specific transcripts, DNA probes were radiolabeled with [alpha -32P]dCTP by the random primed method (Ready-To-Go labeling kit, Pharmacia) and hybridized under high stringency conditions. The blots were subsequently washed and autoradiographed.

Gel Mobility Shift Assay-- DNA fragments containing the agr P2 and P3 promoter region were amplified by PCR using S. aureus chromosomal DNA as a template. Prior to PCR, one of these primers was end-labeled with [gamma -32P]ATP and T4 polynucleotide kinase (Pharmacia), and the PCR fragments were purified by ProbeQuant G-50 columns (Pharmacia). To confirm the fidelity of the PCR reactions, the PCR products were completely sequenced. The following PCR primers were used: 5'-ATCAACTATTTTCCATCACATCT-3' (oligo 422) and 5'-TTACACCACTCTCCTCACT-3' (oligo 178) for a 235-bp P2-P3 fragment (from nt 1539 to 1773) (3); 5'-GTCGTTTTTTATTCTTAACTGT-3' and oligo 178 for a 152-bp P2 fragment (from nt 1622 to 1773) (3); 5'-TTTAACATAAAAAAATTTACAGTTAAGAATAAAAAACGAC-3' and oligo 422 for a 122-bp P3 fragment (from nt 1539 to 1660) (3); and 5'-AGTTAAGAATAAAAAACGAC-3' and oligo 422 for a 103-bp DNA fragment (from nt 1539 to 1641) (3). A 45-bp DNA fragment (5'- GTAAATTTTTTTATGTTAAAATATTAAATACAAATTACATTTAAC-3') and its complementary strand located in the intergenic region between the agr P2 and P3 promoters were also synthesized. Protein samples were incubated with 5 × 103 cpm (0.3 ng) of end-labeled PCR fragments in the presence of 2 µg of poly(dI-dC)·poly(dI-dC) (Pharmacia) in a final volume of 20 µl. Incubations were carried out on ice for 30 min in 10 mM Tris-HCl (pH 7.6), 50 mM NaCl, 5% (w/v) glycerol, 1 mM EDTA, and 1 mM dithiothreitol. Samples were resolved on 5% polyacrylamide gels in 0.5 × Tris-borate-EDTA buffer (19). Following electrophoresis, gels were dried and autoradiographed.

DNase I Footprinting-- Binding reactions were performed as described for the gel mobility shift assay except that a total volume of 100 µl was used. DNase I (Boehringer Mannheim) (0.01 unit) was added and incubated for 2 min at room temperature. The reaction was terminated by adding 100 µl of freshly made stop solution (50 mM Tris-HCl (pH 8.0), 2% (w/v) SDS, 10 mM EDTA, proteinase K at 0.4 µg/ml, and glycogen at 100 mg/ml). The reaction mixture was extracted with phenol/chloroform. DNA was ethanol-precipitated, washed with 70% ethanol, and resuspended in loading buffer (98% deionized formamide, 10 mM EDTA (pH 8.0), 0.025% (w/v) xylene cyanol FF, and 0.025% (w/v) bromphenol blue). DNA was denatured at 95 °C for 3 min and run on a 6% sequencing gel. Chemical cleavage at purine (A+G) residues were performed by the standard method (19).

    RESULTS
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Abstract
Introduction
Procedures
Results
Discussion
References

Purification of GST-SarA Fusion Proteins Produced in E. coli-- The intact 372-bp sarA gene was cloned in-frame into GST fusion vector pGEX-4T-1 and overproduced in E. coli DH5alpha . The expressed recombinant fusion protein contained a 26-kDa GST protein fragment followed by a thrombin cleavage site and the SarA protein. Soluble fraction of the cell lysate from E. coli that had been induced with IPTG was prepared and purified on a GST affinity column as described under "Experimental Procedures." The soluble crude extract and the purified protein were analyzed by SDS-polyacrylamide gel electrophoresis. As shown in Fig. 1A, the purified GST-SarA fusion protein (41.5 kDa) and the SarA protein (14.5 kDa) generated by cleavage with thrombin were essentially homogeneous. The identity of these proteins was confirmed by immunoblots with monoclonal antibody 1D1 raised against SarA (Fig. 1B). These protein preparations were used in subsequent band shift and footprinting assays (see below).


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Fig. 1.   Coomassie Blue-stained SDS-polyacrylamide gel (A) showing GST-SarA and the full-length SarA generated by the cleavage of thrombin and the corresponding immunoblot (B) with 1D1 anti-SarA monoclonal antibody. Lane 2, crude lysate prepared from E. coli (stain ALC1137) as described under "Experimental Procedures"; lane 3, purified GST-SarA eluted from the GST-Sepharose affinity column; lane 4, purified SarA. The molecular mass standards (SeeBlue, Novex) are 250, 98, 64, 50, 36, 30, 16, and 6 kDa (lanes 1 and 5).

Binding of SarA to agr P2 and P3 Promoters-- Indirect biochemical evidence with crude extracts from S. aureus mutant clones containing sar fragments from our laboratory (10, 20) suggested that SarA may interact with the agr locus by binding to the P2 promoter. To examine further the interaction between SarA and agr promoter, purified recombinant GST-SarA and SarA from E. coli were used in band shift assays with agr P2 and P3 promoters. As shown in Fig. 2, A and B, the purified GST-SarA fusion protein bound to the agr P2 and P3 promoters in a dose-dependent fashion, with >=  50% retardation for P2 and P3 promoter probes by adding 1 and 10 µg of the fusion protein, respectively. With the combined P2-P3 promoter fragment (Fig. 2C), binding activity of GST-SarA appeared to be increased (>= 50% band shift with 0.5 µg of protein). The estimated dissociation constant (Kd) for the P2 promoter (18 nM) was lower than its P3 (190 nM) counterpart, thus implying that SarA binds with higher affinity to the P2 than to the P3 agr promoter. Remarkably, the combined P2-P3 promoter has the highest affinity for the SarA protein (Kd = 6 nM). The addition of unlabeled P2-P3 fragment interfered with the formation of the binding complex between the labeled probe and the GST-SarA fusion protein (Fig. 2C, lanes 7-12) while increasing concentrations of a 165-bp nifH2 promoter region from Methanosarcina barkeri or calf thymus DNA had no effect (data not shown). We also tested the binding of the full-length SarA (GST portion removed by thrombin digestion) to the agr P2-P3 promoter (Fig. 2D). As anticipated, purified SarA was able to bind to the P2-P3 promoter, with the binding pattern similar to that of the fusion protein (Fig. 2, C and D).


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Fig. 2.   Binding of purified GST-SarA to agr P2 (A) and P3 (B) promoters. The labeled 152-bp P2 (nt 1622-1773 according to published sequence) (3) or 122-bp P3 (nt 1539-1660) fragment was incubated with 0, 0.5, 1, 3, 5, or 10 µg of purified GST-SarA (lanes 1-6) in the presence of 2 µg of poly(dI-dC)·poly(dI-dC) followed by electrophoresis through a 5% polyacrylamide gel (see "Experimental Procedures"). C, specificity of SarA binding to the 235-bp P2-P3 promoter fragment (nt 1539-1773) of agr. In competition assay, various amounts of unlabeled P2-P3 fragment were added to a tube containing 0.3 ng of labeled agr P2-P3 fragment prior to the addition of purified GST-SarA. Lanes 1-6 show the binding of increasing amounts of GST-SarA (0, 1, 2, 3, 4, and 5 µg) to the P2-P3 promoter fragment; lanes 7-12 show reactions containing labeled P2-P3 DNA, 2 µg of GST-SarA and 0 ng (lane 8), 20 ng (lane 9), 40 ng (lane 10), 60 ng (lane 11), and 100 ng (lane 12) of unlabeled P2-P3 promoter fragment; lane 7 contains the labeled probe alone. D, the binding of purified SarA to labeled P2-P3 promoter fragment. In lanes 1-7, 0, 0.5, 1, 3, 5, 7, and 10 µg of purified SarA was added per assay.

The Effect of Anti-SarA Antibody on Gel Shift Assays-- The data above indicated that recombinant SarA from S. aureus is capable of binding to the agr promoter. To show that SarA is truly a part of the retarded protein-DNA complex, we used four anti-SarA monoclonal antibodies (1D1, 1F7, 3H2, and 8F3) to detect its presence. By incubating these four anti-SarA monoclonal antibodies with the reaction mixture containing SarA and labeled P2-P3 probe, we discovered that they bound to the retarded SarA-DNA complex (Fig. 3) as evidenced by the formation of a supershifted complex in each instance (lanes 3, 6, 9, and 12). As a control, the addition of antibody alone without SarA did not produce any shifted band, suggesting that the supershifted band is not due to the binding of antibody to the agr promoter probe (Fig. 3, lanes 4, 7, 10, and 13).


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Fig. 3.   Detection of DNA-protein complex by monoclonal antibodies to SarA in gel retardation assays. A supershifted complex using monoclonal antibodies against SarA demonstrated the presence of SarA in the retarded complex. The gel shift reactions were performed as described. The labeled 235-bp P2-P3 agr promoter fragment was incubated with 0 (lane 1) or 2 µg (lanes 2, 3, 5, 6, 8, 9, 11, and 12) of GST-SarA in the presence of 2 µg of calf thymus DNA. Lanes 3, 6, 9, and 12 are reactions receiving 2 µl (~2 mg/ml) of 1D1, 1F7, 3H2, and 8F3 anti-SarA antibodies, respectively. Lanes 4, 7, 10, and 13 are the respective controls receiving only 1D1, 1F7, 3H2, and 8F3 anti-SarA antibodies.

Mapping the P2 and P3 Binding Sites of SarA with DNase I Protection Assay-- Our band shift assays have shown that SarA binds specifically to the P2 and P3 promoter region of agr. To determine the binding site more precisely, we analyzed protein-DNA complexes by the DNase I protection assay (19). Binding to both top and bottom strands was examined using PCR-amplified templates. When approx 50 µg of purified GST-SarA was used, a large region of protection was observed on both strands (Fig. 4, A and B). In both instances, the protected regions are identical and correspond to nt -73 to -101 upstream of the P2 transcription start site (-83 to -111 upstream of P3), covering a 29-bp region (Fig. 4C). We also performed the footprinting experiments with purified SarA derived from thrombin-cleaved GST-SarA. The protection pattern is essentially the same (data not shown).


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Fig. 4.   DNase I protection footprint analysis of SarA binding to the agr P2-P3 promoter region of S. aureus. A, footprint analysis of protein binding to the top strand of the agr promoter region. The 235-bp agr promoter fragment was end-labeled by PCR as described under "Experimental Procedures." Labeled DNA (2 ng) was incubated with: no DNase I, no protein (lane 1); no protein (lane 3); 10 µg of GST-SarA (lane 4); 20 µg of GST-SarA (lane 5); 30 µg of GST-SarA (lane 6); 40 µg of GST-SarA (lane 7), and 50 µg of GST-SarA (lane 8). Lane 2 represents chemical cleavage at purine residues. B, footprint analysis of protein binding to the bottom strand of the agr promoter region. The binding reaction and the footprint analysis were identical to the one described above except that an additional control without protein was included in lane 9. C, schematic diagram of both strands of the agr P2-P3 promoter region protected by SarA from DNase I digestion. The bracketed region represents the protected bases. The P2 and P3 promoters are indicated by arrows marked with -35. The two 7-bp direct repeats upstream of both P2 and P3 promoter regions are boxed.

Binding of SarA to a 45-bp DNA Fragment Containing the Protected DNA Region Identified by Footprinting Analysis-- The transcription starts between two agr promoters (P2 and P3) are separated by a 186-bp sequence containing several direct and inverted repeats. The upstream regions of P2 and P3 are very similar in that each contains duplications of the heptanucleotides 5'-AGTTAAG-3 (Fig. 4C). These repeats have been suggested to be the binding site for a common regulatory protein, with SarA being a potential candidate (11). However, our footprinting analysis indicated that the SarA protein binds to a 29-bp region located between the P2 and P3 promoters. This region does not contain the putative repeats. To confirm our footprinting result, we performed band shift assays with a labeled 45-bp oligonucleotide probe spanning the 29-bp SarA binding site. As shown in Fig. 5, the 45-bp DNA fragment was retarded by the GST-SarA fusion protein in a dose-dependent manner (Fig. 5B). In contrast, a 103-bp fragment containing the repeats but not the SarA binding site failed to bind to the SarA protein (Fig. 5C). These data strongly suggest that the direct repeats are not the binding site for SarA. To evaluate the specificity of this binding, we also performed a series of competition assays with combinations of labeled and unlabeled DNA. The results showed that the unlabeled 45-bp DNA was able to compete with labeled P2, P3, or 45-bp DNA fragments for the binding to the SarA protein (data not shown).


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Fig. 5.   Binding of SarA to a 45-bp DNA fragment containing the DNase I protected region. A, schematic diagram showing the probes used in the band shift assays. Reactions are as described in Fig. 2. The labeled 45-bp fragment was incubated with 2 µg of calf thymus DNA and 0, 0.5, 1, 3, 5, or 10 µg of GST-SarA (Fig. 5B, lanes 1-6). Panel C represents an assay of the labeled 103-bp fragment with 2 µg of calf thymus DNA and 0, 3, 5, or 10 µg (lanes 1-4) of purified GST-SarA. Similar results were obtained when purified SarA was used in place of GST-SarA. The directions of transcripts and the direct repeats are indicated by arrows in panel A.

Mapping the DNA-binding Domain of the SarA Protein-- To map the DNA-binding domain of SarA to the agr P2 and P3 promoters, we constructed an assortment of GST fusion proteins spanning full-length to truncated forms of SarA (Fig. 6A). These constructs were expressed with IPTG induction and purified to homogeneity as described under "Experimental Procedures." Gel shift experiments were used to test interactions of these truncated fusion proteins with the agr promoter sequence (P2-P3) in an attempt to determine the minimal SarA protein sequence that can function as a DNA-binding protein (Fig. 6B). N-terminal truncations up to 15 residues (ALC1133) still bound the P2-P3 promoter (Fig. 6B, lane 7), but truncations extending to 25 residues or more (ALC1218, ALC1193, ALC1132, and ALC1054) did not yield any protein-DNA complex. A C-terminal truncation of as little as 11 residues (ALC1176) failed to bind to the P2-P3 promoter probe (Fig. 6B). These results suggested that an extensive region extending from residue 15 to the C terminus of SarA is required for DNA binding to the agr promoter.


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Fig. 6.   Mapping the SarA-GST DNA-binding domain to agr P2-P3 promoter fragment. A, schematic diagram of GST-SarA constructs with in-frame deletion of selected regions of SarA. Amino acid positions in SarA for C-terminal (C) and N-terminal (N) truncations are indicated. B, gel shift assays of GST-SarA fusion proteins with selected in-frame deletions of SarA to the labeled agr P2-P3 fragment. Two µg of each purified GST-fusion protein and 2 µg of calf thymus DNA were added. Lane 1, no protein control; lane 2, purified GST protein alone; lane 3, purified N83 SarA; lane 4, purified N43 SarA; lane 5, purified N35 SarA; lane 6, purified N25 SarA; lane 7, purified N15 SarA; lane 8, purified full-length SarA fusion; lane 9, purified C11 SarA.

Northern Analysis of RNAII and RNAIII Expression in Various sarA-deletion Constructs-- To evaluate whether in vitro binding of truncated SarA protein to the agr promoter region (Fig. 6B) correlates with activation of RNAII and RNAIII in S. aureus cells, we assayed for agr-related transcription in sar mutant clones (see Table I, ALC70, ALC1273, and ALC1274). To serve as the standard against which in-frame deletions of sarA can be compared, we utilized a previously constructed sar mutant clone carrying a recombinant shuttle plasmid (pSPT181) that contained the entire sar locus including sarA and extensive upstream sequence (approx 800 bp). Consequently, activation of RNAII and RNAIII in this clone (ALC70) has been shown to be optimal (10). We constructed two in-frame mutations corresponding to N15 and N25 (Fig. 6A) to yield sar mutant clones ALC1273 and ALC1274. To ensure translation of the full-length or truncated SarA protein in these deletion clones, we utilized anti-SarA monoclonal antibody to confirm the presence of truncated SarA proteins in cell extracts prepared from these S. aureus clones (Fig. 7A). As expected, clone ALC70 containing the intact sarA gene in a multicopy plasmid expressed the full-length SarA (14.5 kDa) while ALC1273 (15- amino acids deletion) and ALC1274 (25-amino acids deletion) yielded truncated SarA protein of approx 13 and 12 kDa, respectively. The parental strain RN6390 (Fig. 7A, lane 6, arrow) and its isogenic sar mutant ALC136 served as the respective positive and negative controls (lane 5). A lower level of SarA expression in parental strain RN6390 as compared with ALC70 (multicopy plasmid) may be attributable to the single copy effect. Based on our observation that truncated SarA protein with a 15-residue deletion in the N terminus (N15) was able to bind the agr P2-P3 promoter (Fig. 6B), we also determined that strain ALC1273, containing this form of truncated SarA, was sufficient for restoring RNAII and RNAIII expression in a sar mutant (Fig. 7B, lane 2), with levels approaching that of the full-length SarA protein (Fig. 7B, ALC70 in lane 1). As with the results of the gel shift assay, clone ALC1274 with a 25-residue truncation in the N terminus failed to activate transcription from the agr promoter (Fig. 7B, lane 3). Taken together, these data indicated that the minimum sarA sequence expressed in ALC1273 was adequate for agr expression in a sar mutant.

                              
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Table I
Bacterial strains and plasmids


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Fig. 7.   Correlation of SarA binding to the agr promoter with RNAII and RNAIII expression. A, the detection of truncated SarA in sar mutant clones with in-frame sarA deletions by Western blot using 1D1 anti-SarA monoclonal antibody. Lane 1, SeeBlue prestained protein standards; lane 2, ALC70 containing the full-length SarA; lane 3, ALC1273 containing the N15 truncated SarA; lane 4, ALC1274 containing the N25 truncated SarA; lane 5, ALC136 (sar mutant); lane 6, RN6390 (wild type). Northern blots of RNAII (B) and RNAIII (C) in sar mutant clones with in-frame sarA deletion. Lane 1, ALC70; lane 2, ALC1273 with N15 truncated SarA; lane 3, ALC1274 with N25 truncated SarA; lane 4, parent RN6390; lane 5, sar mutant ALC136; lane 6, ALC475, ALC136 with control vector pSPT181.

    DISCUSSION
Top
Abstract
Introduction
Procedures
Results
Discussion
References

Expression of virulence determinants in S. aureus is dependent in part on two global regulatory loci, i.e. sar and agr. Recognizing that the sar locus is composed of three overlapping transcriptional units (sarA, C, and B), we have assayed previously the binding of agr promoter fragment to crude cell extracts from sar mutant clones containing a single copy of the respective transcriptional units (10). Coupled with in vitro translation studies, these antecedent data provide evidence that the SarA protein likely regulates hemolysin production by modulating RNAII and RNAIII transcription of agr. However, experimental evidence linking direct binding of SarA to the agr promoter region is lacking. In this report, we presented gel shift and footprinting data showing that purified SarA binds specifically to the agr P2-P3 promoter region. Dissociation constant values (Kd) derived from dose response analysis imply that the SarA protein binds with higher affinity to the P2 than to the P3 promoter (e.g. 1 µg versus 10 µg of GST-SarA for 50% retardation of the labeled P2 and P3 probes, respectively; Fig. 2, A and B). The differential affinity in promoter binding of SarA concurs with our earlier observation that the effect of a sar mutation was more pronounced on RNAII (P2) than on RNAIII (P3) transcription (10). However, a careful scrutiny of these Kd values (6, 18, and 190 nM for P2-P3, P2, and P3, respectively) reveals relatively low binding affinities between SarA and the agr promoters. Consistent with this finding was our recent observation that a sar mutant clone complemented with a single copy of the sarB transcript (encoding SarA and additional smaller ORFs upstream) produced a higher level of RNAII than the sarA transcript counterpart encoding SarA alone (10). In consequence, we speculate that SarA, in conjunction with additional factors encoded by sequences upstream of sarA, may be required for optimal binding to the agr promoter. In this regard, we have preliminary mutagenesis data to suggest that the 39-amino acid ORF immediately upstream of sarA may be required for full agr expression.2 Alternatively, sar-independent regulatory factors may be involved in this interaction.

DNase I footprinting analysis has uncovered the SarA binding site to be a 29-bp sequence located in the interpromoter region between P2 and P3 (Fig. 4). Several relevant observations can be deduced from this experiment. First, the finding that the binding site is more proximal to the P2 than to the P3 -35 promoter box (Fig. 4C) would be compatible with the hypothesis that the SarA protein probably modulates P2 more than P3 transcription. Alternatively, other factors may be required to bind cooperatively with SarA to the P3 promoter (21). Second, this sequence does not encompass any of the 7-bp repeats (AGTTAAG) that have been suggested by Morfeldt et al. (11) to be the putative binding site for SarA protein. In support of our premise is the finding that a 45-bp labeled fragment encompassing this 29-bp sequence but lacking any of the repeats bound to the SarA protein, whereas a 103-bp fragment containing two of the repeats did not (Fig. 5). Third, in divergence to the proposed repeats leading to multiple binding sites and hence a ladder-like pattern of band shift (11), the footprinting data as well as the formation of a single retarded DNA-protein complex (Fig. 2, A, B, and D) presented here strongly substantiate a single binding site when purified SarA protein was used for the binding assay. The reason for the disparate results may arise from the fact that purified protein was used in our assays, whereas crude affinity purified extracts were used in theirs (11). Alternatively, the crude extract employed by Morfeldt et al. (11) may be contaminated with additional DNA binding proteins. In this regard, our group has purified another distinct 13-kDa DNA-binding protein with binding specificity to the agr promoter region. Preliminary N-terminal sequencing revealed some degree of homology to the SarA protein. Amazingly, this protein almost co-migrated with the SarA protein in SDS-gel.2

The identity of a single SarA-agr complex also corroborated with the formation of a supershifted band upon the addition of anti-SarA monoclonal antibodies to the retarded protein-DNA complex (Fig. 3). A careful scrutiny of the supershifted complexes revealed two distinct modes of interactions. The monoclonals 1F7, 3H2, and 8F3 have distinct supershifted bands that migrated more slowly than the SarA-agr promoter complex. In contrast, the antibody 1D1 had a diffuse supershifted complex, consistent with partial disruption of the SarA-DNA complex. Preliminary mapping of these antibodies revealed that the epitope for monoclonals 1F7, 3H2, and 8F3 resides more toward the C-terminal segment, whereas 1D1 is directed toward the middle portion of the SarA molecule.3 Conceivably, monoclonal 1D1 may interfere with the DNA-binding domain of the SarA molecule, thus resulting in partial disruption of the protein-DNA complex. Clearly, additional experiments need to be performed to validate this hypothesis.

In mapping the SarA DNA-binding domain by serial truncations of the sarA gene (Fig. 6), we found that only GST fusions containing the full-length SarA1-124 or a minimally truncated form (SarA16-124) could bind to the agr promoter on gel shift assays. Based upon the size (29 bp) of the SarA recognition site (Fig. 4), it is rather unlikely that the actual DNA-binding domain entails almost the entire SarA molecule. This premise leads us to speculate that, with the exception of 15 residues in the N terminus, the remaining residues in SarA must contribute to the proper conformation of the DNA-binding domain of the molecule to facilitate binding to the agr promoter. Clearly, further mutagenesis studies are needed to exactly define the DNA-binding domain of SarA. Of interest is the fact that SarA1-113 (C11 in Fig. 6B), representing an 11-residue truncation in the C terminus, constitutes the previously reported SarA molecule of S. aureus strain RN6390 (9) while the full-length SarA1-124 is identical to that of S. aureus strains DB and RN450. The failure of GST-SarA1-113 (C11) to bind to agr promoter in vitro (Fig. 6B) corroborated with our previous data in which the cell extract of a sar mutant clone containing the truncated sarA gene either as a recombinant multicopy plasmid (20) or as a single copy chromosomal insertion (10) did not bind to the agr promoter fragment in gel shift assays. To resolve this discrepancy, we resequenced the sarA fragment from strain RN6390 and concluded that a spontaneous mutation (CGA to TGA) may have occurred in the E. coli clone containing the sarA gene of strain RN6390. This was confirmed by directly sequencing the sarA PCR product generated with chromosomal template of strain RN6390 and high fidelity Pfu polymerase.

In agreement with our in vitro binding data (Fig. 6), Northern analysis of S. aureus sar mutant clone (ALC1273) containing the minimally truncated SarA16-124 revealed that this clone could activate RNAII and RNAIII transcription to a level approaching that of the full-length SarA counterpart (ALC70). As predicted from the gel shift assay, the clone containing the N25 deletion in sarA (ALC1274) did not activate RNAII and RNAIII transcription as effectively as the intact SarA control (Fig. 7, B and C, lanes 3 and 1). However, unlike the gel shift data, the SarA26-124 protein was still capable of augmenting RNAII transcription at a low level as compared with the sar mutant control (ALC136), indicating that the truncated SarA molecule (Fig. 7A, lane 3) was capable of low level agr activation. This disparity is not surprising because we have previously found that Northern analysis for agr-related transcription is more sensitive than comparable gel-retardation assays (10, 20).

Attributable to its pleiotropic nature, the SarA protein is likely to be a DNA-binding protein to multiple promoters. Our study here has clearly shown that the SarA binding site on the agr promoter resides in a 29-bp sequence that is extremely AT-rich (26/29 or 89.6%). This degree of AT richness is highly unusual even for S. aureus. Consequently, it is unlikely that this sequence is found randomly at a high frequency in the staphylococcal chromosome. We speculate that this may be a common domain for SarA binding in sarA-dependent promoters. Clearly, a lot of work remains to be done to extend this hypothesis. More recently, we have cloned and sequenced a sarA homolog in Staphylococcus epidermidis (24). Knowing that an agr homolog exists in coagulase negative species (22, 25), it will be of interest to determine if a similar SarA binding site occurs in S. epidermidis and other related pathogenic species.

    FOOTNOTES

* This work was supported in part by Grants-in-aid from the American Heart Association and by National Institutes of Health Grants AI30061 and AI37142.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Dagger Supported by a New York Heart Participatory Laboratory Award.

§ Recipient of the Irma T. Hirshl Career Scientist Award as well as the AHA-Genentech Established Investigator Award from the American Heart Association and to whom correspondence should be addressed. Tel.: 212-327-8163; Fax: 212-327-7385; E-mail: cheunga{at}rockvax.rockefeller.edu.

1 The abbreviations used are: kb, kilobase(s); GST, glutathione S-transferase; bp, base pair(s); PCR, polymerase chain reaction; IPTG, isopropyl-1-thio-beta -D-galactopyranoside; MOPS, 4-morpholinepropanesulfonic acid; nt, nucleotide(s); ORF, open reading frame.

2 Y-t. Chien and A. L. Cheung, unpublished data.

3 Y-t. Chien and A. L. Cheung, unpublished observation.

    REFERENCES
Top
Abstract
Introduction
Procedures
Results
Discussion
References

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