Faculty Bibliography

The leading strand replication origin of pT181 plasmids consists of two adjacent inverted repeat elements (IR-II and IR-III), which are involved in origin recognition by the initiator (Rep) protein. The conserved core element, IR-II, which contains the initiation nick site, is induced by Rep to form a cruciform structure, probably the primary substrate for the initiation of rolling circle replication. The divergent repeat, IR-III, constitutes the determinant of origin recognition specificity. We show here that the distal arm of IR-III is not required for sequence-specific recognition, whereas the proximal arm and central region are required. Since the initiator is dimeric, we presume that it binds symmetrically to IR-III. A unique type of DNA-protein interaction is proposed, in which the lack of sequence requirement for the distal arm is a consequence of binding to the adjacent IR-II, which thereby polarizes the stringency of binding to the two arms of IR-III. In addition, genetic evidence indicates that both the spacing and the phasing of IR-II to IR-III are crucial for function and that the central segment of IR-III may serve to position the two flanking half-sites for optimal interaction of Rep with IR-III

The effect of glucose on accessory gene regulator (agr) expression in Staphylococcus aureus was examined. agr is a global regulator that affects the expression of numerous genes, including those for some factors implicated in virulence, such as toxic shock syndrome toxin 1, alpha-hemolysin, and protein A. The agr locus determines two divergent transcripts, designated RNAII and RNAIII. RNAII contains four open reading frames (agrABCD), and RNAIII encodes delta-hemolysin. The mechanisms responsible for agr-mediated regulation are not well understood, but it appears that the RNAIII transcript plays a central role in the regulation of a number of target genes, including those for alpha-hemolysin (hla), beta-hemolysin (hlb), protein A (spa), and staphylococcal enterotoxin B (seb+). In this study, S. aureus cultures were grown either in a shake flask system with a complex medium or in a fermentor system with a completely defined medium in which the pH and glucose concentration were maintained. Northern (RNA) blot analysis revealed that a dramatic reduction in agr expression was apparent only when the cultures contained glucose and when the pH was 5.5 or was not maintained. The effect of glucose on two agr target genes, sec+ and hla, was also studied. Glucose-containing cultures produced less sec+ and hla mRNAs at maintained pH (6.5). In addition, the glucose effect on sec+ and hla was enhanced under conditions that inhibited agr expression (i.e., pH 5.5 or a nonmaintained pH)

Toxic shock syndrome toxin (TSST) 1 was purified from ovine (TSST-ovine) and bovine (TSST-bovine) mastitis-associated Staphylococcus aureus. These toxins were previously reported to have molecular weights identical to that of human TSST-1. However, TSST-ovine was reported as having an isoelectric point (pI) of 8.5, whereas TSST-bovine has the same pI (7.2) as TSST-1. Nucleotide sequence analysis revealed that TSST-bovine was identical to TSST-1 and that TSST-ovine had 14 nucleotide differences that changed 9 amino acid residues. Only 1 nucleotide difference, at position 514, was predicted to cause an amino acid charge difference, as glutamic acid at position 132 of TSST-1 was changed to lysine in TSST-ovine. Like TSST-1, TSST-ovine was mitogenic, but unlike TSST-1, it was not pyrogenic, was unable to enhance endotoxic shock, and was unable to induce TSS in a rabbit model. Also, TSST-ovine was less reactive to certain monoclonal antibodies raised against TSST-1

The synthesis of several exoproteins, including protein A (SpA) in Staphylococcus aureus is coordinately regulated by the agr locus. Different constructs of the SpA-encoding gene (spa) were introduced into Agr+ and Agr- derivatives of a spa- strain of S. aureus. Plasmid-located spa with deletions at the 3' end expressed a truncated SpA which was almost exclusively extracellular and which confirmed the role of C-terminal region X in cell-wall binding. In the Agr- host, the production of SpA was elevated severalfold. Transcriptional and translational fusions were constructed to study the agr- mediated regulation of spa gene expression. Translational fusions of a beta-lactamase (Bla)-encoding ApR reporter gene with the spa promoter and N-terminal coding sequences expressed elevated levels of Bla activity in the Agr- host. In contrast, a transcriptional fusion of the spa gene with a promoter of the positively regulated staphylococcal epidermolytic toxin A (ETA)-encoding gene synthesized higher levels of SpA in an Agr+ host, as compared to Agr-. Moreover, the synthesis of SpA in the Agr+ strain was switched on during the transition from the exponential to stationary phase in a similar fashion to ETA itself. These data strongly indicate that the regulation of both SpA and ETA occurs at the transcriptional level in S. aureus. The agr-regulated spa promoter was defined by deletion analysis and by transcript mapping.

Glycerol monolaurate (GML) is a naturally occurring surfactant that has potential use as an additive to tampons and wound dressings to reduce the incidence of certain bacterial toxin-mediated illnesses. In vitro studies were undertaken to evaluate the effect of GML on the growth of and toxin production by potentially pathogenic bacteria. GML inhibited the growth of clinical isolates of group A, B, F, and G streptococci at concentrations of 10 to 20 micrograms/ml. Exotoxin production, including that of pyrogenic exotoxins and hemolysins, was reduced by concentrations of GML that were below those inhibitory for growth as well as growth inhibitory. The growth of Staphylococcus aureus strains from patients with toxic shock syndrome and scalded skin syndrome was inhibited or delayed in the presence of 100 to 300 micrograms of GML per ml. Growth inhibition by GML could be overcome by the production of lipase. S. aureus elaboration of hemolysin, toxic shock syndrome toxin 1, and exfoliative toxin A was inhibited at GML concentrations below those necessary to inhibit growth. Results similar to those for S. aureus were obtained in tests of S. hominis. Escherichia coli growth and Salmonella minnesota growth were unaffected by GML, but an S. minnesota Re mutant was susceptible to growth-inhibitory activity. Endotoxin release into the medium from E. coli cells was also unaffected by GML, but the release or activity of E. coli hemolysin was increased by GML. Streptococcal pyrogenic endotoxin A production by an E. coli clone was not affectd by GML. These studies indicate that GML is effective in blocking or delaying the production of exotoxins by pathogenic gram-positive bacteria

We report here the existence of a pair of sequence elements in plasmid cointegrates that together block the function of pT181 plasmid replication origins in cis. The study is an outgrowth of the use of plasmid pE194 as a vector for the analysis of the pT181 replication system. We have observed that whereas the isolated pT181 replication origin is fully functional when cloned to pE194, it is inactive when the entire pT181 plasmid genome is cloned. This cis-inhibition is relieved by deletion of all or part of the pE194 palA element or of the pT181 countertranscript promoter. The inhibitory effect of pE194 palA is independent of distance and orientation, whereas the inhibitory effect of the countertranscript promoter is lost when the promoter is moved to a distance of 1.5 kb from the replication origin or inverted in situ. We found that the cis-inhibited pT181 origin expresses origin-specific (Inc3B) incompatibility, which involves competition for the initiator protein. This finding suggests that the cis-inhibited origin binds the initiator protein and therefore that the inhibition affects a step in the initiation process subsequent to initiator binding

We have investigated the specificity of replication origin recognition by the initiator proteins of a set of six closely related Staphylococcus aureus plasmids, the pT181 family. These plasmids replicate by an asymmetric rolling-circle mechanism using plasmid-coded initiators that nick the replication origins and form a phosphotyrosine bond at the 5' nick terminus. Five of the plasmids are in different incompatibility groups and their initiator proteins do not cross-complement the cloned origins of any but their own plasmid. One pair is weakly incompatible and their initiator proteins and origins do cross-complement for replication in vivo. This pattern of cross-reactivity led to the prediction that the determinant of specificity would correspond to a homologously positioned set of six residues in the C-terminal domain of the protein, some 80 residues away from the active site tyrosine, that are divergent for all of the compatible plasmids and identical for the incompatible pair. Site-directed mutagenesis was used to exchange these six residues among three pairs of plasmids and these exchanges brought about the predicted switching of origin recognition specificity. Single substitution within this six residue set reduced or eliminated the activity of the protein but did not alter the origin recognition specificity. These six and flanking residues cannot form an amphipathic alpha-helix nor do they conform to the classical helix-turn-helix or other known DNA binding motifs. A novel type of interaction is suggested in which the protein binds to its recognition site, bends and melts the DNA, and causes or enhances the extrusion of an adjacent cruciform containing the nick site. This configuration would juxtapose the nicking target and the active site tyrosine residue and would unwind the highly G + C-rich replication origin

Staphylococcus aureus exoprotein expression is controlled by a global regulon known as agr. This system activates transcription of some target genes and represses transcription of others. Target genes expressed postexponentially such as alpha-hemolysin (hla) are activated by agr; target genes expressed during exponential phase such as protein A (spa) are repressed by agr. A unique feature of the agr system is that this transcriptional regulation is mediated by a 517-nucleotide transcript, RNAIII. While it is clear that agr differentially regulates the expression of exponential and postexponential exoproteins, the precise role of agr in the temporal control of these events has not yet been explored. In this report, we examine the effects of expressing RNAIII, the agr regulator, under the control of the inducible beta-lactamase (bla) promoter at different times in the growth cycle. We confirm previous results showing that agr is required for postexponential-phase expression of hla and further show that a separate postexponential-phase signal independent of agr function is also needed for activation of hla transcription. We also show that in an agr mutant transcription of spa occurs throughout the growth cycle, is inhibited immediately upon induction of RNAIII, and is thus indifferent to the postexponential signal required for hla activation