Antagonistic effects Na+ and Mg2+ on the structure, function, and stability of mycobacteriophage L1 repressor.

Temperate mycobacteriophage L1 encodes an unusual repressor (CI) for regulating its lytic-lysogenic switching and, in contrast to the repressors of most temperate phages, it binds to multiple asymmetric operator DNAs. Here, ions like Na(+), Cl(-), and acetate(-) ions were demonstrated to facilitate the optimal binding of CI to cognate operator DNA, whereas K(+), Li(+), NH4(+), Mg(2+), carbonate(2-), and citrate(3-) ions significantly affected its operator binding activity. Of these ions, Mg(2+) unfolded CI most severely at room temperature and, compared to Mg(2+), Na(+) provided improved thermal stability to CI. Furthermore, the intrinsic tryptophan fluorescence of CI was changed notably upon replacing Na(+) with Mg(2+) and these opposing effects of Mg(2+) and Na(+) were also noticed in their actions on the C-terminal fragment (CTD) of CI. Taken together, Na(+) appeared to be more appropriate than Mg(2+) for maintaining the biologically active conformation of CI needed for its optimal binding to operator DNA.

Moderately thermostable phage Phi11 Cro repressor has novel DNA-binding capacity and physicochemical properties.

The temperate Staphylococcus aureus phage Phi11 harbors cI and cro repressor genes similar to those of lambdoid phages. Using extremely pure Phi11 Cro (the product of the Phi11 cro gene) we demonstrated that this protein possesses a single domain structure, forms dimers in solution at micromolar concentrations and maintains a largely alpha-helical structure even at 45 degrees C. Phi11 Cro was sensitive to thermolysin at temperatures ranging from 55-75 degrees C and began to aggregate at ~63 degrees C, suggesting that the protein is moderately thermostable. Of the three homologous 15-bp operators (O1, O2, and O3) in the Phi11 cI-cro intergenic region, Phi11 Cro only binds efficiently to O3, which is located upstream of the cI gene. Our comparative analyses indicate that the DNA binding capacity, secondary structure and dimerization efficiency of thermostable Phi11 Cro are distinct from those of P22 Cro and lambda Cro, the best characterized representatives of the two structurally different Cro families.

Physicochemical properties and distinct DNA binding capacity of the repressor of temperate Staphylococcus aureus phage phi11.

The repressor protein and cognate operator DNA of any temperate Staphylococcus aureus phage have not been investigated in depth, despite having the potential to enrich the molecular biology of the staphylococcal system. In the present study, using the extremely pure repressor of temperate Staphylococcus aureus phage phi11 (CI), we demonstrate that CI is composed of alpha-helix and beta-sheet to a substantial extent at room temperature, possesses two domains, unfolds at temperatures above 39 degrees C and binds to two sites in the phi11 cI-cro intergenic region with variable affinity. The above CI binding sites harbor two homologous 15 bp inverted repeats (O1 and O2), which are spaced 18 bp apart. Several guanine bases located in and around O1 and O2 demonstrate interaction with CI, indicating that these 15 bp sites are used as operators for repressor binding. CI interacted with O1 and O2 in a cooperative manner and was found to bind to operator DNA as a homodimer. Interestingly, CI did not show appreciable binding to another homologous 15 bp site (O3) that was located in the same primary immunity region as O1 and O2. Taken together, these results suggest that phi11 CI and the phi11 CI-operator complex resemble significantly those of the lambdoid phages at the structural level. The mode of action of phi11 CI, however, may be distinct from that of the repressor proteins of lambda and related phages.

Detection of antistaphylococcal and toxic compounds by biological assay systems developed with a reporter Staphylococcus aureus strain harboring a heat inducible promoter - lacZ transcriptional fusion.

Previously it was reported that promoter of groES-groEL operon of Staphylococcus aureus is induced by various cell-wall active antibiotics. In order to exploit the above promoter for identifying novel antistaphylococcal drugs, we have cloned the promoter containing region (P(g)) of groES-groEL operon of S. aureus Newman and found that the above promoter is induced by sublethal concentrations of many antibiotics including cell-wall active antibiotics. A reporter S. aureus RN4220 strain (designated SAU006) was constructed by inserting the P(g)-lacZ transcriptional fusion into its chromosome. Agarose-based assay developed with SAU006 shows that P(g) in single-copy is also induced distinctly by different classes of antibiotics. Data indicate that ciprofloxacin, rifampicin, ampicillin, and cephalothin are strong inducers, whereas, tetracycline, streptomycin and vancomycin induce the above promoter weakly. Sublethal concentrations of ciprofloxacin and ampicilin even have induced P(g) efficiently in microtiter plate grown SAU006. Additional studies show for the first time that above promoter is also induced weakly by arsenate salt and hydrogen peroxide. Taken together, we suggest that our simple and sensitive assay systems with SAU006 could be utilized for screening and detecting not only novel antistaphylococcal compounds but also different toxic chemicals.

Purification and characterization of repressor of temperate S. aureus phage phi11.

To gain insight into the structure and function of repressor proteins of bacteriophages of gram-positive bacteria, repressor of temperate Staphylococcus aureus phage phi11 was undertaken as a model system here and purified as an N-terminal histidine-tagged variant (His-CI) by affinity chromatography. A approximately 19 kDa protein copurified with intact His-CI (approximately 30 kDa) at low level was resulted most possibly due to partial cleavage at its Ala-Gly site. At approximately 10 nM and higher concentrations, His-CI forms significant amount of dimers in solution. There are two repressor binding sites in phi11 cI-cro intergenic region and binding to two sites occurs possibly by a cooperative manner. Two sites dissected by HincII digestion were designated operators O(L) and O(R), respectively. Equilibrium binding studies indicate that His-CI binds to O(R) with a little more strongly than O(L) and binding species is probably dimeric in nature. Interestingly His-CI binding affinity reduces drastically at elevated temperatures (32-42 degrees C). Both O(L) and O(R) harbor a nearly identical inverted repeat and studies show that phi11 repressor binds to each repeat efficiently. Additional analyses indicate that phi11 repressor, like lambda repressor, harbors an N-terminal domain and a C-terminal domain which are separated by a hinge region. Secondary structure of phi11 CI even nearly resembles to that of lambda, phage repressor though they differ at sequence level. The putative N-terminal HTH (helix-turn-helix) motif of phi11 repressor belongs to the HTH -XRE-family of proteins and shows significant identity to the HTH motifs of some proteins of evolutionary distant organisms but not to HTH motifs of most S. aureus phage repressors.

Repressor of temperate mycobacteriophage L1 harbors a stable C-terminal domain and binds to different asymmetric operator DNAs with variable affinity.

BACKGROUND: Lysogenic mode of life cycle of a temperate bacteriophage is generally maintained by a protein called 'repressor'. Repressor proteins of temperate lambdoid phages bind to a few symmetric operator DNAs in order to regulate their gene expression. In contrast, repressor molecules of temperate mycobacteriophages and some other phages bind to multiple asymmetric operator DNAs. Very little is known at present about the structure-function relationship of any mycobacteriophage repressor. RESULTS: Using highly purified repressor (CI) of temperate mycobacteriophage L1, we have demonstrated here that L1 CI harbors an N-terminal domain (NTD) and a C-terminal domain (CTD) which are separated by a small hinge region. Interestingly, CTD is more compact than NTD at 25 degrees C. Both CTD and CI contain significant amount of alpha-helix at 30 degrees C but unfold partly at 42 degrees C. At nearly 200 nM concentration, both proteins form appreciable amount of dimers in solution. Additional studies reveal that CI binds to O64 and OL types of asymmetric operators of L1 with variable affinity at 25 degrees C. Interestingly, repressor-operator interaction is affected drastically at 42 degrees C. The conformational change of CI is most possibly responsible for its reduced operator binding affinity at 42 degrees C. CONCLUSION: Repressors encoded by mycobacteriophages differ significantly from the repressor proteins of lambda and related phages at functional level but at structural level they are nearly similar.

Effects of physical, ionic, and structural factors on the binding of repressor of mycobacteriophage L1 to its cognate operator DNA.

To determine the factors influencing the binding of L1 repressor to its cognate operator DNA, several gel shift as well as bioinformatic analyses have been carried out. The data show that time, temperature, salt, and pH each greatly affect the binding. In order to achieve optimum operator binding of L1 repressor in Tris buffer, the minimum requirements of time, temperature, salt, and pH were estimated to be 1 min, 32 degrees C, NaCl (50 mM), and 7.9, respectively. Interestingly Na+ but not NH4+, K+, or Li+ was found to augment significantly the binding activity of CI protein above the basal level. Anions like Cl-, citrate-, acetate-, and H2PO4- do not alter the binding of L1 repressor to its operator. We also show that an in frame deletion mutant of L1 repressor which does not carry the putative HTH motif (at its N-terminal end) fails to bind to its cognate operator DNA even at very high concentrations. The putative HTH motif was found highly conserved and evolutionarily very close to that of regulatory proteins of Y. pestis, H. marismortui, A. tumefaciens, etc. Taken together we suggest that N-terminal end of L1 repressor carries a HTH motif. Further analysis of the putative secondary structures of mycobacteriophage repressors reveals that two common regions encompassing more than 90% of primary sequence are present in all the four repressor molecules studied here. The results suggest that these common regions are utilized for carrying out identical functions.

A point mutation at the C-terminal half of the repressor of temperate mycobacteriophage L1 affects its binding to the operator DNA.

The wild-type repressor CI of temperate mycobacteriophage L1 and the temperature-sensitive (ts) repressor CIts391 of a mutant L1 phage, L1cIts391, have been separately overexpressed in E. coli. Both these repressors were observed to specifically bind with the same cognate operator DNA. The operator-binding activity of CIts391 was shown to differ significantly than that of the CI at 32 to 42 degrees C. While 40-95% operator-binding activity was shown to be retained at 35 to 42 degrees C in CI, more than 75% operator-binding activity was lost in CIts391 at 35 to 38 degrees C, although the latter showed only 10% less binding compared to that of the former at 32 degrees C. The CIts391 showed almost no binding at 42 degrees C. An in vivo study showed that the CI repressor inhibited the growth of a clear plaque former mutant of the L1 phage more strongly than that of the CIts391 repressor at both 32 and 42 degrees C. The half-life of the CIts391-operator complex was found to be about 8 times less than that of the CI-operator complex at 32 degrees C. Interestingly, the repressor-operator complexes preformed at 0 degrees C have shown varying degrees of resistance to dissociation at the temperatures which inhibit the formation of these complexes are inhibited. The CI repressor, but not that of CIts391, regains most of the DNA-binding activity on cooling to 32 degrees C after preincubation at 42 to 52 degrees C. All these data suggest that the 131(st) proline residue at the C-terminal half of CI, which changed to leucine in the CIts391, plays a crucial role in binding the L1 repressor to the cognate operator DNA, although the helix-turn-helix DNA-binding motif of the L1 repressor is located at its N-terminal end.