Effect of salt shock on stability of lambdaimm434 lysogens

The affinities of the bacteriophage 434 repressor for its various binding sites depend on the type and/or concentration of monovalent cations. The ability of bacteriophage 434 repressor to govern the lysis-lysogeny decision depends on the DNA binding activities of the phage's cI repressor protein. We wished to determine whether changes in the intracellular ionic environment influence the lysis-lysogeny decision of the bacteriophage lambda(imm434). Our findings show that the ionic composition within bacterial cells varies with the cation concentration in the growth media. When lambda(imm434) lysogens were grown to mid-log or stationary phase and subsequently incubated in media with increasing monovalent salt concentrations, we observed a salt concentration-dependent increase in the frequency of bacteriophage spontaneous induction. We also found that the frequency of spontaneous induction varied with the type of monovalent cation in the medium. The salt-dependent increase in phage production was unaffected by a recA mutation. These findings indicate that the salt-dependent increase in phage production is not caused by activation of the SOS pathway. Instead, our evidence suggests that salt stress induces this lysogenic bacteriophage by interfering with 434 repressor-DNA interactions. We speculate that the salt-dependent increase in spontaneous induction is due to a direct effect on the repressor's affinity for DNA. Regardless of the precise mechanism, our findings demonstrate that salt stress can regulate the phage lysis-lysogeny switch.     

A comparative study of the immunity region of lambdoid phages including Shiga-toxin-converting phages: molecular basis for cross immunity

Comparison of eight lambdoid phages, including three Shiga-toxin converting phages, has been carried out with respect to the immunity region, especially the recognition helices of their repressor and CRO proteins on the one hand, and operator sequences on the other. Some as yet unassigned components of the regulatory circuits have been inferred by computer search. The cross immunity phenomenon shown by phages VT2-Sa and lambda is explained on the basis of similarity in their sequences. In addition, the similarity of 933W and HK022 in the sequences of their recognition helices of repressor and CRO, on the one hand, and operators, on the other, has led us to predict that they will have identical or similar immunity specificity. This homology has enabled us also to locate the OL (and consequently PL) of phage 933W that has been thought to be non-existent.     

Operator sequences of bacteriophages P22 and 21

We have determined the sequences of the left and right operators of bacteriophages P22 and 21. The corresponding operators of the two phages have nearly identical sequences, thus explaining how the repressor of each phage recognizes the operators of the other. Experiments probing the binding of repressor and operator show that each operator contains three repressor binding sites. The repressor binding sites are 18 base-pair, partially symmetric sequences. The dispersed symmetric sequence A.T.AAG.…CTT.A.T is highly conserved among the 12 repressor binding sites of the two phages. Four virulent mutations have been sequenced; all of them alter bases in the conserved sequence.     

Selection and design of high affinity DNA ligands for mutant single-chain derivatives of the bacteriophage 434 repressor

Single-chain repressor RRTRES is a derivative of bacteriophage 434 repressor, which contains covalently dimerized DNA-binding domains (amino acids 1-69) of the phage 434 repressor. In this single-chain molecule, the wild type domain R is connected to the mutant domain RTRES by a recombinant linker in a head-to-tail arrangement. The DNA-contacting amino acids of RTRES at the -1, 1, 2, and 5 positions of the a3 helix are T, R, E, S respectively. By using a randomized DNA pool containing the central sequence -CATACAAGAAAGNNNNNNTTT-, a cyclic, in vitro DNA-binding site selection was performed. The selected population was cloned and the individual members were characterized by determining their binding affinities to RRTRES. The results showed that the optimal operators contained the TTAC or TTCC sequences in the underlined positions as above, and that the Kd values were in the 1×10-12 mol/L-1×10-11mol/L concentration range. Since the affinity of the natural 434 repressor to its natural operator sites is in the 1×10-9 mol/L range, the observed binding affinity increase is remarkable. It was also found that binding affinity was strongly affected by the flanking bases of the optimal tetramer binding sites, especially by the base at the 5′ position. We constructed a new homodimeric single-chain repressor RTRESRTRES and its DNA-binding specificity was tested by using a series of new operators designed according to the recog-nition properties previously determined for the RTRES domain. These operators containing the con-sensus sequence GTAAGAAARNTTACN or GGAAGAAARNTTCCN (R is A or G) were recognized by RTRESRTRES specifically, and with high binding affinity. Thus, by using a combination of random selection and rational design principles, we have discovered novel, high affinity protein-DNA inter-actions with new specificity. This method can potentially be used to obtain new binding specificity for other DNA-binding proteins.     

Recognition of DNA by single-chain derivatives of the phage 434 repressor: high affinity binding depends on both the contacted and non-contacted base pairs.

Single-chain derivatives of the phage 434 repressor, termed single-chain repressors, contain covalently dimerized DNA-binding domains (DBD) which are connected with a peptide linker in a head-to-tail arrangement. The prototype RR69 contains two wild-type DBDs, while RR*69 contains a wild-type and an engineered DBD. In this latter domain, the DNA- contacting amino acids of thealpha3 helix of the 434 repressor are replaced by the corresponding residues of the related P22 repressor. We have used binding site selection, targeted mutagenesis and binding affinity studies to define the optimum DNA recognition sequence for these single-chain proteins. It is shown that RR69 recognizes DNA sequences containing the consensus boxes of the 434 operators in a palindromic arrangement, and that RR*69 optimally binds to non-palindromic sequences containing a 434 operator box and a TTAA box of which the latter is present in most P22 operators. The spacing of these boxes, as in the 434 operators, is 6 bp. The DNA-binding of both single-chain repressors, similar to that of the 434 repressor, is influenced indirectly by the sequence of the non-contacted, spacer region. Thus, high affinity binding is dependent on both direct and indirect recognition. Nonetheless, the single-chain framework can accommodate certain substitutions to obtain altered DNA-binding specificity and RR*69 represents an example for the combination of altered direct and unchanged indirect readout mechanisms.     

DNA-induced conformational changes in bacteriophage 434 repressor

Although bacteriophage 434 repressor binds to its specific DNA sites only as a dimer, formation of the dimers in solution occurs at concentrations three orders of magnitude higher than those needed to bind the 434 operator DNA. Our results suggest that both specific and non-specific DNA induce conformational changes in repressor that lead to formation of repressor dimers. The repressor conformational changes induced by DNA occur at concentrations much lower than those needed for binding of repressor, suggesting that the alternative conformations of repressor persist even if the protein is not in direct contact with DNA. Hence, DNA acts in a "catalytic" fashion to induce a steady-state amount of an alternative repressor conformation that has an enhanced affinity for its specific binding site. These findings suggest that the repressor conformer induced by non-specific DNA is the form of the repressor that is optimized for searching for DNA binding sites along non-specific DNA. Upon finding a binding site, the repressor protein undergoes an additional conformational change that allows it to "lock-on" to its specific site.     

The bacteriophage 434 repressor dimer preferentially undergoes autoproteolysis by an intramolecular mechanism

Inactivation of the lambdoid phage repressor protein is necessary to induce lytic growth of a lambdoid prophage. Activated RecA, the mediator of the host SOS response to DNA damage, causes inactivation of the repressor by stimulating the repressor's nascent autocleavage activity. The repressor of bacteriophage lambda and its homolog, LexA, preferentially undergo RecA-stimulated autocleavage as free monomers, which requires that each monomer mediates its own (intramolecular) cleavage. The cI repressor of bacteriophage 434 preferentially undergoes autocleavage as a dimer specifically bound to DNA, opening the possibility that one 434 repressor subunit may catalyze proteolysis of its partner subunit (intermolecular cleavage) in the DNA-bound dimer. Here, we first identified and mutagenized the residues at the cleavage and active sites of 434 repressor. We utilized the mutant repressors to show that the DNA-bound 434 repressor dimer overwhelmingly prefers to use an intramolecular mechanism of autocleavage. Our data suggest that the 434 repressor cannot be forced to use an intermolecular cleavage mechanism. Based on these data, we propose a model in which the cleavage-competent conformation of the repressor is stabilized by operator binding.     

Studies of the Escherichia coli Trp repressor binding to its five operators and to variant operator sequences.

The Escherichia coli Trp repressor binds to promoters of very different sequence and intrinsic activity. Its mode of binding to trp operator DNA has been studied extensively yet remains highly controversial. In order to examine the selectivity of the protein for DNA, we have used electromobility shift assays (EMSAs) to study its binding to synthetic DNA containing the core sequences of each of its five operators and of operator variants. Our results for DNA containing sequences of two of the operators, trpEDCBA and aroH are similar to those of previous studies. Up to three bands of lower mobility than the free DNA are obtained which are assigned to complexes of stoichiometry 1 : 1, 2 : 1 and 3 : 1 Trp repressor dimer to DNA. The mtr and aroL operators have not been studied previously in vitro. For DNA containing these sequences, we observe predominantly one retarded band in EMSA with mobility corresponding to 2 : 1 complexes. We have also obtained retardation of DNA containing the trpR operator sequence, which has only been previously obtained with super-repressor Trp mutants. This gives bands with mobilities corresponding to 1 : 1 and 2 : 1 complexes. In contrast, DNA containing containing a symmetrized trpR operator sequence, trpRs, gives a single retarded band with mobility corresponding solely to a 1 : 1 protein dimer-DNA complex. Using trpR operator variants, we show that a change in a single base pair in the core 20 base pairs can alter the number of retarded DNA bands in EMSA and the length of the DNase I footprint observed. This shows that the binding of the second dimer is sequence selective. We propose that the broad selectivity of Trp repressor coupled to tandem 2 : 1 binding, which we have observed with all five operator sequences, enables the Trp repressor to bind to a limited number of sites with diverse sequences. This allows it to co-ordinately control promoters of different intrinsic strength. This mechanism may be of importance in a number of promoters that bind multiple effector molecules.     

The N-Terminal Domain of the Repressor of Staphylococcus aureus Phage Φ11 Possesses an Unusual Dimerization Ability and DNA Binding Affinity

Bacteriophage Φ11 uses Staphylococcus aureus as its host and, like lambdoid phages, harbors three homologous operators in between its two divergently oriented repressor genes. None of the repressors of Φ11, however, showed binding to all three operators, even at high concentrations. To understand why the DNA binding mechanism of Φ11 repressors does not match that of lambdoid phage repressors, we studied the N-terminal domain of the Φ11 lysogenic repressor, as it harbors a putative helix-turn-helix motif. Our data revealed that the secondary and tertiary structures of the N-terminal domain were different from those of the full-length repressor. Nonetheless, the N-terminal domain was able to dimerize and bind to the operators similar to the intact repressor. In addition, the operator base specificity, binding stoichiometry, and binding mechanism of this domain were nearly identical to those of the whole repressor. The binding affinities of the repressor and its N-terminal domain were reduced to a similar extent when the temperature was increased to 42°C. Both proteins also adequately dislodged a RNA polymerase from a Φ11 DNA fragment carrying two operators and a promoter. Unlike the intact repressor, the binding of the N-terminal domain to two adjacent operator sites was not cooperative in nature. Taken together, we suggest that the dimerization and DNA binding abilities of the N-terminal domain of the Φ11 repressor are distinct from those of the DNA binding domains of other phage repressors.     

Recognition of DNA structure by 434 repressor.

In complexes of bacteriophage 434 binding sites with 434 repressor the central 4 bp of the 14 bp site are not contacted by the protein, although changes in these bases alter binding site affinity for the repressor. Our previous data suggested that the ability of the non-contacted central bases to be overtwisted in repressor-DNA complexes governs affinity of the binding site for 434 repressor. This idea was tested by examining the affinity of two central sequence variant 434 binding sites for 434 repressor as a function of binding site average twist. The 434 repressor preferred the relatively overwound binding site to the two more underwound forms. The greatest affinity enhancement resulting from increasing twist was observed with a binding site that is relatively underwound and more resistant to twisting deformation. Consistent with the idea that 434 repressor overtwists its binding site upon DNA binding, we show that 434 repressor is capable of binding to sites bearing a single base insertion in their center (a 15mer), but binds poorly to binding sites bearing central base deletions (12mer and 13mer). The N-terminal dimer interface plays a large role in determining 434 repressor central base preferences. Mutations in this interface eliminate central base discrimination and/or site size preferences. These mutations also lead to changes in the size of the repressor footprint on the various sized DNA sites that are consistent with their binding characteristics.     

ban operon of bacteriophage P1. Mutational analysis of the c1 repressor-controlled operator

The repressor of bacteriophage P1, encoded by the c1 gene, represses the phage lytic functions and is responsible for maintaining the P1 prophage in the lysogenic state. The c1 repressor interacts with at least 11 binding sites or operators widely scattered over the P1 genome. From these operators, a 17 base-pair asymmetric consensus sequence, ATTGCTCTAATAAATTT, was derived. Here, we show that the operator, Op72 of the P1ban operon consists of two overlapping 17 base-pair sequences a and b forming an incomplete palindrome. Op72a matches the consensus sequence, whereas Op72b contains two mismatches. The evidence is based on the sequence analysis of 27 operator mutants constitutive for ban expression. They were identified as single-base substitutions at positions 2 to 10 of Op72a (26 mutants) and at position 8 of Op72b (one mutant). We conclude from gel retardation and footprinting studies that two repressor molecules bind to the operator and that positions 4, 5 and 7 to 10 of the operator play an essential role in repressor recognition.     

Monovalent cations regulate DNA sequence recognition by 434 repressor

The bacteriophage 434 repressor distinguishes between its six naturally occurring binding sites using indirect readout. In indirect readout, sequence-dependent differences in the structure and flexibility of non-contacted bases in a protein's DNA-binding site modulate the affinity of DNA for protein. The conformation and flexibility of a DNA sequence can be influenced by the interaction of the DNA bases or backbone with solution components. We examined the effect of changing the cation-type present in solution on the stability and structure of 434 repressor complexes with wild-type and mutant OR1 and OR3, binding sites that differ in their contacted and non-contacted base sequences. We find that the affinity of repressor for OR1, but not for OR3, depends remarkably on the type and concentration of monovalent cation. Moreover, the formation of a stable, specific repressor-OR1 complex requires the presence of monovalent cations; however, repressor-OR3 complex formation has no such requirement. Changing monovalent cation type alters the ability of repressor to protect OR1, but not OR3, from *OH radical cleavage. Altering the relative length of the poly(dA) x poly(dT) tract in the non-contacted regions of the OR1 and OR3 can reverse the cation sensitivity of repressor's affinities for these two sites. Taken together these findings show that cation-dependent alterations in DNA structure underlies indirect readout of DNA sequence by 434 repressor and perhaps other proteins.