Single-chain repressors containing engineered DNA-binding domains of the phage 434 repressor recognize symmetric or asymmetric DNA operators

Single-chain (sc) DNA-binding proteins containing covalently dimerized N-terminal domains of the bacteriophage 434 repressor cI have been constructed. The DNA-binding domains (amino acid residues 1 to 69) were connected in a head-to-tail arrangement with a part of the natural linker sequence that connects the N and C-terminal domains of the intact repressor. Compared to the isolated N-terminal DNA-binding domain, the sc molecule showed at least 100-fold higher binding affinity in vitro and a slightly stronger repression in vivo. The recognition of the symmetric O(R)1 operator sequence by this sc homodimer was indistinguishable from that of the naturally dimerized repressor in terms of binding affinity, DNase I protection pattern and in vivo repressor function. Using the new, sc framework, mutant proteins with altered DNA-binding specificity have also been constructed. Substitution of the DNA-contacting amino acid residues of the recognition helix in one of the domains with the corresponding residues of the Salmonella phage P22 repressor c2 resulted in a sc heterodimer of altered specificity. This new heterodimeric molecule recognized an asymmetric, artificial 434-P22 chimeric operator with high affinity. Similar substitutions in both 434 domains have led to a new sc homodimer which showed high affinity binding to a natural, symmetric P22 operator. These findings, supported by both in vitro and in vivo experiments, show that the sc architecture allows for the introduction of independent changes in the binding domains and suggest that this new protein framework could be used to generate new specificities in protein-DNA interaction.     

How Cro and lambda-repressor distinguish between operators: the structural basis underlying a genetic switch

Knowledge of the three-dimensional structures of the lambda-Cro and lambda-repressor proteins in complex with DNA has made it possible to evaluate how these proteins discriminate between different operators in phage lambda. As anticipated in previous studies, the helix-turn-helix units of the respective proteins bind in very different alignments. In Cro the recognition helices are 29 A apart and are tilted by 55 degrees with respect to each other, but bind parallel to the major groove of the DNA. In lambda-repressor [Beamer, L. J. & Pabo, C. O. (1992) J. Mol. Biol. 227, 177-196] the helices are 34 A apart and are essentially parallel to each other, but are inclined to the major grooves. The DNA is much more bent when bound by Cro than in the case with lambda-repressor. The first two amino acids of the recognition helices of the two proteins, Gln-27 and Ser-28 in Cro, and Gln-44 and Ser-45 in lambda-repressor, make very similar interactions with the invariant bps 2 and 4. There are also analogous contacts between the thymine of bp 5 and, respectively, the backbone of Ala-29 of Cro and the backbone of Gly-46 of lambda-repressor. Otherwise, however, unrelated parts of the two proteins are used in sequence-specific recognition. It appears that similar contacts to the invariant or almost invariant bps (especially 2 and 4) are used by both Cro and lambda-repressor to differentiate the operator sites as a group from other sites on the DNA. The discrimination of Cro and lambda-repressor between their different operators is more subtle and seems to be achieved primarily through differences in van der Waals contacts at bp 3', together with weaker, less direct effects at bps 5' and 8', all in the nonconsensus half of the operators. The results provide further support for the idea that there is no simple code for DNA-protein recognition.     

Lune/eye gone, a Pax-like protein, uses a partial paired domain and a homeodomain for DNA recognition

Pax proteins, characterized by the presence of a paired domain, play key regulatory roles during development. The paired domain is a bipartite DNA-binding domain that contains two helix-turn-helix domains joined by a linker region. Each of the subdomains, the PAI and RED domains, has been shown to be a distinct DNA-binding domain. The PAI domain is the most critical, but in specific circumstances, the RED domain is involved in DNA recognition. We describe a Pax protein, originally called Lune, that is the product of the Drosophila eye gone gene (eyg). It is unique among Pax proteins, because it contains only the RED domain. eyg seems to play a role both in the organogenesis of the salivary gland during embryogenesis and in the development of the eye. A high-affinity binding site for the Eyg RED domain was identified by using systematic evolution of ligands by exponential enrichment techniques. This binding site is related to a binding site previously identified for the RED domain of the Pax-6 5a isoform. Eyg also contains another DNA-binding domain, a Prd-class homeodomain (HD), whose palindromic binding site is similar to other Prd-class HDs. The ability of Pax proteins to use the PAI, RED, and HD, or combinations thereof, may be one mechanism that allows them to be used at different stages of development to regulate various developmental processes through the activation of specific target genes.     

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.     

Dimerization specificity of P22 and 434 repressors is determined by multiple polypeptide segments

The repressor protein of bacteriophage P22 binds to DNA as a homodimer. This dimerization is absolutely required for DNA binding. Dimerization is mediated by interactions between amino acids in the carboxyl (C)-terminal domain. We have constructed a plasmid, p22CT-1, which directs the overproduction of just the C-terminal domain of the P22 repressor (P22CT-1). Addition of P22CT-1 to DNA-bound P22 repressor causes the dissociation of the complex. Cross-linking experiments show that P22CT-1 forms specific heterodimers with the intact P22 repressor protein, indicating that inhibition of P22 repressor DNA binding by P22CT-1 is mediated by the formation of DNA binding-inactive P22 repressor:P22CT-1 heterodimers. We have taken advantage of the highly conserved amino acid sequences within the C-terminal domains of the P22 and 434 repressors and have created chimeric proteins to help identify amino acid regions required for dimerization specificity. Our results indicate that the dimerization specificity region of these proteins is concentrated in three segments of amino acid sequence that are spread across the C-terminal domain of each of the two phage repressors. We also show that the set of amino acids that forms the cooperativity interface of the P22 repressor may be distinct from those that form its dimer interface. Furthermore, cooperativity studies of the wild-type and chimeric proteins suggest that the location of cooperativity interface in the 434 repressor may also be distinct from that of its dimerization interface. Interestingly, changes in the dimer interface decreases the ability of the 434 repressor to discriminate between its wild-type binding sites, O(R)1, O(R)2, and O(R)3. Since 434 repressor discrimination between these sites depends in large part on the ability of this protein to recognize sequence-specific differences in DNA structure and flexibility, this result indicates that the C-terminal domain is intimately involved in the recognition of sequence-dependent differences in DNA structure and flexibility.     

Crystal structure of LacI member, PurR, bound to DNA: minor groove binding by alpha helices

The three-dimensional structure of a ternary complex of the purine repressor, PurR, bound to both its corepressor, hypoxanthine, and the 16-base pair purF operator site has been solved at 2.7 A resolution by x-ray crystallography. The bipartite structure of PurR consists of an amino-terminal DNA-binding domain and a larger carboxyl-terminal corepressor binding and dimerization domain that is similar to that of the bacterial periplasmic binding proteins. The DNA-binding domain contains a helix-turn-helix motif that makes base-specific contacts in the major groove of the DNA. Base contacts are also made by residues of symmetry-related alpha helices, the "hinge" helices, which bind deeply in the minor groove. Critical to hinge helix-minor groove binding is the intercalation of the side chains of Leu54 and its symmetry-related mate, Leu54', into the central CpG-base pair step. These residues thereby act as "leucine levers" to pry open the minor groove and kink the purF operator by 45 degrees.     

Crystal structure of an engineered Cro monomer bound nonspecifically to DNA: possible implications for nonspecific binding by the wild-type protein

The structure has been determined at 3.0 A resolution of a complex of engineered monomeric Cro repressor with a seven-base pair DNA fragment. Although the sequence of the DNA corresponds to the consensus half-operator that is recognized by each subunit of the wild-type Cro dimer, the complex that is formed in the crystals by the isolated monomer appears to correspond to a sequence-independent mode of association. The overall orientation of the protein relative to the DNA is markedly different from that observed for Cro dimer bound to a consensus operator. The recognition helix is rotated 48 degrees further out of the major groove, while the turn region of the helix-turn-helix remains in contact with the DNA backbone. All of the direct base-specific interactions seen in the wild-type Cro-operator complex are lost. Virtually all of the ionic interactions with the DNA backbone, however, are maintained, as is the subset of contacts between the DNA backbone and a channel on the protein surface. Overall, 25% less surface area is buried at the protein DNA interface than for half of the wild-type Cro-operator complex, and the contacts are more ionic in character due to a reduction of hydrogen bonding and van der Waals interactions. Based on this crystal structure, model building was used to develop a possible model for the sequence-nonspecific interaction of the wild-type Cro dimer with DNA. In the sequence-specific complex, the DNA is bent, the protein dimer undergoes a large hinge-bending motion relative to the uncomplexed form, and the complex is twofold symmetric. In contrast, in the proposed nonspecific complex the DNA is straight, the protein retains a conformation similar to the apo form, and the complex lacks twofold symmetry. The model is consistent with thermodynamic, chemical, and mutagenic studies, and suggests that hinge bending of the Cro dimer may be critical in permitting the transition from the binding of protein at generic sites on the DNA to binding at high affinity operator sites.     

Conformational changes of purine repressor DNA-binding domain upon complexation with DNA

The purine repressor (PurR) consists of two functional domains: an N-terminal DNA-binding domain and a C-terminal corepressor-binding domain. Recently, the structure of PurR-corepressor-operator ternary complex was determined by X-ray crystallography. In the complex the DNA-binding domain, consisting of 56 amino acids, was composed of four helices. Here, we have determined the solution structure of the DNA-binding domain in its DNA free state by NMR. It consists of three helices and the fourth helix (the hinge helix) region is diordered. The architecture of the first three helices of its DNA free state is very similar to that of its DNA-bound form. The hinge helix is induced by the specific DNA binding and by the dimerization of PurR which is provided by the corepressor-binding domain.     

Cooperative non-specific DNA binding by octamerizing lambda cI repressors: a site-specific thermodynamic analysis

Relationships between dimerization and site-specific binding have been characterized previously for wild-type and mutant cI repressors at the right operator (OR) of bacteriophage lambda DNA. However, the roles of higher-order oligomers (tetramers and octamers) that are also formed from these cI molecules have remained elusive. In this study, a clear correlation has been established between repressor oligomerization and non-specific DNA-binding activity. A modification of the quantitative DNase I footprint titration technique has been used to evaluate the degree of saturation of non-specific, OR-flanking lambda DNA by cI repressor oligomers. With the exception of one mutant, only those repressors capable of octamerizing were found to exhibit non-specific DNA-binding activity. The non-specific interaction was accurately modeled using either a one-dimensional, univalent, site-specific Ising lattice approximation, or a more traditional, multivalent lattice approach. It was found that non-specific DNA-binding by repressor oligomers is highly cooperative and energetically independent from site-specific binding at OR. Furthermore, the coupling free energy resolved for non-specific binding was similar to that of site-specific binding for each repressor, suggesting that similar structural elements may mediate the cooperative component of both binding processes. It is proposed that the state of assembly of the repressor molecule modulates its relative affinity for specific and non-specific DNA sequences. These specificities are allosterically regulated by the transmission of assembly-state information from the C-terminal domain, which mediates self-association and cooperativity, to the N-terminal domain, which primarily mediates DNA-binding. While dimers have a high affinity for their cognate sites within OR, tetramers and octamers may preferentially recognize non-specific DNA sequences. The concepts and findings developed in this study may facilitate quantitative characterization of the relationships between specific, and non-specific binding in other systems that utilize multiple modes of DNA-binding cooperativity.     

DNA binding by the KP repressor protein inhibits P-element transposase activity in vitro

P elements are a family of mobile DNA elements found in Drosophila. P-element transposition is tightly regulated, and P-element-encoded repressor proteins are responsible for inhibiting transposition in vivo. To investigate the molecular mechanisms by which one of these repressors, the KP protein, inhibits transposition, a variety of mutant KP proteins were prepared and tested for their biochemical activities. The repressor activities of the wild-type and mutant KP proteins were tested in vitro using several different assays for P-element transposase activity. These studies indicate that the site-specific DNA-binding activity of the KP protein is essential for repressing transposase activity. The DNA-binding domain of the KP repressor protein is also shared with the transposase protein and resides in the N-terminal 88 amino acids. Within this region, there is a C2HC putative metal-binding motif that is required for site-specific DNA binding. In vitro the KP protein inhibits transposition by competing with the transposase enzyme for DNA-binding sites near the P-element termini.