Solution NMR studies of intact lambda repressor

Papain does not cleave operator-bound lambda repressor: structural characterization of the carboxy terminal domain and the hinge

The circular dichroism spectra of three different purified carboxy terminal fragments 93-236, 112-236 and 132-236 of the bacteriophage lambda cI repressor have been measured and compared with those of the intact repressor and the amino terminal fragment 1-92. All three carboxy terminal fragments contain mostly beta-strands and loops, a minor helix content increasing with the size of the fragment, showing that the 93-131 region previously called a hinge is structured. Fourier transformed infrared spectra also showed that fragment 93-236 contains alpha-helices, alpha-sheets and turns but fragment 132-236 contains no detectable alpha-helix, only beta-sheets and turns. Papain is known to cleave the lambda repressor, but it is shown here that it cannot cleave the operator-bound repressor dimer. For the 132-236 fragment, both the wt and the SN228 mutant previously shown to be dimerization defective in the intact, gave similar dimerization properties as investigated by HPLC at 2 to 100 microM protein concentration, with a KD of 13.2 microM and 19.1 microM respectively. The papain cleavage for wt and SN228 proceed at equal rates for the first cleavage at 92-93; however, the subsequent cleavages are faster for SN228. The three Cys residues in the 132-236 fragment were found to be unreactive upon incubation with DTNB, indicating the thiol sulfur atoms are buried in the repressor carboxy terminal domain. Denaturation of the 132-236 fragment studied by tryptophan fluorescence shows two transitions centered at 1.5 M and 4.5 M of urea.

Crystal structure of the lambda repressor C-terminal domain provides a model for cooperative operator binding

Interactions between transcription factors bound to separate operator sites commonly play an important role in gene regulation by mediating cooperative binding to the DNA. However, few detailed structural models for understanding the molecular basis of such cooperativity are available. The c1 repressor of bacteriophage lambda is a classic example of a protein that binds to its operator sites cooperatively. The C-terminal domain of the repressor mediates dimerization as well as a dimer-dimer interaction that results in the cooperative binding of two repressor dimers to adjacent operator sites. Here, we present the x-ray crystal structure of the lambda repressor C-terminal domain determined by multiwavelength anomalous diffraction. Remarkably, the interactions that mediate cooperativity are captured in the crystal, where two dimers associate about a 2-fold axis of symmetry. Based on the structure and previous genetic and biochemical data, we present a model for the cooperative binding of two lambda repressor dimers at adjacent operator sites.

A variant of lambda repressor with an altered pattern of cooperative binding to DNA sites

The bacteriophage lambda repressor binds cooperatively to pairs of adjacent sites in the lambda chromosome, one repressor dimer binding to each site. The repressor's amino domain (that which mediates DNA binding) is connected to its carboxyl domain (that which mediates dimerization and the interaction between dimers) by a protease-sensitive linker region. We have generated a variant lambda repressor that lacks this linker region. We show that dimers of the variant protein are deficient in cooperative binding to sites at certain, but not all, distances. The linker region thus extends the range over which carboxyl domains of DNA-bound dimers can interact. In particular, the linker is required for cooperative binding to a pair of sites as found in the lambda chromosome, and thus is essential for the repressor's physiological function.

Biochemical characterization of the Oct-2 POU domain with implications for bipartite DNA recognition

B-cell specific regulation of immunoglobulin gene expression provides a model for the interaction of promoter and enhancer elements with eukaryotic sequence-specific DNA binding proteins. A critical element of this system, the octamer site (5'-ATGCAAAT-3'), is recognized by the B-cell transcription factor Oct-2. Octamer recognition is mediated by the POU domain, a conserved structural motif which--like the zinc finger and leucine zipper--defines a family of related transcription factors. Homologies among POU sequences suggest a bipartite structure, consisting of an N-terminal POU-specific subdomain and C-terminal variant homeodomain connected by a linker of variable length and sequence. As a first step toward a molecular understanding of the Oct-2 POU domain and its mechanism of DNA recognition, we have overexpressed in Escherichia coli the intact POU domain and subdomains as thrombin-cleavable fusion proteins and have purified these fragments to homogeneity following digestion with thrombin. Biochemical and biophysical characterization yields the following results. (i) The intact POU domain (166 residues) is monomeric and exhibits high-affinity octamer-specific DNA-binding activity. (ii) Limited proteolytic digestion demonstrates that the POU domain contains two proteolytically stable subdomains (the POU-specific subdomain and the variant homeodomain) connected by a proteolytically sensitive linker. (iii) The isolated subdomains are each monomeric and do not interact to form noncovalent heterodimers.(ABSTRACT TRUNCATED AT 250 WORDS)

Molecular modeling of antibody combining sites

Each of the six CDRs of Gloop2 is shown with the modeled structure in. Overall, the results obtained using the combined algorithm are similar in accuracy to those achieved using the canonical method of Chothia et al. However, the canonical method is limited to those loops where the key residues identified by Chothia are present. With the number of antibody structures currently available, it is not possible to classify CDR-H3 into canonical ensembles. Additionally, a small percentage of examples in the remaining CDRs do not match the current canonical classifications and the protein engineer may well wish to mutate the key residues, precluding the use of Chothia's method for modeling the resulting conformation. Thus the best approach appears to be to use Chothia's method (at least to model the backbone conformation) when the loop to be modeled is represented in the database of canonical structures. Any other loops, either unrepresented among the known canonicals (including CDR-H3), or where mutations have been made to the key residues, may then be modeled by the combined algorithm presented here.

Quaternary structure and function in phage lambda repressor: 1H-NMR studies of genetically altered proteins

The quaternary structure and dynamics of phage lambda repressor are investigated in solution by 1H-NMR methods. lambda repressor contains two domains separable by proteolysis: an N-terminal domain that mediates sequence-specific DNA-A binding, and a C-terminal domain that contains strong dimer and higher-order contacts. The active species in operator recognition is a dimer. Although the crystal structure of an N-terminal fragment has been determined, the intact protein has not been crystallized, and there is little evidence concerning its structure. 1H-NMR data indicate that the N-terminal domain is only loosely tethered to the C-terminal domain, and that its tertiary structure is unperturbed by proteolysis of the "linker" polypeptide. It is further shown that in the intact repressor structure a quaternary interaction occurs between N-terminal domains. This domain-domain interaction is similar to the dimer contact observed in the crystal structure of the N-terminal fragment and involves the hydrophobic packing of symmetry-related helices (helix 5). In the intact structure this interaction is disrupted by the single amino-acid substitution, Ile84----Ser, which reduces operator affinity at least 100-fold. We conclude that quaternary interactions between N-terminal domains function to appropriately orient the DNA-binding surface with respect to successive major grooves of B-DNA.

Interaction of mutant lambda repressors with operator and non-operator DNA

We have described a set of mutations that alter side-chains on the operator binding surface of lambda repressor. In this paper, we study the interactions of 12 purified mutant repressors with operator and non-operator DNA. The mutant proteins have operator affinities that are reduced from tenfold to greater than 10,000-fold compared to wild-type. Nine of the mutants have affinities for non-operator DNA that are similar to wild-type, two mutants show decreased non-specific binding, and one mutant has increased affinity for non-operator DNA. We discuss these findings in terms of the structural and energetic contributions of side-chain--DNA interactions, and show that certain contacts between the repressor and the operator backbone contribute both energy and specificity to the interaction.

N-terminal domain of the bacteriophage lambda repressor: investigation of secondary structure and tyrosine hydrogen bonding in wild-type and mutant sequences by Raman spectroscopy

Laser Raman spectroscopy has been employed to investigate structures of the lambda repressor N-terminal fragment, which recognizes operator DNA. Examination of repressor fragments containing deuterated amide groups and specifically labeled deuteriotyrosines has enabled the assignment of many of the conformation-sensitive Raman bands. By use of Fourier deconvolution and signal averaging techniques, the spectra of both wild-type and mutant sequences have been obtained as a function of the total protein concentration in aqueous solution over the range 5-100 mg/mL. This analysis has permitted monitoring of the monomer-dimer association of the repressor fragment and determination of the effects of dimerization upon individual side-chain interactions and main-chain secondary structure. The spectra are interpreted to reveal the hydrogen-bonding environments of four tyrosines of the N-terminal fragment (Y22, Y60, Y85, and Y88). The fifth tyrosine (Y101) is known from NMR experiments to be exposed to solvent molecules. The results show that in the dimer Y22 and Y85 are each acceptors of a strong hydrogen bond from a positive donor group, while Y88 is the donor of a strong hydrogen bond to a negative acceptor and Y60, like Y101, is involved in both a donor role and an acceptor role. Y60, Y85, and Y88, which are all near the dimer interface, undergo a collective change in hydrogen-bonding environment with dissociation of the dimer. The net effect of this change is the conversion of one acceptor tyrosine, deduced to be Y88, to a combined donor and acceptor role. The Raman results also indicate a predominantly alpha-helical structure for the N-terminal fragment in aqueous solution, with 70 +/- 4% of the residues incorporated into helical domains. The amount of alpha-helix determined from the Raman spectrum is consistent with X-ray and prediction results and is altered neither by the mutations C85----Y85 and C88----Y88 nor by dissociation of the dimer.

Isotope-detected 1H NMR studies of proteins: a general strategy for editing interproton nuclear Overhauser effects by heteronuclear decoupling, with application to phage lambda repressor

A strategy for editing interproton nuclear Overhauser effects (NOEs) in proteins is proposed and illustrated. Selective incorporation of 13C- (or 15N)-labeled amino acids into a protein permits NOEs involving the labeled residues to be identified by heteronuclear difference decoupling. Such heteronuclear editing simplifies the NOE difference spectrum and avoids ambiguities due to spin diffusion. Isotope-detected 1H NMR thus opens to study proteins too large for conventional one- and two-dimensional NMR methods (20-75 kDa). We have applied this strategy to the N-terminal domain of phage lambda repressor, a protein of dimer molecular mass 23 kDa. A tertiary NOE from an internal aromatic ring (Phe-51) to a beta-13C-labeled alanine residue (Ala-62) is demonstrated.

Phage lambda repressor revertants. Amino acid substitutions that restore activity to mutant proteins

We have isolated same-site and second-site revertants that restore partial activity, wild-type activity, or greater than wild-type activity, to lambda repressor proteins bearing different mutations in the DNA binding domain. In some cases the revertant repressors contain same-site substitutions that are similar to the wild-type side-chain (e.g. Tyr22----Phe, Ser77----Thr). The activity of these revertants makes it possible to assess the role of specific hydrogen bonds and/or packing interactions in repressor structure and function. In other same-site revertants, a very different type of residue is introduced (e.g. Ser35----Leu, Gly48----Asn). This indicates that the chemical and steric requirements at these side-chain positions are relaxed. Two of the second-site revertants, Glu34----Lys and Gly48----Ser, restore activity to more than one primary mutant. Both substitutions apparently increase the affinity of the repressor-operator interaction by introducing new contacts with operator DNA. These results suggest that reversion may be a generally applicable method for identifying sequence changes that increase the activity of a protein to greater than wild-type levels.

NH2-terminal arm of phage lambda repressor contributes energy and specificity to repressor binding and determines the effects of operator mutations

Several lines of evidence indicate that the phage lambda repressor recognizes its operator by using, in part, an alpha helix (the "recognition helix"), which it inserts into the major groove of DNA. In addition to its recognition helix, lambda repressor has an "arm," consisting of the first six amino acids, that wraps around the DNA helix. We constructed plasmids that, in Escherichia coli, direct the expression of derivatives of lambda repressor that lack the NH2-terminal one, three, six, or seven amino acids. We studied these modified proteins in vivo and in vitro, and from our results we argue that the arm: contributes a large portion of the binding energy; helps to determine sequence specificity of binding and, in particular, the relative affinities for two wild-type binding sites; determines entirely repressor's response to one operator mutation (a "back-side" mutation); magnifies repressor's response to other operator mutations ("front-side" mutations); and increases the sensitivity of repressor binding to salt concentration and temperature.

Structure of proteins with single-site mutations: a minimum perturbation approach

A large number of mutant proteins with single amino acid substitutions are now being produced. The ability to predict the structural changes expected from such mutations would aid greatly in the efficient utilization of the mutagenic techniques and in the interpretation of the changes in stability and function that result. A minimum perturbation approach is suggested as a first step in such structural predictions and is tested by application to a recently isolated variant of the hemagglutinin glycoprotein. The agreement between the predicted structure and that inferred from the x-ray refinement is encouraging and provides support for the proposed modeling procedure.

Dynamic filtering by two-dimensional 1H NMR with application to phage lambda repressor

Flexible regions of proteins play an important role in catalysis, ligand binding, and macromolecular interactions. Because of its enhanced sensitivity to motional narrowing, two-dimensional coupling constant J-correlated 1H NMR may be used to observe these regions selectively. Dynamic filtering is an intrinsic feature of this experiment because cross-peak amplitude decays rapidly as linewidths approach the coupling constant. We demonstrate here the flexibility of the NH2-terminal arm of phage lambda repressor, which is thought to wrap around the double helix in the repressor-operator complex. The assignment of arm resonances is made possible by the construction of mutant repressor genes containing successive NH2-terminal deletions.

Effect of single amino acid replacements on the thermal stability of the NH2-terminal domain of phage lambda repressor

The thermal stabilities of mutant phage lambda repressors that have single amino acid replacements in the NH2-terminal domain have been studied by means of circular dichroism and differential scanning calorimetry. The variations in stability determined by these physical methods correlate with the resistance to proteolysis at various temperatures and can be compared with the temperature-sensitive activity of the mutants in vivo. In general, mutant proteins bearing solvent-exposed substitutions have thermal stabilities identical to wild type, whereas buried substitutions reduce stability. In one case, a single amino acid replacement increases the thermal stability of the repressor.