NMR study of the interaction between the lac repressor and the lac operator

Introduction to a special issue of Magnetic Resonance in honour of Robert Kaptein at the occasion of his 80th birthday

This publication, in honour of Robert Kaptein's 80th birthday, contains contributions from colleagues, many of whom have worked with him, and others who admire his work and have been stimulated by his research. The contributions show current research in biomolecular NMR, spin hyperpolarisation and spin chemistry, including CIDNP (chemically induced dynamic nuclear polarisation), topics to which he has contributed enormously. His proposal of the radical pair mechanism was the birth of the field of spin chemistry, and the laser CIDNP NMR experiment on a protein was a major breakthrough in hyperpolarisation research. He set milestones for biomolecular NMR by developing computational methods for protein structure determination, including restrained molecular dynamics and 3D NMR methodology. With a lac repressor headpiece, he determined one of the first protein structures determined by NMR. His studies of the lac repressor provided the first examples of detailed studies of protein nucleic acid complexes by NMR. This deepened our understanding of protein DNA recognition and led to a molecular model for protein sliding along the DNA. Furthermore, he played a leading role in establishing the cluster of NMR large-scale facilities in Europe. This editorial gives an introduction to the publication and is followed by a biography describing his contributions to magnetic resonance.

Dynamics of protamine 1 binding to single DNA molecules

Protamine molecules bind to and condense DNA in the sperm of most vertebrates, packaging the sperm genome in an inactive state until it can be reactivated following fertilization. By using methods that enable the analysis of protamine binding to individual DNA molecules, we have monitored the kinetics of DNA condensation and decondensation by protamine 1 (P1) and synthetic peptides corresponding to specific segments of the bull P1 DNA binding domain. Our results show that the number of clustered arginine residues present in the DNA binding domain is the most important factor affecting the condensation and stability of the DNA-protamine complex prior to the formation of inter-protamine disulfide cross-links. The high affinity of P1 for DNA is achieved by the coordinated binding of three anchoring domains, which together in bull P1 contain 19 Arg residues. The single DNA molecule experiments show that sequences containing two or more anchoring domains have an off-rate that is at least 3 orders of magnitude slower than those containing a single domain. The use of Arg, rather than Lys residues, and the inclusion of Tyr or Phe residues in the hinge regions between anchoring domains provide additional stability to the complex.

31P NMR spectra of oligodeoxyribonucleotide duplex lac operator-repressor headpiece complexes: importance of phosphate ester backbone flexibility in protein-DNA recognition

The 31P NMR spectra of various 14-base-pair lac operators bound to both wild-type and mutant lac repressor headpiece proteins were analyzed to provide information on the backbone conformation in the complexes. The 31P NMR spectrum of a wild-type symmetrical operator, d(TGTGAGCGCTCACA)2, bound to the N-terminal 56-residue headpiece fragment of a Y7I mutant repressor was nearly identical to the spectrum of the same operator bound to the wild-type repressor headpiece. In contrast, the 31P NMR spectrum of the mutant operator, d(TATAGAGCGCTCATA)2, wild-type headpiece complex was significantly perturbed relative to the wild-type repressor-operator complex. The 31P chemical shifts of the phosphates of a second mutant operator, d(TGTGTGCGCACACA)2, showed small but specific changes upon complexation with either the wild-type or mutant headpiece. The 31P chemical shifts of the phosphates of a third mutant operator, d(TCTGAGCGCTCAGA)2, showed no perturbations upon addition of the wild-type headpiece. The 31P NMR results provide further evidence for predominant recognition of the 5'-strand of the 5'-TGTGA/3'-ACACT binding site in a 2:1 protein to headpiece complex. It is proposed that specific, strong-binding operator-protein complexes retain the inherent phosphate ester conformational flexibility of the operator itself, whereas the phosphate esters are conformationally restricted in the weak-binding operator-protein complexes. This retention of backbone torsional freedom in strong complexes is entropically favorable and provides a new (and speculative) mechanism for protein discrimination of different operator binding sites. It demonstrates the potential importance of phosphate geometry and flexibility on protein recognition and binding.

The lac repressor and its N-terminal headpiece can bind a mini-operator containing a hairpin loop made of a hexaethylene glycol chain

The binding of the lac repressor and the lac repressor N-terminal headpiece to a mini-operator with a hairpin loop made of a hexaethylene glycol chain was investigated using circular dichroism spectroscopy. The lac repressor's headpiece binds to the modified mini-operator with the same affinity as to a mini-operator of the same sequence without the hexaethylene glycol loop. The conformational effect due to the binding is not affected by the presence of the hexaethylene loop. It is also shown that the entire lac repressor binds to this modified mini-operator inducing a conformational change.

In vivo interaction of Escherichia coli lac repressor N-terminal fragments with the lac operator

Escherichia coli lac repressor is a tetrameric protein composed of 360 amino acid subunits. Considerable attention has focused on its N-terminal region which is isolated by cleavage with proteases yielding N-terminal fragments of 51 to 59 amino acid residues. Because these short peptide fragments bind operator DNA, they have been extensively examined in nuclear magnetic resonance structural studies. Longer N-terminal peptide fragments that bind DNA cannot be obtained enzymatically. To extend structural studies and simultaneously verify proper folding in vivo, the DNA sequence encoding longer N-terminal fragments were cloned into a vector system with the coliphage T7 RNA polymerase/promoter. In addition to the wild-type lacI gene sequence, single amino acid substitutions were generated at positions 3 (Pro3----Tyr) and 61 (Ser61----Leu) as well as the double substitution in a 64 amino acid N-terminal fragment. These mutations were chosen because they increase the DNA binding affinity of the intact lac repressor by a factor of 10(2) to 10(4). The expression of these lac repressor fragments in the cell was verified by radioimmunoassays. Both wild-type and mutant lac repressor N termini bound operator DNA as judged by reduced beta-galactosidase synthesis and methylation protection in vivo. These observations also resolve a contradiction in the literature as to the location of the operator-specific, inducer-dependent DNA binding domain.

Nuclear magnetic spectra of self complementary decanucleotides in solution; base sequence effect on the chemical shifts of nonexchangeable protons

The aim of this study was to attempt to determine the extent to which the chemical shifts of the nonexchangeable base protons of a DNA helix depend upon the base sequence. We measured the proton NMR spectra of twelve decadeoxynucleotides in order to carry out a "statistical" treatment. In the helices, the chemical shifts were found to be determined within +/- 0.04 ppm, largely by the nearest neighbor residues on the 5'-side, and to a smaller extent by the residue on the 3'-side. The theoretical chemical shift calculations reproduced very well the polymerization shifts measured for H2 protons of adenosines if the electrostatic field effect was taken into account. A fair agreement was also obtained for H8 protons of the adenosine and guanosine residues. However, theory underestimates the polarization effects of the base protons of cytidine. This discrepancy suggests that the conformation of this residue is different in the mononucleotides relative to double helices.

Quantum mechanical calculations of NMR chemical shifts in nucleic acids

During the last twenty-five years the development of quantum mechanical calculations and experimental measurements of chemical shifts of the different type of nuclei present in nucleic acids have run parallel in close relation to each other. The first calculations dealt with intramolecular effects on base proton shifts (Veillard, 1962) but the real breakthrough of the theory occurred with the advent of computations of intermolecular shielding due to the ring current effect of the nucleic acid bases (Giessner-Prettre & Pullman, 1970).

Sequence-specific assignments and their use in NMR studies of DNA structure

There has been a surge of recent interest, reflected by a sharp increase in the number of publications, in the area of high-resolution nuclear magnetic resonance (NMR) studies of DNA. The goal of many of these studies is to monitor the structure of biologically important DNA sequences directly in solution; the impetus for such studies was the realization, from early single-crystal X-ray structures, that nearest-neighbor context effects are a major determinant of local structure in short double-helical DNAs (Dickerson & Drew, 1981; Dickerson, 1983). Thus, instead of the previously assumed regular averaged structure of the double helix derived from fibre diffraction analysis, the more interesting concept emerged that specific sequence-dependent distortions from ‘classical’ DNA structure might be responsible for the recognition of such sequences by a variety of ligands such as repressors, polymerases, drugs, etc.

Lac repressor-Lac operator complexes. Solution X-ray scattering and electrophoretic studies

Complexes between the Lac repressor and a small DNA operator fragment (29 base pairs) were investigated using polyacrylamide gel electrophoresis and solution X-ray scattering. Titration of the DNA fragment with the repressor, followed by gel electrophoresis showed that only two types of complexes are formed with repressor/operator ratios of 0.5 and 2. Radii of gyration and forward scattered intensities were obtained from Guinier plots for repressor/operator ratios ranging from 0.3 to 2. They demonstrated that the first complex contains one repressor and two operators, whereas the second one contains four repressors and two operators. Mixing operator and repressor in equimolar concentrations leads to a mixture of both complexes. A possible model for the four repressor/two operator complex is proposed.

NMR studies of DNA recognition sequences and their interaction with proteins. The phage lambda OR1 operator, a symmetric lac operator and their specific complexes with cro protein and lac repressor "headpiece"

The phage lambda operator OR1 and a 18 base pair symmetric lac operator have been studied by high resolution NMR. The imino proton resonances and the resonances of the unexchangeable protons (except the 5' and 5" sugar proton resonances) have been assigned by one- and two-dimensional NOE techniques. The imino proton resonances of OR1 and the symmetric lac operator have been used to monitor changes induced in the operator structure by the formation of a specific complex with the phage lambda cro protein and with the lac repressor N-terminal DNA binding domain ("headpiece"). Two regions within the OR1 sequence could be identified, where changes in the imino proton resonance positions occur: The central part around base pairs CG 9 and 10 and the region around base pairs AT 5 and CG 5. The TA base pair 6 is the only position in the symmetric lac operator, where the complex formation with headpiece induces a change.

Lambda phage cro repressor interaction with its operator DNA: 2'-deoxy-5-fluorouracil OR3 analogues

The experiments here show that chemically synthesized DNA containing fluorine at selected sites can be used to test specific predictions of a model for cro repressor--operator interaction. This is done by observation of the perturbation to the fluorine-19 NMR spectra of analogues of OR3 synthesized with 2'-deoxy-5-fluorouracil at specific positions in the DNA helix. Although the three-dimensional structure of the cro repressor from phage lambda has been determined by Matthews and co-workers [Anderson, W., Ohlendorf, D., Takeda, Y., & Matthews, B. (1981) Nature (London) 290, 754-758], direct structural observations on the complex of the protein with its specific DNA recognition sequence, OR3, are limited. From that structure of the protein, alone, a model of its complex to DNA was built by fitting B-form DNA, with some distortion [Ohlendorf, D., Anderson, W., Fisher, R., Takeda, Y., & Matthews, B. (1982) Nature (London) 298, 718-723]. That model proposes that the cro repressor contacts only one side of this DNA double helix and a number of specific protein--DNA contacts. To test the model, 2'-deoxy-5-fluorouracil was used to place the fluorine-19 nuclear spin-label on the side of the DNA contacting the cro repressor and on the opposite side facing away from the cro repressor. The results presented here are consistent with the prediction that lambda phage cro repressor contacts only one side of the DNA double helix.

1H NMR study of the interaction of bacteriophage lambda Cro protein with the OR3 operator. Evidence for a change of the conformation of the OR3 operator on binding

The specific complex between the lambda phage OR3 operator and the Cro protein has been studied by proton NMR spectroscopy at 500 MHz. The DNA imino proton resonances of this complex have been assigned to specific base pairs using the known assignments of these resonances for the free operator. Increase of the protein/DNA ratio to complete saturation of the OR3 operator with the Cro protein made it possible to follow the shift changes of the resonances. Ambiguities were resolved by nuclear Overhauser effect measurements on the complex. The shifts of the imino proton resonance positions provide information on the changes induced in the conformation of the operator upon complex formation with a dimer of the Cro protein. The most striking shift occurs for the central (GC 9) base pair, which is known to have no direct contacts with the Cro protein. This shift may be induced by a bend in the OR3 operator DNA at the GC 9 base pair to accommodate the operator for the binding of the Cro protein dimer. The imino proton resonances of two additional base pairs can be observed in the complex, demonstrating an overall stabilization of the DNA structure by the binding of the Cro protein.