Circular dichroism and ultraviolet absorption of a deoxyribonucleic acid binding protein of filamentous bacteriophage

Different DNA-binding modes and cooperativities for bacteriophage M13 gene-5 protein revealed by means of fluorescence depolarisation studies

The binding of the bacteriophage-M13-encoded gene-5 protein to oligo(deoxythymidylic acid)s and M13 DNA was studied by means of tyrosyl fluorescence decay and fluorescence anisotropy measurements. The observed fluorescence decays could be described with two exponentials, characterised by the lifetimes tau 1 = 2.2 ns and tau 2 = 0.8 ns respectively. Only the amplitude of the longer-lifetime component is influenced by binding of the protein to DNA. This indicates that a part of the tyrosyl residues is involved in the binding. By means of fluorescence depolarisation measurements the rotational correlation time of the protein dimer is found to be 12.9 ns. In contrast to earlier measurements, carried out on the DNA-binding protein of phage Pf1 [Kneale, G. G. and Wijnaendts van Resandt, R. W. (1985) Eur. J. Biochem. 149, 85-93], the observed rotational correlation times of the gene-5 protein pass through a maximum when the protein is titrated with oligo(deoxythymidylic acid)s. This is not observed upon titration with M13 DNA. Our measurements showed that for the oligo(deoxythymidylic acid)s there clearly is a decrease in the number of clustered proteins on the lattice in the case of excess nucleotide. This is a direct consequence of the much lower cooperativity of the binding to the oligonucleotides compared to the cooperativity characteristic of binding to polynucleotides. The number of nucleotides covered by a protein monomer is found to be less than or equal to 3 for the oligonucleotides and approximately equal to 4 for M13 DNA. Model calculations show that the 'time-window' through which the fluorescence depolarisation can be observed (i.e. the fluorescence lifetime) in this case significantly affects the 'measured' effective rotational correlation times.

The binding of fd gene 5 protein to polydeoxynucleotides: evidence from CD measurements for two binding modes

Circular dichroism measurements were used to study the binding of fd gene 5 protein to fd DNA, to six polydeoxynucleotides (poly[d(A)], poly[d(T)], poly[d(I)], poly[d(C)], poly[d(A-T)], and the random copolymer poly[d(A,T)]), and to three oligodeoxynucleotides (d(pA)20, d(pA)7, and d(pT)7). Titrations of these DNAs with fd gene 5 protein were generally done in a low ionic strength buffer (5 mM Tris-HCl, pH 7.0 or 7.8) to insure tight binding, needed to obtain stoichiometric endpoints. By monitoring the CD of the nucleic acids above 250 nm, where the protein has no significant intrinsic optical activity, we found that there were two modes of binding, with the number of nucleotides covered by a gene 5 protein monomer (n) being close to either 4 or 3. These stoichiometries depended upon which polymer was titrated as well as upon the protein concentration. Single endpoints at nucleotide/protein molar ratios close to 3 were found during titrations of poly[d(T)] and fd DNA (giving n = 3.1 and 2.8 +/- 0.2, respectively), while CD changes with two apparent endpoints at nucleotide/protein molar ratios close to 4 and approximately 3 were found during titrations of poly[d(A)], poly[d(I)], poly[d(A-T)], and poly[d(A,T)] (with the first endpoints giving n = 4.1 4.0, 4.0, and 4.1 +/- 0.3, respectively). Calculations showed that the CD changes we observed during these latter titrations were consistent with a switch between two non-interacting binding modes of n = 4 and n = 3. We found no evidence for an n = 5 binding mode. One implication of our results is that the Brayer and McPherson model for the helical gene 5 protein-DNA complex, which has 5 nucleotides bound per protein monomer (G. Brayer and A. McPherson, J. Biomol. Struct. and Dyn. 2, 495-510, 1984), cannot be correct for the detailed solution structure of the complex. We interpreted the CD changes above 250 nm upon binding of the gene 5 protein to single-stranded DNAs to be the result of a slight unstacking of the bases, along with a significant alteration of the CD contributions of the individual nucleotides in the case of A-and/or T-containing DNAs. Interestingly, CD contributions attributed to nearest-neighbor interactions in free poly[d(A-T)], poly[d(A,T)], poly[d(A)], and poly[d(T)] were partially maintained in the CD spectra of the protein-saturated polymers, so that neighboring nucleotides, when bound to the protein at 20 degrees C, appeared to interact with one another in much the same manner as in the free polymers at 50 degrees C.(ABSTRACT TRUNCATED AT 250 WORDS)

Specificity of the binding of bacteriophage M13 encoded gene-5 protein to DNA and RNA studied by means of fluorescence titrations

The fluorescence quenching of the bacteriophage M13 encoded gene-5 protein was used to study its binding characteristics to different polynucleotides. Experiments were performed at different salt concentrations and in some instances at different temperatures. The affinity of the protein depends on the base and sugar composition of the polynucleotides involved and may differ appreciably, i.e. by orders of magnitude. The salt dependence of binding is within experimental accuracy equal for all single stranded polynucleotides. A method is presented to estimate values of the cooperativity constant from salt titration curves. These values are systematically higher than those obtained from titration experiments in which protein is added to a polynucleotide solution. A comparison is made between the binding constants of the gene-5 protein and the gene-32 protein encoded by the T4 phage. Possible implications of the binding characteristics of the gene-5 protein for an understanding of its role in vivo are discussed.

The precursor complex of Pf3 bacteriophage

Filamentous bacteriophage infections give rise to intracellular filamentous precursor complexes composed of a circular single-stranded DNA molecule and on the order of 10(3) copies of a viral-encoded, single-stranded DNA binding protein. A protocol was developed for the purification of the precursor complex from Pf3 phage-infected Pseudomonas aeruginosa cells, and existing protocols for Ff and Pf1 complexes were amended by the introduction of a molecular sieving column step. The Pf3 precursor complex has an average contour length of 500 nm, which is shorter than that of the mature Pf3 virus. M/L (mass/length) values were obtained from turbidity measurements, from scanning-transmission electron microscopy, and from the total particle mass divided by its length. The average M/L obtained was 19,300 Da/nm which is close to that of the Pf3 virion. The complex has a nucleotide/subunit ratio of 6.0. The protein component of the precursor complex has less than 10% alpha-helicity, whereas the protein component of the virus is greater than 90% alpha-helical. The DNA structure in the precursors is very different from that in the virus, so that during virus assembly the DNA structure must change dramatically. The results for the Pf3 system, together with the available information for the Ff and Pf1 filamentous virus systems, indicate that different DNA-protein interactions and packing arrangements are involved in performing equivalent functions.

A model for intracellular complexation between gene-5 protein and bacteriophage fd DNA

A structural model for the helical intracellular complex formed between the gene-5 DNA-binding protein (G 5 BP; approximately 1274 copies) and bacteriophage fd DNA has been derived by an atomic-contact analysis approach. These studies depended in large part on the recently determined high-resolution structure of the G 5 BP dimer and cross-correlations with physical-chemical data available from other techniques. The approach was to systematically scan the full set of helical complexation parameters involved, based upon observed structural and orientational constraints, to determine those compatible with both the structure of the G 5 BP dimer and the overall dimensions of the full complex. This process was monitored throughout by close scrutiny of dimer-dimer contacts and the use of hard-copy and interactive graphics devices. Instead of the wide variety of possibilities that had been expected from such an approach, only one satisfactory assembly of DNA and G 5 BP dimers could be found. The results indicate that phage DNA will be wound to the outside of the helical protein ribbon that forms the core of intracellular complex at a density of five nucleotides per G 5 BP monomer. Bound DNA strands are positioned in two contiguous binding channels, which form as a consequence of the interactions of complexed G 5 BP dimers. These channels run just inside the outer extended beta loops, composed of residue 20-30, and are separated by approximately 3.2 nm. The DNA phosphate backbone is bound at a substantially smaller radial distance (approximately 3.5 nm) than the maximum radius of the intracellular complex as a whole (approximately 4.5 nm) since bound DNA is embedded within these well-defined binding channels. Our studies also indicate that a number of sterically unacceptable contacts, involving residues 38-42, prevent complexation of otherwise complementary dimer surfaces in the absence of nucleic acids. In the process of binding DNA, these residues change conformation thereby allowing self-assembly of dimer units into a helical structure. We propose that these residues act as a two-position stereochemical switch that allows or disallows complex formation in response to the absence or presence of DNA.

Time-resolved fluorescence of bacteriophage Pf1 DNA-binding protein. Determination of oligonucleotide and polynucleotide binding parameters

The binding of oligonucleotides and polynucleotides to the Pf1 DNA-binding protein was followed by fluorescence spectral shift and lifetime measurements, which gave an anomalous value for the stoichiometry of binding. The anomaly was investigated in detail using fluorescence depolarisation to measure the aggregation during the titration and showed that all the fluorescence parameters are related to the specific aggregation of dimers on ligand binding. At saturation, complexes of the protein with the octanucleotide d(GCGTTGCG) and the hexadecanucleotide (dT)16 have rotational correlation times, phi, of 50 ns and 85 ns, corresponding to protein tetramers and octamers, respectively. In the presence of the tetranucleotide d(CGCA) the protein remains as the native dimer (phi = 19 ns). The titration curves could be analysed in terms of two non-equivalent binding sites, with binding constants K1 and K2. Comparison of K1 values for oligonucleotide binding leads to an estimated (single-site) intrinsic binding constant Kint approximately equal to 3 X 10(4) M-1 and a cooperativity parameter omega approximately equal to 100, in agreement with the apparent binding constant Kapp approximately equal to 3 X 10(6) M-1 for polynucleotides. Binding to the second site on the protein dimer is greatly reduced and cannot be determined accurately. The results suggest that the protein dimers bind cooperatively by lateral association along the DNA and that occupation of only one of the two DNA-binding sites of the protein dimers is sufficient to stabilize the nucleoprotein complexes.

Identification of lysine residues at the binding site of bacteriophage-Pf1 DNA-binding protein

The accessibility of NH2 groups in the DNA-binding protein of Pf1 bacteriophage has been investigated by differential chemical modification with the reagent ethyl acetimidate. The DNA-binding surface was mapped by identification of NH2 groups protected from modification when the protein is bound to bacteriophage-Pf1 DNA in the native nucleoprotein complex and when bound to the synthetic oligonucleotide d(GCGTTGCG). The ability of the modified protein to bind to DNA was monitored by fluorescence spectroscopy. Modification of the NH2 groups in the native nucleoprotein complex showed that seven out of the eight lysine residues present, and the N-terminus, were accessible to the reagent, and were not protected by DNA or by adjacent protein subunits. Modification of these residues did not inhibit the ability of the protein to bind DNA. Lysine-25 was identified by peptide mapping as being the major protected residue. Modification of this residue does abolish DNA-binding activity. Chemical modification of the accessible NH2 groups in the complex formed with the octanucleotide effectively abolishes binding to DNA. Peptide mapping established that, in this case, lysine-17 was the major protected residue. The differences observed in protection from acetimidation, and in the ability of the modified protein to bind DNA, indicate that the oligonucleotide mode of binding is not identical with that found in the native nucleoprotein complex with bacteriophage-Pf1 DNA.

Cooperative interactions of the gene 5 protein

Using the refined molecular structure of the Gene 5 DNA Binding Protein (G5BP) and the mechanism of DNA binding deduced from a variety of experimental techniques (G. D. Brayer and A. McPherson, J. Mol. Biol. 169, 565, 1983; G. D. Brayer and A. McPherson, Biochemistry 23, 340, 1984), we have modeled the contiguous, linear aggregation of G5BP dimers along two opposing single strands of DNA. Using both automated graphics systems and systematic calculations of intermolecular contacts between adjacent units, we have optimized the fit of complementary protein surfaces in the presence of DNA. We propose that a minor conformational change involving residues 38-43, triggered by the binding of nucleic acid, relieves several critical steric contacts and permits otherwise extensively complementary surfaces to form an interface. The bonding between surfaces on adjacent G5BP units is the primary source of the cooperativity of binding observed for G5BP. The interacting amino acid residues at the interface are described.

Reductive methylation of the lysyl residues in the fd gene 5 DNA-binding protein: CD and 13C NMR results on the modified protein

The epsilon-amino groups of the six lysyl residues of the fd gene 5 DNA-binding protein have been modified by reductive methylation to form N epsilon, N epsilon-dimethyl lysyl derivatives containing 13C-labeled methyl groups. The alpha-amino terminus of the protein was not accessible to methylation. Circular dichroism studies show that the modified protein binds to fd DNA, but with a slightly reduced affinity compared with that of unmodified gene 5 protein. We also find that both the modified and unmodified proteins bind to an oligodeoxynucleotide, d(A)7, but in neither case does binding cause a decrease in the 228 nm CD band of the protein as occurs when the protein binds to long DNA polymers. 13C NMR spectra at 50.1 MHz of [13C]methylated gene 5 protein show five distinct resonances between 43.30 and 42.76 ppm originating from the six N epsilon, N epsilon-dimethyl lysyl residues. We attribute one of the resonances to two solvated lysyl residues and the other four to individual lysyl residues in different microenvironments. All four of these latter resonances are affected by the binding of d(A)7. However, since two of these resonances are similarly affected by the presence of salt in the absence of DNA, only two are uniquely affected by DNA binding.

Complex of fd gene 5 protein and double-stranded RNA

We report the formation of complexes of the single-stranded DNA binding protein encoded by gene 5 of fd virus, with natural double-stranded RNAs. In the first direct visualization of a complex of the fd gene 5 protein with a double-stranded nucleic acid, we show by electron microscopy that the double-stranded RNA complex has a structure which is distinct from that of complexes with single-stranded DNA and is consistent with uniform coating of the exterior of the double-stranded RNA helix by the protein. Circular dichroism spectral data demonstrate that the RNA double helix in the complex is undisrupted, and that perturbation of the 228-nm circular dichroism assigned to protein tyrosines can occur in the absence of intercalation of nucleotide bases with protein aromatic residues. Our findings emphasize the potential importance of interaction with the sugar-phosphate polynucleotide backbone in binding of the fd gene 5 protein to nucleic acids.

Refined structure of the gene 5 DNA binding protein from bacteriophage fd

The three-dimensional structure of the gene 5 DNA binding protein (G5BP) from bacteriophage fd has been determined from a combination of multiple isomorphous replacement techniques, partial refinements and deleted fragment difference Fourier syntheses. The structure was refined using restrained parameter least-squares and difference Fourier methods to a final residual of R = 0.217 for the 3528 statistically significant reflections present to 2.3 A resolution. In addition to the 682 atoms of the protein, 12 solvent molecules were included. We describe here the dispositions and orientations of the amino acid side-chains and their interactions as visualized in the G5BP structure. The G5BP monomer of 87 peptide units is almost entirely in the beta-conformation, organized as a three-stranded sheet, a two-stranded beta-ribbon and a broad connecting loop. There is no alpha-helix present in the molecule. Two G5BP monomers are tightly interlocked about an intermolecular dyad axis to form a compact dimer unit of about 55 A X 45 A X 36 A. The dimer is characterized by two symmetry-related antiparallel clefts that traverse the monomer surfaces essentially perpendicular to the dyad axis. From the three-stranded antiparallel beta-sheet, formed from the first two-thirds of the sequence, extend three tyrosine residues (26, 34, 41), a lysine (46) and two arginine residues (16, 21) that, as indicated by other physical and chemical experiments, are directly involved in DNA binding. Other residues likely to share binding responsibility are arginine 80 extending from the beta-ribbon and phenylalanine 73 from the tip of this loop, but as provided, however, by the opposite monomer within each G5BP dimer pair. Thus, both symmetry-related DNA binding sites have a composite nature and include contributions from both elements of the dimer. The gene 5 dimer is clearly the active binding species, and the two monomers within the dyad-related pair are so structurally contiguous that one cannot be certain whether the isolated monomer would maintain its observed crystal structure. This linkage is manifested primarily as a skeletal core of hydrophobic residues that extends from the center of each monomer continuously through an intermolecular beta-barrel that joins the pair. Protruding from the major area of density of each monomer is an elongated wing of tenuous structure comprising residues 15 through 32, which is, we believe, intimately involved in DNA binding. This wing appears to be dynamic and mobile, even in the crystal and, therefore, is likely to undergo conformational change in the presence of the ligand.

The lysine residues implicated in the gene 5 protein association sites

Gene 5 protein, a DNA unwinding protein encoded by the bacteriophage fd, is self-associative in presence of DNA or oligonucleotides. The lysine residues implicated in the protein-protein binding domains have been identified after modification with acetimidate by means of peptide and amino acid analyses. These residues are Lys-7 and Lys-69.

Dissociation of the Pf1 nucleoprotein assembly complex and characterisation of the DNA binding protein

During replication of bacteriophage Pf1, progeny viral strands are complexed with a single-stranded DNA binding protein, analogous to the gene 5 protein of bacteriophage fd. Using fluorescence spectroscopy, ultracentrifugation and DNA-cellulose chromatography, conditions for dissociation of the nucleoprotein have been investigated. The Pf1 protein is unusual in that it is not released from the DNA by 2 M NaCl. Complete separation occurs in 0.6-1.0 M MgCl2, leading to a procedure for the purification of the protein. Two subfractions of the protein can be isolated of isoelectric points 5.9 and 6.4. The molecular weight of the native DNA binding protein has been studied by gel filtration and sedimentation. The major species in solution has a sedimentation coefficient of 2.3 S and a diffusion coefficient of 7.8 X 10(-7) cm2 . s-1, corresponding to a protein dimer (Mr = 30 800). Protein tetramers are induced in the presence of octanucleotides, but not tetranucleotides. Analysis of the ultraviolet spectra of the DNA binding protein and the native nucleoprotein complex indicates a stoichiometry of 3.9 +/- 0.4 nucleotides per protein subunit. The molar extinction coefficient of the DNA when bound to the protein (epsilon 260 = 8100) suggests that the binding protein maintains the DNA in an extended (unstacked) conformation similar to that found in the mature Pf1 virion.

Neutron scattering data on reconstituted complexes of fd deoxyribonucleic acid and gene 5 protein show that the deoxyribonucleic acid is near the center

We have performed low-angle neutron scattering studies on reconstituted complexes of fd DNA and the gene 5 protein that is produced during infection of Escherichia coli by filamentous fd phage. Essentially identical helical complexes have been made with normal protonated DNA or DNA in which at least 87% of the nonexchangeable protons are replaced by deuterium. From neutron scattering profiles of both complexes over a range of D2O/H2O solvent mixtures, the DNA deuteration is shown to have a dramatic influence on the measured cross-sectional radius of gyration. Most importantly, data for the complex containing deuterated DNA lead to a more negative slope in a plot of the square of the cross-sectional radius of gyration vs. the inverse of the solute-solvent contrast, compared with the slope of a plot of data for the complex containing protonated DNA. This means that, in a cross-sectional view of the complex, the DNA is near the center of the structure. By our analysis, the DNA has a cross-sectional radius of gyration of 17.6 +/- 3 A, while the protein has a cross-sectional radius of gyration of about 33.5 A. Therefore, the model for the structure of the helical complex that has been proposed from X-ray diffraction studies on gene 5 protein crystallized with oligodeoxynucleotides [McPherson, A., Jurnak, F., Wang, A., Kolpak, F., Rich, A., Molineux, I., & Fitzgerald, P. (1980) Biophys. J. 32, 155-170] is not valid for the complex in solution. From our neutron diffraction data we have also obtained values for the solvent-excluded volume and mass per unit length. The relation of our findings to the solution structure of the complex is discussed.

1H NMR studies of the binding of bacteriophage-M13-encoded gene-5 protein to oligo(deoxyadenylic acid)s of varying length

The binding of gene-5 protein to oligo(deoxyadenylic acid)s varying in length from 2 to 16 nucleotides has been studied by titrating the protein with the oligonucleotides and recording the 1H NMR spectra at 360 MHz. To obtain information about the mode of binding of the protein the aromatic parts of the spectra have been analysed by performing spectral simulations, starting from the assignments obtained from nuclear Overhausfer enhancements at 500 MHz [Alma, N. C. M., Harmsen, B. J. M., Hull, W. E., Van der Marel, G., Van Boom, J.H., and Hilbers, C. W. (1981) Biochemistry, 20, 4419-4428]. The 1H NMR spectra of the complexes of gene-5 protein with (dA)8, (dA)12 and (dA)16 appear to be identical except for differences in linewidth. The 1H NMR spectra of the complexes with the smaller oligonucleotides (dA)2, (dA)3 and (dA)4 differ from each other and from the spectra obtained from the complexes with longer oligonucleotides. However, binding of all oligonucleotides basically influences the same aromatic residues, namely two tyrosines and one phenylalanine. In the protein-oligonucleotide complexes, one protein monomer covers three nucleotide residues, in contrast to the stoichiometry of 1:4 found for protein-polynucleotide complexes. It was found that the binding to oligonucleotides is cooperative and ionic-strength-dependent but far less so than found for the binding to polynucleotides.

The structure of a DNA unwinding protein and its complexes with oligodeoxynucleotides by x-ray diffraction

The structure of the gene 5 DNA unwinding protein from bacteriophage fd has been solved to 2.3 A resolution by x-ray diffraction techniques. The molecule contains an extensive cleft region that we have identified as the DNA binding site on the basis of the residues that comprise its surface. The interior of the groove has a rather large number of basic amino acid residues that serve to draw the polynucleotide backbone into the cleft. Arrayed along the external edges of the groove are a number of aromatic amino acid side groups that are in position to stack upon the bases of the DNA and fix it in place. The cleft then acts as an elongated pair of jaws that draws the DNA between them by charge interactions involving the phosphates with the interior lysines and arginines. The jaws then close on the DNA strand through small conformation changes and the rotation of aromatic side-chains into position to stack upon the purines and pyrimidines. Complexes of the gene 5 protein with a variety of oligodeoxynucleotides have been formed and crystallized for x-ray diffraction analysis. The crystallographic parameters of four different unit cells indicate that the fundamental unit of the complex is composed of six gene 5 protein dimers. We believe this aggregate has 622 point group symmetry and is a ring formed by end to end closure of a linear array of six dimers. From our results we have proposed a double helical model for the gene 5 protein-DNA complex in which the protein forms a spindle or core around which the DNA is spooled. 5.0-A x-ray diffraction data from one of the crystalline complexes is currently being analyzed by molecular replacement techniques to obtain what we believe will be the first direct visualization of a protein-deoxyribonucleic acid complex approaching atomic resolution.

A circular dichroism study of Escherichia coli Initiation Factor-1 binding to polynucleotides

Binding of Escherichia coli Initiation Factor-1 protein to the nucleic acid lattice induces alterations in the secondary structures of a variety of purine and pyrimidine containing polynucleotides in both the single and double stranded conformations, as assessed by circular dichroism spectroscopy. The helical hairpin form of poly(U), the single-stranded stacked form of poly(C), and the duplex poly(A) x poly(U) (in the presence of Mg2+) are stoichiometrically converted by Initiation Factor-1 (IF-1) to structures spectrally indistinguishable from their partially or completely thermally denatured forms. By contrast, the binding of IF-1 to double stranded poly(C), single- and double-stranded poly(A) elicited spectral responses which were interpreted in terms of diminished base-base interaction, not equivalent to that induced by thermal means. Stoichiometric endpoints of 3-5 nucleotide residues/IF-1 were determined for polynucleotide structures in those cases where light scattering artifacts at low nucleotide residue to protein ratios were absent. In the absence of Mg2+ IF-1 was unable to elicit a conformation alteration effect in poly(A) x poly(U), while for poly(U) much less of an effect was observed than in the presence of this divalent ion. The functional significance of these results is briefly considered.

NMR studies of the interaction of gene-V protein of bacteriophage M13 with oligonucleotides

This paper describes the preparation of deuterated phenylalanine ([2H7]-phenylalanine) and the isolation of phage M13 encoded gene-V protein in which this deuterated amino acid was incorporated. Using this protein spectral assignments of resonances in the aromatic region of the 1H-NMR spectrum of the gene-V protein have been made. Furthermore the interaction of the gene-V protein with the tetranucleotide d(pC-G-C-G) and the hexanucleotide d(pC-G-C-G-C-G) was investigated. From the changes in the aromatic region of the NMR spectrum occurring after binding, it is concluded that at least one phenylalanine and one tyrosine is involved in the interaction with the oligonucleotides via stacking.

Structure of the DNA binding cleft of the gene 5 protein from bacteriophage fd

The structure of the gene 5 DNA unwinding protein from bacteriophage fd has been solved to 2.3-A resolution by X-ray diffraction techniques. The molecule contains an extensive cleft region that we have identified as the DNA binding site on the basis of the residues that comprise its surface. The interior of the groove has a rather large number of basic amino acid residues that serve to draw the polynucleotide backbone into the cleft. Arrayed along the external edges of the groove are a number of aromatic amino acid side groups that are in position to stack upon the bases of the DNA and fix it in place. The structure and binding mechanism as we visualize it appear to be fully consistent with evidence provided by physical-chemical studies of the protein in solution.

Tyrosyl-base-phenylalanyl intercalation in gene 5 protein-DNA complexes: proton nuclear magnetic resonance of selectively deuterated gene 5 protein

The interactions of oligodeoxynucleotides with the aromatic residues of gene 5 protein in complexes with d(pA)8 and d(pT)8 have been determined by 1H NMR of the protein in which the five tyrosyl residues have been selectively deuterated either in the 2,6 or the 3,5 positions. Only the 3,5 protons of the three surface tyrosyls (26, 41, and 56) interact with the bases. The remainder of the aromatic protons undergoing base-dependent upfield ring-current shifts on complex formation are phenylalanyl protons, assigned to Phe(13) on the basis of model building. 19F NMR of the complexes of the m-fluorotyrosyl-labeled protein with d(pT)4 and d(pA)8 confirms the presence of ring-current perturbations of nuclei at the 3,5-tyrosyl positions of the three surface tyrosyls. Differential expression of the 19F(1H) nuclear Overhauser effect confirms the presence of two buried and three surface tyrosyl residues. A new model of the DNA binding groove is presented involving Tyr(26)-base-Phe(13) intercalation.

A photo-CIDNP study of the interaction of oligonucleotides with gene-5 protein of bacteriophage M13

It is shown that photo-CIDNP effects (CIDNP, chemically induced dynamic nuclear polarization) can be generated in the 360-MHz proton NMR spectrum of gene-5 protein from bacteriophage M13. This technique is used to determine the number of tyrosyl residues at the surface of the protein and to assign the resonances from the 3,5-ring protons of these residues. The DNA-binding site of the protein is investigated by formation of complexes with oligonucleotides. Complex formation leads to shifting and/or quenching of the photo-CIDNP emission signals of the surface tyrosines, implying that they are involved in DNA-protein interaction. These experiments are complemented by studying the complex formation of Lys-Tyr-Lys to poly(A).

Studies on DNA unwinding. Proton and phosphorus nuclear-magnetic-resonance studies of gene V protein from bacteriophage M13, interacting with d(pC-G-C-G)

The interaction of gene V protein from bacteriophage M13 with the self-complementary tetranucleotide d(pC-G-C-G) was studied by 1H and 31P nuclear magnetic resonance. It is shown, using the hydrogen-bonded proton resonances of the Watson-Crick base pairs as a probe, that the protein is able to unwind the small double-helical fragment even at 0 degrees C. Binding of the tetranucleotide causes changes in the aromatic part of the 1H NMR spectrum of the complex, suggesting that aromatic residues, most likely tyrosines, take part in the protein.nucleic-acid interaction. From the 31P NMR spectra of the protein.nucleic-acid complex it follows that the pK value of the 5'-terminal phosphate is lower than for the free nucleic acid species. Moreover, it could be shown that the exchange of the protein between nucleic acid substrates is fast. Combination of these measurements has led us to derive a mechanism of unwinding on the tetranucleotide level. To a large extent the unwinding is determined by fluctuations in the double-helical DNA structure.

The binding of fd gene-5 protein to single-stranded nucleic acid

The gene-5 protein of the fd filamentous bacterial virus binds to single-stranded DNA over a pH range of 2-10.3. Binding to fd DNA is several hundred-fold stronger than to bacteriophage R17 RNA or to DNA tetranucleotides.

Conformational changes in chromatin from density inhibited WI-38 fibroblasts stimulated to proliferate

Quiescent confluent monolayers of WI-38 human diploid fibroblasts can be stimulated to proliferate by replacing the old medium with fresh medium plus 10% serum. Circular dichroism spectra of chromatin from stimulated cells between 2 and 10 hrs after stimulation show an increase in positive ellipticity maxima and a blue shift in the 250-300 nm region. These changes are reversed when the stimulated cells enter DNA synthesis (which, in the present conditions, begins to increase at 12-15 hrs and reaches a peak at 20 hrs). The circular dichroism changes occurring 3 hrs after stimulation have been studied in greater detail. They consist in a 35% (average) increase in positive ellipticity and a blue shift in the 250-300 nm region. Changes in the gamma less than 244 nm region are less consistent. The differences between chromatins of stimulated and unstimulated cells are abolished when both chromatins are washed with 0.25 M NaC1. This procedure removes 10-12% of chromosomal proteins, which chromatograph with non-histone proteins. DNA, RNA and histones could not be detected in the 0.25 M NaC1 extract. In gel electrophoretic profiles of radioactively labelled chromosomal proteins from stimulated and unstimulated WI-38 cells there were no detectable differences between histones. The non-histone proteins of stimulated cells showed one radioactive peak which was increased above the level of non-histone proteins from control cells. These results show that structural changes occur in the chromatin of WI-38 cells stimulated to proliferate several hrs before the onset of DNA synthesis. The fact that differences in the chromatins can be abolished by washing with 0.25 M NaC1 could give a clue as to the mechanisms responsible for these structural changes.

Chemical modifications of functional residues of fd gene 5 DNA-binding protein

The binding of gene 5 protein from bacteriophage fd to poly[d(A-T)], fdDNA, and poly(A) is accompanied by a dramatic reversal in the signs of the large ellipticity bands of the nucleic acid chromophores from 250 to 290 nm. The change in the circular dichroism of the DNA induced by the protein, which reaches a maximum at a protein to nucleotide molar ratio of 1:4, has been used as an assay of the alterations in binding of gene 5 protein to DNA accompanying changes in the ionic environment and subsequent to chemical modification of the protein. Divalent cations completely dissociate the gene 5 protein-fd DNA complex at 0.1 M, while 0.5 M monovalent cations are required. All cations are more effective in dissociating the complex with poly[d(A-T)] commensurate with the accompanying stabilization of the double helix to which gene 5 protein does not bind. Acetylation of all six lysyl residues and three of the five tyrosyl residues of the protein with N-acetylimidazole prevents complex formation. Removal of the three tyrosyl O-acetyl groups with hydroxylamine does not restore the binding of gene 5 protein to DNA. Tetranitromethane nitrates the same three tyrosyl residues (Tyr-26, Tyr-41, and Tyr-56 as determined by peptide mapping) and reduces the binding affinity of the protein for fd DNA by similar to 100-fold. The 19F NMR spectrum of gene 5 protein labeled with m-fluorotyrosine shows three surface and two buried fluorotyrosyl residues. All tyrosyl residues are protected from nitration in the complex with fd DNA, but acetylimidazole acetylates surface lysyl residues in the complex and dissociates it. The intrinsic circular dichroism of the acetylated and nitrated gene 5 proteins is not significantly altered. In contrast maleic anhydride reacts with the seven amino groups of the protein and changes the secondary structure to one similar to that present in 6 M guanidine-HCl. The single SH group of the native protein does not react with Ellman's reagent, but it reacts rapidly with one Hg2+ ion which unfolds the protein; fd DNA prevents reaction with Hg2+. Electrostatic forces may be as important as hydrogen bonding in maintaining the native structure of this protein. The lysyl groups of the protein, exposed in both the free protein and the DNA complex, appear to be of prime importance in DNA binding, probably through electrostatic interactions with the DNA binding, probably through electrostatic interactions with the DNA phosphate groups. Three tyrosyl residues also contribute to binding affinity through hydrogen bonding or intercalation. A model of gene 5 protein structure in relation to interactions with a tetranucleotide is presented.