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

Ultrafast fluorescence decay profiles reveal differential unstacking of 2-aminopurine from neighboring bases in single-stranded DNA-binding protein subsites

Gene 5 protein (g5p) is a dimeric single-stranded DNA-binding protein encoded by Ff strains of Escherichia coli bacteriophages. The 2-fold rotationally symmetric binding sites of a g5p dimer each bind to four nucleotides, and the dimers bind with high cooperativity to saturate antiparallel single-stranded DNA (ssDNA) strands. Ultrafast time-resolved fluorescence spectroscopies were used to investigate the conformational heterogeneity and dynamics of fluorescent 2-aminopurine (2AP) labels sequestered by bound g5p. The 2AP labels were positioned within the noncomplementary antiparallel tail sequences of d(AC)(8) or d(AC)(9) of hairpin constructs so that each fluorescent label could probe a different subsite location within the DNA-binding site of g5p. Circular dichroism and isothermal calorimetric titrations yielded binding stoichiometries of approximately six dimers per oligomer hairpin when tails were of these lengths. Mobility shift assays demonstrated the formation of a single type of g5p-saturated complex. Femtosecond time-resolved fluorescence spectroscopy showed that the 2AP in the free (non-protein-bound) DNAs had similar heterogeneous distributions of conformations. However, there were significant changes, dominated by a large increase in the population of unstacked bases from ~22 to 59-68%, depending on their subsite locations, when the oligomers were saturated with g5p. Anisotropy data indicated that 2AP in the bound state was less flexible than in the free oligomer. A control oligomer was labeled with 2AP in the loop of the hairpin and showed no significant change in its base stacking upon g5p binding. A proposed model summarizes the data.

The solution structure and DNA-binding properties of the cold-shock domain of the human Y-box protein YB-1

The human Y-box protein 1 (YB-1) is a member of the Y-box protein family, a class of proteins involved in transcriptional and translational regulation of a wide range of genes. Here, we report the solution structure of the cold-shock domain (CSD) of YB-1, which is thought to be responsible for nucleic acid binding. It is the first structure solved of a eukaryotic member of the cold-shock protein family and consists of a closed five-stranded anti-parallel beta-barrel capped by a long flexible loop. The structure of CSD is similar to the OB-fold and a comparison with bacterial cold-shock proteins shows that its structural properties are conserved from bacteria to man. Our data suggest the presence of a DNA-binding site consisting of a patch of positively charged and aromatic residues on the surface of the beta-barrel. Further, it is shown that CSD, which has a preference for binding single-stranded pyrimidine-rich sequences, binds weakly and hardly specifically to DNA. Binding affinities reported for intact YB-1 indicate that domains other than the CSD play a role in DNA binding of YB-1.

Preferential binding of fd gene 5 protein to tetraplex nucleic acid structures

The gene 5 protein of filamentous bacteriophage fd is a single-stranded DNA-binding protein that binds non-specifically to all single-stranded nucleic acid sequences, but in addition is capable of specific binding to the sequence d(GT(5)G(4)CT(4)C) and the RNA equivalent r(GU(5)G(4)CU(4)C), the latter interaction being important for translational repression. We show that this sequence preference arises from the formation of a tetraplex structure held together by a central block of G-quartets, the structure of which persists in the complex with gene 5 protein. Binding of gene 5 protein to the tetraplex leads to formation of a approximately 170 kDa nucleoprotein complex consisting of four oligonucleotide strands and eight gene 5 protein dimers, with a radius of gyration of 45 A and an overall maximum dimension of 120-130 A. A model of the complex is presented that is consistent with the data obtained. It is proposed that the G-quartet may act as a nucleation site for binding gene 5 protein to adjacent single-stranded regions, suggesting a novel mechanism for translational repression.

Gene V protein dimerization and cooperativity of binding of poly(dA)

Gene V protein of bacteriophage f1 is a dimeric protein that binds cooperatively to single-stranded nucleic acids. In order to determine whether a monomer-dimer equilibrium has an appreciable effect upon the thermodynamics of gene V protein binding to nucleic acids, the dissociation constant for the protein dimer was investigated using size-exclusion chromatography. At concentrations ranging from 5 x 10(-10) to 1.2 x 10(-5) M, the Stokes radius of the protein was that expected of the dimer of the gene V protein. The Stokes radius of the protein was also independent of salt concentration from 0.2 to 1.0 M NaCl in a buffer containing 10 mM Tris-HCl, pH 7.4, and 1 mM EDTA. The binding of the dimeric gene V protein to poly(dA) was studied using a simplified lattice model for protein-protein interactions adapted for use with a dimeric protein that binds simultaneously to two strands of nucleic acid. Interpretation of the salt dependence, C = [d log(Kint omega)]/[d log(NaCl)], of binding of such a dimeric protein to nucleic acid using the theory of Record et al. (Record, M. T., et al. (1976) J. Mol. Biol. 107, 145-158) indicates that C is a function of the numbers of cations and anions released from protein and nucleic acid upon binding of the dimer, not of the monomer. Cooperativity of gene V protein binding to poly(dA) was studied with titration experiments that are sensitive to the degree of cooperativity of binding. The cooperativity factor omega, defined as the ratio of the binding constant for a site adjacent to a previously bound dimer to that for an isolated site, was found to be relatively insensitive to salt, with a value in the range of 2000-7000 for binding to poly(dA) at 3 degrees C and at 23 degrees C. This high cooperativity factor supports the suggestion that protein-protein contacts play a major role in the formation of the superhelical gene V protein-single-stranded nucleic acid complex.

Single-stranded DNA binding protein encoded by the filamentous bacteriophage M13: structural and functional characteristics

The single-stranded DNA binding protein, or gene V protein (gVp), encoded by gene V of the filamentous bacteriophage M13 is a multifunctional protein that not only regulates viral DNA replication but also gene expression at the level of mRNA translation. It furthermore is implicated as a scaffolding and/or chaperone protein during the phage assembly process at the hostcell membrane. The protein is 87 amino acids long and its biological functional entity is a homodimer. In this manuscript a short description of the life cycle of filamentous phages is presented and our current knowledge of the major functional and structural properties and characteristics of gene V protein are reviewed. In addition models of the superhelical complexes gVp forms with ssDNA are described and their (possible) biological meaning in the infection process are discussed. Finally it is described that the 'DNA binding loop' of gVp is a recurring motif in many ssDNA binding proteins and that the fold of gVp is shared by a large family of evolutionarily conserved gene regulatory proteins.

Human replication protein A binds single-stranded DNA in two distinct complexes

Human replication protein A, a single-stranded DNA (ssDNA)-binding protein, is a required factor in eukaryotic DNA replication and DNA repair systems and has been suggested to function during DNA recombination. The protein is also a target of interaction for a variety of proteins that control replication, transcription, and cell growth. To understand the role of hRPA in these processes, we examined the binding of hRPA to defined ssDNA molecules. Employing gel shift assays that "titrated" the length of ssDNA, hRPA was found to form distinct multimeric complexes that could be detected by glutaraldehyde cross-linking. Within these complexes, monomers of hRPA utilized a minimum binding site size on ssDNA of 8 to 10 nucleotides (the hRPA8-10nt complex) and appeared to bind ssDNA cooperatively. Intriguingly, alteration of gel shift conditions revealed the formation of a second, distinctly different complex that bound ssDNA in roughly 30-nucleotide steps (the hRPA30nt complex), a complex similar to that described by Kim et al. (C. Kim, R. O. Snyder, and M. S. Wold, Mol. Cell. Biol. 12:3050-3059, 1992). Both the hRPA8-10nt and hRPA30nt complexes can coexist in solution. We speculate that the role of hRPA in DNA metabolism may be modulated through the ability of hRPA to bind ssDNA in these two modes.

Human replication protein A binds single-stranded DNA in two distinct complexes

Human replication protein A, a single-stranded DNA (ssDNA)-binding protein, is a required factor in eukaryotic DNA replication and DNA repair systems and has been suggested to function during DNA recombination. The protein is also a target of interaction for a variety of proteins that control replication, transcription, and cell growth. To understand the role of hRPA in these processes, we examined the binding of hRPA to defined ssDNA molecules. Employing gel shift assays that "titrated" the length of ssDNA, hRPA was found to form distinct multimeric complexes that could be detected by glutaraldehyde cross-linking. Within these complexes, monomers of hRPA utilized a minimum binding site size on ssDNA of 8 to 10 nucleotides (the hRPA8-10nt complex) and appeared to bind ssDNA cooperatively. Intriguingly, alteration of gel shift conditions revealed the formation of a second, distinctly different complex that bound ssDNA in roughly 30-nucleotide steps (the hRPA30nt complex), a complex similar to that described by Kim et al. (C. Kim, R. O. Snyder, and M. S. Wold, Mol. Cell. Biol. 12:3050-3059, 1992). Both the hRPA8-10nt and hRPA30nt complexes can coexist in solution. We speculate that the role of hRPA in DNA metabolism may be modulated through the ability of hRPA to bind ssDNA in these two modes.

Structure of the gene V protein of bacteriophage f1 determined by multiwavelength x-ray diffraction on the selenomethionyl protein

The crystal structure of the dimeric gene V protein of bacteriophage f1 was determined using multiwavelength anomalous diffraction on the selenomethionine-containing wild-type and isoleucine-47-->methionine mutant proteins with x-ray diffraction data phased to 2.5 A resolution. The structure of the wild-type protein has been refined to an R factor of 19.2% using native data to 1.8 A resolution. The structure of the gene V protein was used to obtain a model for the protein portion of the gene V protein-single-stranded DNA complex.

Exploring the DNA binding domain of gene V protein encoded by bacteriophage M13 with the aid of spin-labeled oligonucleotides in combination with 1H-NMR

The DNA binding domain of the single-stranded DNA binding protein gene V protein encoded by the bacteriophage M13 was studied by means of 1H nuclear magnetic resonance, through use of a spin-labeled deoxytrinucleotide. The paramagnetic relaxation effects observed in the 1H-NMR spectrum of M13 GVP upon binding of the spin-labeled ligand were made manifest by means of 2D difference spectroscopy. In this way, a vast data reduction was accomplished which enabled us to check and extend the analysis of the 2D spectra carried out previously as well as to probe the DNA binding domain and its surroundings. The DNA binding domain is principally situated on two beta-loops. The major loop of the two is the so-called DNA binding loop (residues 16-28) of the protein where the residues which constitute one side of the beta-ladder (in particular, residues Ser20, Tyr26, and Leu28) are closest to the DNA spin-label. The other loop is part of the so-called dyad domain of the protein (residues 68-78), and mainly its residues at the tip are affected by the spin-label (in particular, Phe73). In addition, a part of the so-called complex domain of the protein (residues 44-51) which runs contiguous to the DNA binding loop is in close vicinity to the DNA. The NMR data imply that the DNA binding domain is divided over two monomeric units of the GVP dimer in which the DNA binding loop and the tip of the dyad loop are part of opposite monomers. The view of the GVP-ssDNA binding interaction which emerges from our data differs from previous molecular modeling proposals which were based on the GVP crystal structure (Brayer & McPherson, 1984; Hutchinson et al., 1990). These models implicate the involvement of one or two tyrosines (Tyr34, Tyr41) of the complex loop of the protein to participate in complex formation with ssDNA. In the NMR studies with the spin-labeled oligonucleotides, no indication of such interactions has been found. Other differences between the models and our NMR data are related to the structural differences found when solution and crystal structures are compared.

Exploration of the single-stranded DNA-binding domains of the gene V proteins encoded by the filamentous bacteriophages IKe and M13 by means of spin-labeled oligonucleotide and lanthanide-chelate complexes

Scrutiny of NOE data available for the protein encoded by gene V of the filamentous phage IKe (IKe GVP), resulted in the elucidation of a beta-sheet structure which is partly five stranded. The DNA-binding domain of IKe GVP was investigated using a spin-labeled deoxytrinucleotide. The paramagnetic-relaxation effects observed in the 1H-NMR spectrum of IKe GVP, upon binding of this DNA fragment, could be visualized using two-dimensional difference spectroscopy. In this way, the residues present in the DNA-binding domain of IKe GVP can be located in the structure of the protein. They exhibit a high degree of identity with residues in the gene V protein encoded by the distantly related phage M13 (M13 GVP), for which similar spectral perturbations are induced by such a spin-labeled oligonucleotide. Binding studies with negatively charged lanthanide-1,4,7,10-tetraazacyclodecanetrayl-1,4,7-10- tetrakis(methylene)tetrakisphosphonic acid (DOTP) complexes, showed that these complexes bind to IKe and M13 GVP at two spatially remote sites whose affinities have different pH dependencies. Above pH 7, there is one high-affinity binding site for Gd(DOTP)5-/M13 GVP monomer, which coincides with the single-stranded DNA-binding domain as mapped with the aid of spin-labeled oligonucleotide fragments. The results show that single-stranded DNA binds to conserved (phosphate binding) electropositive clusters at the surface of M13 and IKe GVP. These positive patches are interspersed with conserved or conservatively replaced hydrophobic residues. At pH 5, a second Gd(DOTP)(5-)-binding site becomes apparent. The corresponding pattern of spectral perturbations indicates the accommodation of patches of conserved, or conservatively replaced, hydrophobic residues in the cores of the M13 and IKe dimers.

Fluorescence studies of the binding of bacteriophage M13 gene V mutant proteins to polynucleotides

This investigation describes how the binding characteristics of the single-stranded DNA-binding protein encoded by gene V of bacteriophage M13, are affected by single-site amino acid substitutions. The series of mutant proteins tested includes mutations in the purported monomer-monomer interaction region as well as mutations in the DNA-binding domain at positions which are thought to be functionally involved in monomer-monomer interaction or single-stranded DNA binding. The characteristics of the binding of the mutant proteins to the homopolynucleotides poly(dA), poly(dU) and poly(dT), were studied by means of fluorescence-titration experiments. The binding stoichiometry and fluorescence quenching of the mutant proteins are equal to, or lower than, the wild-type gene V protein values. In addition, all proteins measured bind a more-or-less co-operative manner to single-stranded DNA. The binding affinities for poly(dA) decrease in the following order: Y61H greater than wild-type greater than F68L and R16H greater than Y41F and Y41H greater than F73L greater than R21C greater than Y34H greater than G18D/Y56H. Possible explanations for the observed differences are discussed. The conservation of binding affinity, also for mutations in the single-stranded DNA-binding domain, suggests that the binding to homopolynucleotides is largely non-specific.

Characterization of wild-type and mutant M13 gene V proteins by means of 1H-NMR

Recording of good quality NMR spectra of the single-stranded DNA binding protein gene V of the bacteriophage M13 is hindered by a specific protein aggregation effect. Conditions are described for which NMR spectra of the protein can best be recorded. The aromatic part of the spectrum has been reinvestigated by means of two-dimensional total correlation spectroscopy. Sequence-specific assignments were obtained for all of the aromatic amino acid residues with the help of a series of single-site mutant proteins. The solution properties of the mutants of the aromatic amino acid residues have been fully investigated. It has been shown that, for these proteins, either none or only local changes occur compared to the wild-type molecule. Spin-labeled oligonucleotide-binding studies of wild-type and mutant gene V proteins indicate that tyrosine 26 and phenylalanine 73 are the only aromatic residues involved in binding to short stretches of single-stranded DNA. The degree of aggregation of wild-type gene V protein is dependent on both the total protein and salt concentration. The data obtained suggest the occurrence of specific protein-protein interactions between dimeric gene V protein molecules in which the tyrosine residue at position 41 is involved. This hypothesis is further strengthened by the observation that the solubility of tyrosine 41 mutants of gene V protein is significantly higher than that of the wild-type protein. The discovery of the so-called 'solubility' mutants of M13 gene V protein has finally made it possible to study the solution structure of gene V protein and its interaction with single-stranded DNA by means of two-dimensional NMR.

Isolation and in vitro characterization of temperature-sensitive mutants of the bacteriophage f1 gene V protein

In vivo selections were used to isolate 43 temperature-sensitive gene V mutants of the bacteriophage f1 from a collection of mutants constructed by saturation mutagenesis of the gene. The sites of temperature-sensitive substitutions are found in both the beta-sheets and the turns of the protein, and some sites are exposed to the solvent while others are not. Thirteen of the variant proteins were purified and characterized to evaluate their free energy changes upon unfolding and their affinities for single-stranded DNA, and eight were tested for their tendencies to aggregate at 42 degrees C. Each of the three temperature-sensitive mutants at buried sites and six of ten at surface sites had free energy changes of unfolding substantially lower (less stabilizing) than the wild-type at 25 degrees C. A seventh mutant at a surface site had a substantially altered unfolding transition and its free energy of unfolding was not estimated. The affinities of the mutant proteins for single-stranded DNA varied considerably, but two mutants at a surface site, Lys69, had much weaker binding to single-stranded DNA than any of the other mutants, while two mutants at another surface site, Glu30, had the highest DNA-binding affinities. The wild-type gene V protein is stable at 42 degrees C, but six of the eight mutants tested aggregated within a few minutes and the remaining two aggregated within 30 minutes at this temperature. Overall, each of the temperature-sensitive proteins tested had a tendency to aggregate at 42 degrees C, and most also had either a low free energy of unfolding (at 25 degrees C), or weak DNA binding. We suggest that any of these properties can lead to a temperature-sensitive gene V phenotype.

Circular dichroism and fluorescence analysis of the interaction of Pf1 gene 5 protein with poly(dT)

Circular dichroism (c.d.) and fluorescence spectroscopy have been used to investigate the interaction of the gene 5 protein of the filamentous bacteriophage Pf1 with single-stranded DNA. The c.d. spectrum of the Pf1 gene 5 protein is consistent with the absence of any significant alpha-helical content. The negative c.d. peak in the region of 210 nm, which arises from the protein, is diminished in the complex with poly(dT). Likewise, the c.d. peak at 265 nm arising from the poly(dT) decreases when the Pf1 gene 5 protein is bound, c.d. titrations of poly(dT) with Pf1 gene 5 protein indicate strong binding with a stoichiometry (n) of four nucleotides per protein subunit. In contrast, when the titrations were done using fluorescence anisotropy or fluorescence spectral shifts to follow binding, apparent stoichiometries between n = 2 and n = 4 were observed, often in the same experiment, depending on precise conditions. The results are interpreted in terms of two distinct modes of binding, in which either one or two subunits of the protein dimer are bound to the polynucleotide lattice, but still retaining the same local interaction with the DNA, with each binding site covering four nucleotides. The apparent stoichiometry of 2 results from the interaction of only one subunit of the dimer with the nucleic acid lattice, when protein is in excess. The second, unfilled, subunit of the dimer is nevertheless incorporated into the complex, resulting in the maximum possible fluorescence change when only half the sites are filled, since the fluorescence properties of the complex arise from protein-protein contacts associated with co-operative binding to the lattice. Further experiments in which the order of addition of components is changed, and the concentration of MgCl2 is varied, show that both of these factors are important in determining the dominant binding mode. In the absence of salt, dissociation and redistribution of the polynucleotide can occur following the addition of excess protein. This transition is suppressed in the presence of greater than 3 mM-MgCl2.

Complex between single-stranded DNA and gene 5 protein of bacteriophage M13 studied with linear dichroism and ultraviolet absorption

We have studied complexes between the gene 5 protein (gp5) of bacteriophage M13 and various polynucleotides, including single-stranded DNA, using ultraviolet absorption and linear dichroism. Upon complex formation the absorption spectra of both the protein and the polynucleotides change. The protein absorption changes indicate that for at least two of the five tyrosine residues per protein monomer the environment becomes less polar upon binding to the polynucleotides but also to the oligonucleotide p(dT)8. All gp5-polynucleotide complexes give rise to intense linear dichroism spectra. These spectra are dominated by negative contributions from the bases, but also a small positive dichroism of the protein can be discerned. The spectra can be explained by polynucleotide structures, which are the same in all complexes. The base orientations are characterized by a substantial inclination and propellor twist. The number of possible combinations of inclination and propeller twist values, which are in agreement with the linear dichroism results, is rather limited. The base orientations with respect to the complex axis are essentially different from those in the complex with the single-stranded DNA-binding protein gp32 of bacteriophage T4.

Gene 5 protein-DNA complex: modeling binding interactions

A helical (not toroidal) complex consisting of eight gene 5 protein dimers per turn is proposed for the extension of DNA from dimer to dimer using known bond length constraints, postulated protein-nucleic acid interactions (determined from NMR and chemical modification studies), other physical properties of the complex, and data from electron micrographs. The binding channel has been dictated by these known parameters and the relative ease of geometrically fitting these constituents. This channel is different from that previously reported by other modelers. The channel lies underneath the long arm "claw-like" extension of the monomer, so that it rests inside the outer surface of the protein complex. An explanation is proposed for the two binding modes, n = 4 (the predominate mode) and n = 3, based on the weak binding interaction of Tyrosine 34. Also, the site of the less mobile nucleic acid base as reported from ESR studies (S.-C. Kao, E.V. Bobst, G.T. Pauly and A.M. Bobst, J. Biom. Struc. Dyn. 3,261 (1985)) is postulated as involving the fourth nucleotide, and this particular base is stacked between Tyrosine 34 and Phenylalanine 73'.

Interaction of Ada protein with DNA examined by fluorescence anisotropy of the protein

We made use of enhancement of fluorescence anisotropy of protein upon DNA binding to analyze interactions between Ada protein and DNA. Ada protein is a DNA repair enzyme that also acts as a transcription regulator. The isotropic fluorescence was not significantly affected upon interaction with DNA and could not be used as a signal for detection of the binding. The anisotropy did became larger because the binding to DNA reduces diffusion of the protein. The change was reproducible and independent of protein concentration and also independent of the degree of saturation of DNA with the protein when DNA was large; these values can readily be converted to the proportion of the complexed protein. The binding parameters were then determined by direct comparison between experimental and theoretical variations of anisotropy, with increasing concentrations of DNA. The theoretical variations were computed by considering the overlap of potential binding sites on the DNA lattice [McGhee & von Hippel (1974) J. Mol. Biol. 86, 469-489]. Binding does not seem to occur in a cooperative manner. The number of base pairs covered by a protein monomer was 7 +/- 1; this number is independent of the salt concentration. The equilibrium association constant decreased from 4 X 10(7) to 3 X 10(5) M-1 for an increase of NaCl concentration from 0.1 to 0.2 M, thereby indicating the possible involvement of ionic interactions between phosphate groups of DNA and the protein.

In vitro binding of the bacteriophage f1 gene V protein to the gene II RNA-operator and its DNA analog

We have investigated the binding of the f1 single-stranded DNA-binding protein (gene V protein) to DNA oligonucleotides and RNA synthesized in vitro. The first 16 nucleotides of the f1 gene II mRNA leader sequence were previously identified as the gene II RNA-operator; the target to which the gene V protein binds to repress gene II translation. Using a gel retardation assay, we find that the preferential binding of gene V protein to an RNA carrying the gene II RNA-operator sequence is affected by mutations which abolish gene II translational repression in vivo. In vitro, gene V protein also binds preferentially to a DNA oligonucleotide whose sequence is the DNA analog of the wild-type gene II RNA-operator. Therefore, the gene V protein recognizes the gene II mRNA operator sequence when present in either an RNA or DNA context.

Translational repression in bacteriophage f1: characterization of the gene V protein target on the gene II mRNA

Previous studies have shown that the single-stranded DNA binding protein of bacteriophage f1 (gene V protein) represses the translation of the mRNA of the phage-encoded replication protein (gene II protein). We have characterized phage mutations in the repressor and in its target. Using a gene II-lacZ translational fusion, we have defined a 16-nucleotide-long region in the gene II mRNA sequence that is required in vivo for repression by the gene V protein. We have shown that in vitro the binding affinity of the gene V protein is at least 10-fold higher to an RNA carrying this sequence than to an RNA lacking it. We propose that this sequence constitutes the gene II mRNA operator.

DNA-binding properties of gene-5 protein encoded by bacteriophage M13. 2. Further characterization of the different binding modes for poly- and oligodeoxynucleic acids

The binding of gene-5 protein, encoded by bacteriophage M13, to oligodeoxynucleic acids was studied by means of fluorescence binding experiments, fluorescence depolarization measurements and irreversible dissociation kinetics of the protein.nucleotide complexes with salt. The binding properties thus obtained are compared with those of the binding to polynucleotides, especially at very low salt concentration. It appears that the binding to oligonucleotides is always characterized by a stoichiometry (n) of 2-3 nucleotides/protein, and the absence of cooperativity. In contrast the protein can bind to polynucleotides in two different modes, one with a stoichiometry of n = 3 in the absence of salt and another with n = 4 at moderate salt concentrations. Both modes have a high intramode cooperativity (omega about 500) but are non-interacting and mutually exclusive. For deoxynucleic acids with a chain length of 25-30 residues a transition from oligonucleotide to polynucleotide binding is observed at increasing nucleotide/protein ratio in the solution. The n = 3 polynucleotide binding is very sensitive to the ionic strength and is only detectable at very low salt concentrations. The ionic strength dependency per nucleotide of the n = 4 binding is much less and is comparable with the salt dependency of the oligonucleotide binding. Furthermore it appears that the influence of the salt concentration on the oligonucleotide binding constant is to about the same degree determined by the effect of salt on the association and dissociation rate constants. Model calculations indicate that the fluorescence depolarization titration curves can only be explained by a model for oligonucleotide binding in which a protein dimer binds with its two dimer halves to the same strand. In addition it is only possible to explain the observed effect of the chain length of the oligonucleotide on both the apparent binding constant and the dissociation rate by assuming the existence of interactions between protein dimers bound to different strands. This results in the formation of a complex consisting of two nucleotide strands with protein in between and stabilized by the dimer-dimer interactions.