The Conformation of the Complex of the Helix Destabilizing Protein GP32 of Bacteriophage T4 and Single Stranded DNA

Abstract

The conformation of single stranded polynucleotides is changed specifically upon binding of the helix destabilizing protein of bacteriophage T4 (GP32). On the basis of circular dichroism (CD) and absorption experiments it is shown that denaturing conditions and the binding of oligopeptides can not induce the altered conformation. On the contrary, according to the current CD and absorption theory, the optical properties of the complex can be explained by a specific, regular conformation, characterized by an appreciable tilt of the bases (?—10°) and either a small rotation per base or a small helix diameter. This conformation agrees nicely with the increase of the base-base distance in the complex as determined in solution by electric field induced birefringence measurements. Our calculations show that also the model proposed by Alma (Ph.D. Thesis Catholic University Nijmegen, The Netherlands (1982)) for the complex of the helix destabilizing protein of bacteriophage fd, in which the helix diameter is large and the bases are almost parallel to the helix axis, would agree with the CD- and absorption spectra of the GP32-complex. For the latter protein this model would have to be modified with regard to the axial increment of the bases which is much larger in the GP32-complexes.     

A specific model for the conformation of single-stranded polynucleotides in complex with the helix-destabilizing protein GP32 of bacteriophage T4

The CD and absorption (OD) spectra of single-stranded nucleic acids in complex with the helix-destabilizing protein of either bacteriophage T4 (GP32) or bacteriophage fd (GP5) show similar and unusual features for all polynucleotides investigated. The change in the CD spectra between 310 and 240 nm is in all cases characterized by a considerable decrease in the positive band, while the negative band (if present) remains relatively intense. These changes are different from those due to temperature or solvent denaturation and, moreover, cannot be induced by the binding of simple oligopeptides. Absorption measurements show that all polynucleotides remain hypochromic in the complex. Both CD and OD spectra point to a specific and probably similar conformation in complex for all polynucleotides with substantial interactions between the bases. The spectral properties are almost temperature independent (0–40°C). Therefore, we conclude that the conformation must be regular and rigid. To investigate the relation between these optical properties and the specific polynucleotide structure, CD and OD spectra were calculated for an adenine hexamer over a wide range of the conformational parameters. It appears that the calculated CD intensity is not very sensitive to an increase in the axial increment and that many different conformations can give rise to more or less similar CD spectra. However, simulation of the very nonconservative experimental CD spectrum of the poly(rA)-GP32 complex requires that the conformation satisfies two criteria: (1) a considerable tilt of the bases (? – 10°) in combination with (2) a small rotation per base (?20°) and/or a position of the bases close to the helix axis (dx ? 0 Å). Such conformations can also explain the observed hyperchromism upon binding of GP32 to poly(rA)/(dA). Very similar structural characteristics also account for the optical properties of the complexes with GP5. These are discussed as an alternative to the structure suggested by Alma-Zeestraten for poly(dA) in the complex [N. C. M. Alma-Zeestraten (1982) Doctoral thesis Catholic University, Nijmegen, The Netherlands]. The secondary structure proposed in this work can be reconciled with the overall dimensions of the complex, assuming that the polynucleotide helix is further organized in a superhelix.     

Hydrodynamic studies of a DNA-protein complex. Elongation of single stranded nucleic acids upon complexation with the gene 32 protein of phage T4 deduced from electric field-induced birefringence experiments

Short DNA and RNA fragments complexed with the helix destabilizing protein of bacteriophage T4, GP32, have been studied in solution by electric birefringence and circular dichroism. The birefringence of the complexes is positive and the magnitude indicates that the DNA and RNA fragments become linear and rigid upon protein binding. The field free decay is biphasic. On the basis of a rigid rod approximation the slow relaxation time leads to a base-base distance along the helix axis in the complex from 4.3 to 5.6 A, an elongation of at least 50% compared to single-stranded DNA.     

A model for the complex between the helix destabilizing protein GP32 of bacteriophage T4 and single-stranded DNA

A model for the structure of the complex between the helix-destabilizing protein of bacteriophage T4, GP32, and single-stranded DNA is proposed. In this model the bases are arranged in a helix, that is characterized by a relatively large distance between successive bases, a substantial base tilt, in combination with a small rotation per base. This helix is further organized into a tertiary structure, possibly a superhelix, of which the corresponding protein shell corresponds to the relatively rigid and rod-like structure that is observed in hydrodynamic experiments. It is proposed that similar structural features apply to other single-stranded DNA binding proteins in complex with polynucleotides.     

A Model for the Complex Between the Helix Destabilizing Protein GP32 of Bacteriophage T4 and Single-Stranded DNA

Abstract

A model for the structure of the complex between the helix-destabilizing protein of bacteriophage T4, GP32, and single-stranded DNA is proposed. In this model the bases are arranged in a helix, that is characterized by a relatively large distance between successive bases, a substantial base tilt, in combination with a small rotation per base. This helix is further organized into a tertiary structure, possibly a superhelix, of which the corresponding protein shell corresponds to the relatively rigid and rod-like structure that is observed in hydrodynamic experiments. It is proposed that similar structural features apply to other single-stranded DNA binding proteins in complex with polynucleotides.     

Linear dichroism of the complex between the gene 32 protein of bacteriophage T4 and poly(1,N6-ethenoadenylic acid)

We performed linear dichroism measurements in compressed polyacrylamide gels on the complex between the helix-destabilizing protein of bacteriophage T4, GP32 and poly(1,N6-ethenoadenylic acid), which is used as a model system for single-stranded DNA. A strong hyperchromism for poly(1,N6-ethenoadenylic acid) in the complex indicates a strongly altered conformation. The positive linear dichroism in the wavelength region where the bases absorb must be explained by a strong tilting of the bases in the complex. This finding is in accordance with results from earlier studies, using electric birefringence and circular dichroism measurements. Our measurements show that the angle between the bases and the local helix axis is 42(+/- 6)degrees. In addition, a pronounced contribution from the tryptophan residues of GP32 can be recognized, indicating that several of these residues have a specific orientation in the complex. The sign of the dichroism due to the tryptophan residues is the same as that due to the DNA bases. However, it is not sufficient to assume that all the observed dichroism is due to one or more intercalated tryptophan residues and there must be one or more additional tryptophan residues that make an angle of less than 40 degrees with the local helix axis. Some possible structures of the DNA-protein complex are discussed.     

Resonance Raman spectroscopy of complexes of the helix destabilizing proteins GP32 and GP5 with poly(rA) and poly(dA)

The bacteriophage T4 helix destabilizing protein (hdp) gp32 and its complexes with poly(rA) and poly(dA) were studied with ultra-violet resonant Raman spectroscopy. The UV-resonant Raman (UV-RR) spectrum of the complex of gp5, the coat protein of bacteriophage M13, with poly(dA) was also measured and is compared with the spectrum of the gp 32/poly(dA) complex. The excitation wavelength was 245.1 nm. This is on the far UV-side of the first absorption bands of adenine and near a "window" in the protein absorption spectrum. The overlap of fluorescence due to chromophores present in the protein and resonance Raman scattering was prevented by this choice of wavelength. The spectra of the protein/polynucleotide complexes are compared with the native nucleotide spectra measured at varying temperatures. The hyperchromicity which is expected when a nucleotide changes from a stacked to an unstacked conformation was not observed for poly(rA), neither upon temperature increase nor on protein binding. In both cases poly(dA) revealed a clear hyperchromicity. This different behavior of poly(rA) and poly(dA) is probably a consequence of their different conformations. The contributions of the proteins to the spectra is weak except for two bands, at 1550 and 1610 cm-1 due to tryptophan (in case of gp32) and one band near 1610 cm-1 due to tyrosine and phenylalanine.     

Binding Stoichiometry of the Gene 32 Protein of Phage T4 in the Complex with Single Stranded DNA Deduced from Boundary Sedimentation

Abstract

Short 145 base DNA fragments in complex with the helix destabilizing protein of bacteriophage T4, GP32, have been studied with boundary sedimentation. The sedimentation coefficient was determined as a function of concentration, protein-nucleic acid ratio, temperature and salt concentration. It can be concluded that the measured values reflect the properties of the saturated DNA-GP32 complex. A combination of the earlier obtained translational diffusion coefficient of the complex with the sedimentation coefficient yields its anhydrous molecular weight (M_w = 5.4 · 10^s D), which corresponds to a size of the binding site of 10 nucleotides per protein. This procedure is not sensitive to the presence of non-binding protein molecules and to the assumed protein concentration, and therefore, it seems more reliable than a determination from titration experiments.

Similar sedimentation measurements were performed with tRNA-complexes containing 76 nucleotides. The translational diffusion coefficient can be calculated from the measured rotational diffusion coefficient and assuming the same hydrodynamic diameter for this complex as obtained for the 145 b DNA complex. The molecular weight derived from the data then also leads to a binding site size of about 10 nucleotides. This suggests that also the short tRNA-complex forms an open, strongly solvated structure, as was proposed for the 145 b DNA-GP32 complex.     

Structure calculations for single-stranded DNA complexed with the single-stranded DNA binding protein GP32 of bacteriophage T4: a remarkable DNA structure

In this study it is established by calculation which regular conformations single-stranded DNA and RNA can adopt in the complex with the single-stranded DNA binding protein GP32 of bacteriophage T4. In order to do so, information from previous experiments about base orientations and the length and diameter of the complexes is used together with knowledge about bond lengths and valence angles between chemical bonds. It turns out that there is only a limited set of similar conformations which are in agreement with experimental data. The arrangement of neighboring bases is such that there is ample space for aromatic residues of the protein to partly intercalate between the bases, which is in agreement with a previously proposed model for the binding domain of the protein [Prigodich, R. V., Shamoo, Y., Williams, K. R., Chase, J. W., Konigsberg, W. H., & Coleman, J. E. (1986) Biochemistry 25, 3666-3671]. Both C2'endo and C3'endo sugar conformations lead to calculated DNA conformations that are consistent with experimental data. The orientation of the O2' atoms of the sugars in RNA can explain why the binding affinity of GP32 for polyribonucleotides is lower than for polydeoxyribonucleotides.     

DNA binding site of the helix destabilizing protein gp32 from bacteriophage T4.

A helix destabilizing protein, the product of gene 32 (gp32) of bacteriophage T4, was subjected to limited proteolysis to produce three types of products with differing affinities for DNA. Previous work has suggested that the 18 amino acids at the N-terminus are required for tight binding to single-stranded DNA (Hosoda &; Moise, 1978). This paper reports the sequence of the N-terminal region and predicts the amino acid residues responsible for DNA binding.     

A refined calculation of the solution dimensions of the complex between gene 32 protein and single stranded DNA based on estimates of the bending persistence length

The rotation diffusion coefficient of a complex of GP32, the single stranded DNA binding protein of the bacteriophage T4, with a single stranded DNA fragment with about 270 bases was determined to obtain further information on the flexibility of this particle. The rotation diffusion of these molecules is used as a sensitive measure of the flexibility of different DNA protein complexes. Using the theory of Hagerman and Zimm (Biopolymers 20, 1481 (1981)) and assuming a bending persistence length of about 35 nanometer it can be shown that the axial increment for GP32 complexes with single stranded DNA is close to 0.5 nm per base. The value for the bending persistence length is in agreement with values found for much larger DNA protein complexes using light scattering experiments. This value for the persistence length also implies that the complex is thin. The radius is estimated to be around 1.7 nm, which shows a moderate degree of hydration. With this set of parameters we can describe all the hydrodynamic experiments on GP32 complexes from 76 to more than 7000 bases obtained using electric birefringence, quasi-elastic light scattering and sedimentation experiments performed in our group over the last few years.     

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.     

Topological comparison of two helix destabilizing proteins: ribonuclease A and the gene 5 DNA binding protein

A topological comparison of the two helix destabilizing proteins, pancreatic ribonuclease A and the gene 5 DNA binding protein of bacteriophage fd has been completed utilizing the available high resolution tertiary structures of each protein. The results indicate these two proteins are structurally if not also evolutionarily related. Regions of closet topological equivalence occur between beta loops directly involved in nucleotide binding or are required for the maintenance of their respective oligonucleotide binding channels. In addition, there is a similar placement of critical amino acid side chains about the binding site. Further evidence for this structural relationship is obtained by comparison of structural data for the mode of complexation of polynucleotides to each protein. The results of topological comparison suggest the essential property shared by helix destabilizing proteins, whether specialized DNA binding proteins such as G5BP or proteins with other primary functional roles, like ribonuclease A, is the presence of an elongated oligonucleotide binding channel. Although ribonuclease A and G5BP are structurally related, it seems likely any protein with this structural feature will exhibit a helix destabilizing capacity. This conclusion is supported by the diversity of molecular characteristics shown by other proteins having this activity.     

Topological Comparison of Two Helix Destabilizing Proteins: Ribonuclease A and the Gene 5 DNA Binding Protein

Abstract

A topological comparison of the two helix destabilizing proteins, pancreatic ribonuclease A and the gene S DNA binding protein of bacteriophage fd has been completed utilizing the available high resolution tertiary structures of each protein. The results indicate these two proteins are structurally if not also evolutionarily related. Regions of closest topological equivalence occur between beta loops directly involved in nucleotide binding or are required for the maintenance of their respective oligonucleotide binding channels. In addition, there is a similar placement of critical amino acid side chains about the binding site. Further evidence for this structural relationship is obtained by comparison of structural data for the mode of complexation of polynucleotides to each protein. The results of topological comparison suggest the essential property shared by helix destabilizing proteins, whether specialized DNA binding proteins such as G5BP or proteins with other primary functional roles, like ribonuclease A, is the presence of an elongated oligonucleotide binding channel. Although ribonuclease A and G5BP are structurally related, it seems likely any protein with this structural feature will exhibit a helix destabilizing capacity. This conclusion is supported by the diversity of molecular characteristics shown by other proteins having this activity.     

The internal dynamics of gene 32 protein-DNA complexes studied by quasi-elastic light scattering

The hydrodynamic properties of large homodisperse single stranded DNAs complexed with the helix destabilizing protein of phage T4, the product of gene 32 (GP32), have been measured. The results suggest a size of the binding site between 8 and 10 nucleotides/GP32 molecule, in reasonable agreement with earlier work on a complex between GP32 and single stranded 145 base DNA. From static light scattering experiments it is concluded that the persistence length of these complexes is about 30 nm, distinctly smaller than the generally accepted value for double stranded DNA. The quasi-elastic light scattering properties of the DNA-GP32 complexes were determined. The variation of the apparent translation diffusion coefficient Dapp with the scattering vector q was analyzed using the discrete ISMF and Rouse-Zimm models [S.C. Lin et al., Biopolymers 17 (1978) 425]. The model parameters that followed from the fit of Dapp versus q2 and from an extensive global analysis of the actually measured autocorrelation functions agreed with the notion that these DNA-protein complexes are indeed rather flexible. The continuous Soda model [K. Soda, Macromolecules 17 (1984) 2365] could successfully explain the variation of Dapp versus q2, assuming a persistence length of 30 nm and a base-base distance in the complex of 0.44 nm.     

Investigation of complexes formed between gene 32 protein from bacteriophage T4 and heavy-atom-modified single-stranded polynucleotides using optical detection of magnetic resonance

Optical detection of triplet-state magnetic resonance (ODMR) is employed to study the complexes formed between gene 32 protein (GP32), a single-stranded DNA-binding protein from bacteriophage T4, and the heavy-atom-derivatized polynucleotides poly(5-HgU) and poly(5-BrU). The triplet-state properties of some of the tryptophan (Trp) residues in the complexes are dramatically different from those in the free protein, in that they are subject to an external heavy-atom effect. Direct evidence for the presence of a heavy-atom effect, and hence a close-range interaction between mercurated or brominated nucleotide bases and Trp residues in the complex, is provided by the observation of the zero-field (D) + (E) ODMR transition of Trp, which is not normally observed in the absence of a heavy-atom perturbation. The amplitude-modulated phosphorescence-microwave double-resonance (AM-PMDR) technique is employed to selectively capture the phosphorescence spectrum originating from the heavy-atom-perturbed Trp residue(s) in the GP32-poly(5-HgU) complex. Arguments based on our experimental results lead to the conclusion that the heavy-atom perturbation arises from aromatic stacking interactions between Trp and mercurated bases. Wavelength-selected ODMR measurements reveal the existence of two environmentally distinct and spectrally different types of Trp in GP32. One of these types is perturbed selectively by the heavy atom and hence undergoes stacking interactions with the heavy-atom-derivatized bases of the polynucleotide while the second type of Trp residue is unaffected.(ABSTRACT TRUNCATED AT 250 WORDS)     

Studies of formation of bivalent copper complexes with native and denatured DNA

The formation of Cu2+ complexes with native and denatured DNA is studied by the methods of differential UV spectroscopy, CD spectroscopy, and viscometry. On ion binding to the bases of native DNA the latter transforms into a new conformation. This transition is accompanied with a sharp increase in UV absorption and a decrease in the intrinsic viscosity though the high degree of helicity persists. Possible sites of Cu2+ ion binding on DNA of various conformations are found along with corresponding constants of complex formation.     

Structural Changes of Human Serum Albumin Induced by Cadmium Acetate

The structural changes of human serum albumin (HSA) induced by the addition of cadmium acetate were systematically investigated using UV–vis absorption, circular dichroism (CD), synchronous, and three‐dimentional (3D) fluorescence methods. The fluorescence spectra suggested the formation of cadmium acetate–HSA complex. UV absorption result indicated that the interaction between cadmium acetate and HSA could lead to the alteration of the protein skeleton. The structural analysis according to CD method showed that the cadmium acetate binding altered HSA conformation with a major reduction of α‐helix, inducing a partial protein unfolding. Synchronous fluorescence spectra suggested that cadmium acetate was situated closer to tryptophan residue compared to tyrosine residues, making tryptophan residue locate in a more hydrophobic environment. 3D fluorescence demonstrated that cadmium acetate could induce the HSA aggregation and cause a slight unfolding of the polypeptide backbone of the protein.     

Conformational studies of the C-terminal domain of bacteriophage Pf1 gene 5 protein

The gene 5 protein (g5p) of the bacteriophage Pf1 is a 144 residue single-stranded (ss) DNA binding protein involved in replication and packaging of the viral DNA. Compared to the gene 5 proteins of other filamentous bacteriophages, such as fd, the Pf1 g5p has an additional C-terminal sequence ( approximately 40 residues) with an unusual amino acid composition, being particularly rich in proline, glutamine and alanine. This C-terminal sequence is susceptible to limited proteolysis, in contrast to the globular N-terminal domain of the protein. The C-terminal sequence has been shown to play a role in the stabilisation of the protein-ssDNA complex. In the present study, the DNA sequence corresponding to the 38 amino acid residue C-terminal peptide has been cloned and expressed. A variety of biophysical techniques suggest that this peptide has a largely irregular conformation in solution, in contrast to the N-terminal globular domain that is principally beta-sheet. However, circular dichroism (CD) spectroscopy indicates that the peptide can be induced to form a structure that resembles a left-handed polyproline-like (P(II)) helix, suggesting that the C-terminal tail of the protein may adopt a more structured conformation in the appropriate physiological environment.