Structure of the fd DNA--gene 5 protein complex in solution. A neutron small-angle scattering study

Conformational Changes in Ff Phage Protein gVp upon Complexation with Its Viral Single-Stranded DNA Revealed Using Magic-Angle Spinning Solid-State NMR

Gene V protein (gVp) of the bacteriophages of the Ff family is a non-specific single-stranded DNA (ssDNA) binding protein. gVp binds to viral DNA during phage replication inside host Escherichia coli cells, thereby blocking further replication and signaling the assembly of new phage particles. gVp is a dimer in solution and in crystal form. A structural model of the complex between gVp and ssDNA was obtained via docking the free gVp to structures of short ssDNA segments and via the detection of residues involved in DNA binding in solution. Using solid-state NMR, we characterized structural features of the gVp in complex with full-length viral ssDNA. We show that gVp binds ssDNA with an average distance of 5.5 Å between the amino acid residues of the protein and the phosphate backbone of the DNA. Torsion angle predictions and chemical shift perturbations indicate that there were considerable structural changes throughout the protein upon complexation with ssDNA, with the most significant variations occurring at the ssDNA binding loop and the C-terminus. Our data suggests that the structure of gVp in complex with ssDNA differs significantly from the structure of gVp in the free form, presumably to allow for cooperative binding of dimers to form the filamentous phage particle.

Structure and assembly of filamentous bacteriophages

Filamentous bacteriophages are interesting paradigms in structural molecular biology, in part because of the unusual mechanism of filamentous phage assembly. During assembly, several thousand copies of an intracellular DNA-binding protein bind to each copy of the replicating phage DNA, and are then displaced by membrane-spanning phage coat proteins as the nascent phage is extruded through the bacterial plasma membrane. This complicated process takes place without killing the host bacterium. The bacteriophage is a semi-flexible worm-like nucleoprotein filament. The virion comprises a tube of several thousand identical major coat protein subunits around a core of single-stranded circular DNA. Each protein subunit is a polymer of about 50 amino-acid residues, largely arranged in an α-helix. The subunits assemble into a helical sheath, with each subunit oriented at a small angle to the virion axis and interdigitated with neighbouring subunits. A few copies of "minor" phage proteins necessary for infection and/or extrusion of the virion are located at each end of the completed virion. Here we review both the structure of the virion and aspects of its function, such as the way the virion enters the host, multiplies, and exits to prey on further hosts. In particular we focus on our understanding of the way the components of the virion come together during assembly at the membrane. We try to follow a basic rule of empirical science, that one should chose the simplest theoretical explanation for experiments, but be prepared to modify or even abandon this explanation as new experiments add more detail.

Difference between active and inactive nucleotide cofactors in the effect on the DNA binding and the helical structure of RecA filament dissociation of RecA--DNA complex by inactive nucleotides

The RecA protein requires ATP or dATP for its coprotease and strand exchange activities. Other natural nucleotides, such as ADP, CTP, GTP, UTP and TTP, have little or no activation effect on RecA for these activities. We have investigated the activation mechanism, and the selectivity for ATP, by studying the effect of various nucleotides on the DNA binding and the helical structure of the RecA filament. The interaction with DNA was investigated via fluorescence measurements with a fluorescent DNA analog and fluorescein-labeled oligonucleotides, assisted by linear dichroism. Filament structure was investigated via small-angle neutron scattering. There is no simple correlation between filament elongation, DNA binding affinity of RecA, and DNA structure in the RecA complex. There may be multiple conformations of RecA. Both coprotease and strand exchange activities require formation of a rigid and well organized complex. The triphosphate nucleotides which do not activate RecA, destabilize the RecA-DNA complex, indicating that the chemical nature of the nucleotide nucleobase is very important for the stability of RecA-DNA complex. Higher stability of the RecA-DNA complex in the presence of adenosine 5'-O-3-thiotriphosphate or guanosine 5'-O-3-thiotriphosphate than ATP or GTP indicates that contact between the protein and the chemical group at the gamma position of the nucleotide also affects the stability of the RecA-DNA complex. This contact appears also important for the rigid organization of DNA because ADP strongly decreases the rigidity of the complex.

Nucleotide cofactor-dependent structural change of Xenopus laevis Rad51 protein filament detected by small-angle neutron scattering measurements in solution

Rad51 protein, a eukaryotic homologue of RecA protein, forms a filamentous complex with DNA and catalyzes homologous recombination. We have analyzed the structure of Xenopus Rad51 protein (XRad51.1) in solution by small-angle neutron scattering (SANS). The measurements showed that XRad51.1 forms a helical filament independently of DNA. The sizes of the cross-sectional and helical pitch of the filament could be determined, respectively, from a Guinier plot and the position of the subsidiary maximum of SANS data. We observed that the helical structure is modified by nucleotide binding as in the case of RecA. Upon ATP binding under high-salt conditions (600 mM NaCl), the helical pitch of XRad51.1 filament was increased from 8 to 10 nm and the cross-sectional diameter decreased from 7 to 6 nm. The pitch sizes of XRad51.1 are similar to, though slightly larger than, those of RecA filament under corresponding conditions. A similar helical pitch size was observed by electron microscopy for budding yeast Rad51 [Ogawa, T., et al. (1993) Science 259, 1896-1899]. In contrast to the RecA filament, the structure of XRad51.1 filament with ADP is not significantly different from that with ATP. Thus, the hydrolysis of ATP to ADP does not modify the helical filament of XRad51.1. Together with our recent observation that ADP does not weaken the XRad51.1/DNA interaction, the effect of ATP hydrolysis on XRad51.1 nucleofilament should be very different from that on RecA.

Single-stranded DNA binding protein from bacteriophage cf: characterization, gene localization and protein-ssDNA complex

The single-stranded DNA binding protein from the filamentous bacteriophage cf has been purified and characterized. The first 12 amino acids, resulting from the N-terminal amino acid sequencing analysis of the protein, agree with an open reading frame (ORF) on the cf genome. The ORF contains 294 bp and codes for a 98 a.a. protein of molecular weight 10.8 kDa, consistent with the result from the denaturing protein gel analysis. The protein appears to be a homodimer as evident from the apparent molecular weight of about 22 kDa obtained from native protein gel analysis. The gene location of the protein has been identified as gene V of the cf single stranded genome, same as that from the M13 phage. The GVP of cf shows a strong sequence homology to the ssDNA binding proteins of Ff, IKe and Pf3 filamentous phages. The DNA binding wing of GVP, conserved among the filamentous phages, has been predicted for cf. To further characterize the protein, the GVP-ssDNA complex of cf has been purified from the infected host (Xanthomonas campestris pv. citri) by density gradient centrifugation. Transmission electron microscopy (TEM) images of the complex showed that it is about 1200 nm in length and 9 nm in diameter and it has a highly regular morphology with a central groove shadow running along the entire structure, but without any apparent helical pattern seen in the M13 complex. The GVP-ssDNA complex of cf seems more rigid than that of M13. Our computer modeling study suggested that this difference between the two complexes may be due to the additional 11 or 12 amino acids at the C-terminal end of the cf-GVP.

Structural parameters of the Pf1 gene 5 protein-DNA complex in solution by neutron scattering

Neutron-scattering experiments have been performed on the intracellular complex formed by the gene 5 protein and single-stranded DNA in cells infected by filamentous bacteriophage Pf1. The contrast matched point of the complex (37% 2H2O) is lower than expected and implies that a substantial fraction of potentially labile hydrogen atoms are unable to exchange with the solvent. The mass/length ratio of the complex (3270 daltons/A) indicates an axial subunit repeat of 5.1 A, a value much larger than the subunit repeat previously determined in fibres. The measured value of the cross-sectional radius of gyration at infinite contrast (Rc = 43.3 A) indicates an outer radius of 60 to 63 A for the complex. The variation in Rc with contrast shows that regions of higher scattering density are located, on average, towards the outside of the complex. The high-angle region of the intensity curve (measured in 2H2O) reveals a clear subsidiary maximum at 0.105 A-1 arising from the 60 A helical pitch of the nucleoprotein complex. The structural parameters of the Pf1 gene 5 protein-DNA complex in solution are compared with those of the fd gene 5 protein-DNA complex.

The solution structure of recA filaments by small angle neutron scattering

The technique of small angle neutron scattering has been applied to study the structure in solution of recA self-polymers and various recA-DNA complexes. These results are compared with those recently obtained by other physical techniques.

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'.

Complexes of RecA protein in solution. A study by small angle neutron scattering

RecA complexes on DNA and self-polymers were analysed by small-angle neutron scattering in solution. By Guinier analysis at small angles and by model analysis of a subsidiary peak at wider angles, we find that the filaments fall into two groups: the DNA complex in the presence of ATP gamma S, an open helix with pitch 95 A, a cross-sectional radius of gyration of 33 A and a mass per length of about six RecA units per turn, which corresponds to the state of active enzyme; and the compact form (bound to single-stranded DNA in the absence of ATP, or binding ATP gamma S in the absence of DNA, or just the protein on its own), a helical structure with pitch 70 A, cross-sectional radius of gyration 40 A and mass per length about five RecA units per turn, which corresponds to the conditions of inactive enzyme. The results are discussed in the perspective of unifying previous conflicting structural results obtained by electron microscopy.

Activation of recA protein: the salt-induced structural transition

Purified recA protein is induced by high salt concentrations to hydrolyse ATP even in the absence of DNA. By small angle neutron scattering we show that this salt activation results from a structural transition of the protein filament in the presence of ATP gamma S from the inactive, compact form (a helical polymer of pitch 70 A and cross-sectional radius of gyration Rc 40 A) to the open form (a helical filament of pitch 95 A and Rc 35 A, which are the same structural parameters as in the ATPase active complex with DNA and ATP), without detectable change in the degree of association. We conclude that activation of recA is due to the same structural change whether induced by the binding of DNA or by salt. Indeed, the other enzymatic activity of recA, the proteolytic cleavage of the lexA repressor, is found to be inducible by the same salt concentrations as those of the structural transition.

Three-dimensional structure of complexes of single-stranded DNA-binding proteins with DNA. IKe and fd gene 5 proteins form left-handed helices with single-stranded DNA

Specimen-tilting in an electron microscope was used to determine the three-dimensional architecture of the helical complexes formed with DNA by the closely related single-stranded DNA binding proteins of fd and IKe filamentous viruses. The fd gene 5 protein is the only member of the DNA-helix-destabilizing class of proteins whose structure has been determined crystallographically, and yet a parameter essential to molecular modeling of the co-operative interaction of this protein with DNA, the helix handedness, has not been available prior to this work. We find that complexes formed by titrating fd viral DNA with either the fd or IKe gene 5 protein have a left-handed helical sense. Complexes isolated from Escherichia coli infected by fd virus are also found to be left-handed helical; hence, the left-handed fd helices are not an artefact of reconstitution in vitro. Because the proteins and nucleic acid of the complexes are composed of asymmetric units which cannot be fitted equivalently to right-handed and left-handed helices, these results rule out a previous computer graphics atomic model for the helical fd complexes: a right-handed helix had been assumed for the model. Our work provides a defined three-dimensional structural framework within which to model the protein-DNA and protein-protein interactions of two structurally related proteins that bind contiguously and co-operatively on single-stranded DNAs.

The location of DNA in complexes of recA protein with double-stranded DNA. A neutron scattering study

Purified recA protein is found as rodlike homopolymers, and it forms filamentous complexes with double-stranded DNA that are stable in the presence of ATP gamma S, a nonhydrolyzable analogue of ATP. The structure of these filaments has been described in some detail by electron microscopy. Here we confirm the mass per length of 6.5 recA/100 A in solution by small-angle neutron scattering and extend the analysis to homopolymers of recA protein, finding a mass per length of about 7 recA/100 A and a radial mass distribution (cross-sectional radius of gyration) significantly different for the two filaments. The models proposed so far for the structure of the complex have placed the DNA in the center of the filament. Here we verify this assumption using small-angle neutron scattering to locate the DNA in the complexes, exploiting the contrast variation method in D2O/H2O mixtures. Model calculations show that the natural contrast difference between DNA and protein is not sufficient to locate the DNA (which accounts for only 4.7% of the mass in the complex). When deuterated DNA is used, the contrast difference is enhanced, and model calculations and experiment then converge, indicating that the DNA is indeed near the axis of the complex.

Two-dimensional 1H nuclear magnetic resonance studies on the gene V-encoded single-stranded DNA-binding protein of the filamentous bacteriophage IKe. II. Characterization of the DNA-binding wing with the aid of spin-labelled oligonucleotides

The DNA-binding domain of the single-stranded DNA-binding protein IKe GVP was studied by means of 1H nuclear magnetic resonance, through use of oligonucleotides of two and three adenyl residues in length, that were spin-labelled at their 3' and/or 5' termini. These spin-labelled ligands were found to cause line broadening of specific protein resonances when bound to the protein, although they were present in small quantities, i.e. of the order of 0.04 molar equivalent and less. The line broadening of protein resonances was made manifest by means of difference one and two-dimensional spectroscopy. Difference one-dimensional experiments revealed line broadening of the same protein resonances upon binding of either 3' or 5' spin-labelled oligonucleotides. Evidence in favour of the existence of a fixed 5' to 3' orientation in the binding of oligonucleotides to the protein surface was therefore not obtained from the spin-labelled oligonucleotide binding studies. Residue-specific assignments of broadened resonances could not, or could only sparsely, be derived from the difference one-dimensional spectra, because of the tremendous overlap in the aliphatic region of the spectrum. In contrast, such assignments were easily obtained from the difference two-dimensional spectra, which were recorded by means of both total correlated spectroscopy and nuclear Overhauser effect spectroscopy. Difference signals were detected for 15 spin systems; ten out of these were assigned to the residues I29, Y27, S20, G18, R16, T28, K22, Q21, V19 and S17 in the amino acid sequence of IKe GVP; the other five spin systems could be assigned to a phenylalanyl residue, an arginyl or lysyl residue, an aspartic acid or asparagyl residue, a glycyl residue and a glutamic acid or glutamyl residue. From the evaluation of the relative difference signals, it was concluded that the direct surroundings of the spin-label group of the labelled oligonucleotide in the bound state is composed of the first five residues in the former group of residues and the five residues in the latter group.(ABSTRACT TRUNCATED AT 400 WORDS)

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.

Filamentous phage assembly: morphogenetically defective mutants that do not kill the host

The filamentous phage virion is assembled without killing the host, by extrusion of the DNA through the envelope and concomitant acquisition of coat proteins from the inner membrane. When assembly is blocked, however, intracellular phage DNA and gene products accumulate and the host is killed. This "cell killing" is largely absent in phage fd-tet, which carries a tetracycline-resistance determinant within the origin of minus-strand synthesis; as a result of the replication defect, phage DNA does not accumulate to high levels intracellularly when virion assembly is blocked. This allows morphogenetically defective mutants except those ablating gene V to be freely propagated in tetracycline-containing medium and studied in the absence of the confounding factor of cell morbidity. Because cultures can be initiated by transfection in the complete absence of input virions, extremely low levels of phage production can be assayed. Using this system, I show that genes III, VI, I, and IV are not required to form the complex between viral DNA and gene-V protein that is the intracellular precursor to mature virions; that genes I and/or IV are absolutely (or nearly absolutely) required for assembly; and that mos, a cis-acting sequence previously shown to enhance phage yield in some circumstances, is without such effect in others.

Structural studies of proteins by high-flux X-ray and neutron solution scattering

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Interaction between the gene 5 protein, gene 5 protein/single stranded fd DNA complex and gene 8 protein of the filamentous phage fd

An affinity column consisting of gene 8 protein, the major coat protein of fd phage, bound to Sepharose was prepared. Isolated gene 5 protein/single stranded fd DNA complex was found to bind to this column and was eluted with fd phage single stranded fd DNA. pH changes, and 1 M CaCl2 were not effective in eluting the protein from the affinity column. Gene 5 protein/single stranded fd DNA complex from the crude extracts of fd-infected E. coli also bound to the column, as did isolated gene 5 protein; whereas fd single stranded DNA alone did not. These results may be relevant for the illucidation of the molecular events occurring in the early stages of fd phage assembly.

A Raman scattering study of the helix-destabilizing gene-5 protein with adenine-containing nucleotides

Raman spectra of gp5 and complexes of gp5 with poly(rA) and poly(dA) have been determined and analysed. From a fit of the amide I-band with model spectra it follows that the secondary structure of gp5 contains 52% beta-sheet, 28% undefined conformation and 19% alpha-helix. The band at 1032 cm-1 due to phenylalanine has an anomalous intensity both in the spectra of the complexes and the free protein. This possibly indicates a stacked structure present in the protein. Binding of gp5 to poly(rA) and poly(dA) influences the intensity of bands near 1338 and 1480 cm-1 which are considered to be marker-bands for the phosphate-sugar-base conformer. A change in conformation of the nucleotides is also reflected by vibrations originating in the phosphate- and sugar-residues of the backbone. In the spectrum of complexed poly(rA) the intensity of the conformation sensitive band at 813 cm-1, which is due to the phosphodiester group, is zero. It seems that gp5 forces poly(rA) and poly(dA) to a similar conformation. A marker band for stacking interaction in poly(rA) indicates that stacking interactions in the complex have increased.

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)

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.

Hydrodynamic studies of a DNA-protein complex. Dimensions of the complex of single-stranded 145 base DNA with gene 32 protein of phage T4 deduced from quasi-elastic light scattering

The translational diffusion coefficient of the saturated complex of single-stranded 145 base DNA and the helix-destabilizing protein of phage T4, GP32, can be measured at equilibrium by means of quasi-elastic light scattering. If the complex is considered as a rigid rod one can estimate its dimensions by combining the translational diffusion coefficient with earlier data on rotational diffusion. It was found that the average base-base distance of the 145 base DNA in the complex is between 4.3 and 4.7 A, while the diameter of the complex is between 44 and 68 A. This suggests that the conformation of the complex must be such that a large amount of water is trapped.

The bacteriophage f1 morphogenetic signal and the gene V protein/phage single-stranded DNA complex

The region of the bacteriophage f1 genome near the gene IV/intergenic region (IG) junction previously was shown to contain a sequence necessary for efficient packaging of single-stranded (SS) DNA into phage particles (the f1 "morphogenetic signal") [G. P. Dotto, V. Enea, and N. D. Zinder (1981) Virology 114, 463-473]. The DNA content of f1 phage/pBR322 chimeric plasmid-transformed, phage-infected bacteria has been investigated. The chimeric plasmids, constructed by Dotto et al. (1981), contained the f1 origins of DNA replication and, in some cases, also contained the "morphogenetic signal." Chimeric plasmid SS DNA was detected in phage-infected bacteria harboring any one of these chimeric plasmids, and the majority of this SS DNA was found complexed to the phage gene V protein. Therefore, the "morphogenetic signal" is not required for the formation of the gene V protein/f1 SS DNA complex but instead must function at a later stage of filamentous phage morphogenesis.

Minor protein content of the gene V protein/phage single-stranded DNA complex of the filamentous bacteriophage f1

The gene V protein/phage single-stranded (SS) DNA complex is an intermediate in the assembly of the filamentous bacteriophage f1. The minor protein content of this complex isolated from wild-type and amber mutant phage-infected Escherichia coli bacteria has been analyzed. Other than the gene V protein, none of the proteins found in purified samples of the complex correspond to any known phage gene products. In particular, the minor coat proteins found in the mature phage particle do not appear to be components of the cytoplasmic gene V protein/f1 SS DNA complex. However, approximately 1-3 molecules of E. coli single-stranded DNA binding protein (SSB) copurify with the complex and may be stably associated with this structure in vivo.

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.

Morphogenesis of filamentous bacteriophage f1: orientation of extrusion and production of polyphage

Crosslinking reagents were used to interrupt the process of filamentous phage morphogenesis and investigate the orientation in which nascent virions are extruded through the host cell membrane. Infected bacteria with emerging phage particles were crosslinked with glutaraldehyde. Immunoferritin-labeling studies on these emerging phage using anti-A protein IgG suggested that extrusion begins with the C protein end. To confirm this, phage extruding from infected bacteria were frozen using the reversible crosslinker dimethyl 3,3'-dithiobis-propionimidate and fragments of emerging phage were isolated by shearing. Protein analysis of these fragments showed them to be enriched in C protein relative to A protein, as predicted if phage extrusion begins with the C protein end. The production of multiple-length phage particles (polyphage) by nonpermissive bacterial hosts infected with amber mutant phage strains was also studied. Polyphage were produced upon infection with amber mutants in genes III, VI, VII, and IX which code for proteins found at the ends of the mature phage particle. No polyphage were produced by mutants in the other genes tested. Gene III amber mutants produce noninfective polyphage, but those produced by genes VII and IX are infective. Gene VI amber mutants appear to produce unstable, noninfective polyphage particles.

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.