Silver and mercury probing of deoxyribonucleic acid structures in the filamentous viruses fd, If1, IKe, Xf, Pf1, and Pf3

Ag+ binding and Hg2+ binding to both double-stranded DNA (dsDNA) and single-stranded DNA (ssDNA) have been examined in some detail, and the results have been applied to study the structures of circular ssDNA in several filamentous viruses. It has been known for some time that Ag+ and Hg2+ bind to the bases of DNA producing characteristic large changes in absorbance and circular dichroism (CD) spectra, as well as changes in sedimentation rates. In the case of Ag+, it is known that there are three modes of binding to isolated dsDNA, referred to as types I, II, and III. Type III binding, by definition, occurs when Ag+ binds to Ag-dsDNA complexes having sites for binding types I and II extensively occupied, if not saturated. It produces CD spectra, assigned in this study, and absorbance spectra that are isosbestic with those of the Ag-dsDNA complexes present prior to its onset. In phosphate buffers binding is restricted to types I and II, whereas in borate buffers weaker type III binding can occur. Characteristics of types I, II, and III were observed for the DNAs in fd, If1, IKe, and Xf, but not for those in Pf1 and Pf3. Similarly, many of the spectral changes seen when Hg2+ binds to isolated double-stranded DNA are mimicked by Hg2+ binding to the DNAs within fd, IKe, If1, and Xf, but not for those in Pf1 and Pf3. The Ag+ and Hg2+ results indicate the presence of right-handed DNA helices in fd, If1, IKe, and Xf, with the two antiparallel strands of the covalently closed single-stranded DNAs having the bases directed toward the virion axes. For Pf1 and Pf3, Ag+ and Hg2+ binding cause large absorbance changes but only small CD changes. The very different results for Pf1 and Pf3 are consistent with the presence of inverted DNA structures (I-DNA) with the bases directed away from the structure axes, but the two structures differ from one another. Sedimentation velocity changes with Ag+ and Hg2+ binding strongly suggest structural linkages between the DNA and the surrounding protein sheath in each of the viruses.     

Sugar pucker and phosphodiester conformations in viral genomes of filamentous bacteriophages: fd, If1, IKe, Pf1, Xf, and Pf3

The laser Raman spectra of filamentous viruses contain discrete bands which are assignable to molecular vibrations of the encapsidated, single-stranded DNA genomes and which are informative of their molecular conformations. Discrimination between Raman bands of the DNA and those of the coat proteins is facilitated by analysis of viruses containing deuterium-labeled amino acids. Specific DNA vibrational assignments are based upon previous studies of A-, B-, and Z-DNA oligonucleotide crystals of known structure [Thomas, G.J., Jr., & Wang, A.H.-J. (1988) in Nucleic Acids and Molecular Biology (Eckstein, F., & Lilley, D.M.J., Eds.) Vol. 2, Springer-Verlag, Berlin]. The present results show that canonical DNA structures are absent from six filamentous viruses: fd, If1, IKe, Pfl, Xf, and Pf3. The DNAs in three viruses of symmetry class I (fd, If1, IKe) contain very similar nucleoside sugar puckers and glycosyl torsions, deduced to be C3'-endo/anti. However, nucleoside conformations are not the same among the three class II viruses examined: Pf1 and Xf DNAs contain similar conformers, deduced to be C2'-endo/anti, whereas Pf3 DNA exhibits bands usually associated with C3'-endo/anti conformers. Conformation-sensitive Raman bands of the DNA 3'-C-O-P-O-C-5' groups show that in all class I viruses and in Pf1 the ssDNA backbones do not contain regularly ordered phosphodiester group geometries, like those found in ordered single- and double-stranded nucleic acids.(ABSTRACT TRUNCATED AT 250 WORDS)     

Comparison of protein and deoxyribonucleic acid backbone structures in fd and Pf1 bacteriophages

The conformations of the protein and nucleic acid backbones in the filamentous viruses fd and Pf1 are characterized by one- and two-dimensional solid-state NMR experiments on oriented virus solutions. Striking differences are observed between fd and Pf1 in both their protein and DNA structures. The coat proteins of fd and Pf1 are almost entirely alpha helical and in both viruses most of the helix is oriented parallel to the filament axis. fd coat protein is one stretch of alpha helix that is slightly slued about the filament axis. In Pf1 coat protein two distinct sections of alpha helix are present, the smaller of which is tilted with respect to the filament axis by about 20 degrees. The DNA backbone structure of fd is completely disordered. By contrast, the DNA backbone of Pf1 is uniformly oriented such that all of the phosphodiester groups have the O-P-O plane of the nonesterified oxygens approximately perpendicular to the filament axis.     

Raman spectroscopy of mercury (II) binding to two filamentous viruses: Ff (fd, M13, f1) and Pf1

Ff and Pf1 are filamentous bacteriophages. Each contains, in a central core region surrounded by protein, a circular single-stranded DNA molecule, and it is known that the DNA bases are sites of Hg(II) binding. In the present study, Raman spectra were obtained for the two viruses in the presence of increasing amounts of Hg(II), with ratios (m) of Hg(II) added per nucleotide residue in the range 0 less than m less than 2.0. Hg(II) binding to the viruses induces Raman intensity changes in previously assigned Raman lines of viral DNA, demonstrating metal binding to the DNA bases, but also in many lines assigned to protein. The overall structures of the viruses do not change with Hg(II) binding, and the Raman spectra indicate little, if any, change in protein secondary structure. Changes in certain protein Raman lines induced by Hg(II) binding to the DNA for low values of m are attributed to altered interactions between solvent and protein side chains, aliphatic groups being the most affected. The nature of such changes for both viruses suggests DNA-protein linkage. In Pf1, lines assigned to ring vibrations of all four bases are perturbed upon initial addition of Hg(II) to m = 0.25. In Ff, however, lines assigned to base ring vibrations are not perturbed until m greater than or equal to 0.5. The results provide additional evidence for fundamentally different DNA structures in Ff and Pf1.     

Structure similarity, difference and variability in the filamentous viruses fd, If1, IKe, Pf1 and Xf. Investigation by laser Raman spectroscopy

The filamentous bacteriophages fd, If1, IKe, Pf1, Xf and Pf3 in aqueous solutions of low, moderate and high ionic strength have been investigated as a function of temperature by laser Raman difference spectroscopy. By analogy with Raman spectra of model compounds and viruses of known structure, the data reveal the following structural features: the predominant secondary structure of the coat protein subunit in each virus is the alpha-helix, but the amount of alpha-helix differs from one virus to another, ranging from an estimated high of 100% in Pf1 to a low of approximately 50% in Xf. The molecular environment and intermolecular interactions of tyrosine, tryptophan and phenylalanine residues differ among the different viruses, as do the conformations of aliphatic amino acid side-chains. The foregoing features of coat protein structure are highly sensitive to changes in Na+ concentration, temperature or both. The backbones of A-DNA and B-DNA structures do not occur in any of the viruses, and unusual DNA structures are indicated for all six viruses. The alpha-helical protein subunits of Pf1, like those of Pf3 and Xf, can undergo reversible transitions to beta-sheet structures while retaining their association with DNA; yet fd, IKe and If1 do not undergo such transitions. Raman intensity changes with ionic strength or temperature suggest that transgauche rotations of aliphatic amino acid side-chains and stacking of aromatic side-chains are important structural variables in each virus.     

Export of infectious particles by Escherichia coli transfected with the RF DNA of Pf1, a virus of Pseudomonas aeruginosa strain K

Pf1 is a filamentous, single-stranded DNA virus that has Pseudomonas aeruginosa (strain K) as host. It is the longest of the filamentous bacterial viruses, and the DNA within it has the most extended conformation known. Pf1 virus cannot infect Escherichia coli (strain MM294) cells, but when these cells are transfected with the double-stranded replicative form of Pf1 DNA (RF DNA, 7.35 kb), they export low levels of infectious particles that create plaques on lawns of P. aeruginosa. Several different structural species, at least two of which are infectious, are exported. One of them, called Epf1, has virtually the same structure as Pf1, but the amount of Epf1 exported by E. coli is 10(4) lower than the amount of Pf1 exported by P. aeruginosa. The results imply that host factors affect not only the efficiency of virus assembly and export, but also the actual structures of the species exported.     

Different packaging of DNA in the filamentous viruses Pf1 and Xf

Xf Virus DNA, like Pf1 DNA, is a single-stranded circular molecule and contains, within experimental error, the same number of nucleotides, 7400. This was unexpected since Pf1 virus is 2 μm long while Xf virus is only 1 μm long. The ratio of nucleotides to major coat protein subunits has been found to be nearly unity in Pf1 and nearly two in Xf, but it is not certain that the ratios have exactly integer values. Calculations give the average axial internucleotide separation in Pf1virus as 5.3 Å whereas in Xf virus, the calculated separation is only 2.6 Å. The protein subunits in both Pf1 and Xf have calculated axial separations close to 2.6 Å. The results provide a solution to a problem encountered in the interpretation of X-ray diffraction patterns of these viruses concerning the number of protein subunits per helical turn.     

Protect thy host: Pf4 phages shield Pseudomonas aeruginosa from antibiotics

Bacterial viruses or bacteriophages exert profound effects on host cell lifestyle and evolution. The prophage Pf4 in Pseudomonas aeruginosa is highly induced in biofilms and is shown to confer antibiotic resistance to the bacterium. A novel study has now revealed that Pf4 forms crystalline structures that serve to physically wall off antibiotics from the bacterium. This represents an entirely novel mechanism involving liquid–liquid phase separation in prokaryotic systems. Furthermore, the toxin-antitoxin system PfiAT, which is encoded within the prophage Pf4, represents a unique production mechanism for Pf4. Combined, these two studies broadened our knowledge on the antibiotic resistance mechanisms used by P. aeruginosa.     

Filamentous bacterial viruses. XI. Molecular architecture of the class II (Pf1, Xf) virion

The diffraction patterns of the Pf 1 and Xf strains of filamentous bacterial viruses (class II) can be interpreted in terms of a simple helix of protein subunits with 15Åpitch, having 22 units in five turns. The protein subunits are each elongated in an axial direction, and also slope radially, so as to overlap each other, giving an arrangement of subunits reminiscent of scales on a fish. The protein helix forms a tube with inner diameter about 20Åand outer diameter about 60Å. The single-stranded circular DNA is contained within this tube, with two DNA strands running the length of the tube.The diffraction patterns of fd, If 1 and IKe (class I) can be interpreted in terms of a perturbed version of the class II simple helix.     

Demonstration by ultraviolet resonance Raman spectroscopy of differences in DNA organization and interactions in filamentous viruses Pf1 and fd

Pf1, a class II filamentous virus, has been investigated by ultraviolet resonance Raman (UVRR) spectroscopy with excitation wavelengths of 257, 244, 238, and 229 nm. The 257-nm UVRR spectrum is rich in Raman bands of the packaged single-stranded DNA (ssDNA) genome, despite the low DNA mass (6%) of the virion. Conversely, the 229-nm UVRR spectrum is dominated by tyrosines (Tyr 25 and Tyr 40) of the 46-residue alpha-helical coat subunit. UVRR spectra excited at 244 and 238 nm exhibit Raman bands diagnostic of both viral DNA and coat protein tyrosines. Raman markers of packaged Pf1 DNA contrast sharply with those of the DNA packaged in the class I filamentous virus fd [Wen, Z. Q., Overman, S. A., and Thomas, G. J., Jr. (1997) Biochemistry 36, 7810-7820]. Interestingly, deoxynucleotides of Pf1 DNA exhibit sugars in the C2'-endo/anti conformation and bases that are largely unstacked, compared with C3'-endo/anti conformers and very strong base stacking in fd DNA; hydrogen-bonding interactions of thymine carbonyls are also different in Pf1 and fd. On the other hand, coat protein tyrosines of Pf1 exhibit Raman markers of ring environment identical to those of fd, including an anomalous singlet at 853 cm-1 in lieu of the canonical Fermi doublet (850/830 cm-1) found in globular proteins. The results indicate markedly different modes of organization of ssDNA in Pf1 and fd virions, despite similar environments for coat protein tyrosines, and suggest strong hydrogen-bonding interactions between DNA bases and coat subunits of Pf1 but not between those of fd. We propose that structural relationships between the protein coat and encapsidated ssDNA genome are also fundamentally different in the two assemblies.     

A theory of the symmetries of filamentous bacteriophages.

A mathematical model is presented which explains the symmetries observed for the protein coats of filamentous bacterial viruses. Three viruses (Ff, IKe, and If1) all have five-start helices with rotation angles of 36 degrees and axial translations of 16 A (Type I symmetry), and three other viruses (Pf1, Xf, and Pf3) all have one-start helices with rotation angles of approximately equal to 67 degrees and translations of approximately 3 A (Type II symmetry). The coat protein subunits in each group diverge from each other in amino acid sequence, and Type II viruses differ dramatically in DNA structure. Regardless of the differences, both Type I and Type II symmetry can be understood as direct, natural consequences of the close-packing of alpha-helical protein subunits. In our treatment, an alpha-helical subunit is modeled as consisting of two interconnected, flexible tubular segments that follow helical paths around the DNA, one in an inner layer and the other in an outer layer. The mathematical model is a set of algebraic equations describing the disposition of the flexible segments. Solutions are described by newly introduced symmetry indices and other parameters. An exhaustive survey over the range of indices has produced a library of all structures that are geometrically feasible within our modeling scheme. Solutions which correspond in their rotation angles to Type I and Type II viruses occur over large ranges of the parameter space. A few solutions with other symmetries are also allowed, and viruses with these symmetries may exist in nature. One solution to the set of equations, obtained without any recourse to the x-ray data, yields a calculated x-ray diffraction pattern for Pf1 which compares reasonably with experimental patterns. The close-packing geometry we have used helps explain the near constant linear mass density of known filamentous phages. Helicoid, rigid cylinder, and maximum entropy structure models proposed by others for Pf1 are reconciled with the flexible tube models and with one another.     

Structure and organization of bacteriophage Pf3 probed by Raman and ultraviolet resonance Raman spectroscopy

The Pseudomonas bacteriophage Pf3 is a long and narrow filament consisting of a covalently closed DNA single strand of 5833 bases sheathed by approximately 2500 copies of a 44-residue subunit. Ultraviolet resonance Raman spectra excited at 257, 244, 238, and 229 nm and off-resonance Raman spectra excited at 514.5 nm are reported for Pf3 in both H2O and D2O solutions. The key Raman bands are assigned to specific protein and DNA groups of the native virion assembly. The results are compared with proposed assembly models and Raman spectra recently reported for the isomorphous (class II) Pseudomonas phage Pf1 and the morphologically distinct (class I) coliphage fd [Wen, Z. Q., Overman, S. A., and Thomas, G. J. , Jr. (1997) Biochemistry 36, 7810-7820; Wen, Z. Q., Armstrong, A., and Thomas, G. J., Jr. (1999) Biochemistry 38, 3148-3156]. Surprisingly, deoxynucleosides of the packaged DNA genome of Pf3 adopt the same conformation (C3'-endo/anti) found for DNA packaged in the class I fd virion rather than that (C2'-endo/anti) associated with DNA in the isomorphous Pf1 virion. However, DNA base stacking in Pf3, as judged by Raman hypochromic effects, differs significantly from that occurring in either Pf1 or fd. Thus, the single-stranded DNA genomes of Pf3, Pf1, and fd are all organized differently within their respective capsids, implying that local subunit-DNA interactions may be important in determining the structure specific to each native assembly. The present study confirms a completely alpha-helical secondary structure for the Pf3 subunit and an unusual indolyl ring environment for the subunit tryptophan residue (Trp-38).     

Different arrangements of protein subunits and single-stranded circular DNA in the filamentous bacterial viruses fd and Pf1

A single-stranded circular DNA molecule of 6690 ± 450 nucleotides accounts for 5.5 ± 0.3% of the mass of Pf1 virus. The remaining mass is contributed almost entirely by subunits of the major coat protein. A non-integral nucleotide to subunit ratio of 0.87 ± 0.05 is calculated from the DNA content, the average nucleotide mass (309), and the known mass of one protein subunit (4609). There are therefore 7690 ± 680 major coat protein subunits in the virus. The virus length determined by electron microscopy is 1960 ± 70 nm. The data give an average axial distance of 2.55 ± 0.24 Å between protein subunits in dry virus. Since there is an up strand and a down strand of the circular DNA within the virus filament, an axial distance between bases in a given strand of 5.9 ± 0.5 Å is calculated. Available X-ray data show that an axial repeat of 72 Å, or slightly less, would be expected for dry Pf1 virus (0% relative humidity). A structural model in which 27 protein subunits and 24 nucleotides are contained in this repeat would be consistent with our data. The DNA conformation and the subunit packing in Pf1 differ considerably from those in fd, even though both are filamentous viruses containing single-stranded circular DNA. The uncertainties cited are 95% confidence limits.     

Sialic acid-dependent binding of Plasmodium falciparum merozoite surface antigen, Pf200, to human erythrocytes

Plasmodium falciparum merozoites, the extracellular stage of the erythrocytic cycle of the human malarial parasite, specifically invade human E. The major determinant of that specificity is the sialic acid residues of E glycophorin. In the present study we show that the merozoite surface Ag, Pf200 (m.w. 195,000 to 205,000), of two different isolates of P. falciparum, binds to the surface of human E but not E from other species not invaded by P. falciparum. Pf200 does not bind to neuraminidase-treated E, indicating the interaction is dependent on sialic acid residues. Binding is inhibited by soluble glycophorin and selective mAb against the glycosylated domain of glycophorin, but not by a mAb against the peptide domain of glycophorin. mAb.5B1 previously identified as reacting with Pf 200, blocks binding of the protein to the E. Binding between Pf200 and the E is not high affinity, as Pf200 can be released from the surface by 0.25 M NaCl.     

Ultraviolet-resonance raman spectroscopy of the filamentous virus Pf3: interactions of Trp 38 specific to the assembled virion subunit

The class II filamentous virus Pf3 packages a circular single-stranded DNA genome of approximately 5833 [corrected] nucleotides within a cylindrical capsid constructed from approximately 2500 [corrected] copies of a 44 residue alpha-helical subunit. The single tryptophan residue (Trp 38) of the capsid subunit is located within a basic C-terminal sequence (.R(+)WIK(+)AQFF). The local environment of Trp 38 in the native Pf3 assembly has been investigated using 229 nm excited ultraviolet-resonance Raman (UVRR) spectroscopy and fluorescence spectroscopy. Trp 38 exhibits an anomalous UVRR signature in Pf3, including structure-diagnostic Raman bands (763, 1228, 1370, and 1773 cm(-)(1)) that are greatly displaced from corresponding Raman markers observed in either detergent-disassembled Pf3, class I filamentous viruses, most globular proteins, or aqueous L-TRP. An unusual and highly quenched fluorescence spectrum is also observed for Trp 38. These distinctive UVRR and fluorescence signatures together reflect interactions of the Trp 38 side chain that are specific to the native PF3 assembly. The experimental results on PF3 and supporting spectroscopic data from other proteins of known three-dimensional structure favor a model in which pi electrons of the Trp 38 indolyl ring interact specifically with a basic side chain of the subunit C-terminal sequence. Residues Arg 37 AND Lys 40 are plausible candidates for the proposed cation-pi interaction of Trp 38. The present study suggests that raman spectroscopy may be a generally useful probe of interactions between the indolyl pi-electron system of tryptophan and electropositive groups in proteins and their assemblies.     

Effects of virion and salt concentrations on the Raman signatures of filamentous phages fd, Pf1, Pf3, and PH75

Filamentous phages consist of a single-stranded DNA genome encapsidated by several thousand copies of a small alpha-helical coat protein subunit plus several copies of four minor proteins at the filament ends. The filamentous phages are important as cloning vectors, vehicles for peptide display, and substrates for macromolecular alignment. Effective use of a filamentous phage in such applications requires an understanding of experimental factors that may influence the propensity of viral filaments to laterally aggregate in solution. Because the Raman spectrum of a filamentous phage is strongly dependent on the relative orientation of the virion with respect to the polarization direction of the electromagnetic radiation employed to excite the spectrum, we have applied Raman spectroscopy to investigate lateral aggregation of phages fd, Pf1, Pf3, and PH75 in solution. The results show that lateral aggregation of the virions and anisotropic orientation of the aggregates are both disfavored by high concentrations of salt (>200 mM NaCl) in solutions containing a relatively low virion concentration (<10 mg/mL). Conversely, the formation of lateral aggregates and their anisotropic orientation are strongly favored by a low salt concentration (<0.1 mM NaCl), irrespective of the virion concentration over a wide range. The use of Raman polarization effects to distinguish isotropic and anisotropic solutions of filamentous phages is consistent with previously reported Raman analyses of virion structures in both solutions and fibers. The Raman data are supported by electron micrographs of negatively stained specimens of phage fd, which permit an independent assessment of salt effects on lateral aggregation. The present results also identify new Raman bands that serve as potential markers of subunit side-chain orientations in filamentous virus assemblies.     

Intermediate states between P* and Pf in bacterial reaction centers,as detected by the fluorescence kinetics

The fluorescence lifetimes of the reaction centers isolated from the wild-type Rhodopseudomonas sphaeroides purple bacterium and those from the R26 mutant strain, lacking the carotenoid, were measured at low redox potential. In addition to the prompt fluorescence occurring directly from P* and the long delayed emission related to the radical pair state Pf, two other components are present. We suggest that they may come from intermediate states between P* and Pf, or reflect the stabilization of Pf itself.