A structural model for the single-stranded DNA genome of filamentous bacteriophage Pf1.

The filamentous bacteriophage Pf1, which infects strain PAK of Pseudomonas aeruginosa, is a flexible filament ( approximately 2000 x 6.5 nm) consisting of a covalently closed DNA loop of 7349 nucleotides sheathed by 7350 copies of a 46-residue alpha-helical subunit. The subunit alpha-helices, which are inclined at a small average angle ( approximately 16 degrees ) from the virion axis, are arranged compactly around the DNA core. Orientations of the Pf1 DNA nucleotides with respect to the filament axis are not known. In this work we report and interpret the polarized Raman spectra of oriented Pf1 filaments. We demonstrate that the polarizations of DNA Raman band intensities establish that the nucleotide bases of packaged Pf1 DNA are well ordered within the virion and that the base planes are positioned close to parallel to the filament axis. The present results are combined with a previously proposed projection of the intraviral path of Pf1 DNA [Liu, D. J., and Day, L. A. (1994) Science 265, 671-674] to develop a novel molecular model for the Pf1 assembly.

Unfolding thermodynamics of the Delta-domain in the prohead I subunit of phage HK97: determination by factor analysis of Raman spectra.

An early step in the morphogenesis of the double-stranded DNA (dsDNA) bacteriophage HK97 is the assembly of a precursor shell (prohead I) from 420 copies of a 384-residue subunit (gp5). Although formation of prohead I requires direct participation of gp5 residues 2-103 (Delta-domain), this domain is eliminated by viral protease prior to subsequent shell maturation and DNA packaging. The prohead I Delta-domain is thought to resemble a phage scaffolding protein, by virtue of its highly alpha-helical secondary structure and a tertiary fold that projects inward from the interior surface of the shell. Here, we employ factor analysis of temperature-dependent Raman spectra to characterize the thermostability of the Delta-domain secondary structure and to quantify the thermodynamic parameters of Delta-domain unfolding. The results are compared for the Delta-domain within the prohead I architecture (in situ) and for a recombinantly expressed 111-residue peptide (in vitro). We find that the alpha-helicity (approximately 70%), median melting temperature (T(m)=58 degrees C), enthalpy (DeltaH(m)=50+/-5 kcal mol(-1)), entropy (DeltaS(m)=150+/-10 cal mol(-1) K(-1)), and average cooperative melting unit (n(c) approximately 3.5) of the in situ Delta-domain are altered in vitro, indicating specific interdomain interactions within prohead I. Thus, the in vitro Delta-domain, despite an enhanced helical secondary structure ( approximately 90% alpha-helix), exhibits diminished thermostability (T(m)=40 degrees C; DeltaH(m)=27+/-2 kcal mol(-1); DeltaS(m)=86+/-6 cal mol(-1) K(-1)) and noncooperative unfolding ( approximately 1) vis-à-vis the in situ Delta-domain. Temperature-dependent Raman markers of subunit side chains, particularly those of Phe and Trp residues, also confirm different local interactions for the in situ and in vitro Delta-domains. The present results clarify the key role of the gp5 Delta-domain in prohead I architecture by providing direct evidence of domain structure stabilization and interdomain interactions within the assembled shell.

Impact of in vitro assembly defects on in vivo function of the phage P22 portal.

The podovirus P22, which infects O-antigen strains of Salmonella, incorporates a dsDNA translocating channel (portal dodecamer) at a unique vertex of the icosahedral capsid. The portal subunit (gp1, 82.7 kDa) exhibits multiple S-Hcdots, three dots, centeredX hydrogen bonding states for cysteines 153, 173, 283 and 516 and these interactions are strongly perturbed by portal ring formation. Here, we analyze in vivo activities of wild type (wt) and Cys-->Ser mutant portals, demonstrate that in vivo activity is correlated with in vitro assembly kinetics, and suggest mechanistic bases for the observed assembly defects. The C283S portal protein, which assembles into rings at about half the rate of wt, exhibits significantly diminished infectivity ( approximately 50% of wt) and manifests its defect prior to DNA packaging, most likely at the stage of procapsid assembly. Conversely, the C516S mutant, which assembles at twice the rate of wt, is more severely deficient in vivo ( approximately 20% of wt) and manifests its defect subsequent to capsid maturation and DNA packaging. Both C153S and C173S portals function at levels close to wt. The results suggest that C283S and C516S mutations may be exploited for improved characterization of the folding and assembly pathway of P22 portal protein.

Structural characterization of the filamentous bacteriophage PH75 from Thermus thermophilus by Raman and UV-resonance Raman spectroscopy.

The filamentous bacteriophage PH75, which infects the thermophile T. thermophilus, assembles in vivo at 70 degrees C and is stable to at least 90 degrees C. Although a high-resolution structure of PH75 is not available, the virion is known to comprise a closed single-stranded (ss) DNA circle of 6500 nucleotides sheathed by a capsid comprising 2700 copies of a 46-residue subunit (pVIII). Here, we employ Raman and UV-resonance Raman (UVRR) spectroscopy to identify structural details of the pVIII and DNA constituents of PH75 that may be related to the high thermostability of the native virion assembly. Analysis of the Raman amide I and amide III signatures reveals that the capsid subunit secondary structure is predominantly (87%) alpha-helical but contains a significant number of residues (6 +/- 1 or 13 +/- 3%) differing from the canonical alpha-helix. This minor structural component is not apparent in capsid subunits of the mesophilic filamentous phages, fd, Pf1, and Pf3, previously examined at similar spectral resolution. The Raman signature of PH75 also differs from those of fd, Pf1, and Pf3 by virtue of an unusual alanine marker (898 cm(-)(1) band), which is attributed to C(alpha)-H hydrogen-bond donation by subunit Ala residues. Because alanines of the PH75 subunit occur primarily within sXXXs motifs (where s is a small side chain, e.g. Gly, Ala, Ser), and because the occurrence of such motifs in alpha-helices is believed to thermostabilize interhelix associations via C(alpha)-H...O interactions [G. Kleiger et al. (2002) Biochemistry 41, 5990-5997], we propose that such hydrogen bonding may explain both the alanyl and amide I/III markers of PH75 capsid subunits and that C(alpha)-H...O interactions may serve as a significant source of virion thermostabilization. Raman and UVRR signatures of PH75 are also distinguished from those of fd, Pf1, and Pf3 by several marker bands that are indicative of hydrophilic Trp and Tyr environments, including hydrogen bonding interactions of aromatic ring substituents. These interactions are likewise proposed as contributors to the high thermostability of PH75 vis-a-vis fd, Pf1, and Pf3. Finally, PH75 is the only filamentous phage exhibiting UVRR markers diagnostic of a highly base-stacked ssDNA genome incorporating the low energy C2'-endo/anti deoxynucleoside conformation. The present results suggest that both intersubunit interactions and genome organization contribute to the enhanced thermostability of PH75 relative to mesophilic filamentous bacteriophages.

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.

Raman spectroscopy of proteins.

A protein Raman spectrum comprises discrete bands representing vibrational modes of the peptide backbone and its side chains. The spectral positions, intensities, and polarizations of the Raman bands are sensitive to protein secondary, tertiary, and quaternary structures and to side -chain orientations and local environments. In favorable cases, the Raman spectrum serves as an empirical signature of protein three-dimensional structure, intramolecular dynamics, and intermolecular interactions. Here, the strengths of Raman spectroscopy are illustrated by considering recent applications that address (1) subunit folding and recognition in assembly of the icosahedral capsid of bacteriophage P22, (2) orientations of subunit main chains and side chains in native filamentous viruses, (3) roles of cysteine hydrogen bonding in the folding, assembly, and function of virus structural proteins, and (4) structural determinants of protein/DNA recognition in gene regulatory complexes. Conventional Raman, UV-resonance Raman, and polarized Raman techniques are surveyed.

Orientation and interactions of an essential tryptophan (Trp-38) in the capsid subunit of Pf3 filamentous virus.

The filamentous bacteriophage Pf3 consists of a covalently closed DNA single strand of 5833 nucleotides sheathed by approximately 2500 copies of a 44-residue capsid subunit. The capsid subunit contains a single tryptophan residue (Trp-38), which is located within the basic C-terminal sequence (-RWIKAQFF) and is essential for virion assembly in vivo. Polarized Raman microspectroscopy has been employed to determine the orientation of the Trp-38 side chain in the native virus structure. The polarized Raman measurements show that the plane of the indolyl ring is tilted by 17 degrees from the virion axis and that the indolyl pseudo-twofold axis is inclined at 46 degrees to the virion axis. Using the presently determined orientation of the indolyl ring and side-chain torsion angles, chi(1) (N-C(alpha)-C(beta)-C(gamma)) and chi(2,1) (C(alpha)-C(beta)-C(gamma)-C(delta1)), we propose a detailed molecular model for the local structure of Trp-38 in the Pf3 virion. The present Pf3 model is consistent with previously reported Raman, ultraviolet-resonance Raman and fluorescence results suggesting an unusual environment for Trp-38 in the virion assembly, probably involving an intrasubunit cation-pi interaction between the guanidinium moiety of Arg-37 and the indolyl moiety of Trp-38. Such a C-terminal Trp-38/Arg-37 interaction may be important for the stabilization of a subunit conformation that is required for binding to the single-stranded DNA genome during virion assembly.

Protein and DNA residue orientations in the filamentous virus Pf1 determined by polarized Raman and polarized FTIR spectroscopy.

The Pseudomonas bacteriophage Pf1 is a long ( approximately 2000 nm) and thin ( approximately 6.5 nm) filament consisting of a covalently closed, single-stranded DNA genome of 7349 nucleotides coated by 7350 copies of a 46-residue alpha-helical subunit. The coat subunits are arranged as a superhelix of C(1)()S(5.4)() symmetry (class II). Polarized Raman and polarized FTIR spectroscopy of oriented Pf1 fibers show that the packaged single-stranded DNA genome is ordered specifically with respect to the capsid superhelix. Bases are nonrandomly arranged along the capsid interior, deoxynucleosides are uniformly in the C2'-endo/anti conformation, and the average DNA phosphodioxy group (PO(2)(-)) is oriented so that the line connecting the oxygen atoms (O.O) forms an angle of 71 degrees +/- 5 degrees with the virion axis. Raman and infrared amide band polarizations show that the subunit alpha-helix axis is inclined at an average angle of 16 degrees +/- 4 degrees with respect to the virion axis. The alpha-helical symmetry of the capsid subunit is remarkably rigorous, resulting in splitting of Raman-active helix vibrational modes at 351, 445 and 1026 cm(-)(1) into apparent A-type and E(2)()-type symmetry pairs. The subunit tyrosines (Tyr 25 and Tyr 40) are oriented with phenoxyl rings packed relatively close to parallel to the virion axis. The Tyr 25 and Tyr 40 orientations of Pf1 are surprisingly close to those observed for Tyr 21 and Tyr 24 of the Ff virion (C(5)()S(2)() symmetry, class I), suggesting a preferred tyrosyl side chain conformation in packed alpha-helical subunits, irrespective of capsid symmetry. The polarized Raman spectra also provide information on the orientations of subunit alanine, valine, leucine and isoleucine side chains of the Pf1 virion.