Critical Salt Bridges Guide Capsid Assembly,Stability, and Maturation Behavior in Bacteriophage HK97

HK97 is a double-stranded DNA bacteriophage that undergoes dramatic conformational changes during viral capsid maturation and for which x-ray structures, at near atomic resolution, of multiple intermediate and mature capsid states are available. Both amide H/²H exchange and crystallographic comparisons between the pre-expanded Prohead II particles and the expanded Head II of bacteriophage HK97 revealed quaternary interactions that remain fixed throughout maturation and appear to maintain intercapsomer integrity at all quasi- and icosahedral 3-fold axes. These 3-fold staples are formed from Arg and Glu residues and a metal binding site. Mutations of either Arg-347 or Arg-194 or a double mutation of E344Q and E363A resulted in purification of the phage in capsomer form (hexamers and pentamers). Mutants that did assemble had both decreased thermal stability and decreased in vitro expansion rates. Amide H/²H exchange mass spectrometry showed that in the wild type capsid some subunits had a bent “spine” helix (highly exchanging), whereas others were straight (less exchanging). Similar analysis of the never assembled mutant capsomers showed uniform amide exchange in all of these that was higher than that of the straight spine helices (characterized in more mature intermediates), suggesting that the spine helix is somewhat bent prior to capsid assembly. The result further supports a previously proposed mechanism for capsid expansion in which the delta domains of each subunit induce a high energy intermediate conformation, which now appears to include a bent helix during capsomer assembly.The viral capsid, particularly in double-stranded DNA bacteriophage, requires a highly stable macromolecular structure capable of encapsulating genome at near liquid crystalline density. Viral capsids are composed of hundreds to thousands of individual subunits that efficiently assemble into a closed capsid form often of a highly symmetrized icosahedral geometry, avoiding kinetic traps that would result in increased off-pathway assemblies. Recent studies have proposed that capsid assembly is mediated by weak intersubunit interactions that nucleate larger assembly intermediates, resulting in a considerably more stable capsid form due to a favorable geometry with a more constrained network of interactions. Measurements in systems such as cowpea chlorotic mottle virus, hepatitis B virus, and the bacteriophages P22 and HK97 have estimated the association energy of the initial assembly interaction between two subunits at 2–5 kcal/mol, which is seemingly low for a robust assembly product (1–5). An entropically driven process based on burial of hydrophobic surfaces was considered the driving force for the initial weak interactions with subsequent nucleation and elongation reactions leading to assembly of the full capsid (2, 6). Most complex viruses undergo a staged assembly process involving conformational transitions that occur after the initial assembly of a procapsid (7). The process is known as virion maturation. The interplay between interactions necessary for the initial assembly of capsomers into the procapsid and those that facilitate capsid maturation have been poorly understood, but recent crystal structures of procapsid and mature capsid states of HK97 allowed us to evaluate the structural properties that may facilitate maturation.HK97 is an amenable system for the study of capsid assembly and maturation. Symmetric procapsid particles can be assembled in Escherichia coli with the expression of just two gene products, gp4 (protease) and gp5 (capsid subunit). Maturation can then be followed in vitro by lowering the pH or chemically perturbing the procapsids. Unlike bacteriophages such as P22 that assemble their capsids directly from individual monomeric subunits, HK97 subunits initially assemble into capsomers composed of six-subunit (hexamers) or five-subunit (pentamers) oligomers. Twelve pentamers and 60 hexamers then assemble to form an icosahedral capsid with a triangulation number of 7 laevo, although a portal complex substitutes one of the pentamers during in vivo assembly. Residues 2–103 at the N terminus of the subunit, referred to as the delta domain, is thought to serve the same role as the scaffolding proteins identified for other phage in the assembly process (8). Capsomers then assemble, packaging the protease (gp4), to form the initial procapsid, Prohead I (P-I).¹ If the expression is done without the protease or with an inactive (by mutation) protease, this step is reversible (Fig. 1). The equilibrium of this assembly can be controlled in vitro with specific buffers and concentrations that favor either the capsomer or the capsid form (9). Expression with an active protease leads to proteolysis of the delta domains in the assembled P-I state followed by autodigestion of the protease and diffusion of the fragments from the particle. P-I then undergoes subtle structural adjustments, resulting in the Prohead II state composed entirely of the cleaved gp5* subunits (10, 11). At this stage of assembly in vivo, concatameric double-stranded DNA is packaged through a portal complex (composed of gp3 subunits) that fits into a single 5-fold vertex of the capsid. We used an HK97 construct that lacks gp3, so the purified Prohead II capsid is icosahedrally symmetric and cannot package DNA. Purified P-II can be matured in vitro using low pH and other chemical perturbation methods. During maturation, conformational changes in the subunits and their interactions result in large scale expansion and morphological changes in the capsid. The diameter of the capsid shell increases from 540 Å in P-II to 660 Å in Head II (H-II), the fully expanded particle form (12, 13). Intermediate particle forms can be trapped during the expansion and were previously characterized with a variety of biophysical techniques including cryo-EM microscopy (14, 15), x-ray crystallography (12, 13, 16), and small angle x-ray scattering (16–18). During the expansion process, self-catalyzed covalent cross-links are formed through isopeptide bond formation between Lys-169 and Asn-356 of different subunits situated on adjacent capsomers (19). The reaction is promoted by Glu-363, which is adjacent to the bonding residues and functions as a proton acceptor. Cross-linking during maturation was previously shown by differential scanning calorimetry (DSC) to greatly enhance the thermal stability of HK97 (5). In addition to covalent bonding, the H-II has significantly more buried surface area than P-II as seen in the highly intercalated intersubunit interactions depicted in the previous 3.44-Å structure of Head II (13, 20). A cross-link-defective mutant, K169Y, stills undergoes particle expansion, reaching the penultimate particle form, termed Head I (H-I), which has nearly identical conformations of hexamer capsomers but less extruded pentamers than H-II (16). H-I was used for all H/²H exchange studies instead of H-II because the cross-links in H-II dramatically affect the efficiency of proteolysis required for the mass spectrometry-based experiment (12, 20).Open in a separate windowFig. 1.HK97 assembly and expansion pathway. The schematic diagram depicts the assembly and expansion of HK97 in an E. coli expression system lacking the portal protein and other machinery required for genome packaging. 42-kDa subunits assemble into hexamer and pentamer capsomers, which then assemble into an initial icosahedral procapsid shell, P-I. Proteolytic cleavage of the delta domain of each subunit results in the formation of the metastable intermediate form P-II, which is able to undergo in vitro maturation when perturbed by various chemical agents. WT expansion proceeds through EI, balloon, and ultimately H-II forms, an expansion process that involves covalent cross-linking. K169Y mutant P-II proceeds through EI to the H-I form without any cross-linking occurring. Other than the lack of cross-links, H-I is identical to balloon.It was hypothesized that for highly intercalated mature capsid forms such as that seen in bacteriophage HK97 early procapsid intermediates are necessary for initial positioning of subunits before conformational changes can facilitate a protein architecture with increased stability. We recently showed with amide H/²H exchange and crystallographic comparisons between the pre-expanded P-II particles and the mature H-II that maturation is probably guided by tertiary structure twisting and secondary structure changes around a fixed set of intercapsomer interactions that surround all quasi- and icosahedral 3-fold axes in the capsid shell (12). The major interactions that appear to facilitate these “3-fold staples” include two sets of salt bridges and a putative metal binding site (Fig. 2). The salt bridge interactions are between residues Glu-344 and Arg-194 and between residues Glu-363 and Arg-347. Glutamate 363 serves dual roles as it is involved in both a salt bridge with Arg-347 and serves as a proton acceptor that catalyzes the isopeptide bond formation (21). The metal binding site is formed by 3-fold related glutamates at position 348 interacting with a sphere of electron density at high σ level in the P-II crystal structure (12). Although comparable density for metal ions is not present at the equivalent position in crystal structures of the late intermediates, the positions of the glutamates are nearly identical, indicating a stable interaction with some mechanism for neutralizing the negative charge repulsion. In contrast to the near identical conformations of the residues at the 3-fold interface, the rest of the subunit was shown to undergo a large scale twisting motion, causing hinging in all three P-domain β-strands (see Fig. 8A for domain nomenclature). These data imply that interactions at the 3-fold interface may be crucial in assembling the capsid from individual capsomers as well as providing a fixed point from which subunits bend while maintaining intercapsomer contacts.Open in a separate windowFig. 2.Importance of 3-fold intercapsomer contacts. A, P-II capsid from previously solved 3.65-Å crystal structure rendered in low resolution in chimera. Two hexon subunits (subunits a and f, yellow and green, respectively) and one penton subunit (orange) that form a quasi-3-fold interaction are shown as ribbons. B, zoomed in view of quasi-3-fold interaction between the two hexamer subunits and one pentamer subunit as highlighted in A. The view is from inside the capsid, 180° rotated from the view shown in A. Residues involved in salt bridges as well as a putative metal binding site (Glu-348) are labeled accordingly. C, table identifying various mutations made to perturb 3-fold contacts. The phenotypes following protein expression are identified. Mutants are distinguished as to whether they were purified as capsids or capsomers (hexamers and pentamers) following protein expression. Data for the Glu-363 mutants are from Dierkes et al. (21).Open in a separate windowFig. 8.Solvent accessibility of R347N capsomer spine helix. A, subunit C of Prohead II is shown with the major domains labeled. Residues 206–216 of the spine helix are colored orange. B, mass envelopes for P-II and H-I particle forms as well as the R347N capsomers following 5 min of exchange. The top spectrum is non-deuterated P-II. C, H/²H exchange results of the residues colored orange are plotted for the R347N capsomers (orange curve) and compared with the solvent accessibility curves for the same fragment in the P-II capsid state, EI, and the nearly mature H-I capsid form. D, the solvent accessibility of the same spine helix fragment is shown for both the R347N capsomers and WT capsomers that were disassembled from the P-I state.Here we confirmed this role for the 3-fold interactions by mutagenesis of relevant residues and characterized the resulting assembly products, thermal stabilities, and maturation kinetics. Some of the mutants did not assemble into particles following the formation of capsomers (e.g. R347N). Capsomers were then purified, and the amide exchange of the spine helices was analyzed with H/²H exchange coupled to mass spectrometry (22–24). Previous data illustrated a direct correlation between increased H/²H exchange and an increased bend in the helix conformation (12, 20). Amide exchange of the spine helix in the mutant capsomers was compared with previously characterized particle forms as well as P-I and WT capsomers disassembled from P-I.