Virus maturation involving large subunit rotations and local refolding.

Large-scale conformational changes transform viral precursors into infectious virions. The structure of bacteriophage HK97 capsid, Head-II, was recently solved by crystallography, revealing a catenated cross-linked topology. We have visualized its precursor, Prohead-II, by cryoelectron microscopy and modeled the conformational change by appropriately adapting Head-II. Rigid-body rotations ( approximately 40 degrees) cause switching to an entirely different set of interactions; in addition, two motifs undergo refolding. These changes stabilize the capsid by increasing the surface area buried at interfaces and bringing the cross-link-forming residues, initially approximately 40 angstroms apart, close together. The inner surface of Prohead-II is negatively charged, suggesting that the transition is triggered electrostatically by DNA packaging.

Genome organization and characterization of mycobacteriophage Bxb1.

Mycobacteriophage Bxb1 is a temperate phage of Mycobacterium smegmatis. The morphology of Bxb1 particles is similar to that of mycobacteriophages L5 and D29, although Bxb1 differs from these phages in other respects. First, it is heteroimmune with L5 and efficiently forms plaques on an L5 lysogen. Secondly, it has a different host range and fails to infect slow-growing mycobacteria, using a receptor system that is apparently different from that of L5 and D29. Thirdly, it is the first mycobacteriophage to be described that forms a large prominent halo around plaques on a lawn of M. smegmatis. The sequence of the Bxb1 genome shows that it possesses a similar overall organization to the genomes of L5 and D29 and shares weak but detectable DNA sequence similarity to these phages within the structural genes. However, Bxb1 uses a different system of integration and excision, a repressor with different specificity to that of L5 and encodes a large number of novel gene products including several with enzymatic functions that could degrade or modify the mycobacterial cell wall.

Topologically linked protein rings in the bacteriophage HK97 capsid.

The crystal structure of the double-stranded DNA bacteriophage HK97 mature empty capsid was determined at 3.6 angstrom resolution. The 660 angstrom diameter icosahedral particle contains 420 subunits with a new fold. The final capsid maturation step is an autocatalytic reaction that creates 420 isopeptide bonds between proteins. Each subunit is joined to two of its neighbors by ligation of the side-chain lysine 169 to asparagine 356. This generates 12 pentameric and 60 hexameric rings of covalently joined subunits that loop through each other, creating protein chainmail: topologically linked protein catenanes arranged with icosahedral symmetry. Catenanes have not been previously observed in proteins and provide a stabilization mechanism for the very thin HK97 capsid.

Genomic sequences of bacteriophages HK97 and HK022: pervasive genetic mosaicism in the lambdoid bacteriophages.

We report the complete genome DNA sequences of HK97 (39,732 bp) and HK022 (40,751 bp), double-stranded DNA bacteriophages of Escherichia coli and members of the lambdoid or lambda-like group of phages. We provide a comparative analysis of these sequences with each other and with two previously determined lambdoid family genome sequences, those of E. coli phage lambda and Salmonella typhimurium phage P22. The comparisons confirm that these phages are genetic mosaics, with mosaic segments separated by sharp transitions in the sequence. The mosaicism provides clear evidence that horizontal exchange of genetic material is a major component of evolution for these viruses. The data suggest a model for evolution in which diversity is generated by a combination of illegitimate and homologous recombination and mutational drift, and selection for function produces a population in which most of the surviving mosaic boundaries are located at gene boundaries or, in some cases, at protein domain boundaries within genes. Comparisons of these genomes highlight a number of differences that allow plausible inferences of specific evolutionary scenarios for some parts of the genome. The comparative analysis also allows some inferences about function of genes or other genetic elements. We give examples for the generalized recombination genes of HK97, HK022 and P22, and for a putative headtail adaptor protein of HK97 and HK022. We also use the comparative approach to identify a new class of genetic elements, the morons, which consist of a protein-coding region flanked by a putative delta 70 promoter and a putative factor-independent transcription terminator, all located between two genes that may be adjacent in a different phage. We argue that morons are autonomous genetic modules that are expressed from the repressed prophage. Sequence composition of the morons implies that they have entered the phages' genomes by horizontal transfer in relatively recent evolutionary time.

Maturation dynamics of a viral capsid: visualization of transitional intermediate states.

Typical of DNA bacteriophages and herpesviruses, HK97 assembles in two stages: polymerization and maturation. First, capsid protein polymerizes into closed shells; then, these precursors mature into larger, stabler particles. Maturation is initiated by proteolysis, producing a metastable particle primed for expansion-the major structural transition. We induced expansion in vitro by acidic pH and monitored the resulting changes by time-resolved X-ray diffraction and cryo-electron microscopy. The transition, which is not synchronized over the population, proceeds in a series of stochastically triggered subtransitions. Three distinct intermediates were identified, which are comparable to transitional states in protein folding. The intermediates' structures reveal the molecular events occurring during expansion. Integrated into a movie (see Dynamic Visualization below), they show capsid maturation as a dynamic process.

Bacteriophage T4 self-assembly: localization of gp3 and its role in determining tail length.

Gene 3 of bacteriophage T4 participates at a late stage in the T4 tail assembly pathway, but the hypothetical protein product, gp3, has never been identified in extracts of infected cells or in any tail assembly intermediate. In order to overcome this difficulty, we expressed gp3 in a high-efficiency plasmid expression vector and subsequently purified it for further analysis. The N-terminal sequence of the purified protein showed that the initial methionine had been removed. Variant C-terminal amino acid sequences were resolved by determining the cysteine content of the protein. The molecular mass of 20.6 kDa for the pure protein was confirmed by Western blotting, using a specific anti-gp3 serum for which the purified protein was the immunogen. We also demonstrated, for the first time, the physical presence of gp3 in the mature T4 phage particle and localized it to the tail tube. By finding a nonleaky, nonpermissive host for a gene 3 mutant, we could clearly demonstrate a new phenotype: the slow, aberrant elongation of the tail tube in the absence of gp3.

Crystallographic analysis of the dsDNA bacteriophage HK97 mature empty capsid.

HK97 is a member of the Siphovirus family of dsDNA bacteriophages. It is similar in architecture to bacteriophage lambda, the type member of this family, with an icosahedral capsid of triangulation number T = 7. No high-resolution structural information is available for the dsDNA phages, and HK97 is the only dsDNA bacteriophage capsid to produce crystals which diffract X-rays. At 650 A in diameter, the large size of the particle and resultant large unit cell create crystallographic challenges. The empty Head II (mature) particles were expressed in Escherichia coli and assembled in vitro, but they have the same morphology as the mature HK97 capsid. Previously reported Head II crystals diffracting to 3.5 A resolution are examined here in detail. Although the cell dimensions suggest an orthorhombic lattice, further analysis demonstrated that the space group was monoclinic. This has been confirmed by the present study. Images were recorded on the F1 beamline at CHESS and they were processed and scaled, resulting in a data set with a cumulative completeness of 65% and a scaling R factor of 7.7% to 7 A. The cell dimensions after post-refinement were a = 580, b = 626, c = 788 A, beta = 90.0 degrees. From the particle dimensions determined by cryo-electron microscopy (cryo-EM), there were determined to be two particles per unit cell. Systematic absences of even reflections along the 0k0 lattice line indicate that the space group is P21. The rotation function was used to determine the orientation of the particles in the unit cell and to confirm the space group. An icosahedral twofold axis is approximately, but not exactly, aligned with the crystallographic screw (b) axis. An icosahedral twofold axis orthogonal to the one approximately parallel to the b axis, is rotated 18 degrees away from the a axis. The centers of the two particles must be positioned close to the minimum-energy packing arrangement for spheres, which places one particle at ((1/4), 0, (1/4)) and the other particle at ((3/4), (1/2), (3/4)). The particle position and orientation were confirmed by calculating a Patterson function. The particles interact closely along icosahedral threefold axes, which occurs both along the crystallographic a axis and along the b axis. The particle dimensions derived from this packing arrangement agree well with those determined by cryo-EM and image reconstruction. The cryo-EM reconstruction will be used as a model to initiate phase determination; structure determination at 7 A is under way.

Protein chainmail: catenated protein in viral capsids.

The capsid shells of bacteriophage HK97 and several other phages contain polypeptides that are covalently linked into complexes so large that they do not enter polyacrylamide gels after denaturation. The enormous apparent size of these protein complexes in HK97 derives from a novel protein topology. HK97 subunits cross-link via isopeptide bonds into oligomers that are closed rings of five or six members. However, polypeptides from neighboring pentamer and hexamer rings intertwine before the covalent cross-links form. As a result, adjacent protein rings catenate into a network similar to chainmail armor. In vitro linking and unlinking experiments provide strong support for the chainmail model, which explains the unusual properties of these bacteriophages and may apply to other macromolecular structures.

Crystallization and preliminary X-ray analysis of the dsDNA bacteriophage HK97 mature empty capsid.

HK97 is a temperate dsDNA bacteriophage of Escherichia coli that is structurally similar to phage lambda, with an icosahedral head of triangulation (7) number 7. Although the capsids of several large dsDNA phages have been studied extensively using a variety of biophysical approaches, no high-resolution structure is available. We have grown crystals of mature but empty bacteriophage HK97 capsids that diffract to at least 3.5 A using synchrotron radiation. The HK97 Head II crystals are the first capsid crystals from a dsDNA bacteriophage that diffract X-rays to high resolution. A capsid precursor (prohead) was made in vivo by expressing capsid proteins in E. coli. This prohead was purified, converted to Head II in vitro, and used to grow crystals. The empty Head II has the same form as the mature HK97 capsid, but without DNA. The crystals were grown in a mixture of ammonium sulfate and PEG 8000, directly in an X-ray capillary to minimize crystal handling. The unit cell is monoclinic, with dimensions a = 580 A, b = 625 A, c = 790 A, beta = 90.0 degrees and two particles per unit cell.

Complexes between chaperonin GroEL and the capsid protein of bacteriophage HK97.

The 42 kDa capsid protein of bacteriophage HK97 requires the GroEL and GroES chaperonin proteins of its Escherichia coli host to facilitate correct folding, both in vivo and in vitro. In the absence of GroES and ATP, denatured gp5 forms a stable complex with the 14 subunit GroEL molecule. We characterized the electrophoretic and biochemical properties of this complex. In electrophoresis on a native (nondenaturing) gel, the band of the gp5-GroEL complex shifts to a slower migrating position relative to uncomplexed GroEL. The results show that there is only one subunit of gp5 bound to each GroEL 14-mer and that the shift in band position is due primarily to a change in the overall charge of the complex relative to uncomplexed GroEL, and not to a change in size or shape. GroEL forms similar complexes with proteolytic fragments of gp5, with a series of sequence duplication derivatives of gp5, and with other proteins. Electrophoretic examination of these complexes shows that a band shift occurs with proteins larger than 31-33 kDa but not with smaller proteins. For those proteins that cause a band shift upon complex formation, the magnitude of the shift is correlated with the predicted if the charge of the complex were simply the sum of the charge of GroEL and the charge of the substrate protein. We suggest that binding of a substrate protein to GroEL is accompanied by a net binding of solution cations to the complex, but only in the case of proteins above a minimum size of 31-33 kDa. The gp5-GroEL complex is in an association/dissociation equilibrium, with a binding constant measured in the range of 11-17 microM-1.

Proteolytic and conformational control of virus capsid maturation: the bacteriophage HK97 system.

Bacteriophage capsid assembly pathways provide excellent model systems to study large-scale conformational changes and other mechanisms that regulate the formation of macromolecular complexes. These capsids are formed from proheads: relatively fragile precursor particles which mature by undergoing extensive remodeling. Phage HK97 employs novel features in its strategy for building capsids, including assembly without a scaffolding protein, and the formation of a network of covalent cross-links between neighboring subunits in the mature virion. In addition, proteolytic cleavage of the capsid protein from 42 kDa to 31 kDa is essential for maturation. To investigate the structural bases for proteolysis and cross-linking, we have used cryo-electron micrographs to reconstruct the three-dimensional structures of purified particles from four discrete stages in the assembly pathway: Prohead I, Prohead II, Head I and Head II. Prohead I has icosahedral T = 7 packing of blister-shaped pentamers and hexamers. The pentamers are 5-fold symmetric, but the hexamers exhibit an unusual departure from 6-fold symmetry, as if two trimers had undergone a shear dislocation of about 25 A. Proteolytic conversion to Prohead II leaves the outer surface largely unchanged, but a major loss of density from the inner surface is observed, which we infer to represent the excision of the amino-terminal domains of the capsid protein. Upon expansion to the Head I state, the capsid becomes markedly larger, thinner walled, and more polyhedral: moreover, the capsomer shapes change radically; especially notable is the disappearance of the large hexon dislocation. No differences between Head I and the covalently cross-linked Head II could be observed at the current resolution of about 25 A, from which we infer that it is the conformational rearrangements effected by expansion that create the micro-environments needed for the autocatalytic formation of the isodipeptide bonds found in the mature virions ("pseudo-active sites").

Bacteriophage HK97 head assembly.

The head assembly pathway of bacteriophage HK97 shares many features with head assembly pathways determined for other dsDNA phages, and it also provides examples of novel variations on the basic theme. We describe aspects of two specific steps in the assembly pathway, the covalent cross-linking among the assembled head protein subunits and the cleavage of those subunits that takes place earlier in the pathway. Comparisons of head assembly pathways among different phages, as well as comparisons of the organization of the genes that specify those pathways, suggest the range of different solutions phages have found to common assembly problems and give insight into the evolutionary histories of these assembly processes.

Structural transitions during bacteriophage HK97 head assembly.

Bacteriophage HK97 builds its head shell from a 42 kDa major head protein, but neither this 42 kDa protein nor its processed, 31 kDa form is found in the mature head. Instead, each of the major head-protein subunits is covalently cross-linked into oligomers of five, six or more by a protein cross-linking reaction that occurs both in vivo and in vitro. Mutants that block prohead maturation lead to the accumulation of one of two types of proheads, termed Prohead I and Prohead II. Prohead I is assembled from about 415 copies of the 42 kDa (384 amino acids) protein subunit and accumulates in infections by mutant amU4. Following assembly, the N-terminal 102 amino acids of each subunit are removed, leaving a prohead shell constructed of 31 kDa subunits, called Prohead II, which accumulates in infections by mutant amC2. During DNA packaging, when the prohead shell expands, all of the head protein subunits become covalently cross-linked to other subunits. Purified Prohead II (or, less completely, Prohead I) becomes cross-linked in vitro in response to any of a number of conditions that induce shell expansion, including conditions commonly used for protein analysis. In vitro cross-linking occurs efficiently in the absence of added cofactors of enzymes, and we propose that cross-linking is catalyzed by shell subunits themselves. Shell expansion is easily monitored by observing a decrease in electrophoretic mobility of Prohead II in agarose gels. Using the mobility shift in agarose gel to monitor expansion and SDS/gel electrophoresis to monitor cross-linking in vitro, we find that expansion precedes and is required for cross-linking, and we propose that expansion triggers the cross-linking reaction. Comparison of peptides isolated from Prohead II and in vitro cross-linked Prohead II shows a single altered major cross-link peptide in which a lysine, originating from lysine169 of the protein sequence, is linked to asparagine356, presumably derived from the neighboring subunit. Examination of the cross-link-containing peptide by mass spectrometry shows that the cross-link bond is an amide between the side-chains of the lysine and the asparagine residues.

Genetic basis of bacteriophage HK97 prohead assembly.

We report studies to determine which bacteriophage genes are required for assembly of phage HK97 proheads and what roles they play. We identify the gene encoding the major capsid protein of phage HK97 and report its DNA sequence, together with the DNA sequences of the two genes immediately upstream from it. When the capsid protein is expressed from a plasmid in the absence of other phage-encoded proteins, it assembles, with good efficiency and accuracy into prohead-like structures composed of the unprocessed 42 kDa capsid protein. No separately encoded scaffolding protein is required for this assembly. If the 25 kDa product of the next gene upstream is co-expressed with the capsid protein, the prohead structures that are produced undergo the normal morphogenetic cleavage, which removes 102 amino acids from the N terminus of each subunit, leaving 31 kDa subunits. The 25 kDa protein is therefore probably a phage-encoded protease. The third gene, upstream from the protease gene, encodes the portal protein. Presence of the portal protein is not required for assembly of the capsid protein. Analysis of the phenotypes of four single amino acid-substitution mutants in the capsid-protein gene leads to several insights into the functions of the capsid protein and its interactions with the putative protease.

Bacteriophage lambda PaPa: not the mother of all lambda phages.

The common laboratory strain of bacteriophage lambda--lambda wild type or lambda PaPa--carries a frameshift mutation relative to Ur-lambda, the original isolate. The Ur-lambda virions have thin, jointed tail fibers that are absent from lambda wild type. Two novel proteins of Ur-lambda constitute the fibers: the product of stf, the gene that is disrupted in lambda wild type by the frameshift mutation, and the product of gene tfa, a protein that is implicated in facilitating tail fiber assembly. Relative to lambda wild type, Ur-lambda has expanded receptor specificity and adsorbs to Escherichia coli cells more rapidly.

Expression of plasmid-encoded structural proteins permits engineering of bacteriophage T4 assembly.

A complementation system for studying bacteriophage T4 tail assembly has been developed and used to test the effects of nonviable mutations on the function of a specific T4 tail protein, gp48. The complementation system assays the assembly function of gp48 without requiring that viable phage be produced, circumventing the operational problems of maintaining nonviable mutants of this lytic bacteriophage. The protein to be tested was preexpressed from cloned genes in a host cell prior to infection with the challenge phage. Assembly activity was assayed by monitoring the conversion of one tail assembly intermediate, the baseplate lacking gp48, into baseplates containing gp48 or into tube baseplates (or sheathed tails) assembled from such baseplates. Specific incorporation of gp48 into these structures was confirmed using gp48-specific antiserum, and the same serum was used in direct immunoelectron microscopy experiments to localize gp48 to the baseplate-proximal end of the T4 tail tube, at the site where the tube and sheath bind to the baseplate. The protein gp48 has been previously shown to be a baseplate protein, as well as a tail-tube-associated protein, and was tested for a possible role as a tail-length tape-measure protein. Tests with a deleted variant of gp48 were inconclusive because the protein was inactive. A variant of gp48, 20% longer than wild-type protein due to an internal duplication, was found to be partly functional in our assembly complementation system. This abnormally elongated protein allows several assembly steps to proceed, including the assembly of normal length T4 tails, implying that it does not specify tail length. The insertion-duplication variant of gp48 appears to have a defect in its interaction with the tail sheath protein, leading to abnormal sheath contraction.

Potential length determiner and DNA injection protein is extruded from bacteriophage T4 tail tubes in vitro.

Bacteriophage T4 tails contain a set of extended protein molecules in the central channel of the tail tube through which the DNA must exit during infection. Treatment of tails with guanidine hydrochloride separates the baseplates, leaving the tail tube and several specific tube-associated proteins. Methods were developed to purify these structures. Using specific antisera, immunoblotting, and electrophoretic analysis, these structures were shown to contain proteins gp19, 29, and 48. Electron microscopy showed specifically defined stain penetration into the tail tube, a bulge at one end, and a short fiber extruded from the tube. These structures could be removed by proteases but the gp19 tube itself was resistant. Structural studies of tails and intact phage show that the bulge and fiber are at the end of the tube that interacts with the cell membrane during infection. Since the fiber did not protrude from baseplates or from incomplete (short) tube-baseplates, we propose that it is first assembled as a compact structure formed of six copies of a tube-associated protein, which elongates during tail tube formation to fill the central channel, span the length of the tube, and regulate its length. We suggest that the exit of this fiber during infection signals DNA ejection.

Mass distribution of a probable tail-length-determining protein in bacteriophage T4.

Analysis of dark-field scanning transmission electron micrographs of unstained freeze-dried specimens established that the interior of the intact bacteriophage T4 tail tube contains extra density that is missing in tubes artificially emptied by treatment with 3 M guanidine hydrochloride. The mass of the tail tube is 3.1 X 10(6) daltons, and the central channel is 3.2 nm in diameter. Quantitative analysis of the density data is consistent with the presence of up to six strands of a protein molecule in the central channel that could serve as the template or ruler structure that determines the length of the bacteriophage tail and that could be injected into the cell with the phage DNA.

Evidence for an internal component of the bacteriophage T4D tail core: a possible length-determining template.

The length of the T4 tail is precisely regulated in vivo at the time of polymerization of the tail core protein onto the baseplate. Since no mutations which alter tail length have been identified, a study of in vivo-assembled tail cores was begun to determine whether the structural properties of assembled cores would reveal the mechanism of length regulation. An assembly intermediate consisting of a core attached to a baseplate (core-baseplate) was purified from cells infected with a T4 mutant in gene 15. When core-base plates were treated with guanidine hydrochloride, cores were released from baseplates. The released cores had the same mean length as cores attached to baseplates. Electron micrographs of these cores showed partial penetration of negative stain into one end, and, at the opposite end, a modified tip which often appeared as a short fiber projecting from the core. When cores were purified and analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, two minor proteins and the major core protein were detected. One minor protein, the product of gene 48 (gp48), was present in at least 72% of the amount found in core-baseplates, relative to the amount of the major core protein. These findings suggest that cores contain a fibrous structure, possibly composed of gp48, which may form a "ruler" that specifies the length of the T4 tail.