Role of the C-terminus in folding and oligomerization of bacteriophage T4 gene product 9

Bacteriophage T4 gene product 9 (gp9) is a structural protein of baseplate that plays a key role at the beginning of the infection process. Biologically active gp9 is a trimer that consists of three domains. It is a convenient model to study folding and oligomerization mechanisms of complex multidomain proteins. The influence of deletions and mutations of several amino acid residues in the C-terminal part of molecule on protein folding, oligomerization, and functional activity has been studied. It was determined that gp9 trimerization occurs post-translationally. It was shown that Gln282 and Ile284 are essential for gp9 trimer stabilization. The disruption of hydrogen bonds formed by Gln282 with Leu203 and Thr205 of neighboring chain has effect not only on interaction between monomers within trimer but also on folding of the polypeptide chain. Tsf (temperature sensitive for folding) and su (suppressor) mutations in the C-terminal region of the polypeptide chain affecting protein folding have been found.

Properties of the endolytic transglycosylase encoded by gene 144 of Pseudomonas aeruginosa bacteriophage phiKZ

Bacteriophage endolysins degrading bacterial cell walls are prospective enzymes for therapy of bacterial infections. The genome of the giant bacteriophage phiKZ of Pseudomonas aeruginosa encodes two endolysins, gene products (g.p.) 144 and 181, which are homologous to lytic transglycosylases. Gene 144 encoding a 260 amino acid residue protein was cloned into the plasmid expression vector. Recombinant g.p. 144 purified from Escherichia coli effectively degrades chloroform-treated P. aeruginosa cell walls. The protein has predominantly alpha-helical conformation and exists in solution in stoichiometric monomer : dimer : trimer equilibrium. Antibodies against the protein bind the phage particle. This demonstrates that g.p. 144 is a structural component of the phiKZ particle, presumably, a phage tail.

Functional Role of the N-Terminal Domain of Bacteriophage T4-Gene Product 11

Bacteriophage T4 late gene product 11 (gp11), the three-dimensional structure of which has been solved by us to 2.0 A resolution, is a part of the virus' baseplate. The gp11 polypeptide chain consists of 219 amino acid residues and the functionally active protein is a three-domain homotrimer. In this work, we have studied the role of gp11 N-terminal domain in the formation of a functionally active trimer. Deletion variants of gp11 and monoclonal antibodies recognizing the native conformation of gp11 trimer have been selected. Long deletions up to a complete removal of the N-terminal domain, containing 64 residues, do not affect the gp11 trimerization, but considerably change the protein structure and lead to the loss of its ability to incorporate into the baseplate. However, the deletion of the first 17 N-terminal residues results in functionally active protein that can complete the 11(-)-defective phage particles in in vitro complementation assay. This region of the polypeptide chain is probably essential for gp11-gp10 stable complex formation at the early stages of phage baseplate assembly in vivo. A study of the gp10 deletion variants suggests that the central domain of gp10 trimer is responsible for the interaction with gp11.

Molecular architecture of bacteriophage T4

In studying bacteriophage T4--one of the basic models of molecular biology for several decades--there has come a Renaissance, and this virus is now actively used as object of structural biology. The structures of six proteins of the phage particle have recently been determined at atomic resolution by X-ray crystallography. Three-dimensional reconstruction of the infection device--one of the most complex multiprotein components--has been developed on the basis of cryo-electron microscopy images. The further study of bacteriophage T4 structure will allow a better understanding of the regulation of protein folding, assembly of biological structures, and also mechanisms of functioning of the complex biological molecular machines.

Structure and morphogenesis of bacteriophage T4

Bacteriophage T4 is one of the most complex viruses. More than 40 different proteins form the mature virion, which consists of a protein shell encapsidating a 172-kbp double-stranded genomic DNA, a 'tail,' and fibers, attached to the distal end of the tail. The fibers and the tail carry the host cell recognition sensors and are required for attachment of the phage to the cell surface. The tail also serves as a channel for delivery of the phage DNA from the head into the host cell cytoplasm. The tail is attached to the unique 'portal' vertex of the head through which the phage DNA is packaged during head assembly. Similar to other phages, and also herpes viruses, the unique vertex is occupied by a dodecameric portal protein, which is involved in DNA packaging.

Engineering of bacteriophage T4 tail sheath protein

Gene product 18 (gp18, 659 amino acids) forms bacteriophage T4 contractile tail sheath. Recombinant protein assembles into different length polysheaths during expression in the cell, which complicates the preparation of protein crystals for its spatial structure determination. To design soluble monomeric gp18 mutants unable to form polysheaths and useful for crystallization, we have used Bal31 nuclease for generation deletions inside gene 18 encoding the Ile507-Gly530 region. Small deletions in the region of Ile507-Ile522 do not affect the protein assembly into polysheaths. Protein synthesis termination occurs because of reading frame failure in the location of deletions. Some fragments of gp18 containing short pseudo-accidental sequence in the C-terminal, while being soluble, have lost the ability for polysheath assembly. For the first time we succeeded in obtaining crystals of a soluble gp18 fragment containing 510 amino acids which, according to trypsin resistance, is similar to native protein monomer.

Chaperonin-mediated folding of bacteriophage T4 major capsid protein. II. Production of gene product 23 deletion mutants

Folding of bacteriophage T4 major capsid protein, gene product 23 (534 a.a.), is aided by two proteins: E. coli GroEL chaperonin and viral gp31 co-chaperonin. In the present work a set of mutants with extensive deletions inside gene 23 using controlled digestion with Bal31 nuclease has been constructed. Proteins with deletions were co-expressed from plasmid vectors with phage gp31 co-chaperonin. Deletions from 8 to 33 a.a. in the N-terminal region of the gp23 molecule covering the protein proteolytic cleavage site during capsid maturation have no influence on the mutants' ability to produce in E. coli cells proteins which form regular structures--polyheads. Deletions in other regions of the polypeptide chain (187-203 and 367-476 a.a.) disturb the correct folding and subsequent assembly of gp23 into polyheads.

Properties of bacteriophage T4 baseplate protein encoded by gene 8

Gene product 8 (gp8, 344 amino acids per monomer) of bacteriophage T4 is one of the baseplate structural proteins. We constructed an expression vector of gp8 and developed a method for purification of recombinant protein. CD spectroscopy showed that gp8 is an alpha/beta type structural protein. Its polypeptide chain consists of nearly 40% beta-structure and 15% alpha-helix. These data agree with results of prediction of secondary structure based on the amino acid sequence of the protein. The sedimentation coefficient under standard conditions (S20,w) is 4.6S. Analytical ultracentrifugation results demonstrated that gp8 in solution has two types of oligomers--dimer and tetramer. The tetramer of gp8 may be included in the wedge (1/6 of the baseplate), and the dimer may be an intermediate product of association.

Expression and properties of bacteriophage T4 gene product 11

A plasmid vector for expression of bacteriophage T4 gene product 11 (gp11) in E. coli cells has been constructed. Gp11 is a baseplate protein that connects short tail fibers providing irreversible adsorption of the virus on a cell. A method based on chromatography on hydroxyapatite has been developed for purification of recombinant gp11. The protein is active in an in vitro complementation assay and transforms defective phage particles lacking gp11 into infective ones. Gel filtration data suggest that the biologically active protein is a trimer. According to CD spectroscopy and sequence analysis data, the polypeptide chain of gp11 contains not less than 20% alpha-helical segments, about 30% beta-structure, and belongs to the class of alpha/beta structural proteins.

Transformation of a fragment of beta-structural bacteriophage T4 adhesin to stable alpha-helical trimer

Gene product 12 of bacteriophage T4, adhesin, serves to adhere the virus to host cells. Adhesin is a fibrous homotrimer, and a novel tertiary structure element, a beta-helix, is supposed to be a major structural feature of this protein. We have constructed two truncated gp12 mutants, 12N1 and 12N2, containing 221 and 135 N-terminal residues, respectively. When expressed in E. coli cells, these gp12 fragments formed labile beta-structural trimers. Another hybrid protein, 12FN, containing 179 N-terminal amino acid residues of gp12 fused to the C-terminal domain (31 amino acids) of T4 fibritin, was shown to have a trimeric proteolytically resistant alpha-helical structure. This structure is probably similar to that of fibritin, which has a triple alpha-helical coiled-coil structure. Hence, we have demonstrated the possibility of global transformation of fibrous protein structure using fusion with a C-terminal domain that initiates trimerization.

Structure and folding of bacteriophage T4 gene product 9 triggering infection. II. Study Of conformational changes of gene product 9 mutants using monoclonal antibodies

Gene product 9 (gp9) of bacteriophage T4, whose spatial structure we have recently solved to 2.3 A resolution, is a convenient model for studying the folding and oligomerization mechanisms of complex proteins. The gp9 polypeptide chain consists of 288 amino acids forming three domains. Three monomers, packed in parallel, assemble to a functionally active protein. The main aim of this work was to study conformational changes and trimerization of gp9 deletion mutants using monoclonal antibodies (mAbs). We selected a set of mAbs interacting with the amino, middle, and carboxyl regions of the protein, respectively. Eighteen mAbs bind to native as well as to denatured protein, and two mAbs bind to denatured protein only. Using mAbs, we found that deletions of the gp9 N-terminal region result in conformational changes in the middle and C-terminal domains. The study of mAb binding to the CDelta. truncated mutant by competitive ELISA and immunoblotting shows that the C-terminus of the gp9 sequence is essential for protein trimerization and stability. A single point substitution of the Gln282 residue causes formation of a labile trimer that has significant conformational changes in the protein domains. The results of our study show that folding and trimerization of gp9 is a cooperative process that involves all domains of the protein.

Structure of bacteriophage T4 gene product 11, the interface between the baseplate and short tail fibers

Bacteriophage T4, like all other viruses, is required to be stable while being transmitted from host to host, but also is poised to eject efficiently and rapidly its double-stranded DNA genome to initiate infection. The latter is coordinated by the recognition of receptors on Escherichia coli cells by the long tail fibers and subsequent irreversible attachment by the short tail fibers. These fibers are attached to the baseplate, a multi-subunit assembly at the distal end of the tail. Recognition and attachment induce a conformational transition of the baseplate from a hexagonal to a star-shaped structure. The crystal structure of gene product 11 (gp11), a protein that connects the short tail fibers to the baseplate, has been determined to 2.0 A resolution using multiple wavelength anomalous dispersion with Se. This structure is compared to the trimeric structure of gp9, which connects the baseplate with the long tail fibers. The structure of gp11 is a trimer with each monomer consisting of 218 residues folded into three domains. The N-terminal domains form a central, trimeric, parallel coiled coil surrounded by the middle "finger" domains. The fingers emanate from the carboxy-terminal beta-annulus domain, which, by comparison with the T4 whisker "fibritin" protein, is probably responsible for trimerization. The events leading from recognition of the host to the ejection of viral DNA must be communicated along the assembled trimeric (gp9)(3) attached to the long tail fibers via the trimeric baseplate protein (gp10)(3) to the trimeric (gp11)(3) and the trimeric short tail fibers.

Structure and folding of bacteriophage T4 gene product 9 triggering infection. I. Production and properties of recombinant protein

Gene product 9 (gp9, 288 amino acid residues per monomer, molecular weight 30.7 kD) of bacteriophage T4 triggers the baseplate reorganization and the sheath contraction after interaction of the long tail fibers with the receptors of the bacterial cell. In this work we have produced the recombinant protein and determined that gp9 is a stable homotrimer and active in in vitro complementation assay completing the defective phage particles which lack gp9. According to CD-spectroscopy data, the gp9 polypeptide chain contains 65-73% beta-structure and 11-16% alpha-helical segments, this being in good agreement with secondary structure prediction results. Additionally, we have constructed a set of plasmid vectors for expression of gp9 deletion mutants. The fragments with consecutive truncations of the N-terminus of the molecule, as well as the full-length protein, are trimers resistant to SDS treatment and decrease infective phage particle formation in in vitro complementation assay with native gp9. The deletion of the molecule C-terminal region results in failure of trimerization and decreases the stability of the protein.

The structure of bacteriophage T4 gene product 9: the trigger for tail contraction

BACKGROUND

The T4 bacteriophage consists of a head, filled with double-stranded DNA, and a complex contractile tail required for the ejection of the viral genome into the Escherichia coli host. The tail has a baseplate to whïch are attached six long and six short tail fibers. These fibers are the sensing devices for recognizing the host. When activated by attachment to cell receptors, the fibers cause a conformational transition in the baseplate and subsequently in the tail sheath, which initiates DNA ejection. The baseplate is a multisubunit complex of proteins encoded by 15 genes. Gene product 9 (gp9) is the protein that connects the long tail fibers to the baseplate and triggers the tail contraction after virus attachment to a host cell.

RESULTS

The crystal structure of recombinant gp9, determined to 2.3 A resolution, shows that the protein of 288 amino acid residues assembles as a homotrimer. The monomer consists of three domains: the N-terminal domain generates a triple coiled coil; the middle domain is a mixed, seven-stranded beta sandwich with a topology not previously observed; and the C-terminal domain is an eight-stranded, antiparallel beta sandwich having some resemblance to 'jelly-roll' viral capsid protein structures.

CONCLUSIONS

The biologically active form of gp9 is a trimer. The protein contains flexible interdomain hinges, which are presumably required to facilitate signal transmission between the long tail fibers and the baseplate. Structural and genetic analyses show that the C-terminal domain is bound to the baseplate, and the N-terminal coiled-coil domain is associated with the long tail fibers.

Polymerization of bacteriophage T4 tail sheath protein mutants truncated at the C-termini

Gene 18 of bacteriophage T4 encodes the contractile protein of the tail sheath. Previous work has shown that the full-length recombinant gene product (gp) 18 of 658 amino acid residues assembles in Escherichia coli cells into a long polysheath structure. However, the gp18 mutants truncated at the N-termini form insoluble aggregates similar to inclusion bodies. In this study, six plasmid vectors expressing the recombinant gp18 proteins truncated at the C-termini have been constructed. The CDelta58, CDelta129, CDelta152, C[g1]72, CDelta248, and CDelta287 proteins contain 600, 529, 506, 486, 410, and 371 residues of the full-length gp18 molecule, respectively. All the recombinant proteins were soluble and, except for the CDelta287 mutant, were assembled into polysheath-related structures. Electron microscopy of negatively stained purified proteins was performed and the resulting images were analyzed by computing their Fourier transforms. The CDelta58 and CDelta129 mutants, in addition to forming common contracted-type polysheath structures, assembled into thinner filaments that we called "noncontracted polysheaths" (NCP). The CDelta152, CDelta172, and CDelta248 proteins assembled into the NCP type only. Image processing showed that the NCP filaments significantly differ from both extended sheaths of T4 particle and polysheaths. The structure of the NCP filaments might correspond to the transitional helices postulated by Moody (J. Mol. Biol., 1973, 80, 613-636) that appeared during the process of tail contraction. Our results suggest that a short region at the C-terminus of the CDelta129 protein determines the contractile properties of the gp18 molecule. The shortest, the CDelta287 protein, does not assemble into regular structures, thus indicating that a sequence's stretch at the C-end of the CDelta248 mutant might be responsible for polymerization of gp18.

The carboxy-terminal domain initiates trimerization of bacteriophage T4 fibritin

Bacteriophage T4 fibritin is a triple-stranded, parallel, segmented alpha-helical coiled-coil protein. Earlier we showed that the C-terminal globular domain (foldon) of fibritin is essential for correct trimerization and folding of the protein. We constructed the chimerical fusion protein W31 in which the fibritin foldon sequence is followed by the small globular non-alpha-helical protein gp31 of the T4 phage. We showed that the foldon is capable of trimerization in the absence of the coiled-coil part of fibritin. A deletion mutant of fibritin (NB1) with completely deleted foldon is unable to fold and trimerize correctly. An excess of this mutant protein did not influence the refolding of fibritin in vitro, and the chimerical protein inhibited this process efficiently. Our conclusion is that the trimerization of the foldon is the initial step of fibritin refolding and is followed by the formation of the coiled-coil structure.

Co-expression of gene 31 and 23 products of bacteriophage T4

Folding of the major capsid protein of bacteriophage T4 encoded by gene 23 is aided by Escherichia coli GroEL chaperonin and phage co-chaperonin gp31. In the absence of gene product (gp) 31, aggregates of recombinant gp23 accumulate in the cell similar to inclusion bodies. These aggregates can be solubilized with 6 M urea. However, the protein cannot form regular structures in solution. A system of co-expression of gp31 and gp23 under the control of phage T7 promoter in E. coli cells has been constructed. Folding of entire-length gp23 (534 amino acid residues) in this system results in the correctly folded recombinant gp23, which forms long regular structures (polyheads) in the cell.

Structure of bacteriophage T4 fibritin M: a troublesome packing arrangement

Fibritin, a 52 kDa product of bacteriophage T4 gene wac, forms 530 A long fibers, named whiskers, that attach to the phage neck and perform a helper function during phage assembly. Fibritin is a homotrimer, with its predominant central domain consisting of 12 consecutive alpha-helical coiled-coil segments linked together by loops. The central domain is flanked by small globular domains at both ends. Fibritin M is a genetically engineered fragment of the wild type and contains 74 amino-acid residues corresponding to the last coiled-coil segment and the complete carboxy-terminal domain. The crystals of fibritin M belong to the rare space group P3 with three crystallographically independent trimers in the unit cell. The structure has been established at 1.85 A resolution by combining molecular and isomorphous replacement techniques. One of the two heavy-atom derivatives used was gaseous xenon. A substantial fraction of residues in each independent trimer is disordered to various extents in proportion to the lack of restraints on the molecules provided by the lattice contacts. Accurate modeling of the solvent present in the crystals was crucial for achieving good agreement with experimental data.

Properties of recombinant bacteriophage T4 tail sheath protein and its deletion fragments

A vector for expression of recombinant bacteriophage T4 tail sheath protein (gp18) under control of phage T7 promoter in Escherichia coli cells has been constructed. The entire length recombinant gp18 (659 amino acids) polymerizes in vivo into extended polysheaths. To study gp18 folding mechanisms, six vectors for expression of deletion mutants have been constructed. Three proteins--1N, 2N, and 3N--contain, respectively, 268, 316, and 372 amino acids of the gp18 N-tail region. The other three fragments--1C, 2C, and 3C--contain, respectively, 455, 356, and 288 amino acids of the gp18 C-tail. The fragments 1N, 2N, 1C, 2C, and 3C form insoluble aggregates during expression. However, fragment 3N accumulates in soluble form in the cellular cytoplasm and does not form polymeric structures; this has allowed an effective purification method to be developed for it. The interaction of monoclonal antibodies against recombinant gp18 with protein fragments and with phage sheath before and after contraction has been studied. The fragment 3N seems to be a stable domain of native phage sheath gp18.

Chaperones in bacteriophage T4 assembly

Protein folding in the cell is controlled at the levels of translation and post-translational modification, depends on a number of conserved proteins known as chaperones, and is catalyzed by specific enzymes, such as protein disulfide isomerase and peptidyl prolyl cis-trans isomerase. The chaperones stabilize folding intermediates and participate in assembly and disaggregation of supramolecular structures. Bacteriophage T4 is an especially convenient system for studying of protein folding mechanisms, since its genome encodes several virus-specific chaperones. In this review, the chaperones of phage T4 that take part in capsid formation (gp31 and gp40) and in folding and assembly of virion tail fibers (gp38, gp57A) have been considered. Protein encoded by gene 31 completely substitutes co-chaperonin GroES of the host cell in folding of the major capsid protein, gp23, aided by chaperonin GroEL. The product of gene 40, which is homologous to analogs of eukaryotic GroEL and peptidyl prolyl cis-trans isomerase, participates in assembly of gp20 while the formation of procapsid connector. The chaperone encoded by gene 57A is essential for folding and oligomerization of both long and short phage tail fibers. gp38, together with gp57A, participates in the formation of the distal part of the long fibers. This protein seems to represent a principally new group of chaperones that change steric structure of folded polypeptide. One phage chaperone, fibritin, encoded by gene wac (whiskers antigen control) and taking part in assembly the subunits of the long tail fibers is a constituent of the virion. Fibritin is a convenient model for studying mechanisms of folding and oligomerization of fibrous proteins due to its labile triple-stranded alpha-helical coiled-coil structure.

Engineering trimeric fibrous proteins based on bacteriophage T4 adhesins

The adsorption specificity of bacteriophage T4 is determined by genes 12 and 37, encoding the short tail-fibers (STF) and the distal part of the long tail-fibers (LTF), respectively. Both are trimeric proteins with rod domains made up of similar tandem quasi-repeats, approximately 40 amino acids long. Their assembly requires the viral chaperones gp57A and gp38. Here we report that fusing fragments of gp12 and gp37 to another trimeric T4 fibrous protein, fibritin, facilitates correct assembly, thereby by-passing the chaperone requirement. Fibritin is an alpha-helical coiled coil protein whose C-terminal part (fibritin E, comprising the last 120 residues) has recently been solved to atomic resolution. Gp12 fragments of 109 and 70 amino acids, corresponding to three and two quasi-repeats respectively, were fused to the C-terminus of fibritin E. A similar chimera was designed for the last 63 residues of gp37, which contain four copies of the pentapeptide Gly-X-His-X-His and assume a narrow rigid structure in the LTF distal tip. Expressed from plasmids, all three chimeras form soluble trimers that are resistant to dissociation by SDS and digestion by trypsin, indicative of correct folding and oligomerization.

The 'adenobody' approach to viral targeting: specific and enhanced adenoviral gene delivery

Recombinant adenoviruses have enormous potential as vectors for gene therapy. They have evolved an efficient method of infection and a wide host range but this leads to concerns about the specificity of gene delivery. In order to target an adenovirus type 5-based vector we have investigated an antibody approach. A virus neutralising scFv antibody fragment was isolated from a phage library and a C-terminal fusion protein with epidermal growth factor (EGF) constructed. This fusion protein, or 'adenobody', bound both to the fibre protein of the adenovirus and to the EGF receptor (EGFR) on human cells, and was able to direct adenoviral binding to the new receptor. Using this system the efficiency of viral infection was markedly enhanced and was targeted to the EGFR. The adenobody-directed infection correlated with the level of EGF receptor expressed on the cells and could be blocked by competition with pure EGF. Peptide inhibition experiments suggest that infection is mediated directly through attachment to the EGFR and does not require penton-integrin interactions. This work shows that the 'adenobody' approach can enhance the efficiency as well as target adenoviral infection and has numerous potential applications for gene therapy.

Structure of bacteriophage T4 fibritin: a segmented coiled coil and the role of the C-terminal domain

BACKGROUND

Oligomeric coiled-coil motifs are found in numerous protein structures; among them is fibritin, a structural protein of bacteriophage T4, which belongs to a class of chaperones that catalyze a specific phage-assembly process. Fibritin promotes the assembly of the long tail fibers and their subsequent attachment to the tail baseplate; it is also a sensing device that controls the retraction of the long tail fibers in adverse environments and, thus, prevents infection. The structure of fibritin had been predicted from sequence and biochemical analyses to be mainly a triple-helical coiled coil. The determination of its structure at atomic resolution was expected to give insights into the assembly process and biological function of fibritin, and the properties of modified coiled-coil structures in general.

RESULTS

The three-dimensional structure of fibritin E, a deletion mutant of wild-type fibritin, was determined to 2.2 A resolution by X-ray crystallography. Three identical subunits of 119 amino acid residues form a trimeric parallel coiled-coil domain and a small globular C-terminal domain about a crystallographic threefold axis. The coiled-coil domain is divided into three segments that are separated by insertion loops. The C-terminal domain, which consists of 30 residues from each subunit, contains a beta-propeller-like structure with a hydrophobic interior.

CONCLUSIONS

The residues within the C-terminal domain make extensive hydrophobic and some polar intersubunit interactions. This is consistent with the C-terminal domain being important for the correct assembly of fibritin, as shown earlier by mutational studies. Tight interactions between the C-terminal residues of adjacent subunits counteract the latent instability that is suggested by the structural properties of the coiled-coil segments. Trimerization is likely to begin with the formation of the C-terminal domain which subsequently initiates the assembly of the coiled coil. The interplay between the stabilizing effect of the C-terminal domain and the labile coiled-coil domain may be essential for the fibritin function and for the correct functioning of many other alpha-fibrous proteins.

A member of the immunoglobulin superfamily in bacteriophage T4

We report a prediction that the highly immunogenic outer capsid (Hoc) protein of the prokaryotic phage T4 contains three tandem immunoglobulin-like domains. Immunoglobulin-like folds have previously been identified in prokaryotic proteins but these share no recognizable sequence similarity with eukaryotic immunoglobulin superfamily (IgSF) folds, and may represent products of convergent evolution. In contrast, the Hoc immunoglobulin-like folds are proposed, based on immunoglobulin-like sequence consensus matches detected by hidden Markov modeling. We propose that the Hoc immunoglobulin-like domains and eukaryotic immunoglobulin-like domains are likely to be related by divergence from a common ancestor.

Preliminary crystallographic studies of bacteriophage T4 fibritin confirm a trimeric coiled-coil structure

Fibritin, a 52-kDa product of gene wac of bacteriophage T4, forms fibrous "whiskers" that connect to the phage tail and facilitate the later stages of phage assembly. Preliminary experiments suggest that fibritin is a trimer, and its predominant central part has a parallel alpha-helical coiled-coil structure. To investigate the oligomerization and function of fibritin, we have designed and studied two related deletion mutants, denoted M and E, that consist of its last 75 and 120 amino acids, respectively. Both proteins contain part of the coiled-coil region and the 29 amino acid carboxy-terminal domain essential for the trimerization of fibritin. The proteins are expressed as a soluble product in an Escherichia coli system. We have obtained crystals of fibritins M and E. Complete native X-ray diffraction data sets have been collected to 1.85 and 2.7 A resolution, respectively. The crystals have space group P3 with a=44.3 A, c=91.3 A (fibritin M) and R32 with a=41.2 A, b=358.7 A (fibritin E) in the hexagonal setting. Symmetry and packing considerations show that fibritin is a triple coiled coil.

Bacteriophage T4 as a surface display vector

We describe a method for construction of hymeric bacteriophage T4 particles displaying foreign polypeptides on their surface. The method is based on our finding that minor T4 fibrous protein fibritin encoded by gene wac (whisker's antigen control) could be lengthened at the C terminus without impairing its folding or binding to the phage particle. The lengthened fibritin gene could easily be transferred into the T4 genome by homologous recombination with a plasmid containing the modified gene wac. The modified gene wac is expressed properly during phage reproduction, and the lengthened fibritin is bound to phage particles. As an example of this type of method, we have obtained the hymeric T4 particles carrying a polypeptide of 53 residues, 45 of which are from the pre-S2 region of hepatitis B virus. The T4 display vector extends currently available display systems.

In vitro maturation of prehead-like bacteriophage T4 polyheads: structural changes accompanying proteolytic cleavage and lattice expansion

We have studied cleavage and expansion of the major T4 phage capsid protein gp23 (56 kDa) using polyheads, an aberrant, polymorphic tubular variant of bacteriophage T4D, as a model system. In a first step, we have cleaved the 65-amino-acid-long amino-terminal "delta piece" by limited proteolysis with Staphylococcus aureus V8 protease (type XVII) at exactly the same position, i.e., between residues 65 and 66, at which the phage-coded T4Ppase cleaves, to yield mature gp23* (48.7 kDa) without significantly affecting a second potential cleavage site between amino acids 142 and 143. Negatively stained preparations of thus cleaved polyheads revealed a near-hexagonal lattice with a 11.2-nm lattice constant. One-sided correlation averages of these cleaved/unexpanded polyheads yielded capsomeres that were rounder than those of prehead-like (i.e., uncleaved) control polyheads, with distinct trimers of mass (specifically, trimers of delta pieces in the area where three protomers are shared among three different capsomeres) removed, as revealed by difference maps computed from the correlation averages. Quantitative expansion of the 11.2-nm near-hexagonal lattice into the 13-nm near-hexagonal lattice characteristic of mature phage heads could be induced by pelleting the cleaved/unexpanded polyheads and resuspending them in water. This expansion step was inhibited by the presence of 100 mM phosphate. Cleavage of prehead-like polyheads to the 41-kDa gp23+ either between residues 142 and 143 by V8 protease or between residues 143 and 144 by trypsin rendered the polyheads unable to expand. In contrast, cleaved/expanded gp23* polyheads became resistant to cleavage to gp23+. As revealed by difference maps, the 7.3-kDa mass was additionally missing at the corners where the delta-piece trimers contact the protomers.

Crystallization and preliminary crystallographic characterization of bacteriophage T4 baseplate protein encoded by gene 9

The structural protein, gene product 9 (gp9), of bacteriophage T4 controls baseplate expansion at the first steps of virus attachment onto its host bacterial cell with subsequent tail contraction. Gp9, which has an M(r) of 30.8 kDa and contains 287 amino acids, has been purified from a recombinant Escherichia coli strain and crystallized at 25 degrees C using the hanging drop vapor diffusion method at pH 4.0 with ammonium sulfate as precipitant. The crystals of gp9 belong to the space group R32 with hexagonal cell dimensions a = b = 86.5 A and c = 156.2 A and diffract X-rays to at least 2.7 A. There is one molecule per asymmetric unit.

The short tail-fiber of bacteriophage T4: molecular structure and a mechanism for its conformational transition

Electron microscopy, image processing and computational sequence analysis were used to investigate the structure of the short tail-fiber of bacteriophage T4. This molecule, an oligomer of gp12, is an adhesin that binds the virion irreversibly to the bacterial surface. Short tail-fibers were isolated from mutant-infected cells in which gp12 is synthesized and assembled correctly, but not incorporated into virions. Visualized in negative stain, these filamentous molecules are approximately 38 nm in total length, with an arrowhead-shaped head (approximately 10 nm long by 6 nm wide), a 24-nm shaft of uniform width (approximately 3.8 nm), and a small, seemingly flexible, tail. The primary sequence contains a domain consisting of tandem quasi-repeats, each about 40 residues long, extending from approximately residue 50 to residue 320. Molecular mass analyses by scanning transmission electron microscopy confirm that the molecule is a trimer. The masses of the head, shaft, and tail domains are consistent with (trimers of) the carboxy-terminus, the repeat region, and the amino-terminus, respectively. When short tail-fibers are visualized extending from baseplates, their heads are distal, i.e., detached, implying that it is the tail that remains in contact with the baseplate. Analysis of the molecules' curvature properties detects three hinge-sites: these suggest how the short tail-fiber may be initially accommodated in a compact conformation in the "hexagon" state of the baseplate, from which it converts to the extended conformation when the baseplate switches into its "star" state.

The wac gene product of bacteriophage T4 contains coiled-coil structural patterns

The bacteriophage T4 late gene wac (whisker antigen control) encodes the protein which forms the fibrous structure on the neck of the virion called whiskers. Amino acid sequence analysis of wac gene product, as deduced from the nucleotide sequence, indicate ten alpha-helical domains (19-40 residues long) with coiled-coil structural patterns. These regions comprise about 70% of the entire 486 amino acid sequence. The alpha-helices are separated by short stretches of polypeptide chain which are similar to the loop regions of the globular protein sequences. We propose a structural model for the dimer of wac gene product molecule, that we call fibritin in which two polypeptide chains associate in a parallel fashion and form a segmented alpha-helical coiled-coil rod similar to epidermal keratins.

A proposed structure of bacteriophage T4 gene product 22--a major prohead scaffolding core protein

Gene 22 of bacteriophage T4 encodes a major prohead scaffolding core protein of 269 amino acid residues. From its nucleotide sequence the gene product (gp) 22 has a predicted Mr of 29.9 and a pI of 4.3. The protein is rich in charged residues (glutamic acid and lysine) and contains low amounts of proline and glycine and no cysteine residues. We suggest that gp22 undergoes limited proteolytic processing which eliminates the short C-terminal piece from the molecule during the early steps of prohead assembly. Most amino acid residues of the gp22 polypeptide chain (80%) have an alpha-helical conformation and form seven peculiar alpha-helices. A model suggesting the spatial organization of gp22 is presented. Three long alpha-helices numbered 1 (1A and 1B), 3, and 5 (5A and 5B) are packed in an antiparallel fashion along the major axis of the road-shaped molecule. Two rather short alpha-helices (2 and 4) are located at the distal and proximal ends of the protein molecule, respectively. Helix number 2, which is a proteolytic fragment of gp22 found in mature T4 heads, is packed with helices 1A and 3, similar to a novel element of supersecondary structure, the alpha alpha-corner. Helix number 4 probably interacts with the gp20 connector of the prohead. The implications of the structure of the gp22 molecule for the assembly of the prohead core are discussed.

Cascade of overlapping late genes in bacteriophage T4

The DNA sequences of genes 9, 10, 11, 12, and wac, which encode the structural proteins in the bacteriophage T4 base plate, were determined. These genes form a single operon which is transcribed in a clockwise direction from a single late promoter in the TATAAATA region located upstream of gene 9 at position -10. A feature of the operon is an overlap between the termination codon of each upstream gene and the initiation codon of its downstream gene. With the exception of gene 10, the open reading frames encode proteins which have a calculated molecular mass close to that obtained experimentally. The reading frame of gene 10 encodes a polypeptide with a calculated molecular mass of 66.2 kDa, which is at least 22 kDa less than that in the phage particle. Thus the mature protein encoded by gene 10 is possibly a product of the fusion of two adjacent phage genes. The hybrid protein may be formed by a frameshift during the translation of messenger RNA at the end of gene 9 or gene 10.

Monomeric (7S) and polymeric (19S) IgM anti-delta in acute and chronic delta infections

The chromatographic profiles of IgM anti-delta in 45 acute and 24 chronic delta patients were analyzed by fast protein liquid chromatography (FPLC). Predominance of 19S IgM anti-delta was observed in the sera of 100 percent of coinfected and 62% of superinfected patients. In contrast, 7S IgM anti-delta was predominant in 83% of patients with chronic hepatitis delta. The study of the chromatographic profiles of IgM anti-delta in the development of the disease showed an association between the process of chronic delta-infection and the failure of 7S IgM anti-delta monomers to form 19S pentamers. The results showed that the test for 7S and 19S IgM anti-delta could be useful for differential diagnosis of acute and chronic hepatitis delta infection and for determining the prognosis of acute delta infection.

Prediction of secondary structure, spatial organization and distribution of antigenic determinants for hepatitis A virus proteins

On the basis of the secondary structure calculations from the known amino acid sequence we came to the conclusion that hepatitis A virus capsid proteins have the typical antiparallel beta-sheet bilayer structure. The predicted secondary structure of the HAV proteins can be well aligned with those of the poliovirus (type 1 Mahoney) and human rhinovirus (type 14). It enabled us to use the X-ray structure of the PV-1M and HRV-14 proteins as a template and then, firstly, to localize the positions of alpha and beta regions in the architecture of the HAV protein molecules and, secondly, to discover the amino acid homologies of the secondary structure regions aligned. The obtained model of the three-dimensional structure for HAV proteins helped us to indicate the exposed regions of the polypeptide chains and to pinpoint the potential neutralizing antigenic sites.