The distal half of the tail fibre of bacteriophage T4. Rigidly linked domains and cross-beta structure

Bacteriophage T4 long tail fiber domains

Bacteriophage T4 initially recognizes its host cells using its long tail fibers. Long tail fibers consist of a phage-proximal and a phage-distal rod, each around 80 nm long and attached to each other at a slight angle. The phage-proximal rod is formed by a homo-trimer of gene product 34 (gp34) and is attached to the phage-distal rod by a monomer of gp35. The phage-distal rod consists of two protein trimers: a trimer of gp36, attached to gp35, although most of the phage-distal rod, including the receptor-binding domain, is formed by a trimer of gp37. In this review, we discuss what is known about the detailed structure and function of the different long tail fiber domains. Partial crystal structures of gp34 and gp37 have revealed the presence of new protein folds, some of which are present in several repeats, while others are apparently unique. Gp38, a phage chaperone protein necessary for folding of gp37, is thought to act on an α-helical coiled-coil region in gp37. Future studies should reveal the remaining structure of the long tail fibers, how they assemble into a functional unit, and how the long tail fibers trigger the infection process after successful recognition of a suitable host bacterium.

A molecular model of the amyloid fibril

We have investigated the ultrastructure of the homozygous amyloid fibrils from the vitreous humour of patients with Met30 familial amyloidotic polyneuropathy (FAP) by high-resolution electron microscopy and X-ray diffraction using synchrotron radiation. Image reconstruction of thin sections of Met30 FAP fibrils shows that they are composed of four parallel protofilaments, 50-60 A in diameter, arranged in a square around a hollow centre. The X-ray diffraction patterns are consistent with the presence in the protofilaments of a repeating unit of 24 beta-strands forming a continuous beta-sheet extended along the fibre axis, with the beta-strands perpendicular to the axis. We have characterized this repeat unit as one turn of a beta-sheet helix. This newly-described helix reconciles the classical cross-beta structure of amyloid with the twisted beta-sheet that is known to be the most stable form of the structure. All four beta-sheets composing the protofilament twist around a single helical axis which is coincident with the axis of the protofilament. Other amyloid diffraction patterns are similar to that of FAP, suggesting that the beta-sheet helix may be the generic core structure of amyloid.

In vivo bypass of chaperone by extended coiled-coil motif in T4 tail fiber

The distal-half tail fiber of bacteriophage T4 is made of three gene products: trimeric gp36 and gp37 and monomeric gp35. Chaperone P38 is normally required for folding gp37 peptides into a P37 trimer; however, a temperature-sensitive mutation in T4 (ts3813) that suppresses this requirement at 30 degrees C but not at 42 degrees C was found in gene 37 (R. J. Bishop and W. B. Wood, Virology 72:244-254, 1976). Sequencing of the temperature-sensitive mutant revealed a 21-bp duplication of wild-type gene 37 inserted into its C-terminal portion (S. Hashemolhosseini et al., J. Mol. Biol. 241:524-533, 1994). We noticed that the 21-amino-acid segment encompassing this duplication in the ts3813 mutant has a sequence typical of a coiled coil and hypothesized that its extension would relieve the temperature sensitivity of the ts3813 mutation. To test our hypothesis, we crossed the T4 ts3813 mutant with a plasmid encoding an engineered pentaheptad coiled coil. Each of the six mutants that we examined retained two amber mutations in gene 38 and had a different coiled-coil sequence varying from three to five heptads. While the sequences varied, all maintained the heptad-repeating coiled-coil motif and produced plaques at up to 50 degrees C. This finding strongly suggests that the coiled-coil motif is a critical factor in the folding of gp37. The presence of a terminal coiled-coil-like sequence in the tail fiber genes of 17 additional T-even phages implies the conservation of this mechanism. The increased melting temperature should be useful for "clamps" to initiate the folding of trimeric beta-helices in vitro and as an in vivo screen to identify, sequence, and characterize trimeric coiled coils.

Design of protein struts for self-assembling nanoconstructs

Bacteriophage T4 tail fibers have a quaternary structure of bent rigid rods, 3 x 160 nm in size. The four proteins which make up these organelles are able to self-assemble in an essentially irreversible manner. To use the self-assembly domains of these proteins as elements in construction of mesoscale structures, we must be able to rearrange these domains without affecting the self-assembly properties and add internal binding sites for other functional elements. Here we present results on several alterations of the P37 component of the T4 tail fiber that change its length and add novel protein sequences into the protein. One of these sequences is an antibody binding site that is used to inactivate phage carrying the modified gene.

Overproduced and purified receptor binding protein pb5 of bacteriophage T5 binds to the T5 receptor protein FhuA

A promotor-less oad gene of bacteriophage T5, encoding the receptor binding protein pb5, was cloned into pT7-3 under the control of phage T7 promoter phi 10. Induction with IPTG resulted in enhanced production of pb5. Upon fractionation of the producing cells, most of the overproduced pb5 was found in the membrane fraction, which was most likely due to aggregation of the protein. The minor, soluble fraction of pb5 specifically inhibited adsorption of T5 to its FhuA receptor protein. Inhibition was also seen with trace amounts of pb5, and binding of pb5 to FhuA appeared to be almost irreversible. Purification of pb5 from the cytosolic fraction was performed by FPLC using a MonoQ column. pb5, which did not bind to the matrix of the column, was obtained in almost pure form. The purified protein also inhibited T5 adsorption.

Structure of beta-crystallite assemblies formed by Alzheimer beta-amyloid protein analogues: analysis by x-ray diffraction

To elucidate the relation between amyloid fibril formation in Alzheimer disease and the primary structure of the beta/A4 protein, which is the major component of the amyloid, we have been investigating the ability of peptides sharing sequences with beta/A4 to form fibrils in vitro. In previous studies we focused on the macroscopic morphology of the assemblies formed by synthetic peptides corresponding in sequence to different regions of this protein. In the present study we analyze the x-ray diffraction patterns obtained from these assemblies. All specimens showed wide angle reflections that could be indexed by an orthogonal lattice of beta-crystallites having unit cell dimensions a = 9.4 A, b = 7 A, and c = 10 A, where a refers to hydrogen bonding direction, b to polypeptide chain direction, and c to intersheet direction. Given the amino acid sequence of beta/A4 as NH2-DAEFRHDSGYEVHHQKLVFFAEDVGSNKGAIIGLMVGGVVIAT-COOH, we found that, based on their orientation and assembly, the analogues could be classified into three groups: Group A, residues 19-28, 13-28, 12-28, 11-28, 9-28, 1-28, 1-38, 1-40, 6-25, 11-25 and 34-42; Group B, residues 18-28, 17-28, and 15-28; and Group C, residues 22-35 and 26-33. For Groups A and C, the sharpest reflections were (h00), indicating that the assemblies were fibrillar, i.e., elongated in a single direction. Lateral alignment of the crystallites in Group A account for its cross-beta pattern, in which the hydrogen bonding (H-bonding) direction is the fiber (rotation) axis. By comparison, the beta-crystallites of Group C had no preferential orientation, thus giving circular scattering. For Group B, the sharpest reflections were (h0l) on the meridian, indicating that the assemblies were plate-like, i.e., extended in two directions. A series of equatorial Bragg reflections having a 40 A period indicated regular stacking of the plates, and the rotation axis was normal to the surface of the plates. Of the Group A peptides, the analogues 11-28 and 6-25 showed intensity maxima on the equator as well as on higher layer lines, indicating that the beta-crystallites are highly ordered relative to one another in the axial, H-bonding direction. This sampling of the layer lines by a larger period (60 A) suggests that the beta-crystallites are arrayed either in cylindrical or small restricted crystalline lattices. Consistent with its electron microscopic images, we modeled the structure as a tube with five or six f,-crystallites constituting the wall and with the individual crystallite, which either rotates freely or is restricted, made of five or fewer beta-pleated sheets. For the Group B peptides, the electron density projection along the b-axis was calculated from the observed intensities using phase combinations from fl-keratin.Amino acid side-chain positions were apparent and, when refined as 4-A-diameter spheres, led to a substantial decrease in the R-factors.For peptide 18-28 the electron density peaks, which are thought to correspond to side chains, were centered 3.3 A from the peptide backbone, whereas for peptides 17-28 and 15-28, these peaks were centered 1 A or more further from the backbone. Peaks having high electron density faced peaks having lower density, suggesting a favorable stereochemical arrangement of the residues. Thus, our analysis of the fiber x-ray patterns from beta/A4 peptides shows the organization of the beta-crystallites that form the wall of the amyloid fibrils as well as possible side-chain interactions.

High resolution biological scanning electron microscopy: a comparative study of low temperature metal coating techniques

Structural information on the surface of biological specimens can be resolved within molecular dimensions by "in-lens" field emission scanning electron microscopes when cryo-methods are used to adequately preserve the native state of the specimen. The visual definition of molecular surface structures depends largely on the metal coating. The thickness of the coating, as well as the temperature at which it is deposited, are among the most important parameters affecting visual definition. These were evaluated on T4 polyheads and T4D phages using chromium double-axis rotary shadowing (DARS). Micrographs of optimally DARS coated T4 polyheads and T4D phages were compared with chromium planar-magnetron sputtering (PMS) and unidirectional shadowing with platinum/carbon. Metal deposition was carried out at low temperatures during all three procedures. Optimal visual definition of structural details on the surface of DARS coated T4 polyheads and T4D phages (capsomeres of T4 polyheads and their subunits with diameters of 8 and 3 nm; T4D phage tail fibres with a thickness of 3 nm) is achieved at a thickness of the chromium film greater than the minimum required for metal film coalescence. Chromium DARS coating at room temperature resulted in poor structural definition, whereas DARS at specimen temperatures of -85 degrees C and -150 degrees C, with the chromium thickness optimized for each temperature, yielded good visual detail of polyhead substructures. The visual definition was slightly reduced when DARS coating was carried out at a specimen temperature of -250 degrees C. Adequate structural visibility of T4D phage and T4 polyhead surface structures was achieved with the three coating techniques tested.(ABSTRACT TRUNCATED AT 250 WORDS)

Requirement of the SecB chaperone for export of a non-secretory polypeptide in Escherichia coli

The SecB protein of Escherichia coli is a cytosolic component of the export machinery which can prevent some precursors from prematurely folding into export-incompatible conformations by binding to the newly synthesised polypeptide. The feature(s) of target proteins recognised by SecB, however, are unclear and have been a matter of controversy. Also, it has not been asked if binding of SecB is specific for secretory proteins. We demonstrate here that a non-secretory polypeptide, a fragment of a tail fiber protein of phage T4, fused to the signal peptide of the outer membrane protein OmpA has a very strong SecB requirement for export and that the signal peptide itself cannot, at least not alone, be responsible for this action of SecB. The data reported, together with those of the literature, suggest that SecB recognizes the polypeptide backbone of the target protein.

Structure of adenovirus fibre. I. Analysis of crystals of fibre from adenovirus serotypes 2 and 5 by electron microscopy and X-ray crystallography

An analysis by electron microscopy in amorphous ice and X-ray diffraction of four types of three-dimensional crystals of adenovirus fibre is presented. Fibre from adenovirus type 2 (Ad2) crystallizes in two forms depending on whether it is native or cleaved near the N terminus at Tyr17. Fibre from Ad5 also crystallizes in two forms, both of which contained fibre cleaved at Tyr17. Analysis of the packing of the fibres in each of these crystals suggests that the overall length of the fibre may be considerably longer (about 350 to 370 A) than previously reported. Crystals of cleaved Ad2 fibre are of sufficient quality to be characterized by X-ray diffraction. They are of space group C2 and cell dimensions a = 134.4 A, b = 77.6 A, c = 539.4 A, beta = 92.7 degrees. These crystals are remarkable in that, despite being monoclinic, the ab plane forms a perfect hexagonal lattice. This is explained by a trigonal packing of the trimeric fibre heads in the crystal. A similar feature is found for one type of Ad5 crystal, although the hexagonal lattice is 12% smaller. The crystals of cleaved Ad2 show very strong meridional intensity at a Bragg spacing of 4.4 A and weaker diffuse intensity corresponding to layer-lines of spacing 26.4 A. This must reflect the quasiperiodicity of the structure of the fibre shaft, which is apparent in the primary sequence. The occurrence of these features combined with the new determination of the length of the fibre (see also the accompanying paper) require a reappraisal of the cross-beta model of the fibre shaft proposed by Green et al.

Structure of adenovirus fibre. II. Morphology of single fibres

Adenovirus type 2 fibres in crystals appear to be significantly longer than found previously (accompanying paper). We therefore examined isolated fibre by electron microscopy and measured a length of 370 A, consistent with the length found in the crystals. The specific N-terminal structure of the fibre caused a heterogeneity in the length that may at least partially explain the values of 280 to 310 A published previously. Green et al. described a 15 amino acid repeat in the primary structure of the shaft of the fibre thought to be associated with the specific three-dimensional folding of the shaft. We compared the adenovirus type 2 (with 22 repeats) and type 3 (with 6 repeats) fibre lengths and derived a contribution of 13.2 A to the length of the shaft per 15 amino acid repeat. Specific morphological features of the fibre are discussed in relation to its amino acid sequence.

Molecular structure of the cell-attachment protein of reovirus: correlation of computer-processed electron micrographs with sequence-based predictions

The receptor-recognition interaction that initiates reovirus infection is mediated by the sigma 1 protein, located at the vertices of the icosahedral virion. We have applied computer-based image-averaging techniques to electron micrographs of negatively stained preparations of sigma 1 purified from virions (serotype 2 Jones). Combining these results with inferences based on the amino acid sequence has led to a molecular model in which the overall folding of the chains is described; its conformation embodies motifs, coiled-coil alpha-helices and nodular multichain elements rich in beta-sheets, previously detected in the corresponding proteins of other viruses, but with some novel variations. Sigma 1 is a filamentous lollipop-shaped molecule with an overall length of approximately 48 nm; it has a flexible "tail," approximately 40 nm long by 4 to 6 nm wide, terminating at its distal end in a globular "head," approximately 9.5 nm in diameter. The purified protein is a tetramer (4 by 50 kilodaltons) consisting of two similarly oriented dimers bonded side by side and in register. For each chain, a cluster of hydrophobic residues at its amino terminus resides at the proximal end of the tail; next, an alpha-helical domain (residues 25 to 172) participates in a two-chained coiled coil, 22 nm long, with two such coiled coils pairing laterally to form the proximal half of the tail. The remainder of the tail (residues 173 to approximately 316) is less uniform in width and is expected to be rich in beta-sheet; the interdimer bonding is evidently sustained through this portion of the molecule. Finally, the globular head consists of the carboxy-terminal domains (which contain the receptor-binding sites) folded into compact globular conformations; in appropriate side views, the head is resolved into two subunits, presumably contributed by the respective dimers. This model for how the four sigma 1 polypeptide chains are threaded in parallel through the fiber is supported by the observed match between an empirical curvature profile, which identifies the locations of relatively flexible sites along the tail, and the flexibility profile predicted on the basis of the model. Appraisal of the interactions that stabilize the coiled coils suggests that (i) the alpha-helices are individually only marginally stable, a property that may be of significance with regard to the retracted conformation in which sigma 1 is accommodated in the intact virion, and (ii) the predominant interactions between the two coiled coils are likely to involve hydrogen bonding between patches of uncharged residues.

Structure of the reovirus cell-attachment protein: a model for the domain organization of sigma 1

This report describes a model for the structure of the reovirus cell-attachment protein sigma 1. S1 gene nucleotide sequences were determined for prototype strains of the three serotypes of mammalian reoviruses. Deduced amino acid sequences of the S1-encoded sigma 1 proteins were then compared in order to identify conserved features of these sequences. Discrete regions in the amino-terminal two-thirds of sigma 1 sequence share characteristics with the fibrous domains of other cellular and viral proteins. Most of the amino-terminal one-third of sigma 1 sequence is predicted to form an alpha-helical coiled coil like that of myosin. The middle one-third of sigma 1 sequence appears more heterogeneous; it is predicted to form a large region of beta-sheet that is followed by a region which contains two short alpha-helical coiled coils separated by a smaller region of beta-sheet. The two beta-sheet regions are each proposed to form a cross-beta sandwich like that suggested for the rod domain of the adenovirus fiber protein (N. M. Green, N. G. Wrigley, W. C. Russell, S. R. Martin, and A. D. McLachlan, EMBO J. 2:1357-1365, 1983). The remaining carboxy-terminal one-third of sigma 1 sequence is predicted to form a structurally complex globular domain. A model is suggested in which the discrete regions of sigma 1 sequence are ascribed to morphologic regions seen in computer-processed electron micrographic images of the protein (R. D. B. Fraser, D. B. Furlong, B. L. Trus, M. L. Nibert, B. N. Fields, and A. C. Steven, J. Virol. 64:2990-3000, 1990.

Nature and distribution of sites of temperature-sensitive folding mutations in the gene for the P22 tailspike polypeptide chain

Temperature-sensitive folding (tsf) mutations in gene 9 of bacteriophage P22 interfere with the folding and association of the tailspike polypeptide chain at restrictive temperature. We report here the location and amino acid substitutions for 24 independent tsf mutants. The distribution of these and previously identified mutations is distinctly non-random; all of the 32 unambiguous sites of tsf mutations are located in the central 350 residues of the 666 residue tailspike polypeptide chain. No ts mutation has been found among the N-terminal 140 amino acids, and none among the C-terminal 170 amino acids. Since the physiological defect in these mutants is the destabilization of an early intermediate in the folding pathway, the localization of the mutants suggests that the central region of the chain is critical for formation or stabilization of this early intermediate. The majority of amino acids that served as sites for the tsf mutations were hydrophilic residues. Sixty percent of the replacements of these residues represented charge changes. This probably reflects the selection for mutant sites at the mature protein surface where the substitutions can be best tolerated without interfering with function. None of the sites of tsf mutations were at aromatic residues, and only one proline site was found. Substitutions at these residues may cause lethal folding defects which are not recovered as tsf mutants. The local sequences at tsf sites resemble those reported for turns. Structural studies identify beta-sheet as the dominant secondary structure. These mutations may disrupt the formation of conformational features of beta-sheets which are repeated, such as turns, associations between pairs of strands, or sheet/sheet packing interactions. Such a model accounts for the occurrence of tsf mutations with similar defective phenotypes at multiple positions along the chain.

Predicted structure of tail-fiber proteins of T-even type phages

The sequences of the tail fiber protein 36 of the phages T4, T2, K3, and Ox2 were analyzed for homologies and for folding patterns using structure prediction methods. No repeating motif was found. A model for the fiber structure is proposed in which beta-strands of about 6 amino acids are separated by turns. In the beta-strand, hydrophobic amino acids are found alternating with hydrophilic ones. Such amphipathic beta-strands can be stabilized by dimer formation. The dimerization occurs in a parallel fashion so that both N-termini are at one end of the dimer. This structure represents a rigid fiber. Our model is consistent with electron microscopic data and electron diffraction patterns for the T4 tail fiber. The observation that all fiber components are found as dimers supports our model. Sequences of the receptor recognition proteins 38 of T-even type phages reveal an architecture different from the architecture of the fiber proteins 36 and 37 of these phages.

DNA sequence of the tail fiber genes 37, encoding the receptor recognizing part of the fiber, of bacteriophages T2 and K3

The DNA sequences of genes 37 of bacteriophages T2 and K3 are presented and compared with that of phage T4. The corresponding proteins constitute, as dimers, the part of the long tail fibers that recognizes the bacterial receptor. The CO2H termini of the polypeptides are located at the free ends of the fibers. Morphologically, the three phages are essentially identical, but they use different receptors. The genes from phages T4, T2 and K3 encode proteins consisting of 1026, 1341 and 1243 amino acid residues, respectively. DNA-DNA hybridizations had shown earlier that genes 37, in contrast to the gene for the major capsid protein, of a number of T-even type phages are highly polymorphic. The deduced amino acid sequences now show that this polymorphism extends to the protein primary structures. About 50 NH2-terminal residues are conserved and are probably required for binding to the adjacent protein 36. This area is followed by more or less irregularly spaced regions of non-homology, partial homology or complete homology. The heterogeneity is most prominent in a region encompassing about 600 CO2H-terminal residues of the T2 or K3 proteins. Nevertheless, the amino acid compositions of the three proteins are very similar and all are rich in glycine. It has been found that the receptor specificities of phages K3 and T2 are determined by protein 38, a polypeptide required for the efficient dimerization of protein 37 of phage T4. Proteins 38 of phages K3 and T2 are functionally interchangeable, those of T4 and T2 or K3 are not. Proteins 37 of phages K3 and T2 possess a conserved sequence of 160 CO2H-terminal residues. This area is missing in the T4 protein. This region may serve as a binding site for polypeptides 38 of phages K3 and T2. The overall picture of the protein primary structures of the three phages strongly suggests that the evolution of genes 37, which was most likely driven by selection for variations in receptor recognition specificities, has not been a steady process but has involved loss and gain of segments of DNA.

Morphogenesis of the long tail fibers of bacteriophage T2 involves proteolytic processing of the polypeptide (gene product 37) constituting the distal part of the fiber

Gene 37 of phage T2 codes for a protein that, as a dimer, constitutes the most distal, receptor-recognizing part of its long tail fibers. It was found that, from a plasmid carrying a fragment of gene 37 that lacked a region of the gene encoding 87 CO2H-terminal amino acid residues, a protein was expressed that was slightly larger than that present in the phage. This size difference could not be accounted for. The missing region of gene 37 and also gene 38 (which codes for the auxiliary protein required for dimerization of protein 37) were cloned. Plasmids were constructed with gene 37, or gene 37 together with gene 38, under inducible control. Independent of the presence of the latter gene, a protein was produced that had the same size as protein 37 in the phage. A pulse-chase experiment revealed that a precursor of protein 37 is synthesized and processed such that approximately 120 amino acid residues, most likely CO2H-terminal, are removed. Therefore, the protein produced from the truncated gene was larger because it cannot be processed. This fact also solved an old puzzle: an amber fragment of protein 37 of phage T2 had been found to be larger than the mature protein. The amber codon could be located 24 codons away from the normal stop codon. Obviously, the fragment cannot be processed. The existence of this fragment demonstrates that processing occurs during phage maturation.

X-ray diffraction from intraneuronal paired helical filaments and extraneuronal amyloid fibers in Alzheimer disease indicates cross-beta conformation

Information about the structure of the paired helical filaments (PHF) that accumulate within human neurons and the amyloid fibers that accumulate in the extracellular spaces between neurons in Alzheimer disease has so far depended on electron microscopy of thin-sectioned or negatively stained material. To determine the protein conformation of these abnormal fibers, we have obtained x-ray diffraction patterns from unfixed human brain fractions highly enriched in PHF and from purified amyloid cores isolated from senile plaques. The predominant x-ray scatter evident from both types of samples, either wet or dry, is a sharp reflection at 4.76-A spacing and a diffuse one at about 10.6-A spacing. These features are characteristic of a beta-pleated sheet type of protein conformation. In doubly oriented dried pellets of PHF fractions, the two reflections are accentuated at right angles to each other and the arc at 4.76-A spacing is in the fiber direction indicating a cross-beta conformation. From the integral widths of the reflections we estimate the cross-beta crystallite to be about 80 A long in the fiber direction and about 40 A thick. These dimensions correspond to approximately four pleated sheets, each of which consists of approximately 16 hydrogen-bonded polypeptide chains running normal to the fiber direction. The cross-beta conformation of PHF and amyloid fibers that we have found from x-ray diffraction is in contrast to the predominant alpha-helical coiled-coil conformation of the neurofilaments with which they share epitopes and from which they have been postulated to derive.

Purification and structural studies of a major scrapie prion protein

Scrapie is a degenerative, neurological disorder caused by a slow infectious agent or prion. Extensively purified preparations of prions were denatured by boiling in sodium dodecyl sulfate and the major protein component (PrP 27-30) was isolated by preparative HPLC size exclusion chromatography after proteinase K digestion. The purified PrP 27-30 molecules were not infectious. Ultraviolet absorption spectra of purified PrP 27-30 demonstrated the absence of covalently linked polynucleotides. Amino acid composition studies showed that PrP 27-30 contains at least 17 naturally occurring amino acids. A single N-terminal amino acid sequence for PrP 27-30 was obtained; the sequence is N-Gly-Gln-Gly-Gly-Gly-Thr-His-Asn-Gln-Trp-Asn-Lys-Pro-Ser-Lys and it does not share homology with any known proteins. The same amino acid sequence was found when an extensively purified preparation of prions aggregated into rods and containing approximately 10(9.5) ID50 U/ml was sequenced directly. Knowledge of the amino acid sequence should permit determination of the genetic origin and replication mechanism of prions.

Structural characteristics of the short-tail fibers of T4 bacteriophage

The characteristics of pure preparations of short-tail fibers of bacteriophage T4 have been studied in the optical and electron microscope. Three main structures were observed: 1) spheres of 8.1 nm diameter; 2) fibers 43 nm long and 3.8 nm thick; and 3) fibers 54 nm long and 3.2 nm thick. Both types of fibers exhibited a regular beaded appearance. The 43-nm fibers were the most abundant structure. During the process of purification of the short-tail fibers, the formation of aggregates was observed each time the material containing the short-tail fibers was dialyzed against saline solutions. These aggregates became increasingly fibrous (as observed in the optical microscope) as the material used was increasingly enriched in short-tail fibers. Finally, most of the aggregates were of the fibrous type when they were formed from a purified preparation of short-tail fibers. In the electron microscope, it was found that the filamentous aggregates were organized in well-defined bundles. The amino acid composition of the highly purified short-tail fibers was also determined. Among the known fibrous proteins, the ones that most resemble the amino acid composition of the short-tail fibers are actin and fibrinogen. These observations are discussed in relation to the T4 short-tail fiber structure and their localization on the hexagonal baseplate of the T4 tail structure.

Spikes and fimbriae: alpha-helical proteins form surface projections on microorganisms

Two basic alpha-helical plans appear to characterize portions of the proteins projecting from the surface of many microorganisms. Structure A is related to that of the antibody-binding protein A of Staphylococcus aureus, in which a single polypeptide chain doubles back to form an Anti-parallel domain; the other, structure M, is related to the M proteins of group A streptococci, in which Multiple parallel alpha-helical chains interlock in a coiled-coil conformation. A projection about 100 A long may be organized on either plan, but very long projections are likely to be of the M pattern. The alpha-helical motif may account for the length of these spikes, with other functions such as anchoring or antiphagocytic activity located in domains of different structure.

Molecular cloning of the T4 genome: organization and expression of the tail fiber gene cluster 34--38

lambda T4 derivatives that carry T4 tail fiber genes 34-38 have been isolated and characterized by genetic, structural and functional analysis. 32 lambda T4 recombinants were identified by a marker rescue screen of 310 lambda T4 clones generated by restriction of partial cytosine-containing T4 DNA with either HindIII or EcoRI and ligation into appropriately cleaved lambda vectors. These tests defined 15 recombinant classes with respect to the contiguous stretches of genome recovered. Restriction enzyme structural analysis identified 7 HindIII fragments and 7 EcoRI fragments, established a restriction map covering about 11 kb, and indicated the orientation of the DNA inserts within the lambda vectors. The cloned tail fiber genes are expressed efficiently from lambda promoters and complement in vivo T4 phage carrying amber mutations in the tail fiber genes. Polypeptides corresponding to gp34--gp38 have been detected by SDS polyacrylamide gel electrophoresis of 35S-labeled extracts of appropriate lambda T4 recombinant infected UV-treated host cells. The genetic, structural and functional maps of the T4 tail fiber gene cluster have been correlated, and provide a rational approach to genetically directed DNA sequence analysis of genes 34--38 and their mutant variants that affect the assembly, structure and function of the tail fibers.