Structure of polar pili from Pseudomonas aeruginosa strains K and O

The polar pili of Pseudomonas aeruginosa strains K and O are hollow cylinders with 52 Å outer diameter and 12 Å inner diameter. There is a girdle of low electron density (interpreted as due to a local concentration of hydrophobic amino acid side-chains) centred at 31 Å diameter. Similar X-ray diffraction patterns are obtained from oriented fibres of the two types of pili, to a resolution of 7 Å in the equatorial direction and 4 Å in the meridional direction. The two types of pilin protein subunits have a similar molecular weight, and their sequences contain a number of homologous regions. They form a helical array with 4.06 to 4.08 units per turn of a basic helix that has a pitch of 40.8 Å for strain K pili and 41.3 Å for strain O pili at 75% relative humidity. A method is described for distinguishing between very similar diffraction patterns.There is strong intensity at 10 Å near the equator and at 5 Å near the meridian on the diffraction patterns. This intensity distribution is characteristic of α-helical rods running roughly in the direction of the fibre axis. The orientation of these rods was established by the fit between the transform of an α-helical polyalanine model and the strong near-equatorial layer-line.     

Pf1 filamentous bacterial virus: X-ray fibre diffraction analysis of two heavy-atom derivatives

Specific chemical reactions have been used to prepare and characterize two different heavy-atom derivatives of Pfl filamentous bacterial virus. Two atoms of iodine were bound to Tyr25 of the coat protein using immobilized lactoperoxidase. One atom of mercury was introduced by first attaching a thiol group to the amino terminus of the protein. High quality X-ray fibre diffraction patterns of the virus were obtained using a strong magnetic field to orient the virions during preparation of fibres. Bessel functions were resolved by preparing native fibres at 4 °C, which induces layer-line “splitting” and thereby gives three-dimensional data to 4 Å resolution. Analysis of the intensity changes caused by the heavy atoms on the diffraction patterns at 10 Å resolution showed that the virus has 5.4 protein subunits per 15 Å pitch. The iodine atoms were found at a mean radius of 26 to 28 Å and the mercury at a radius of 31 to 33 Å.     

Three-dimensional reconstruction of the flagellar hook from Caulobacter crescentus

The structure of the bacterial flagellar hook produced by a mutant of Caulobacter crescentus was studied by electron microscopy, optical diffraction, and digital image processing techniques. The helical surface lattice of the hook is defined by a single, right-handed genetic helix having a pitch of about 23 Å, an axial rise per subunit of 4 Å and an azimuthal angle between subunits of 64·5 °. The lattice is also characterized by intersecting families of 5-start, 6-start and long-pitch 11-start helices. These helical parameters are remarkably similar to those determined for the flagellar filaments from several strains of gram-negative bacteria. The technique of three-dimensional image reconstruction (DeRosier & Klug, 1968) was applied to nine of the better preserved specimens and the diffraction data from five of these were correlated and averaged and used to generate an average three-dimensional model of the hook. The pattern of density modulations in the three-dimensional model is suggestive of an elongated, curved shape for the hook subunit (100 Å × 25 Å × 25 Å). The subunits are situated in the lattice of the polyhook such that their long axes are tilted about 45 ° with respect to the hook axis. The subunits appear to make contact with each other along the 6-start helices at a radius of 80 Å and also along the 11-start helices at a radius of 65 Å. Few structural features are revealed at radii between 15 å and 45 Å and, therefore, we are unable to decide to what extent the hook subunits extend into this region. The most striking characteristic of the model is the presence of deep, broad, continuous 6-start helical grooves extending from an inner radius of about 50 Å to the perimeter of the particle at 105 Å radius. Normal hooks usually appear curved in electron micrographs and sometimes so are the mutant hooks; the prominent 6-start grooves appear to allow for bending with minimal distortion of matter in the outer regions of the hook. A round stain-filled channel about 25 Å in diameter runs down the center of the polyhook. Such a channel supports a model for flagellar assembly in which flagellin subunits travel through the interior of the flagellum to the growing distal end of the filament.     

Filamentous bacterial viruses. XI. Molecular architecture of the class II (Pf1, Xf) virion

The diffraction patterns of the Pf 1 and Xf strains of filamentous bacterial viruses (class II) can be interpreted in terms of a simple helix of protein subunits with 15Åpitch, having 22 units in five turns. The protein subunits are each elongated in an axial direction, and also slope radially, so as to overlap each other, giving an arrangement of subunits reminiscent of scales on a fish. The protein helix forms a tube with inner diameter about 20Åand outer diameter about 60Å. The single-stranded circular DNA is contained within this tube, with two DNA strands running the length of the tube.The diffraction patterns of fd, If 1 and IKe (class I) can be interpreted in terms of a perturbed version of the class II simple helix.     

X-ray diffraction studies of bacterial pili

A sample of bacterial pili was prepared from Escherichia coli. An X-ray diffraction pattern was obtained from an oriented wet gel specimen in 0.01 m-phosphate buffer (pH 7.0) packed in a capillary tube. Sixteen independent spots were observed with the spacing of the outermost being 4.2 Å. Analysis of the diffraction pattern shows that the arrangement of subunits in pili rods is strictly simple-helical with 3.14₅ units being present in one turn of the helix and the axial rise per unit being 8.09_o Å.     

Pf1 bacteriophage replication-assembly complex: X-ray fibre diffraction and scanning transmission electron microscopy

X-ray fibre diffraction and scanning transmission electron microscopy have been used to investigate the structure of an intracellular complex between circular single-stranded viral DNA and a viral DNA-binding protein. This complex is an intermediate between replication and assembly of the filamentous bacteriophage Pf1. By scanning transmission electron microscopy, the complex has a length of 1.00 μm and M_r = 29.6 × 10⁶. It consists of 1770 protein subunits, each of 15,400 M_r, and one viral DNA molecule of 2.3 × 10⁶M_r: there are 4.2 ± 0.5 nucleotides per subunit. The structure is flexible in solution, but in oriented dry fibres it forms a regular helix of 45 Å pitch having 6.0 dimeric protein subunits per turn, with an axial spacing of 7.5 Å between dimers and 1.9 Å between adjacent nucleotides. Model calculations suggest that the protein dimers may be oriented in a direction approximately perpendicular to the 45 Å helix, so that each dimer spans the two anti-parallel DNA chains. The results imply that conformational changes are required of the DNA as it is transferred from the double-stranded form to the replication-assembly complex, and subsequently to the virion.     

Filamentous Bacterial viruses

The filamentous bacterial virus is a simple and well-characterized model system for studying how genetic information is transformed into molecular machines. The viral DNA is a single-stranded circle coding for about 10 proteins. The major viral coat protein is largely α-helical, with about 46 amino acid residues. Several thousand identical copies of this protein in a helical array form a hollow cylindrical tube 1–2μ long, of outer diameter 60 Å and inner diameter 20 Å, with the twisted circular DNA extending down the core of the tube. Before assembly, the viral coat protein spans the cell membrane, and assembly involves extrusion of the coat from the membrane. X-ray fibre diffraction patterns of the Pf 1 species of virus at 4°C, oriented in a strong magnetic field, give three-dimensional data to 4 Å resolution. An electron density map calculated from native virus and a single iodine derivative, using the maximum entropy technique, shows a helix pitch of 5.9 Å. This may indicate a stretched A-helix, or it may indicate a partially 3₁₀ helix conformation, resulting from the fact that the coat protein is an integral membrane protein before assembly, and is still in the hydrophobic environment of other coat proteins after assembly.     

Changes in the pitch of the myosin helix preceding cross-brdige attachment in oscillatory contractions of frog sartorius muscle

When glycerinated fibres in presence of 5·10^?7M Ca²⁺ were oscillated at a frequency of 10 Hz, the X-ray intensities at 429 Å and at the small radial position of the 191 Å layer-line change in an inverse pattern. This rearrangement of the pitch of the myosin helix precedes by at least 10 msec the intensity increase on the 59 Å X-ray layer-line, which provides a measure for cross-bridge attachment to the actin. The perfect match of the new pitch of the myosin helix with the pitch of the actin helix may ensure optimal cross-bridge attachment.     

Filamentous bacterial viruses. XIL. Molecular architecture of the class I (fd, If1, IKe) virion

The X-ray diffraction patterns of the fd, If1 and IKe strains of filamentous bacterial viruses (class I) indicate that the arrangement of capsid proteins in the virion approximates a left-handed helix of 15 Å pitch with 4.5 units per turn. The protein molecules are each elongated in an axial direction, and also slope radially, so as to overlap each other and give an arrangement of molecules reminiscent of scales on a fish. This helix of capsid proteins is related to the class II helix by a small twist about the helix axis. The protein molecules are also perturbed (by a few Ångström units) away from the positions that they would occupy in a simple 4.5 units per turn helix. The perturbation repeats about every five protein molecules, and is mainly axial. This arrangement of proteins forms a tube with inner diameter about 20 Å and outer diameter about 60 Å, encapsulating the DNA.     

Chromatin subunit small angle neutron scattering: A DNA rich coil surrounds a protein-DNA core

The small angle neutron scattering radii of gyration of 185 base pair subunits have been determined in H₂O and D₂O These values suggest that the outer diameter is 120 to 150Å. The results are not consistent with models in which all of the DNA is in an external shell. The neutron scattering profiles are in good agreement with a model based upon freeze etching electron microscopy (4) having two concentric coils of DNA with 80Åand 150Åexternal diameters.     

Tubulin rings: Curved filaments with limited flexibility and two modes of association

Tubulin rings have been previously identified as composed of linear polymers of tubulin subunits, equivalent to a protofilament in the microtubule wall but in a curved rather than a straight conformation. We have examined and measured a number of different ring structures obtained under different conditions. The preferred curvature is indicated by a single ring of 380 Å outside diameter. Radially double rings consist of two coplanar rings of 460 Å and 350 Å outside diameter, held together by a pattern of eight identical contacts between the 40 Å subunits in the inner and outer rings. In some circumstances a larger ring, 570 Å diameter, can be added to the outside, or a smaller ring, 240 Å diameter, may be added to the inside of the radially double ring, in both cases repeating the pattern of eight radial contacts. The distortion of the filament from its relaxed 380 Å diameter curvature apparently can be made without disrupting the longitudinal bond between subunits in the filament, but must be stabilized by the energy of the radial contacts. All of these rings (single and radially double and triple) are observed to associate axially to form pairs or in some cases larger stacks. The radially double rings or an axially associated pair of these (quadruple ring) may also associate to form crystals. These are thin plates, up to 100 μm in extent and several μm thick which have been of limited use so far in diffraction studies because of irregularities in the packing of adjacent rings.     

Flagellar hook structures of Caulobacter and Salmonella and their relationship to filament structure

Native flagellar hooks from a polarly flagellated bacterium, Caulobacter crescentus, and polyhooks from a peritrichously flagellated bacterium, Salmonella typhimurium. have been studied by densitometry of electron micrographs of negatively stained specimens, followed by computerized Fourier analysis and three-dimensional reconstruction. The two structures are remarkably similar. In both cases, the subunits are arranged along a right-handed basic helix of 2.3 nm pitch with successive subunits separated by an azimuthal angle of 64 to 65 °, and there is a pronounced system of continuous 6-start grooves and ridges on the surface of the structures. The subunit of Salmonella (M_r 42,000, versus 70,000 for Caulobacter) is somewhat thinner and yields a smaller overall hook diameter. The “bent finger” subunit shape and orientation in both cases suggests that the hook could bend readily by a sliding motion in the 11-start direction at inner radii, with the 6-start groove preventing collision at outer radii. The basic helical pitch of the Salmonella hook structure, and the number of subunits per basic helical turn (5.56) makes it highly compatible with the Salmonella flagellar filament (2.6 nm pitch. 5.51 subunits per turn); so also does the elongated shape and tilt angle of the hook and flagellin subunits in the respective structures. The two structures may therefore conjoin directly in the intact flagellum, although participation of a minor protein is not ruled out by the data.     

Assembly of pili on the surface of Corynebacterium diphtheriae

Pili of Gram-negative pathogens are formed from pilin precursor molecules by non-covalent association within the outer membrane envelope. Gram-positive microbes employ the cell wall peptidoglycan as a surface organelle for the covalent attachment of proteins, however, an assembly pathway for pili has not yet been revealed. We show here that pili of Corynebacterium diphtheriae are composed of three pilin subunits, SpaA, SpaB and SpaC. SpaA, the major pilin protein, is distributed uniformly along the pilus shaft, whereas SpaB is observed at regular intervals and SpaC seems positioned at the pilus tip. Assembled pili are released from the bacterial surface by treatment with murein hydrolase, suggesting that the pilus fibres may be anchored to the cell wall envelope. All three pilin subunit proteins are synthesized as precursors carrying N-terminal signal peptides and C-terminal sorting signals. Some, but not all, of the six sortase genes encoded in the genome of C. diphtheriae are required for precursor processing, pilus assembly or cell wall envelope attachment. Pilus assembly is proposed to occur by a mechanism of ordered cross-linking, whereby pilin-specific sortase enzymes cleave precursor proteins at sorting signals and involve the side chain amino groups of pilin motif sequences to generate links between pilin subunits. This covalent tethering of adjacent pilin subunits appears to have evolved in many Gram-positive pathogens that encode sortase and pilin subunit genes with sorting signals and pilin motifs.     

The Agrobacterium tumefaciens T pilus composed of cyclic T pilin is highly resilient to extreme environments

Agrobacterium tumefaciens T pili are long semi-rigid, flexuous filaments of 10 nm diameter that are primarily composed of T pilin cyclized protein subunits. The cyclic character of T pilin apparently confers a high level of structural stability on the T pilus. Purified T pili subjected to extreme environmental conditions such as acid and alkali, including glycerol remained relatively unaffected morphologically. T pili lost their semi-rigidity when subjected to high temperatures and high pH, and dissociated into donut shaped subunits when exposed to Triton X-100. Sodium dodecyl sulfate increased the uptake of uranyl acetate exposing a 2 nm wide lumen running the length of the T pilus filament.     

Structure of the Vibrio cholerae Type IVb Pilus and stability comparison with the Neisseria gonorrhoeae type IVa pilus

Type IV pili are multifunctional filaments displayed on many bacterial pathogens. Members of the Type IVa pilus subclass are found on a diverse group of human pathogens, whereas Type IVb pili are found almost exclusively on enteric bacteria. The Type IVa and IVb subclasses are distinguished by differences in the pilin subunits, including the fold of the globular domain. To understand the implications of the distinct pilin folds, we compared the stabilities of pilin subunits and pilus filaments for the Type IVa GC pilus from Neisseria gonorrhoeae and the Type IVb toxin-coregulated pilus (TCP) from Vibrio cholerae. We show that while recombinant TCP pilin is more stable than GC pilin, the GC pili are more resistant to proteolysis, heat and chemical denaturation than TCP, remaining intact in 8?M urea. To understand these differences, we determined the TCP structure by electron microscopy and three-dimensional image reconstruction. TCP have an architecture similar to that of GC pili, with subunits arranged in a right-handed 1-start helix and related by an 8.4-? axial rise and a 96.8° azimuthal rotation. However, the TCP subunits are not as tightly packed as GC pilins, and the distinct Type IVb pilin fold exposes a segment of the α-helical core of TCP. Hydrophobic interactions dominate for both pilus subtypes, but base stacking by aromatic residues conserved among the Type IVa pilins may contribute to GC pilus stability. The extraordinary stability of GC pili may represent an adaptation of the Type IVa pili to harsh environments and the need to retract against external forces.     

Structure and function of the adhesive type IV pilus of Sulfolobus acidocaldarius

Archaea display a variety of type IV pili on their surface and employ them in different physiological functions. In the crenarchaeon Sulfolobus acidocaldarius the most abundant surface structure is the aap pilus (a rchaeal a dhesive p ilus). The construction of in frame deletions of the aap genes revealed that all the five genes (aapA, aapX, aapE, aapF, aapB) are indispensible for assembly of the pilus and an impact on surface motility and biofilm formation was observed. Our analyses revealed that there exists a regulatory cross‐talk between the expression of aap genes and archaella (formerly archaeal flagella) genes during different growth phases. The structure of the aap pilus is entirely different from the known bacterial type IV pili as well as other archaeal type IV pili. An aap pilus displayed 3 stranded helices where there is a rotation per subunit of ～ 138° and a rise per subunit of ～ 5.7 Å. The filaments have a diameter of ～ 110 Å and the resolution was judged to be ～ 9 Å. We concluded that small changes in sequence might be amplified by large changes in higher‐order packing. Our finding of an extraordinary stability of aap pili possibly represents an adaptation to harsh environments that S. acidocaldarius encounters.     

Comparative Biochemical Studies on F and EDP208 Conjugative Pili

EDP208 pili are encoded by a derepressed derivative of a naturally occurring lac plasmid, F(0)lac (incompatibility group FV), originally isolated from Salmonella typhi. EDP208 pili are serologically unrelated to F pili and do not promote infection by F-specific ribonucleic acid bacteriophages. However, they do confer sensitivity to the F-specific filamentous deoxyribonucleic acid phages. EDP208-containing cells are multi-piliated and contain approximately 20 pili per cell. These pili contain a single polypeptide subunit of 11,500 daltons. EDP208-specific RNA phages were readily isolated from local sewage. These phages were somewhat smaller in diameter than the F-specific ribonucleic acid phages and absorbed relatively weakly to EDP208 pili. Comparing EDP208 pilin to F, it was found that both contain the equivalent of two to three hexose units per subunit as well as blocked N-termini. EDP208 pilin contains one covalently linked phosphate residue per subunit, whereas the F pilin subunit contains two such residues. Although notable differences were found in the case of three or four amino acids, the overall amino acid compositions of F and EDP208 were very similar. Moreover, the tryptic peptide maps of the two proteins contained seven peptides with similar mobilities, suggesting considerable homology in their amino acid sequences. Substantial similarities were also noted in the secondary structures of F and EDP208 pilin on the basis of circular dichroism studies. The alpha-helix content of both proteins was calculated to be 65 to 70%. X-ray fiber diffraction studies have indicated that the arrangements of subunits in F and EDP208 pili are also similar. It was concluded that F and EDP208 pili are closely related structures.     

A helical,polymeric extracellular protein associated with the luminal surface of Haemonchus contortus intestinal cells

The structure of the intestinal cells of the parasitic nematode Haemonchus contortus is described. The cells have numerous microvilli about 0.09 μ in diameter; most being 5.5–7.5 μ in length. The microvillar (plasma) membrane is coated with a layer of amorphous material (glycocalyx) about 60 Å thick which is electron dense in sectioned preparations. Associated with the surface of this material, and filling the spaces between the microvilli, are filaments in the form of helices about 400 Å in diameter and of variable pitch. The helices appear to be flexible but they are aligned approximately with the long axes of the microvilli. There are up to ten helices per microvillus; they extend beyond the tips of the microvilli and are up to 10 μ long. The material has been obtained nearly pure in small amounts. It is primarily protein and it is proposed that it should be called contortin. The monomeric form (of molecular weight about 60,000) has been identified with a Y-shaped structure with arms about 45 Å long and 25 Å wide seen in negatively stained preparations. The helical filament appears to be formed by lateral polymerization of pairs of these units.     

The archaeabacterial flagellar filament: a bacterial propeller with a pilus-like structure

Common prokaryotic motility modes are swimming by means of rotating internal or external flagellar filaments or gliding by means of retracting pili. The archaeabacterial flagellar filament differs significantly from the eubacterial flagellum: (1) Its diameter is 10-14 nm, compared to 18-24 nm for eubacterial flagellar filaments. (2) It has 3.3 subunits/turn of a 1.9 nm pitch left-handed helix compared to 5.5 subunits/turn of a 2.6 nm pitch right-handed helix for plain eubacterial flagellar filaments. (3) The archaeabacterial filament is glycosylated, which is uncommon in eubacterial flagella and is believed to be one of the key elements for stabilizing proteins under extreme conditions. (4) The amino acid composition of archaeabacterial flagellin, although highly conserved within the group, seems unrelated to the highly conserved eubacterial flagellins. On the other hand, the archaeabacterial flagellar filament shares some fundamental properties with type IV pili: (1) The hydrophobic N termini are largely homologous with the oligomerization domain of pilin. (2) The flagellin monomers follow a different mode of transport and assembly. They are synthesized as pre-flagellin and have a cleavable signal peptide, like pre-pilin and unlike eubacterial flagellin. (3) The archaeabacterial flagellin, like pilin, is glycosylated. (4) The filament lacks a central channel, consistent with polymerization occurring at the cell-proximal end. (5) The diameter of type IV pili, 6-9 nm, is closer to that of the archaeabacterial filament, 10-14 nm. A large body of data on the biochemistry and molecular biology of archaeabacterial flagella has accumulated in recent years. However, their structure and symmetry is only beginning to unfold. Here, we review the structure of the archaeabacterial flagellar filament in reference to the structures of type IV pili and eubacterial flagellar filaments, with which it shares structural and functional similarities, correspondingly.     

Pili in gram-positive pathogens

Most bacterial pathogens have long filamentous structures known as pili or fimbriae extending from their surface. These structures are often involved in the initial adhesion of the bacteria to host tissues during colonization. In gram-negative bacteria, pili are typically formed by non-covalent interactions between pilin subunits. By contrast, the recently discovered pili in gram-positive pathogens are formed by covalent polymerization of adhesive pilin subunits. Evidence from studies of pili in the three principal streptococcal pathogens of humans indicates that the genes that encode the pilin subunits and the enzymes that are required for the assembly of these subunits into pili have been acquired en bloc by the horizontal transfer of a pathogenicity island.