Comparative image simulations for phase-plate transmission electron microscopy

Numerous physical phase plates (PP) for phase-contrast enhancement in transmission electron microscopy (TEM) have been proposed and studied with the hole-free or Volta PP having a high impact and interest in recent years. This study is concerned with comparative TEM image simulations considering realistic descriptions of various PP approaches and samples from three different fields of application covering a large range of object sizes. The simulated images provide an illustrative characterization of the typical image appearance and common artifacts of the different PPs and the influence of simulation parameters especially important for PP simulations. A quantitative contrast analysis shows the superior phase-shifting properties of the hole-free phase plate for biological applications and the benefits of adjustable phase plates. The application of PPs in high-resolution TEM imaging, especially of weak-phase objects such as (atomically thin) 2D materials, is shown to increase image interpretability. The software with graphical user interface written and used for the presented simulations is available for free usage.

Isolation and characterization of a new T-even bacteriophage, CEV1, and determination of its potential to reduce Escherichia coli O157:H7 levels in sheep

Bacteriophage CEV1 was isolated from sheep resistant to Escherichia coli O157:H7 colonization. In vitro, CEV1 efficiently infected E. coli O157:H7 grown both aerobically and anaerobically. In vivo, sheep receiving a single oral dose of CEV1 showed a 2-log-unit reduction in intestinal E. coli O157:H7 levels within 2 days compared to levels in the controls.

The genome of the novel phage Rtp, with a rosette-like tail tip, is homologous to the genome of phage T1

A new Escherichia coli phage, named Rtp, was isolated and shown to be closely related to phage T1. Electron microscopy revealed that phage Rtp has a morphologically unique tail tip consisting of four leaf-like structures arranged in a rosette, whereas phage T1 has thinner, flexible leaves that thicken toward the ends. In contrast to T1, Rtp did not require FhuA and TonB for infection. The 46.2-kb genome of phage Rtp encodes 75 open reading frames, 47 of which are homologous to phage T1 genes. Like phage T1, phage Rtp encodes a large number of small genes at the genome termini that exhibit no sequence similarity to known genes. Six predicted genes larger than 300 nucleotides in the highly homologous region of Rtp are not found in T1. Two predicted HNH endonucleases are encoded at positions different from those in phage T1. The sequence similarity of rtp37, -38, -39, -41, -42, and -43 to equally arranged genes of lambdoid phages suggests a common tail assembly initiation complex. Protein Rtp43 is homologous to the lambda J protein, which determines lambda host specificity. Since the two proteins differ most in the C-proximal area, where the binding site to the LamB receptor resides in the J protein, we propose that Rtp43 contributes to Rtp host specificity. Lipoproteins similar to the predicted lipoprotein Rtp45 are found in a number of phages (encoded by cor genes) in which they prevent superinfection by inactivating the receptors. We propose that, similar to the proposed function of the phage T5 lipoprotein, Rtp45 prevents inactivation of Rtp by adsorption to its receptor during cells lysis. Rtp52 is a putative transcriptional regulator, for which 10 conserved inverted repeats were identified upstream of genes in the Rtp genome. In contrast, the much larger E. coli genome has only one such repeat sequence.

Phage DNA transport across membranes

Phage nucleic acid transport is atypical in bacterial membrane transport: it is unidirectional and concerns a unique molecule the size of which may represent 50 times that of the bacterium. The rate of DNA transport, although it varies from one phage to another, can reach values as high as 3000 bp s(-1). This raises the following questions which will be discussed in this review. Is there a single mechanism of transport for all types of phages? Does the phage genome cross the outer and inner membranes by a unique mechanism? Is it transported as a free molecule or in association with proteins? How does it avoid periplasmic nucleases? Is such transport dependent on phage and/or host cell components? What is the driving force for transport? Recent cryoelectron microscopy experiments will be presented which show that it is possible to encapsulate a phage genome (121000 bp) into unilamellar liposomes. The interest of such a model system in gene delivery and in the study of the mechanisms of DNA compaction will be discussed.

An 8-A projected structure of FhuA, A "ligand-gated" channel of the Escherichia coli outer membrane

The structure of FhuA, a siderophore and phage receptor in the outer membrane of Escherichia coli, has been investigated by electron crystallography. Bidimensional crystals of hexahistidine-tagged FhuA protein solubilized in N,N-dimethyldodecylamine-N-oxide were produced after detergent removal with polystyrene beads. Frozen-hydrated crystals (unit cell dimensions of a = 124 A, b = 98 A, gamma = 90 degrees ) exhibited a p22121 plane group symmetry. A projection map at 8 A resolution showed the presence of dimeric ring-like structures with an elliptical shape (48 x 40 A). Each monomer was composed of a ring of densities with a radial width of 8-10 A corresponding to a cylinder of beta sheets. Few densities are present inside the barrel, leaving a central channel approximately 25 A in diameter. A projection map of FhuA at 15 A resolution, which was calculated from negatively stained preparations, demonstrated that most of the central channel was masked by extramembrane domains. This map also revealed an asymmetric distribution of extramembrane domains in FhuA, with large domains located mainly on one side of the molecule. Comparison with density maps derived from recent atomic structure allowed further interpretation of the electron microscopy projection structures with regard to long hydrophilic loops governing the selectivity and opening of the channel.

TEM moiré patterns explain STM images of bacteriophage T5 tails

A subtle combination of constant current and constant height modes in scanning tunnelling microscopy allowed the imaging of a non-flat uncoated biological specimen, namely the tail of the bacteriophage T5. In parallel, a reference three-dimensional structure of the T5 tail was calculated from cryo-transmission electron microscopy images, based on its helical symmetry. This three dimensional reconstruction was compared with scanning tunnelling microscopy data. The images of the tail obtained by transmission electron microscopy, as well as projections of the reconstructed model, show similar moiré patterns. Here we show that scanning tunnelling microscopy performed in an aqueous environment provides direct images which are remarkably similar to the projection of the three dimensional model obtained by transmission electron microscopy. We deduce that our scanning tunnelling microscopy images are the result of a transmission of electrons through the gap between the scanning tip and the conductive support across the biological specimen.

Electron microscopy of biological specimens by the plasma-polymerization rapid-freeze replica method

The plasma-polymerization replica method is a unique replica technique for transmission electron microscopy. In the present study, we used this method in combination with a rapid-freeze technique to observe T4 bacteriophages and hepatitis B virus core particles. The heads of T4 bacteriophages appeared hexagonal and measured approximately 110 nm in length. Striations in their tails were also visible, indicating that the resolution of the present method is better than 4 nm. The images corresponded well with those obtained by ice-embedding and negative staining methods, with respect to both morphology and size of the phage particle. Hepatitis B virus core particles observed by the present method appeared round, approximately 30 nm in diameter, with hollow centres. Again, the morphology and size of the particles corresponded well with those obtained by ice-embedding, negative staining, and ultrathin sectioning. From these results, we conclude that the plasma-polymerization rapid-freeze replica method provides a useful technique for observation of biological specimens in a natural state and at high resolution.

Mechanism of the long tail-fiber deployment of bacteriophages T-even and its role in adsorption, infection and sedimentation

Models for the tail-fiber deployment of T-even bacteriophages have been experimentally tested by correlating sedimentation constants, adsorption rates, protease inactivation kinetics, and fiber configurations of individual phages observed by electron microscopy. Neither the collective nor the individualistic model, i.e. coordinated fiber retraction and expansion or oscillation of fibers independently of each other, respectively, could satisfactorily account for the results presented. We propose a new intermediary model, in which the base-plate determines a collective behaviour by fixing the hinge angle, around which individual fibers oscillate freely. The bidisperse, so-called dual sedimentation was shown to occur mainly with nascent high-concentration phage stocks in potassium glutamate containing media. Indeed, when mature intracellular phages are released in 0.5 M potassium glutamate--a condition simulating the intracellular environment--only the fast form appears. Upon storage in the cold or release into 0.5 M chloride, both forms appear. Results confirming that the sedimentation constants of the fast and slow form roughly correspond to those of the monodisperse sedimentation, characteristic of the extreme pH values, i.e. 5 and 8, do not allow to conclude that fiber configuration is the only cause of the bidisperse sedimentation.

[The effect of point amino acid substitutions on T4 phage lysozyme stability. II. Transition of a protein molecule to the "molten globule" state with replacements Asp10---His, Asn101---Asp, Arg148---Ser]

The amino acid replacements (Asp10-->His, Asn101-->Asp, Arg148-->Ser) in the T4 phage lysozyme were obtained by site directed mutagenesis and the plasmid for mutant protein expression was constructed. At acid pH (pH 2.7) the mutant is in the conformational state with properties of the molten globule (Ptitsyn, 1992): 1) the mutant protein molecule is essentially compact, 2) its circular dichroism (CD) spectrum in the near ultra violet (UV) region is drastically reduced in intensity as compared with the wild type protein spectrum, 3) the CD spectrum in the far UV region indicates the presence of a pronounced secondary structure in the mutant, 4) unlike the wild type protein, the mutant protein can bind the hydrophobic fluorescent probe ANS.

[From disorder to order using the example of the function of phage T4 baseplate]

The structure of key elements of T4 baseplate distal part was investigated by electron microscopy and image processing. The functional aspects of interaction of distal part structures in cell infection process were discussed. According to the results obtained earlier the baseplate functioning was suggested to be like a synchronization process of the complex protein structure caused by variation of external factors.

Assembly-associated structural changes of bacteriophage T7 capsids. Detection by use of a protein-specific probe

To detect changes in capsid structure that occur when a preassembled bacteriophage T7 capsid both packages and cleaves to mature-size longer (concatameric) DNA, the kinetics and thermodynamics are determined here for the binding of the protein-specific probe, 1,1'-bi(4-anilino)naphthalene-5,5'-di-sulfonic acid (bis-ANS), to bacteriophage T7, a T7 DNA deletion (8.4%) mutant, and a DNA-free T7 capsid (metrizamide low density capsid II) known to be a DNA packaging intermediate that has a permeability barrier not present in a related capsid (metrizamide high density capsid II). Initially, some binding to either bacteriophage or metrizamide low density capsid II occurs too rapidly to quantify (phase 1, duration < 10 s). Subsequent binding (phase 2) occurs with first-order kinetics. Only the phase 1 binding occurs for metrizamide high density capsid II. These observations, together with both the kinetics of the quenching by ethidium of bound bis-ANS fluorescence and the nature of bis-ANS-induced protein alterations, are explained by the hypothesis that the phase 2 binding occurs at internal sites. The number of these internal sites increases as the density of the packaged DNA decreases. The accompanying change in structure is potentially the signal for initiating cleavage of a concatemer. Evidence for the following was also obtained: (a) a previously undetected packaging-associated change in the conformation of the major protein of the outer capsid shell and (b) partitioning by a permeability barrier of the interior of the T7 capsid.

A small (58-nm) attached sphere perturbs the sieving of 40-80-kilobase DNA in 0.2-2.5% agarose gels: analysis of bacteriophage T7 capsid-DNA complexes by use of pulsed field electrophoresis

Although the icosahedral bacteriophage T7 capsid has a diameter (58 nm) that is 234-fold smaller than the length of the linear, double-stranded T7 DNA, binding of a T7 capsid to T7 DNA is found here to have dramatic effects on the migration of the DNA during both pulsed field agarose gel electrophoresis (PFGE; the field inversion mode is used) and constant field agarose gel electrophoresis (CFGE). For these studies, capsid-DNA complexes were obtained by expelling DNA from mature bacteriophage T7; this procedure yields DNA with capsids bound at a variable position on the DNA. When subjected to CFGE at 2-6 V/cm in 0.20-2.5% agarose gels, capsid-DNA complexes arrest at the electrophoretic origin. Progressively lowering the electrical potential gradient to 0.5 V/cm results in migration; most complexes form a single band. The elevated electrical potential gradient (3 V/cm) induced arrest of capsid-DNA complexes is reversed when PFGE is used instead of CFGE. For some conditions of PFGE, the mobility of capsid-DNA complexes is a function of the position of the capsid on the DNA. During either CFGE (0.5 V/cm) or PFGE, capsid-DNA complexes increasingly separate from capsid-free DNA as the percentage of agarose increases. During these studies, capsid-DNA complexes are identified by electron microscopy of enzymatically-digested pieces of agarose gel; this is apparently the first successful electron microscopy of DNA from an agarose gel.(ABSTRACT TRUNCATED AT 250 WORDS)

Formation of the right before the left mature DNA end during packaging-cleavage of bacteriophage T7 DNA concatemers

During bacteriophage T7 morphogenesis in a T7-infected cell, mature length T7 DNA molecules join end-to-end to form concatemers that are subsequently both packaged in the T7 capsid and cut to mature size. In the present study, the kinetics of the appearance in vivo of the mature right and left T7 DNA ends have been analyzed. To perform this analysis, the intercalating dye proflavine is used to interrupt DNA packaging. When used at 0.5 to 8.0 micrograms/ml, proflavine progressively inhibits events in the T7 DNA packaging pathway, without either altering protein synthesis or degrading intracellular T7 DNA. Restriction endonuclease kinetic analysis reveals that proflavine (8 micrograms/ml) completely blocks formation of the mature T7 DNA left end, but only partially blocks formation of the mature T7 DNA right end. Both these and other observations are explained by the hypothesis that, in the T7 DNA packaging pathway, events occur in the following sequence: (1) formation of a mature right end; (2) packaging of at least some of the genome; (3) formation of the mature left end.

Deposition and imaging of metal-coated biomolecules with the STM

We have applied a simple and reliable procedure for imaging biomolecules with the scanning tunneling microscope (STM). The biomolecules are adsorbed on glow-discharged mica, then coated with a thin film of platinum-carbon. We have tested this method with linear and circular (plasmid) DNA molecules. The contrast and resolution of the STM images are comparable to electron micrographs of the same molecules when shadowed. Though the present lateral resolution (5-6 nm) is limited by the grain size of the conductive film, some details like supercoiled regions in the DNA are resolved. This method is interesting for two reasons. First, as an alternative technique for imaging biomolecules. Second, for use as a control in STM studies of bare biomolecules.

Cryoelectron microscopic visualization of functional subassemblies of the bacteriophage T4 DNA replication complex

A specific complex of proteins involved in bacteriophage T4 replication has been visualized by cryoelectron microscopy as distinctive structures in association with DNA. Formation of these structures, which we term "hash-marks" for their characteristic appearance in association with DNA, requires the presence of the T4 polymerase accessory proteins (the products of T4 genes 44, 45 and 62), ATP and appropriate DNA cofactors. ATP hydrolysis by the DNA-stimulated ATPase activity of the accessory proteins is required for visualization of the hash-mark structures. If ATP hydrolysis is stopped by chelation of Mg2+, by dilution with a non-hydrolyzable ATP analogue, or by exhaustion of the ATP supply, the DNA-associated structures disappear within seconds to minutes, indicating that they have a finite and relatively short lifetime. The labile nature of the structures makes their study by more conventional methods of electron microscopy, as well as by most other structural approaches, difficult if not impossible. Addition of T4 gene 32 protein increases the number of hash-mark structures, as well as increasing the rate of ATP hydrolysis. Using plasmid DNA in either a native (supercoiled) or enzymatically modified state, we have shown that nicked or gapped DNA is required as a cofactor for hash-mark formation. Stimulation of the ATPase activity of the accessory proteins has a similar cofactor requirement. These conditions for the formation and visualization of the structures parallel those required for the action of these complexes in promoting the enzymatic activity of the T4 DNA polymerase, as well as the transcription of late T4 genes. Substructure in the hash-marks has been examined by image analysis, which reveals a variation in the projected density of the subunits comprising the structures. The three-dimensional size of the hash-marks, modeled as a solid ellipsoid, is consistent with that of the gene 44/62 protein subcomplex. Density variations suggest an arrangement of subunits, either tetragonal or trigonal, viewed from a variety of angles about the DNA axis. The hash-mark structures often appear in clusters, even in DNA that has a single nick. We interpret this distribution as the result of one-dimensional translocation of the hash-marks along the DNA after their ATP-dependent initial association with, and injection into, the DNA at nicks or gaps.

Conformation of DNA packaged in bacteriophage T7. Analysis by use of ultraviolet light-induced DNA-capsid cross-linking

The conformation of the linear, double-stranded, 39,936 kilobase-pair DNA packaged in the protein capsid of bacteriophage T7 is investigated here by use of short wavelength ultraviolet light-induced DNA-capsid cross-linking. To detect both DNA-capsid and DNA-DNA cross-links, DNA is expelled from the T7 capsid and the products of expulsion are analyzed by use of Nycodenz buoyant density centrifugation, followed by either pulsed field gel electrophoresis or invariant field gel electrophoresis. Short wavelength ultraviolet light is found to progressively induce both DNA-DNA and DNA-protein cross-links in intact bacteriophage T7, but not in T7 from which DNA had been expelled before exposure to ultraviolet light. Protein-protein cross-links are not induced. When DNA expelled from previously cross-linked T7 is cleaved with restriction endonuclease (1 to 3 sites cleaved), analysis of the resulting fragments reveals no regions on T7 DNA that are excluded from cross-linking to the capsid. However, the efficiency of cross-linking decreases as the distance from the left end (last end packaged) of the packaged DNA increases. Electron microscopy of negatively stained capsid-DNA complexes reveals no DNA-retaining structure other than the outer shell of the capsid. Together with previously reported data that indicate lack of protein-based specificity for ultraviolet light-induced cross-linking, these observations are interpreted by the assumptions that, within the limits of resolution of these experiments: (1) no region of packaged T7 DNA is excluded from contact with the outer shell of the T7 capsid; (2) the probability of contacting the outer shell decreases as the distance from the left end of packaged T7 DNA increases. Thus, T7 DNA packaging concentrates the last end packaged near the inner surface of the outer shell of the T7 capsid.

Effect of thermoinduced changes in T4 bacteriophage structure on the process of molecular recognition of 'host' cells

By means of high-precision acoustic measurements and by methods of fluorescent and electron microscopy, investigations have been performed of thermoinduced conformational changes in T4 bacteriophage and its thermolabile mutants altered in baseplate proteins (gene products 7, 8, 10). A relationship was found between the conformational changes in T4 bacteriophage structure in the temperature range of 33-45 degrees C and the efficiency of bacteriophage adsorption and the changes in the orientation of long tail fibers. The possibility of heat regulation of 'recognition' of 'host' cells by bacterial viruses is suggested.

GTPase activity of bacteriophage T4 sheath protein

We show by nuclear magnetic resonance studies that, following GTP hydrolysis during phage T4 sheath contraction, GDP remains bound to the sheath protein (gp18), whereas orthophosphate is released. gp18 in the contracted state has GTPase activity and can hydrolyse exogenous GTP; the reaction is calcium-dependent and displays high substrate specificity. The process comprises two steps: (1) displacement of GDP from gp18 by exogenous GTP, and (2) GTP hydrolysis proper. The first step appears to be rate-limiting and to be accelerated when the nucleotide-protein interaction is mechanically disrupted by sonication.

Membrane fusion during infection of Escherichia coli cells by phage T4

Phage T4 infection of Escherichia coli was studied by thin-section and freeze-fracture electron microscopy. It was found that phage T4 induces the formation of a bridge between the outer and inner membranes of E. coli. A membrane fusion during the infection is suggested.

High precision immunoscanning electron microscopy using Fab fragments coupled to ultra-small colloidal gold

Ultra-small colloidal gold (less than 1 nm), bound to Fab fragments provides the shortest practical specific marker system to date and can be used in concert with field emission scanning electron microscopes to precisely locate antigenic sites. An "in-lens" FE-SEM equipped with a highly sensitive single crystal YAG-detector for backscattered electrons, as well as the use of advanced specimen preparation techniques based on cryofixation, are among the indispensible prerequisites. A T-even type Escherichia coli bacteriophage, Tu II*-46, was chosen to study properties of the immunogold labeling system. Distinct regions on the tail fibers of this phage were labeled with Fab fragments derived from antibodies against the related phage Tu II*-6. The tail fibers are composed of pairs of homologous proteins, thus offering two identical antigenic sites at the same locus on the tail fibers. Fab fragments can be visualized in the SEM at high accelerating voltage (30 kV) without any additional marker. This permits comparison of the labeling characteristics of unmarked and colloidal gold-marked Fab fragments. Unmarked Fab fragments often bind by pairs (two singlet Fab fragments bound opposed to each other along the axis of the tail fiber). The labeling efficiency of unmarked Fab fragments was greater than that of ultra-small gold-labeled Fab fragments. Binding by pairs was not seen after labeling with ultra-small gold-Fab fragments. The conjugates used in this study exhibited one colloidal gold per Fab fragment.

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)

Platinum/iridium/carbon: a high-resolution shadowing material for TEM, STM and SEM of biological macromolecular structures

Thin Pt/Ir/C coating films (1.5 nm) show a fine granularity and provide a high structural resolution in the transmission electron microscope (TEM) when applied to freeze-dried biological macromolecules. They keep their structure when exposed to atmospheric conditions, without the need of an additional stabilizing carbon layer, in contrast to conventional high-resolution shadowing materials such as Ta/W and Pt/C. However, the correct ratio of the components has turned out to be crucial. When evaporating Pt/Ir/C from the source electrode in an electron-beam-heated evaporator, the ratio of the three elements changes progressively, and, consequently, the properties of such films depend strongly on the mass that has been pre-evaporated. In this paper we present a quantitative analysis of the composition of Pt/Ir/C films by wavelength-dispersive X-ray analysis (WDX) undertaken in association with TEM experiments. We applied Pt/Ir/C shadowing to two regular biological test specimens, the phage T4 type III polyhead and the HPI-layer of Deinococcus radiodurans. It turns out that Pt/Ir/C films containing at least 25% C are three-dimensionally stable on the freeze-dried macromolecular samples. By the dramatically improved resolution power of the latest scanning electron microscopes (SEM) and the invention of the scanning tunnelling microscope (STM), two new surface-sensitive tools for the investigation of biological macromolecular structures became available. The Pt/Ir/C coating has proved to be well suited for STM and SEM imaging of freeze-dried biological structures because of its good electrical conductivity and its direct three-dimensional stability. We compare STM, SEM and TEM images of freeze-dried and Pt/Ir/C-coated polyheads.

Biological structures imaged in a hybrid scanning transmission electron microscope and scanning tunneling microscope

A hybrid scanning transmission electron microscope (STEM) and scanning tunneling microscope (STM) is described which allows simultaneous imaging of biological structures adsorbed to electron-transparent specimen supports in both modes of scanning microscopy, as demonstrated on uncoated phage T4 polyheads. We further discuss the reproducibility and validity of height data obtained from STM topographs of biomacromolecules and present raw data from topographs of freeze-dried, metal-coated nuclear envelopes from Xenopus laevis oocytes.

The maturation-dependent conformational change of phage T4 capsid involves the translocation of specific epitopes between the inner and the outer capsid surfaces

After polymerization of the phage T4 prohead is complete, its capsid expands by approximately 16%, is greatly stabilized, and acquires the capacity to bind accessory proteins. These effects are manifestations of a large-scale, irreversible, conformational change undergone by the major capsid protein, gp23 (521 residues) which is cleaved to gp23* (residues 66-521) during this maturation process. In order to explore its structural basis, we have performed immunoelectron microscopy with antibodies raised against synthetic peptides that correspond to precisely defined segments of the amino acid sequence of gp23. These antibodies were used to label purified polyheads (tubular polymorphic variants of the normal icosahedral capsid), in experiments designed to impose constraints on the possible foldings of the gp23/gp23* polypeptide chains in their successive conformational states. Peptide 1 (residues 48-57), part of the gp23-delta domain that is excised when gp23 is converted to gp23*, resides on the inner surface of the precursor surface lattice, but--if not proteolyzed--is found on the outer surface of the mature surface lattice. Peptide 2 (residues 65-73), immediately distal to the cleavage site, is located on the inside of the precursor surface lattice, and remains there subsequent to expansion. Peptide 3 (residues 139-146) is translocated in the opposite direction from peptide 1, i.e., from the outer to the inner surface upon expansion; moreover, expansion greatly increases the polyheads' affinity for these antibodies. Peptide 5 (residues 301-308) is located on the inside in both the precursor and the mature states. Taking into account data from other sources, these observations imply that the conformational change that underlies capsid expansion involves a radical reorganization of the proteins' structure, in which at least three distinct epitopes, situated in widely differing parts of the polypeptide chain, are translocated from one side to the other. Moreover, the amino-terminal portion of gp23/gp23*, around the cleavage site, is particularly affected.

Application of scanning tunneling microscopy to structural biology

Scanning tunneling microscopy offers the possibility of visualizing biological molecules in conditions similar to those in vivo with molecular resolution. Images of DNA and various proteins have been obtained, but insufficient conductivity through, and inhomogeneous and unstable adsorption of the biomolecules continue to prevent reliable imaging. Applying a metal coating to samples, to separate the conductivity and deposition problems has yielded satisfactory deposition procedures in various laboratories, but extension of this protocol to high resolution imaging of macromolecules has yet to be demonstrated. In this paper we present a review of the main results obtained in our laboratory, which illustrate the main problems encountered by investigators attempting to image metal-coated and uncoated biological specimens.

Mass analysis of bacteriophage T4 proheads and mature heads by scanning transmission electron microscopy and hydrodynamic measurements

Quantitative mass analysis of bacteriophage T4 proheads by scanning transmission electron microscopy (STEM) revealed a mass of 79.5 +/- 0.6 MDa, while hydrodynamic measurements yielded a prohead mass of about 80 MDa. This is 25% less than the prohead mass deduced from its polypeptide composition, and this finding implies that the bacteriophage T4 prohead is built of fewer polypeptide copies than previously reported. In contrast, the mass of mature heads measured by STEM, 194 +/- 2 MDa, is in agreement with previous mass measurements of DNA and protein content, and it is consistent with the previously determined stoichiometry. This good agreement of average STEM values for proheads and mature heads with corresponding hydrodynamic measurements suggests that STEM allows faithful evaluation of the masses of large supramolecular assemblies (i.e., greater than or equal to 200 MDa) such as whole viruses or cellular organelles.

Analysis of symmetry and three-dimensional reconstruction of thin gp32*I crystals

Thin, multilayered crystals of gp32*I were analyzed by negative stain electron microscopy and image processing. Images of untilted crystals exhibited different projection symmetries and structural motifs. Systematic analysis of these images categorized the projections into four types. Areas producing the type 1 projection were reconstructed in three-dimensions from four tilt series containing 111 images. The three-dimensional data has excellent p121 plane group symmetry and reveals that the gp32*I molecule contains two large domains linked together by a small domain. Computer simulations utilizing projection data suggested that the type 2 and 3 projections arise from superposition of type 1 projections related by a 21 screw axis along the projection axis. The three-dimensional reconstruction was utilized in a final simulation that explained the occurrence of the fourth type of projection. This work provides a firm foundation for future high-resolution analysis of the crystal by electron cryomicroscopy.

Variation of the permeability of bacteriophage T4: analysis by use of a protein-specific probe for the T4 interior

The permeability of bacteriophage T4 and the change in T4 permeability caused by mutation to osmotic shock resistance are investigated here by quantification of the kinetics with which both a DNA-specific probe (ethidium) and a protein-specific probe [1,1'-bi(4-anilino)naphthalene-5,5'-di-sulfonic acid, or bis-ANS)] bind to T4. In the case of an osmotic shock-resistant mutant, T40s41, both ethidium and bis-ANS bind with first order kinetics. The first-order rate constant (k*) for both bis-ANS and ethidium is a function of anion type and concentration. Adenosine triphosphate, phosphate, bisulfite, sulfate, and acetate anions all reduce k* below the k* observed when chloride is the only anion. When chloride is the only anion at 25 degrees C, k* values for binding to T40s41 are orders of magnitude above k* values for binding to wild-type T4 (T4wt). At 25 degrees C, k* for T4wt is too small to measure but k* for T4wt increases at 50-55 degrees C to values approaching those measured for T40s41, without inactivating T4wt, when chloride is the only anion; during heating, T4wt is stabilized by both ethidium and bis-ANS. Binding to T4wt is reversible at 50-55 degrees C, but not at 25 degrees C. Equilibrium binding of bis-ANS to T40s41 reveals 112 +/- 24 sites per T4 capsid. Equilibrium binding of ethidium to T40s41 reveals both high- and low-affinity sites previously observed in the packaged DNA of other bacteriophages. The ATP-induced decrease in k* is not accompanied by a decrease in equilibrium binding. The following hypotheses are presented to explain the above data: (a) All detected bis-ANS binding sites on T4 are interior to the outer surface of T4. (b) The value of k* for both bis-ANS and ethidium is controlled at the port(s) of passage through the outer shell of the T4 capsid. (c) The anions present control k* values at the port(s) of entry, probably by controlling the size of this port. The effects on k* of phosphate explain the otherwise paradoxical observation [P. J. McCall and V. A. Bloomfield (1976) Biopolymers 15, 2323-2336] that in a phosphate buffer the permeabilities of T4wt and T40s41 are the same.

Bacteriophage T7 DNA packaging. I. Plasmids containing a T7 replication origin and the T7 concatemer junction are packaged into transducing particles during phage infection

Bacteriophage T7 DNA is a linear duplex molecule with a 160 base-pair direct repeat (terminal redundancy) at its ends. During replication, large DNA concatemers are formed, which are multimers of the T7 genome linked head to tail through recombination at the terminal redundancy. We define the sequence that results from this recombination, a mature right end joined to the left end of T7 DNA, as the concatemer junction. To study the processing and packaging of T7 concatemers into phage particles, we have cloned the T7 concatemer junction into a plasmid vector. This plasmid is efficiently (at least 15 particles/infected cell) packaged into transducing particles during a T7 infection. These transducing particles can be separated from T7 phage by sedimentation to equilibrium in CsCl. The packaged plasmid DNA is a linear concatemer of about 40 x 10(3) base-pairs with ends at the expected T7 DNA sequences. Thus, the T7 concatemer junction sequence on the plasmid is recognized for processing and packaging by the phage system. We have identified a T7 DNA replication origin near the right end of the T7 genome that is necessary for efficient plasmid packaging. The origin, which is associated with a T7 RNA polymerase promoter, causes amplification of the plasmid DNA during T7 infection. The amplified plasmid DNA sediments very rapidly and contains large concatemers, which are expected to be good substrates for the packaging reaction. When cloned in pBR322, a sequence containing only the mature right end of T7 DNA is sufficient for efficient packaging. Since this sequence does not contain DNA to the right of the site where a mature T7 right end is formed, it was expected that right ends would not form on this DNA. In fact, with this plasmid the right end does not form at the normal T7 sequence but is instead formed within the vector. Apparently, the T7 packaging system can also recognize a site in pBR322 DNA to produce an end for packaging. This site is not recognized solely by a "headful" mechanism, since there can be considerable variation in the amount of DNA packaged (32 x 10(3) to 42 x 10(3) base-pairs). Furthermore, deletion of this region from the vector DNA prevents packaging of the plasmid. The end that is formed in vector DNA is somewhat heterogeneous. About one-third of the ends are at a unique site (nucleotide 1712 of pBR322), which is followed by the sequence 5'-ATCTGT-3'. This sequence is also found adjacent to the cut made in a T7 DNA concatemer to produce a normal T7 right end.

Imaging biological macromolecules by STM: quantitative interpretation of topographs

Methods are discussed which permit the calibration of x-, y-, z-sensitivities, non-linearities and frequency responses of the scanning device of a scanning tunneling microscope (STM) either by interferometry or directly from STM topographs. A technique is presented to measure the frequency response of the complete STM feedback unit and to derive a maximum speed in z direction which allows one to estimate the maximum scanning speed still permitting one to track surface corrugations. The signal transfer characteristics of a STM are evaluated in a direct comparison with high resolution transmission electron microscopy on an identical specimen area. The various effects of contaminants between tip and specimen and the finite tip radius receive special attention.

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

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

Localization of the proteins gp7, gp8 and gp10 in the bacteriophage T4 baseplate with colloidal gold: F(ab)2 and undecagold: Fab' conjugates

We report the localization of the proteins gp7, gp8 and gp10 in the bacteriophage T4 baseplate. Proceeding on the assumption that these proteins occupy discrete locations, we have decorated baseplates and tails with immunological probes. Using 5 nm diameter colloidal gold: F(ab')2 conjugates, we show that proteins gp7 and gp10 are located directly at the vertex, with gp10 positioned in the pin directly below gp7. gp8 is located beside gp7 towards the centre of the baseplate. Using a novel undecagold: Fab' conjugate we have also determined the radial positions of gp7 and gp8 in baseplates that have transformed to stars. A mechanism for the nature of the hexagon-to-star transformation is proposed.

Pore formation associated with the tail-tip protein pb2 of bacteriophage T5

Upon binding of bacteriophage T5 tails to purified FhuA receptor protein the tail-tip protein pb2 became extremely sensitive to trypsin and other proteases. However, when T5 tails were bound to FhuA integrated into liposomes, pb2 was found to retain some resistance to trypsin. Electron microscopic examination of tail-liposome complexes supported the idea that trypsin resistance of pb2 in such complexes was caused by insertion of the tail-tip into the liposomes. pb2 was isolated from tails by treatment with sodium dodecyl sulfate and was further purified by gel filtration using a fast protein liquid chromatography system. pb2 obtained with this procedure was most likely monomeric. It was extremely sensitive to trypsin. When reconstituted into black lipid bilayer membranes, it formed pores with an average single-channel conductance of 4.6 nanosiemens in 1 M KCl. Zero-current potential measurements showed only a very slight preference, if any, for cations over anions. The data are compatible with pb2 forming a large water-filled transmembrane channel. The functioning during infection of pb2 in cytoplasmic membrane depolarization and phage DNA uptake into the cell is discussed.

Role of gene 6 exonuclease in the replication and packaging of bacteriophage T7 DNA

When bacteriophage T7 gene 6 exonuclease is genetically removed from T7-infected cells, degradation of intracellular T7 DNA is observed. By use of rate zonal centrifugation, followed by either pulsed-field agarose gel electrophoresis or restriction endonuclease analysis, in the present study, the following observations were made. (1) Most degradation of intracellular DNA requires the presence of T7 gene 3 endonuclease and is independent of DNA packaging; rapidly sedimenting, branched DNA accumulates when both the gene 3 and gene 6 products are absent. (2) A comparatively small amount of degradation requires packaging and occurs at both the joint between genomes in a concatemer and near the left end of intracellular DNA; DNA packaging is only partially blocked and end-to-end joining of genomes is not blocked in the absence of gene 6 exonuclease. (3) Fragments produced in the absence of gene 6 exonuclease are linear and do not further degrade; precursors of the fragments are non-linear. (4) Some, but not most, of the cleavages that produce these fragments occur selectively near two known origins of DNA replication. On the basis of these observations, the conclusion is drawn that most degradation that occurs in the absence of T7 gene 6 exonuclease is caused by cleavage at branches. The following hypothesis is presented: most, possibly all, of the extra branching induced by removal of gene 6 exonuclease is caused by strand displacement DNA synthesis at the site of RNA primers of DNA synthesis; the RNA primers, produced by multiple initiations of DNA replication, are removed by the RNase H activity of gene 6 exonuclease during a wild-type T7 infection. Observation of joining of genomes in the absence of gene 6 exonuclease and additional observations indicate that single-stranded terminal repeats required for concatamerization are produced by DNA replication. The observed selective shortening of the left end indicates that gene 6 exonuclease is required for formation of most, possibly all, mature left ends.

Role of the major capsid protein of phage T4 in DNA packaging from structure-function and site-directed mutagenesis studies

Heat cleavage of asp-pro peptide bonds was used to probe the primary structures of the Phage T4 major capsid protein precursor, gp23, its mature capsid form gp23*, and a DNA-dependent ATPase, called capsizyme. This analysis suggests that capsizyme is a gp23** resulting from the N-terminal processing found in gp23* as well as shortening at the C-terminus. Photoaffinity labeling with Azido-ATP and BrU-DNA, followed by heat cleavage, suggests binding sites for these compounds toward the C-terminus of gp23**, suggesting localization of functions within the gp23 primary sequence. Site-directed mutagenesis experiments were targeted therefore to the C-terminal end of g23 as well as to its processing sites. N-terminal processing site modification supports the consensus gp21 proteinase cleavage rule, whereas mutagenesis at the C-terminus suggests that the C-terminal alteration is unlikely to result from a gp21-morphogenesis proteinase cleavage. Amino acid replacements in gp23 at newly introduced amber sites reveal a new g23 mutant phenotype, defective partially DNA-filled heads, in support of the hypothesis that gp23 and its products function directly in the DNA packaging mechanism.

Genetic control of capsid length in bacteriophage T4. VII. A model of length regulation based on DNA size

Four models for head length regulation in bacteriophage T4 are described and discussed. Several length mutants in the major capsid protein gene (23) were studied by sucrose gradient analysis, rotating gel analysis of DNA length, and by mixed infection gene dosage experiments with T4 amber mutants in gene 24. The results show that head length variation is quantized and highly specific, in that certain amino acid changes in gp23 results in reproducible and well-defined head length phenotypes. These data are presented as being most consistent with a vernier-type of head length control mechanism.

The maturation-dependent conformational change of the major capsid protein of bacteriophage T4 involves a substantial change in secondary structure

We have investigated the conformational basis of the expansion transformation that occurs upon maturation of the bacteriophage T4 prohead, by using laser Raman spectroscopy to determine the secondary structure of the major capsid protein in both the precursor and the mature states of the surface lattice. This transformation involves major changes in the physical, chemical, and immunological properties of the capsid and is preceded in vivo by processing of its major protein, gp23 (56 kDa), to gp23* (49 kDa), by proteolysis of its N-terminal gp23-delta domain. The respective secondary structures of gp23 in the unexpanded state, and of gp23* in the expanded state, were determined from the laser Raman spectra of polyheads, tubular polymorphic variants of the capsid. Similar measurements were also made on uncleaved polyheads that had been expanded in vitro and, for reference, on thermally denatured polyheads. We find that, with or without cleavage of gp23, expansion is accompanied by substantial changes in secondary structure, involving a major reduction in alpha-helix content and an increase in beta-sheet. The beta-sheet contents of gp23* or gp23 in the expanded state of the surface lattice, and even of gp23 in the unexpanded state, are sufficient for a domain with the "jellyroll" fold of antiparallel beta-sheets, previously detected in the capsid proteins of other icosahedral viruses.(ABSTRACT TRUNCATED AT 250 WORDS)

Structural studies of the contractile tail sheath protein of bacteriophage T4. 2. Structural analyses of the tail sheath protein, Gp18, by limited proteolysis, immunoblotting, and immunoelectron microscopy

The molecular structure of the T4 phage tail sheath protein, gp18, was studied by limited proteolysis, immunoblotting, and immunoelectron microscopy. Gp18 is extremely resistant to proteolysis in the assembled form of either extended or contracted sheaths, but it is readily cleaved by proteases in the monomeric form, giving rise to stable protease-resistant fragments. Limited proteolysis with trypsin gave rise to a trypsin-resistant fragment, Ala82-Lys316, with a molecular weight of 27K. Chymotrypsin- and thermolysin-resistant fragments were also mapped close to the trypsin-resistant region. The time course of trypsin digestion of the monomeric gp18 as monitored by SDS-polyacrylamide gel electrophoresis and immunoblotting of the gel revealed that the polypeptide chain consisting of 658 amino acid residues is sequentially cleaved at several positions from the C terminus. The N-terminal portion, Thr1-Arg81, was then removed to form the trypsin-resistant fragment. Immunoelectron microscopy revealed that the polyclonal antibodies against the trypsin-resistant fragment bound to the tail sheath. This supported the idea that at least part of the protease-resistant region of gp18 constitutes the protruding part of the sheath protein as previously revealed with three-dimensional image reconstruction from electron micrographs by Amos and Klug [Amos, L. A., & Klug, A. (1975) J. Mol. Biol. 99, 51-73].

Automated electrokinetic analysis; description and application in virology and cell biology

The electrophoretic mobility (EPM) of selected macromolecules in solution was shown to be accurately determined using an automated electrokinetic analyzer, the PenKem S3000. In addition, the S3000 was used to monitor the effects of T4 phage infection on the EPM of Escherichia coli B. EPM, expressed as the ratio of velocity in microns/sec to field strength in V/cm, was measured for calf thymus DNA, for pneumococcal capsular polysaccharide serotype 3 (PCP-3), and for bovine serum albumin (BSA) unbound in solution; values of -3.05, -2.736 and -1.176, respectively, were obtained. The EPM of these macromolecules remained the same when they were bound to latex beads. The S3000 may therefore be suitable for measurement of the EPM of unbound macromolecules. The EPM of T4 phage in solution was measured to be -1.203. However, both the zwitterionic latex-bound T4 phage as well as T4 phage disrupted by ultrasonication exhibited an EPM of approximately -2.50, suggesting to us that binding to zwitterionic latex may cause release of phage DNA. The notion that phage DNA is responsible for the increased negative charge was supported by the observation that the EPM of E. coli B increased to the level of free DNA within 5 min when E. coli B (the host cell for phage T4) had been exposed to 10 phage particles per cell. Electronmicrographs of phage infected E. coli B cells showed numerous strands of free DNA at the bacterial surface. It is concluded that the S3000 not only measures the EPM of macromolecules in solution but that the instrument can be used also to monitor the behavior of the host cell surface in response to attachment of viral particles.

Solution structure of bacteriophage T4D and icosahedral capsid geometry visualized in freeze-fractured, deep-etched replicas

The prolate icosahedral capsid geometry of wild type bacteriophage T4D has been determined by direct visualization of the triangular faces in stereoimages of transmission electron micrographs of phage particles. Bacteriophage T4 was prepared for transmission electron microscopy (TEM) following a protocol of freeze-fracturing, deep-etching (FDET) and replication by vertical deposition (80 degrees angle) of a thin platinum-carbon (Pt-C) metal layer of 1.01 nm. From direct statistical measurements of the ratio of the head length to width and of stereometric angles on T4 heads, we have estimated a Q number of 21. This confirms previous indirect studies on T4 and agrees with determinations on bacteriophage T2. Many of the structural features of T4 observed in FDET preparations differ significantly from those observed by classical negative staining methods for TEM imaging. Most important among the differences are the conformation of the baseplate (a closed rosebud) and the positioning of the tail fibers (retracted). The retracted position of the tail fibers in the FDET preparations has been confirmed by negatively staining phage previously fixed suspended in solution with 2% glutaraldehyde. The FDET protocols appear to reveal important structural features not seen in negative stained preparations. These have implications for bacteriophage T4 conformation in solution, viral assembly and phage conformation states prior to tail contraction and DNA ejection.

The phage T4 uvs Y recombination protein stabilizes presynaptic filaments

The bacteriophage T4 uvsY protein is required for efficient recombination in T4-infected Escherichia coli cells. Previous in vitro work has shown that the purified uvsY protein is an accessory protein; it stimulates homologous pairing catalyzed by the phage uvsX protein (a RecA-like recombinase) under certain conditions. We show here that this effect can be traced, at least in part, to a UvsY-dependent stabilization of uvsX protein-single-stranded DNA complexes. These presynaptic filaments are one of the early obligatory intermediates in the strand exchange reaction between homologous single- and double-stranded DNAs. The mechanism of filament stabilization seems to involve a slower loss of UvsX subunits. A model that accounts for the data is presented in which both recombination proteins are incorporated into the presynaptic filament.

Evidence for a net-like organization of lipopolysaccharide particles in the Escherichia coli outer membrane

Cell wall LPS of Escherichia coli are organized as particles which are visible in the electron microscope, after treatment of the wall with alkali. We now describe alkali treated walls of three E. coli strains with differences in susceptibility to the T4 phage infection. Strain CR63, a usual host for the T4 phage, shows the LPS particles on the murein layer. These particles are absent in alkali treated cell walls of the strain W. Walls of this strain are broken during T4 infection and phages can be seen bearing pieces of membrane attached to their long as well as their short tail fibers. Strain AS19 which is hypersensitive to the lysis from without caused by T4 shows murein layers with no LPS particles on their surface, and networks of LPS particles with bacterial shape. This suggested that LPS are organized in a network of particles which may serve as the skeleton of the cell wall.

Real-time imaging of single DNA molecules with fluorescence microscopy

A fluorescence microscopy technique was used to image the dynamics of individual DNA molecules. Lambda, calf thymus, cosmid (circular), and T4 DNA were studied with the fluorescent dye acridine orange. Experiments with DNAase I were conducted, and the results indicate that these observations correspond to DNA molecules. The results of experiments with circular DNA provide strong evidence that these were single DNA molecules. Molecules were observed free in solution or attached to a glass or copper surface at one or several points. The Brownian motion of these molecules was observed, indicating that DNA in solution exists in a partially supercoiled state. Some molecules appeared stretched and were attached to the surface by their termini; the lengths of these molecules were measured. Such molecules also exhibited elastic behavior upon breaking. The power of this technique is demonstrated in images of cosmid DNA molecules, catenanes, and DNA extending from T4 phage particles. These results suggest immediate applications to molecular biology, such as examining the dynamics of protein-DNA interactions. Areas of ongoing research are discussed.

Bacteriophage T4 late gene expression: overlapping promoters direct divergent transcription of the base plate gene cluster

Eight 5' ends of RNA molecules which encompass the bacteriophage T4 base plate late genes 51 to 26 region have been mapped by S1 nuclease protection and reverse transcription within a 246-bp DNA segment. Two of eight 5' ends are initiated at two absolutely conserved late promoter sites, P51 and P26a, that direct RNA synthesis on opposite strands. These two promoters share four of eight promoter sequence base pairs. A third 5' end arises from another promoter, P26b, which shows one base pair mismatch with respect to the absolutely conserved -10 sequence. All the other 5' ends arise from RNA processing and/or degradation. Since no other late transcription promoter sites were found within the base plate cluster sequence, we propose that the two overlapping late promoters, P51 and P26a, direct the expression of the T4 base plate gene cluster, included between map coordinates 114,000 and 121,038: P51 directs the transcription of genes 51, 27, 28, 29, 48, and 54 on the rDNA strand and P26a the transcription of genes 26 and 25 on the /DNA strand. This peculiar promoter configuration might account for the low level of transcription of these late genes.

A component of the side tail fiber of Escherichia coli bacteriophage lambda can functionally replace the receptor-recognizing part of a long tail fiber protein of the unrelated bacteriophage T4

The distal part of the long tail fiber of Escherichia coli bacteriophage T4 consists of a dimer of protein 37. Dimerization requires the catalytic action of protein 38, which is encoded by T4 and is not present in the virion. It had previously been shown that gene tfa of the otherwise entirely unrelated phage lambda can functionally replace gene 38. Open reading frame (ORF) 314, which encodes a protein that exhibits homology to a COOH-terminal area of protein 37, is located immediately upstream of tfa. The gene was cloned and expressed in E. coli. An antiserum against the corresponding polypeptide showed that it was present in phage lambda. The serum also reacted with the long tail fibers of phage T4 near their free ends. An area of the gene encoding a COOH-terminal region of ORF 314 was recombined, together with tfa, into the genome of T4, thus replacing gene 38 and a part of gene 37 that codes for a COOH-terminal part of protein 37. Such T4-lambda hybrids, unlike T4, required the presence of outer membrane protein OmpC for infection of E. coli B. An ompC missense mutant of E. coli K-12, which was still sensitive to T4, was resistant to these hybrids. We conclude that the ORF 314 protein represents a subunit of the side tail fibers of phage lambda which probably recognize the OmpC protein. ORF 314 was designated stf (side tail fiber). The results also offer an explanation for the very unusual fact that, despite identical genomic organizations, T4 and T2 produce totally different proteins 38. An ancestor of T4 from the T2 lineage may have picked up tfa and stf from a lambdoid phase, thus possibly demonstrating horizontal gene transfer between unrelated phage species.

Normalization procedures and factorial representations for classification of correlation-aligned images: a comparative study

We have addressed the problem of optimizing procedures of multivariate statistical analysis (MSA) for identifying homogeneous sets of electron micrographs of biological macromolecules, with a view to averaging over consistent sets of images. Using pre-aligned images of negatively stained protein molecules - known a priori to fall into two subtly different classes - we compared how the capacity to discriminate between them was affected by the normalization procedure used, and by the choice of factorial representation. Specifically, these images were analyzed both after being scaled according to constant minimum and maximum (CMM) values, and after imposing constant values of image mean and variance (CMV). The factorial representations compared were correspondence analysis (CA) and the principal components (PC) formalism. When used with PC, CMM normalization was found to give rise to spurious inter-image fluctuations that were more pronounced than the genuine difference between the two kinds of images; even with CA, CMV proved to be a more satisfactory method of normalization. When CMV was used with CA or PC, both factorial representations yielded qualitatively similar results, although according to a quantitative measure of inter-set discrimination, the performance of PC was slightly superior. Even in the best case, however, the two classes of images - as mapped in factorial space - were not fully resolved. The implications of this observation are discussed with regard to potential ambiguities of image classification in practice.

Scanning tunneling and transmission electron microscopy on identical areas of biological specimens

A methodology for tip and specimen-support manufacturing is described which allows for scanning tunneling microscopy (STM) and transmission electron microscopy (TEM) on identical areas of biological specimens, at comparable resolution. Topographs and dI/ds-maps were used to investigate tip-specimen interaction on native air-dried phage T4 polyheads where individual capsomeres and structural alterations upon repetitive scans have been observed at a tunnel current of 0.5 pA.

Analysis of near-neighbor contacts in bacteriophage T4 wedges and hubless baseplates by using a cleavable chemical cross-linker

Although bacteriophage T4 baseplate morphogenesis has been analyzed in some detail, there is little information available on the spatial arrangement and associations of its 150 subunits. We have therefore carried out the first analysis of its near-neighbor interactions by using the cleavable chemical cross-linker ethylene glycolbis(succinimidylsuccinate). In this report, we describe the cross-linked complexes that have been identified in the one-sixth arms or wedges and also in baseplatelike structures called rings consisting of six wedges but lacking the central hub, both of which are purified from T4 gene 5- -infected cells. Thirty different complexes were identified, of which about half contain multimers of a single species and half contain two different species. In general, the complexes reflect and support the assembly pathway derived by Kikuchi and King (Y. Kikuchi and J. King, J. Mol. Biol. 99:695-716, 1975) but broaden its scope to include such complexes as gp25-gp53, gp25-gp48, and gp48-gp53, which locate the gp48 binding site over the inner edge of the ring but outside the central hub. The data also supports the view that wedges are assembled from the outer edge inward toward the central hub. Wedge-wedge contact in rings was mediated primarily by gp12 and gp9, the absence of which dramatically destabilized the ring----wedge equilibrium in favor of wedges. Although no heterologous complexes containing gp9 were identified, gp12 contacts unique to rings were observed with both gp10 and gp11.

Imaging of metal-coated biological samples by scanning tunneling microscopy

A method for imaging biological samples by scanning tunneling microscopy (STM) is presented. There are two main difficulties in imaging biological samples by STM: (1) the low conductivity of biological material and (2) finding a method of reliably depositing the sample on a flat conducting surface. The first of these difficulties was solved by coating the samples with a thin film of platinum-carbon. The deposition problem was solved by a method similar to a procedure used to deposit biological molecules onto field ion microscope (FIM) tips. STM images of bacteriophage T7 and filamentous phage fd are shown. The substrate on which the samples were absorbed was atomically flat gold. The images do not show molecular detail due to the metal coating, but the gross dimensions and morphology are correct for each type of virus. Also, the surface density of virus particles increases and decreases in the way expected when the conditions of deposition are changed. These methods allow reliable and reproducible STM imaging of biological samples.