Structure of the tobacco mosaic virus particle; polymerization of tobacco mosaic virus protein

Protein-solvent interaction

Protein folding and assembly can be manipulated in in vitro systems by co-solvents at high concentrations. A number of co-solvents that enhance protein stability and assembly have been shown to be excluded from the protein surface. Such co-solvent exclusion has been demonstrated by dialysis experiments and shown to be correlated with their effects on protein stability and assembly.

Optical trapping of individual human immunodeficiency viruses in culture fluid reveals heterogeneity with single-molecule resolution

Optical tweezers use the momentum of photons to trap and manipulate microscopic objects, contact-free, in three dimensions. Although this technique has been widely used in biology and nanotechnology to study molecular motors, biopolymers and nanostructures, its application to study viruses has been very limited, largely due to their small size. Here, using optical tweezers that can simultaneously resolve two-photon fluorescence at the single-molecule level, we show that individual HIV-1 viruses can be optically trapped and manipulated, allowing multi-parameter analysis of single virions in culture fluid under native conditions. We show that individual HIV-1 differs in the numbers of envelope glycoproteins by more than one order of magnitude, which implies substantial heterogeneity of these virions in transmission and infection at the single-particle level. Analogous to flow cytometry for cells, this fluid-based technique may allow ultrasensitive detection, multi-parameter analysis and sorting of viruses and other nanoparticles in biological fluid with single-molecule resolution.

Small capsid protein pORF65 is essential for assembly of Kaposi's sarcoma-associated herpesvirus capsids

Kaposi's sarcoma-associated herpesvirus (KSHV) is the etiologic agent for KS tumors, multicentric Castleman's disease, and primary effusion lymphomas. Like other herpesvirus capsids, the KSHV capsid is an icosahedral structure composed of six proteins. The capsid shell is made up of the major capsid protein, two triplex proteins, and the small capsid protein. The scaffold protein and the protease occupy the internal space. The assembly of KSHV capsids is thought to occur in a manner similar to that determined for herpes simplex virus type 1 (HSV-1). Our goal was to assemble KSHV capsids in insect cells using the baculovirus expression vector system. Six KSHV capsid open reading frames were cloned and the proteins expressed in Sf9 cells: pORF25 (major capsid protein), pORF62 (triplex 1), pORF26 (triplex 2), pORF17 (protease), pORF17.5 (scaffold protein), and also pORF65 (small capsid protein). When insect cells were coinfected with these baculoviruses, angular capsids that contained internal core structures were readily observed by conventional electron microscopy of the infected cells. Capsids were also readily isolated from infected cells by using rate velocity sedimentation. With immuno-electron microscopy methods, these capsids were seen to be reactive to antisera to pORF65 as well as to KSHV-positive human sera, indicating the correct conformation of pORF65 in these capsids. When either virus expressing the triplex proteins was omitted from the coinfection, capsids did not assemble; similar to observations made in HSV-1-infected cells. If the virus expressing the scaffold protein was excluded, large open shells that did not attain icosahedral structure were seen in the nuclei of infected cells. The presence of pORF65 was required for capsid assembly, in that capsids did not form if this protein was absent as judged by both by ultrastructural analysis of infected cells and rate velocity sedimentation experiments. Thus, a novel outcome of this study is the finding that the small capsid protein of KSHV, like the major capsid and triplex proteins, is essential for capsid shell assembly.

Kinetic properties of fractions of extracellular NAD+ nucleosidase from Streptococcus pyogenes as an example of host selection by a pathogen: possible role of serum albumin in the organism

Preparative isoelectric focusing was used to separate free bacterial NAD+ nucleosidase from its complex with a bound host component. Both fractions were characterized by optimum temperature and activation energy of denaturation. The bacterial product is enzymically inactive. The enzymically active structure is formed upon binding to the host component. Only the host organism can provide the suitable, activating structure. The host component in the present system is added to the cultivation medium with a beef heart extract but it can be replaced by serum albumin. The possible role of albumin as a carrier structure for flexible and enzymically inactive peptides is discussed. Different peptides bound to albumin can provide different enzyme activities. The term binary enzyme is coined, referring to a situation where the two enzyme components are coded at genetically distant loci. The pathogen makes use of the carrier structure of albumin type and produces another polypeptide invested with an enzyme activity convenient for the pathogen.

Limitations of different ELISA procedures for localizing epitopes in viral coat protein subunits

The reactivity of monoclonal antibodies (McAbs) to the coat protein of tobacco mosaic virus (TMVP) with the isolated coat protein, disks, virions and a number of antigenic variants of TMV was tested in eight different ELISA procedures. Although certain McAbs, when used as detecting antibody in the liquid phase, did not react with some of these antigens, they were able to bind to them when used as the capturing antibody on the solid phase. This finding was attributed to the ability of the trapping McAb to induce a complementary conformation in the antigen presented in the liquid phase. In many cases, the reactivity of the McAbs was found to depend on the format of the ELISA. This finding together with the presence of oligomers in viral coat protein preparations made it impossible to map TMVP epitopes on the surface of the viral subunit by means of competitive ELISA.

Assembly and disassembly of bacteriophage T4 polyheads

The assembly of the product of bacteriophage T4 gene 23 (gp23), the uncleaved form of the main shell protein, has been studied. Assembly and disassembly follow the predictions for entropy-driven processes; assembly is strongly favored by conditions of high salt concentrations and high temperatures, whereas low salt and low temperatures promote disassembly. In the absence of the scaffolding core proteins in vitro, only polyheads, the tubular variant of the prohead, are produced. Kinetic studies show that the rate of polyhead dissociation depends on the concentration of associated protein, not on the number and length of the particles. Comparable to crystal formation, assembly of gp23 occurs above a critical concentration, which is dependent on salt concentration, pH and temperature. These characteristics are common to most self-assembling systems. The oligomeric states of gp23 have been investigated by analytical ultracentrifugation, which indicated the existence, at very low salt concentration and low temperature, of an equilibrium between monomers and higher oligomers, culminating in the hexamer. At pH 9.0 polyheads are completely dissociated into their monomeric gp23 subunits. Our data suggest that the hexamer is a true intermediate of polyhead assembly.

Tobacco mosaic virus protein aggregates in solution: structural comparison of 20S aggregates with those near conditions for disk crystallization

Previous X-ray studies (2.8-A resolution) on the crystals of tobacco mosaic virus protein (TMVP) grown from solutions containing high salt have characterized the structure of the protein aggregate as a bilayered cylindrical disk formed by 34 identical subunits [Bloomer, A.C., Champness, J.N., Bricogne, G., Staden, R., & Klug, A. (1978) Nature (London) 276, 362-368]. Under low-salt conditions, 20S aggregates are in equilibrium with 4S species and involved in the efficient nucleation of TMV assembly in vitro [Butler, P.J.G. (1984) J. Gen. Virol. 65, 253-279]. We have investigated by sedimentation velocity and near-UV circular dichroism (CD) measurements the structure of 20S aggregates in low salt (I = 0.1 potassium phosphate at pH 7.0 and 20 degrees C) and the aggregates in high salt [0.2 M (NH4)2SO4 in I = 0.1 tris(hydroxymethyl)aminomethane hydrochloride at pH 8.0 and 20 degrees C, close to the conditions under which TMVP crystallizes as disk aggregates]. At high salt, we observe structures (presumably stacks of disks) having s20,w values around 40, 45, and 50 S, but not the 20S species present in low-salt buffers. The near-UV CD spectrum of 20S aggregates has been obtained for the first time, using computer techniques, from the spectra of the 4S-20S equilibrium mixture and the 4S species. This spectrum of 20S aggregates differs dramatically from that of the stacks of disks examined at both high and low salt (into which the stacks can be returned by dialysis), indicating that the difference is not a solvent effect.(ABSTRACT TRUNCATED AT 250 WORDS)

A reevaluation of the structure of purified tubulin in solution: evidence for the prevalence of oligomers over dimers at room temperature

We studied the molecular form of tubulin in solution by ultrafiltration, nondenaturing electrophoresis, and chemical cross-linking. Our results are not consistent with the generally-held belief that tubulin in solution is a 110,000-mol-wt dimer. Rather, tubulin in solution consists of small oligomers; dimers are a minority species. The small proportion of dimers was readily apparent from ultrafiltration experiments. We first compared the filterability (defined as the ratio of protein concentration in filtrate to that applied to the filter) of phosphocellulose-purified tubulin (PC-tubulin) with aldolase (142,000 mol wt). Using an Amicon XM 300 filter, the filterability of PC-tubulin at room temperature and at a concentration of 0.5 mg/ml was only 0.12, whereas under the same conditions the filterability of aldolase was 0.60. We determined the average effective molecular weight of tubulin from its filterability on XM 300 filters calibrated with standard proteins. At room temperature, PC-tubulin at 0.5 mg/ml had an effective molecular weight of approximately 300,000. This molecular weight was significantly reduced at 10 degrees C, indicating that oligomers dissociated at low temperatures. Oligomers were also demonstrated by chemical cross-linking using glutaraldehyde, dimethyl suberimidate, and bis[2-(succinimidooxycarbonyoxy)ethyl] sulfone. In addition, PC-tubulin ran as a series of discrete bands in a nondenaturing PAGE system at alkaline pH. Quantitative examination of the mobilities of these bands and of standard proteins revealed that the bands represented a series of oligomeric forms. Similar electrophoretic patterns were observed in solutions of tubulin containing microtubule-associated proteins (MAPs) but with a shift to a greater proportion of higher oligomers. Nondenaturing PAGE at pH 8.3 showed that a shift towards higher oligomers also occurred in the absence of MAPs as the concentration of tubulin was increased. This concentration-dependence of oligomerization at room temperature was further demonstrated by ultrafiltration. When solutions of PC-tubulin at concentrations less than 0.25 mg/ml were ultrafiltered, filterability increased as concentration decreased. Quantitative studies of filterability following progressive dilution or concentration showed that this process was completely and rapidly reversible. A diffuse pattern of PC-tubulin on nondenaturing PAGE at pH 7 was observed and is consistent with a mixture of oligomers in rapid equilibrium.(ABSTRACT TRUNCATED AT 400 WORDS)

Studies on the mechanism of assembly of tobacco mosaic virus

Sedimentation and proton binding studies on the endothermic self-association of tobacco mosaic virus (TMV) protein indicate that the so-called "20S" sedimenting protein is an interaction system involving at least the 34-subunit two-turn yield cylindrical disk aggregate and the 49-subunit three-turn helical rod. The pH dependence of this overall equilibrium suggests that disk formation is proton-linked through the binding of protons to the two-turn helix which is not present as significant concentrations near pH 7. There is a temperature-induced intramolecular conformation change in the protein leading to a difference spectrum which is complete in 5 x 10(-6) s at pH 7 and 20 degrees C and is dominated at 300 nm by tryptophan residues. Kinetics measurements of protein polymerization, from 10(-6) to 10(3) s, reveal three relaxation processes at pH 7.0, 20 degrees C, 0.10 M ionic strength K (H) PO4. The fastest relaxation time is a few milliseconds and represents reactions within the 4S protein distribution. The second fastest relaxation is 50-100 x 10(-3) s and represents elementary polymerization steps involved in the formation of the approximately 20 S protein. Analysis of the slowest relaxation, approximately 5 x 10(4) s, suggests that this very slow formation of approximately 20 S protein may be dominated by some first order process in the overall dissociation of approximately 20S protein. Sedimentation measurements of the rate of TMV reconstitution, under the same conditions, show by direct measurements of 4S and approximately 20S incorporation at various 4S to approximately 20S weight ratios that the relative rate of approximately 20S incorporation decreases almost linearly, from 0 to 50% 4S. There appears to be one or more regions of TMV-RNA, approximately 1-1.5 kilobases long, which incorporates approximately 20S protein exclusively. Solutions of approximately 95-100% approximately 20S protein have been prepared for the first time and used for reconstitution with RNA. Such protein solutions yield full size TMV, but at a slower rate than if 4S protein is added. Thus the elongation reaction in TMV assembly, following nucleation with approximately 20S protein, is not exclusively dependent upon the presence of either 4S or approximately 20S protein aggregates. The initial, maximum, rate of reconstitution increases about threefold when the protein composition is changed from 5% to 30% 4S protein, at constant total protein concentration at pH 7.0, 20 degrees C in 0.10 M ionic strength K (H)PO4. The probable binding frame at the internal assembly nucleation site of TMV-RNA has been determined by measuring the association constants for the binding of various trinucleoside diphosphates to helical TMV protein rods. The -CAG-AAG-AAG-sequence at the nucleation site is capable of providing at least 10-14 kcal/mol of sites of binding free energy for the nucleation event in TMV self-assembly.

Kinetics of the polymerization reaction of tobacco mosaic virus protein: transient-saturation type polymerization reaction

The kinetics of the endothermic polymerization reaction of tobacco mosaic virus protein in the mild acid region was studied by means of temperature-jump (rising time of 6 sec)-turbidimetry, electron microscopy, and computer simulation. The time course profile of the turbidity increase changed from a normal one to an anomalous one as the size of the temperature-jump was made greater. The anomalous type polymerization profile, which we named the "transient-saturation" type, could be characterized by a rapid increase of turbidity and its transient saturation, and a slow increase to the final level. At a higher concentration of the protein, this transient-saturation effect was more marked, whereas the slow turbidity in the second phase occurred with a higher rate. This transient-saturation type polymerization profile was observed also in a pH-induced polymerization reaction. It was not observed in the case of the N-bromosuccinimide modified tobacco mosaic virus protein under a similar environmental change. By an electron microscopic study and computer simulation, it was revealed that in the first phase, a large number of short polymers were formed, and the concentration of the polymerizing units was rapidly reduced to the equilibrium value, and the polymerization reaction stopped transiently. In the second phase, polymer-polymer associations took place slowly and longer polymers were formed. The revlevance of the present study to the polymerization reaction of actin, myosin, and to a transient-overshoot type polymerization are discussed.

Striated fibers of the rho form of Mycoplasma: in vitro reassembly, composition, and structure

The rho-form of Mycoplasma contains a striated, axial fiber and associated terminal structure. The presence of this organelle was correlated with the synthesis of two proteins, A and B, of molecular weights of approximately 85,000 and 26,000, respectively, each accounting for about 10% of the total cell protein. Their amino acid compositions showed them to have distinct polypeptide chains. After osmotic lysis of rho-form cells the organelles disappeared; protein A accompanied the membrane fraction, whereas protein B was partly released in soluble form. After lysis by Nonidet P-40 in a medium composed of 4 M glycerol, 50 mM phosphate, and 10 mM MgSO4 at pH 6 (GPM-6), the organelles were preserved and released with ultrastructure unchanged. Protein A was recovered in the soluble fraction and protein B in the particulate (crude fiber) fraction. Treatment of the crude fiber fraction with 0.5 M NaCl in GPM-6 or with a solution containing 4 M glycerol, 10 mM morpholinoethanesulfonate, and 1 mM ethylenediaminetetraacetate at pH 7.0 caused the fibers to disassemble into subunits. By subsequent changes in the ionic conditions and temperature it was possible to cause the subunits to reassemble into ordered aggregates having the same ultrastructure as the native rho-fibers. The optimum temperature for reassembly in the presence of 4 M glycerol was 37 C, the optimum pH was 6.5 to 7.0, and the presence of Mg-2+, replaceable by Ca-2+, SR-2+, or Ba-2+, was essential. Protein B was the only protein detected in the purified, reconsituted fibers.

A prediction of the structure of tobacco-mosaic-virus protein

The location of amino acid residues within the tobacco mosaic virus protein subunit is discussed. Sequence data, X-ray crystallographic measurements, and the availability of specific residues for enzymic, immunological or chemical reaction are amongst the information used to trace roughly how the tobacco mosaic virus polypeptide chain winds in and out from the virus axis. Published rules for predicting secondary structure are then applied to obtain a diagram of the course of the polypeptide chain. This map should be useful for the interpretation of X-ray diffraction data and already permits an outline of the main features of the inner third of subunit to be suggested.

The reactivity of functional groups as a probe for investigating the topography of tobacco mosaic virus. The use of mutants with additional lysine residues in the coat protein

Several mutants of tobacco mosaic virus that contain additional lysine residues as a result of mutations in the coat protein were investigated. Mutant E66 has a lysine residue replacing asparagine at position 140 when compared with the wild-type vulgare and this lysine residue reacts readily in the intact virus with methyl picolinimidate. Mutant B13a has two new lysine residues in the coat protein, replacing a glutamine at position 9 and an asparagine at position 33, whereas mutant B13b has the single replacement of glutamine by lysine at position 9. The lysine residue at position 9 in mutants B13a and B13b also reacts readily with methyl picolinimidate in the intact virus but the lysine at position 33 in mutant B13a did not react under these conditions. However, when the isolated coat protein from mutant B13a was treated with methyl picolinimidate, the lysine residue at position 33 did become modified, showing that the loss in reactivity of this residue towards the imidoester in the intact virus is a result of the assembly of the protein subunit into the virus structure. These results are compatible with and extend previous studies on the sero-logical properties of mutants of tobacco mosaic virus and illustrate the value of methyl picolinimidate as a reagent for probing the accessibility of amino groups in proteins. When intact tobacco mosaic virus (vulgare) was treated with p-iodobenzenesulphonyl chloride, no reaction with the lysine residues at positions 33 or 68 in the virus subunit could be detected but complete modification of tyrosine-139 was achieved. This result also extends previous studies with other reagents. The usefulness of the differential reactivity of the lysine residues in tobacco mosaic virus and its mutants as a means of attaching heavy-atom labels at chemically defined positions for subsequent X-ray-diffraction analysis and the implications of these experiments for deciphering the folding of the peptide chain in the virus subunit are discussed.

Circular dichroism studies on coat proteins of some strains and mutants of tobacco mosaic virus

1. Tobacco mosaic virus (TMV) protein has in near ultraviolet a complex but well resolved circular dichroism (CD) spectrum at room temperature. There are seven positive bands at 248, 252, 257, 265, 274, 281 and 291 nm, and a negative one at 296 nm. The CD spectrum is pH-dependent. The shape of the pH-dependence curves and the comparison with CD spectra of model compounds suggest that the bands at 248, 252 and 257 nm are mainly caused by phenylalanyl, those at 265, 274 and 281 nm by tyrosyl, and those at 291 and 296 nm by tryptophanyl side chains. 2. Only insignificant changes of the tertiary structure seem to occur between pH 6.5 and 8.5. Changes in ellipticity of TMV protein during the pH-induced polymerization reaction suggest that: (1) tyrosyl residues are involved in the binding of subunits, (2) phenylalanyl residues seem to be transferred to a less rigid environment, and (3) tryptophanyl residues are not essential for the reaction. 3. The proteins of several TMV strains and mutants studied have similar far ultraviolet CD spectra and apparently do not differ significantly in their structure. Their near ultraviolet CD spectra are, however, different. Replacements involving aliphatic amino acids do not change considerably the near ultraviolet CD spectra. On the other hand, replacements involving aromatic amino acids have a great effect on the spectra rendering possible identification of CD bands and recognition of the aromatic amino acid residues responsible for optical activity.