ASSEMBLY AND STABILITY OF THE TOBACCO MOSAIC VIRUS PARTICLE

Solution X-ray scattering study of reconstitution process of tobacco mosaic virus particle using low-temperature quenching

The reconstitution process of tobacco mosaic virus (TMV) was investigated by the solution X-ray scattering measurements with the synchrotron radiation source using low-temperature quenching. TMV assembly in an aqueous solution is completely stopped below 5 degrees C. The TMV assembly was traced by the small-angle X-ray scattering (SAXS) measurements at 5 degrees C on a series of solutions prepared by low-temperature quenching after incubation either at 15, 20 or 25 degrees C for an appropriate interval between 0 and 60 min. The SAXS results were analyzed by the Guinier plot, the Kratky plot and the distance distribution function. In order to account the time course of SAXS profiles in terms of the elongation of TMV assembly, a model calculation was performed to simulate the Guinier plot, the Kratky plot and the distance distribution function by applying Glatter's multibody method using models that were constituted of the spheres representing a column of piled two-layer disks of TMV-protein. The three simulated functions thus obtained support the conclusion derived from the three functions calculated from the experimental results that the incubation of the RNA and protein of TMV began to reconstitute TMV instantly after mixing, proceeded steeply to a long rod, and then extended asymptotic to the full length of the TMV particle. This process is in good agreement with that obtained from electron microscopic studies.

Site-directed mutagenesis confirms the involvement of carboxylate groups in the disassembly of tobacco mosaic virus

Electrostatic repulsion between carboxylate groups across subunit interfaces has for many years been recognized as important in the disassembly of simple plant viruses. In the coat protein of tobacco mosaic virus (TMV), the amino acids Glu50 and Asp77 have been proposed as examples of such carboxylate groups. Site-directed mutagenesis has been used to replace these amino acids by Gln and Asn, respectively. Increased virion stability, together with reduced infectivity and reduced capacity for long-distance transport within the host plant confirms that the negative charges on the side chains of these amino acids are involved in the disassembly of TMV. Mixing purified mutant coat proteins with wild-type virions under appropriate conditions stabilizes the virions to alkaline disassembly and reduces their infectivity. It is suggested that transgenic plants expressing such mutant coat proteins could have enhanced resistance to virus infection.

Stereospecific dihaloalkane binding in a pH-sensitive cavity in cubic insulin crystals

Crystallographic analysis at 2-A resolution of the selective binding of dihalogenated methane, ethane, and ethylene compounds in the cavity on the cubic insulin dimer axis provides a model for anesthetic-protein interactions. At pH 6-11, 1,2-dichloroethane binds isomorphically in the right-handed cis-conformation, displacing four water molecules from the invariant cavity. Lowering the pH to 5.7 in 1 M Na2SO4 without dihaloalkanes induces a cooperative structural transition in which the dyad cavities between B13 glutamate pairs are constricted, and SO4(2-) ions are bound by rearranged triads of B1 NH+3 groups. In the presence of dichloroethane at pH 5-5.5, the equilibrium is shifted to a mixture of the ligand-bound and ligand-excluding cavity structures, with half-occupancy of the sulfate sites, exemplifying how a volatile anesthetic can act as an allosteric effector. Measurements at pH 9 of the occupancies of structurally similar dihaloalkanes demonstrate a high degree of binding selectivity. Induced polarization of the ligand and bound water by the charge distribution in the binding cavity apparently provides the selective electrostatic interactions that discriminate between dihaloalkanes of comparable size and polarity.

Expression of tobacco mosaic virus coat protein and assembly of pseudovirus particles in Escherichia coli

The bidirectional self-assembly of tobacco mosaic virus (TMV, common or U1 strain) has been studied extensively in vitro. Foreign single-stranded RNA molecules containing the TMV origin-of-assembly sequence (OAS, 75-432 nt in length) are also packaged by TMV coat protein (CP) in vitro to form helical pseudovirus particles. To study virus assembly in vivo requires an easily manipulated model system, independent of replication in plants. The TMV assembly machinery also provides a convenient means to protect and recover chimeric gene transcripts of almost any length or sequence for a variety of applications. Native TMV CP expressed in and purified from Escherichia coli formed nonhelical, stacked aggregates after dialysis into pH 5 buffer and was inactive for in vitro assembly with TMV RNA. U1 CP derivatives in which the second amino acid was changed from Ser to Ala or Pro, nonacetylated N termini found in two natural strains of the virus, failed to remediate these anomalous properties. However, in vivo coexpression of CP and single-stranded RNAs (up to approximately 2 kb) containing the TMV OAS gave high yields of helical pseudovirus particles of the predicted length (up to 7.4 +/- 1.4 micrograms/mg of total bacterial protein). If the OAS-containing RNA was first recruited into bacterial polyribosomes, elongation of pseudovirus assembly was blocked. In vivo, E. coli expression of a full-length cDNA clone of the TMV genome (6.4 kb) resulted in high, immunodetectable levels of CP and assembly of sufficient intact genomic RNA to initiate systemic infection of susceptible tobacco plants.

Roles of FliK and FlhB in determination of flagellar hook length in Salmonella typhimurium

The length of flagellar hooks isolated from wild-type and mutant cells with various hook lengths were measured on electron micrographs. The length of the wild-type hook showed a narrow distribution with a peak (+/- standard deviation) at 55.0 +/- 5.9 nm, whereas fliK mutants (so-called polyhook mutants) showed a broad distribution of hook lengths ranging from 40 to 900 nm, strongly indicating that FliK is involved in hook length determination. Among pseudorevertants isolated from such polyhook mutants, fliK intragenic suppressors gave rise to polyhook filaments. However, intergenic suppressors mapping to flhB also gave rise to hooks of abnormal length, albeit they were much shorter than polyhooks. Furthermore, double mutations of flhB and flgK (the structural gene for hook-associated protein 1; HAP1) resulted in polyhooks, suggesting another way in which hook length can be affected. The roles of FliK, FlhB, and HAP1 in hook length determination are discussed.

Assembly of tobacco mosaic virus and TMV-like pseudovirus particles in Escherichia coli

High-level expression of plant viral proteins, including coat protein (CP), is possible in Escherichia coli. Native tobacco mosaic virus (TMV) CP expressed in E. coli remains soluble but has a non-acetylated N-terminal Ser residue and following extraction, is unable to package TMV RNA in vitro under standard assembly conditions. Changing the Ser to Ala or Pro by PCR-mutagenesis did not confer assembly competence in vitro, despite these being non-acetylated N-termini present in two natural strains of TMV. All TMV CPs made in E. coli formed stacked cylindrical aggregates in vitro at pH 5.0 and failed to be immunogold-labelled using a mouse monoclonal antibody specific for helically assembled TMV CP. TMV self-assembly has been studied extensively in vitro, and an origin of assembly sequence (OAS) mapped internally on the 6.4 kb ssRNA genome. Pseudovirus particles can be assembled mono- or bi-directionally in vitro using virus-derived CP and chimeric ssRNAs containing the cognate TMV OAS, but otherwise of unlimited length and sequence. Studies on plant virus assembly in vivo would be facilitated by a model system amenable to site-directed mutagenesis and rapid recovery of progeny particles. When chimeric transcripts containing the TMV OAS were co-expressed with TMV CP in vivo for 2-18 h, helical TMV-like ribonucleoprotein particles of the predicted length were formed in high yield (up to 7.4 micrograms/mg total bacterial protein). In addition to providing a rapid, inexpensive and convenient system to produce, protect and recover chimeric gene transcripts of any length or sequence, this E. coli system also offers a rapid approach for studying the molecular requirements for plant virus "self-assembly" in vivo. Transcription of a full-length cDNA clone of TMV RNA also resulted in high levels of CP expression and assembly of sufficient intact genomic RNA to initiate virus infection of susceptible tobacco plants.

The mechanism of Ca(2+)-coordination in the EF-hand of TnC, by cassette mutagenesis

Genetic engineering of TnC and skinned fiber physiology on rabbit psoas muscle are combined to study the mechanisms of Ca(2+)-binding in the EF-hand in TnC. Of the six coordinating positions (X,Y,Z,-Y,-X & -Z) for Ca(2+)-binding in the loop, the X position is invariably occupied by an aspartate, and the -Z position by a glutamate. X-ray analysis has indicated that both oxygen atoms of the beta-carboxylate in aspartate (in X) are extensively hydrogen bonded to other residues in the loop. When this aspartate in site II was replaced by a glutamate (gamma-carboxylate), Ca(2+)-binding was annihilated, and the mutant was unable to regulate force development in the fiber. Similarly, glutamate for aspartate exchange in the -Z position of site I also inactivated the site as well as its function in skinned fiber. Mutations in the Y position indicated that a glutamate was unacceptable in place of aspartate but that an asparagine was acceptable. The Ca(2+)-sensitivity with asparagine was also similar to that of the wild type. The study indicates a powerful approach for defining the physicochemical principles governing Ca-coordination and sensitivity in Ca-binding proteins. Furthermore, by comparison with findings on chemically synthesized peptides, the results show that behavior of the EF-hand in TnC is modified by quaternary structure of the molecule.

Developments in the understanding of the particle structure of tobraviruses

Particles of tobraviruses resemble those of tobacco mosaic tobramovirus (TMV) in having helical symmetry and in being rod-shaped. However, isolated tobravirus coat protein and TMV coat protein respond to changes in the ionic strength and pH of the solute in contrasting ways. The types of aggregate formed in solutions of coat protein also differ which may be related to differences in the apparent mechanism of reconstitution of virus particles from isolated protein and RNA. The amino acid sequences of tobravirus and tobramovirus coat proteins have been shown to be similar in some regions known to be important for the structure of TMV particles. These alignments also show that tobravirus proteins are larger than tobramoviral proteins in part because of extra residues at the C-terminus. Tobravirus particles give a signal in proton NMR spectroscopy but TMV particles do not. The signal is caused by segmental mobility of the C-terminal peptide. This difference between TMV and tobraviruses may be related to a property not shared by tobraviruses and TMV and it is therefore speculated that the mobile C-terminal peptide of tobravirus coat proteins may be important in the transmission of tobravirus particles by nematode vectors.

Structure of the U2 strain of tobacco mosaic virus refined at 3.5 A resolution using X-ray fiber diffraction

The structure of the U2 strain of tobacco mosaic virus (TMV) has been determined by fiber diffraction methods at 3.5 A resolution, and refined by a combination of restrained least-squares and molecular dynamics methods to an R-factor of 0.096. The structure is extremely similar to that of the common strain of TMV, with the largest differences being in the protein loop that makes up the inner surface of the virus, and in the C-terminal region on the outer surface. Differences in the inner loop can be correlated with differences in the properties of the two viruses.

Structure of tobraviral particles: a model suggested from sequence conservation in tobraviral and tobamoviral coat proteins

Comparisons of the coat protein sequences of four tobraviruses with those of seven tobamoviruses indicate that these proteins share a common evolutionary origin. Numerous amino acids for which specific functions have been identified in the molecular structure of the tobacco mosaic virus vulgare protein have identical or closely similar counterparts among the tobraviral proteins. These include those with roles in the hydrophobic core of the protein, those that contribute to the RNA binding site and those involved in the control of virus assembly. We suggest a model for the structure of the tobraviral particle that not only offers an explanation for the greater diameter of the tobraviral particle but also confirms an early suggestion for RNA placement within this particle.

Direct visualization of the structure of the "20 S" aggregate of coat protein of tobacco mosaic virus. The "disk" is the major structure at pH 7.0 and the Proto-helix at lower pH

We have employed the rapid-freeze technique to prepare specimens for electron microscopy of a coat protein solution of tobacco mosaic virus at equilibrium at pH 7.0 and 6.8, ionic strength 0.1 M and 20 degrees C. The former are the conditions for the most rapid assembly of the virus from its isolated protein and RNA. At both pH values, the equilibrium mixture contains approximately 80% of a "20 S" aggregate and 20% of a "4 S" aggregate (the so-called A-protein). The specimens were prepared either totally unstained or positively stained with methyl mercury nitrate, which binds to an amino acid residue (Cys27) internally located within the subunit, which we show not to affect the virus assembly. The images in the electron microscope are compatible only with the major structure for the "20 S" aggregate at pH 7.0 containing two rings of subunits and these aggregates display the same binding contacts as those seen between the aggregate that forms the asymmetric unit in the crystal, which has been shown by X-ray crystallography to be a disk containing two rings, each of 17 subunits, oriented in the same direction. In contrast, the images from specimens prepared at pH 6.8 show the major structure to be a proto-helix at this slightly lower pH, demonstrating that the technique of cryo-electron microscopy is capable of distinguishing between these aggregates of tobacco mosaic virus coat protein. The main structure in solution at pH 7.0 must therefore be very similar to that in the crystal, although slight differences could occur and there are probably other, minor, components in a mixture of species sedimenting around 20 S under these conditions. The equilibrium between aggregates is extremely sensitive to conditions, with a drop of 0.2 pH unit tipping the disk to proto-helix ratio from approximately 10:1 at pH 7.0 to 1:10 at pH 6.8. This direct determination of the structure of the "20 S" aggregate in solution, under conditions for virus assembly, contradicts some recent speculation that it must be helical, and establishes that, at pH 7.0, it is in fact predominantly a two-layer disk as it had been modelled before.

Characterization of a putative calcium-binding site in tobacco mosaic virus

Lead has been used as a substitute for calcium binding to tobacco mosaic virus (TMV). The high atomic number of lead has allowed us to use difference maps from X-ray fiber diffraction data to characterize a calcium-binding site in the virus. The metal ligands are slightly different from those previously believed to bind calcium to TMV, although the binding site is very close to one previously described. Two acetate groups are also bound to the lead atom. There is no significant backbone conformational change in the protein as a result of metal binding; the binding is accomplished by means of relatively small movements in amino acid side chains.

Normal modes of symmetric protein assemblies. Application to the tobacco mosaic virus protein disk

We use group theoretical methods to study the molecular dynamics of symmetric protein multimers in the harmonic or quasiharmonic approximation. The method explicitly includes the long-range correlations between protein subunits. It can thus address collective dynamic effects, such as cooperativity between subunits. The n lowest-frequency normal modes of each individual subunit are combined into symmetry coordinates for the entire multimer. The Hessian of the potential energy is thereby reduced to a series of blocks of order n or 2n. In the quasiharmonic approximation, the covariance matrix of the atomic oscillations is reduced to the same block structure by an analogous set of symmetry coordinates. The method is applied to one layer of the tobacco mosaic virus protein disk in vacuo, to gain insight into the role of conformational fluctuations and electrostatics in tobacco mosaic virus assembly. The system has 78,000 classical, positional, degrees of freedom, yet the calculation is reduced by symmetry to a problem of order 4,600. Normal modes in the 0-100 cm-1 range were calculated. The calculated correlations extend mainly from each subunit to its nearest neighbors. The network of core helices has weak correlations with the rest of the structure. Similarly, the inner loops 90-108 are uncorrelated with the rest of the structure. Thus, the model predicts that the dielectric response in the RNA-binding region is mainly due to the loops alone.

Alleged common antigenic determinant of tobacco mosaic virus coat protein and the host protein ribulose-1,5-bisphosphate carboxylase is an artifact of indirect ELISA and western blotting

We have reported the detection of an antigenic determinant shared by the tobacco mosaic virus coat protein and the large subunit of ribulose-1,5-bisphosphate carboxylase, a host protein (R.G. Dietzgen and M. Zaitlin Virology 155, 262-266, 1986). This conclusion was questioned by D. Zimmermann and M.H.V. Van Regenmortel (Arch. Virol. 106, 15-22, 1989). Thus we have reinvestigated this unexpected serological cross-reaction in Western immunoblotting and indirect ELISA. We found that when skimmed milk instead of bovine serum albumin was used as a blocking agent and as a diluent for antibodies and alkaline phosphatase conjugates, the alleged cross-reaction was abolished. In light of these findings, we retract our previous conclusions.

Small angle x-ray scattering of chromatin. Radius and mass per unit length depend on linker length

Analyses of low angle x-ray scattering from chromatin, isolated by identical procedures but from different species, indicate that fiber diameter and number of nucleosomes per unit length increase with the amount of nucleosome linker DNA. Experiments were conducted at physiological ionic strength to obtain parameters reflecting the structure most likely present in living cells. Guinier analyses were performed on scattering from solutions of soluble chromatin from Necturus maculosus erythrocytes (linker length 48 bp), chicken erythrocytes (linker length 64 bp), and Thyone briareus sperm (linker length 87 bp). The results were extrapolated to infinite dilution to eliminate interparticle contributions to the scattering. Cross-sectional radii of gyration were found to be 10.9 +/- 0.5, 12.1 +/- 0.4, and 15.9 +/- 0.5 nm for Necturus, chicken, and Thyone chromatin, respectively, which are consistent with fiber diameters of 30.8, 34.2, and 45.0 nm. Mass per unit lengths were found to be 6.9 +/- 0.5, 8.3 +/- 0.6, and 11.8 +/- 1.4 nucleosomes per 10 nm for Necturus, chicken, and Thyone chromatin, respectively. The geometrical consequences of the experimental mass per unit lengths and radii of gyration are consistent with a conserved interaction among nucleosomes. Cross-linking agents were found to have little effect on fiber external geometry, but significant effect on internal structure. The absolute values of fiber diameter and mass per unit length, and their dependencies upon linker length agree with the predictions of the double-helical crossed-linker model. A compilation of all published x-ray scattering data from the last decade indicates that the relationship between chromatin structure and linker length is consistent with data obtained by other investigators.

Dynamic mechanism of the self-assembly process of tobacco mosaic virus protein studied by rapid temperature-jump small-angle X-ray scattering using synchrotron radiation

The self-assembly process of tobacco mosaic virus protein (TMVP) was observed by rapid temperature-jump time-resolved solution X-ray small-angle scattering using synchrotron radiation. The temperature-jump device used for the X-ray measurements is rapid enough to cope with even the fastest-assembling process of TMVP, and accumulates data of reasonable signal-to-noise ratios with a minimum total counting time of 7.5 seconds. The measurements suggested that the 20 S disk of TMVP polymerized to stacked disks (short rods). The time to complete stacking varied from approximately 25 seconds to approximately 1200 seconds, depending on the solution condition and magnitude of the temperature gap. Higher protein concentration, ionic strength and temperature favoured faster association. The results were analysed in terms of a set of kinetic equations that describe the two-stage aggregation of TMVP with an equilibrium constant K1, and two rate constants k+2 and k-2 for association and dissociation of disks, respectively. The consistency of the analysis suggests that the TMVP assembly proceeds in two steps of: (1) the aggregation of A-proteins into double-layered disks; and (2) the stacking of double-layered disks. The kinetic analysis indicated that the stacking belongs to the lowest range of protein-protein interaction system.

Preparation and properties of recombinant DNA derived tobacco mosaic virus coat protein

Recombinant DNA derived tobacco mosaic virus (vulgare strain) coat protein (r-TMVP) was obtained by cloning and expression in Escherichia coli and was purified by column chromatography, self-assembly polymerization, and precipitation. SDS-PAGE, amino terminal sequencing, and immunoblotting with polyclonal antibodies raised against TMVP confirmed the identify and purity of the recombinant protein. Isoelectric focusing in 8 M urea and fast atom bombardment mass spectrometry demonstrated that the r-TMVP is not acetylated at the amino terminus, unlike the wild-type protein isolated from the tobacco plant derived virus. The characterization of r-TMVP with regard to its self-assembly properties revealed reversible endothermic polymerization as studied by analytical ultracentrifugation, circular dichroism, and electron microscopy. However, the details of the assembly process differed from those of the wild-type protein. At neutral pH, low ionic strength, and 20 degrees C, TMVP forms a 20S two-turn helical rod that acts as a nucleus for further assembly with RNA and additional TMVP to form TMV. Under more acidic conditions, this 20S structure also acts as a nucleus for protein self-assembly to form viruslike RNA-free rods. The r-TMVP that is not acetylated carries an extra positive charge at the amino terminus and does not appear to form the 20S nucleus. Instead, it forms a 28S four-layer structure, which resembles in size and structure the dimer of the bilayer disk formed by the wild-type protein at pH 8.0, high ionic strength, and 20 degrees C.(ABSTRACT TRUNCATED AT 250 WORDS)

Polarity of binding of monoclonal antibodies to tobacco mosaic virus rods and stacked disks

Monoclonal antibodies to tobacco mosaic virus that bind only to one end of the viral rods have been shown to recognize the surface of the protein subunit designated as the bottom, which contains the right radial and left radial alpha-helices. The specificity of the antibody binding was established by immunoelectron microscopy of complexes in which the 5' end of the RNA had been exposed at the bottom of the helical virus particle. These antibodies have been shown to bind to both ends of the stacked disk aggregate of TMV protein, which is therefore bipolar. The observations on the bipolarity of this structure are inconsistent with the presumption that stacked disks are formed by aggregation of polar two-layer disks.

Polymorphism in the assembly of polyomavirus capsid protein VP1

Polyomavirus major capsid protein VP1, purified after expression of the recombinant gene in Escherichia coli, forms stable pentamers in low-ionic strength, neutral, or alkaline solutions. Electron microscopy showed that the pentamers, which correspond to viral capsomeres, can be self-assembled into a variety of polymorphic aggregates by lowering the pH, adding calcium, or raising the ionic strength. Some of the aggregates resembled the 500-A-diameter virus capsid, whereas other considerably larger or smaller capsids were also produced. The particular structures formed on transition to an environment favoring assembly depended on the pathway of the solvent changes as well as on the final conditions. Mass measurements from cryoelectron micrographs and image analysis of negatively stained specimens established that a distinctive 320-A-diameter particle consists of 24 close-packed pentamers arranged with octahedral symmetry. Comparison of this unexpected octahedral assembly with a 12-capsomere icosahedral aggregate and the 72-capsomere icosahedral virus capsid by computer graphics methods indicates that similar connections are made among trimers of pentamers in these shells of different size. The polymorphism in the assembly of VP1 pentamers can be related to the switching in bonding specificity required to build the virus capsid.

Assembly of hybrid RNAs with tobacco mosaic virus coat protein. Evidence for incorporation of disks in 5'-elongation along the major RNA tail

We have shown that during the reassembly of tobacco mosaic virus (TMV) RNA, with the coat protein supplied as a "disk preparation", the lengths of RNA protected from nuclease are "quantized" with steps which correspond to incorporation of the subunits from either a single or, more commonly, both rings of a disk. This interpretation has been challenged and it was suggested that the pattern was due to special, though unspecified features of the sequence of TMV RNA. To test whether the specific sequence of TMV RNA is important during the elongation, rather than just during nucleation, we have now followed growth of particles containing hybrid RNAs, with the TMV RNA origin of assembly but otherwise non-TMV sequences. We have prepared in vitro RNA transcripts containing heterologous RNA 5' to the origin of assembly sequence from TMV RNA, i.e. with a heterologous RNA tail in place of the natural major 5'-tail and no minor tail, and used these for assembly experiments. In each case we observe a banding pattern very similar to that which we had found with native TMV RNA and with a dominant quantum step of just over 100 bases, and sometimes also a step of 50 bases, strongly suggesting that this is not due to any feature of the TMV RNA. This same repeat is also visible even with a heterologous RNA chosen because it had a sequence repeat of 135 or 136 bases, confirming that the quantization is due to a feature of the elongation reaction and in no way to the RNA sequence being encapsidated. We have also followed elongation with the origin of assembly located 5' to the heterologous RNA. This leads to a slower elongation along this 3'-tail, after the initial rapid encapsidation of the origin RNA, which lacks any quantization of length protected. These results are fully compatible with the hypothesis we had advanced earlier, that the major growth along the 5'-tail is from performed aggregates ("disks") while the minor growth along the 3'-tail is from subunits in the "A-protein" adding singly or a few at a time.

Structure-function relationships of icosahedral plant viruses

X-ray diffraction studies on single crystals of a few viruses have led to the elucidation of their three dimensional structure at near atomic resolution. Both the tertiary structure of the coat protein subunit and the quaternary organization of the icosahedral capsid in these viruses are remarkably similar. These studies have led to a critical re-examination of the structural principles in the architecture of isometric viruses and suggestions of alternative mechanisms of assembly. Apart from their role in the assembly of the virus particle, the coat proteins of certian viruses have been shown to inhibit the replication of the cognate RNA leading to cross-protection. The coat protein amino acid sequence and the genomic sequence of several spherical plant RNA viruses have been determined in the last decade. Experimental data on the mechanisms of uncoating, gene expression and replication of several classes of viruses have also become available. The function of the non-structural proteins of some viruses have been determined. This rapid progress has provided a wealth of information on several key steps in the life cycle of RNA viruses. The function of the viral coat protein, capsid architecture, assembly and disassembly and replication of isometric RNA plant viruses are discussed in the light of this accumulated knowledge.

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.

Visualization of protein-nucleic acid interactions in a virus. Refined structure of intact tobacco mosaic virus at 2.9 A resolution by X-ray fiber diffraction

The structure of tobacco mosaic virus (TMV) has been determined by fiber diffraction methods at 2.9 A resolution, and refined by restrained least-squares to an R-factor of 0.096. Protein-nucleic acid interactions are clearly visible. The final model contains all of the non-hydrogen atoms of the RNA and the protein, 71 water molecules, and two calcium-binding sites. Viral disassembly is driven by electrostatic repulsions between the charges in two carboxyl-carboxylate pairs and a phosphate-carboxylate pair. The phosphate-carboxylate pair and at least one of the carboxyl-carboxylate pairs appear to be calcium-binding sites. Nucleotide specificity, enabling TMV to recognize its own RNA by a repeating pattern of guanine residues, is provided by two guanine-specific hydrogen bonds in one of the three base-binding sites.

Mechanisms of cooperativity and allosteric regulation in proteins

AUosteric proteins control and coordinate chemical events in the living cell. When Monod conceived that idea he said that he had discovered the second secret of life. The first was the structure of DNA. The theory as published by Monodet al.(1963) was concerned chiefly with cooperativity and feedback inhibition of enzymes, such as the inhibition of threonine deaminase, the first enzyme in the pathway of the synthesis of isoleucine, by isoleucine, and its activation by valine. Two years later the theory was formalized by Monodet al.(1965).

Temperature dependence of the structure of aggregates of tobacco mosaic virus protein at pH 7.2. Static synchrotron small-angle X-ray scattering

The small-angle X-ray scattering (SAXS) method using a synchrotron radiation source was applied to the study of the self-aggregation process of tobacco mosaic virus protein (TMVP) at a concentration of 5.0 or 12.0 mg ml-1 in 50 mM or 100 mM-phosphate buffer (ionic strengths approx. 0.1 and 0.2, respectively) at pH 7.2 in the temperature region of 4.8 to 25.0 degrees C. This paper presents the results of static measurements of SAXS. Sedimentation velocity experiments were performed simultaneously under the same conditions. These results are qualitatively parallel to those of the SAXS measurements, although the size of stacked disks derived from the SAXS measurements is larger than that derived from the sedimentation experiments, suggesting a change in the equilibrium conditions in the centrifugal field. Qualitative analysis of the SAXS data with model simulation calculations implies that the aggregation of TMVP consists of two steps: (1) the aggregation of A-protein comprising a few subunits to form double-layered disks; and (2) the random polymerization of double-layered disks by disk-stacking. Increase in temperature, ionic strength or protein concentration induced TMVP to polymerize to form a double-layered disk or a quadruple-layered short rod with consumption of A-proteins, accompanied by a small number of multi-layered short rods. The SAXS results indicate that the A-protein and the multilayered short rods are polydisperse with respect to size and shape, i.e. the mixture of A-protein, double-layered disks and multi-layered short rods coexists in the equilibrium state without pressure-induced partial dissociation of TMPV as observed during normal ultracentrifugation, and even under solution conditions in which the formation of double-layered disks or higher-order aggregates is favored.

The structure of tubes of bovine rotavirus nucleocapsid protein (VP6) assembled in vitro

The structure of tubes of reassembled nucleocapsid protein (VP6) from bovine rotavirus (BRV) was determined using optical diffraction of electron micrographs. The tubes consist of a five-start helix of hexagons, with 38 hexagons per helix in a true repeat of three turns. The morphological subunits comprising the hexagons are probably elongated trimers. The structure of naturally occurring tubes (D. Chasey and J. Labram, 1983, J. Gen. Virol. 64, 863-872) was also examined and shown to be similar but not identical to that of tubes assembled in vitro. Considerations of the assembly process are discussed.

The tobacco mosaic virus assembly origin RNA. Functional characteristics defined by directed mutagenesis

The in vitro reassembly of tobacco mosaic virus (TMV) begins with the specific recognition by the viral coat protein disk aggregate of an internal TMV RNA sequence, known as the assembly origin (Oa). This RNA sequence contains a putative stem-loop structure (loop 1), believed to be the target for disk binding in assembly initiation, which has the characteristic sequence AAGAAGUCG exposed as a single strand at its apex. We show that a 75-base RNA sequence encompassing loop 1 is sufficient to direct the encapsidation by TMV coat protein disks of a heterologous RNA fragment. This RNA sequence and structure, which is sufficient to elicit TMV assembly in vitro, was explored by site-directed mutagenesis. Structure analysis of the RNA identified mutations that appear to effect assembly via a perturbation in RNA structure, rather than by a direct effect on coat protein binding. The binding of the loop 1 apex RNA sequence to coat protein disks was shown to be due primarily to its regularly repeated G residues. Sequences such as (UUG)3 and (GUG)3 are equally effective at initiating assembly, indicating that the other bases are less functionally constrained. However, substitution of the sequences (CCG)3, (CUG)3 or (UCG)3 reduced the assembly initiation rate, indicating that C residues are unfavourable for assembly. Two additional RNA sequences within the 75-base Oa sequence, both of the form (NNG)3, may play subsidiary roles in disk binding. RNA structure plays an important part in permitting selective protein-RNA recognition, since altering the RNA folding close to the apex of the loop 1 stem reduces the rate of disk binding, as does shortening the stem itself. Whereas the RNA sequence making up the hairpin does not in general affect the specificity of the protein-RNA interaction, it is required to present the apex signal sequence in a special conformation. Mechanisms for this are discussed.

Tobacco mosaic virus particles contain ubiquitinated coat protein subunits

Virions of tobacco mosaic virus (TMV) are composed of a single strand of RNA, encapsidated in about 2130 copies of a coat protein of MW 17,500. Asselin and Zaitlin [Virology 91, 173-181 (1978)] demonstrated that virion preparations also contained small amounts of a second protein of MW 26,500, which they termed "H protein." H protein, detectable to an average frequency of one per virion, was thought to be a protein of host origin. Subsequent studies [Collmer, Vogt, and Zaitlin, Virology 126, 429-448 (1983)] showed the H protein was comprised of a backbone of TMV coat protein, linked by a postulated isopeptide bond to a small protein that probably was of host origin. The host-derived moiety of H protein is shown here to be ubiquitin, most probably coupled to the coat protein at lysine 53. This finding is based on microsequencing of the H protein, and is substantiated by immunoblotting analysis with antibodies to human ubiquitin. Conjugated ubiquitin was detected in virions of all five strains of the virus tested. To our knowledge, this is the first report of a ubiquitinated viral structural protein.

The use of thermally activated tritium atoms for structural-biological investigations: the topography of the TMV protein-accessible surface of the virus

Thermally activated tritium atoms were used for studying the topography of the TMV protein-accessible surface of the virus. The accessibility profile of amino acid residues in a protein polypeptide chain was determined from data on the intramolecular distribution of a tritium label in the TMV protein. It was shown that tryptic peptides T3, T4, T12, the N-terminal region of peptide T1 and the proximal tryptic peptide T8 (located 20 to 25 A (1 A = 0.1 nm) from the viral axis) are accessible to tritium labelling. The fact of tritiation of the viral RNA was detected as well. This evidence was compared with the high-resolution X-ray analysis data for the TMV. A model is suggested to explain the exposure of the buried sites of the virus to thermally activated tritium atoms. The possibilities and limitations of this method in studying the surface topography of proteins in supramolecular systems as well as for location of protein antigenic regions are discussed.

Phycocyanin aggregation. A small angle neutron scattering and size exclusion chromatographic study

The influence of environmental factors on the aggregation properties of phycocyanin from Synechocystis 6701 was studied by small angle neutron scattering and high-pressure size-exclusion liquid chromatography. Phycocyanin was found to exist in a reversible equilibrium between the monomer, trimer and hexamer forms. The distribution of the protein between these oligomers is determined by the pH, buffer composition and ionic strength of the medium, and protein concentration. Phycocyanin was in a stable hexameric state at pH 5.0 to 6.0 at a concentration of 1 to 10 mg/ml, and was primarily in a trimeric state at pH 8.0 at a concentration of about 5 mg/ml. Comparison of the small angle scattering data with the computed scattering curve for a hollow cylinder was used to determine the dimensions of the best-fit model by a least-squares fitting procedure. The outer radius, inner radius and height of the phycocyanin hexamer were found to be 54.1, 12.0 and 61.4 A (1 A = 0.1 nm), respectively, and the corresponding dimensions for the trimer were 54.5, 14.0 and 33.0 A. The molecular weight ratio for phycocyanin hexamer was determined to be 217,000. The dimensions and molecular weight ratios of phycocyanin from Synechocystis 6701 obtained by solution scattering are similar to the values for Mastigocladus laminosus obtained by X-ray crystallography.

Enhancement and simplification of macromolecular images

Computer graphics programs have been devised to display selected atomic features and to simplify images of complex macromolecular structures. By using boundary outlines, adjustment of size and shape of the molecular components, color coding, shading, and selective omission of obscuring detail, attention can be focused on specific interactions which determine higher levels of organization. A balanced color table has been constructed in which different hues have equal steps in brightness; this table has facilitated distinction of atom types and sequence coding together with representation of an optimum range of depth cueing and surface shading. The graphics system has been used with the atomic coordinates of the tobacco mosaic virus structure to simplify images of the protein subunit, to illustrate intermolecular interactions, and to relate subunit packing arrangements in different assemblies to the underlying atomic structure. The system has also been used to construct a schematic representation of the polyomavirus capsid, based on low resolution data. Application of artistic methods contributes to the effective presentation and interpretation of detailed scientific information about complex macromolecular structures.

Chapter 12 Compound Biopolymers and Biooligomers

This chapter is devoted to the separation of simple saccharides. In this chapter, the rapid chromatographic separation of natural oligomeric or polymeric compounds containing important molecular moieties of a different type are discussed, such as nucleoprotein complexes, glycolipids, glycopeptides and glycoside oligomeric derivatives. In addition, separations of several natural complex substances that are not well known are discussed. This chapter concludes with a brief discussion on the separation techniques used for the miscellaneous polymeric and oligomeric substances.

Preliminary X-ray fiber diffraction studies of cucumber green mottle mosaic virus, watermelon strain

Fiber diffraction patterns have been obtained for cucumber green mottle mosaic virus, watermelon strain (a distant relative of tobacco mosaic virus), and two heavy-atom derivatives. These patterns and the similarity between the cucumber and the tobacco virus offer the potential of a full structure determination of the cucumber virus.

The gene-specific initiation factor USF (upstream stimulatory factor) bound at the adenovirus type 2 major late promoter: mass and three-dimensional structure

The gene-specific transcription initiation factor USF (upstream stimulatory factor) binds at a palindromic sequence that extends from -52 to -63 relative to the start site of the adenovirus type 2 major late promoter; USF enhances in vitro transcription 10- to 20-fold. By analysis of digital micrographs from the Brookhaven scanning transmission electron microscope, we have identified a sample of 29 proteins (mass, 55 +/- 5 kDa) specifically bound at the palindrome. The individual protein digital images show extensive homology, which permits modeling a three-dimensional structure at a relatively low resolution, which is nonetheless significant for the study of protein-protein interactions in initiation. Non-sequence-specific competitor DNA at high mass excess can be used in reactions for microscopy, enabling characterization of specific binding for proteins present at 1% of total protein or less.

Correlation of co-ordinated amino acid substitutions with function in viruses related to tobacco mosaic virus

Sequence data are available for the coat proteins of seven tobamoviruses, with homologies ranging from at least 26% to 82%, and atomic co-ordinates are known for tobacco mosaic virus (TMV) vulgare. A significant spatial relationship has been found between groups of residues with identical amino acid substitution patterns. This strongly suggest that their location is linked to a particular function, at least in viruses identical with the wild-type for these residues. The most conserved feature of TMV is the RNA binding region. Core residues are conserved in all viruses or show mutations complementary in volume. The specificity of inter-subunit contacts is achieved in different ways in the three more distantly related viruses.

The dynamics of angular homeostasis: I. General principles

A general model is proposed casting aspects of ontogeny in quantitative terms amenable to genetic analysis. Its primordial construct is a chain of cells (termed a "pursuer") growing under the influence of a signal towards a fixed structure termed a "target." There is provision for graduated correction of the direction of growth of the pursuer. The determinants of scale include the size of the cells and the distance from the target. The minimum number of parameters is two: the initial angle of growth; and the force of the correction of errors of direction. Both are potentially of genetic interest. The impact of variation in these factors on the path of growth is studied. These findings are readily translated into biological terms, notably in congenital defects of the heart. Besides the primordial purposes, there are other objectives to the process. Some membranes require free edges, or large curvatures, or circular arrays. These secondary qualities require that the cells never reach the target. The target then becomes simply a construction point: that is, while remaining a center of attraction, it is no longer a true goal. If, because of undercorrection, the cell line misses the target at the first pass, it assumes a permanent orbit about it. The orbit rapidly comes to lie on a circle, with a radius independent of the initial angle of growth but related to the cell size and the restoration constant. From this property, several kinds of structures other than a simple bridge may result, especially when a series of lines of growth together form a tissue: a cusp, a free-floating membrane, or a circular membrane to fill a gap.

Accumulated strain mechanism for length determination of thick filaments in skeletal muscle. I. Experimental bases

The kinetics of dissociation of myosin from both ends of thick filaments in glycerinated skeletal muscle fibres and myofibrils was studied in the presence of MgATP by use of an optical diffraction method and phase-contrast microscopy. The dissociation velocity, v (identical to -dL/dt where L is the length of thick filaments at time t), increased with increasing KCl concentration (0.225 to 0.5 M), or increasing pH (6.5 to 8.0) but hardly changed with temperature (5 and 25 degrees C), micromolar concentrations of Ca2+ or sarcomere length (2.4 and 2.75 micron). Over a wide range of filament length, the dissociation velocity could be expressed by v0exp(alpha L), where v0 and alpha are positive constants depending upon the dissociation condition. When the effects of crossbridge formation are minimized it was thus shown that the structural stability of thick filaments in a muscle fibre and a myofibril gradually decreases from the central part to the tips of the filaments. On the basis of these results we propose that the length of thick filaments is largely regulated by an accumulated strain mechanism in which the free energy of association of myosin molecules increases with filament length.

Disk aggregates of tobacco mosaic virus protein in solution: electron microscopy observations

Previous studies of the coat protein of tobacco mosaic virus (TMVP) have shown that TMVP presumably exists as linear stacks of two-ring cylindrical disks in the 0.7 M ionic strength buffer used for crystallizing the disks for X-ray diffraction studies [Raghavendra, K., Adams, M.L., & Schuster, T.M. (1985) Biochemistry 24, 3298-3304]. The spectroscopic and sedimentation studies of solutions of TMVP under these crystallizing conditions have demonstrated a long-term metastability of these disk aggregates when they are placed in 0.1 M ionic strength buffers, as are used for reconstituting tobacco mosaic virus from TMVP and viral RNA. The present work describes an electron microscopic study of TMVP disk aggregates under the same solution conditions employed in the previous spectroscopic and sedimentation studies. The results show that in the pH 8.0 0.7 M ionic strength crystallization buffer TMVP exists as stacks of disks which range in size from about 6 to 24 layers, corresponding to 3-12 2-layer disk aggregates having 17 subunits per layer. These TMVP aggregates persist in a metastable form in 0.1 M ionic strength virus reconstitution buffer with no apparent changes in structure of the stacked disks. The results are consistent with the conclusions of the solution physical-chemical studies which suggest that the disk structure may not be related to the 20S TMVP aggregate that is the nucleation species in virus

Self-assembly of purified polyomavirus capsid protein VP1

The polyomavirus major capsid protein VP1, purified after expression of the recombinant gene in E. coli, was isolated as oligomers resembling the dissociated capsomeres derived from viral capsids. Image analysis of low-dose electron micrographs demonstrates that these VP1 oligomers are exclusively pentamers. The purified VP1 pentamers associated to form capsid-like assemblies and polymorphic aggregates at high ionic strength. The capsid-like assemblies were stabilized at low ionic strength by the addition of calcium. Self-assembly of the unmodified, recombinant DNA-generated VP1 implies that the posttranslational charge modifications of VP1 and the minor virion protein components, VP2 and VP3, are not essential for capsid formation. The nonequivalently related subunits of the penta- and hexavalent capsomeres therefore must spontaneously switch their bonding specificity during assembly.

A model for length-regulation in thick filaments of vertebrate skeletal myosin

A mechanism for length regulation in the parallel-packed section of the thick filament is proposed. It is based on experiments done on synthetic, mini- and native filaments, and its primary purpose is to explain the physical basis of the kinetic mechanism for the assembly of synthetic thick filaments from myosin alone. Kinetically, length is regulated by a dissociation rate constant that increases exponentially as the filament grows bi-directionally from its center. Growth ceases at the point of equilibrium between invariant on and length-dependent off rates. The three subfilaments structure of the parallel-packed region of the thick filament is fundamental to the proposed scheme. The intra-subfilament bonding is strong and predominantly ionic in character, whereas the inter-subfilament bonding is relatively weak. These strong and weak interactions participate directly in the strictly sequential mechanism of assembly of dimer subunit observed in the kinetics. A third domain, independent of the sequential mechanism, consists of opposing negative charges on the subfilament surface, juxtaposed at or close to the thick filament axis. The weak and repulsive domains are additively coupled to each other through the rigidity in the subfilaments. Length regulation occurs through the repulsive component rising in intensity more rapidly with length than the initially stronger positive interactions. Growth ceases at the point where the repulsive interactions weaken the attractive interactions to the extent that equilibrium is established between head-to-tail dimer subunit and its binding sites at the tips of the arms of thick filament. This myosin-mediated mechanism, which gives rise to a narrow length distribution, is considered to be fine-tuned by co-polymerizing proteins to give the precise length of the native filament.