Water-soluble complexes through coulombic interactions between bovine serum albumin and anionic polyelectrolytes grafted with hydrophilic nonionic side chains

The interaction between bovine serum albumin (BSA) and the anionic graft copolymers poly(sodium acrylate-co-sodium 2-acrylamido-2-methyl-1-propanesulfonate)-graft-poly(N,N-dimethylacrylamide) (P(NaA-co-NaAMPS)-g-PDMAMx) was investigated within the acid pH region, 2 < or = pH < or = 7. The weight percentage, x, of the poly(N,N-dimethylacrylamide) (PDMAM) side chains varied from 0 up to 75% (w:w). When BSA and P(NaA-co-NaAMPS)-g-PDMAMx are oppositely charged, i.e., when pH is lower than the isoelectric point of BSA, the two macromolecules associate through Coulombic attractions. When the anionic graft copolymer is rich enough to the nonionic PDMAM side chains, x > or = 50% w:w, the associative phase separation is practically prevented, as revealed by the turbidimetric study of the BSA/P(NaA-co-NaAMPS)-g-PDMAMx mixtures in aqueous solution vs pH. In addition, the viscosity measurements support the formation through a charge neutralization process of a rather compact protein-polyelectrolyte complex stabilized by the hydrophilic PDMAM side chains grafted onto the anionic copolymer backbone.     

Interaction of tobacco mosaic virus and tobacco mosaic virus protein with bovine serum albumin.

Bovine serum albumin (BSA) causes tobacco mosaic virus (TMV) to crystallize at pH values where both have negative charges. The amount of albumin required to precipitate the virus varies inversely with ionic strength of added electrolyte. At pH values above 5, the precipitating power is greatest when BSA has the maximum total, positive plus negative, charge. Unlike early stages of the crystallization of TMV in ammonium sulfate-phosphate solutions, which can be reversed by lowering the temperature, the precipitation of TMV by BSA is not readily reversed by changes in temperature. The logarithm of the apparent solubility of TMV in BSA solutions, at constant ionic strength of added electrolyte, decreases linearly with increasing BSA concentration. This result and the correlation of precipitating power with total BSA charge suggest that BSA acts in the manner of a salting-out agent. The effect of BSA on the reversible entropy-driven polymerization of TMV protein (TMVP) depends on BSA concentration, pH, and ionic strength. In general, BSA promotes TMVP polymerization, and this effect increases with increasing BSA concentrations. The effect is larger at pH 6.5 than at pH 6. Even though increasing ionic strength promotes polymerization of TMVP in absence of BSA, the effect of increasing ionic strength from 0.08 to 0.18 at pH 6.5 decreases the polymerization-promoting effect of BSA. Likewise, the presence of BSA decreases the polymerization-promoting effect of ionic strength. The polymerization-promoting effect of BSA can be interpreted in terms of a process akin to salting-out. The mutual suppression of the polymerization-promoting effects of BSA and of electrolytes by each other can be partially explained in terms of salting-in of BSA.     

Zur Frage Des Einflusses Von R?ntgen- Und Uv-Strahlen Auf Die Mutationsrate Des Tabakmosaikvirus Nach Bestrahlung Reiner Pr?parate

Summary Pure solutions of TMV were irradiated with x-rays or ultraviolet light in order to study possible effects on the mutation rate of the virus. If no spontaneous mutations were observed in a particular virus preparation, no induced mutations resulted from irradiation. In preparations showing spontaneous mutations, the rate of mutation was increased by irradiation only if the exposed material was compared with unirradiated virus diluted so as to give more lesions per leaf than the irradiated sample. The apparent mutation rate increased with dilution of active virus, whether this dilution was effected by irradiation or by the direct addition of phosphate buffer. Artificial unequal mixtures of two related virus strains, with either in the majority, were tested at different dilutions of the whole; without exception the symptoms of that partner present in minority became relatively more frequent with decreasing total concentration of the mixture.The effects observed here, as well as those described byGowen (1941), can readily be explained on the basis of competition between related virus strains. The evidence does not support an hypothesis of mutagenic action of irradiation on purified TMV preparations.

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Ein Teil der hier veröffentlichten Ergebnisse ist Bestandteil einer Dissertation der math.-naturw. Fakultät der Univ. Tübingen 1954.     

Heat-induced gelation of bovine serum albumin/low-methoxyl pectin systems and the effect of calcium ions

Influence of low-methoxyl pectin (LM pectin) and calcium ions (3 mM) on mechanical behavior and microstructure of bovine serum albumin (BSA) gels (pH 6.8, in 0.1 M NaCl) was evaluated. Protein and LM pectin concentrations were fixed at 2, 4, and 8 wt % and 0.21, 0.43, and 0.85 wt %, respectively. Rheological measurements and confocal laser scanning microscopy coupled with texture image analysis by use of the co-occurrence method were performed. Heat treatment of BSA/LM pectin mixtures induced protein gelation and a phase separation process between the two biopolymers, which was kinetically trapped. Calcium ions induced pectin gelation and modified BSA gel properties. Depending on biopolymer concentrations, a balance between pectin and/or protein gel contribution on final gel strength exists. The microstructures of the mixed systems in the presence of calcium can be interpreted as interpenetrated structures. Texture image analysis allowed one to classify more precisely the different microstructures observed in relation with mechanical properties.     

Composition dependence of the crystallization behavior and morphology of the poly(ethylene oxide)-poly(epsilon-caprolactone) diblock copolymer

The crystallization behavior and morphology of the crystalline-crystalline poly(ethylene oxide)-poly(epsilon-caprolactone) diblock copolymer (PEO-b-PCL) was studied by differential scanning calorimetry (DSC), wide-angle X-ray diffraction (WAXD), Fourier transform infrared spectroscopy (FTIR), small-angle X-ray scattering (SAXS), and hot-stage polarized optical microscope (POM). The mutual effects between the PEO and PCL blocks were significant, leading to the obvious composition dependence of the crystallization behavior and morphology of PEO-b-PCL. In this study, the PEO block length was fixed (Mn = 5000) and the weight ratio of PCL/PEO was tailored by changing the PCL block length. Both blocks could crystallize in PEO-b-PCL with the PCL weight fraction (WFPCL) of 0.23-0.87. For the sample with the WFPCL of 0.36 or less, the PEO block crystallized first, resulting in the obvious confinement of the PCL block and vice versa for the sample with WFPCL of 0.43 or more. With increasing WFPCL, the crystallinity of PEO reduced continuously while the variation of the PCL crystallinity exhibited a maximum. The long period of PEO-b-PCL increased with increasing WFPCL from 0.16 to 0.50 but then decreased with the further increase of WFPCL due to the interaction of the respective variation of the thicknesses of the PEO and PCL crystalline lamellae. Only the PEO spherulites were observed in samples with WFPCL of 0.16-0.36 by POM, in contrast to only the PCL spherulites in samples with WFPCL of 0.56-0.87. For samples with WFPCL of 0.43 and 0.50, a unique concentric spherulite was observed. The morphology of the inner and outer portions of the concentric spherulites was determined by the PCL and PEO spherulites, respectively. The growth rate of the PEO spherulites reduced rapidly with increasing WFPCL from 0 to 0.50. However, when increasing WFPCL from 0.43 to 0.87, the variation of the growth rate of the PCL spherulites exhibited a maximum rather than a monotonic change.     

Polar uncoating of tobacco mosaic virus (TMV) with dimethylsulfoxide (DMSO) and subsequent reassembly of partially stripped TMV

Summary Increasing concentrations of dimethylsulfoxide (DMSO) strip tobacco mosaic virus (TMV) stepwise from the 3 end. The RNA tail increases in length up to 2,000 nucleotides (nu) reaching a region of very strong protein-RNA affinity. Thereafter, uncoating occurs from the other end and produces a second RNA tail 500 nu long. Further stripping of TMV proceeds from both ends, the long tail increasing in length up to 4,000 nu and the short one increasing more moderately and remaining below 2,000 nu. The region of strongest protein-RNA affinity is located between 4,000 and 5,000 nu away from the 3 end.Using the same conditions as for in vitro TMV reassembly, it is possible to recoat the RNA tails with viral protein preferentially in the 5 direction.The advantages of DMSO in studies of TMV protein-RNA interactions are discussed.     

Crystal Structure of a Four-Layer Aggregate of Engineered TMV CP Implies the Importance of Terminal Residues for Oligomer Assembly

Background

Crystal structures of the tobacco mosaic virus (TMV) coat protein (CP) in its helical and disk conformations have previously been determined at the atomic level. For the helical structure, interactions of proteins and nucleic acids in the main chains were clearly observed; however, the conformation of residues at the C-terminus was flexible and disordered. For the four-layer aggregate disk structure, interactions of the main chain residues could only be observed through water–mediated hydrogen bonding with protein residues. In this study, the effects of the C-terminal peptides on the interactions of TMV CP were investigated by crystal structure determination.

Methodology/Principal Findings

The crystal structure of a genetically engineered TMV CP was resolved at 3.06 Å. For the genetically engineered TMV CP, a six-histidine (His) tag was introduced at the N-terminus, and the C-terminal residues 155 to 158 were truncated (N-His-TMV CP¹⁹). Overall, N-His-TMV CP¹⁹ protein self-assembled into the four-layer aggregate form. The conformations of residues Gln36, Thr59, Asp115 and Arg134 were carefully analyzed in the high radius and low radius regions of N-His-TMV CP¹⁹, which were found to be significantly different from those observed previously for the helical and four-layer aggregate forms. In addition, the aggregation of the N-His-TMV CP¹⁹ layers was found to primarily be mediated through direct hydrogen-bonding. Notably, this engineered protein also can package RNA effectively and assemble into an infectious virus particle.

Conclusion

The terminal sequence of amino acids influences the conformation and interactions of the four-layer aggregate. Direct protein–protein interactions are observed in the major overlap region when residues Gly155 to Thr158 at the C-terminus are truncated. This engineered TMV CP is reassembled by direct protein–protein interaction and maintains the normal function of the four-layer aggregate of TMV CP in the presence of RNA.     

Model System for the Adsorption of Tobacco Mosaic Virus

Materials which can adsorb tobacco mosaic virus (TMV) were isolated from tobacco leaves and studied for applicability as a model system for TMV adsorption. Leaves were homogenized and fractionated by sucrose density gradient centrifugation. One fraction adsorbed TMV in the presence of polyornithine. Deduced from its sensitivity to trypsin and detergent as well as from its manner of isolation, the material responsible for adsorption of TMV seemed to be cytoplasmic membrane. Membrane derived from light particulate, as well as cytoplasmic membrane, seemed to be capable of adsorbing TMV. Shorter rods obtained by sodium dodecyl sulfate or sonic treatment of TMV could adsorb to membrane as efficiently as TMV. Viral protein subunit could not adsorb whereas helical rods made of viral protein aggregates could. A two-step nature of the adsorption of TMV was suggested: a salt-sensitive and a subsequent salt-resistant steps. In the first step, ionic bonding plays a main role in the combination between TMV and membrane. Adsorption of ¹⁴C-labeled TMV was inhibited by an excess amount of non-labeled TMV or cucumber green mottle mosaic virus but not by potato virus X or rice dwarf virus, suggesting the specific nature of adsorption. In contrast to the observed specificity on the part of virus, a membrane fraction isolated from various plants, including non-hosts for TMV, could adsorb TMV. This may imply that adsorption and injection are not the determinant of host specificity in plant viral infection.     

A century of tobamovirus evolution in an Australian population of Nicotiana glauca.

The evolution over the past century of two tobamoviruses infecting populations of the immigrant plant Nicotiana glauca in New South Wales (NSW), Australia, has been studied. This plant species probably entered Australia in the 1870s. Isolates of the viruses were obtained from N. glauca specimens deposited in the NSW Herbarium between 1899 and 1972, and others were obtained from living plants in 1985 and 1993. It was found that the NSW N. glauca population was infected with tobacco mosaic tobamovirus (TMV) and tobacco mild green mosaic tobamovirus (TMGMV) before 1950 but only with TMGMV after that date. Half the pre-1950 infections were mixtures of the two viruses, and one was a recombinant. Remarkably, sequence analyses showed no increase in the genetic diversity among the TMGMV isolates over the period. However, for TMV, the genetic diversity of synonymous (but not of nonsynonymous) differences between isolates varied and was correlated with their time of isolation. TMV accumulated to smaller concentrations than TMGMV in N. glauca plants, and in mixed experimental infections, the accumulation of TMV, but not of TMGMV, was around 1/10 that in single infections. However, no evidence was found of isolate-specific interaction between the viruses. We conclude that although TMV may have colonized N. glauca in NSW earlier or faster than TMGMV, the latter virus caused a decrease of the TMV population below a threshold at which deleterious mutations were eliminated. This phenomenon, called Muller's ratchet, or a "mutational meltdown," probably caused the disappearance of TMV from the niche.     

Continuous foaming for protein recovery: part II. Selective recovery of proteins from binary mixtures

Foam separation may have potential for protein recovery. However, for foam separation to be a viable protein recovery technique it is important to demonstrate, not only that high enrichments and recoveries can be achieved for single proteins, but also that high enrichments and recoveries, together with selectivity of partition, can be achieved for recovery from multi-component mixtures. Most process streams which require purification are indeed complex multi-component mixtures, for example, fermentation broths. In this study, three binary protein mixtures were chosen for continuous foam separation: beta-casein:lysozyme; Bovine serum albumin (BSA):lysozyme and beta-casein:BSA (mixtures 1, 2, and 3, respectively). For each of these mixtures, the expected outcome of each experiment, based on a previous knowledge and determination of relevant protein physical properties, was that the first protein should be preferentially separated into the foam phase. On the basis of results reported in Part I of this study for the continuous foam separation of beta-casein, conditions found to favor maximum enrichment were selected. For each mixture a range of concentrations of both proteins was considered. For mixture 1, maximum protein recoveries in the foam phase were 85.6% and 25% for beta-casein and lysozyme, respectively; and for mixture 2, maximum recoveries of 77. 6% and 18.9% were obtained for BSA and lysozyme, respectively. Maximum enrichment ratios in the foam phase were 79.4 and 2.5 for beta-casein and lysozyme respectively in mixture 1; and 74.0 and 1.4 for BSA and lysozyme respectively in mixture 2. Selective partitioning of beta-casein and BSA into the foam phase was obtained in mixtures 1 and 2, respectively, particularly for protein concentrations at which dilute protein films are known to form at the gas-liquid interface in the foam. Maximum partition ratios for mixtures 1 and 2 were 31.8 and 52.8, respectively. For mixture 3, both BSA and beta-casein were enriched into the foam phase. Maximum enrichments were 42.9 and 24.7 for BSA and beta-casein, respectively; however, selective partitioning in mixture 3 was limited (maximum partition ratio being 1.8).     

Early trans-plasma membrane responses to Tobacco mosaic virus infection

Early trans-plasma membrane behavior after in vivo mechanical inoculation of Nicotiana tabacum with Tobacco mosaic virus (TMV) was investigated and compared to virus quantification in leaf tissues. To identify early events related to virus/host interaction, the systemic virus TMV was used to infect lower leaves and tests were carried out on upper leaves which were not directly infected. Non-invasive microelectrodes were used to estimate trans-plasma membrane electron transport and membrane potential after artificial inoculum of virus, monitoring the plant for the following 15 days. Virus infection was assessed by ELISA and quantified by quantitative RT-PCR. Collected data showed that after 2-day post-inoculation (dpi), TMV was able to modify membrane parameters: transient hyperpolarization of trans-membrane potential was observed until 10 dpi, while redox activity in infected samples was higher compared to control until end of tests. Conversely, ELISA diagnostic test was not able to reveal the virus presence in tobacco leaves until 6 dpi, while leaf symptoms were manifested after 13 dpi.     

Permeability studies in chitosan membranes. Effects of crosslinking and poly(ethylene oxide) addition

Pure chitosan, glutaraldehyde crosslinked chitosan, and a blend of chitosan with poly(ethylene oxide) (PEO) membranes were prepared. The three membranes were characterized in terms of their swelling capacities as well as their permeabilities to a drug model (sulfamerazine sodium salt). For the permeation experiments, the variables analyzed were the type of membrane and the initial drug concentration in the liquid phase (from 0.1% to 1.5%). Permeability coefficients were calculated using UV spectroscopy. The results showed that for the three analyzed membranes, the permeability did not change with time (over the studied time interval). An increase in the permeability for CHI/PEO membranes compared to those made of pure chitosan was also observed, possibly due to microporous region formation and/or crystallinity reduction. For the crosslinked membrane, an even higher increase in the permeability coefficient was observed. In this case, the increase was attributed to free volume variation.     

Changes in Glucose-6-Phosphate Dehydrogenase, Ribonucleases, Esterases and Contents of Viruses in Potato Virus Y Infected Tobacco Superinfected with Tobacco Mosaic Virus

Effects of the superinfection with tobacco mosaic virus (TMV) on susceptible tobacco plants infected with potato virus Y (PVY) were determined. Dynamic changes in the TMV and/or PVY contents, the ribonucleases (RNases), the phosphomonoesterase (PME), the phosphodiesterase (PDE) and the glucose-6-phosphate dehydrogenase (G6P DH) activities were studied. The PVY infection caused a substantial reduction in the multiplication of TMV. The content of TMV in the PVY inoculated leaves amounts to 6 and 9 % in the PVY systemically infected leaves when compared with single TMV. Surprisingly, the challenging virus (TMV) enhanced the content of inducing virus (PVY) in the locally inoculated leaves up to 130 – 141 %. In contrast, the reduction of PVY content down to 35 – 40 % by TMV was seen in the PVY systemically infected leaves. The activities of the RNase, the PME, the PDE and the G6P DH were increased (when compared with the healthy plants) during the acute phase of single virus multiplication (PVY or TMV). The increase in the activities of the enzymes in the leaves with mixed infection was at least as high as the sum of the increases of single infections. Moreover, a higher increase than the sum was seen for G6P DH and PDE (by about 20 – 35 %). This revised version was published online in July 2006 with corrections to the Cover Date.     

Effects of the tom1 mutation of Arabidopsis thaliana on the multiplication of tobacco mosaic virus RNA in protoplasts.

For the multiplication of RNA viruses, specific host factors are considered essential, but as of yet little is known about this aspect of virus multiplication. To identify such host factors, we previously isolated PD114, a mutant of Arabidopsis thaliana, in which the accumulation of the coat protein of tobacco mosaic virus (TMV) in uninoculated leaves of an infected plant was reduced to low levels. The causal mutation, designated tom1, was single, nuclear, and recessive. Here, we demonstrate that the tom1 mutation affects the amplification of TMV-related RNAs in a single cell. When protoplasts were inoculated with TMV RNA by electroporation, the percentage of TMV-positive protoplasts (detected by indirect immunofluorescence staining with anti-TMV antibodies) was lower (about 1/5 to 1/10) among PD114 protoplasts than among wild-type protoplasts. In TMV-positive PD114 protoplasts, the amounts of the positive-strand RNAs (the genomic RNA and subgenomic mRNAs) and coat protein reached levels similar to, or slightly lower than, those reached in TMV-positive wild-type protoplasts, but the accumulation of the positive-strand RNAs and coat protein occurred more slowly than with the wild-type protoplasts. The parallel decrease in the amounts of the coat protein and its mRNA suggests that the coat protein is translated from its mRNA with normal efficiency. These observations support the idea that the TOM1 gene encodes a host factor necessary for the efficient amplification of TMV RNA in an infected cell. Furthermore, we show that TMV multiplication in PD114 protoplasts is severely affected by the coinoculation of cucumber mosaic virus (CMV) RNA. When PD114 protoplasts were inoculated with a mixture of TMV and CMV RNAs by electroporation, the accumulation of TMV-related molecules was approximately one-fifth of that in PD114 protoplasts inoculated with TMV RNA alone. No such reduction in the accumulation of TMV-related molecules was observed when wild-type protoplasts were inoculated with a mixture of TMV and CMV RNAs or when wild-type and PD114 protoplasts were inoculated with a mixture of TMV and turnip crinkle virus RNAs. These observations are compatible with a hypothetical model in which a gene(s) that is distinct from the TOM1 gene is involved in both TMV and CMV multiplication.     

ASSEMBLY AND AGGREGATION OF TOBACCO MOSAIC VIRUS IN TOMATO LEAFLETS

Cells of tomato leaflets (Lycopersicum esculentum Mill.) were studied by phase and electron microscopy at various intervals after inoculation with a common strain of tobacco mosaic virus (TMV). Forty-eight hours after inoculation, prior to the development of assayable virus, individual TMV particles, and also particle aggregates, were observed in the ground cytoplasm of mesophyll cells. The most rapid synthesis of virus occurred between 80 and 300 hours after inoculation. Cytological changes during this time were characterized by an increased number of individual particles in the cytoplasm, growth of some aggregates, distortion and vacuolation of chloroplasts, and formation of filaments in the cytoplasm which were approximately four times the size of TMV. These filaments were interpreted as possible developmental forms of the TMV particle. Vacuoles in chloroplasts commonly contained virus particles. Evidence indicated that TMV was assembled in the ground cytoplasm and, in some cases, subsequently was enveloped by distorted chloroplasts.     

Influence of κ/β-carrageenan from red alga <Emphasis Type="Italic">Tichocarpus crinitus</Emphasis> on development of local infection induced by tobacco mosaic virus in Xanthi-nc tobacco leaves

The influence of κ/β-carrageenan from red marine alga Tichocarpus crinitus on the development of tobacco mosaic virus (TMV) infection in Xanthi-nc tobacco leaves was studied. It was shown that the number of necrotic lesions on the leaves inoculated with the mixture of TMV (2 μg/ml) and carrageenan (1 mg/ml) was reduced by 87%, compared to the leaves inoculated with the virus only. The suppression of virus infection was also observed when leaves were treated with carrageenan 24 h before or 24 h after leaf inoculation with TMV; however, in these cases, suppression was less evident than after inoculation with the virus-polysaccharide mixture. It is supposed that the antiviral activity of carrageenan applied together with TMV may be explained by its action not only on the plant but also on the virus itself. The inhibitory effect of carrageenan pretreatment can be explained by its favorable effect on tissue resistance to infection. The suppression of this resistance by actinomycin D indicates that carrageenan functions via its action on the cell genome.     

THE STRUCTURE OF CELLS DURING TOBACCO MOSAIC VIRUS REPRODUCTION : Mesophyll Cells Containing Virus Crystals

The submicroscopic organization of mesophyll cells from tobacco leaves systemically infected with tobacco mosaic virus (TMV) is described. After fixation with glutaraldehyde and osmium tetroxide the arrangement of the TMV particles within the crystalline inclusions is well preserved. Only the ribonucleic acid-containing core of the virus particles is visible in the micrographs. Besides the hexagonal virus crystals, several characteristic types of "inclusion bodies" are definable in the cytoplasm: The so-called fluid crystals seem to correspond to single layers of oriented TMV particles between a network of the endoplasmic reticulum and ribosomes. Unordered groups or well oriented masses of tubes with the diameter of the TMV capsid are found in certain areas of the cytoplasm. A complicated inclusion body is characterized by an extensively branched and folded part of the endoplasmic reticulum, containing in its folds long aggregates of flexible rods. Certain parts of the cytoplasm are filled with large, strongly electron-scattering globules, probably of lipid composition. These various cytoplasmic differentiations and the different forms of presumed virus material are discussed in relation to late stages of TMV reproduction and virus crystal formation.     

Glucose-6-Phosphate Dehydrogenase, Ribonucleases and Esterases upon Tobacco Mosaic Virus Infection and Benzothiodiazole Treatment in Tobacco

Effect of the benzothiodiazole (BTH) pre-treatment was monitored during the acute infection stage in the susceptible and the hypersensitive tobacco plants infected with the tobacco mosaic virus (TMV). Dynamic changes in the contents of chlorophyll, the total proteins, and the pathogenesis related proteins (PR-proteins), and activities of ribonucleases (RNase), phosphomonoesterase (PME), phosphodiesterase (PDE), and glucose-6-phosphate dehydrogenase (G6P DH) were studied. Neither the protein nor the chlorophyll contents were significantly changed by the TMV infection and/or the BTH treatment. The BTH pre-treatment caused a substantial reduction in the multiplication of TMV in the locally-infected leaves of the hypersensitive cultivar Xanthi-nc (to 15.1%). A lesser decrease (to 50.3%) was observed in the locally-infected leaves of susceptible cultivar Samsun. But in the systemically-infected leaves of this cultivar, only a 4-d delay in the multiplication of TMV was found. In the locally-infected leaves of both cultivars, the activities of the RNase, PME, PDE and G6P DH were sharply increased during the acute phase of TMV multiplication (when compared with the healthy plants) and the curves of these activities correlated with the multiplication curves of TMV. The BTH alone also strongly enhanced the activities of these enzymes early after application. Only low additional increases in some enzymes and even slight declines in the others were observed when the inoculation of leaves of cultivar Xanthi-nc followed the pre-treatment with the BTH. No inhibition of the enzymes was observed when the direct effect of different concentration of the BTH (1 – 1000 M) was examined in vitro during a measurement of the activity. The analysis of intercellular proteins by PAGE under native conditions shows the similar spectrum of the proteins extracted from either the BTH-treated or the TMV-infected tobacco cv. Xanthi-nc.     

Coordinated two-disk nucleation, growth and properties, of virus-like particles assembled from tobacco-mosaic-virus capsid protein with poly(A) or oligo(A) of different length

Assembly of nucleoprotein rods from tobacco mosaic virus (TMV) coat protein and poly(A) depends on the presence of 20S disks in a manner very similar to nucleation and growth of virions in reconstitution with TMV RNA. Products assembled with (A) approximately equal to 5000 appear to have the same buoyant density in CsCl, the same nucleotide/protein ratio and the same nuclease stability, as reconstituted and native TMV. Their rate of formation is very similar to the rate of reconstitution with TMV RNA when high-molecular-mass (A) approximately equal to 5000 is used, but becomes a function of chain length particularly with (A) less than or equal to 185. The composition of assembly products can be described sufficiently with the relation between number of capsid polypeptide monomers/particle, np, to the number of nucleotide residues/chain, nnt, of np = 1/3 (nnt + 50) with two important restrictions: (1) particles of less than four turns of helically arranged capsid subunits are unstable, and (2) particles with about 150 or less nucleotides per chain deviate in structure from mature virus and virus-like (= longer) assembly products. This is indicated by changes in both buoyant density in CsCl and optical properties, while 'dislocation' of the disk to the helical arrangement of capsid subunits ('helicalization') and nuclease stability already become established with chains as short as (A) approximately equal to 58 +/- 20. Consequently, we suggest that assembly proceeds through three distinct phases: (1) nucleation (resulting in helicalization) by interaction of nucleic acid with the first disk; (2) stabilization of the primary (unstable!) nucleation complex by addition of a second disk and formation of a four-turn virus-like and stable nucleoprotein helix, which is then fit for (3) elongation by addition of further disks. The question of what makes the TMV protein disk select specifically TMV RNA during virion assembly is discussed in some detail.     

Macroscopic Aggregation of Tobacco Mosaic Virus Coat Protein

The relationship between processes of thermal denaturation and heat-induced aggregation of tobacco mosaic virus (TMV) coat protein (CP) was studied. Judging from differential scanning calorimetry melting curves, TMV CP in the form of a trimer–pentamer mixture (4S-protein) has very low thermal stability, with a transition temperature at about 40°C. Thermally denatured TMV CP displayed high propensity for large (macroscopic) aggregate formation. TMV CP macroscopic aggregation was strongly dependent on the protein concentration and solution ionic strength. By varying phosphate buffer molarity, it was possible to merge or to separate the denaturation and aggregation processes. Using far-UV CD spectroscopy, it was found that on thermal denaturation TMV CP subunits are converted into an intermediate that retains about half of its initial -helix content and possesses high heat stability. We suppose that this stable thermal denaturation intermediate is directly responsible for the formation of TMV CP macroscopic aggregates.