Similarity in structure and function of the 3′-terminal region of the four brome mosaic viral RNAs

A 3′-terminal fragment, about 160 nucleotides long, was cleaved by limited nuclease digestion from each of the four RNA components of brome mosaic virus, and purified by two cycles of gel electrophoresis. These fragments accepted tyrosine in reactions catalyzed by wheat germ aminoacyl-tRNA synthetase. Analyses of nuclease digests suggested that the sequences of the fragments from brome mosaic virus RNA 3 and 4 were identical and that the fragments from RNA 1 and 2 differed from that of RNA 4 only in the positions of two and one nucleotides, respectively. A fragment isolated in a similar way from cowpea chlorotic mottle virus was similar in size to the brome mosaic virus RNA fragments, accepted tyrosine in the presence of wheat germ aminoacyl-tRNA synthetase, but had a substantially different nucleotide sequence.     

Translation of the RNAs of brome mosaic virus: The monocistronic nature of RNA1 and RNA2

Each of the two largest brome mosaic virus RNAs, RNA1 and RNA2, directs the synthesis of a large protein in cell-free extracts derived from wheat embryo. The size of each protein represents the translation of almost the entire length of the corresponding RNA. It was shown previously that brome mosaic virus RNA4 directs the synthesis of the coat protein and that brome mosaic virus RNA3, although it also contains the coat protein cistron, is translated mostly into a single product unrelated to the coat protein (Shih & Kaesberg, 1973). Thus, the brome mosaic virus genome encodes a total of four proteins.     

Alterations of the conformation of the RNAs of alfalfa mosaic virus upon binding of a few coat protein molecules

Structural changes in the single-stranded genome RNAs (RNAs 1, 2 and 3) and the subgenomic coat protein messenger (RNA 4) of alfalfa mosaic virus upon addition of a few coat protein molecules of the virus were investigated by measuring the fluorescent intensity of bound ethidium bromide and by circular dichroism. No effect could be observed in the case of the genome RNAs. However, in RNA 4, which is of much less complexity than the genome RNAs, a reduction of the ethidium bromide binding by 30% was found, whereas the positive molar ellipticity at 265 nm was reduced by 9% upon binding of the coat protein. Both changes point to a reduction of the ordered structure of the RNA. Since the protein is known to bind first at the 3′-terminus of RNA 4 and probably also of the genome RNAs, the conformational changes observed could be those thought to be necessary for replicase recognition in this positive-stranded RNA virus which needs the coat protein for starting an infection cycle.     

The Assembly Pathway of an Icosahedral Single-Stranded RNA Virus Depends on the Strength of Inter-Subunit Attractions

The strength of attraction between capsid proteins (CPs) of cowpea chlorotic mottle virus (CCMV) is controlled by the solution pH. Additionally, the strength of attraction between CP and the single-stranded RNA viral genome is controlled by ionic strength. By exploiting these properties, we are able to control and monitor the in vitro co-assembly of CCMV CP and single-stranded RNA as a function of the strength of CP–CP and CP–RNA attractions. Using the techniques of velocity sedimentation and electron microscopy, we find that the successful assembly of nuclease-resistant virus-like particles (VLPs) depends delicately on the strength of CP–CP attraction relative to CP–RNA attraction. If the attractions are too weak, the capsid cannot form; if they are too strong, the assembly suffers from kinetic traps. Separating the process into two steps—by first turning on CP–RNA attraction and then turning on CP–CP attraction—allows for the assembly of well-formed VLPs under a wide range of attraction strengths. These observations establish a protocol for the efficient in vitro assembly of CCMV VLPs and suggest potential strategies that the virus may employ in vivo.     

Identification of maize lethal necrosis disease causal viruses in maize and suspected alternative hosts through small RNA profiling

Maize lethal necrosis disease (MLND) is a devastating viral disease of maize caused by double infection with Maize chlorotic mottle virus (MCMV) and any one of the Potyviridae family members. Management of MLND requires effective resistance screening and surveillance tools. In this study, we report the use of small RNA (sRNA) profiling to detect MLND causal viruses and further the development of alternative detection markers for use in routine surveillance of the disease-causing viruses. Small RNAs (sRNAs) originating from five viruses namely MCMV, Sugarcane mosaic virus (SCMV), Maize streak virus (MSV), Maize-associated totivirus (MATV) and Maize yellow mosaic virus (MYMV) were assembled from infected maize samples collected from MLND hot spots in Kenya. The expression of the identified viral domains was further validated using quantitative real-time PCR. New markers for the detection of some of the MLND causal viruses were also developed from the highly expressed domains and used to detect the MLND-causative viruses in maize and alternative hosts. These findings further demonstrate the potential of using sRNAs especially from highly expressed viral motifs in the detection of MLND causal viruses. We report the validation of new sets of primers for use in detection of the most common MLND causal viruses MCMV and SCMV in East Africa.     

RNA Binding by the Brome Mosaic Virus Capsid Protein and the Regulation of Viral RNA Accumulation

Viral capsid proteins (CPs) can regulate gene expression and encapsulate viral RNAs. Low-level expression of the brome mosaic virus (BMV) CP was found to stimulate viral RNA accumulation, while higher levels inhibited translation and BMV RNA replication. Regulation of translation acts through an RNA element named the B box, which is also critical for the replicase assembly. The BMV CP has also been shown to preferentially bind to an RNA element named SLC that contains the core promoter for genomic minus-strand RNA synthesis. To further elucidate CP interaction with RNA, we used a reversible cross-linking-peptide fingerprinting assay to identify peptides in the capsid that contact the SLC, the B-box RNA, and the encapsidated RNA. Transient expression of three mutations made in residues within or close by the cross-linked peptides partially released the normal inhibition of viral RNA accumulation in agroinfiltrated Nicotiana benthamiana. Interestingly, two of the mutants, R142A and D148A, were found to retain the ability to down-regulate reporter RNA translation. These two mutants formed viral particles in inoculated leaves, but only R142A was able to move systemically in the inoculated plant. The R142A CP was found to have higher affinities for SLC and the B box compared with those of wild-type CP and to alter contacts to the RNA in the virion. These results better define how the BMV CP can interact with RNA and regulate different viral processes.     

Survey of two beet viruses in South Kazakhstan and Central Asia

During two surveys of beet root crops in South Kazakhstan and Central Asia conducted in 1988 and 1989, 465 of 990 samples were found to contain beet mosaic virus (BMV) by double-antibody sandwich (DAS) ELISA. BMV infection was widely scattered in the area surveyed, and its incidence varied considerably, reaching 100% in some fields adjacent to beet seed crops. BMV isolates from Kazakhstan, Kirgizia, Uzbekistan and Ukraine were found to be serologically closely related in DAS-ELISA test. Beet yellows virus (BYV) was not detected in any location surveyed in South Kazakhstan and Central Asia. BYV spread into the area is probably prevented by its geographical isolation.     

Age dependence of cowpea protoplasts for uptake of spermidine and infectibility by alfalfa mosaic virus

Cowpea protoplasts were prepared from plants of different ages and examined for their ability to take up polyamines and for their infectibility by alfalfa mosaic virus. A lag period of 20 h was necessary before the onset of rapid polyamine uptake; the occurrence of this rapid uptake depended on the age of the leaves used for protoplast preparation. The percentage of infection of cowpea protoplasts by alfalfa mosaic virus, and the amount of virus produced also depended on the age of the plants used for protoplast preparation. In contrast, the uptake of amino acids was rapid in all cowpea protoplasts tested.     

Inheritance of resistance to potyviruses in Phaseolus vulgaris L. IV. Inheritance, linkage relations, and environmental effects on systemic resistance to four potyviruses

We have examined the genetics of systemic resistance in Phaseolus vulgaris to azuki bean mosaic virus (AzMV) and cowpea aphid-borne mosaic virus (CABMV) and the relationship of this resistance to a phenotypically similar resistance to watermelon mosaic virus (WMV) and soybean mosaic virus (SMV). In P. vulgaris cv Great Northern 1140 (GN1140), resistance to SMV and WMV has been attributed to the genes Smv and Wmv, respectively, which have been shown to segregate as a unit. Systemic resistance to AzMV is conferred by two incompletely dominant alleles, Azm1 and Azm2, at unlinked loci. At least three resistance alleles must be present at these two loci for systemic resistance to be expressed in the plant. Systemic resistance to CABMV in GN 1140 is conditioned by a dominant allele that has been designated Cam2. Under some environmental conditions, a recessive allele at an unlinked locus, cam3, also controls a resistant response to CABMV. Resistance to AzMV and CABMV does not assort independently from Wmv/Smv, but also does not consistently cosegregate, suggesting that perhaps in each case one of the factors involved in resistance is associated with Smv/Wmv.     

The incidence and distribution of viruses infecting lettuce, cultivated Brassica and associated natural vegetation in Spain

A virus survey was conducted during the spring and autumn of 2001 and 2002 to determine the presence, prevalence and distribution in Spain of the viruses that are most commonly found infecting lettuce and Brassica worldwide. Crop plants showing virus symptoms from the principal lettuce and Brassica-growing regions of Spain, and some samples of the annual and perennial flora nearby, were tested by enzyme-linked immunosorbent assays using specific commercial antibodies against the following viruses: Alfalfa mosaic virus (AMV), Broad bean wilt virus 1 (BBWV-1), Beet western yellows virus (BWYV), Cauliflower mosaic virus (CaMV), Cucumber mosaic virus (CMV), Lettuce mosaic virus (LMV), Pea seed-borne mosaic virus (PSbMV), Turnip mosaic virus (TuMV) and Tomato spotted wilt virus (TSWV). Samples were also tested with a Potyvirus genus antibody. Virus incidence was much lower in spring than in autumn, especially in 2001. In spring 2002, CMV and LMV were the most prevalent viruses in lettuce, while CaMV was the most important virus present in Brassica crops grown in Navarra, followed by CMV and BWYV. In the autumn, the spectrum of viruses was different; potyviruses were widespread in lettuce grown in Madrid, but TSWV and BWYV were predominant in the Murcia region. The prevalent Potyvirus detected in lettuce fields was LMV, but none of the samples collected were positive for PSbMV or TuMV. In Brassica crops, TSWV was the most abundant in autumn-sown crops, especially in the Navarra region. All of the viruses present in lettuce and Brassica were also frequently detected in their associated natural vegetation at the same time, suggesting that they probably play an important role as virus reservoirs. Sonchus spp. were particularly common and were frequently infected with CMV, LMV and BWYV. Another common species, Chenopodium album, was often infected with TSWV and BWYV. Multiple infections were common, especially in non-crop plants, and the most common combination was BWYV and TSWV. The role of weeds in the epidemiology of viruses that infect lettuce and Brassica crops in Spain is discussed.     

Occurrence of latent virus infection in visually-rated cowpea (Vigna unguiculata L. Walp) seedlings

Abstract

The presence of latent infections was studied in five cowpeas varieties. Seeds of the varieties were planted and the seedlings inoculated with antigens from Cucumber mosaic virus (CMV) genus Cucumovirus, Bean common mosaic virus (BCMV) genus Potyvirus (Blackeye cowpea mosaic virus strain), Southern bean mosaic virus (SBMV) genus Sobemovirus and Cowpea mottle virus (CPMoV) genus Carmovirus seven days after planting. Seedlings expressing symptoms were rouged at two weeks after inoculation, while asymptomatic ones were subjected to serological indexing to detect the presence/absence of latent infection. Protein A-sandwich enzyme-linked immunosorbent assay (PAS ELISA) was employed for the serological detection of CMV, SBMV and CPMoV, while antigen-coated plate (ACP) ELISA was used to detect BCMV in the asymptomatic plants. Cowpea seedlings without virus symptoms but with positive serological reactions were considered as being latently infected. All of the inoculated TVu 1272 and SuVita-2 plants showed symptoms consistent with CMV and CPMoV infections, respectively. The rate of CMV latent infection was high in TVu 1179 (14.5%), low in SuVita-2 (1.3%) but not recorded in TVu 1272.     

Differentiation of Dasheen Mosaic Potyvirus Isolates Based on Variability in the Apparent Size of the Capsid Protein in Western Blots

The capsid protein (CP) sizes of seven dasheen mosaic virus (DsMV) isolates and one isolate of vanilla mosaic virus were estimated to be 38–47 kDa and 47 kDa, respectively, based on Western blot analyses using DsMV polyclonal antiserum. The CP sizes of 12 other potyviruses were estimated to be 31–36 kDa. Apparent CP sizes of the DsMV isolates extracted from their original hosts were 47 kDa ( Xanthosoma caracu ), 45 kDa ( Colocasia esculenta , Zantedeschia aethiopica ), and 38–46 kDa ( Caladium hortulanum ). Propagation in seedlings of Philodendron selloum did not affect the CP sizes of any of the individual DsMV isolates. The same characteristic CP sizes were also detected in Western blot analyses of these isolates, using polyclonal antisera of eight other potyviruses, or using Agdia Poty 1 monoclonal antiserum, and using three monoclonal antisera of papaya ringspot virus type W. The apparent CP size and pattern of apparent breakdown products as revealed by Western blots of extracts from infected aroids may be used in the characterization and differentiation of DsMV isolates.     

Rubus host range of rubus yellow net virus and its involvement with other aphid-borne latent viruses in inducing raspberry veinbanding mosaic disease

After graft inoculation with rubus yellow net virus (RYNV), 12 of 34 Rubus species and cultivars developed noticeable symptoms. R. macraei developed the most conspicuous symptoms and is recommended as an improved indicator plant. In attempts to determine the cause of raspberry veinbanding mosaic, a disease in which RYNV is involved, several European and North American red raspberry cvs were graft-inoculated with RYNV and three other aphid-borne viruses, black raspberry necrosis (BRNV), raspberry leaf mottle (RLMV) and raspberry leaf spot, singly and in all combinations. In periods of up to 4 yr, classical veinbanding mosaic symptoms developed in sensitive cvs only when they contained both RYNV and RLMV. These symptoms were intensified in plants co-infected with additional viruses. Veinbanding mosaic disease did not develop in any of 11 cvs infected with RYNV + BRNV, the combination of viruses previously assumed to be responsible for this disease in Britain and North America.     

Letter: Nuclear magnetic resonance of protein-nucleic acid interactions. II. The E. coli tRNA-Glu complex with glutamyl-tRNA synthetase

We have observed the 300 MHz high-resolution proton nuclear magnetic resonance spectrum of the Escherichia coli tRNA^Glu complex with the glutamyl-tRNA synthetase. The observations are fitted very well by a computer-simulated spectrum of the E. coli tRNA^Glu itself, with the individual resonances broadened from 45 Hz to 150 Hz because of the increased molecular weight. This indicates that no helical arms open upon complex formation, nor is there evidence for any additional Watson-Crick base-pairs in the complex.     

Pathways for Virus Assembly around Nucleic Acids

Understanding the pathways by which viral capsid proteins assemble around their genomes could identify key intermediates as potential drug targets. In this work, we use computer simulations to characterize assembly over a wide range of capsid protein–protein interaction strengths and solution ionic strengths. We find that assembly pathways can be categorized into two classes, in which intermediates are either predominantly ordered or disordered. Our results suggest that estimating the protein–protein and the protein–genome binding affinities may be sufficient to predict which pathway occurs. Furthermore, the calculated phase diagrams suggest that knowledge of the dominant assembly pathway and its relationship to control parameters could identify optimal strategies to thwart or redirect assembly to block infection. Finally, analysis of simulation trajectories suggests that the two classes of assembly pathways can be distinguished in single-molecule fluorescence correlation spectroscopy or bulk time-resolved small-angle X-ray scattering experiments.     

Faithful and efficient translation of viral and cellular eukaryotic mRNAs in a cell-free S-27 extract of Saccharomycescerevisiae

The preparation of yeast spheroplast 27,000 × g supernatant /S-27/ which initiates translation of endogenous and exogenous mRNAs is described. The activity of this protein synthesis system is comparable to that of the most efficient cell-free extracts currently in use. The yeast S-27 system is able to carry out faithful translation of distinct eukaryotic mRNAs into proteins as large as 180,000 daltons.     

Nuclear magnetic resonance spectroscopy with the stringent substrate rhodanese bound to the single-ring variant SR1 of the E. coli chaperonin GroEL

Nuclear magnetic resonance (NMR) observation of the uniformly (2) H,(15) N-labeled stringent 33-kDa substrate protein rhodanese in a productive complex with the uniformly (14) N-labeled 400 kDa single-ring version of the E. coli chaperonin GroEL, SR1, was achieved with the use of transverse relaxation-optimized spectroscopy, cross-correlated relaxation-induced polarization transfer, and cross-correlated relaxation-enhanced polarization transfer. To characterize the NMR-observable parts of the bound rhodanese, coherence buildup rates by different magnetization transfer mechanisms were measured, and effects of covalent crosslinking of the rhodanese to the apical binding surface of SR1 were investigated. The results indicate that the NMR-observable parts of the SR1-bound rhodanese are involved in intracomplex rate processes, which are not related to binding and release of the substrate protein from the SR1 binding surface. Rather, they correspond to mobility of the stably bound substrate, which thus appears to include flexibly disordered polypeptide segments devoid of long-lived secondary structures or tertiary folds, as was previously observed also with the smaller substrate human dihydrofolate reductase.     

Identification and characterization of maize pathogenesis-related proteins. Four maize PR proteins are chitinases

Eight pathogenesis-related proteins extractable at pH 2.8 were found to accumulate in maize leaves after mercuric chloride treatment or brome mosaic virus infection. These proteins were called PRm (pathogenesis-related maize) proteins. Seven PRm proteins were purified to homogeneity by preparative polyacrylamide gel electrophoresis and their amino acid compositions determined. Estimated molecular weights in SDS-containing gels were: PRm 1 14.2 kDa; Prm 2 16.5 kDa; PRm 3 and PRm 4 25 kDa; PRm 6b 30.5 kDa; PRm 6a 32 kDa; PRm 7 34.5 kDa. Antisera raised against either PRm 3 or PRm 4 reacted specifically each with PRm 3 or PRm 4. Antisera raised against PRm 6b reacted with PRm 6b as well as with PRm 6a and antisera against PRm 7 reacted with PRm 7 and PRm 5. Tobacco anti-PR 1b antisera reacted with maize PRm 2.Chitinase (poly[1,4-(N-acetyl--D-glucosamide)]glycanhydrolase, EC 3.2.1.14) activity was found for PRm 3, PRm 4, PRm 5, and PRm 7.     

35Cl nuclear magnetic resonance study of zinc and phosphate binding of E. coli alkaline phosphatase

³⁵Cl^? quadrupole relaxation was measured in the presence of metal-free alkaline phosphatase and in the presence of Zn²⁺-alkaline phosphatase. The relaxation data show that for an enzyme containing the minimum amount of zinc needed for full activity—2 g atoms of zinc per mole of protein—there appears to be no binding of halide ions to the protein-bound zinc ions. In contrast, when there is a high metal-enzyme ratio, a large relaxation enhancement is observed, demonstrating coordination of halide ions to the metal ions.Addition of inorganic phosphate causes no change in the ³⁵Cl^? relaxation in the presence of metal-free enzyme. However, marked decreases in relaxation are observed upon addition of phosphate to the Zn²⁺-alkaline phosphatase. The relaxation measurements carried out in the presence of phosphate show that substrate binding does prove to be metal-ion dependent. Furthermore, experiments with inorganic phosphate suggest the tight binding of one phosphate to the alkaline phosphatase.     

A study of E. coli and T. maritima ribosomes by atomic force microscopy

Whole 70S ribosomes and 50S and 30S ribosomal subunits of E. coli and T. maritima were studied by atomic force microscopy. Adsorption of the ribosomal subunits on a substrate revealed considerable heterogeneity of their structures. Analysis of the geometric size of the particles demonstrated essential difference between the heights of E. coli and T. maritima ribosomes 9.4 ± 0.01 nm and 10.35 ± 0.02 nm, respectively. Presumably, the difference in size is determined by the difference in organization of the mobile ribosomal domain, the L7/L12 stalk.