Total nucleotide sequence of a nearly full-size DNA copy of satellite tobacco necrosis virus RNA

Virophages of Giant Viruses: An Update at Eleven

The last decade has been marked by two eminent discoveries that have changed our perception of the virology field: The discovery of giant viruses and a distinct new class of viral agents that parasitize their viral factories, the virophages. Coculture and metagenomics have actively contributed to the expansion of the virophage family by isolating dozens of new members. This increase in the body of data on virophage not only revealed the diversity of the virophage group, but also the relevant ecological impact of these small viruses and their potential role in the dynamics of the microbial network. In addition, the isolation of virophages has led us to discover previously unknown features displayed by their host viruses and cells. In this review, we present an update of all the knowledge on the isolation, biology, genomics, and morphological features of the virophages, a decade after the discovery of their first member, the Sputnik virophage. We discuss their parasitic lifestyle as bona fide viruses of the giant virus factories, genetic parasites of their genomes, and then their role as a key component or target for some host defense mechanisms during the tripartite virophage–giant virus–host cell interaction. We also present the latest advances regarding their origin, classification, and definition that have been widely discussed.

Investigating the Biological Relevance of In Vitro-Identified Putative Packaging Signals at the 5' Terminus of Satellite Tobacco Necrosis Virus 1 Genomic RNA

Satellite tobacco necrosis virus 1 (STNV-1) is a model system for in vitro RNA encapsidation studies (N. Patel, E. C. Dykeman, R. H. A. Coutts, G. P. Lomonossoff, et al., Proc Natl Acad Sci U S A 112:2227-2232, 2015, https://doi.org/10.1073/pnas.1420812112; N. Patel, E. Wroblewski, G. Leonov, S. E. V. Phillips, et al., Proc Natl Acad Sci U S A 114:12255-12260, 2017, https://doi.org/10.1073/pnas.1706951114), leading to the identification of degenerate packaging signals (PSs) proposed to be involved in the recognition of its genome by the capsid protein (CP). The aim of the present work was to investigate whether these putative PSs can confer selective packaging of STNV-1 RNA in vivo and to assess the prospects of using decoy RNAs in antiviral therapy. We have developed an in planta packaging assay based on the transient expression of STNV-1 CP and have assessed the ability of the resulting virus-like particles (VLPs) to encapsidate mutant STNV-1 RNAs expected to have different encapsidation potential based on in vitro studies. The results revealed that >90% of the encapsidated RNAs are host derived, although there is some selectivity of packaging for STNV-1 RNA and certain host RNAs. Comparison of the packaging efficiencies of mutant STNV-1 RNAs showed that they are encapsidated mainly according to their abundance within the cells, rather than the presence or absence of the putative PSs previously identified from in vitro studies. In contrast, subsequent infection experiments demonstrated that host RNAs represent only <1% of virion content. Although selective encapsidation of certain host RNAs was noted, no direct correlation could be made between this preference and the presence of potential PSs in the host RNA sequences. Overall, the data illustrate that the differences in RNA packaging efficiency identified through in vitro studies are insufficient to explain the specific packaging of STNV-1 RNA.IMPORTANCE Viruses preferentially encapsidate their own genomic RNA, sometimes as a result of the presence of clearly defined packaging signals (PSs) in their genome sequence. Recently, a novel form of short degenerate PSs has been proposed (N. Patel, E. C. Dykeman, R. H. A. Coutts, G. P. Lomonossoff, et al., Proc Natl Acad Sci U S A 112:2227-2232, 2015, https://doi.org/10.1073/pnas.1420812112; N. Patel, E. Wroblewski, G. Leonov, S. E. V. Phillips, et al., Proc Natl Acad Sci U S A 114:12255-12260, 2017, https://doi.org/10.1073/pnas.1706951114) using satellite tobacco necrosis virus 1 (STNV-1) as a model system for in vitro studies. It has been suggested that competing with these putative PSs may constitute a novel therapeutic approach against pathogenic single-stranded RNA viruses. Our work demonstrates that the previously identified PSs have no discernible significance for the selective packaging of STNV-1 in vivo in the presence and absence of competition or replication: viral sequences are encapsidated mostly on the basis of their abundance within the cell, while encapsidation of host RNAs also occurs. Nevertheless, the putative PSs identified in STNV-1 RNA may still have applications in bionanotechnology, such as the in vitro selective packaging of RNA molecules.

A classification system for virophages and satellite viruses

Satellite viruses encode structural proteins required for the formation of infectious particles but depend on helper viruses for completing their replication cycles. Because of this unique property, satellite viruses that infect plants, arthropods, or mammals, as well as the more recently discovered satellite-like viruses that infect protists (virophages), have been grouped with other, so-called "sub-viral agents." For the most part, satellite viruses are therefore not classified. We argue that possession of a coat-protein-encoding gene and the ability to form virions are the defining features of a bona fide virus. Accordingly, all satellite viruses and virophages should be consistently classified within appropriate taxa. We propose to create four new genera - Albetovirus, Aumaivirus, Papanivirus, and Virtovirus - for positive-sense single-stranded (+) RNA satellite viruses that infect plants and the family Sarthroviridae, including the genus Macronovirus, for (+)RNA satellite viruses that infect arthopods. For double-stranded DNA virophages, we propose to establish the family Lavidaviridae, including two genera, Sputnikvirus and Mavirus.

Satellite RNAs and Satellite Viruses of Plants

The view that satellite RNAs (satRNAs) and satellite viruses are purely molecular parasites of their cognate helper viruses has changed. The molecular mechanisms underlying the synergistic and/or antagonistic interactions among satRNAs/satellite viruses, helper viruses, and host plants are beginning to be comprehended. This review aims to summarize the recent achievements in basic and practical research, with special emphasis on the involvement of RNA silencing mechanisms in the pathogenicity, population dynamics, and, possibly, the origin(s) of these subviral agents. With further research following current trends, the comprehensive understanding of satRNAs and satellite viruses could lead to new insights into the trilateral interactions among host plants, viruses, and satellites.

Size regulation of ss-RNA viruses

While a monodisperse size distribution is common within one kind of spherical virus, the size of viral shells varies from one type of virus to another. In this article, we investigate the physical mechanisms underlying the size selection among spherical viruses. In particular, we study the effect of genome length and genome and protein concentrations on the size of spherical viral capsids in the absence of spontaneous curvature and bending energy. We find that the coat proteins could well adjust the size of the shell to the size of their genome, which in turn depends on the number of charges on it. Furthermore, we find that different stoichiometric mixtures of proteins and genome can produce virus particles of various sizes, consistent with in vitro experiments.

Analysis of the genome of satellite panicum mosaic virus

The relatedness of the genomes of satellite panicum mosaic virus (SPMV) and its helper virus, panicum mosaic virus (PMV), were investigated by nucleic acid hybridization. The results show that the satellite and helper virus RNAs have no appreciable homology or complementarity as assessed by hybridization with cDNA probes derived from the genomes of PMV and SPMV and with a probe complementary to the 3' terminus of SPMV RNA. The complete nucleotide sequence of SPMV RNA reveals that the genome is 826 nucleotides (nt) long. The ability to label SPMV RNA with polynucleotide kinase only after phosphatase treatment suggests that the 5' terminus is phosphorylated, but the extent of phosphorylation was not determined. The first open reading frame (ORF), encountered after an 88-nt 5'-untranslated region, encodes a 17,000 mol wt protein of a size and amino acid composition that are consistent with analysis of SPMV coat protein. An additional short ORF, located near the 3' end of the RNA, could encode a 6300 mol wt polypeptide. The minus strand also contains two ORFs that could potentially encode polypeptides of 7100 and 11,000 mol wt. No evidence is available to determine whether the second positive-strand ORF or the two minus-strand ORFs are expressed. The data presented here clearly show the SPMV RNA is distinct from the RNAs of other satellite viruses, in both size and nucleotide sequence. However, the 5'-untranslated portions of SPMV and satellite tobacco mosaic virus RNAs share some structural features that may be important in initiation of translation.

A history of plant virology

This review traces developments in plant virus research from its very beginning in the eighties of the 19th century until the present day. Starting with the earliest research, which gave a clue as to the existence of a pathogen different from the then known bacteria and fungi, the subsequent topics in plant virus research are highlighted, including the spread of plant viruses in nature and their relationships with possible vectors. In the course of more than a century, macroscopical and (sub)microscopical studies gave way to those with a molecular dimension, thanks to the development of sophisticated molecular-biological techniques and information technology. As a result an insight has been gained into both the molecular characteristics of plant viruses and various resistance mechanisms in plants.

A novel interaction of Cap-binding protein complexes eukaryotic initiation factor (eIF) 4F and eIF(iso)4F with a region in the 3'-untranslated region of satellite tobacco necrosis virus

Satellite tobacco necrosis virus (STNV) RNA is naturally uncapped at its 5' end and lacks polyadenylation at its 3' end. Despite lacking these two hallmarks of eukaryotic mRNAs, STNV-1 RNA is translated very efficiently. A approximately 130-nucleotide translational enhancer (TED), located 3' to the termination codon, is necessary for efficient cap-independent translation of STNV-1 RNA. The STNV-1 TED RNA fragment binds to the eukaryotic cap-binding complexes, initiation factor (eIF) 4F and eIF(iso)4F, as measured by nitrocellulose binding and fluorescence titration. STNV-1 TED is a potent inhibitor of in vitro translation when added in trans. This inhibition is reversed by the addition of eIF4F or eIF(iso)4F, and the subunits of eIF4F and eIF(iso)4F cross-link to STNV-1 TED, providing additional evidence that these factors interact directly with STNV-1 TED. Deletion mutagenesis of the STNV-1 TED indicates that a minimal region of approximately 100 nucleotides is necessary to promote cap-independent translation primarily through interaction with the cap binding subunits (eIF4E or eIF(iso)4E) of eIF4F or eIF(iso)4F.

Expression of different coding sequences in cell-free bacterial and eukaryotic systems indicates translational pausing on Escherichia coli ribosomes

Five different coding sequences of bacterial or eukaryotic origin in plasmids under the T7 promoter were expressed in a cell-free system derived from Escherichia coli. Translation on E. coli ribosomes resulted in a full-length product only in four of the five coding sequences tested. A unique pattern of less than full-length polypeptides was generated in each case. Many of these polypeptides on E. coli ribosomes reacted with a puromycin derivative, cytidylic acid-puromycin, which was radioactively labeled. Thus these incomplete polypeptides can be defined as nascent peptides bound to the ribosomal P site. Certain nascent peptides could be shifted into full-length protein indicating that they resulted from translational pausing. In contrast to these results, expression of the same coding sequences in a wheat germ or reticulocyte cell-free system resulted in a 80-90% full-length product with no evidence for nascent polypeptides and translational pausing.

A sequence located 4.5 to 5 kilobases from the 5' end of the barley yellow dwarf virus (PAV) genome strongly stimulates translation of uncapped mRNA

An infectious, in vitro transcript from a full-length cDNA clone of the barley yellow dwarf virus (PAV serotype) genome translated efficiently in a wheat germ translation extract. Deletions in a region that we call the 3' translational enhancer, located between bases 4,513 and 5,009 in the 5,677-base genome, reduced translation of the 5'-proximal open reading frames from uncapped RNA by at least 30-fold. Deletions elsewhere in all but the 5' end of the genome had no effect on translation. Presence of a m7G(5')pp(5')G cap on the 5' end fully restored translational efficiency of transcripts lacking the 3' translational enhancer. The translation enhancer reduced inhibition of translation by free cap analog, did not affect RNA stability, and did not function in reticulocyte lysates. When placed in the 3'-untranslated region of uncapped mRNA encoding the beta-glucuronidase gene, the translation enhancer stimulated translation more than 80-fold, in the presence of the viral, but not a plasmid-derived, 5' leader. A polyadenylate tail could not substitute for the 3' translation enhancer. These observations provide an extreme example, in terms of distance from the 5' end and level of stimulation, of an mRNA in which a sequence near the 3' end stimulates translation.

A histidine accepting tRNA-like fold at the 3'-end of satellite tobacco mosaic virus RNA

A model of secondary structure is proposed for the 3'-terminal sequence of the satellite tobacco mosaic virus (STMV) RNA on the basis of phylogenetic comparisons with tobacco mosaic virus (TMV) genomic RNA. Sequence homologies and compensatory base changes found between the two related viral RNAs imply that the 3'-end of STMV RNA folds into a tRNA-like domain similar to that found in the TMV RNA. Accordingly, functional assays showed that STMV RNA can be aminoacylated in vitro with histidine by yeast histidyl-tRNA synthetase to plateaus reaching 30%. Histidylation properties of STMV RNA were compared to those of TMV RNA and of a canonical yeast tRNA(His) transcript which both are chargeable to nearly 100% plateau levels. Kinetic data indicate an excellent catalytic efficiency of STMV RNA charging expressed as Vmax/Km ratio, quasi-equivalent to that of TMV RNA, and only 17-fold reduced as compared to that of the yeast tRNAHis transcript. Biological implications of the structural mimicry between the tRNA-like regions of TMV and STMV RNAs are discussed in the light of the relationships of a satellite virus with its helper virus. This is the first report on a chargeable tRNA-like structure at the 3'-end of a satellite virus RNA.

The 3' untranslated region of satellite tobacco necrosis virus RNA stimulates translation in vitro

The RNA of satellite tobacco necrosis virus (STNV) is a monocistronic messenger that lacks both a 5' cap structure and a 3' poly(A) tail. We show that in a cell-free translation system derived from wheat germ, STNV RNA lacking the 600-nucleotide trailer is translated an order of magnitude less efficiently than full-size RNA. Deletion analyses positioned the translational enhancer domain (TED) within a conserved hairpin structure immediately downstream from the coat protein cistron. TED enhances translation when fused to a heterologous mRNA, but the level of enhancement depends on the nature of the 5' untranslated sequence and is maximal in combination with the STNV leader. The STNV leader and TED have two regions of complementarity. One of the complementary regions in TED resembles picornavirus box A, which is involved in cap-independent translation but which is located upstream of the coding region.

The 3' untranslated region of satellite tobacco necrosis virus RNA stimulates translation in vitro

The RNA of satellite tobacco necrosis virus (STNV) is a monocistronic messenger that lacks both a 5' cap structure and a 3' poly(A) tail. We show that in a cell-free translation system derived from wheat germ, STNV RNA lacking the 600-nucleotide trailer is translated an order of magnitude less efficiently than full-size RNA. Deletion analyses positioned the translational enhancer domain (TED) within a conserved hairpin structure immediately downstream from the coat protein cistron. TED enhances translation when fused to a heterologous mRNA, but the level of enhancement depends on the nature of the 5' untranslated sequence and is maximal in combination with the STNV leader. The STNV leader and TED have two regions of complementarity. One of the complementary regions in TED resembles picornavirus box A, which is involved in cap-independent translation but which is located upstream of the coding region.

Structural similarities between the RNAs of two satellites of tobacco necrosis virus

The complete nucleotide sequence of satellite tobacco necrosis virus 2 (STNV-2) RNA has been determined. It has the same organization as the previously studied STNV-1 RNA. The 5' untranslated regions (about 30 nt) are nearly identical, while the coat protein coding regions (about 600 nt) have 55% nucleotide sequence similarity. The 620-nt-long trailer sequences, with 64% nucleotide sequence conservation, can fold into a phylogenetically conserved secondary structure consisting of three pseudoknots followed by a long-range interaction-born hairpin structure. The significance of these elements is discussed in view of the particular properties (stability, translational competitiveness, and replication) that characterize these RNAs.

Tumor necrosis factor. Characterization at the molecular, cellular and in vivo level

TNF was originally characterized as an antitumor agent and a factor cytotoxic for many malignant cells. It is now clear that it plays an important role in the defense against viral, bacterial and parasitic infections, - and in (auto-)immune responses. Natural induction of TNF is protective, but its overproduction may be detrimental and even lethal to the host. The structure of TNF and its interaction with the two types of cellular receptor are becoming better understood. TNF elicits a variety of events in different cell types. It subverts the electron transport system or the mitochondria into production of oxygen radicals, which can kill the (malignant) cells when these do not contain or produce protective enzymes. Furthermore, TNF induces a set of genes and at least part of this transcriptional activation is mediated by NF kappa B. The prospects of TNF as an antitumor drug can be improved on the one hand by agents such as LI+, which synergizes, and on the other hand by inhibitors of the systemic toxicity which do not interfere with the antitumor efficacy. Also, in tumor-bearing animals which have been rendered tolerant by administration of small doses of TNF, an effective and complete elimination of the tumors can be obtained by the combined action of TNF plus interferon.

Helper virus-dependent replication, nucleotide sequence and genome organization of the satellite virus of maize white line mosaic virus

Virus like particles (17 nm in diameter) associated with maize white line mosaic virus (MWLMV) were shown to be a satellite virus of MWLMV (SV-MWLMV) on the basis of the following properties: (1) The SV-MWLMV was dependent upon the presence of MWLMV for replication in maize, while the latter virus could replicate independently of the SV particles. (2) No nucleotide sequence homology was detected between the SV-MWLMV and MWLMV, using complementary DNA probes prepared to the two RNAs, in a Northern blot hybridization analysis. (3) The RNA of the SV-MWLMV translated in vitro to produce a protein of the same Mr (24,000) as that found associated with the SV particles. This protein could be immunoprecipitated with an antiserum to the SV particles. And (4), there was no serological relationship between the coat proteins of MWLMV and the SV-MWLMV. The complete nucleotide sequence of the SV-MWLMV RNA (1168 nucleotides) was determined. The SV-MWLMV RNA contains a single open reading frame encoding a polypeptide of Mr 23,961. Computer analysis revealed no significant homology between SV-MWLMV RNA and any other viral or satellite RNAs. However, the putative SV-MWLMV capsid protein is predicted to share some structural features with the capsid protein of the satellite virus of panicum mosaic virus.

Genome structure of tobacco necrosis virus strain A

An almost complete sequence of the RNA genome of tobacco necrosis virus (TNV) strain A has been determined. The genome organization is very similar to that of carnation mottle virus (CarMV) and turnip crinkle virus (TCV). The 5'-proximal open reading frame (ORF) encodes a 23-kDa protein and read-through of its amber codon into the second ORF is presumably used for the translation of a 82-kDa protein. The third large ORF encodes the 30-kDa coat protein. Two small ORFs are located upstream and one immediately downstream of this coat protein cistron. Extensive sequence similarity was found between the TNV 82-kDa protein and the putative polymerases of TCV, CarMV, cucumber necrosis virus (CNV), maize chlorotic mottle virus (MCMV), red clover necrotic mosaic virus (RCNMV), and barley yellow dwarf virus (BYDV). The TNV coat protein is very similar to southern bean mosaic virus (SBMV) capsid protein. Of the predicted small proteins only a 7.9-kDa protein shows some sequence similarity with a corresponding protein of MCMV, CarMV, and TCV. The others are unique to TNV. Except for the first four nucleotides at the 5' end no homology was found with the RNA of STNV (satellite of TNV).

Similarities among plant virus (+) and (-) RNA termini imply a common ancestry with promoters of eukaryotic tRNAs

The 5' ends of brome mosaic virus (BMV) RNAs contain sequences similar to the consensus internal control region (ICR) of pol III promoters in tRNA genes. Comparison of BMV (+)RNA 5' termini with BMV (-)RNA termini revealed the presence of two (tandem) repeats of some 30 nucleotides, the more internal containing a region of 73% similarity to the tRNA consensus ICR2 (downstream) region of the ICR. Tandem repeats containing motifs similar to the ICR2 consensus were found at the 5' termini of (-)RNAs of cucumo-, tobamo-, and tymoviruses whose 3' (+)RNAs have aminoacylatable tRNA-like structures. Single regions of homology to the BMV(+)RNA 5' terminus, containing an ICR2-like motif, were detected for several tobravirus RNAs, and for satellite tobacco necrosis virus RNA. The (+)-stranded genomes of these viruses have not been shown to be capable of amino acid esterification. The ICR2 consensus (GGUUCGANUCC) is nearly palindromic, and is contained with the T psi C loop of tRNAs and viral analogs. Consequently, tRNA promoter-like motifs can be seen at both termini of (+) and (-) RNAs of bromoviruses and other viruses. The presence of ICR1 and ICR2-like sequences in BMV genomic 5' (+)RNAs and the tobamovirus 5' (-)RNAs may reflect promoter arrangements of primordial genomic RNAs ancestral to both modern plant viruses and eukaryotic tRNAs. Several derivative concepts related to genome evolution are discussed, including the origin of asymmetric strand synthesis of RNAs.

Nucleotide sequence and translation of satellite tobacco mosaic virus RNA

Satellite tobacco mosaic virus (STMV) is a plant virus with a 17-nm icosahedral particle encapsidating a 0.3 X 10(6) Mr ssRNA genome that depends on tobamoviruses for its replication. The complete nucleotide sequence of STMV RNA deduced in the experiments described here was 1059 nucleotides in length. The efficiency of labeling viral RNA with [gamma-32P]ATP using T4 polynucleotide kinase was not affected by treatment with tobacco acid pyrophosphatase and/or bacterial alkaline phosphatase, indicating that the majority of the 5' termini of encapsidated STMV RNAs were not phosphorylated. The 240 3'-terminal nucleotides of STMV RNA and either tobacco mosaic virus (TMV) U1 RNA or TMV U2/U5 RNA had greater than 65% overall sequence similarity, with two nearly identical regions of 40 and 50 bases, respectively. There were no other regions of sequence relatedness to TMV RNA. The 19 5'-terminal nucleotides of STMV RNA had greater than 65% sequence similarity with the 16 5'-terminal nucleotides of brome mosaic virus (RNA 3 and 50% sequence similarity with the 12 5'-terminal nucleotides of the Q strain of cucumber mosaic virus RNA 3. The first open reading frame (ORF) beginning at base 53 encoded a 6800 Mr protein that corresponded in size to a major in vitro translation product directed by STMV RNA. A second ORF, beginning at nucleotide 163, had the capacity to code for a protein that corresponded in size (17,500 Mr) to the other major in vitro translation product. The first 12 codons of this ORF corresponded to the sequence of the N-terminal amino acids of the capsid protein. Western-blot analysis of the in vitro translation products revealed that the 17,500 Mr protein had the same electrophoretic mobility as the authentic capsid protein; it was also antigenically related to the capsid protein, but the 6800 Mr protein was not. Time course analysis of in vitro translation demonstrated that the 6800 Mr protein was synthesized at the same time as the capsid protein and did not arise by the proteolytic cleavage of a larger precursor polypeptide. These results suggest that the genome of STMV functioned as a polycistronic messenger RNA. It has not been determined if the 6800 Mr protein is synthesized in vivo. STMV RNA had untranslated regions of 52 and 418 nucleotides at its 5' and 3' termini, respectively.(ABSTRACT TRUNCATED AT 400 WORDS)

Nucleotide and deduced amino acid sequence of stp: the bacteriophage T4 anticodon nuclease gene

Pre-existing host tRNAs are reprocessed during bacteriophage T4 infection of certain Escherichia coli strains. In this pathway, tRNALys is cleaved 5' to the wobble base by anticodon nuclease and is later restored in polynucleotide kinase and RNA ligase reactions. Anticodon nuclease depends on prr, a locus found only in host strains that restrict T4 mutants lacking polynucleotide kinase and RNA ligase; and on stp, the T4 suppressor of prr restriction. stp was cloned and the nucleotide sequences of its wild-type and mutant alleles determined. Their comparison defined an stp open reading frame of 29 codons at 162.8 to 9 kb of T4 DNA (1 kb = 10(3) base-pairs). We suggest that stp encodes a subunit of anticodon nuclease, perhaps one that harbors the catalytic site; while additional subunits, such as a putative prr gene product, impart protein folding environment and tRNA substrate recognition.

Structure of RNA in satellite tobacco necrosis virus. A low resolution neutron diffraction study using 1H2O/2H2O solvent contrast variation

The crystal structure of satellite tobacco necrosis virus has been studied by neutron diffraction at 16 A resolution using the technique of 1H2O/2H2O solvent contrast variation to distinguish between the regions of protein and nucleic acid. The RNA density is essentially localized in a region just inside the protein coat, leading to a significant interaction between the two components. From the appearance of the RNA density we conclude that the protein coat imposes partial icosahedral symmetry on a significant proportion of the nucleic acid. The shape and dimensions of the major part of this density suggests that about 72% of the total RNA could be double-helical in structure. The most important interaction between the two components of the virus occurs between the N-terminal triple-helical arms of the protein subunits and those regions of the RNA density that could have a double-helical secondary structure.

Structure of satellite tobacco necrosis virus after crystallographic refinement at 2.5 A resolution

The structure of the protein subunit of satellite tobacco necrosis virus has been solved at 3.7 A resolution. We have now crystallographically refined the original model and extended the resolution ot 2.5 A in order to get a model accurate enough to explain the details of the subunit interactions. The refinement was done with a novel method utilizing the icosahedral symmetry of the virus particle. The final model shows a complicated network of interactions, involving salt linkages, hydrogen bonds and hydrophobic contacts. In addition, we have located three different metal ion sites in the protein shell, linking the protein subunits together. These sites are probably occupied by calcium ions. One site is found in a general position near the icosahedral 3-fold axis of the virus. The ligands form an octahedral arrangement, with two main chain carbonyl oxygens (0-61 and 0-64), one carboxylate oxygen (OD1 from Asp194) of the same subunit and a second carboxylate oxygen (OE1 of Glu25) from a 3-fold related subunit. Two water molecules complete the octahedral arrangement. A second site is on the icosahedral 3-fold axis and is liganded by the carboxylate oxygens of the 3-fold related Asp55 residues. The third metal ion site is found on the 5-fold axis, liganded by the five carbonyl oxygens of Thr138 and two water molecules. We are unable to locate the first 11 N-terminal amino acid residues, which point into the virus interior. No interpretable density for RNA has been found, indicating that the nucleic acid of the virus does not have a unique orientation in the crystal.

The 5'-terminal sequence of TMV RNA. Question on the polymorphism found in vulgare strain

The complete nucleotide sequence of TMV RNA (common strain) reported in [Proc. Natl. Acad. Sci. USA (1982) 79, 5818] its 5'-end to be represented by two variants which differed in length. We have tested that result and sequenced the 5'-terminal regions of two strains of TMV RNA (common strain OM and tomato strain L) using cloned cDNA copies. The results showed that the 5'-terminal region of the TMV genome is not polymorphic and that one of the two variants cited above represents a tomato strain but not the common strain.

Structural comparisons of some small spherical plant viruses

The structures of tomato bushy stunt virus, southern bean mosaic virus and satellite tobacco necrosis virus have been compared quantitatively. The organization of the shell domains of tomato bushy stunt virus and southern bean mosaic virus within the icosahedral envelope is identical. The wedge-shaped end of the subunit is closer to the fivefold or quasi-sixfold axes in all three viruses but the packing about the three- and twofold axes is quite different in satellite tobacco necrosis virus as compared to tomato bushy stunt virus or southern bean mosaic virus. The polypeptide folds of these viruses have greatest similarity in the beta-sheet region of the eight-stranded anti-parallel beta-barrel. The largest differences occur in the connecting segments. There is no clear indication of homologous amino acid sequences between southern bean mosaic virus and satellite tobacco necrosis virus. However, there is some conservation of the following functional groups. (1) Threonines and serines at the hexagonal-pentagonal wedge-shaped end of the subunit. (2) Lysines and arginines at the protein-RNA interface. (3) Hydrophobic residues in the cavity within the anti-parallel beta-barrel. (4) An aspartic acid near a site which binds Ca in tomato bushy stunt virus. (5) Ionic interactions in the contacts between fivefold-related subunits. These virus coat protein structures are not as similar to each other as the alpha and beta chains of hemoglobin but have greater likeness to one another than the NAD-binding domains of dehydrogenases or lysozymes from hen egg-white and T4 phage. The surface domains of tomato bushy stunt virus and southern bean mosaic virus are more like each other than like satellite tobacco necrosis virus. A divergent evolutionary tree is proposed on the basis of these observations.

Open reading frame in the minus strand of two plus type RNA viruses

: Inspection of the nucleotide sequences of the RNAs complementary to the coat protein mRNAs from two plant viruses with a tripartite genome: alfalfa mosaic virus and brome mosaic virus, showed the presence of open reading frames for 138 and 118 amino acids, respectively. A third virus (cowpea chlorotic mottle virus) from the same family (1) does not show this phenomenon. This suggests that if a protein is coded for by the open reading frames it may be not essential for virus multiplication. Alternatively the open reading frames have no coding function but result from structural requirements of the RNAs.

The sequence specificity of endonucleases CauI and CauII isolated from chloroflexus aurantiacus

The type II restriction enzymes CauI and CauII, isolated from Chloroflexus aurantiacus, recognize and cleave (at the position indicated by an arrow) the sequences G decreases G A/T CC and CC decreases G/C GG, respectively. These conclusions are supported by the results from restriction site mapping, sequence analysis by partial chemical degradation, end-group analysis after lambda exonuclease treatment and computer-assisted comparison of DNA sequence data.

Probing the function of the eucaryotic 5' cap structure by using a monoclonal antibody directed against cap-binding proteins

A monoclonal antibody directed against cap-binding proteins was used to elucidate the possible mechanism by which cap-binding proteins function in initiation of eucaryotic translation. The monoclonal antibody preparation employed in this study exhibited a marked differential effect in inhibiting the translation of folded, capped eucaryotic-mRNAs to a far greater extent than naturally uncapped mRNAs or native capped mRNAs that do not possess extensive 5' end secondary structure. These findings were consistent with the effects of the antibody on initiation complex formation with three different types of reovirus mRNA: native reovirus mRNA; inosine-substituted reovirus mRNA, which has a relaxed secondary structure; and bromouridine-substituted reovirus mRNA, in which base pairing is enhanced relative to regular reovirus mRNA. The extent that translation initiation complex formation was inhibited by the monoclonal antibody directly correlated to the degree of secondary structure present in the mRNA. Binding of bromouridine-substituted reovirus mRNA to ribosomes was inhibited to the greatest extent, while binding of inosine-substituted reovirus mRNA was not inhibited at all in the reticulocyte lysate system or was slightly inhibited in a wheat-germ system. These results support the hypothesis that cap-binding proteins are involved in unwinding of the 5' terminal, secondary structure of many eucaryotic mRNAs, thus facilitating the attachment of ribosomes to mRNA.