Complete nucleotide sequence of the group I RNA bacteriophage fr

Analysis of Six New Genes Encoding Lysis Proteins and Coat Proteins inEscherichia coliGroup A RNA Phages

Group A RNA phages consist of four genes-maturation protein, coat protein, lysis protein and replicase genes. We analyzed six plasmids containing lysis protein genes and coat protein genes of Escherichia coli group A RNA phages and compared their amino acid sequences with the known proteins of E. coli(group A), Pseudomonas aeruginosa(PP7) RNA phages and Rg-lysis protein from Qbeta phage. The size of lysis proteins was different by the groups but the coat proteins were almost the same size among phages. The phylogenetic analysis shows that the sub-groups A-I and A-II of E. coli RNA phages were clearly dispersed into two clusters.

Rethinking the evolution of single-stranded RNA (ssRNA) bacteriophages based on genomic sequences and characterizations of two R-plasmid-dependent ssRNA phages, C-1 and Hgal1

We have sequenced and characterized two R-plasmid-dependent single-stranded RNA bacteriophages (RPD ssRNA phages), C-1 and Hagl1. Phage C-1 requires a conjugative plasmid of the IncC group, while Hgal1 requires the IncH group. Both the adsorption rate constants and one-step growth curves are determined for both phages. We also empirically confirmed the lysis function of the predicted lysis genes. Genomic sequencing and phylogenetic analyses showed that both phages belong to the Levivirus group and are most closely related to another IncP-plasmid-dependent ssRNA phage, PRR1. Furthermore, our result strongly suggests that the stereotypical bauplans of genome organization found in Levivirus and Allolevivirus predate phage specialization for conjugative plasmids, suggesting that the utilization of conjugative plasmids for cell attachment and entry comprises independent evolutionary events for these two main clades of ssRNA phages. Our result is also consistent with findings of a previous study, making the Levivirus-like genome organization ancestral and the Allolevivirus-like genome derived. To obtain a deeper insight into the evolution of ssRNA phages, more phages specializing for various conjugative plasmids and infecting different bacterial species would be needed.

Genome structure of caulobacter phage phiCb5

The complete genome sequence of caulobacter phage phiCb5 has been determined, and four open reading frames (ORFs) have been identified and characterized. As for related phages, the ORFs code for maturation, coat, replicase, and lysis proteins, but unlike other Leviviridae members, the lysis protein gene of phiCb5 entirely overlaps with the replicase in a different reading frame. The lysis protein of phiCb5 is about two times longer than that of the distantly related MS2 phage and presumably contains two transmembrane helices. Analysis of the proposed genome secondary structure revealed a stable 5' stem-loop, similar to other phages, and a substantially shorter 3' untranslated region (UTR) structure with only three stem-loops.

Molecular detection and genotyping of male-specific coliphages by reverse transcription-PCR and reverse line blot hybridization

In recent years, there has been increased interest in the use of male-specific or F+ coliphages as indicators of microbial inputs to source waters. Sero- or genotyping of these coliphages can also be used for microbial source tracking (MST). Among the male-specific coliphages, the F+ RNA (FRNA) viruses are well studied, while little is known about the F+ DNA (FDNA) viruses. We have developed a reverse line blot hybridization (RLB) assay which allows for the simultaneous detection and genotyping of both FRNA as well as FDNA coliphages. These assays included a novel generic duplex reverse transcription-PCR (RT-PCR) assay for FRNA viruses as well as a generic PCR for FDNA viruses. The RT-PCR assays were validated by using 190 field and prototype strains. Subsequent DNA sequencing and phylogenetic analyses of RT-PCR products revealed the classification of six different FRNA clusters, including the well-established subgroups I through IV, and three different FDNA clusters, including one (CH) not previously described. Within the leviviruses, a potentially new subgroup (called JS) including strains having more than 40% nucleotide sequence diversity with the known levivirus subgroups (MS2 and GA) was identified. We designed subgroup-specific oligonucleotides that were able to genotype all nine (six FRNA, three FDNA) different clusters. Application of the method to a panel of 351 enriched phage samples from animal feces and wastewater, including known prototype strains (MS2, GA, Q beta, M11, FI, and SP for FRNA and M13, f1, and fd for FDNA), resulted in successful genotyping of 348 (99%) of the samples. In summary, we developed a novel method for standardized genotyping of F+ coliphages as a useful tool for large-scale MST studies.

Structure of phage fr capsids with a deletion in the FG loop: implications for viral assembly

The loop between beta-strands F and G in the coat protein of small RNA bacteriophages forms the interactions at the fivefold and threefold (quasi-sixfold) icosahedral axes. In many cases, mutations in this region renders the coat protein unable to form capsids. This FG loop has therefore been suggested to be of major importance for the virus assembly process by guiding the assembly and helping to define the correct curvature of the virus shell. We have determined the crystal structure of a phage fr capsid where the coat protein has a four-residue deletion in the FG loop. This mutant retains the ability to form virus capsids of normal size but has a significantly lower temperature stability than the wild type. The structure reveals that the mutated loops are flexible and too short to interact with each other. This seems incompatible with a role of the FG loop in the regulation of capsid size.

RNA folding kinetics regulates translation of phage MS2 maturation gene

The gene for the maturation protein of the single-stranded RNA coliphage MS2 is preceded by an untranslated leader of 130 nt, which folds into a cloverleaf, i.e., three stem-loop structures enclosed by a long distance interaction (LDI). This LDI prevents translation because its 3' moiety contains the Shine-Dalgarno sequence of the maturation gene. Previously, several observations suggested that folding of the cloverleaf is kinetically delayed, providing a time window for ribosomes to access the RNA. Here we present direct evidence for this model. In vitro experiments show that ribosome binding to the maturation gene is faster than refolding of the denatured cloverleaf. This folding delay appears related to special properties of the leader sequence. We have replaced the three stem-loop structures by a single five nt loop. This change does not affect the equilibrium structure of the LDI. Nevertheless, in this construct, the folding delay has virtually disappeared, suggesting that now the RNA folds faster than ribosomes can bind. Perturbation of the cloverleaf by an insertion makes the maturation start permanently accessible. A pseudorevertant that evolved from an infectious clone carrying the insertion had overcome this defect. It showed a wild-type folding delay before closing down the maturation gene. This experiment reveals the biological significance of retarded cloverleaf formation.

Efficient transcription of the tRNA-like structure of turnip yellow mosaic virus by a template-dependent and specific viral RNA polymerase obtained by a new procedure [corrected]

The RNA-dependent RNA polymerase (RdRp) of turnip yellow mosaic virus (TYMV) was isolated by a simple, new method. An active, template-dependent and specific enzyme was obtained. Although the genomic RNA of TYMV could not be transcribed completely during an in vitro RdRp assay, a complete double-stranded product was obtained when a 3' terminal RNA fragment of 83 nucleotides was used as a template. The reaction product was identified as being of negative polarity by complete digestion with ribonuclease T1. Antibodies directed to part of the N-terminal (Ab140) or C-terminal (Ab66) in vitro autocleavage products of the large non-structural polyprotein of TYMV, could both partially inhibit RdRp activity. Further purification of the RdRp preparation by ion-exchange chromatography resulted in two activity peaks with different protein compositions. Both peak fractions retained high specificity for transcription of TYMV RNA. A protein of approximately 115 kDa was detected by both Ab140 and Ab66.

An oligonucleotide hybridization assay for the identification and enumeration of F-specific RNA phages in surface water

F-specific RNA phages can be used as model organisms for enteric viruses to monitor the effectiveness of sewage treatment, and to assess the potential contamination of surface water with these viruses. In this paper a method is described which identifies RNA phages quantitatively by a plaque hybridization assay. Oligonucleotide probes were developed that can assign phages to their phylogenetic subgroups. Such a distinction is important, since some subgroups preferentially occur in sewage of human origin, while others tend to be associated with animal wastewater. The method has been tested on a large number of isolates and represents an improvement in time and reliability over the previously used serological classification.

Secondary structure model of the Mason-Pfizer monkey virus 5' leader sequence: identification of a structural motif common to a variety of retroviruses

A stable secondary structure model is presented for the region 3' of the primer-binding site to 130 bases into the gag sequence of the prototype type D retrovirus Mason-Pfizer monkey virus. Using biochemical probing of RNA from this region in association with free energy minimization, we have identified a stem-loop structure in the region, which from other studies has been shown to be important for genomic RNA encapsidation. The structure involves a highly stable stem of five G-C pairs terminating in a heptaloop. Comparison of the Mason-Pfizer monkey virus structure with one predicted for squirrel monkey retrovirus demonstrates an identical stem and a common ACC motif in the loop. Free energy studies of the secondary structure of the 5' regions of eight other retroviruses predict stem loops which have similar GAYC motifs. We believe this may represent a common structural and sequence motif which among other functions may be involved in genomic RNA packaging in these viruses.

Nucleotide sequence of a single-stranded RNA phage from Pseudomonas aeruginosa: kinship to coliphages and conservation of regulatory RNA structures

We report the complete nucleotide sequence of the single-stranded RNA phage PP7 from Pseudomonas aeruginosa. There are three open reading frames which code for apparent protein homologues of the single-stranded RNA coliphages, i.e., maturation protein, coat protein, and replicase. A fourth overlapping reading frame exists that probably encodes a lysis protein, similar to what has been found in the group A coliphages such as MS2. The genetic map of PP7 is colinear with group A coliphages and we accordingly classify the phage as a levivirus. There is, generally speaking, no significant nucleotide sequence identity between PP7 and the coliphages except for a few regions where homologous parts of proteins are encoded, most notable in the replicase gene. In these regions the nucleotide sequence similarity between PP7 and MS2 is no greater than between PP7 and the group B coliphages such as Q beta. Surprisingly, Q beta and MS2 are no closer to each other than they are to PP7. Several regulatory RNA secondary structure features that are present in the coliphages were identified also in PP7 RNA although the sequences involved cannot be aligned. Among these are the coat protein binding helix at the start of the replicase gene, structures at the 5' and 3' terminus of the RNA, a replicase binding site, and the structure of the coat protein cistron start. Some of these features resemble MS2 type coliphages but others the Q beta type. These findings suggest that PP7 is related to the coliphages but branched off before the coliphages diverged into separate groups.

Translational control by a long range RNA-RNA interaction; a basepair substitution analysis

One of the two mechanisms that regulate expression of the replicase cistron in the single stranded RNA coliphages is translational coupling. This mechanism prevents ribosomes from binding at the start of the replicase cistron unless the upstream coat cistron is being translated. Genetic analysis had identified a maximal region of 132 nucleotides in the coat gene over which ribosomes should pass to activate the replicase start. Subsequent deletion studies in our laboratory had further narrowed down the regulatory region to 12 nucleotides. Here, we identify a long-distance RNA-RNA interaction of 6 base pairs as the basis of the translational polarity. The 3' side of the complementarity region is located in the coat-replicase intercistronic region, some 20 nucleotides before the start codon of the replicase. The 5' side encodes amino acids 31 and 32 of the coat protein. Mutations that disrupt the long-range interaction abolish the translational coupling. Repair of basepairing by second site base substitutions restores translational coupling.

Bacteriophage lysis: mechanism and regulation

Bacteriophage lysis involves at least two fundamentally different strategies. Most phages elaborate at least two proteins, one of which is a murein hydrolase, or lysin, and the other is a membrane protein, which is given the designation holin in this review. The function of the holin is to create a lesion in the cytoplasmic membrane through which the murein hydrolase passes to gain access to the murein layer. This is necessary because phage-encoded lysins never have secretory signal sequences and are thus incapable of unassisted escape from the cytoplasm. The holins, whose prototype is the lambda S protein, share a common organization in terms of the arrangement of charged and hydrophobic residues, and they may all contain at least two transmembrane helical domains. The available evidence suggests that holins oligomerize to form nonspecific holes and that this hole-forming step is the regulated step in phage lysis. The correct scheduling of the lysis event is as much an essential feature of holin function as is the hole formation itself. In the second strategy of lysis, used by the small single-stranded DNA phage phi X174 and the single-stranded RNA phage MS2, no murein hydrolase activity is synthesized. Instead, there is a single species of small membrane protein, unlike the holins in primary structure, which somehow causes disruption of the envelope. These lysis proteins function by activation of cellular autolysins. A host locus is required for the lytic function of the phi X174 lysis gene E.

Structural consensus of RNA templates replicated by Q beta replicase

Q beta replicase replicates a variety of enzyme-specific small RNAs in addition to the phage genomic RNA. The sequence analysis has revealed that all these RNAs are potentially capable of forming a consensus secondary structure element. It represents a stalk which is formed by the 5'-GGG ... and ... CCCA-3' complementary stretches at the termini of the replicating RNA molecules and adjacent 5'- and 3'-hairpins, which may form a stacking with the stalk. The structure found is rather similar to the analogous structure in the tRNA molecule. The genomic RNA of the Q beta phage and other related phages can also form a similar structural element.

Secondary structure of coliphage Q beta RNA. Analysis by electron microscopy

The secondary structure of genomic RNA from the coliphage Q beta has been examined by electron microscopy in the presence of varying concentrations of spermidine using the Kleinschmidt spreading technique. The size and position of structural features that cover 70% of the viral genome have been mapped. The structural features that are visualized by electron microscopy in Q beta RNA are large. They range in size from 170 to 1600 nucleotides. A loop containing approximately 450 nucleotides is located at the 5' end of the RNA. It includes the initiation region for the viral maturation protein. A large hairpin containing approximately 1600 nucleotides is located in the center of the molecule. It is multibranched and includes most of the viral coat gene, the readthrough region of the A1 gene, and approximately one third of the viral replicase gene. Within the central hairpin, the initiation region for the viral replicase gene pairs with a region within the distal third of the viral coat gene. This structure may participate in the regulation of translational initiation of the viral replicase gene. Two structural variants of the central hairpin were observed. One of them brings the internal S and M viral replicase binding regions into juxtaposition. These observations suggest that the central hairpin may also participate in the regulation of translation of the viral coat gene. The secondary structures that are observed in Q beta RNA differ significantly from structures that we described previously in the genomic RNA of coliphage MS2 but are similar to structures we observed by electron microscopy in the related group B coliphage SP.

Secondary structure at the 3' terminal region of RNA coliphages: comparison with tRNA

Secondary structure models for the 3' non-coding region of the four groups of coliphage RNA are proposed based on comparative sequence analysis and on previously published data on the sensitivity of nucleotides in MS2 RNA to chemical modification and enzymes. We report the following observations. (1) In contrast to the coding regions, the structure at the 3' terminus is characterized by stable regular helices. We note the occurrence of the loop sequences 5'-GUUCGC and 5'-CGAAAG, that are reported to confer exceptional stability to stem structures. These features are probably present to promote the segregation of mother and daughter strands during replication. (2) Comparison of homologous helices indicates that only those base pair substitutions are allowed that maintain the thermodynamic stability. (3) We have compared the structure of phage RNA with tRNA. Overall similarity is low, but one common element may exist. It is a quasi-continuous helix of 12 basepairs that could be the equivalent of the 12 basepair long coaxially stacked helix, formed by the T psi C arm and the aminoacyl acceptor arm in tRNA. As in tRNA, this structure element starts after the fourth nucleotide from the 3' end. (4) Phage RNA contains a large variable region of about 35 nucleotides bulging out from the quasi-continuous helix. We speculate that the variable loop in present-day tRNA could be the remnant of the variable region found in phage RNA. The variable region contains overlapping binding sites for the replicase enzyme and the maturation protein. This common binding site may serve as a switch from replication to packaging.