Double-stranded RNA Bacteriophage Phi Research Articles

RNA Packaging Device of Double-stranded RNA Bacteriophages, Possibly as Simple as Hexamer of P4 Protein

Genomes of complex viruses have been demonstrated, in many cases, to be packaged into preformed empty capsids (procapsids). This reaction is performed by molecular motors translocating nucleic acid against the concentration gradient at the expense of NTP hydrolysis. At present, the molecular mechanisms of packaging remain elusive due to the complex nature of packaging motors. In the case of the double-stranded RNA bacteriophage phi 6 from the Cystoviridae family, packaging of single-stranded genomic precursors requires a hexameric NTPase, P4. In the present study, the purified P4 proteins from two other cystoviruses, phi 8 and phi 13, were characterized and compared with phi 6 P4. All three proteins are hexameric, single-stranded RNA-stimulated NTPases with alpha/beta folds. Using a direct motor assay, we found that phi 8 and phi 13 P4 hexamers translocate 5' to 3' along ssRNA, whereas the analogous activity of phi 6 P4 requires association with the procapsid. This difference is explained by the intrinsically high affinity of phi 8 and phi 13 P4s for nucleic acids. The unidirectional translocation results in RNA helicase activity. Thus, P4 proteins of Cystoviridae exhibit extensive similarity to hexameric helicases and are simple models for studying viral packaging motor mechanisms.

Replicase activity of purified recombinant protein P2 of double-stranded RNA bacteriophage phi6.

In nature, synthesis of both minus- and plus-sense RNA strands of all the known double-stranded RNA viruses occurs in the interior of a large protein assembly referred to as the polymerase complex. In addition to other proteins, the complex contains a putative polymerase possessing characteristic sequence motifs. However, none of the previous studies has shown template-dependent RNA synthesis directly with an isolated putative polymerase protein. In this report, recombinant protein P2 of double-stranded RNA bacteriophage phi6 was purified and demonstrated in an in vitro enzymatic assay to act as the replicase. The enzyme efficiently utilizes phage-specific, positive-sense RNA substrates to produce double-stranded RNA molecules, which are formed by newly synthesized, full-length minus-strands base paired with the plus-strand templates. P2-catalyzed replication is also shown to be very effective with a broad range of heterologous single-stranded RNA templates. The importance and implications of these results are discussed.

Double-stranded RNA bacteriophage phi 6 protein P4 is an unspecific nucleoside triphosphatase activated by calcium ions.

Double-stranded RNA bacteriophage phi 6 has an envelope surrounding the nucleocapsid (NC). The NC is composed of a surface protein, P8, and proteins P1, P2, P4, and P7, which form a dodecahedral polymerase complex enclosing the segmented viral genome. Empty polymerase complex particles (procapsids) package positive-sense viral single-stranded RNAs provided that energy is available in the form of nucleoside triphosphates (NTPs). Photoaffinity labelling of both the NC and the procapsid has earlier been used to show that ATP binds to protein P4 and that the NC hydrolyzes NTPs. Using the NC and the NC core particles (NCs lacking surface protein P8) and purified protein P4, we demonstrate here that multimeric P4 is the active NTPase. Isolation of multimeric P4 is successful only in the presence of NTPs. The activity of P4 is the same in association with the viral particles as it is in pure form. P4 is an unspecific NTPase hydrolyzing ribo-NTPs, deoxy NTPs, and dideoxy NTPs to the corresponding nucleoside diphosphates. The Km of the reaction for ATP, GTP, and UTP is around 0.2 to 0.3 mM. The NTP hydrolysis by P4 absolutely requires residual amounts of Mg2+ ions and is greatly activated when the Ca2+ concentration reaches 0.5 mM. Competition experiments indicate that Mg2+ and Ca2+ ions have approximately equal binding affinities for P4. They might compete for a common binding site. The nucleotide specificity and enzymatic properties of the P4 NTPase are similar to the NTP hydrolysis reaction conditions needed to translocate and condense the viral positive-sense RNAs to the procapsid particle.

RNA structure and heterologous recombination in the double-stranded RNA bacteriophage phi 6

Bacteriophage phi 6 has a genome of three segments of double-stranded RNA, designated L, M, and S. A 1.2-kbp kanamycin resistance gene was inserted into segment M but was shown to be genetically unstable because of a high recombination rate between segment M and the 3' ends of segments S and L. The high rate of recombination is due to complementary homopolymer tracts bounding the kan gene. Removal of one arm of this potential hairpin stabilizes the insertion. The insertion of a 241- or 427-bp lacZ' gene into segment M leads to a stable Lac+ phage. The insertion of the same genes bounded by complementary homopolymer arms leads to recombinational instability. A stable derivative of this phage was shown to have lost one of the homopolymer arms. Several other conditions foster recombination. The truncation of a genomic segment at the 3' end prevents replication, but such a damaged molecule can be rescued by recombination. Similarly, insertion of the entire 3-kb lacZ gene prevents normal formation of virus, but the viral genes can be rescued by recombination. It appears that conditions leading to the retardation or absence of replication of a particular genomic segment facilitate recombinational rescue.

Dependence of minus-strand synthesis on complete genomic packaging in the double-stranded RNA bacteriophage phi 6.

Bacteriophage phi 6 has a segmented genome consisting of three pieces of double-stranded RNA (dsRNA). The viral procapsid is the structure that packages plus strands, synthesizes the complementary negative strands to form dsRNA, and then transcribes dsRNA to form plus-strand message. The minus-strand synthesis of a particular genomic segment is dependent on prior packaging of the other segments. The 5' end of the plus strand is necessary and sufficient for packaging, while the normal 3' end is necessary for synthesis of the negative strand. We have now investigated the ability of truncated RNA segments which lack the normal 3' end of the molecules to stimulate the synthesis of minus strands of the other segments. Fragments missing the normal 3' ends were able to stimulate the minus-strand synthesis of intact heterologous segments. Minus-strand synthesis of one intact segment could be stimulated by the presence of two truncated nonreplicating segments. The 5' fragments of each single-stranded genomic segment can compete with homologous full-length single-stranded genomic segments in minus-strand synthesis reactions, suggesting that there is a specific binding site in the procapsid for each segment.

Heterologous recombination in the double-stranded RNA bacteriophage phi 6.

Bacteriophage phi 6 contains three double-stranded RNA genomic segments. We have constructed a virus with an insertion of a kanamycin resistance gene in genomic RNA segment M. The virus forms small, turbid plaques, and its genome is unstable. Virus from a single plaque contained from about 0.1 to 10% large clear-plaque forms of the virus; these were usually missing the kanamycin resistance gene, and in many cases, the resulting segment M was larger or smaller than its normal size. Sequence analysis of the genomic RNA of the apparent deletions showed that they were formed by recombination events between segment M and either segment S or L. These heterologous recombination events resulted in the loss of the kanamycin resistance gene from segment M and the replacement of the 3' end of segment M with the 3' end of segment S or L. Although the 3' ends of the single-stranded RNA transcripts of the genomic segments appear to have extensive secondary structure, the sequences at the 3' ends are not involved in the specificity of genomic packaging.

The nucleocapsid of the lipid-containing double-stranded RNA bacteriophage phi 6 contains a protein skeleton consisting of a single polypeptide species.

The nucleocapsid of the enveloped double-stranded RNA bacteriophage phi 6 was isolated by extraction with the nonionic detergent Triton X-114 and subjected to disruption analysis with chelating and protein-denaturing agents. The subnucleocapsid particles were separated in rate-zonal sucrose gradients, and their ultrastructure and protein composition were analyzed. The role of divalent cations in the nucleocapsid structure was studied by using a precipitation assay of the isolated nucleocapsid proteins. The phi 6 nucleocapsid had a cagelike skeleton consisting of a single polypeptide species (P1). Two other proteins (P2 and P4) were associated with the P1 cage. These three early proteins were previously known to be involved in the RNA synthesis machinery of the virus. The stability of the nucleocapsid surface lattice consisting of protein P8 was dependent on Ca2+ ions.

Semi-conservative transcription of double-stranded RNA catalyzed by bacteriophage phi 6 RNA polymerase.

Treatment of Pseudomonas phaseolicola double-stranded RNA bacteriophage phi 6 with sodium deoxycholate converted the virions to nucleocapsids, which had in vitro RNA polymerase activity. The incorporation of [3H]UMP continued for at least 7 h. The initial incorporation was detected as intermediate RNA. Radioactivity was chased first into three segments of double-stranded RNA, and then into small, medium, and large species of single-stranded RNA successively via the intermediate RNA. Several copies of single-stranded RNA at least were synthesized from a template. The RNA synthesis clearly took place by a semi-conservative mechanism with respect to templates. That is, 5-bromo UTP was incorporated into one strand of double-stranded RNA to make a hybrid RNA of brominated and unbrominated strands. Furthermore, one strand of the 3H-labeled parental double-stranded RNA was shown to be released as single-stranded RNA.