Further characterization of the replicative complex of vesicular stomatitis virus.

Replicating vesicular stomatitis virus ribonucleoprotein (RNP) complexes were isolated in nonequilibrium Renografin density gradients. These nascent RNPs had the same buoyant density as virion nucleocapsids in both isopycnic Renografin and CsCl gradients. Both transcribing and replicating RNP complexes were shown to be stable in sucrose gradients, whereas only replicating RNP complexes were stable in Renografin gradients. Size analysis of the 5-min-pulse-labeled RNA species from the replicating RNPs using methylmercury gels revealed that the nascent strands were primarily less than full-length molecules. Longer times of radiolabeling demonstrated that the nascent RNA accumulated as 42S RNA, which was primarily of the same sense as the virion strand when it was radiolabeled at 5 h postinfection. The percentage of this radiolabeled RNA which was plus stranded was higher at 2.5 h postinfection, reflective of the shift in plus- to minus-stranded full-length 42S RNA synthesis which occurs in the cell. Addition of cycloheximide to the infected cells before the addition of the radiolabel prevented the formation of these RNP complexes. Both the change in the percentage of minus strands found in the RNP complexes at the different times postinfection and the sensitivity to cycloheximide indicate that the RNP complex which was isolated was indeed the replicative complex.     

Ribonucleoprotein complexes of hepatitis delta virus.

Human hepatitis delta virus (HDV) is a subviral satellite agent of hepatitis B virus (HBV). The envelope proteins of HDV are provided by the helper virus, HBV, but very little is known about the internal structure of HDV. The particles contain multiple copies of the delta antigen and an unusual RNA genome that is small, about 1,700 nucleotides in length, single stranded, and circular. By using UV cross-linking, equilibrium density centrifugation, and immunoprecipitation, we obtained evidence consistent with the interpretation that delta antigen and genomic RNA form a stable ribonucleoprotein (RNP) complex within the virion. Furthermore, electron-microscopic examination of the purified viral RNP revealed a roughly spherical core-like structure with a diameter of 18.7 +/- 2.5 nm. We also isolated HDV-specific RNP structures from the nuclei of cells undergoing HDV genome replication; both the genome and antigenome (a complement of the genome) of HDV were found to be in such complexes. From the equilibrium density analyses of the viral and nuclear RNPs, we were able to deduce the number of molecules of delta antigen per molecule of HDV RNA. For virions, this number was predominantly ca. 70, which was larger than for the nuclear RNPs, which were more heterogeneous, with an average value of ca. 30.     

Comparison of Vesicular Stomatitis Virus Intracellular and Virion Ribonucleoproteins

Vesicular stomatitis virus ribonucleoproteins (RNP) obtained by a detergent treatment of purified virus (vRNP) or from infected HeLa cell cytoplasm (icRNP) were examined by sedimentation in sucrose or Renografin gradients in the presence or absence of EDTA. It was shown that vRNP and icRNP sediment at the same rate in sucrose and Renografin in the absence of EDTA; however, icRNP sedimented more slowly in the presence of EDTA than did vRNP. Polyacrylamide gel electrophoresis of the proteins of vRNA and icRNP recovered from EDTA-containing gradients demonstrated that both RNP structures contained L, N, and NS proteins in the same proportion. Electron microscopy of both RNP structures, in the absence of EDTA, demonstrated that both exist as helical structures ~20 by 700 nm. However, in the presence of EDTA the icRNP was completely uncoiled with a mean length of 4,095 nm, whereas vRNP was hardly affected. The addition of excess Mg²⁺ or Mn²⁺ to uncoiled icRNP preparations partially restored the coiled configuration. These observations suggest that the change in sedimentation of icRNP in the presence of EDTA is due to a change from a coiled to an uncoiled conformation, that icRNP and vRNP are not structurally identical, and that icRNP must undergo a conformational change during maturation of VSV from the 20-by-700-nm intracellular form to the 50-by-175-nm form found in intact virus. The icRNP containing L, N, and NS proteins (icRNP^L,N,NS) and icRNP containing only N protein (icRNP^N), prepared by centrifugation of icRNP^L,N,NS in CsCl to remove L and NS, were compared by cosedimentation in sucrose gradients. There was a decrease in sedimentation rate of icRNP^N due to loss of L and NS. This sedimentation difference was also apparent in the presence of EDTA; however, both icRNP^L,N,NS and icRNP^N sedimented at a much slower rate in the presence of EDTA, and by electron microscopy both were completely uncoiled. These observations suggest that N protein alone is responsible for the 20-by-700-nm coiled structure and that the divalent cation interactions disrupted by EDTA are N-N or N-RNA interactions. These results are discussed with regard to vesicular stomatitis virus maturation.     

DNA polymerase δ stalls on telomeric lagging strand templates independently from G-quadruplex formation

Previous evidence indicates that telomeres resemble common fragile sites and present a challenge for DNA replication. The precise impediments to replication fork progression at telomeric TTAGGG repeats are unknown, but are proposed to include G-quadruplexes (G4) on the G-rich strand. Here we examined DNA synthesis and progression by the replicative DNA polymerase δ/proliferating cell nuclear antigen/replication factor C complex on telomeric templates that mimic the leading C-rich and lagging G-rich strands. Increased polymerase stalling occurred on the G-rich template, compared with the C-rich and nontelomeric templates. Suppression of G4 formation by substituting Li⁺ for K⁺ as the cation, or by using templates with 7-deaza-G residues, did not alleviate Pol δ pause sites within the G residues. Furthermore, we provide evidence that G4 folding is less stable on single-stranded circular TTAGGG templates where ends are constrained, compared with linear oligonucleotides. Artificially stabilizing G4 structures on the circular templates with the G4 ligand BRACO-19 inhibited Pol δ progression into the G-rich repeats. Similar results were obtained for yeast and human Pol δ complexes. Our data indicate that G4 formation is not required for polymerase stalling on telomeric lagging strands and suggest that an alternative mechanism, in addition to stable G4s, contributes to replication stalling at telomeres.     

Ribonucleoprotein particles containing non-coding Y RNAs, Ro60, La and nucleolin are not required for Y RNA function in DNA replication

Background

Ro ribonucleoprotein particles (Ro RNPs) consist of a non-coding Y RNA bound by Ro60, La and possibly other proteins. The physiological function of Ro RNPs is controversial as divergent functions have been reported for its different constituents. We have recently shown that Y RNAs are essential for the initiation of mammalian chromosomal DNA replication, whereas Ro RNPs are implicated in RNA stability and RNA quality control. Therefore, we investigate here the functional consequences of RNP formation between Ro60, La and nucleolin proteins with hY RNAs for human chromosomal DNA replication.

Methodology/Principal Findings

We first immunoprecipitated Ro60, La and nucleolin together with associated hY RNAs from HeLa cytosolic cell extract, and analysed the protein and RNA compositions of these precipitated RNPs by Western blotting and quantitative RT-PCR. We found that Y RNAs exist in several RNP complexes. One RNP comprises Ro60, La and hY RNA, and a different RNP comprises nucleolin and hY RNA. In addition about 50% of the Y RNAs in the extract are present outside of these two RNPs. Next, we immunodepleted these RNP complexes from the cytosolic extract and tested the ability of the depleted extracts to reconstitute DNA replication in a human cell-free system. We found that depletion of these RNP complexes from the cytosolic extract does not inhibit DNA replication in vitro. Finally, we tested if an excess of recombinant pure Ro or La protein inhibits Y RNA-dependent DNA replication in this cell-free system. We found that Ro60 and La proteins do not inhibit DNA replication in vitro.

Conclusions/Significance

We conclude that RNPs containing hY RNAs and Ro60, La or nucleolin are not required for the function of hY RNAs in chromosomal DNA replication in a human cell-free system, which can be mediated by Y RNAs outside of these RNPs. These data suggest that Y RNAs can support different cellular functions depending on associated proteins.     

Subnuclear particles containing a small nuclear RNA and heterogeneous nuclear RNA

Five of the stable low molecular weight RNA species in the HeLa cell nucleus have been localized in RNP complexes in the cell nucleus. The two abundant species C and D and the three minor species F, G′ and H are found in RNP particles following two different methods of preparation. Sonication of nuclei releases the five small RNAs and also the hnRNA in RNPs that sediment in a range from 10 to 150 S. Alternatively, incubation of intact nuclei at elevated temperature and pH releases four of the small RNAs and degraded hnRNA in more slowly sedimenting structures.When nuclear RNPs obtained by sonication are digested with RNAase in the presence of EDTA, the hnRNA is degraded and the hnRNPs sediment at 30 S. The structures containing the small RNA species D are similarly shifted to 30 S particles by RNAase and EDTA but not by either agent alone. In contrast, the sedimentation of complexes containing species G′ and H are not altered by exposure to RNAase/EDTA and small RNA species C and F are unstable under these conditions.In isopycnic metrizamide/²H₂O gradients species D and hnRNA accumulate at a density characteristic of RNP particles. They have a similar but not identical distribution.Species D is released from large RNPs by salt concentrations of 0.1 m-NaCl or greater, while the hnRNA remains in large RNP particles. In contrast, the structures containing species G′ and H are stable in 0.3 m-NaCl. All five of the small nuclear RNA species and the hnRNAs are released from rapidly sedimenting complexes by the ionic detergent sodium deoxycholate.It is suggested that the low molecular weight RNA species play a structural role in RNP particles in the cell nucleus and that a subpopulation of species D may be associated with the particles that package the hnRNA.     

Poliovirus RNA replication requires genome circularization through a protein-protein bridge.

The mechanisms and factors involved in the replication of positive stranded RNA viruses are still unclear. Using poliovirus as a model, we show that a long-range interaction between ribonucleoprotein (RNP) complexes formed at the ends of the viral genome is necessary for RNA replication. Initiation of negative strand RNA synthesis requires a 3' poly(A) tail. Strikingly, it also requires a cloverleaf-like RNA structure located at the other end of the genome. An RNP complex formed around the 5' cloverleaf RNA structure interacts with the poly(A) binding protein bound to the 3' poly(A) tail, thus linking the ends of the viral RNA and effectively circularizing it. Formation of this circular RNP complex is required for initiation of negative strand RNA synthesis. RNA circularization may be a general replication mechanism for positive stranded RNA viruses.     

The C-terminal LCAR of host ANP32 proteins interacts with the influenza A virus nucleoprotein to promote the replication of the viral RNA genome

The segmented negative-sense RNA genome of influenza A virus is assembled into ribonucleoprotein complexes (RNP) with viral RNA-dependent RNA polymerase and nucleoprotein (NP). It is in the context of these RNPs that the polymerase transcribes and replicates viral RNA (vRNA). Host acidic nuclear phosphoprotein 32 (ANP32) family proteins play an essential role in vRNA replication by mediating the dimerization of the viral polymerase via their N-terminal leucine-rich repeat (LRR) domain. However, whether the C-terminal low-complexity acidic region (LCAR) plays a role in RNA synthesis remains unknown. Here, we report that the LCAR is required for viral genome replication during infection. Specifically, we show that the LCAR directly interacts with NP and this interaction is mutually exclusive with RNA. Furthermore, we show that the replication of a short vRNA-like template that can be replicated in the absence of NP is less sensitive to LCAR truncations compared with the replication of full-length vRNA segments which is NP-dependent. We propose a model in which the LCAR interacts with NP to promote NP recruitment to nascent RNA during influenza virus replication, ensuring the co-replicative assembly of RNA into RNPs.     

Messenger ribonucleoprotein complexes of cryptobiotic embryos of Artemia salina.

Poly(A)-containing ribonucleoprotein (poly(A)+-RNP) particles in the post-mitochondrial supernatant of cryptobiotic embryos of Artemia salina were characterized by hybridization to [3H]-poly(U). By sucrose isopycnic centrifugation, approximately 2/3 of poly(A)+-RNPs was found to band at 1.27-1.30 (g/cm3) and the rest 1+/3 at 1.20-1.23 (g/cm3) and below 1.20 (g/cm3). The 1.27-1.30 RNPs could be separated into two density classes, 1.27-1.28 and 1.30 (g/cm3) respectively. The latter RNP class was apparently complexed with ribosomal components because they were completely converted to the former RNP class (free RNPs) by 25 mM EDTA treatment. Further, the 1.30 (g/cm3) RNPs were resolved into several RNP species having sedimentation coefficients above 50 S. which were transformed mostly to 20-30 S rnps in the presence of 25 mM EDTA. The free 20-30 S RNPs contained 8-14 S poly(A)+-RNAs, having the highest template activity in a wheat embryo cell-free system, whereas the 1.20-1.23 poly(A)+-RNPs consisted of 10 S and 16 S RNPs, both of which contained 4 S poly(A)-containing sequences without any template activity.     

Ultrastructure of free ribonucleoprotein complexes in spread mammalian nuclei

Mouse erythroleukemia cell nuclei obtained by three different methods were spread for electron microscopy under low ionic conditions. It was found that this procedure allows the observation of free large ribonucleoprotein (RNP) complexes released from the nuclei during the centrifugation. The morphology of these complexes was readily affected by the conditions of cell treatment and spreading. Two extreme forms of free nuclear RNP structures were obtained, both consisting of spherical particles with diameters of approximately 17-20 nm. The first type was of loosened complexes of irregularly assembled particles interconnected with RNA fibrils. The second represented tightly packed particles forming mostly branched structures. The latter structures appeared to be closer to the native form of the nuclear RNP particles, differing from polyribosomes by their characteristic branching and stability in EDTA solutions.