Representation of the leader region of Rous sarcoma virus genome RNA in double-stranded RNA produced in virus-transformed cells

Restriction fragments of recombinant plasmids containing a proviral sequence of Rous sarcoma virus (RSV) were Southern hybridized with double-stranded (ds) RNA isolated from the cells transformed with RSV. Hybridization data show that the major subpopulation of dsRNA molecules is homologous to the 5'-end region of the viral genome including the leader sequence. We have analysed the RNAs of RSV-transformed cells by the Northern procedure hybridizing them with the proviral fragment containing double long terminal repeats. The results demonstrate that the 14-16S RNA fraction is enriched in sequences which are homologous to the proviral end regions. We consider this RNA fraction to be homologous to the 5'-terminal region of the viral genome and (or) to its antisense strand.     

RNAi: double-stranded RNA directs the ATP-dependent cleavage of mRNA at 21 to 23 nucleotide intervals

Double-stranded RNA (dsRNA) directs the sequence-specific degradation of mRNA through a process known as RNA interference (RNAi). Using a recently developed Drosophila in vitro system, we examined the molecular mechanism underlying RNAi. We find that RNAi is ATP dependent yet uncoupled from mRNA translation. During the RNAi reaction, both strands of the dsRNA are processed to RNA segments 21-23 nucleotides in length. Processing of the dsRNA to the small RNA fragments does not require the targeted mRNA. The mRNA is cleaved only within the region of identity with the dsRNA. Cleavage occurs at sites 21-23 nucleotides apart, the same interval observed for the dsRNA itself, suggesting that the 21-23 nucleotide fragments from the dsRNA are guiding mRNA cleavage.     

Effects of cDNA hybridization on translation of encephalomyocarditis virus RNA.

Cell-free translation of the RNA of encephalomyocarditis virus was examined after hybridization of chemically synthesized cDNA fragments to different sites of the 5' noncoding region of the viral RNA. The following results were obtained. The binding of cDNA fragments to the first 41 nucleotides, to the poly(C) tract (between nucleotides 149 and 263), and to the sequence between nucleotides 309 and 338 did not affect translation of the viral RNA; the binding of cDNA fragments to the sequence between nucleotides 420 and 449 caused a slight inhibition; and the binding of fragments to eight different sites between nucleotides 450 and the initiator AUG codon (nucleotide 834) caused high degrees of inhibition. The results suggest that the first part of the 5' untranslated region, at least to nucleotide 338, may not be required for encephalomyocarditis viral RNA translation; however, the region near nucleotide 450 is important for translation of the viral RNA. The possibility that initiation occurs at an internal site is discussed.     

Native replication intermediates of the yeast 20 S RNA virus have a single-stranded RNA backbone

20 S RNA virus is a positive strand RNA virus found in Saccharomyces cerevisiae. The viral genome (2.5 kb) only encodes its RNA polymerase (p91) and forms a ribonucleoprotein complex with p91 in vivo. A lysate prepared from 20 S RNA-induced cells showed an RNA polymerase activity that synthesized the positive strands of viral genome. When in vitro products, after phenol extraction, were analyzed in a time course, radioactive nucleotides were first incorporated into double-stranded RNA (dsRNA) intermediates and then chased out to the final single-stranded RNA products. The positive and negative strands in these dsRNA intermediates were non-covalently associated, and the release of the positive strand products from the intermediates required a net RNA synthesis. We found, however, that these dsRNA intermediates were an artifact caused by phenol extraction. Native replication intermediates had a single-stranded RNA backbone as judged by RNase sensitivity experiments, and they migrated distinctly from a dsRNA form in non-denaturing gels. Upon completion of RNA synthesis, positive strand RNA products as well as negative strand templates were released from replication intermediates. These results indicate that the native replication intermediates consist of a positive strand of less than unit length and a negative strand template loosely associated, probably through the RNA polymerase p91. Therefore, W, a dsRNA form of 20 S RNA that accumulates in yeast cells grown at 37 degrees C, is not an intermediate in the 20 S RNA replication cycle, but a by-product.     

Double-stranded RNA is internalized by scavenger receptor-mediated endocytosis in Drosophila S2 cells

Double-stranded RNA (dsRNA) fragments are readily internalized and processed by Drosophila S2 cells, making these cells a widely used tool for the analysis of gene function by gene silencing through RNA interference (RNAi). The underlying mechanisms are insufficiently understood. To identify components of the RNAi pathway in S2 cells, we developed a screen based on rescue from RNAi-induced lethality. We identified Argonaute 2, a core component of the RNAi machinery, and three gene products previously unknown to be involved in RNAi in Drosophila: DEAD-box RNA helicase Belle, 26 S proteasome regulatory subunit 8 (Pros45), and clathrin heavy chain, a component of the endocytic machinery. Blocking endocytosis in S2 cells impaired RNAi, suggesting that dsRNA fragments are internalized by receptor-mediated endocytosis. Indeed, using a candidate gene approach, we identified two Drosophila scavenger receptors, SR-CI and Eater, which together accounted for more than 90% of the dsRNA uptake into S2 cells. When expressed in mammalian cells, SR-CI was sufficient to mediate internalization of dsRNA fragments. Our data provide insight into the mechanism of dsRNA internalization by Drosophila cells. These results have implications for dsRNA delivery into mammalian cells.     

Solid-phase methods for sequencing nucleic acids. III. Simultaneous sequencing of different long RNA fragments using DE 81 anion-exchange paper

A solid-phase method for simultaneous sequencing of different long RNA fragments has been developed using Whatman DE 81 anion-exchange paper as the support. The approach involves 8 operations including: immobilization of heat-denatured 3'-end labeled RNA fragment on DE 81 paper; washing; modification reactions; washing; aniline reaction; washing; RNA desorption by salt and ethanol precipitation. For modifying the RNA, the following reactions were selected for the routine: G with dimethylsulfate at 90 degrees C/sodium borohydride at 0 degrees C, A + G with diethylpyrocarbonate at 90 degrees C, U + C with hydrazine at 0 degrees C and C with hydrazine/5M NaCl at 0 degrees C. The losses of RNA material during the reactions with large excess of reactants were 50% during the reduction with NaBH4 and 30% during C-reaction. Almost no losses were observed during aniline reaction. The RNA could be recovered by desorption with 2M NaClO4 in 50-70% yield. The whole solid-phase procedure up to the sequencing gel takes about 2 hours and is much faster and more convenient than chemical RNA sequencing in solution according to Peattie, especially if many fragments are to be processed.     

Double-stranded RNA in rice: A novel RNA replicon in plants

The entire sequence of 13952 nucleotides of a plasmid-like, double-stranded RNA (dsRNA) from rice was assembled from more than 50 independent cDNA clones. The 5 non-coding region of the coding (sense) strand spans over 166 nucleotides, followed by one long open reading frame (ORF) of 13716 nucleotides that encodes a large putative polyprotein of 4572 amino acid residues, and by a 70-nucleotide 3 noncoding region. This ORF is apparently the longest reported to date in the plant kingdom. Amino acid sequence comparisons revealed that the large putative polyprotein includes an RNA helicase-like domain and an RNA-dependent RNA polymerase (replicase)-like domain. Comparisons of the amino acid sequences of these two domains and of the entire genetic organization of the rice dsRNA with those found in potyviruses and the CHV1-713 dsRNA of chestnut blight fungus suggest that the rice dsRNA is located evolutionarily between potyviruses and the CHV1-713 dsRNA. This plasmid-like dsRNA in rice seems to constitute a novel RNA replicon in plants.     

Both yeast W double-stranded RNA and its single-stranded form 20S RNA are linear.

Most yeast strains carry a cytoplasmic double-stranded RNA (dsRNA) molecule called W, of 2.5 kb in size. We have cloned and sequenced most of W genome (1), and we proposed that W (+) strands were identical to 20S RNA, a single-stranded RNA (ssRNA) species, whose copy number is highly induced under stress conditions. Recently it was proposed that 20S RNA was circular (2). In this paper, however, we demonstrate that both W dsRNA and 20S RNA are linear. Linearity of W dsRNA is shown by the stoichiometric labelling of both strands of W with 32P-pCp and T4 RNA ligase. The last 3' end nucleotide of both strands is about 70 to 80% C and 20 to 30% A. Linearity of 20S RNA is directly demonstrated by a site-specific cleavage of 20S RNA with RNase H, using an oligodeoxynucleotide complementary to an internal site of 20S RNA. The cleavage produced not one but two RNA fragments expected from the linearity of 20S RNA.     

DEAD-box RNA helicase domains exhibit a continuum between complete functional independence and high thermodynamic coupling in nucleotide and RNA duplex recognition

DEAD-box helicases catalyze the non-processive unwinding of double-stranded RNA (dsRNA) at the expense of adenosine triphosphate (ATP) hydrolysis. Nucleotide and RNA binding and unwinding are mediated by the RecA domains of the helicase core, but their cooperation in these processes remains poorly understood. We therefore investigated dsRNA and nucleotide binding by the helicase cores and the isolated N- and C-terminal RecA domains (RecA_N, RecA_C) of the DEAD-box proteins Hera and YxiN by steady-state and time-resolved fluorescence methods. Both helicases bind nucleotides predominantly via RecA_N, in agreement with previous studies on Mss116, and with a universal, modular function of RecA_N in nucleotide recognition. In contrast, dsRNA recognition is different: Hera interacts with dsRNA in the absence of nucleotide, involving both RecA domains, whereas for YxiN neither RecA_N nor RecA_C binds dsRNA, and the complete core only interacts with dsRNA after nucleotide has been bound. DEAD-box proteins thus cover a continuum from complete functional independence of their domains, exemplified by Mss116, to various degrees of inter-domain cooperation in dsRNA binding. The different degrees of domain communication and of thermodynamic linkage between dsRNA and nucleotide binding have important implications on the mechanism of dsRNA unwinding, and may help direct RNA helicases to their respective cellular processes.     

Organization of shared and unshared sequences in the genomes of chicken endogenous and sarcoma viruses.

The genome of the genetically transmitted endogenous C type virus of chickens, RAV-O, is closely related to that of Rous sarcoma virus (RSV). Nevertheless, these viruses differ widely in oncogenicity and regulation by the host cell. Competitive hybridization analysis of ¹²⁵I-labeled genomic RNA demonstrated that the genome of RAV-O lacks about 35% of the sequences of nondefective RSV which formed hybrids with proviral DNA from RSV-infected cells, and that the genome of transformation-defective deletion mutants of RSV (td RSV) lacks about 15% of these sequences. Conversely, about 12% of the RAV-O sequences forming hybrids with normal chicken cell DNA were not detected in the sarcoma virus. A technique was developed to map the location of these unshared sequences by competitive hybridization. The deletion in the genome of td RSV was seen to begin at about 0.2 and to end at about 0.05 of the genome length from the 3′ end of sarcoma virus RNA, confirming the results of other laboratories using the method of mapping RNAase TI resistance of oligonucleotides. The 35% of RSV sequences missing and/or diverged in the genome of RAV-O were concentrated within 40% of the sarcoma virus genome from the 3′ end, and most of this large section did not appear to form hybrids with chicken DNA under the conditions of these experiments. A low level of hybrid formation was, however, detected between uninfected chicken cellular DNA and a small fraction of the nucleotides in the region of the td deletion. Analysis of RAV-O 3′ end fragments demonstrated that the genomic sequences of RAV-O missing in RSV were concentrated at the 3′ end of the endogenous viral genome. We conclude that the sequence differences between endogenous and sarcoma viruses are largely concentrated in specific regions of the viral genome.     

The first two nucleotides of the respiratory syncytial virus antigenome RNA replication product can be selected independently of the promoter terminus

There is limited knowledge regarding how the RNA-dependent RNA polymerases of the nonsegmented negative-strand RNA viruses initiate genome replication. In a previous study of respiratory syncytial virus (RSV) RNA replication, we found evidence that the polymerase could select the 5'-ATP residue of the genome RNA independently of the 3' nucleotide of the template. To investigate if a similar mechanism is used during antigenome synthesis, a study of initiation from the RSV leader (Le) promoter was performed using an intracellular minigenome assay in which RNA replication was restricted to a single step, so that the products examined were derived only from input mutant templates. Templates in which Le nucleotides 1U, or 1U and 2G, were deleted directed efficient replication, and in both cases, the replication products were initiated at the wild-type position, at position -1 or -2 relative to the template, respectively. Sequence analysis of the RNA products showed that they contained ATP and CTP at the -1 and -2 positions, respectively, thus restoring the mini-antigenome RNA to wild-type sequence. These data indicate that the RSV polymerase is able to select the first two nucleotides of the antigenome and initiate at the correct position, even if the 3'-terminal two nucleotides of the template are missing. Substitution of positions +1 and +2 of the template reduced RNA replication and resulted in increased initiation at positions +3 and +5. Together these data suggest a model for how the RSV polymerase initiates antigenome synthesis.     

Pyrimidine-rich oligonucleotides from rat-liver ribosome surface.

The distribution of oligonucleotides which are released from rat liver ribosomes by treatment with pancreatic ribonuclease has been studied. Rat liver monoribosomes lost from 15 to 17% of their nucleotides by treatment with pancreatic ribonuclease. This quantity was highly reproducible and did not depend significantly on the temperature (0-20 degrees C) and time (10-120 min) of incubation or on the concentration of enzyme (1:5000-1:50). Whereas the amounts of oligonucleotides liberated was 16%, it was shown by column chromatography that they consisted of 71% mononucleotides, 16% dinucleotides, 6% trinucleotides, 4% tetranucleotides and 2% pentanucleotides and that these oligonucleotides were enriched in uridine, containing approximately half of the uridine residues present in the high-molecular-weitht ribosomal RNA. The high molecular weight of the RNA from ribonuclease-treated ribosomes was preserved until it was heated; after heating, RNA fragments having sedimentation coefficients of 5 S and less were present. It is inferred that the olignucleotides are derived from pyrimidine-rich clusters located in single-stranded "hairpin" loops on the outside surface of the ribosome.     

A ribonuclease-resistant region of 5S RNA and its relation to the RNA binding sites of proteins L18 and L25.

An RNA fragment, constituting three subfragments of nucleotide sequences 1-11, 69-87 and 89-120, is the most ribonuclease-resistant part of the native 5S RNA of Escherichia coli, at 0 degrees C. A smaller fragment of nucleotide sequence 69-87 and 90-110 is ribonuclease-resistant at 25 degrees. Degradation of the L25-5S RNA complex with ribonuclease A or T2 yielded RNA fragments similar to those of the free 5S RNA at 0 degrees C and 25 degrees C; moreover L25 remained strongly bound to both RNA fragments and also produced some opening of the RNA structure in at least two positions. Protein L18 initially protected most of the 5S RNA against ribonuclease digestion, at 0 degrees C, but was then gradually released prior to the formation of the larger RNA fragment. It cannot be concluded, therefore, as it was earlier (Gray et al., 1973), that this RNA fragment contains the primary binding site of L18.     

单引物法扩增马尾松毛虫CPV基因组第8片段及其序列分析

本文利用T4 RNA连接酶将5'－磷酸,3'-氨基修饰的引物1连接到马尾松毛虫质型多角体病毒第8片段dsRNA的3'-OH端,经逆转录,退火,补齐形成全长双链cDNA。使用单一的互补引物2进行PCR 增,扩增产物克隆在pMD18-T载体上,对重组子进行限制性内切酶分析及序列测定。结果表明,克隆片段全长330bp,S'端具有CPV－1型末端保守序列AGTAAA'端具有保守序列GTTAGCC。起始密码子从ATG位于38－40残基,终止密码子TAA位于1208－1210残基。推测S8片段编码390年氨基酸多肽,分子量为44kDa。与舞毒蛾质多角体病（LdCPV)第8片段相比较,核苷酸和氨基酸同源性分别为97％和98％。与家蚕质型多角体病毒（BmCPV）第8片段相比较,核苷酸和氨基酸的同源性分别为83％和85％。与人的呼肠孤病毒第8片段比较没有明显的同源性。     

Dynamics of double-stranded RNA segments in a Helicobasidium mompa clone from a tulip tree plantation

Eighty-three isolates of the violet root rot fungus, Helicobasidium mompa, were collected in a tulip tree plantation and analyzed for the dynamics of double-stranded (ds) RNA for five years. They were divided into eight mycelial compatibility groups (MCGs). Prevalent MCGs 60 and 68 included 61 and 11 isolates, respectively. Electrophoretic profiles of dsRNA in the first year collection of MCG 60 contained no or a single large dsRNA (more than 10 kb) with or without small dsRNAs (ca. 2.0-2.5 kb). Additional dsRNA fragments, i.e., a middle dsRNA (ca. 8.0 kb) or another type of small dsRNAs, became evident within MCG 60 isolates with time. Northern hybridization revealed the relatedness of all large and middle dsRNA fragments within MCG 60 but small fragments of dsRNA were variable. Large dsRNA fragment differed from that in other MCGs even in the same field. Correlation between specific dsRNA fragments and hypovirulence was not observed. Possible explanations for the accumulation of dsRNA fragments during the growth of disease patch by MCG 60 are discussed in terms of their internal changes such as evolution of novel dsRNA fragments from pre-existing viruses or fungal genomic DNA and horizontal transmissions.