Common Sequence at the 5′ Ends of the Segmented RNA Genomes of Influenza A and B Viruses

Guanylyl- and methyltransferases, isolated from purified vaccinia virus, were used to specifically label the 5′ ends of the genome RNAs of influenza A and B viruses. All eight segments were labeled with [α-³²P]guanosine 5′-triphosphate or S-adenosyl[methyl-³H]methionine to form “cap” structures of the type m⁷G(5′)pppN^m-, of which unmethylated (p)ppN- represents the original 5′ end. Further analyses indicated that m⁷G(5′)pppA^m, m⁷G(5′)pppA^mpGp, and m⁷G(5′)pppA^mpGpUp were released from total and individual labeled RNA segments by digestion with nuclease P1, RNase T1, and RNase A, respectively. Consequently, the 5′-terminal sequences of most or all individual genome RNAs of influenza A and B viruses were deduced to be (p)ppApGpUp. The presence of identical sequences at the ends of RNA segments of both types of influenza viruses indicates that they have been specifically conserved during evolution.     

The 3' and 5'-terminal sequences of influenza A,B and C virus RNA segments are highly conserved and show partial inverted complementarity

The 3'- and 5'-terminal nucleotides of the genome segments of an influenza A, B, and C virus were identified by directly sequencing viral RNA using two different sequencing techniques. A high degree of conservation at the 3' ends as well as at the 5' ends was observed among the genome segments of each virus and among the segments of the three different virus types. A uridine-rich region was observed from positions 17 through 22 at the 5' end of each segment. Moreover, the conserved 3' and 5'-terminal sequences showed partial and inverted complementarity. This feature results in very similar sequences at the 3' ends of the plus and minus strand RNAs and may also enable single-strand RNAs of influenza virus to form “panhandle” structures. Inverted complementary repeats may play an important role in initiation of viral RNA replication.     

Blocked and unblocked 5' termini in reovirus genome RNA

Uniformly ³²P-labeled, double-stranded genome RNA isolated from purified reovirus contains two types of 5′-terminal sequences. One strand contains a phosphatase-resistant 5′-terminal structure, XpppG^*pCpU, which is also present in the viral mRNA. The 5′ blocking group, X, is removed by β-elimination indicating that it is a nucleoside containing free 2′,3′-hydroxyls. G^*pC is an alkaline-resistant, 2′-O-methylated sequence. The other strand contains a phosphatase-sensitive 5′ sequence, ppGpPupPyp. The results are discussed in relation to blocked 5′-terminal structures in other viral and cellular RNAs.     

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.     

Reovirus Replicase-Directed Synthesis of Double-Stranded Ribonucleic Acid

After the incubation of reovirus replicase reaction mixtures (containing labeled ribonucleoside triphosphates), partially double-stranded ribonucleic acid (pdsRNA) products were isolated by cellulose column chromatography followed by precipitation with 2 m NaCl. The pulse-labeled reaction product contained a significantly large amount of pdsRNA that became complete dsRNA as reaction time increased, indicating that pdsRNA was an intermediate of the replicase reaction. The newly synthesized RNA strand (³H-labeled) of the pdsRNA was resistant to ribonuclease digestion, suggesting that single-stranded RNA regions were part of a preexistent unlabeled RNA template. These observations, together with the electrophoretic behavior of the pdsRNA in polyacrylamide gel, are consistent with the hypothesis that dsRNA is synthesized by the elongation of a complementary RNA strand upon a preexistent template of single-stranded RNA (i.e., messenger RNA). The direction of the RNA strand elongation was determined by carrying out the replicase reaction in the presence of ³H-cytidine triphosphate (or ³H-uridine triphosphate) and adenine triphosphate-α-³²P followed by a chase with excess unlabeled cytidine triphosphate (or uridine triphosphate). The dsRNA product was digested with T1 ribonuclease and the resulting 3′-terminal fragments were isolated by chromatography on a dihydroxyboryl derivative of cellulose. Examination of the ratio of ³H to ³²P in these fragments indicated that RNA synthesis proceeded from the 5′ to 3′ terminus.     

A Functional Antigenomic Promoter for the Paramyxovirus Simian Virus 5 Requires Proper Spacing between an Essential Internal Segment and the 3′ Terminus

A previous analysis of naturally occurring defective interfering (DI) RNA genomes of the prototypic paramyxovirus simian virus 5 (SV5) indicated that 113 bases at the 3′ terminus of the antigenome were sufficient to direct RNA encapsidation and replication. A nucleotide sequence alignment of the antigenomic 3′-terminal 113 bases of members of the Rubulavirus genus of the Paramyxoviridae family identified two regions of sequence identity: bases 1 to 19 at the 3′ terminus (conserved region I [CRI]) and a more distal region consisting of antigenome bases 73 to 90 (CRII) that was contained within the 3′ coding region of the L protein gene. To determine whether these regions of the antigenome were essential for SV5 RNA replication, a reverse genetics system was used to analyze the replication of copyback DI RNA analogs that contained a foreign gene (GL, encoding green fluorescence protein) flanked by 113 5′-terminal bases and various amounts of SV5 3′-terminal antigenomic sequences. Results from a deletion analysis showed that efficient encapsidation and replication of SV5-GL DI RNA analogs occurred when the 90 3′-terminal bases of the SV5 antigenomic RNA were retained, but replication was reduced ~5- to 14-fold in the case of truncated antigenomes that lacked the 3′-end CRII sequences. A chimeric copyback DI RNA containing the 3′-terminal 98 bases including the CRI and CRII sequences from the human parainfluenza virus type 2 (HPIV2) antigenome in place of the corresponding SV5 sequences was efficiently replicated by SV5 cDNA-derived components. However, replication was reduced ~20-fold for a truncated SV5-HPIV2 chimeric RNA that lacked the HPIV2 CRII sequences between antigenome bases 72 and 90. Progressive deletions of 6 to 18 bases in the region located between the SV5 antigenomic CRI and CRII segments (3′-end nucleotides 21 to 38) resulted in a ~25-fold decrease in SV5-GL RNA synthesis. Surprisingly, replication was restored to wild-type levels when these length alterations between CRI and CRII were corrected by replacing the deleted bases with nonviral sequences. Together, these data suggest that a functional SV5 antigenomic promoter requires proper spacing between an essential internal region and the 3′ terminus. A model is presented for the structure of the 3′ end of the SV5 antigenome which proposes that positioning of CRI and CRII along the same face of the helical nucleocapsid is an essential feature of a functional antigenomic promoter.     

Unpaired 5′ ppp-Nucleotides,as Found in Arenavirus Double-stranded RNA Panhandles,Are Not Recognized by RIG-I

Arenavirus and bunyavirus RNA genomes are unusual in that they are found in circular nucleocapsids, presumably due to the annealing of their complementary terminal sequences. Moreover, arenavirus genome synthesis initiates with GTP at position +2 of the template rather than at the precise 3′ end (position +1). After formation of a dinucleotide, 5′ pppGpC_OH is then realigned on the template before this primer is extended. The net result of this “prime and realign” mechanism of genome initiation is that 5′ pppG is found as an unpaired 5′ nucleotide when the complementary genome ends anneal to form a double-stranded (dsRNA) panhandle. Using 5′ pppRNA made in vitro and purified so that all dsRNA side products are absent, we have determined that both this 5′ nucleotide overhang, as well as mismatches within the dsRNA (as found in some arenavirus genomes), clearly reduce the ability of these model dsRNAs to induce interferon upon transfection into cells. The presence of this unpaired 5′ ppp-nucleotide is thus another way that some viruses appear to use to avoid detection by cytoplasmic pattern recognition receptors.     

草鱼出血病病毒873株基因组外发现缺损性干扰颗粒的亚基因组成份

草鱼出血病病毒基因组由 11条dsRNA片段组成。最近在研究其基因组时发现 ,在病毒基因组外存在许多核酸成份 ,但在核苷酸数量上少于基因组成份 ,表现为较小分子量的RNA片段。在完整地克隆了这些片段的全长cDNA后 ,测定了其中两个克隆的序列组成 ,发现它们为病毒基因组经剪切后的部分片段 ,已经重新装配 ,而且都含有原基因组某一片段 3′端和 5′端的保守区和倒转重复区 ,缺失中间部分。根据其特点来看 ,它们应为目前病毒学研究的重要材料———缺损性干扰颗粒的亚基因组成份。     

A complex RNA motif defined by three discontinuous 5-nucleotide-long strands is essential for Flavivirus RNA replication

Tertiary or higher-order RNA motifs that regulate replication of positive-strand RNA viruses are as yet poorly understood. Using Japanese encephalitis virus (JEV), we now show that a key element in JEV RNA replication is a complex RNA motif that includes a string of three discontinuous complementary sequences (TDCS). The TDCS consists of three 5-nt-long strands, the left (L) strand upstream of the translation initiator AUG adjacent to the 5′-end of the genome, and the middle (M) and right (R) strands corresponding to the base of the Flavivirus-conserved 3′ stem–loop structure near the 3′-end of the RNA. The three strands are arranged in an antiparallel configuration, with two sets of base-pairing interactions creating L-M and M-R duplexes. Disrupting either or both of these duplex regions of TDCS completely abolished RNA replication, whereas reconstructing both duplex regions, albeit with mutated sequences, fully restored RNA replication. Modeling of replication-competent genomes recovered from a large pool of pseudorevertants originating from six replication-incompetent TDCS mutants suggests that both duplex base-pairing potentials of TDCS are required for RNA replication. In all cases, acquisition of novel sequences within the 3′M-R duplex facilitated a long-range RNA–RNA interaction of its 3′M strand with either the authentic 5′L strand or its alternative (invariably located upstream of the 5′ initiator), thereby restoring replicability. We also found that a TDCS homolog is conserved in other flaviviruses. These data suggest that two duplex base-pairings defined by the TDCS play an essential regulatory role in a key step(s) of Flavivirus RNA replication.     

Tandem oligonucleotide synthesis using linker phosphoramidites

Multiple oligonucleotides of the same or different sequence, linked end-to-end in tandem can be synthesized in a single automated synthesis. A linker phosphoramidite [R. T. Pon and S. Yu (2004) Nucleic Acids Res., 32, 623–631] is added to the 5′-terminal OH end of a support-bound oligonucleotide to introduce a cleavable linkage (succinic acid plus sulfonyldiethanol) and the 3′-terminal base of the new sequence. Conventional phosphoramidites are then used for the rest of the sequence. After synthesis, treatment with ammonium hydroxide releases the oligonucleotides from the support and cleaves the linkages between each sequence. Mixtures of one oligonucleotide with both 5′- and 3′-terminal OH ends and other oligonucleotides with 5′-phosphorylated and 3′-OH ends are produced, which are deprotected and worked up as a single product. Tandem synthesis can be used to make pairs of PCR primers, sets of cooperative oligonucleotides or multiple copies of the same sequence. When tandem synthesis is used to make two self-complementary sequences, double-stranded structures spontaneously form after deprotection. Tandem synthesis of oligonucleotide chains containing up to six consecutive 20mer (120 bases total), various trinucleotide codons and primer pairs for PCR, or self-complementary strands for in situ formation of double-stranded DNA fragments has been demonstrated.     

Genomic analysis of codon,sequence and structural conservation with selective biochemical-structure mapping reveals highly conserved and dynamic structures in rotavirus RNAs with potential cis-acting functions

Rotaviruses are a major cause of acute, often fatal, gastroenteritis in infants and young children world-wide. Virions contain an 11 segment double-stranded RNA genome. Little is known about the cis-acting sequences and structural elements of the viral RNAs. Using a database of 1621 full-length sequences of mammalian group A rotavirus RNA segments, we evaluated the codon, sequence and RNA structural conservation of the complete genome. Codon conservation regions were found in eight ORFs, suggesting the presence of functional RNA elements. Using ConStruct and RNAz programmes, we identified conserved secondary structures in the positive-sense RNAs including long-range interactions (LRIs) at the 5′ and 3′ terminal regions of all segments. In RNA9, two mutually exclusive structures were observed suggesting a switch mechanism between a conserved terminal LRI and an independent 3′ stem–loop structure. In RNA6, a conserved stem–loop was found in a region previously reported to have translation enhancement activity. Biochemical structural analysis of RNA11 confirmed the presence of terminal LRIs and two internal helices with high codon and sequence conservation. These extensive in silico and in vitro analyses provide evidence of the conservation, complexity, multi-functionality and dynamics of rotavirus RNA structures which likely influence RNA replication, translation and genome packaging.     

Identification of Specific Nucleotide Sequences within the Conserved 3′-SL in the Dengue Type 2 Virus Genome Required for Replication

The flavivirus genome is a positive-stranded ~11-kb RNA including 5′ and 3′ noncoding regions (NCR) of approximately 100 and 400 to 600 nucleotides (nt), respectively. The 3′ NCR contains adjacent, thermodynamically stable, conserved short and long stem-and-loop structures (the 3′-SL), formed by the 3′-terminal ~100 nt. The nucleotide sequences within the 3′-SL are not well conserved among species. We examined the requirement for the 3′-SL in the context of dengue virus type 2 (DEN2) replication by mutagenesis of an infectious cDNA copy of a DEN2 genome. Genomic full-length RNA was transcribed in vitro and used to transfect monkey kidney cells. A substitution mutation, in which the 3′-terminal 93 nt constituting the wild-type (wt) DEN2 3′-SL sequence were replaced by the 96-nt sequence of the West Nile virus (WN) 3′-SL, was sublethal for virus replication. An analysis of the growth phenotypes of additional mutant viruses derived from RNAs containing DEN2-WN chimeric 3′-SL structures suggested that the wt DEN2 nucleotide sequence forming the bottom half of the long stem and loop in the 3′-SL was required for viability. One 7-bp substitution mutation in this domain resulted in a mutant virus that grew well in monkey kidney cells but was severely restricted in cultured mosquito cells. In contrast, transpositions of and/or substitutions in the wt DEN2 nucleotide sequence in the top half of the long stem and in the short stem and loop were relatively well tolerated, provided the stem-loop secondary structure was conserved.