Transcription strategy in a Closterovirus: a novel 5'-proximal controller element of Citrus Tristeza Virus produces 5'- and 3'-terminal subgenomic RNAs and differs from 3' open reading frame controller elements

Citrus tristeza virus (CTV) produces more than thirty 3'- or 5'-terminal subgenomic RNAs (sgRNAs) that accumulate to various extents during replication in protoplasts and plants. Among the most unusual species are two abundant populations of small 5'-terminal sgRNAs of approximately 800 nucleotides (nt) termed low-molecular-weight tristeza (LMT1 and LMT2) RNAs. Remarkably, CTV replicons with all 10 3' genes deleted produce only the larger LMT1 RNAs. These 5'-terminal positive-sense sgRNAs do not have corresponding negative strands and were hypothesized to be produced by premature termination during plus-strand genomic RNA synthesis. We characterized a cis-acting element that controls the production of the LMT1 RNAs. Since manipulation of this cis-acting element in its native position (the L-ProI region of replicase) was not possible because the mutations negatively affect replication, a region (5'TR) surrounding the putative termination sites (nt approximately 550 to 1000) was duplicated in the 3' end of a CTV replicon to allow characterization. The duplicated sequence continued to produce a 5'-terminal plus-strand sgRNA, here much larger ( approximately 11 kb), apparently by termination. Surprisingly, a new 3'-terminal sgRNA was observed from the duplicated 5'TR. A large 3'-terminal sgRNA resulting from the putative promoter activity of the native 5'TR was not observed, possibly because of the down-regulation of a promoter approximately 19 kb from the 3' terminus. However, we were able to observe a sgRNA produced from the native 5'TR of a small defective RNA, which placed the native 5'TR closer to the 3' terminus, demonstrating sgRNA promoter activity of the native 5'TR. Deletion mutagenesis mapped the promoter and the terminator activities of the 5'TR (in the 3' position in the CTV replicon) to a 57-nt region, which was folded by the MFOLD computer program into two stem-loops. Mutations in the putative stem-loop structures equally reduced or prevented production of both the 3'- and 5'-terminal sgRNAs. These mutations, when introduced in frame in the native 5'TR, similarly abolished the synthesis of the LMT1 RNAs and presumably the large 3'-terminal sgRNA while having no impact on replication, demonstrating that neither 5'- nor 3'-terminal sgRNA is necessary for replication of the replicon or full-length CTV in protoplasts. Differences between the 5'TR, which produced two plus-strand sgRNAs, and the cis-acting elements controlling the 3' open reading frames, which produced additional minus-strand sgRNAs corresponding to the 3'-terminal mRNAs, suggest that the different sgRNA controller elements had different origins in the modular evolution of closteroviruses.     

The p23 Protein of Citrus Tristeza Virus Controls Asymmetrical RNA Accumulation

Citrus tristeza virus (CTV), a member of the Closteroviridae, has a 19.3-kb positive-stranded RNA genome that is organized into 12 open reading frames (ORFs) with the 10 3' genes expressed via a nested set of nine or ten 3'-coterminal subgenomic mRNAs (sgRNAs). Relatively large amounts of negative-stranded RNAs complementary to both genomic and sgRNAs accumulate in infected cells. As is characteristic of RNA viruses, wild-type CTV produced more positive than negative strands, with the plus-to-minus ratios of genomic and sgRNAs estimated at 10 to 20:1 and 40 to 50:1, respectively. However, a mutant with all of the 3' genes deleted replicated efficiently, but produced plus to minus strands at a markedly decreased ratio of 1 to 2:1. Deletion analysis of 3'-end genes revealed that the p23 ORF was involved in asymmetric RNA accumulation. A mutation which caused a frameshift after the fifth codon resulted in nearly symmetrical RNA accumulation, suggesting that the p23 protein, not a cis-acting element within the p23 ORF, controls asymmetric accumulation of CTV RNAs. Further in-frame deletion mutations in the p23 ORF suggested that amino acid residues 46 to 180, which contained RNA-binding and zinc finger domains, were indispensable for asymmetrical RNA accumulation, while the N-terminal 5 to 45 and C-terminal 181 to 209 amino acid residues were not absolutely required. Mutation of conserved cysteine residues to alanines in the zinc finger domain resulted in loss of activity of the p23 protein, suggesting involvement of the zinc finger in asymmetric RNA accumulation. The absence of p23 gene function was manifested by substantial increases in accumulation of negative-stranded RNAs and only modest decreases in positive-stranded RNAs. Moreover, the substantial decrease in the accumulation of negative-stranded coat protein (CP) sgRNA in the presence of the functional p23 gene resulted in a 12- to 15-fold increase in the expression of the CP gene. Apparently the excess negative-stranded sgRNA reduces the availability of the corresponding positive-stranded sgRNA as a messenger. Thus, the p23 protein controls asymmetric accumulation of CTV RNAs by downregulating negative-stranded RNA accumulation and indirectly increases expression of 3' genes.     

Involvement of a subgenomic mRNA in the generation of a variable population of defective citrus tristeza virus molecules.

The fusion sites between the termini of naturally occurring defective RNAs (D-RNAs) from three citrus tristeza virus (CTV) isolates were sequenced. Seven of eight clones showed a common 3' terminus of 940 nucleotides (nt) fused to 5' termini with different sizes. An extra cytosine nucleotide was found at the junction site of the majority of the common 3' D-RNAs. Molecular analysis of the plus and minus strands of the 0.9-kbp double-stranded RNA, corresponding to the CTV open reading frame 11 subgenomic RNA (sgRNA), showed that they were identical in length and sequence to the common 3' sequence of the D-RNAs. These results imply that viral sgRNA messengers also function as building components for genomic rearrangement and exchange of complete viral genes.     

Selection of 3'-template bases and initiating nucleotides by hepatitis C virus NS5B RNA-dependent RNA polymerase

De novo RNA synthesis by hepatitis C virus (HCV) nonstructural protein 5B (NS5B) RNA-dependent RNA polymerase has been investigated using short RNA templates. Various templates including those derived from the HCV genome were evaluated by examining the early steps of de novo RNA synthesis. NS5B was shown to be able to produce an initiation dinucleotide product from templates as short as 4-mer and from the 3'-terminal sequences of both plus and minus strands of the HCV RNA genome. GMP, GDP, and guanosine were able to act as an initiating nucleotide in de novo RNA synthesis, indicating that the triphosphate moiety is not absolutely required by an initiating nucleotide. Significant amounts of the initiation product accumulated in de novo synthesis, and elongation from the dinucleotide was observed when large amounts of dinucleotide were available. This result suggests that NS5B, a template, and incoming nucleotides are able to form an initiation complex that aborts frequently by releasing the dinucleotide product before transition to an elongation complex. The transition is rate limiting. Furthermore, we discovered that the secondary structure of a template was not essential for de novo initiation and that 3'-terminal bases of a template conferred specificity in selection of an initiation site. Initiation can occur at the +1, +2, or +3 position numbered from the 3' end of a template depending on base composition. Pyrimidine bases at any of the three positions are able to serve as an initiation site, while purine bases at the +2 and +3 positions do not support initiation. This result implies that HCV possesses an intrinsic ability to ensure that de novo synthesis is initiated from the +1 position and to maintain the integrity of the 3' end of its genome. This assay system should be an important tool for investigating the detailed mechanism of de novo initiation by HCV NS5B as well as other viral RNA polymerases.     

Expansion of CRISPR targeting sites in Bombyx mori

The CRISPR/Cas9 system has been proven as a revolutionary genome engineering tool. In most cases, single guide RNA (sgRNA) targeting sites have been designed as GN19NGG or GGN18NGG, because of restriction of the initiation nucleotide for RNA Pol III promoters. Here, we demonstrate that the U6 promoter from a lepidopteran model insect, Bombyx mori, effectively expressed the sgRNA initiated with any nucleotide bases (adenine, thymine, guanine or cytosine), which further expands the CRISPR targeting space. A detailed expansion index in the genome was analysed when N20NGG was set as the CRISPR targeting site instead of GN19NGG, and revealed a significant increase of suitable targets, with the highest increase occurring on the Z sex chromosome. Transfection of different types of N20NGG sgRNAs targeting the enhanced green fluorescent protein (EGFP) combined with Cas9, significantly reduced EGFP expression in the BmN cells. An endogenous gene, BmBLOS2, was also disrupted by using various types of N20NGG sgRNAs, and the cleavage efficiency of N20NGG sgRNAs with different initial nucleotides and GC contents was evaluated in vitro. Furthermore, transgenic silkworms expressing Cas9 and sgRNAs targeting the BmBLOS2 gene were generated with many types of mutagenesis. The typical transparent skin phenotype in knock-out silkworms was stable and inheritable, suggesting that N20NGG sgRNAs function sufficiently in vivo. Our findings represent a renewal of CRISPR/Cas9 target design and will greatly facilitate insect functional genetics research.     

Control of start codon choice on a plant viral RNA encoding overlapping genes.

The signals that control initiation of translation in plants are not well understood. To dissect some of these signals, we used a plant viral mRNA on which protein synthesis initiates at two out-of-frame start codons. On the large subgenomic RNA (sgRNA1) of barley yellow dwarf virus-PAV serotype, the coat protein (CP) and overlapping 17K open reading frames (ORFs) are translated beginning at the first and second AUG codons, respectively. The roles of bases at positions -3 and +4 relative to the AUG codons in efficiency of translation initiation were investigated by translation of sgRNA1 mutants in a cell-free extract and by expression of a reporter gene from mutant sgRNA1 leaders in protoplasts. The effects of mutations that disrupted and restored secondary structure encompassing the CP AUG independently of, and in combination with, changes to bases -3 and +4 were also examined. Partial digestion of the 5' end of the sgRNA1 leader with structure-sensitive nucleases gave products that were consistent with the predicted secondary structure. Secondary structure had an overall inhibitory effect on translation of both ORFs. In general, the "Kozak rules" of start codon preference predominate in determining start codon choice. Unexpectedly, for a given CP AUG sequence context, changes that decreased initiation at the downstream 17K AUG also reduced initiation at the CP AUG. To explain this observation, we propose a new model in which pausing of the ribosome at the second AUG allows increased initiation at the first AUG. This detailed analysis of the roles of primary and secondary structure in controlling translation initiation should be of value for understanding expression of any plant gene and in the design of artificial constructs.     

A highly conserved lysine residue in phi29 DNA polymerase is important for correct binding of the templating nucleotide during initiation of phi29 DNA replication

DNA polymerases that initiate replication by protein-priming are able to catalyze terminal protein (TP)-primed initiation, the following transition steps and finally DNA-primed elongation. Therefore, their structures must be able to position sequentially both primers, TP and DNA, at a common binding site. For DNA-templated initiation, these DNA polymerases have to bind the origin of replication as template and TP as primer. It is likely that very precise interactions are required to position both TP and templating nucleotide at the polymerization active site. Such a specificity during TP-priming must rely on specific amino acids that must be evolutionarily conserved in this subfamily of DNA polymerases. By site-directed mutagenesis, we have analyzed the functional significance of Lys392 of phi29 DNA polymerase, immediately adjacent to the Kx3NSxYG motif, and specifically conserved among protein-primed DNA polymerases. During TP-primed initiation, mutations in this residue did not affect untemplated TP-dAMP formation, indicating that the interaction with the initiating nucleotide and TP were not affected, whereas the template-directed initiation activity was severely inhibited. Both mutant DNA polymerases had a wild-type-like (overall) DNA binding activity. We thus infer that residue Lys392 of phi29 DNA polymerase is important for the correct positioning of the templating nucleotide at the polymerization active site, a critical requirement during template-directed TP-priming at phi29 DNA origins. Consequently, mutation of this residue compromised the fidelity of the initiation reaction, not controlled by the 3'-5' exonuclease activity. During DNA-primed polymerization, the mutant polymerases showed a defect in translocation of the template strand. This translocation problem could be the consequence of a more general defect in the stabilization and positioning of a next templating nucleotide at the polymerization active site, during DNA-primed DNA synthesis.     

Characterization of a novel 5' subgenomic RNA3a derived from RNA3 of Brome mosaic bromovirus

The synthesis of 3' subgenomic RNA4 (sgRNA4) by initiation from an internal sg promoter in the RNA3 segment was first described for Brome mosaic bromovirus (BMV), a model tripartite positive-sense RNA virus (W. A. Miller, T. W. Dreher, and T. C. Hall, Nature 313:68-70, 1985). In this work, we describe a novel 5' sgRNA of BMV (sgRNA3a) that we propose arises by premature internal termination and that encapsidates in BMV virions. Cloning and sequencing revealed that, unlike any other BMV RNA segment, sgRNA3a carries a 3' oligo(A) tail, in which respect it resembles cellular mRNAs. Indeed, both the accumulation of sgRNA3a in polysomes and the synthesis of movement protein 3a in in vitro systems suggest active functions of sgRNA3a during protein synthesis. Moreover, when copied in the BMV replicase in vitro reaction, the minus-strand RNA3 template generated the sgRNA3a product, likely by premature termination at the minus-strand oligo(U) tract. Deletion of the oligo(A) tract in BMV RNA3 inhibited synthesis of sgRNA3a during infection. We propose a model in which the synthesis of RNA3 is terminated prematurely near the sg promoter. The discovery of 5' sgRNA3a sheds new light on strategies viruses can use to separate replication from the translation functions of their genomic RNAs.     

Sequence, necessary for initiating RNA synthesis, in the 3'-noncoding region of the classical swine fever virus genome

Classical swine fever virus (CSFV) is the causative agent of swine fever, which represents an economically important disease in hogs. We previously made a prediction about the recognition sites of replication initiation of CSFV by using the information content method, and it was predicted that the 21 nucleotides located at 3' end of the CSFV genome 3'UTR were essential to CSFV replication. In this paper, we experimentally studied these 21 nucleotides by site-directed mutagenesis. It was found that the 3'UTRs with the 21 nucleotides had the function of initiating RNA synthesis, while the 3'UTRs without the 21 nucleotides did not. The 21 nucleotides alone, without the rest of 3'UTR, were able to initiate RNA synthesis, though with a slump. It was demonstrated that the 21 nucleotides were essential to the replication of CSFV genome. The other part of 3'UTR was also required for sufficient RNA synthesis. It is highly likely that the 21 nucleotides were the necessary site for the CSFV genome replication initiation, and that the elements required for sufficient RNA synthesis were in the other part of 3'UTR. It was assumed that the CSFV replicase bound to the site and initiated the replication of the CSFV genome. In the 21 nucleotides, it was found that the mutation of position 216 and destruction of the 3' terminus in the 3'UTR precluded initiation of RNA synthesis, that the mutation of position 212 did not affect the capacity for initiation of RNA synthesis but attenuated the synthesis of RNA. Among the four mutants of 3'UTR at position 219, three produced the 3'UTR without initiation of RNA synthesis, and the other one produced the 3'UTR with initiation of less RNA synthesis. Therefore, it could be concluded that T216 was the most important while T212 was the least important, and that G219 and C228 were also important for RNA synthesis. The normal base component within the 21 nucleotides was essential to sufficient RNA synthesis.     

Expanding the utility of heptamer-type sgRNA for TRUE gene silencing

tRNase Z(L)-utilizing efficacious gene silencing (TRUE gene silencing) is a novel technology for suppressing gene expression. TRUE gene silencing is based on a unique enzymatic property of mammalian tRNase Z(L), which is that it can cleave any target RNA at any desired site by recognizing a pre-tRNA-like or micro-pre-tRNA-like complex formed between the target RNA and artificial small guide RNA (sgRNA). sgRNA is divided into four groups, 5'-half-tRNA, RNA heptamer, hook RNA, and ～14-nt linear RNA. One of the final destinations of TRUE gene silencing is to generate cancer therapeutic sgRNAs, and from a pharmacological point of view, heptamer-type sgRNA appears to be the most appropriate for this purpose. In this paper, we present two strategies to expand the utility of heptamer-type sgRNA: one is about locked nucleic acid (LNA) modifications of heptamers and the other is about usage of double heptamers. We showed that RNA heptamers with LNA modifications can work as sgRNA in vitro and in vivo. We also demonstrated that two consecutively aligned heptamers can guide target RNA cleavage by human tRNase Z(L) as efficiently as a corresponding 14-nt sgRNA in vitro and that a double heptamer can work much better than a 14-nt sgRNA in vivo.     

快速构建多重sgRNA载体利用CRISPR/Cas9技术敲除拟南芥IAA2基因

IAA2(Indole Acetic Acid 2)是拟南芥Aux/IAA生长素响应基因大家族中的一员,目前还没有它的突变体的报道,阻碍了对其功能和作用机制的深入研究。在CRISPR/Cas9基因组编辑技术中,1个sgRNA只能靶向基因的1个位点,有时基因敲除的效率并不高。为了提高敲除效率,本文在Golden-Gate克隆技术的基础上,通过两轮PCR扩增,将每3个sgRNA串联到同1个入门载体中,再将入门载体与含Cas9表达框的目标载体LR反应,获得最终的表达载体。结果表明,设计的6个sgRNA有4个发挥了作用,产生了碱基插入突变和大片段缺失突变等多种可遗传的突变。与单个sgRNA相比,多重sgRNA的基因敲除效率高、种系突变多;与其他构建多重sgRNA载体的方法相比,本方法具有快速、高效等优点。本文所得到的5个突变体为后续的IAA2功能研究提供了良好的材料。