dsRNA介导的RNA干扰

在多种生物中 ,外源或内源性的双链ＲＮＡ(ｄｏｕｂｌｅ ｓｔｒａｎｄｅｄＲＮＡ ,ｄｓＲＮＡ)导入细胞中 ,与ｄｓＲＮＡ同源的ｍＲＮＡ则受到降解 ,因而其相应的基因受到抑制。这种转录后基因沉默 (ｐｏｓｔ ｔｒａｎｓｃｒｉｐｔｉｏｎａｌｇｅｎｅｓｉｌｅｎｃｉｎｇ ,ＰＴＧＳ)机制首先在线虫 (Ｃ .ｅｌｅｇａｎｓ)中得以证实。由于这是一种在ＲＮＡ水平的基因表达抑制 ,故也称为ＲＮＡ干扰 (ＲＮＡｉｎｔｅｒｆｅｒ ｅｎｃｅ) ,简称ＲＮＡｉ[1] 。随后发现 ,在各种生物 ,如果蝇[2 ] 、拟南芥菜[3 ] 、及小鼠[4] 等均存在ｄｓＲＮＡ介导…     

Tentative identification of RNA-dependent RNA polymerases of dsRNA viruses and their relationship to positive strand RNA viral polymerases

Amino acid sequence stretches similar to the four most conserved segments of positive strand RNA viral RNA-dependent RNA polymerases have been identified in proteins of four dsRNA viruses belonging to three families, i.e. P2 protein of bacteriophage phi 6 (Cystoviridae), RNA 2 product of infectious bursa disease virus (Birnaviridae), lambda 3 protein of reovirus, and VP1 of bluetongue virus (Reoviridae). High statistical significance of the observed similarity was demonstrated, allowing identification of these proteins as likely candidates for RNA-dependent RNA polymerases. Based on these observations, and on the previously reported sequence similarity between the RNA polymerases of a yeast dsRNA virus and those of positive strand RNA viruses, a possible evolutionary relationship between the two virus classes is discussed.     

A mutant viral RNA promoter with an altered conformation retains efficient recognition by a viral RNA replicase through a solution-exposed adenine.

Brome mosaic virus (BMV) genomic minus-strand RNA synthesis requires an RNA motif named stem-loop C (SLC). An NMR-derived solution structure of SLC was reported by Kim et al. (Nature Struc Biol, 2000, 7:415-423) to contain three replicase-recognition elements, the most important of which is a stable stem with a terminal trinucleotide loop, 5'AUA3'. The 5'-most adenine of the triloop is rigidly fixed to the stem helix by interactions that require the 3'-most adenine, which is called a clamped adenine motif. However, a change of the 3' adenine to guanine (5'AUG3') unexpectedly directed RNA synthesis at 130% of wild type (Kim et al., Nature Struc Biol, 2000, 7:415-423). To understand how RNA with the AUG mutation maintains interaction with the BMV replicase, we used NMR and other biophysical techniques to elucidate the solution conformation of a 13-nt RNA containing the AUG triloop, called S-AUG. We found that S-AUG has a drastically different loop conformation in comparison to the wild type, as evidenced by an unusual C x G loop-closing base pair. Despite the conformational change, S-AUG maintains a solution-exposed adenine similar to the clamped adenine motif found in the wild type. Biochemical studies of the 5'AUG3' loop with various substitutions in the context of the whole SLC construct confirm that the clamped adenine motif exists in S-AUG remains a primary structural feature required for RNA synthesis by the BMV replicase.     

Members of the heterogeneous nuclear ribonucleoprotein H family activate splicing of an HIV-1 splicing substrate by promoting formation of ATP-dependent spliceosomal complexes

In this study we analyzed members of the heterogeneous nuclear ribonucleoprotein (hnRNP) H protein family to determine their RNA binding specificities and roles in splicing regulation. Our data indicate that hnRNPs H, H', F, 2H9, and GRSF-1 bind the consensus motif DGGGD (where D is U, G, or A) and aggregate in a multimeric complex. We analyzed the role of these proteins in the splicing of a substrate derived from the HIV-1 tat gene and have shown that hnRNP H family members are required for efficient splicing of this substrate. The hnRNP H protein family members activated splicing of the viral substrate by promoting the formation of ATP-dependent spliceosomal complexes. Mutational analysis of six consensus motifs present within the intron of the substrate indicated that only one of these motifs acts as an intronic splicing enhancer.     

Regulation of alternative RNA splicing by exon definition and exon sequences in viral and mammalian gene expression

Intron removal from a pre-mRNA by RNA splicing was once thought to be controlled mainly by intron splicing signals. However, viral and other eukaryotic RNA exon sequences have recently been found to regulate RNA splicing, polyadenylation, export, and nonsense-mediated RNA decay in addition to their coding function. Regulation of alternative RNA splicing by exon sequences is largely attributable to the presence of two majorcis-acting elements in the regulated exons, the exonic splicing enhancer (ESE) and the suppressor or silencer (ESS). Two types of ESEs have been verified from more than 50 genes or exons: purine-rich ESEs, which are the more common, and non-purine-rich ESEs. In contrast, the sequences of ESSs identified in approximately 20 genes or exons are highly diverse and show little similarity to each other. Through interactions with cellular splicing factors, an ESE or ESS determines whether or not a regulated splice site, usually an upstream 3 splice site, will be used for RNA splicing. However, how these elements function precisely in selecting a regulated splice site is only partially understood. The balance between positive and negative regulation of splice site selection likely depends on thecis-element's identity and changes in cellular splicing factors under physiological or pathological conditions.     

Completion of RNA synthesis by viral RNA replicases

How the 5′-terminus of the template affects RNA synthesis by viral RNA replicases is poorly understood. Using short DNA, RNA and RNA–DNA chimeric templates that can direct synthesis of replicase products, we found that DNA templates tend to direct the synthesis of RNA products that are shorter by 1 nt in comparison to RNA templates. Template-length RNA synthesis was also affected by the concentration of nucleoside triphosphates, the identity of the bases at specific positions close to the 5′-terminus and the C2′-hydroxyl of a ribose at the third nucleotide from the 5′-terminal nucleotide. Similar requirements are observed with two bromoviral replicases, but not with a recombinant RNA-dependent RNA polymerase. These results begin to define the interactions needed for the viral replicase to complete synthesis of viral RNA.     

The serine protease domain of hepatitis C viral NS3 activates RNA helicase activity by promoting the binding of RNA substrate

Nonstructural (NS) protein 3 is a DEXH/D-box motor protein that is an essential component of the hepatitis C viral (HCV) replicative complex. The full-length NS3 protein contains two functional modules, both of which are essential in the life cycle of HCV: a serine protease domain at the N terminus and an ATPase/helicase domain (NS3hel) at the C terminus. Truncated NS3hel constructs have been studied extensively; the ATPase, nucleic acid binding, and helicase activities have been examined and NS3hel has been used as a target in the development of antivirals. However, a comprehensive comparison of NS3 and NS3hel activities has not been performed, so it remains unclear whether the protease domain plays a vital role in NS3 helicase function. Given that many DEXH/D-box proteins are activated upon interaction with cofactor proteins, it is important to establish if the protease domain acts as the cofactor for stimulating NS3 helicase function. Here we show that the protease domain greatly enhances both the direct and functional binding of RNA to NS3. Whereas electrostatics plays an important role in this process, there is a specific allosteric contribution from the interaction interface between NS3hel and the protease domain. Most importantly, we establish that the protease domain is required for RNA unwinding by NS3. Our results suggest that, in addition to its role in cleavage of host and viral proteins, the NS3 protease domain is essential for the process of viral RNA replication and, given its electrostatic contribution to RNA binding, it may also assist in packaging of the viral RNA.     

Molecular polymorphism of viral dsRNA of yeast Saccharomyces paradoxus

An analysis of 53 strains of yeast Saccharomyces paradoxus (YSP) of different geographic origins enabled us, for the first time, to find viral double-stranded RNA (L and M fractions) in YSP and to study natural polymorphism. As in the cultured Scerevisiae, the size of L dsRNA was constant (4.5 kb). The size of minor M dsRNA varied from 1.5 to 2.4 k.b. In YSP, we determined 7 types of M dsRNA (M1-M7), which were not connected with the source of isolation or geographic origin of the host strains.