Universal and strain specific structure features of segment 8 genomic RNA of influenza A virus—application of 4-thiouridine photocrosslinking

RNA structure in the influenza A virus (IAV) has been the focus of several studies that have shown connections between conserved secondary structure motifs and their biological function in the virus replication cycle. Questions have arisen on how to best recognize and understand the pandemic properties of IAV strains from an RNA perspective, but determination of the RNA secondary structure has been challenging. Herein, we used chemical mapping to determine the secondary structure of segment 8 viral RNA (vRNA) of the pandemic A/California/04/2009 (H1N1) strain of IAV. Additionally, this long, naturally occurring RNA served as a model to evaluate RNA mapping with 4-thiouridine (4sU) crosslinking. We explored 4-thiouridine as a probe of nucleotides in close proximity, through its incorporation into newly transcribed RNA and subsequent photoactivation. RNA secondary structural features both universal to type A strains and unique to the A/California/04/2009 (H1N1) strain were recognized. 4sU mapping confirmed and facilitated RNA structure prediction, according to several rules: 4sU photocross-linking forms efficiently in the double-stranded region of RNA with some flexibility, in the ends of helices, and across bulges and loops when their structural mobility is permitted. This method highlighted three-dimensional properties of segment 8 vRNA secondary structure motifs and allowed to propose several long-range three-dimensional interactions. 4sU mapping combined with chemical mapping and bioinformatic analysis could be used to enhance the RNA structure determination as well as recognition of target regions for antisense strategies or viral RNA detection.     

Recognition of 3′ nucleotide context and stop codon readthrough are determined during mRNA translation elongation

The nucleotide context surrounding stop codons significantly affects the efficiency of translation termination. In eukaryotes, various 3′ contexts that are unfavorable for translation termination have been described; however, the exact molecular mechanism that mediates their effects remains unknown. In this study, we used a reconstituted mammalian translation system to examine the efficiency of stop codons in different contexts, including several previously described weak 3′ stop codon contexts. We developed an approach to estimate the level of stop codon readthrough in the absence of eukaryotic release factors (eRFs). In this system, the stop codon is recognized by the suppressor or near-cognate tRNAs. We observed that in the absence of eRFs, readthrough occurs in a 3′ nucleotide context-dependent manner, and the main factors determining readthrough efficiency were the type of stop codon and the sequence of the 3′ nucleotides. Moreover, the efficiency of translation termination in weak 3′ contexts was almost equal to that in the tested standard context. Therefore, the ability of eRFs to recognize stop codons and induce peptide release is not affected by mRNA context. We propose that ribosomes or other participants of the elongation cycle can independently recognize certain contexts and increase the readthrough of stop codons. Thus, the efficiency of translation termination is regulated by the 3′ nucleotide context following the stop codon and depends on the concentrations of eRFs and suppressor/near-cognate tRNAs.     

Identification and characterization of a short 2′–3′ bond-forming ribozyme

A large number of natural and artificial ribozymes have been isolated since the demonstration of the catalytic potential of RNA, with the majority of these catalyzing phosphate hydrolysis or transesterification reactions. Here, we describe and characterize an extremely short ribozyme that catalyzes the positionally specific transesterification that produces a 2′–3′ phosphodiester bond between itself and a branch substrate provided in trans, cleaving itself internally in the process. Although this ribozyme was originally derived from constructs based on snRNAs, its minimal catalytic motif contains essentially no snRNA sequence and the reaction it catalyzes is not directly related to either step of pre-mRNA splicing. Our data have implications for the intrinsic reactivity of the large amount of RNA sequence space known to be transcribed in nature and for the validity and utility of the use of protein-free systems to study pre-mRNA splicing.     

Importance of the leader region of mRNA for translation initiation of ColE2 Rep protein

Translation initiation of mRNA encoding the Rep protein of the ColE2 plasmid required for initiation of plasmid DNA replication is fairly efficient in Escherichia coli cells despite the absence of a canonical Shine-Dalgarno sequence. To define sequences and structural elements responsible for translation efficiency of the Rep mRNA, a series of rep-lacZalpha translational fusions bearing various mutations in the region encoding the leader region of the Rep mRNA was generated and tested for the translation activity by measuring the beta-galactosidase activity. We showed that the region rich in A and U between the stem-loop II structure and GA cluster sequence, formation of the stem-loop II structure, but not its sequence, and the region between the GA cluster sequence and initiation codon are important along with the GA cluster sequence for efficient translation of the Rep protein. The existence of these important regions in the leader region of the Rep mRNA may explain the mechanism of inhibition of the Rep protein translation by an antisense RNA (RNAI), which is complementary to the leader region.     

Capturing the Mechanism Underlying TOP mRNA Binding to LARP1

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The RNA-Binding Protein Rasputin/G3BP Enhances the Stability and Translation of Its Target mRNAs

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Only a subset of the PAB1‐mRNP proteome is present in mRNA translation complexes

We have previously identified 55 nonribosomal proteins in PAB1‐mRNP complexes in Saccharomyces cerevisiae using mass spectrometric analysis. Because one of the inherent limitations of mass spectrometry is that it does not inform as to the size or type of complexes in which the proteins are present, we consequently used analytical ultracentrifugation with fluorescent detection system (AU‐FDS) to determine which proteins are present in the 77S monosomal translation complex that contains minimally the closed‐loop structure components (eIF4E, eIF4G, and PAB1), mRNA, and the 40S and 60S ribosomes. We assayed by AU‐FDS analysis 33 additional PAB1‐mRNP factors but found that only five of these proteins were present in the 77S translation complex: eRF1, SLF1, SSD1, PUB1, and SBP1. eRF1 is involved in translation termination, SBP1 is a translational repressor, and SLF1, SSD1, and PUB1 are known mRNA binding proteins. Many of the known P body/stress granule proteins that associate with the PAB1‐mRNP were not present in the 77S translation complex, implying that P body/stress granules result from significant protein additions after translational cessation. These data inform that AU‐FDS can clarify protein complex identification that remains undetermined after typical immunoprecipitation and mass spectrometric analyses.     

A small RNA activates CFA synthase by isoform‐specific mRNA stabilization

Small RNAs use a diversity of well‐characterized mechanisms to repress mRNAs, but how they activate gene expression at the mRNA level remains not well understood. The predominant activation mechanism of Hfq‐associated small RNAs has been translational control whereby base pairing with the target prevents the formation of an intrinsic inhibitory structure in the mRNA and promotes translation initiation. Here, we report a translation‐independent mechanism whereby the small RNA RydC selectively activates the longer of two isoforms of cfa mRNA (encoding cyclopropane fatty acid synthase) in Salmonella enterica. Target activation is achieved through seed pairing of the pseudoknot‐exposed, conserved 5′ end of RydC to an upstream region of the cfa mRNA. The seed pairing stabilizes the messenger, likely by interfering directly with RNase E‐mediated decay in the 5′ untranslated region. Intriguingly, this mechanism is generic such that the activation is equally achieved by seed pairing of unrelated small RNAs, suggesting that this mechanism may be utilized in the design of RNA‐controlled synthetic circuits. Physiologically, RydC is the first small RNA known to regulate membrane stability.     

Mouse Ifit1b is a cap1-RNA–binding protein that inhibits mouse coronavirus translation and is regulated by complexing with Ifit1c

Knockout mouse models have been extensively used to study the antiviral activity of IFIT (interferon-induced protein with tetratricopeptide repeats). Human IFIT1 binds to cap0 (m7GpppN) RNA, which lacks methylation on the first and second cap-proximal nucleotides (cap1, m7GpppNm, and cap2, m7GpppNmNm, respectively). These modifications are signatures of “self” in higher eukaryotes, whereas unmodified cap0-RNA is recognized as foreign and, therefore, potentially harmful to the host cell. IFIT1 inhibits translation at the initiation stage by competing with the cap-binding initiation factor complex, eIF4F, restricting infection by certain viruses that possess “nonself” cap0-mRNAs. However, in mice and other rodents, the IFIT1 orthologue has been lost, and the closely related Ifit1b has been duplicated twice, yielding three paralogues: Ifit1, Ifit1b, and Ifit1c. Although murine Ifit1 is similar to human IFIT1 in its cap0-RNA–binding selectivity, the roles of Ifit1b and Ifit1c are unknown. Here, we found that Ifit1b preferentially binds to cap1-RNA, whereas binding is much weaker to cap0- and cap2-RNA. In murine cells, we show that Ifit1b can modulate host translation and restrict WT mouse coronavirus infection. We found that Ifit1c acts as a stimulatory cofactor for both Ifit1 and Ifit1b, promoting their translation inhibition. In this way, Ifit1c acts in an analogous fashion to human IFIT3, which is a cofactor to human IFIT1. This work clarifies similarities and differences between the human and murine IFIT families to facilitate better design and interpretation of mouse models of human infection and sheds light on the evolutionary plasticity of the IFIT family.     

A 38 nt region and its flanking sequences within gag of Friend murine leukemia virus are crucial for splicing at the correct 5′ and 3′ splice sites

The genome of the Friend murine leukemia virus (Fr‐MLV) contains a 5′ splice site (5′ss) located at 205 nt and a 3′ss located at 5489 nt. In our previous studies, it was shown that if the HindIII–BglII (879–1904 bp) fragment within gag is deleted from the proA8m1 vector, which carries the entire Fr‐MLV sequence, then cryptic splicing of env‐mRNA occurs. Here, attempts were made to identify the genomic segment(s) in this region that is/are essential to correct splicing. First, vectors with a serially truncated HindIII–BglII fragment were constructed. The vector, in which a 38 bp fragment (1612–1649 bp) is deleted or reversed in proA8m1, only produced splice variants. It was found that a 38 nt region within gag contains important elements that positively regulate splicing at the correct splice sites. Further analyses of a series of vectors carrying the 38 bp fragment and its flanking sequences showed that a region (1183–1611 nt) upstream of the 38 nt fragment also contains sequences that positively or negatively influence splicing at the correct splice sites. The SphI–NdeI (5140–5400 bp) fragment just upstream of the 3′ss was deleted from vectors that carried the 38 bp fragment and its flanking sequences, which yielded correctly spliced mRNA; interestingly, these deleted vectors showed cryptic splicing. These findings suggest that the 5140–5400 nt region located just upstream of the 3′ss is required for the splicing function of the 38 nt fragment and its flanking sequences.