Structural insights into human co-transcriptional capping

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Molecular mechanisms of coronavirus RNA capping and methylation

The 5′-cap structures of eukaryotic m RNAs are important for RNA stability, pre-m RNA splicing,m RNA export, and protein translation. Many viruses have evolved mechanisms for generating their own cap structures with methylation at the N7 position of the capped guanine and the ribose 2′-Oposition of the first nucleotide, which help viral RNAs escape recognition by the host innate immune system. The RNA genomes of coronavirus were identified to have 5′-caps in the early1980 s. However, for decades the RNA capping mechanisms of coronaviruses remained unknown.Since 2003, the outbreak of severe acute respiratory syndrome coronavirus has drawn increased attention and stimulated numerous studies on the molecular virology of coronaviruses. Here, we review the current understanding of the mechanisms adopted by coronaviruses to produce the 5′-cap structure and methylation modification of viral genomic RNAs.     

The C‐terminal α–α superhelix of Pat is required for mRNA decapping in metazoa

Pat proteins regulate the transition of mRNAs from a state that is translationally active to one that is repressed, committing targeted mRNAs to degradation. Pat proteins contain a conserved N‐terminal sequence, a proline‐rich region, a Mid domain and a C‐terminal domain (Pat‐C). We show that Pat‐C is essential for the interaction with mRNA decapping factors (i.e. DCP2, EDC4 and LSm1–7), whereas the P‐rich region and Mid domain have distinct functions in modulating these interactions. DCP2 and EDC4 binding is enhanced by the P‐rich region and does not require LSm1–7. LSm1–7 binding is assisted by the Mid domain and is reduced by the P‐rich region. Structural analysis revealed that Pat‐C folds into an α–α superhelix, exposing conserved and basic residues on one side of the domain. This conserved and basic surface is required for RNA, DCP2, EDC4 and LSm1–7 binding. The multiplicity of interactions mediated by Pat‐C suggests that certain of these interactions are mutually exclusive and, therefore, that Pat proteins switch decapping partners allowing transitions between sequential steps in the mRNA decapping pathway.     

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.     

Functional characterization of the C-terminal domain of mouse capping enzyme

Mouse capping enzyme (Mce1) consists of two functional domains: the amino-terminal triphosphatase domain and the carboxyl-terminal guanylyltransferase (GTase) domain. The bifunctional Mce1 gene encodes 597 a.a. with a molecular weight approximately 68 kDa. Mce1 cDNA is located on chromosome 4A4 approximately 4A5 and is composed of 17 exons. To functionally characterize the C-terminus of Mce1, we generated four truncated proteins with 12, 30, 37, or 60 a.a. deletions from the C-terminus of either the wild type (Mce1) or the isolated GTase domain (211-597), respectively. Plasmid shuffling experiment with Saccharomyces cerevisiae GTase subunit gene CEG1 null mutant demonstrated that deletion mutants 211-567 and 211-585 were able to support cell viability in the presence of 5-fluoroorotic acid, whereas 211-537 and 211-560 were not. Consistent with the yeast genetic study, both 211-567 and 211-585 had significant GTase activity in vitro, while 211-537 and 211-560 that were only detected in the insoluble fraction in the bacterial expression system, were completely inactive. Overall, both in vivo and in vitro studies indicate that the functional domain of Mce1 is between a.a. 211 and 567, and the heptapeptide sequence between 561 and 567 may play an important role in the enzyme activity.     

Structural insights into viral RNA capping and plasma membrane targeting by Chikungunya virus nonstructural protein 1

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The Helicase-Like Domain of Plant Potexvirus Replicase Participates in Formation of RNA 5′ Cap Structure by Exhibiting RNA 5′-Triphosphatase Activity

Open reading frame 1 (ORF1) of potexviruses encodes a viral replicase comprising three functional domains: a capping enzyme at the N terminus, a putative helicase in the middle, and a polymerase at the C terminus. To verify the enzymatic activities associated with the putative helicase domain, the corresponding cDNA fragment from bamboo mosaic virus (BaMV) was cloned into vector pET32 and the protein was expressed in Escherichia coli and purified by metal affinity chromatography. An activity assay confirmed that the putative helicase domain has nucleoside triphosphatase activity. We found that it also possesses an RNA 5'-triphosphatase activity that specifically removes the gamma phosphate from the 5' end of RNA. Both enzymatic activities were abolished by the mutation of the nucleoside triphosphate-binding motif (GKS), suggesting that they have a common catalytic site. A typical m(7)GpppG cap structure was formed at the 5' end of the RNA substrate when the substrate was treated sequentially with the putative helicase domain and the N-terminal capping enzyme, indicating that the putative helicase domain is truly involved in the process of cap formation by exhibiting its RNA 5'-triphosphatase activity.     

Uncoupling of Protein and Ribonucleic Acid Synthesis by 5′,5′,5′-Trifluoroleucine in Salmonella typhimurium

The addition of 5',5',5'-trifluoroleucine (fluoroleucine) to leucine auxotrophs of Salmonella typhimurium permitted protein but not ribonucleic acid (RNA) synthesis to continue after leucine depletion. The uncoupling of the formation of these macromolecules by fluoroleucine was apparent if RNA and protein synthesis was measured either by the uptake of radioactive precursors or by direct chemical determinations. The analogue did not appear to be an inhibitor of RNA formation, since it was as effective as leucine in permitting RNA synthesis in a leucine auxotroph upon the addition of small amounts of chloramphenicol. In contrast to these data, fluoroleucine allowed continued protein and RNA formation in a leucine auxotroph of Escherichia coli strain W. In addition, contrary to the results obtained with S. typhimurium, the analogue replaced leucine for repression of the leucine bio-synthetic enzymes as well as the isoleucine-valine enzymes. We propose that these ambivalent effects of fluoroleucine on repression and RNA and protein synthesis in the two strains are due to differences in the ability of the analogue to attach to the various species of leucine transfer RNA.     

NMR solution structures of Runella slithyformis RNA 2′-phosphotransferase Tpt1 provide insights into NAD+ binding and specificity

Tpt1, an essential component of the fungal and plant tRNA splicing machinery, catalyzes transfer of an internal RNA 2′-PO₄ to NAD⁺ yielding RNA 2′-OH and ADP-ribose-1′,2′-cyclic phosphate products. Here, we report NMR structures of the Tpt1 ortholog from the bacterium Runella slithyformis (RslTpt1), as apoenzyme and bound to NAD⁺. RslTpt1 consists of N- and C-terminal lobes with substantial inter-lobe dynamics in the free and NAD⁺-bound states. ITC measurements of RslTpt1 binding to NAD⁺ (K_D ∼31 μM), ADP-ribose (∼96 μM) and ADP (∼123 μM) indicate that substrate affinity is determined primarily by the ADP moiety; no binding of NMN or nicotinamide is observed by ITC. NAD⁺-induced chemical shift perturbations (CSPs) localize exclusively to the RslTpt1 C-lobe. NADP⁺, which contains an adenylate 2′-PO₄ (mimicking the substrate RNA 2′-PO₄), binds with lower affinity (K_D ∼1 mM) and elicits only N-lobe CSPs. The RslTpt1·NAD⁺ binary complex reveals C-lobe contacts to adenosine ribose hydroxyls (His99, Thr101), the adenine nucleobase (Asn105, Asp112, Gly113, Met117) and the nicotinamide riboside (Ser125, Gln126, Asn163, Val165), several of which are essential for RslTpt1 activity in vivo. Proximity of the NAD⁺ β-phosphate to ribose-C1″ suggests that it may stabilize an oxocarbenium transition-state during the first step of the Tpt1-catalyzed reaction.     

Effects of Adenosine 3′,5′-Monophosphate and Adenosine 5′-Monophosphate on Glycogen Degradation and Synthesis in Dictyostelium discoideum

Data are presented demonstrating that the presence in vivo of adenosine 3',5'-monophosphate (3',5'-AMP) causes a rapid depletion of glycogen storage material in the cellular slime mold. The effect of adenosine 5'-monophosphate (5'-AMP) is twofold, stimulating both glycogen degradation and synthesis. In pseudoplasmodia, cell-free extracts appear to contain at least two species of glycogen phosphorylase, one of which is severely inhibited by glucose-1-phosphate and another which is only partially inhibited by this hexose-phosphate. In some cases, 5'-AMP partially overcomes the inhibition by glucose-1-phosphate. Data presented here also indicate the existence of two forms of glycogen synthetase, the total activity of which does not change during 10 hr of differentiation from aggregation to culmination. During this period there is a quantitative conversion of glucose-6-phosphate-independent enzyme activity to glucose-6-phosphate-dependent activity. It is suggested that one effect of 3',5'-AMP is closely related to enzymatic processes involved in the rapid conversion of glycogen to cell wall material and other end products accumulating during sorocarp construction.     

Aminonucleosides and their derivatives. IVI Synthesis of the 3′-amino-3′-deoxynucleoside 5′-phosphates

A new procedure has been developed for the synthesis of 3′-amino-3′-deoxyribonucleosides of adenine, cytosine and uracil by condensing the trimethylsilylated bases with peracylated 3-azido-3-deoxyribose derivative. The azido group could subsequently be reduced to amino. The 5′-phosphates of these nucleosides have been prepared and the analogues have been tested for their ability to stimulate the ribosome-catalyzed reaction of 3′(2′)-O-(N-formylmethionyl)adenosine 5′-phosphate with phenylalanyl-tRNA.     

Functional stabilization of an RNA recognition motif by a noncanonical N-terminal expansion

RNA recognition motifs (RRMs) constitute versatile macromolecular interaction platforms. They are found in many components of spliceosomes, in which they mediate RNA and protein interactions by diverse molecular strategies. The human U11/U12-65K protein of the minor spliceosome employs a C-terminal RRM to bind hairpin III of the U12 small nuclear RNA (snRNA). This interaction comprises one side of a molecular bridge between the U11 and U12 small nuclear ribonucleoprotein particles (snRNPs) and is reminiscent of the binding of the N-terminal RRMs in the major spliceosomal U1A and U2B″ proteins to hairpins in their cognate snRNAs. Here we show by mutagenesis and electrophoretic mobility shift assays that the β-sheet surface and a neighboring loop of 65K C-terminal RRM are involved in RNA binding, as previously seen in canonical RRMs like the N-terminal RRMs of the U1A and U2B″ proteins. However, unlike U1A and U2B″, some 30 residues N-terminal of the 65K C-terminal RRM core are additionally required for stable U12 snRNA binding. The crystal structure of the expanded 65K C-terminal RRM revealed that the N-terminal tail adopts an α-helical conformation and wraps around the protein toward the face opposite the RNA-binding platform. Point mutations in this part of the protein had only minor effects on RNA affinity. Removal of the N-terminal extension significantly decreased the thermal stability of the 65K C-terminal RRM. These results demonstrate that the 65K C-terminal RRM is augmented by an N-terminal element that confers stability to the domain, and thereby facilitates stable RNA binding.     

3′-Fluoro-3′-deoxyribonucleoside 5′-triphosphates: Synthesis and use as terminators of RNA biosynthesis

3′-Fluoro-3′-deoxy-uridine, -cytidine, -adenosine and -guanosine have been synthesized by glycosylation of the corresponding silylated bases with 1-O-acetyl-2,5-di-O-benzoyl-3-fluoro-3-deoxy-D-ribofuranose in the presence of Friedel-Crafts catalysts and were converted to the 5′- triphosphates, NTP(3′-F). It was shown that NTP(3′-F) are terminators of RNA synthesis catalyzed by DNA-dependent RNA polymerase from E. coli and may thus serve as tools for DNA sequencing.