Probing RNA in vivo with methylation guide small nucleolar RNAs

Most box C/D small nucleolar RNAs (snoRNAs) direct the formation of 2'-O-methylated nucleotides in ribosomal RNA and, apparently, other RNAs present in the nucleolar complex. Sites to be modified are selected by a long (>10-nt) antisense guide sequence in the snoRNA and a distance measurement from a box D or D' element that follows the snoRNA guide sequence. Modification of the substrate occurs in the region of complementarity, at a position five nucleotides upstream from box D/D'. Methylation can be targeted to novel sites by expressing a snoRNA with a new guide sequence. In some cases methylation impairs the growth rate of the cell, indicating that a functionally important nucleotide has been altered. With a view to harnessing snoRNA-directed methylation for functional mapping, we have developed a method for constructing libraries of snoRNA genes that, in principle, can introduce methylation point mutations into any rRNA segment of interest. The strategy and procedures are described here, and preliminary results are presented that show the feasibility of using this technology to probe a region of the yeast large subunit rRNA that includes the core of the peptidyltransferase center.     

SnoRNA-guided ribose methylation of rRNA: structural features of the guide RNA duplex influencing the extent of the reaction.

Eukaryotic rRNAs contain a large number of ribose-methylated nucleotides of elusive function which are confined to the universally conserved rRNA domains. Ribose methylation of these nucleotides is directed by a large family of small trans -acting guide RNAs, called box C/D antisense snoRNAs. Each snoRNA targets precisely one of the nucleotides to be methylated within the pre-rRNA sequence, through transient formation of a 10-21 bp regular RNA duplex around the modification site. In this study we have analyzed how different features of the double-stranded RNA guide structure affect the extent of site-specific ribose methylation, by co-expressing an appropriate RNA substrate and its cognate tailored snoRNA guide in transfected mouse cells. We show that an increased GC content of the duplex can make up for the inhibitory effects of a helix truncation or for the presence of helix irregularities such as a mismatched pair or a bulge nucleotide. However, some helix irregularities dramatically inhibit the reaction and are not offset by further stabilization of the duplex. Overall, the RNA duplex tolerates a much larger degree of irregularity than anticipated, even in the immediate vicinity of the methylation site, which offers new prospects in the search for additional snoRNA guides. Accordingly, a few snoRNA-like sequences of uncertain status detected in the yeast Saccharomyces cerevisiae genome now appear as likely bona fide ribose methylation guides.     

Location of 2(')-O-methyl nucleotides in 26S rRNA and methylation guide snoRNAs in Caenorhabditis elegans

Many nucleotides in rRNAs are modified. We devised a method to locate 2(')-O-methyl nucleotide residues using a conventional DNA sequencer. We found 38 2(')-O-methyl nucleotides in the 26S rRNA of Caenorhabditis elegans using this method. Fourteen of the 38 residues are conserved in both human and yeast rRNAs and 14 residues are conserved in either human or yeast rRNA. The remaining 10 nucleotides are uniquely methylated in C. elegans 26S rRNA. We searched the C. elegans genomic sequence for small nucleolar RNAs (snoRNAs), which guide the methylation of ribose residues, and predicted 18 snoRNA sequences that are expected to guide the methylation of some of these nucleotide residues.     

Identification of a new ribose methylation in the 18S rRNA of S. cerevisiae

Methylation of ribose sugars at the 2′-OH group is one of the major chemical modifications in rRNA, and is catalyzed by snoRNA directed C/D box snoRNPs. Previous biochemical and computational analyses of the C/D box snoRNAs have identified and mapped a large number of 2′-OH ribose methylations in rRNAs. In the present study, we systematically analyzed ribose methylations of 18S rRNA in Saccharomyces cerevisiae, using mung bean nuclease protection assay and RP-HPLC. Unexpectedly, we identified a hitherto unknown ribose methylation at position G562 in the helix 18 of 5′ central domain of yeast 18S rRNA. Furthermore, we identified snR40 as being responsible to guide snoRNP complex to catalyze G562 ribose methylation, which makes it only second snoRNA known so far to target three ribose methylation sites: Gm562, Gm1271 in 18S rRNA, and Um898 in 25S rRNA. Our sequence and mutational analysis of snR40 revealed that snR40 uses the same D′ box and methylation guide sequence for both Gm562 and Gm1271 methylation. With the identification of Gm562 and its corresponding snoRNA, complete set of ribose methylations of 18S rRNA and their corresponding snoRNAs have finally been established opening great prospects to understand the physiological function of these modifications.     

Sequence and structural elements of methylation guide snoRNAs essential for site-specific ribose methylation of pre-rRNA.

Site-specific 2'-O-ribose methylation of eukaryotic rRNAs is guided by small nucleolar RNAs (snoRNAs). The methylation guide snoRNAs carry long perfect complementaries to rRNAs. These antisense elements are located either in the 5' half or in the 3' end region of the snoRNA, and are followed by the conserved D' or D box motifs, respectively. An uninterrupted helix formed between the rRNA and the antisense element of the snoRNA, in conjunction with the adjacent D' or D box, constitute the recognition signal for the putative methyltransferase. Here, we have identified an additional essential box element common to methylation guide snoRNAs, termed the C' box. We show that the C' box functions in concert with the D' box and plays a crucial role in the methyltransfer reaction directed by the upstream antisense element and the D' box. We also show that an internal fragment of U24 methylation guide snoRNA, encompassing the upstream antisense element and the D' and C' box motifs, can support the site-specific methylation of rRNA. This strongly suggests that the C box of methylation guide snoRNAs plays an essential role in the methyltransfer reaction guided by the 3'-terminal antisense element and the D box of the snoRNA.     

A snoRNA that guides the two most conserved pseudouridine modifications within rRNA confers a growth advantage in yeast

Ribosomal RNAs contain a number of modified nucleotides. The most abundant nucleotide modifications found within rRNAs fall into two types: 2'-O-ribose methylations and pseudouridylations. In eukaryotes, small nucleolar guide RNAs, the snoRNAs that are the RNA components of the snoRNPs, specify the position of these modifications. The 2'-O-ribose methylations and pseudouridylations are guided by the box C/D and box H/ACA snoRNAs, respectively. The role of these modifications in rRNA remains poorly understood as no clear phenotype has yet been assigned to the absence of specific 2'-O-ribose methylations or pseudouridylations. Only very recently, a slight translation defect and perturbation of polysome profiles was reported in yeast for the absence of the Psi at position 2919 within the LSU rRNA. Here we report the identification and characterization in yeast of a novel intronic H/ACA snoRNA that we called snR191 and that guides pseudouridylation at positions 2258 and 2260 in the LSU rRNA. Most interestingly, these two modified bases are the most conserved pseudouridines from bacteria to human in rRNA. The corresponding human snoRNA is hU19. We show here that, in yeast, the presence of this snoRNA, and hence, most likely, of the conserved pseudouridines it specifies, is not essential for viability but provides a growth advantage to the cell.     

AtNUFIP, an essential protein for plant development, reveals the impact of snoRNA gene organisation on the assembly of snoRNPs and rRNA methylation in Arabidopsis thaliana

In all eukaryotes, C/D small nucleolar ribonucleoproteins (C/D snoRNPs) are essential for methylation and processing of ribosomal RNAs. They consist of a box C/D small nucleolar RNA (C/D snoRNA) associated with four highly conserved nucleolar proteins. Recent data in HeLa cells and yeast have revealed that assembly of these snoRNPs is directed by NUFIP protein and other auxiliary factors. Nevertheless, the precise function and biological importance of NUFIP and the other assembly factors remains unknown. In plants, few studies have focused on RNA methylation and snoRNP biogenesis. Here, we identify and characterise the AtNUFIP gene that directs assembly of C/D snoRNP. To elucidate the function of AtNUFIP in planta, we characterized atnufip mutants. These mutants are viable but have severe developmental phenotypes. Northern blot analysis of snoRNA accumulation in atnufip mutants revealed a specific degradation of C/D snoRNAs and this situation is correlated with a reduction in rRNA methylation. Remarkably, the impact of AtNUFIP depends on the structure of snoRNA genes: it is essential for the accumulation of those C/D snoRNAs encoded by polycistronic genes, but not by monocistronic or tsnoRNA genes. We propose that AtNUFIP controls the kinetics of C/D snoRNP assembly on nascent precursors to overcome snoRNA degradation of aberrant RNPs. Finally, we show that AtNUFIP has broader RNP targets, controlling the accumulation of scaRNAs that direct methylation of spliceosomal snRNA in Cajal bodies.     

Structure and biogenesis of small nucleolar RNAs acting as guides for ribosomal RNA modification.

Maturation of pre-ribosomal RNA (pre-rRNA) in eukaryotic cells takes place in the nucleolus and involves a large number of cleavage events, which frequently follow alternative pathways. In addition, rRNAs are extensively modified, with the methylation of the 2'-hydroxyl group of sugar residues and conversion of uridines to pseudouridines being the most frequent modifications. Both cleavage and modification reactions of pre-rRNAs are assisted by a variety of small nucleolar RNAs (snoRNAs), which function in the form of ribonucleoprotein particles (snoRNPs). The majority of snoRNAs acts as guides directing site-specific 2'-O-ribose methylation or pseudouridine formation. Over one hundred RNAs of this type have been identified to date in vertebrates and the yeast Saccharomyces cerevisiae. This number is readily explained by the findings that one snoRNA acts as a guide usually for one or at most two modifications, and human rRNAs contain 91 pseudouridines and 106 2'-O-methyl residues. In this article we review information about the biogenesis, structure and function of guide snoRNAs.     

Solution structure of an rRNA substrate bound to the pseudouridylation pocket of a box H/ACA snoRNA

Base pairing between the RNA components of box H/ACA small nucleolar ribonucleoproteins (snoRNPs) and sequences in other eukaryotic RNAs target specific uridines for pseudouridylation. An RNA called HJ1 has been developed that interacts with the rRNA sequence targeted by the 5' pseudouridylation pocket of human U65 snoRNA the same way as intact U65 snoRNA. Sequences on both strands of the analog of the U65 snoRNP pseudouridylation pocket in HJ1 pair with its substrate sequence, and the resulting complex, called HJ3, is strongly stabilized by Mg(2+). The solution structure of HJ3 reveals an Omega-shaped RNA interaction motif that has not previously been described, which is likely to be common to all box H/ACA snoRNP-substrate complexes. The topology of the complex explains why the access of substrate sequences to snoRNPs is facile and how uridine selection may occur when these complexes form.     

Identification of a novel box C/D snoRNA from mouse nucleolar cDNA library

By construction and screen of mouse nucleolar cDNA library, a novel mammalian small nucleolar RNAs (snoRNA) was identified. The novel snoRNA, 70 nt in length, displays structural features typical of C/D box snoRNA family. The snoRNA possesses an 11-nt-long rRNA antisense element and is predicted to guide the 2'-O-methylation of mouse 28S rRNA at G4043, a site unknown so far to be modified in vertebrates. The comparison of functional element of snoRNA guides among eukaryotes reveals that the novel snoRNA is a mammalian counterpart of yeast snR38 despite highly divergent sequence between them. Mouse and human snR38 and other cognates in distant vertebrates were positively detected with slight length variability. As expected, the rRNA ribose-methylation site predicted by mouse snR38 was precisely mapped by specific-primer extension assay. Furthermore, our analyses show that mouse and human snR38 gene have multiple variants and are nested in the introns of different host genes with unknown function. Thus, snR38 is a phylogenetically conserved methylation guide but exhibits different genomic organization in eukaryotes.     

A new method for detecting sites of 2'-O-methylation in RNA molecules.

2'-O-methylation of eukaryotic ribosomal RNAs occurs in the cell nucleoli. At least 100 modification sites that are highly conserved among vertebrate rRNAs have been mapped. However, in part because of the insensitivity of current approaches, there are 2'-O-methylated sites that remain unidentified. We have developed an extremely sensitive method for detecting 2'-O-methylated residues that are predicted within a long RNA molecule. Utilizing RNase H cleavage directed by a 2'-O-methyl RNA-DNA chimeric oligonucleotide, this method has allowed identification of two methylated nucleotides, G1448 in Xenopus 18S rRNA and A394 in Xenopus 28S rRNA. The latter (A394 in 28S) had not been detected before. We have confirmed that the methylation at G1448 in 18S is dependent upon Xenopus U25 snoRNA and have demonstrated that the methylation at A394 in 28S requires U26 snoRNA. One advantage of this technique is that it can examine specific rRNA and precursor molecules. We show that about 30% of the 40S pre-rRNA has been methylated at these two sites and their methylation is complete at the stage of 20S (immediate precursor to 18S) and 32S (immediate precursor to 28S). We also show that methylation at these two sites is not essential for rRNA transport from the nucleus to the cytoplasm.     

Conserved boxes C and D are essential nucleolar localization elements of U14 and U8 snoRNAs.

Sequences necessary for nucleolar targeting were identified in Box C/D small nucleolar RNAs (snoRNAs) by fluorescence microscopy. Nucleolar preparations were examined after injecting fluorescein-labelled wild-type and mutated U14 or U8 snoRNA into Xenopus oocyte nuclei. Regions in U14 snoRNA that are complementary to 18S rRNA and necessary for rRNA processing and methylation are not required for nucleolar localization. Truncated U14 molecules containing Boxes C and D with or without the terminal stem localized efficiently. Nucleolar localization was abolished upon mutating just one or two nucleotides within Boxes C and D. Moreover, the spatial position of Boxes C or D in the molecule is essential. Mutations in Box C/D of U8 snoRNA also impaired nucleolar localization, suggesting the general importance of Boxes C and D as nucleolar localization sequences for Box C/D snoRNAs. U14 snoRNA is shown to be required for 18S rRNA production in vertebrates.     

水稻D1snoRNA及其基因的鉴定和功能分析

测定和比较了籼稻（ＯｒｙｚａｓａｔｉｖａＬ．ｓｐ．ｉｎｄｉｃａ）、粳稻（Ｏ．ｓａｔｉｖａＬ．ｓｐ．ｊａｐｏｎｉｃａ）和多年生野生稻（Ｏ．ｒｕｆｉｐｏｇｏｎＷ．Ｇｒｉｆｉｔｈ）ｈｓｐ７０基因第一个内含子中Ｄ１ＤＮＡ以及部分上游序列,并通过Ｎｏｒｔｈｅｒｎ杂交及ｃＤＮＡ序列分析对Ｄ１ＤＮＡ编码的Ｄ１ｓｎｏＲＮＡ进行了实验鉴定。Ｄ１ｓｎｏＲＮＡ属于反义ｓｎｏＲＮＡ家族,它与水稻２５ＳｒＲＮＡ互补序列为１４个核苷酸长。根据理论计算,Ｄ１ｓｎｏＲＮＡ具有指导水稻２５ＳｒＲＮＡ中第８０７位的核糖甲基化功能。Ｄ１ＤＮＡ与Ｃ１ＤＮＡ相隔仅１０５个核苷酸,在内含子中如此短的距离内连续编码两种ｓｎｏＲＮＡ是罕见的,这一结构为研究串联结构的ｓｎｏＲＮＡ转录后加工机制提供了一个良好的研究体系。