Box C/D sRNA stem ends act as stabilizing anchors for box C/D di-sRNPs

Ribosomal RNA (rRNA) modifications are essential for ribosome function in all cellular organisms. Box C/D small (nucleolar) ribonucleoproteins [s(no)RNPs] catalyze 2′-O-methylation, one rRNA modification type in Eukarya and Archaea. Negatively stained electron microscopy (EM) models of archaeal box C/D sRNPs have demonstrated the dimeric sRNP (di-sRNP) architecture, which has been corroborated by nuclear magnetic resonance (NMR) studies. Due to limitations of the structural techniques, the orientation of the box C/D sRNAs has remained unclear. Here, we have used cryo-EM to elucidate the sRNA orientation in a M. jannaschii box C/D di-sRNP. The cryo-EM reconstruction suggests a parallel orientation of the two sRNAs. Biochemical and structural analyses of sRNPs assembled with mutant sRNAs indicate a potential interaction between the sRNA stem ends. Our results suggest that the parallel arrangement of the sRNAs juxtaposes their stem ends into close proximity to allow for a stabilizing interaction that helps maintain the di-sRNP architecture.     

Efficient RNA 2'-O-methylation requires juxtaposed and symmetrically assembled archaeal box C/D and C'/D' RNPs

Box C/D ribonucleoprotein (RNP) complexes direct the nucleotide-specific 2'-O-methylation of ribonucleotide sugars in target RNAs. In vitro assembly of an archaeal box C/D sRNP using recombinant core proteins L7, Nop56/58 and fibrillarin has yielded an RNA:protein enzyme that guides methylation from both the terminal box C/D core and internal C'/D' RNP complexes. Reconstitution of sRNP complexes containing only box C/D or C'/D' motifs has demonstrated that the terminal box C/D RNP is the minimal methylation-competent particle. However, efficient ribonucleotide 2'-O-methylation requires that both the box C/D and C'/D' RNPs function within the full-length sRNA molecule. In contrast to the eukaryotic snoRNP complex, where the core proteins are distributed asymmetrically on the box C/D and C'/D' motifs, all three archaeal core proteins bind both motifs symmetrically. This difference in core protein distribution is a result of altered RNA-binding capabilities of the archaeal and eukaryotic core protein homologs. Thus, evolution of the box C/D nucleotide modification complex has resulted in structurally distinct archaeal and eukaryotic RNP particles.     

A guided tour: small RNA function in Archaea

In eukaryotes, the C/D box family of small nucleolar (sno)RNAs contain complementary guide regions that are used to direct 2'-O-ribose methylation to specific nucleotide positions within rRNA during the early stages of ribosome biogenesis. Direct cDNA cloning and computational genome searches have revealed homologues of C/D box snoRNAs (called sRNAs) in prokaryotic Archaea that grow at high temperature. The guide sequences within the sRNAs indicate that they are used to direct methylation to nucleotides in both rRNAs and tRNAs. The number of sRNA genes that are detectable within currently sequenced genomes correlates with the optimal growth temperature. We suggest that archaeal sRNAs may have two functions: to guide the deposition of methyl groups at the 2'-O position of ribose, which is an important determinant in RNA structural stability, and to serve as a molecular chaperones to help orchestrate the folding of rRNAs and tRNAs at high temperature.     

Assembly of the archaeal box C/D sRNP can occur via alternative pathways and requires temperature-facilitated sRNA remodeling

Archaeal dual-guide box C/D small nucleolar RNA-like RNAs (sRNAs) bind three core proteins in sequential order at both terminal box C/D and internal C'/D' motifs to assemble two ribonuclear protein (RNP) complexes active in guiding nucleotide methylation. Experiments have investigated the process of box C/D sRNP assembly and the resultant changes in sRNA structure or "remodeling" as a consequence of sRNP core protein binding. Hierarchical assembly of the Methanocaldococcus jannaschii sR8 box C/D sRNP is a temperature-dependent process with binding of L7 and Nop56/58 core proteins to the sRNA requiring elevated temperature to facilitate necessary RNA structural dynamics. Circular dichroism (CD) spectroscopy and RNA thermal denaturation revealed an increased order and stability of sRNA folded structure as a result of L7 binding. Subsequent binding of the Nop56/58 and fibrillarin core proteins to the L7-sRNA complex further remodeled sRNA structure. Assessment of sR8 guide region accessibility using complementary RNA oligonucleotide probes revealed significant changes in guide region structure during sRNP assembly. A second dual-guide box C/D sRNA from M. jannaschii, sR6, also exhibited RNA remodeling during temperature-dependent sRNP assembly, although core protein binding was affected by sR6's distinct folded structure. Interestingly, the sR6 sRNP followed an alternative assembly pathway, with both guide regions being continuously exposed during sRNP assembly. Further experiments using sR8 mutants possessing alternative guide regions demonstrated that sRNA folded structure induced by specific guide sequences impacted the sRNP assembly pathway. Nevertheless, assembled sRNPs were active for sRNA-guided methylation independent of the pathway followed. Thus, RNA remodeling appears to be a common and requisite feature of archaeal dual-guide box C/D sRNP assembly and formation of the mature sRNP can follow different assembly pathways in generating catalytically active complexes.     

A novel Nop5-sRNA interaction that is required for efficient archaeal box C/D sRNP formation

Archaeal and eukaryotic box C/D RNPs catalyze the 2'-O-methylation of ribosomal RNA, a modification that is essential for the correct folding and function of the ribosome. Each archaeal RNP contains three core proteins--L7Ae, Nop5, and fibrillarin (methyltransferase)--and a box C/D sRNA. Base-pairing between the sRNA guide region and the rRNA directs target site selection with the C/D and related C'/D' motifs functioning as protein binding sites. Recent structural analysis of in vitro assembled archaeal complexes has produced two divergent models of box C/D sRNP structure. In one model, the complex is proposed to be monomeric, while the other suggests a dimeric sRNP. The position of the RNA in the RNP is significantly different in each model. We have used UV-cross-linking to characterize protein-RNA contacts in the in vitro assembled Pyrococcus furiosus box C/D sRNP. The P. furiosus sRNP components assemble into complexes that are the expected size of di-sRNPs. Analysis of UV-induced protein-RNA cross-links revealed a novel interaction between the ALFR motif, in the Nop domain of Nop5, and the guide/spacer regions of the sRNA. We show that the ALFR motif and the spacer sequence adjacent to box C or C' are important for box C/D sRNP assembly in vitro. These data therefore reveal new RNA-protein contacts in the box C/D sRNP and suggest a role for Nop5 in substrate binding and/or release.     

Binding of L7Ae protein to the K-turn of archaeal snoRNAs: a shared RNA binding motif for C/D and H/ACA box snoRNAs in Archaea

Small nucleolar RNAs (designated as snoRNAs in Eukarya or sRNAs in Archaea) can be grouped into H/ACA or C/D box snoRNA (sRNA) subclasses. In Eukarya, H/ACA snoRNAs assemble into a ribonucleoprotein (RNP) complex comprising four proteins: Cbf5p, Gar1p, Nop10p and Nhp2p. A homolog for the Nhp2p protein has not been identified within archaeal H/ACA RNPs thus far, while potential orthologs have been identified for the other three proteins. Nhp2p is related, particularly in the middle portion of the protein sequence, to the archaeal ribosomal protein and C/D box protein L7Ae. This finding suggests that L7Ae may be able to substitute for the Nhp2p protein in archaeal H/ACA sRNAs. By band shift assays, we have analyzed in vitro the interaction between H/ACA box sRNAs and protein L7Ae from the archaeon Archaeoglobus fulgidus. We present evidence that L7Ae forms specific complexes with three different H/ACA sRNAs, designated as Afu-4, Afu-46 and Afu-190 with an apparent K(d) ranging from 28 to 100 nM. By chemical and enzymatic probing we show that distinct bases located within bulges or loops of H/ACA sRNAs interact with the L7Ae protein. These findings are corroborated by mutational analysis of the L7Ae binding site. Thereby, the RNA motif required for L7Ae binding exhibits a structure, designated as the K-turn, which is present in all C/D box sRNAs. We also identified four H/ACA RNAs from the archaeal species Pyrococcus which exhibit the K-turn motif at a similar position in their structure. These findings suggest a triple role for L7Ae protein in Archaea, e.g. in ribosomes as well as H/ACA and C/D box sRNP biogenesis and function by binding to the K-turn motif.     

Dynamic guide-target interactions contribute to sequential 2'-O-methylation by a unique archaeal dual guide box C/D sRNP

Assembly and guide-target interaction of an archaeal box C/D-guide sRNP was investigated under various conditions by analyzing the lead (II)-induced cleavage of the guide RNA. Guide and target RNAs derived from Haloferax volcanii pre-tRNA(Trp) were used with recombinant Methanocaldococcus jannaschii core proteins in the reactions. Core protein L7Ae binds differentially to C/D and C'/D' motifs of the guide RNA, and interchanging the two motifs relative to the termini of the guide RNA did not affect L7Ae binding or sRNA function. L7Ae binding to the guide RNA exposes its D'-guide sequence first followed by the D guide. These exposures are reduced when aNop5p and aFib proteins are added. The exposed guide sequences did not pair with the target sequences in the presence of L7Ae alone. The D-guide sequence could pair with the target in the presence of L7Ae and aNop5p, suggesting a role of aNop5p in target recruitment and rearrangement of sRNA structure. aFib binding further stabilizes this pairing. After box C/D-guided modification, target-guide pairing at the D-guide sequence is disrupted, suggesting that each round of methylation may require some conformational change or reassembly of the RNP. Asymmetric RNPs containing only one L7Ae at either of the two box motifs can be assembled, but a functional RNP requires L7Ae at the box C/D motif. This arrangement resembles the asymmetric eukaryal snoRNP. Observations of initial D-guide-target pairing and the functional requirement for L7Ae at the box C/D motif are consistent with our previous report of the sequential 2'-O-methylations of the target RNA.     

The expanding world of small RNAs in the hyperthermophilic archaeon Sulfolobus solfataricus

Archaeal L7Ae is a multifunctional protein that binds to a distinctive K-turn motif in RNA and is found as a component in the large subunit of the ribosome, and in ribose methylation and pseudouridylation guide RNP particles. A collection of L7Ae-associated small RNAs were isolated from Sulfolobus solfataricus cell extracts and used to construct a cDNA library; 45 distinct cDNA sequences were characterized and divided into six groups. Group 1 contained six RNAs that exhibited the features characteristic of the canonical C/D box archaeal sRNAs, two RNAs that were atypical C/D box sRNAs and one RNA representative of archaeal H/ACA sRNA family. Group 2 contained 13 sense strand RNA sequences that were encoded either within, or overlapping annotated open reading frames (ORFs). Group 3 contained three sequences form intergenic regions. Group 4 contained antisense sequences from within or overlapping sense strand ORFs or antisense sequences to C/D box sRNAs. More than two-thirds of these sequences possessed K-turn motifs. Group 5 contained two sequences corresponding to internal regions of 7S RNA. Group 6 consisted of 11 sequences that were fragments from the 5' or 3' ends of 16S and 23S ribosomal RNA and from seven different tRNAs. Our data suggest that S. solfataricus contains a plethora of small RNAs. Most of these are bound directly by the L7Ae protein; the others may well be part of larger, transiently stable RNP complexes that contain the L7Ae protein as core component.     

Archaeal homologs of eukaryotic methylation guide small nucleolar RNAs: lessons from the Pyrococcus genomes

Ribose methylation is a prevalent type of nucleotide modification in rRNA. Eukaryotic rRNAs display a complex pattern of ribose methylations, amounting to 55 in yeast Saccharomyces cerevisiae and about 100 in vertebrates. Ribose methylations of eukaryotic rRNAs are each guided by a cognate small RNA, belonging to the family of box C/D antisense snoRNAs, through transient formation of a specific base-pairing at the rRNA modification site. In prokaryotes, the pattern of rRNA ribose methylations has been fully characterized in a single species so far, Escherichia coli, which contains only four ribose methylated rRNA nucleotides. However, the hyperthermophile archaeon Sulfolobus solfataricus contains, like eukaryotes, a large number of (yet unmapped) rRNA ribose methylations and homologs of eukaryotic box C/D small nucleolar ribonuclear proteins have been identified in archaeal genomes. We have therefore searched archaeal genomes for potential homologs of eukaryotic methylation guide small nucleolar RNAs, by combining searches for structured motifs with homology searches. We have identified a family of 46 small RNAs, conserved in the genomes of three hyperthermophile Pyrococcus species, which we have experimentally characterized in Pyrococcus abyssi. The Pyrococcus small RNAs, the first reported homologs of methylation guide small nucleolar RNAs in organisms devoid of a nucleus, appear as a paradigm of minimalist box C/D antisense RNAs. They differ from their eukaryotic homologs by their outstanding structural homogeneity, extended consensus box motifs and the quasi-systematic presence of two (instead of one) rRNA antisense elements. Remarkably, for each small RNA the two antisense elements always match rRNA sequences close to each other in rRNA structure, suggesting an important role in rRNA folding. Only a few of the predicted P. abyssi rRNA ribose methylations have been detected so far. Further analysis of these archaeal small RNAs could provide new insights into the origin and functions of methylation guide small nucleolar RNAs and illuminate the still elusive role of rRNA ribose methylations.     

A large collection of compact box C/D snoRNAs and their isoforms in Euglena gracilis: structural, functional and evolutionary insights

In the domains Eucarya and Archaea, box C/D RNAs guide methylation at the 2'-position of selected ribose residues in ribosomal RNA (rRNA). Those eukaryotic box C/D RNAs that have been identified to date are larger and more variable in size than their archaeal counterparts. Here, we report the first extensive identification and characterization of box C/D small nucleolar (sno) RNAs from the protist Euglena gracilis. Among several unexpected findings, this organism contains a large assortment of methylation-guide RNAs that are smaller and more uniformly sized than those of other eukaryotes, and that consist of surprisingly few double-guide RNAs targeting sites of rRNA modification. Our comprehensive examination of the modification status of E.gracilis rRNA indicates that many of these box C/D snoRNAs target clustered methylation sites requiring extensive, overlapping guide RNA/rRNA pairings. An examination of the structure of the RNAs, in particular the location of the functional guide elements, suggests that the distances between adjacent box elements are an important factor in determining which of the potential guide elements is used to target a site of O(2')-methylation.     

The box C/D sRNP dimeric architecture is conserved across domain Archaea

Box C/D small (nucleolar) ribonucleoproteins [s(no)RNPs] catalyze RNA-guided 2'-O-ribose methylation in two of the three domains of life. Recent structural studies have led to a controversy over whether box C/D sRNPs functionally assemble as monomeric or dimeric macromolecules. The archaeal box C/D sRNP from Methanococcus jannaschii (Mj) has been shown by glycerol gradient sedimentation, gel filtration chromatography, native gel analysis, and single-particle electron microscopy (EM) to adopt a di-sRNP architecture, containing four copies of each box C/D core protein and two copies of the Mj sR8 sRNA. Subsequently, investigators used a two-stranded artificial guide sRNA, CD45, to assemble a box C/D sRNP from Sulfolobus solfataricus with a short RNA methylation substrate, yielding a crystal structure of a mono-sRNP. To more closely examine box C/D sRNP architecture, we investigate the role of the omnipresent sRNA loop as a structural determinant of sRNP assembly. We show through sRNA mutagenesis, native gel electrophoresis, and single-particle EM that a di-sRNP is the near exclusive architecture obtained when reconstituting box C/D sRNPs with natural or artificial sRNAs containing an internal loop. Our results span three distantly related archaeal species--Sulfolobus solfataricus, Pyrococcus abyssi, and Archaeoglobus fulgidus--indicating that the di-sRNP architecture is broadly conserved across the entire archaeal domain.     

Identification of novel non-coding RNAs as potential antisense regulators in the archaeon Sulfolobus solfataricus

By generating a specialized cDNA library from the archaeon Sulfolobus solfataricus, we have identified 57 novel small non-coding RNA (ncRNA) candidates and confirmed their expression by Northern blot analysis. The majority was found to belong to one of two classes, either antisense or antisense-box RNAs, where the latter only exhibit partial complementarity to RNA targets. The most prominent group of antisense RNAs is transcribed in the opposite orientation to the transposase genes, encoded by insertion elements (transposons). Thus, these antisense RNAs may regulate transposition of insertion elements by inhibiting expression of the transposase mRNA. Surprisingly, the class of antisense RNAs also contained RNAs complementary to tRNAs or sRNAs (small-nucleolar-like RNAs). For the antisense-box ncRNAs, the majority could be assigned to the class of C/D sRNAs, which specify 2'-O-methylation sites on rRNAs or tRNAs. Five C/D sRNAs of this group are predicted to target methylation at six sites in 13 different tRNAs, thus pointing to the widespread role of these sRNA species in tRNA modification in Archaea. Another group of antisense-box RNAs, lacking typical C/D sRNA motifs, was predicted to target the 3'-untranslated regions of certain mRNAs. Furthermore, one of the ncRNAs that does not show antisense elements is transcribed from a repeat unit of a cluster of small regularly spaced repeats in S. solfataricus which is potentially involved in replicon partitioning. In conclusion, this is the first report of stably expressed antisense RNAs in an archaeal species and it raises the prospect that antisense-based mechanisms are also used widely in Archaea to regulate gene expression.     

RNA processing in the minimal organism Nanoarchaeum equitans

ABSTRACT: BACKGROUND: The minimal genome of the tiny, hyperthermophilic archaeon Nanoarchaeum equitans contains several fragmented genes and revealed unusual RNA processing pathways. These include the maturation of tRNA molecules via the trans-splicing of tRNA halves and genomic rearrangements to compensate for the absence of RNase P. RESULTS: Here, the RNA processing events in the N. equitans cell are analyzed using RNA-Seq deep sequencing methodology. All tRNA half precursor and tRNA termini were determined and support the tRNA trans-splicing model. The processing of CRISPR RNAs from two CRISPR clusters was verified. Twenty-seven C/D box small RNAs (sRNAs) and a H/ACA box sRNA were identified. The C/D box sRNAs were found to flank split genes, to form dicistronic tRNA-sRNA precursors and to be encoded within the tRNAMet intron. CONCLUSIONS: The presented data provide an overview of the production and usage of small RNAs in a cell that has to survive with a highly reduced genome. N. equitans lost many essential metabolic pathways but maintains highly active CRISPR/Cas and rRNA modification systems that appear to play an important role in genome fragmentation.     

RNA-Seq of the Nucleolus Reveals Abundant SNORD44-Derived Small RNAs

Small non-coding RNAs represent RNA species that are not translated to proteins, but which have diverse and broad functional activities in physiological and pathophysiological states. The knowledge of these small RNAs is rapidly expanding in part through the use of massive parallel (deep) sequencing efforts. We present here the first deep sequencing of small RNomes in subcellular compartments with particular emphasis on small RNAs (sRNA) associated with the nucleolus. The vast majority of the cellular, cytoplasmic and nuclear sRNAs were identified as miRNAs. In contrast, the nucleolar sRNAs had a unique size distribution consisting of 19–20 and 25 nt RNAs, which were predominantly composed of small snoRNA-derived box C/D RNAs (termed as sdRNA). Sequences from 47 sdRNAs were identified, which mapped to both 5′ and 3′ ends of the snoRNAs, and retained conserved box C or D motifs. SdRNA reads mapping to SNORD44 comprised 74% of all nucleolar sdRNAs, and were confirmed by Northern blotting as comprising both 20 and 25 nt RNAs. A novel 120 nt SNORD44 form was also identified. The expression of the SNORD44 sdRNA and 120 nt form was independent of Dicer/Drosha–mediated processing pathways but was dependent on the box C/D snoRNP proteins/sno-ribonucleoproteins fibrillarin and NOP58. The 120 nt SNORD44-derived RNA bound to fibrillarin suggesting that C/D sno-ribonucleoproteins are involved in regulating the stability or processing of SNORD44. This study reveals sRNA cell-compartment specific expression and the distinctive unique composition of the nucleolar sRNAs.     

Small RNA interactome of pathogenic E. coli revealed through crosslinking of RNase E

RNA sequencing studies have identified hundreds of non‐coding RNAs in bacteria, including regulatory small RNA (sRNA). However, our understanding of sRNA function has lagged behind their identification due to a lack of tools for the high‐throughput analysis of RNA–RNA interactions in bacteria. Here we demonstrate that in vivo sRNA–mRNA duplexes can be recovered using UV‐crosslinking, ligation and sequencing of hybrids (CLASH). Many sRNAs recruit the endoribonuclease, RNase E, to facilitate processing of mRNAs. We were able to recover base‐paired sRNA–mRNA duplexes in association with RNase E, allowing proximity‐dependent ligation and sequencing of cognate sRNA–mRNA pairs as chimeric reads. We verified that this approach captures bona fide sRNA–mRNA interactions. Clustering analyses identified novel sRNA seed regions and sets of potentially co‐regulated target mRNAs. We identified multiple mRNA targets for the pathotype‐specific sRNA Esr41, which was shown to regulate colicin sensitivity and iron transport in E. coli. Numerous sRNA interactions were also identified with non‐coding RNAs, including sRNAs and tRNAs, demonstrating the high complexity of the sRNA interactome.     

Structural features of the guide:target RNA duplex required for archaeal box C/D sRNA-guided nucleotide 2'-O-methylation

Archaeal box C/D sRNAs guide the 2'-O-methylation of target nucleotides using both terminal box C/D and internal C'/D' RNP complexes. In vitro assembly of a catalytically active Methanocaldococcus jannaschii sR8 box C/D RNP provides a model complex to determine those structural features of the guide:target RNA duplex important for sRNA-guided nucleotide methylation. Watson-Crick pairing of guide and target nucleotides was found to be essential for methylation, and mismatched bases within the guide:target RNA duplex also disrupted nucleotide modification. However, dependence upon Watson-Crick base-paired guide:target nucleotides for methylation was compromised in elevated Mg(2+) concentrations where mismatched target nucleotides were modified. Nucleotide methylation required that the guide:target duplex consist of an RNA:RNA duplex as a target ribonucleotide within a guide RNA:target DNA duplex that was not methylated. Interestingly, D and D' target RNAs exhibited different levels of methylation when deoxynucleotides were inserted into the target RNA or when target methylation was carried out in elevated Mg(2+) concentrations. These observations suggested that unique structural features of the box C/D and C'/D' RNPs differentially affect their respective methylation capabilities. The ability of the sR8 box C/D sRNP to methylate target nucleotides positioned within highly structured RNA hairpins suggested that the sRNP can facilitate unwinding of double-stranded target RNAs. Finally, increasing target RNA length to extend beyond those nucleotides that base pair with the sRNA guide sequence significantly increased sRNP turnover and thus nucleotide methylation. This suggests that target RNA interaction with the sRNP core proteins is also important for box C/D sRNP-guided nucleotide methylation.