YbxF and YlxQ are bacterial homologs of L7Ae and bind K-turns but not K-loops.

The archaeal protein L7Ae and eukaryotic homologs such as L30e and 15.5kD comprise the best characterized family of K-turn-binding proteins. K-turns are an RNA motif comprised of a bulge flanked by canonical and noncanonical helices. They are widespread in cellular RNAs, including bacterial gene-regulatory RNAs such as the c-di-GMP-II, lysine, and SAM-I riboswitches, and the T-box. The existence in bacteria of K-turn-binding proteins of the L7Ae family has not been proven, although two hypothetical proteins, YbxF and YlxQ, have been proposed to be L7Ae homologs based on sequence conservation. Using purified, recombinant proteins, we show that Bacillus subtilis YbxF and YlxQ bind K-turns (K(d) ~270 nM and ~2300 nM, respectively). Crystallographic structure determination demonstrates that both YbxF and YlxQ adopt the same overall fold as L7Ae. Unlike the latter, neither bacterial protein recognizes K-loops, a structural motif that lacks the canonical helix of the K-turn. This property is shared between the bacterial and eukaryal family members. Comparison of our structure of YbxF in complex with the K-turn of the SAM-I riboswitch and previously determined structures of archaeal and eukaryal homologs bound to RNA indicates that L7Ae approaches the K-turn at a unique angle, which results in a considerably larger RNA-protein interface dominated by interactions with the noncanonical helix of the K-turn. Thus, the inability of the bacterial and eukaryal L7Ae homologs to bind K-loops probably results from their reliance on interactions with the canonical helix. The biological functions of YbxF and YlxQ remain to be determined.

The box H/ACA ribonucleoprotein complex: interplay of RNA and protein structures in post-transcriptional RNA modification.

The box H/ACA ribonucleoproteins (RNPs) are protein-RNA complexes responsible for pseudouridylation, the most abundant post-transcriptional modification of cellular RNAs. Integrity of its box H/ACA domain is also essential for assembly and stability of the human telomerase RNP. The recent publication of the complete box H/ACA RNP structures combined with the previously reported structures of the protein and RNA components makes it possible to deduce the structural accommodation that accompanies assembly of the full particle. This analysis reveals how the protein components distort the RNA component of the RNP, enabling productive docking of the substrate RNA into the enzymatic active site.

The structure and function of small nucleolar ribonucleoproteins.

Eukaryotes and archaea use two sets of specialized ribonucleoproteins (RNPs) to carry out sequence-specific methylation and pseudouridylation of RNA, the two most abundant types of modifications of cellular RNAs. In eukaryotes, these protein-RNA complexes localize to the nucleolus and are called small nucleolar RNPs (snoRNPs), while in archaea they are known as small RNPs (sRNP). The C/D class of sno(s)RNPs carries out ribose-2'-O-methylation, while the H/ACA class is responsible for pseudouridylation of their RNA targets. Here, we review the recent advances in the structure, assembly and function of the conserved C/D and H/ACA sno(s)RNPs. Structures of each of the core archaeal sRNP proteins have been determined and their assembly pathways delineated. Furthermore, the recent structure of an H/ACA complex has revealed the organization of a complete sRNP. Combined with current biochemical data, these structures offer insight into the highly homologous eukaryotic snoRNPs.

Pseudouridine synthases.

Pseudouridine synthases are the enzymes responsible for the most abundant posttranscriptional modification of cellular RNAs. These enzymes catalyze the site-specific isomerization of uridine residues that are already part of an RNA chain, and appear to employ both sequence and structural information to achieve site specificity. Crystallographic analyses have demonstrated that all pseudouridine synthases share a common core fold and active site structure and that this core is modified by peripheral domains, accessory proteins, and guide RNAs to give rise to remarkable substrate versatility.

The Cbf5-Nop10 complex is a molecular bracket that organizes box H/ACA RNPs.

Box H/ACA ribonucleoprotein particles (RNPs) catalyze RNA pseudouridylation and direct processing of ribosomal RNA, and are essential architectural components of vertebrate telomerases. H/ACA RNPs comprise four proteins and a multihelical RNA. Two proteins, Cbf5 and Nop10, suffice for basal enzymatic activity in an archaeal in vitro system. We now report their cocrystal structure at 1.95-A resolution. We find that archaeal Cbf5 can assemble with yeast Nop10 and with human telomerase RNA, consistent with the high sequence identity of the RNP components between archaea and eukarya. Thus, the Cbf5-Nop10 architecture is phylogenetically conserved. The structure shows how Nop10 buttresses the active site of Cbf5, and it reveals two basic troughs that bidirectionally extend the active site cleft. Mutagenesis results implicate an adjacent basic patch in RNA binding. This tripartite RNA-binding surface may function as a molecular bracket that organizes the multihelical H/ACA and telomerase RNAs.

Structure of protein L7Ae bound to a K-turn derived from an archaeal box H/ACA sRNA at 1.8 A resolution.

The archaeal RNA binding protein L7Ae and its eukaryotic homolog 15.5 kDa/Snu13 recognize K-turns. This structural motif is canonically comprised of two stems (one with tandem A.G base pairs, the other with Watson-Crick pairs) linked by an asymmetric internal loop. L7Ae recognizes conventional K-turns in ribosomal and box C/D RNAs but also binds specifically to some box H/ACA RNAs at terminal stem loops. These have the A.G paired stem, but lack the Watson-Crick stem. The structure of Methanococcus jannaschii L7Ae bound to a symmetric duplex RNA without Watson-Crick stems demonstrates how a binding site for this component of diverse ribonucleoprotein complexes can be constructed with only the A.G stem and the loop. The RNA adopts a functional conformation with the aid of a base triple and tight binding of divalent cations. Comparison with the 15.5 kDa/Snu13-RNA complex structure suggests why the eukaryotic homolog does not recognize terminal stem loop L7Ae binding sites.

Inhibition of HIV tat-TAR interactions by an antisense oligo-2'-O-methylribonucleoside methylphosphonate.

An antisense oligo-2'-O-methylribonucleotide having alternating methylphosphonate/phosphodiester linkages, 1676, whose sequence is complementary to the apical stem-loop of HIV-1 TAR RNA, was prepared to determine its effects on Tat protein-TAR interaction and Tat-mediated gene transactivation in cell culture. This oligomer and its all-phosphodiester analogue, 1707, were shown to: (1) bind to TAR at 37 degrees C with K(d)'s in the low nM concentration range; (2) inhibit Tat-TAR complex formation; and (3) inhibit expression of a chloramphenicol reporter gene under control of the HIV LTR in HeLa HL3T1 cells in culture.

Interactions of hairpin oligo-2'-O-methylribonucleotides containing methylphosphonate linkages with HIV TAR RNA.

Methylphosphonate-modified oligo-2'-O-methylribonucleotides 15-20 nucleotides (nt) in length were prepared whose sequences are complementary to the 5' and 3' sides of the upper hairpin of HIV trans-acting response element (TAR) RNA. These anti-TAR oligonucleotides (ODNs) form stable hairpins whose melting temperatures (Tm) range from 55 degrees C to 80 degrees C. Despite their rather high thermal stabilities, the hairpin oligo-2'-O-methylribonucleotides formed very stable complexes with TAR RNA, with dissociation constants in the nanomolar concentration range at 37 degrees C. The affinities of the hairpin oligomers for TAR RNA were influenced by the positions of the methylphosphonate linkages. The binding affinity was reduced approximately 17-fold by the presence of two methylphosphonate linkages in the TAR loop complementary region (TLCR) of the oligomer, whereas methylphosphonate linkages outside this region increased binding affinity approximately 3-fold. The configurations of the methylphosphonate linkages in the TLCR also affected binding affinity, with the RpRp isomer showing significantly higher binding than the SpSp isomer. In addition to serving as probes of the interactions between the oligomer and TAR RNA, the presence of the methylphosphonate linkages in combination with the hairpin structure increases the resistance of these oligomers to degradation by exonucleases found in mammalian serum. The combination of high binding affinity and nuclease resistance of the hairpin ODNs containing methylphosphonate linkages suggests their potential utility as antisense compounds.

4-(2-aminooxyethoxy)-2-(ethylureido)quinoline-oligonucleotide conjugates: synthesis, binding interactions, and derivatization with peptides.

Oligo-2'-O-methylribonucleotides conjugated with 4-(2-aminooxyethoxy)-2-(ethylureido)quinoline (AOQ) and 4-ethoxy-2-(ethylureido)quinoline (EOQ) were prepared by reaction of the AOQ or EOQ phosphoramidite with the protected oligonucleotide on a controlled pore glass support. Deprotection with ethylenediamine enabled successful isolation and purification of the highly reactive AOQ-conjugated oligomer. Polyacrylamide gel electrophoresis mobility shift experiments showed that the dissociation constants of complexes formed between an AOQ- or EOQ-conjugated 8-mer and complementary RNA or 2'-O-methyl-RNA targets (9- and 10-mers) were in the low nM concentration range at 37 degrees C, whereas no binding was observed for the corresponding nonconjugated oligomer, even at a concentration of 500 nM. Fluorescence studies suggested that this enhanced affinity is most likely due to the ability of the quinoline ring of the AOQ or EOQ group to stack on the last base pair formed between the oligomer and target, thus stabilizing the duplex. The binding affinity of a 2'-O-methyl RNA 15-mer, which contained an alternating methylphosphonate/phosphodiester backbone, for a 59-nucleotide stem-loop HIV TAR RNA target, increased 2.3 times as a consequence of conjugation with EOQ. The aminooxy group of AOQ-conjugated oligomers is a highly reactive nucleophile, which reacts readily with aldehydes and ketones to form stable oxime derivatives. This feature was used to couple an AOQ-oligomer with leupeptin, a tripeptide that contains a C-terminus aldehyde group. A simple method was developed to introduce a ketone functionality into peptides that contain a cysteine residue by reacting the peptide with bromoacetone. The resulting keto-peptide was then coupled to the AOQ-oligomer. This procedure was used to prepare oligonucleotide conjugates of a tetrapeptide, RGDC, and a derivative of HIV tat peptide having a C-terminus cysteine. The combination of the unique reactivity of the aminooxy group and enhanced binding affinity conferred by its quinoline ring suggests that AOQ may serve as a useful platform for the preparation of novel oligonucleotide conjugates.