Telomerase activity is sensitive to subtle perturbations of the TLC1 pseudoknot 3' stem and tertiary structure.

Pseudoknot formation in the core region of the telomerase RNA has been demonstrated to be important for telomerase activity in vertebrates, ciliates, and yeast. Characterization of the Saccharomyces cerevisiae telomerase RNA (TLC1) pseudoknot identified tertiary structural interactions that are also important for telomerase activity, as previously observed for the Kluyveromyces lactis and human telomerase RNA pseudoknots. In addition, the contributions of backbone ribose 2'-OH groups in the pseudoknot to telomerase catalysis were investigated previously, using 2'-OH (ribose) to 2'-H (deoxyribose) or 2'-O-methyl substitutions in the stem 2 helix, and it was proposed that one or more 2'-OH groups from the stem 2 sequences at or near the triple helix participate in telomerase catalysis. Based on these studies and investigations of the structural and thermodynamic properties of the TLC1 RNA pseudoknot region, we have examined the structural and thermodynamic perturbations of the 2'-O-methyl and 2'-H substituted pseudoknots, using UV-monitored thermal denaturation, native gel electrophoresis, and circular dichroism spectroscopy. Our results demonstrate the presence of A-form helical geometry perturbations in the backbone sugar substituted pseudoknots, show a correlation between thermodynamic stability and telomerase activity, and are consistent with the identification of the U809 ribose 2'-OH as a potential contributor to telomerase activity.

Thermodynamic characterization of the Saccharomyces cerevisiae telomerase RNA pseudoknot domain in vitro.

Recent structural and functional characterization of the pseudoknot in the Saccharomyces cerevisiae telomerase RNA (TLC1) has demonstrated that tertiary structure is present, similar to that previously described for the human and Kluyveromyces lactis telomerase RNAs. In order to biophysically characterize the identified pseudoknot secondary and tertiary structures, UV-monitored thermal denaturation experiments, nuclear magnetic resonance spectroscopy, and native gel electrophoresis were used to investigate various potential conformations in the pseudoknot domain in vitro, in the absence of the telomerase protein. Here, we demonstrate that alternative secondary structures are not mutually exclusive in the S. cerevisiae telomerase RNA, tertiary structure contributes 1.5 kcal mol(-1) to the stability of the pseudoknot (≈ half the stability observed for the human telomerase pseudoknot), and identify additional base pairs in the 3' pseudoknot stem near the helical junction. In addition, sequence conservation in an adjacent overlapping hairpin appears to prevent dimerization and alternative conformations in the context of the entire pseudoknot-containing region. Thus, this work provides a detailed in vitro characterization of the thermodynamic features of the S. cerevisiae TLC1 pseudoknot region for comparison with other telomerase RNA pseudoknots.

NMR studies of protein-RNA interactions.

This chapter describes the preparation of NMR quantities of RNA purified to single-nucleotide resolution for protein-RNA interaction studies. The protocol is easily modified to make nucleotide-specific isotopically labeled RNAs or uniformly labeled RNA fragments for ligation to generate segmentally labeled RNAs.

Effect of pseudouridylation on the structure and activity of the catalytically essential P6.1 hairpin in human telomerase RNA.

Telomerase extends the 3'-ends of linear chromosomes by adding conserved telomeric DNA repeats and is essential for cell proliferation and genomic stability. Telomerases from all organisms contain a telomerase reverse transcriptase and a telomerase RNA (TER), which together provide the minimal functional elements for catalytic activity in vitro. The RNA component of many functional ribonucleoproteins contains modified nucleotides, including conserved pseudouridines (Ψs) that can have subtle effects on structure and activity. We have identified potential Ψ modification sites in human TER. Two of the predicted Ψs are located in the loop of the essential P6.1 hairpin from the CR4-CR5 domain that is critical for telomerase catalytic activity. We investigated the effect of P6.1 pseudouridylation on its solution NMR structure, thermodynamic stability of folding and telomerase activation in vitro. The pseudouridylated P6.1 has a significantly different loop structure and increase in stability compared to the unmodified P6.1. The extent of loop nucleotide interaction with adjacent residues more closely parallels the extent of loop nucleotide evolutionary sequence conservation in the Ψ-modified P6.1 structure. Pseudouridine-modification of P6.1 slightly attenuates telomerase activity but slightly increases processivity in vitro. Our results suggest that Ψs could have a subtle influence on human telomerase activity via impact on TER-TERT or TER-TER interactions.

The 3'-flap pocket of human flap endonuclease 1 is critical for substrate binding and catalysis.

Flap endonuclease 1 (FEN1) proteins, which are present in all kingdoms of life, catalyze the sequence-independent hydrolysis of the bifurcated nucleic acid intermediates formed during DNA replication and repair. How FEN1s have evolved to preferentially cleave flap structures is of great interest especially in light of studies wherein mice carrying a catalytically deficient FEN1 were predisposed to cancer. Structural studies of FEN1s from phage to human have shown that, although they share similar folds, the FEN1s of higher organisms contain a 3'-extrahelical nucleotide (3'-flap) binding pocket. When presented with 5'-flap substrates having a 3'-flap, archaeal and eukaryotic FEN1s display enhanced reaction rates and cleavage site specificity. To investigate the role of this interaction, a kinetic study of human FEN1 (hFEN1) employing well defined DNA substrates was conducted. The presence of a 3'-flap on substrates reduced Km and increased multiple- and single turnover rates of endonucleolytic hydrolysis at near physiological salt concentrations. Exonucleolytic and fork-gap-endonucleolytic reactions were also stimulated by the presence of a 3'-flap, and the absence of a 3'-flap from a 5'-flap substrate was more detrimental to hFEN1 activity than removal of the 5'-flap or introduction of a hairpin into the 5'-flap structure. hFEN1 reactions were predominantly rate-limited by product release regardless of the presence or absence of a 3'-flap. Furthermore, the identity of the stable enzyme product species was deduced from inhibition studies to be the 5'-phosphorylated product. Together the results indicate that the presence of a 3'-flap is the critical feature for efficient hFEN1 substrate recognition and catalysis.

Solution structure and dynamics of the wild-type pseudoknot of human telomerase RNA.

Telomerase is a ribonucleoprotein complex that replicates the 3' ends of linear chromosomes by successive additions of telomere repeat DNA. The telomerase holoenzyme contains two essential components for catalysis, a telomerase reverse transcriptase (TERT) and telomerase RNA (TER). The TER includes a template for telomere repeat synthesis as well as other domains required for function. We report the solution structure of the wild-type minimal conserved human TER pseudoknot refined with an extensive set of RDCs, and a detailed analysis of the effect of the bulge U177 on pseudoknot structure, dynamics analyzed by RDC and 13C relaxation measurements, and base pair stability. The overall structure of PKWT is highly similar to the previously reported DeltaU177 pseudoknot (PKDU) that has a deletion of a conserved bulge U important for catalytic activity. For direct comparison to PKWT, the structure of PKDU was re-refined with a comparable set of RDCs. Both pseudoknots contain a catalytically essential triple helix at the junction of the two stems, including two stem 1-loop 2 minor groove triples, a junction loop 1-loop 2 Hoogsteen base pair, and stem 2-loop 1 major groove U.A-U Watson-Crick-Hoogsteen triples located directly above the bulge U177. However, there are significant differences in the stabilities of base pairs near the bulge and the dynamics of some nucleotides. The stability of the base pairs in stem 2 surrounding the bulge U177 is greatly decreased, with the result that the Watson-Crick pairs in the triple helix begin to unfold before the Hoogsteen pairs, which may affect telomerase assembly and activity. The bulge U is positioned in the minor groove on the face opposite the triple helical interactions, and sterically blocks the A176 2'OH, which has recently been proposed to have a role in catalysis. The bulge U may serve as a hinge providing backbone flexibility in this region.

Structural and functional characterization of human telomerase RNA processing and cajal body localization signals.

The RNA component of human telomerase (hTR) includes H/ACA and CR7 domains required for 3' end processing, localization, and accumulation. The terminal loop of the CR7 domain contains the CAB box (ugAG) required for targeting of scaRNAs to Cajal bodies (CB) and an uncharacterized sequence required for accumulation and processing. To dissect out the contributions of the CR7 stem loop to hTR processing and localization, we solved the solution structures of the 3' terminal stem loops of hTR CR7 and U64 H/ACA snoRNA, and the 5' terminal stem loop of U85 C/D-H/ACA scaRNA. These structures, together with analysis of localization, processing, and accumulation of hTRs containing nucleotide substitutions in the CR7 domain, identified the sequence and structural requirements of the hTR processing and CB localization signals and showed that these signals are functionally independent. Further, 3' end processing was found to be a prerequisite for translocation of hTR to CBs.

Structure and function of telomerase RNA.

Maintenance of telomeres by the enzyme telomerase is essential for genomic stability and cell viability in ciliates, vertebrates and yeast. The minimal components of telomerase required for catalytic activity are the telomerase reverse transcriptase (TERT) protein and the template-containing telomerase RNA (TER). Recent studies have afforded significant advances in the biophysical characterization of telomerase RNAs from various species. The first TER structures have been reported, for regions of the catalytically essential pseudoknot and CR4/CR5 domains of human TER, and provide a structural basis for interpretation of mutational and biochemical data. The domains and interactions of the Tetrahymena thermophila telomerase holoenzyme RNA and protein components have been further characterized biochemically, and structures of the TER template boundary element and the N-terminal domain of T. thermophila TERT have been determined. Phylogenetic and biochemical analyses of yeast TERs have revealed core structural elements in common with ciliates and vertebrates, and the minimal domains required for function in vivo.

Structure of the Tetrahymena thermophila telomerase RNA helix II template boundary element.

Telomere addition by telomerase requires an internal templating sequence located in the RNA subunit of telomerase. The correct boundary definition of this template sequence is essential for the proper addition of the nucleotide repeats. Incorporation of incorrect telomeric repeats onto the ends of chromosomes has been shown to induce chromosomal instability in ciliate, yeast and human cells. A 5' template boundary defining element (TBE) has been identified in human, yeast and ciliate telomerase RNAs. Here, we report the solution structure of the TBE element (helix II) from Tetrahymena thermophila telomerase RNA. Our results indicate that helix II and its capping pentaloop form a well-defined structure including unpaired, stacked adenine nucleotides in the stem and an unusual syn adenine nucleotide in the loop. A comparison of the T.thermophila helix II pentaloop with a pentaloop of the same sequence found in the 23S rRNA of the Haloarcula marismortui ribosome suggests possible RNA and/or protein interactions for the helix II loop within the Tetrahymena telomerase holoenzyme.

Structure of the human telomerase RNA pseudoknot reveals conserved tertiary interactions essential for function.

Human telomerase contains a 451 nt RNA (hTR) and several proteins, including a specialized reverse transcriptase (hTERT). The 5' half of hTR comprises the pseudoknot (core) domain, which includes the RNA template for telomere synthesis and a highly conserved pseudoknot that is required for telomerase activity. The solution structure of this essential pseudoknot, presented here, reveals an extended triple helix surrounding the helical junction. The network of tertiary interactions explains the phylogenetic sequence conservation and existing human and mouse TR functional studies as well as mutations linked to disease. Thermodynamic stability, dimerization potential, and telomerase activity of mutant RNAs that alter the tertiary contacts were investigated. Telomerase activity is strongly correlated with tertiary structure stability, whereas there is no correlation with dimerization potential of the pseudoknot. These studies reveal that a conserved pseudoknot tertiary structure is required for telomerase activity.

New applications of 2D filtered/edited NOESY for assignment and structure elucidation of RNA and RNA-protein complexes.

NMR spectra of large RNAs are difficult to assign because of extensive spectral overlap and unfavorable relaxation properties. Here we present a new approach to facilitate assignment of RNA spectra using a suite of four 2D-filtered/edited NOESY experiments in combination with base-type-specific isotopically labeled RNA. The filtering method was developed for use in 3D filtered NOESY experiments (Zwahlen et al., 1997), but the 2D versions are both more sensitive and easier to interpret for larger RNAs than their 3D counterparts. These experiments are also useful for identifying intermolecular NOEs in RNA-protein complexes. Applications to NOE assignment of larger RNAs and an RNA-protein complex are presented.

YNMG tetraloop formation by a dyskeratosis congenita mutation in human telomerase RNA.

Autosomal dominant dyskeratosis congenita (DKC) has been linked to mutations in the RNA component of telomerase, the ribonucleoprotein responsible for telomere maintenance. Recent studies have investigated the role of the GC (107-108) --> AG mutation in the conserved P3 helix in the pseudoknot domain of human telomerase RNA. The mutation was found to significantly destabilize the pseudoknot conformation, resulting in a shift in the thermodynamic equilibrium to favor formation of a P2b hairpin intermediate. In the wild-type sequence, the hairpin intermediate was found to form a novel sequence of pyrimidine base pairs in a continuous stem capped by a structured pentaloop. The DKC mutant hairpin was observed to be slightly more stable than the wild-type hairpin, further shifting the pseudoknot-hairpin equilibrium to favor the mutant P2b hairpin. Here we examined the solution structure of the DKC mutant hairpin to identify the reason for this additional stability. We found that the mutant hairpin forms the same stem structure as wild-type and that the additional stabilization observed using optical melting can be explained by the formation of a YNMG-type tetraloop structure, with the last nucleotide of the pentaloop bulged out into the major groove. Our results provide a structural explanation for the increased stability of the mutant hairpin and further our understanding of the effect of this mutation on the structure and stability of the dominant conformation of the pseudoknot domain in this type of DKC.

Mutations linked to dyskeratosis congenita cause changes in the structural equilibrium in telomerase RNA.

Autosomal dominant dyskeratosis congenita (DKC), as well as aplastic anemia, has been linked to mutations in the RNA component of telomerase, the ribonucleoprotein responsible for telomere maintenance. Here we examine the effect of the DKC mutations on the structure and stability of human telomerase RNA pseudoknot and CR7 domains by using NMR and thermal melting. The CR7 domain point mutation decreases stability and alters a conserved secondary structure thought to be involved in human telomerase RNA accumulation in vivo. We find that pseudoknot constructs containing the conserved elements of the pseudoknot domain are in equilibrium with a hairpin conformation. The solution structure of the wild-type hairpin reveals that it forms a continuous helix containing a novel run of three consecutive U.U and a U.C base pairs closed by a pentaloop. The six base pairs unique to the hairpin conformation are phylogenetically conserved in mammals, suggesting that this conformation is also functionally important. The DKC mutation in the pseudoknot domain results in a shift in the equilibrium toward the hairpin form, primarily due to destabilization of the pseudoknot. Our results provide insight into the effect of these mutations on telomerase structure and suggest that the catalytic cycle of telomerase involves a delicate interplay between RNA conformational states, alteration of which leads to the disease state.