Identification of ribozymes within a ribozyme library that efficiently cleave a long substrate RNA.

Positions 2-6 of the substrate-binding internal guide sequence (IGS) of the L-21 Sca I form of the Tetrahymena thermophila intron were mutagenized to produce a GN5 IGS library. Ribozymes within the GN5 library capable of efficient cleavage of an 818-nt human immunodeficiency virus type 1 vif-vpr RNA, at 37 degrees C, were identified by ribozyme-catalyzed guanosine addition to the 3' cleavage product. Three ribozymes (IGS = GGGGCU, GGCUCC, and GUGGCU) within the GN5 library that actively cleaved the long substrate were characterized kinetically and compared to the wild-type ribozyme (GGAGGG) and two control ribozymes (GGAGUC and GGAGAU).

Protein facilitation of group I intron splicing by assembly of the catalytic core and the 5' splice site domain.

The yeast mitochondrial group I intron b15 undergoes self-splicing at high Mg2+ concentrations, but requires the splicing factor CBP2 for reaction under physiological conditions. Chemical accessibility and UV cross-linking experiments now reveal that self-processing is slow because functional elements are not properly positioned in an active tertiary structure. Folding energy provided by CBP2 drives assembly of two RNA domains that comprise the catalytic core and meditates association of an approximately 100 nt 5' domain that contains the 5' splice site.

Telomerase RNA localized in the replication band and spherical subnuclear organelles in hypotrichous ciliates.

The intranuclear distribution of telomere DNA-binding protein and telomerase RNA in hypotrichous ciliates was revealed by indirect fluorescent antibody staining and in situ hybridization. The Oxytricha telomere protein colocalized with DNA, both being dispersed throughout the macronucleus except for numerous spherical foci that contained neither DNA nor the protein. Surprisingly, the telomerase RNA was concentrated in these foci; therefore, much of telomerase does not colocalize with telomeres.

Efficient protein-facilitated splicing of the yeast mitochondrial bI5 intron.

The splicing factor CBP2 is required to excise the yeast mitochondrial group I intron bI5 in vivo and at low magnesium ion concentrations in vitro. CBP2 binding is strengthened 20-fold by increasing Mg2+ concentrations from 5 to 40 mM, implying the protein binds, in part, to the same structure as that stabilized by the cation. The same transition is also observed as a cooperative increase in the rate of self-processing between 5 and 40 mM Mg2+, providing strong evidence for an RNA folding transition promoted by either Mg2+ or CBP2.

Phosphorylation of the Oxytricha telomere protein: possible cell cycle regulation.

In the macronucleus of the ciliate Oxytricha nova, telomeres end with single-stranded (T4G4)2 DNA bound to a heterodimeric telomere protein (alpha beta). Both the alpha and beta subunits (alpha-TP and beta-TP) were phosphorylated in asynchronously growing Oxytricha; beta-TP was phosphorylated to a much higher degree. In vitro, mouse cyclin-dependent kinases (Cdks) phosphorylated beta-TP in a lysine-rich domain that is not required for specific DNA binding but is implicated in higher order structure formation of telomeres.

Analysis of the structure of Tetrahymena nuclear RNAs in vivo: telomerase RNA, the self-splicing rRNA intron, and U2 snRNA.

Dimethyl sulfate modification of RNA in living Tetrahymena thermophila allowed assessment of RNA secondary structure and protein association. The self-splicing rRNA intron had the same methylation pattern in vivo as in vitro, indicating that the structures are equivalent and suggesting that this RNA is not stably associated with protein in the nucleolus. Methylation was consistent with the current secondary structure model.

A positive entropy change for guanosine binding and for the chemical step in the Tetrahymena ribozyme reaction.

The ribozyme derived from the group I intron of Tetrahymena thermophila binds an exogenous guanosine nucleotide, which acts as the nucleophile in the sequence-specific cleavage of oligonucleotides. By examining the temperature dependence of the reaction under conditions where Km = Kd, we conclude the following: (1) Guanosine 5'-monophosphate (pG) binds to the closed ribozyme-oligonucleotide substrate complex with a positive entropy change (delta S degree' = +23 eu) and an enthalpy change (delta H degree') close to zero. This is contrary to the expectation that binding would cause increased order (negative delta S degree) and be driven by a negative delta H degree.

Selection of an RNA molecule that mimics a major autoantigenic epitope of human insulin receptor.

Autoimmunity often involves the abnormal targeting of self-antigens by antibodies, leading to tissue destruction and other pathologies. This process could potentially be disrupted by small ligands that bind specifically to autoantibodies and inhibit their interaction with the target antigen. Here we report the identification of an RNA sequence that binds a mouse monoclonal antibody specific for an autoantigenic epitope of human insulin receptor.

Self-assembly of a group I intron active site from its component tertiary structural domains.

The catalytic core of Group I self-splicing introns has been proposed to consist of two structural domains, P4-P6 and P3-P9. Each contains helical segments and conserved unpaired nucleotides, and the isolated P4-P6 domain has been shown to have substantial native tertiary structure. The proposed tertiary structure domains of the Tetrahymena intron were synthesized separately and shown to self-assemble into a catalytically active complex.

Minor groove recognition of the conserved G.U pair at the Tetrahymena ribozyme reaction site.

The guanine-uracil (G.U) base pair that helps to define the 5'-splice site of group I introns is phylogenetically highly conserved. In such a wobble base pair, G makes two hydrogen bonds with U in a geometry shifted from that of a canonical Watson-Crick pair.

Catalysis of RNA cleavage by a ribozyme derived from the group I intron of Anabaena pre-tRNA(Leu).

In the cyanobacterium Anabaena PCC7120, the precursor to tRNA(Leu) contains a 249-nucleotide group I intron that undergoes efficient self-splicing in vitro. By deleting the 5' and 3' splice sites, this intron has now been converted to an RNA enzyme that uses a guanosine nucleophile to cleave substrate RNAs (S) with multiple turnover. This Anabaena ribozyme has a second-order rate constant for RNA cleavage (kcat/Km)S that is 250-500-fold smaller than that of the Tetrahymena ribozyme, and a multiple-turnover rate constant at saturating S [kcat(mt)] that is approximately 400-fold larger.

Replacement of the conserved G.U with a G-C pair at the cleavage site of the Tetrahymena ribozyme decreases binding, reactivity, and fidelity.

There is a phylogenetically conserved G.U pair at the 5'-splice site of group I introns. When this is mutagenized to a G-C pair, splicing of these introns is greatly reduced.

The 2,6-diaminopurine riboside.5-methylisocytidine wobble base pair: an isoenergetic substitution for the study of G.U pairs in RNA.

Phylogenetically invariant G.U wobble pairs are present in a wide variety of RNA's. As a means to study the contribution of individual chemical groups within a G.

Ribozyme-mediated repair of defective mRNA by targeted, trans-splicing.

Ribozymes can be targeted to cleave specific RNAs, which has led to much interest in their potential as gene inhibitors. Such trans-cleaving ribozymes join a growing list of agents that stop the flow of genetic information. Here we describe a different application of ribozymes for which they may be uniquely suited.

Coaxially stacked RNA helices in the catalytic center of the Tetrahymena ribozyme.

Coaxial stacking of helical elements is a determinant of three-dimensional structure in RNA. In the catalytic center of the Tetrahymena group I intron, helices P4 and P6 are part of a tertiary structural domain that folds independently of the remainder of the intron. When P4 and P6 were fused with a phosphodiester linkage, the resulting RNA retained the detailed tertiary interactions characteristic of the native P4-P6 domain and even required lower magnesium ion concentrations for folding.

Telomerase RNAs of different ciliates have a common secondary structure and a permuted template.

Telomerase is composed of protein and RNA. The RNA serves as a template for telomere DNA synthesis and may also be important for enzyme structure or catalysis. We have used the presence of conserved sequence elements in the promoter and template regions to amplify by PCR the telomerase RNA genes from six different hypotrichous ciliates: Oxytricha nova, Oxytricha trifallax, Stylonychia mytilis, Stylonychia lemnae, Euplotes aediculatus, and Euplotes eurystomus.

Two major tertiary folding transitions of the Tetrahymena catalytic RNA.

The L-21 Tetrahymena ribozyme, an RNA molecule with sequence-specific endoribonuclease activity derived from a self-splicing group I intron, provides a model system for studying the RNA folding problem. A 160 nucleotide, independently folding domain of tertiary structure (the P4-P6 domain) comprises about half of the ribozyme. We now apply Fe(II)-EDTA cleavage to mutants of the ribozyme to explore the role of individual structural elements in tertiary folding of the RNA at equilibrium.

A tertiary interaction in the Tetrahymena intron contributes to selection of the 5' splice site.

The utilization of cryptic splice sites has been observed in a number of RNA splicing reactions. In the self-splicing group I intron of Tetrahymena thermophila, point mutations of either A57 or A95 promote cleavage at two sites other than the normal 5' splice site, suggesting that these nucleotides are involved in a common tertiary interaction. These results are unusual since A57 and A95 are neither at nor near the 5' splice site in the sequence or secondary structure.

Representation of the secondary and tertiary structure of group I introns.

Group I introns, which are widespread in nature, carry out RNA self-splicing. The secondary structure common to these introns was for the most part established a decade ago. Information about their higher order structure has been derived from a range of experimental approaches, comparative sequence analysis, and molecular modelling.

Telomeric protein-DNA point contacts identified by photo-cross-linking using 5-bromodeoxyuridine.

The Oxytricha telomere protein specifically recognizes single-stranded telomeric DNA, forming an extremely salt resistant and kinetically stable nucleoprotein complex. The absence of information on how this heterodimeric protein binds to DNA prompted this photo-cross-linking study. Multiple protein-DNA photo-cross-links are formed upon UV irradiation of Oxytricha telomeres reconstituted with a synthetic oligonucleotide terminating in 5'-T16T15T14T13G12G11G10G9T8T7T6T5G4G3G2G1-3'.