Synthesis, incorporation efficiency, and stability of disulfide bridged functional groups at RNA 5'-ends

Modified guanosine monophosphates have been employed to introduce various functional groups onto RNA 5'-ends. Applications of modified RNA 5'-ends include the generation of functionalized RNA libraries for in vitro selection of catalytic RNAs, the attachment of photoaffinity-tags for mapping RNA-protein interactions or active sites in catalytic RNAs, or the nonradioactive labeling of RNA molecules with fluorescent groups. While in these and in similar applications a stable linkage is desired, in selection experiments for generating novel catalytic RNAs it is often advantageous that a functional group is introduced reversibly. Here we give a quantitative comparison of the different strategies that can be applied to reversibly attach functional groups via disulfide bonds to RNA 5'-ends. We report the preparation of functional groups with disulfide linkages, their incorporation efficiency into an RNA library, and their stability under various conditions.     

Mechanism of peptide bond formation on the ribosome

Peptide bond formation is the fundamental reaction of ribosomal protein synthesis. The ribosome's active site--the peptidyl transferase center--is composed of rRNA, and thus the ribosome is the largest known RNA catalyst. The ribosome accelerates peptide bond formation by 10(7)-fold relative to the uncatalyzed reaction. Recent progress of structural, biochemical and computational approaches has provided a fairly detailed picture of the catalytic mechanisms employed by the ribosome. Energetically, catalysis is entirely entropic, indicating an important role of solvent reorganization, substrate positioning, and/or orientation of the reacting groups within the active site. The ribosome provides a pre-organized network of electrostatic interactions that stabilize the transition state and facilitate proton shuttling involving ribose hydroxyl groups of tRNA. The catalytic mechanism employed by the ribosome suggests how ancient RNA-world enzymes may have functioned.     

“Bind,cleave and leave”: multiple turnover catalysis of RNA cleavage by bulge–loop inducing supramolecular conjugates

Antisense sequence-specific knockdown of pathogenic RNA offers opportunities to find new solutions for therapeutic treatments. However, to gain a desired therapeutic effect, the multiple turnover catalysis is critical to inactivate many copies of emerging RNA sequences, which is difficult to achieve without sacrificing the sequence-specificity of cleavage. Here, engineering two or three catalytic peptides into the bulge–loop inducing molecular framework of antisense oligonucleotides achieved catalytic turnover of targeted RNA. Different supramolecular configurations revealed that cleavage of the RNA backbone upon sequence-specific hybridization with the catalyst accelerated with increase in the number of catalytic guanidinium groups, with almost complete demolition of target RNA in 24 h. Multiple sequence-specific cuts at different locations within and around the bulge–loop facilitated release of the catalyst for subsequent attacks of at least 10 further RNA substrate copies, such that delivery of only a few catalytic molecules could be sufficient to maintain knockdown of typical RNA copy numbers. We have developed fluorescent assay and kinetic simulation tools to characterise how the limited availability of different targets and catalysts had restrained catalytic reaction progress considerably, and to inform how to accelerate the catalytic destruction of shorter linear and larger RNAs even further.     

Important 2'-hydroxyl groups in model substrates for M1 RNA, the catalytic RNA subunit of RNase P from Escherichia coli.

The role of 2'-hydroxyl groups in a model substrate for RNase P from Escherichia coli was studied using mixed DNA/RNA derivatives of such a substrate. The presence of the 2'-hydroxyl groups of nucleotides at positions -1 and -2 in the leader sequence and at position 1, as well as at the first C in the 3'-terminal CCA sequence, are important but not absolutely essential for efficient cleavage of the substrate by RNase P or its catalytic RNA subunit, M1 RNA. The 2'-hydroxyl groups in the substrate that are important for efficient cleavage also participate in the binding of Mg2+. An all-DNA external guide sequence (EGS) can efficiently render a potential substrate, derived from the model substrate, susceptible to cleavage by the enzyme or its catalytic RNA subunit. Furthermore, both DNA and RNA EGSs turn over during the reaction with RNase P in vitro. The identity of the nucleotide at position 1 in the substrate, the adjacent Mg(2+)-binding site in the leader sequence, and the junction of the single and double-stranded regions are the important elements in the recognition of model substrates, as well as in the identification of the sites of cleavage in those model substrates.     

Identification by modification-interference of purine N-7 and ribose 2'-OH groups critical for catalysis by bacterial ribonuclease P.

The RNA subunit of bacterial ribonuclease P is a catalytic RNA that cleaves precursor tRNAs to generate mature tRNA 5' ends. A self-cleaving RNase P RNA-substrate conjugate was used in modification-interference analysis to identify purine N-7 and ribose 2'-hydroxyl functional groups that are critical to catalysis. We identify six adenine N-7 groups and only one 2'-hydroxyl that, when substituted with 7-deazaadenine or 2'-deoxy analogues, respectively, reduce the RNase P catalytic rate approximately 10-fold at pH 8 and limiting concentration of magnesium. Two sites of low-level interference by phosphorothioate modification were detected in addition to the four sites of strong interference documented previously. These modification-interference results, the absolute phylogenetic conservation of these functional groups in bacterial RNase P RNA, their proximity to the substrate-phosphate in the tertiary structure of the ribozyme-substrate complex, and the importance of some of the sites for binding of catalytic magnesium all implicate these functional groups as components of the RNase P active site. Five of the 7-deazaadenine interferences are suppressed at pH 6, where the hydrolytic step is rate-limiting, or at saturating concentrations of magnesium. We propose, therefore, that these base functional groups are specifically engaged in the catalytic center of RNase P RNA, possibly by involvement in magnesium-dependent folding. One 7-deazaadenine interference and one 2'-deoxy-interference, although partially suppressed at pH 6, are not suppressed at saturating magnesium concentrations. This implicates these groups in magnesium-independent folding of the catalytic substructure of the ribozyme.     

Synthetic metallonucleases for RNA cleavage

Synthetic metallonucleases are versatile metal ion catalysts that use multiple catalytic strategies for the cleavage of RNA. Recent work in the design of more active metallonucleases combines a single metal ion with functional groups that interact with RNA, including amino acid fragments or additional metal ions. Rate enhancements by multifunctional catalysts for cleavage of simple model substrates with good leaving groups are as high as 10(6) but somewhat lower (10(5)) for real RNA. However, cleavage of RNA substrates is complicated by different binding modes and steric interactions that can interfere with catalysis. Antisense oligonucleotides, peptides and small molecules that act as RNA recognition agents increase the strength of substrate binding, but not necessarily the catalytic rate constant. In general, catalytic strategies used by synthetic metallonucleases are probably not optimized. A better grasp of the mechanism of RNA cleavage by metal ions and more effort on positioning the metal ion complex with respect to the cleavage site may lead to improved catalysts.     

The role of metal ions in RNA catalysis

Understanding the catalytic mechanisms of RNA enzymes remains an important and intriguing challenge - one that has grown in importance since the recent demonstration that the ribosome is a ribozyme. At first, it seemed that all RNA enzymes compensate for the limited chemical versatility of ribonucleotide functional groups by recruiting obligatory metal ion cofactors to carry out catalytic chemistry. Mechanistic studies of the large self-splicing and pre-tRNA-processing ribozymes continue to support this idea, yielding increasingly detailed views of RNA active sites as scaffolds for positioning catalytic metal ions. Re-evaluation of the methodologies used to distinguish catalytic and structural roles for metal ions, however, has challenged this notion in the case of the small self-cleaving RNAs. Recent studies of the small ribozymes blur the distinction between catalytic and structural roles for metal ions, and suggest that RNA nucleobases have a previously unrecognized capacity for mediating catalytic chemistry.     

Amplification, mutation and selection of catalytic RNA

RNA, by virtue of its genotypic and phenotypic properties, is a suitable substrate for molecular evolution in the laboratory. We have developed techniques for the rapid amplification, mutation and selection of catalytic RNA. By combining these techniques in an iterative fashion, we are attempting to construct an RNA-based evolving system. Such a system could be used to explore the catalytic potential of RNA.     

Helix P4 is a divalent metal ion binding site in the conserved core of the ribonuclease P ribozyme

The ribonuclease P ribozyme (RNase P RNA), like other large ribozymes, requires magnesium ions for folding and catalytic function; however, specific sites of metal ion coordination in RNase P RNA are not well defined. To identify and characterize individual nucleotide functional groups in the RNase P ribozyme that participate in catalytic function, we employed self-cleaving ribozyme-substrate conjugates that facilitate measurement of the effects of individual functional group modifications. The self-cleavage rates and pH dependence of two different ribozyme-substrate conjugates were determined and found to be similar to the single turnover kinetics of the native ribozyme. Using site-specific phosphorothioate substitutions, we provide evidence for metal ion coordination at the pro-Rp phosphate oxygen of A67, in the highly conserved helix P4, that was previously suggested by modification-interference experiments. In addition, we detect a new metal ion coordination site at the pro-Sp phosphate oxygen of A67. These findings, in combination with the proximity of A67 to the pre-tRNA cleavage site, support the conclusion that an important role of helix P4 in the RNase P ribozyme is to position divalent metal ions that are required for catalysis.     

Identification of phosphates involved in catalysis by the ribozyme RNase P RNA.

The RNA subunit of ribonuclease P (RNase P RNA) is a catalytic RNA that cleaves precursor tRNAs to generate mature tRNA 5' ends. Little is known concerning the identity and arrangement of functional groups that constitute the active site of this ribozyme. We have used an RNase P RNA-substrate conjugate that undergoes rapid, accurate, and efficient self-cleavage in vitro to probe, by phosphorothioate modification-interference, functional groups required for catalysis. We identify four phosphate oxygens where substitution by sulfur significantly reduces the catalytic rate (50-200-fold). Interference at one site was partially rescued in the presence of manganese, suggesting a direct involvement in binding divalent metal ion cofactors required for catalysis. All sites are located in conserved sequence and secondary structure, and positioned adjacent to the substrate phosphate in a tertiary structure model of the ribozyme-substrate complex. The spatial arrangement of phosphorothioate-sensitive sites in RNase P RNA was found to resemble the distribution of analogous positions in the secondary and potential tertiary structures of other large catalytic RNAs.     

Mechanistic studies on acyl-transferase ribozymes and beyond

In vitro selection has allowed the isolation of many new ribozymes that are able to catalyze an ever-widening array of chemical transformations. Mechanistic studies on these selected ribozymes have provided valuable insight into the methods that RNA can invoke to overcome different catalytic tasks. We focus on the methods employed in these mechanistic studies using the acyl-transferase family of selected ribozymes as well-studied reference systems. Chemical and biochemical techniques have been used in tandem in order to draw conclusions on the various modes of catalysis employed by the different family members. In turn, this type of mechanistic information may provide a means for the redesign and optimization of existing ribozymes or the basis for new selection systems for more powerful RNA catalysts.     

The ribosomal peptidyl transferase center: structure, function, evolution, inhibition

The ribosomal peptidyl transferase center (PTC) resides in the large ribosomal subunit and catalyzes the two principal chemical reactions of protein synthesis: peptide bond formation and peptide release. The catalytic mechanisms employed and their inhibition by antibiotics have been in the focus of molecular and structural biologists for decades. With the elucidation of atomic structures of the large ribosomal subunit at the dawn of the new millennium, these questions gained a new level of molecular significance. The crystallographic structures compellingly confirmed that peptidyl transferase is an RNA enzyme. This places the ribosome on the list of naturally occurring ribozymes that outlived the transition from the pre-biotic RNA World to contemporary biology. Biochemical, genetic and structural evidence highlight the role of the ribosome as an entropic catalyst that accelerates peptide bond formation primarily by substrate positioning. At the same time, peptide release should more strongly depend on chemical catalysis likely involving an rRNA group of the PTC. The PTC is characterized by the most pronounced accumulation of universally conserved rRNA nucleotides in the entire ribosome. Thus, it came as a surprise that recent findings revealed an unexpected high level of variation in the mode of antibiotic binding to the PTC of ribosomes from different organisms.     

The hairpin ribozyme

The hairpin ribozyme is a naturally occurring RNA that catalyzes sequence-specific cleavage and ligation of RNA. It has been the subject of extensive biochemical and structural studies, perhaps the most detailed for any catalytic RNA to date. Comparison of the structures of its constituent domains free and fully assembled demonstrates that the RNA undergoes extensive structural rearrangement. This rearrangement results in a distortion of the substrate RNA that primes it for cleavage. This ribozyme is known to achieve catalysis employing exclusively RNA functional groups. Metal ions or other catalytic cofactors are not used. Current experimental evidence points to a combination of at least four mechanistic strategies by this RNA: (1) precise substrate orientation, (2) preferential transition state binding, (3) electrostatic catalysis, and (4) general acid base catalysis.     

Artificial ribozymes and deoxyribozymes.

RNA and DNA molecules with catalytic properties have been isolated by in vitro selection from combinatorial nucleic acid libraries. A broad range of chemical reactions is catalyzed and nucleic acids can accelerate bond formation between small organic substrates. The catalytic performance of nucleic acids can be enhanced by the incorporation of additional functional groups.     

Sequence-specific cleavage of RNA in the absence of divalent metal ions by a DNAzyme incorporating imidazolyl and amino functionalities

Two modified 2′-deoxynucleoside 5′-triphosphates have been used for the in vitro selection of a modified deoxyribozyme (DNAzyme) capable of the sequence-specific cleavage of a 12 nt RNA target in the absence of divalent metal ions. The modified nucleotides, a C5-imidazolyl-modified dUTP and 3-(aminopropynyl)-7-deaza-dATP were used in place of TTP and dATP during the selection and incorporate two extra protein-like functionalities, namely, imidazolyl (histidine analogue) and primary amino (lysine analogue) into the DNAzyme. The functional groups are analogous to the catalytic Lys and His residues employed during the metal-independent cleavage of RNA by the protein enzyme RNaseA. The DNAzyme requires no divalent metal ions or other cofactors for catalysis, remains active at physiological pH and ionic strength and can recognize and cleave a 12 nt RNA substrate with sequence specificity. This is the first example of a functionalized, metal-independent DNAzyme that recognizes and cleaves an all-RNA target in a sequence-specific manner. The selected DNAzyme is two orders of magnitude more efficient in its cleavage of RNA than an unmodified DNAzyme in the absence of metal ions and represents a rate enhancement of 10⁵ compared with the uncatalysed hydrolysis of RNA.     

The Ribosomal Peptidyl Transferase Center: Structure,Function, Evolution,Inhibition

ABSTRACT

The ribosomal peptidyl transferase center (PTC) resides in the large ribosomal subunit and catalyzes the two principal chemical reactions of protein synthesis: peptide bond formation and peptide release. The catalytic mechanisms employed and their inhibition by antibiotics have been in the focus of molecular and structural biologists for decades. With the elucidation of atomic structures of the large ribosomal subunit at the dawn of the new millennium, these questions gained a new level of molecular significance. The crystallographic structures compellingly confirmed that peptidyl transferase is an RNA enzyme. This places the ribosome on the list of naturally occurring riboyzmes that outlived the transition from the pre-biotic RNA World to contemporary biology. Biochemical, genetic and structural evidence highlight the role of the ribosome as an entropic catalyst that accelerates peptide bond formation primarily by substrate positioning. At the same time, peptide release should more strongly depend on chemical catalysis likely involving an rRNA group of the PTC. The PTC is characterized by the most pronounced accumulation of universally conserved rRNA nucleotides in the entire ribosome. Thus, it came as a surprise that recent findings revealed an unexpected high level of variation in the mode of antibiotic binding to the PTC of ribosomes from different organisms.