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.     

Riboswitch effectors as protein enzyme cofactors

The recently identified glmS ribozyme revealed that RNA enzymes, like protein enzymes, are capable of using small molecules as catalytic cofactors to promote chemical reactions. Flavin mononucleotide (FMN), S-adenosyl methionine (SAM), adenosyl cobalamin (AdoCbl), and thiamine pyrophosphate (TPP) are known ligands for RNA riboswitches in the control of gene expression, but are also catalytically powerful and ubiquitous cofactors in protein enzymes. If RNA, instead of just binding these molecules, could harness the chemical potential of the cofactor, it would significantly expand the enzymatic repertoire of ribozymes. Here we review the chemistry of AdoCbl, SAM, FMN, and TPP in protein enzymology and speculate on how these cofactors might have been used by ribozymes in the prebiotic RNA World or may still find application in modern biology.     

The chemical versatility of RNA

The ability of RNA to both store genetic information and catalyse chemical reactions has led to the hypothesis that it predates DNA and proteins. While there is no doubt that RNA is capable of storing the genetic information of a primitive organism, only two classes of reactions-phosphoryl transfer and peptide bond formation-have been observed to be catalysed by RNA in nature. However, these naturally occurring ribozymes use a wide range of catalytic strategies that could be applied to other reactions. Furthermore, RNA can bind several cofactors that are used by protein enzymes to facilitate a wide variety of chemical processes. Despite its limited functional groups, these observations indicate RNA is a versatile molecule that could, in principle, catalyse the myriad reactions necessary to sustain life.     

In vitro selection of adenine-dependent hairpin ribozymes

Adenine-dependent hairpin ribozymes were isolated by in vitro selection from a degenerated hairpin ribozyme population. Two new adenine-dependent ribozymes catalyze their own reversible cleavage in the presence of free adenine. Both aptamers have Mg(2+) requirements for adenine-assisted cleavage similar to the wild-type hairpin ribozyme. Cleavage kinetics studies in the presence of various other small molecules were compared. The data suggest that adenine does not induce RNA self-cleavage in the same manner for both aptamers. In addition, investigations of pH effects on catalytic rates show that both adenine-dependent aptamers are more active in basic conditions, suggesting that they use new acid/base catalytic strategies in which adenine could be involved directly. The discovery of hairpin ribozymes dependent on adenine for their reversible self-cleavage presents considerable biochemical and evolutionary interests because we show that RNA is able to use exogenous reactive molecules to enhance its own catalytic activity. Such a mechanism may have been a means by which the ribozymes of the RNA world enlarged their chemical repertoire.     

A common speed limit for RNA-cleaving ribozymes and deoxyribozymes

It is widely believed that the reason proteins dominate biological catalysis is because polypeptides have greater chemical complexity compared with nucleic acids, and thus should have greater enzymatic power. Consistent with this hypothesis is the fact that protein enzymes typically exhibit chemical rate enhancements that are far more substantial than those achieved by natural and engineered ribozymes. To investigate the true catalytic power of nucleic acids, we determined the kinetic characteristics of 14 classes of engineered ribozymes and deoxyribozymes that accelerate RNA cleavage by internal phosphoester transfer. Half approach a maximum rate constant of approximately 1 min(-1), whereas ribonuclease A catalyzes the same reaction approximately 80,000-fold faster. Additional biochemical analyses indicate that this commonly encountered ribozyme "speed limit" coincides with the theoretical maximum rate enhancement for an enzyme that uses only two specific catalytic strategies. These results indicate that ribozymes using additional catalytic strategies could be made that promote RNA cleavage with rate enhancements that equal those of proteins.     

Focus on function: single molecule RNA enzymology

The ability of RNA to catalyze chemical reactions was first demonstrated 25 years ago with the discovery that group I introns and RNase P function as RNA enzymes (ribozymes). Several additional ribozymes were subsequently identified, most notably the ribosome, followed by intense mechanistic studies. More recently, the introduction of single molecule tools has dissected the kinetic steps of several ribozymes in unprecedented detail and has revealed surprising heterogeneity not evident from ensemble approaches. Still, many fundamental questions of how RNA enzymes work at the molecular level remain unanswered. This review surveys the current status of our understanding of RNA catalysis at the single molecule level and discusses the existing challenges and opportunities in developing suitable assays.     

Coenzymes as coribozymes

Coenzymes are small organic molecules that supply a varied set of reactive groups to protein enzymes, thereby diversifying catalysis beyond the chemistries of amino acid sidechains. As RNA structures begin with a more limited chemical diversity than proteins, it seems likely that RNA enzymes would also use functional groups from other molecules to support a complex RNA world metabolism. In fact, ribonucleotide moieties in many coenzymes have long been thought to be surviving vestiges of covalently bound coenzymes in an RNA world. The idea of coenzyme utilization by ribozymes can be explored by selection-amplification of coenzyme-binding RNAs and coenzyme-assisted ribozymes. Here, we review coenzyme-RNAs, and discuss their possible significance for RNA-mediated metabolism. In summary, a plausible route from prebiotic chemistry to ribozyme biochemistry exists for CoA, and via similar activities, likely exists for all the nucleotidyl coenzymes.     

Chimeric DNA-RNA hammerhead ribozymes have enhanced in vitro catalytic efficiency and increased stability in vivo.

Subsequent to the discovery that RNA can have site specific cleavage activity, there has been a great deal of interest in the design and testing of trans-acting catalytic RNAs as both surrogate genetic tools and as therapeutic agents. We have been developing catalytic RNAs or ribozymes with target specificity for HIV-1 RNA and have been exploring chemical synthesis as one method for their production. To this end, we have chemically synthesized and experimentally analyzed chimeric catalysts consisting of DNA in the non-enzymatic portions, and RNA in the enzymatic core of hammerhead type ribozymes. Substitutions of DNA for RNA in the various stems of a hammerhead ribozyme have been analyzed in vitro for kinetic efficiency. One of the chimeric ribozymes used in this study, which harbors 24 bases of DNA capable of base-pairing interactions with an HIV-1 gag target, but maintains RNA in the catalytic center and in stem-loop II, has a sixfold greater kcat value than the all RNA counterpart. This increased activity appears to be the direct result of enhanced product dissociation. Interestingly, a chimeric ribozyme in which stem-loop II (which divides the catalytic core) is comprised of DNA, exhibited a marked reduction in cleavage activity, suggesting that DNA in this region of the ribozyme can impart a negative effect on the catalytic function of the ribozyme. DNA-RNA chimeric ribozymes transfected by cationic liposomes into human T-lymphocytes are more stable than their all-RNA counterparts. Enhanced catalytic turnover and stability in the absence of a significant effect on Km make chimeric ribozymes favorable candidates for therapeutic agents.     

Ribozymes: recent advances in the development of RNA tools

The discovery 20 years ago that some RNA molecules, called ribozymes, are able to catalyze chemical reactions was a breakthrough in biology. Over the last two decades numerous natural RNA motifs endowed with catalytic activity have been described. They all fit within a few well-defined types that respond to a specific RNA structure. The prototype catalytic domain of each one has been engineered to generate trans-acting ribozymes that catalyze the site-specific cleavage of other RNA molecules. On the 20th anniversary of ribozyme discovery we briefly summarize the main features of the different natural catalytic RNAs. We also describe progress towards developing strategies to ensure an efficient ribozyme-based technology, dedicating special attention to the ones aimed to achieve a new generation of therapeutic agents.     

Ribozymes: the characteristics and properties of catalytic RNAs

Ribozymes, or catalytic RNAs, were discovered a little more than 15 years ago. They are found in the organelles of plants and lower eukaryotes, in amphibians, in prokaryotes, in bacteriophages, and in viroids and satellite viruses that infect plants. An example is also known of a ribozyme in hepatitis delta virus, a serious human pathogen. Additional ribozymes are bound to be found in the future, and it is tempting to regard the RNA component(s) of various ribonucleoprotein complexes as the catalytic engine, while the proteins serve as mere scaffolding--an unheard-of notion 15 years ago! In nature, ribozymes are involved in the processing of RNA precursors. However, all the characterized ribozymes have been converted, with some clever engineering, into RNA enzymes that can cleave or modify targeted RNAs (or even DNAs) without becoming altered themselves. While their success in vitro is unquestioned, ribozymes are increasingly used in vivo as valuable tools for studying and regulating gene expression. This review is intended as a brief introduction to the characteristics of the different identified ribozymes and their properties.     

A general strategy for effector-mediated control of RNA-cleaving ribozymes and DNA enzymes

A novel and general approach is described for generating versions of RNA-cleaving ribozymes (RNA enzymes) and DNAzymes (DNA enzymes), whose catalytic activity can be controlled by the binding of activator molecules. Variants of the RNA-cleaving 10-23 DNAzyme and 8-17 DNAzyme were created, whose catalysis was activated by up to approximately 35-fold by the binding of the effector adenosine. The design of such variants was possible even though the tertiary folding of the two DNAzymes is not known. Variants of the hammerhead ribozyme were constructed, to respond to the effectors ATP and flavin mononucleotide. Whereas in conventional allosteric ribozymes, effector-binding modulates the chemical step of catalysis, here, effectors exercise their effect upon the substrate-binding step, by stabilizing the enzyme-substrate complex. Because such an approach for controlling the activity of DNAzymes/ribozymes requires no prior knowledge of the enzyme's secondary or tertiary folding, this regulatory strategy should be generally applicable to any RNA-cleaving ribozyme or DNAzyme, natural or in vitro selected, provided substrate-recognition is achieved by Watson-Crick base-pairing.     

New catalytic structures from an existing ribozyme

Although protein enzymes with new catalytic activities can arise from existing scaffolds, less is known about the origin of ribozymes with new activities. Furthermore, mechanisms by which new macromolecular folds arise are not well characterized for either protein or RNA. Here we investigate how readily ribozymes with new catalytic activities and folds can arise from an existing ribozyme scaffold. Using in vitro selection, we isolated 23 distinct kinase ribozymes from a pool of sequence variants of an aminoacylase parent ribozyme. Analysis of these new kinases showed that ribozymes with new folds and biochemical activities can be found within a short mutational distance of a given ribozyme. However, the probability of finding such ribozymes increases considerably as the mutational distance from the parental ribozyme increases, indicating a need to escape the fold of the parent.     

Ribozymes: Flexible molecular devices at work

The discovery of ribozymes, RNAs with catalytic activity, revealed the extraordinary characteristic of this molecule, and corroborated the idea that RNA was the first informative polymer. The “RNA world” hypothesis asserts that the DNA/RNA/PROTEIN world arose from an earlier RNA world in which were present only RNA molecules able to perform both of the two functions performed separately by DNA and proteins in the present-day cells: the ability to transfer genetic information and to carry out catalytic activity.The catalytic properties of ribozymes are exclusively due to the capacity of RNA molecules to assume particular structures. Moreover, the structural versatility of RNA can allow to a single RNA sequence to fold in more than one structure, able to perform more than one function. In the first part of this work we will discuss the RNA plasticity, focusing on “bifunctional” ribozymes isolated by in vitro selection experiments, and on the consequences of this plasticity in the prospective of the emergence of new specific functions.The possibility that one sequence could have more than one structure/function, greatly increase the evolutionary potential of RNA, and the capacity of RNA to switch from a structure/function to another is probably one of the reasons of the evolutionary success also in modern-day cells. Naturally occurring ribozymes discovered in contemporary cells, demonstrate the crucial role that ribozymes still have in the modern protein world. In the second part of this paper we will discuss the capacity of natural ribozymes to modulate gene expression making use of their exclusive catalytic properties. Moreover, we will consider the possibility of their ancient origin.     

Nucleic acid enzymes as a novel generation of anti-gene agents

Recent molecular and cellular studies have highlighted the important role of some gene products in the cause and/or perpetuation of human pathological conditions including cancer and autoimmune diseases. The identification of such gene products has led to the development of new candidate therapies. The discovery of catalytic nucleic acid enzymes has provided researchers with a potentially important tool to block the expression of abnormal genes, provided that their sequences are known. The cleavage specificity of these compounds is determined by their hybridizing antisense arms, which anneal with the target mRNA in a complementary fashion. Nucleic acid enzymes can be delivered to cells either endogenously as gene encoding RNA enzymes (ribozymes) or exogenously as in vitro made agents. Given the progress reported during the last years, a wide range of molecular designs and chemical modifications can be introduced into these compounds, in particular the hammerhead type ribozyme. Here, we review the design, stability and the therapeutic application of these agents with the goals of illustrating relevant gene targets and signal pathways for molecular medicine. Relevant in vivo problems of the technology, mRNA repair by group I intron ribozymes and gene regulation by endogenous RNA will also be discussed.     

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.     

Applications of nucleic acid technology in the CNS

This review examines applications of nucleic acid technology in the form of catalytic nucleic acids (ribozymes and DNAzymes) and RNA interference (RNAi) in the CNS. The basic mechanism of catalytic nucleic acids and RNAi is reviewed, and potentials and problems highlighted. Recent advances in chemical modifications and delivery techniques are summarized. Applications in the CNS, including their use in primary neuronal cells, organotypic slice culture and the brain in vivo are further discussed.     

Comparative study of two ribozymes and DNA-enzyme against the same RNA target.

Two ribozymes, hammerhead ribozyme and hairpin ribozyme, and a DNA-enzyme were designed to cleave a same RNA target, the same site of the rat complement regulatory factor 512 antigen mRNA. The kinetic properties of these RNA-cleaving enzymes were measured and compared under the same conditions, using multiple turnover kinetics and competition kinetics. The catalytic efficiencies of these enzymes, and also the order of these enzymes will be discussed.