Design and analysis of hammerhead ribozyme activity against an artificial gene target (original) (raw)

Can hammerhead ribozymes be efficient tools to inactivate gene function

Nucleic Acids Research, 1994

In order to improve hammerhead ribozyme efficiency and specificity, we have analyzed, both in vitro and in vivo, the activity of a series of ribozyme/substrate combinations that have the same target sequence but differ in the length of the ribozyme/substrate duplex or in their structure, i.e., the total length of the RNA. In vitro, we have found that optimal kcatlKm (at 370C) is obtained when the ribozyme/substrate duplex has a length of 12 bases, which according to the base composition represents a calculated free energy of binding of -16 kcal/mol. We discuss the importance of this value for ribozyme specificity and present strategies that may improve it. Increasing the length of the duplex from 14 to 17 bases (from -19 to -26 kcal/mol) produces a reduced ribozyme activity which is probably due to a slower rate of product dissociation. In addition, inclusion of either the substrate or the ribozyme in a long transcript produces a reduction (10 fold) of the kcat/Km, probably because of a different accessibility of the target sequence. In vivo, the activity of the trans-acting ribozyme was extremely low and detected in only one case: with a ribozyme/substrate duplex length of 13 bases and with both ribozyme and substrate embedded in short RNAs expressed at a very high level. The similarity of the results obtained in vitro and in vivo indicates that it is possible to use an in vitro system to optimize ribozymes which are to be used in vivo. Satisfactory results were obtained in vivo only with cisacting ribozymes. Altogether these results suggest that the ribozyme/substrate hybridization step is the limiting step in vivo and therefore it is not clear if ribozymes represent an improvement over antisense RNAs.

Recent developments in the hammerhead ribozyme field

Nucleic Acids Research, 1998

Developments in the hammerhead ribozyme field during the last two years are reviewed here. New results on the specificity of this ribozyme, the mechanism of its action and on the question of metal ion involvement in the cleavage reaction are discussed. To demonstrate the potential of ribozyme technology examples of the application of this ribozyme for the inhibition of gene expression in cell culture, in animals, as well as in plant models are presented. Particular emphasis is given to critical steps in the approach, including RNA site selection, delivery, vector development and cassette construction.

The Structure, Function and Application of the Hammerhead Ribozyme

European Journal of Biochemistry, 1997

The hammerhead ribozyme is one of the smallest ribozymes known and catalyses the site-specific hydrolysis of a phosphodiester bond. This small ribozyme is of interest for two reasons. It offers a convenient system to study the structure/function relationship of a nucleotide sequence, and is a potential vehicle for the inhibition of gene expression. The first part of the review summarizes the sequence requirements of the hammerhead, its three-dimensional structure and the proposed mechanism, in addition to ribozyme specificity and turnover. The second part of the review focuses on the in vivo application of the ribozyme. The processes involved in designing ribozymes for efficient cleavage in vivo are described, together with possible delivery strategies.

Synthetic Hammerhead Ribozymes as Tools in Gene Expression

Critical Reviews in Oral Biology & Medicine, 2001

The assessment of genetic controls for sequential developmental processes such as tooth formation and biomineralization is often difficult in transgenic "knockout" models, where phenotypes reflect only the permanent eradication of a gene, and reveal little about the dynamic range of expression for the gene(s) involved. One promising strategy to overcome this problem is through the use of ribozymes, a class of metalloenzymes made entirely of ribonucleic acid (RNA), that are capable of cleaving other RNA molecules in a catalytic fashion. Their activity can be targeted against specific mRNAs by selection of unique sequences flanking a conserved catalytic motif. In synthetic ribozymes, specificity, stability, and cell permeability can be dramatically improved by the incorporation of chemically modified ribonucleotides. This review focuses on the design and application of hammerhead ribozymes, the best-known and most widely used class of RNA-based enzymes. So far, except for a ...

Synthetic Hammerhead Ribozymes as Therapeutic Tools to Control Disease Genes

Current Gene Therapy, 2005

Ribozymes are RNA molecules that have the ability to catalyse the cleavage and formation of covalent bonds in RNA strands at specific sites. The "hammerhead" motif, approximately 30-nucleotide long, is the smallest endonucleolytic cis-acting ribozyme structure found in natural circular RNAs of some plant viroids. Hammerhead ribozymes became appealing when it was shown that it is possible to produce transacting ribozymes directed against RNA sequences of interest. Since then, gene-tailored ribozymes have been designed, produced and given to cells to knock down the expression of specific genes. At present, this technology has advanced so much that many hammerhead ribozymes are being used in clinical trials. With this work we would provide some guidelines to design efficient transacting hammerhead ribozymes as well as review the recent results obtained with them as gene therapy tools.

Redesigned and chemically-modified hammerhead ribozymes with improved activity and serum stability

BMC chemical biology, 2004

BACKGROUND: Hammerhead ribozymes are RNA-based molecules which bind and cleave other RNAs specifically. As such they have potential as laboratory reagents, diagnostics and therapeutics. Despite having been extensively studied for 15 years or so, their wide application is hampered by their instability in biological media, and by the poor translation of cleavage studies on short substrates to long RNA molecules. This work describes a systematic study aimed at addressing these two issues. RESULTS: A series of hammerhead ribozyme derivatives, varying in their hybridising arm length and size of helix II, were tested in vitro for cleavage of RNA derived from the carbamoyl phosphate synthetase II gene of Plasmodium falciparum. Against a 550-nt transcript the most efficient (t1/2 = 26 seconds) was a miniribozyme with helix II reduced to a single G-C base pair and with twelve nucleotides in each hybridising arm. Miniribozymes of this general design were targeted to three further sites, and t...

A structural analysis of in vitro catalytic activities of hammerhead ribozymes

BMC Bioinformatics, 2007

Background Ribozymes are small catalytic RNAs that possess the dual functions of sequence-specific RNA recognition and site-specific cleavage. Trans-cleaving ribozymes can inhibit translation of genes at the messenger RNA (mRNA) level in both eukaryotic and prokaryotic systems and are thus useful tools for studies of gene function. However, identification of target sites for efficient cleavage poses a challenge. Here, we have considered a number of structural and thermodynamic parameters that can affect the efficiency of target cleavage, in an attempt to identify rules for the selection of functional ribozymes. Results We employed the Sfold program for RNA secondary structure prediction, to account for the likely population of target structures that co-exist in dynamic equilibrium for a specific mRNA molecule. We designed and prepared 15 hammerhead ribozymes to target GUC cleavage sites in the mRNA of the breast cancer resistance protein (BCRP). These ribozymes were tested, and thei...

Ribozymes: the characteristics and properties of catalytic RNAs

FEMS Microbiology Reviews, 1999

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. ß Contents 0168-6445 / 99 / $20.00 ß 1999 Federation of European Microbiological Societies. Published by Elsevier Science B.V. All rights reserved. PII: S 0 1 6 8 -6 4 4 5 ( 9 9 ) 0 0 0 0 7 -8 * Tel.

Hammerhead ribozyme engineering

Current Opinion in Structural Biology, 1996

Of all the catalytic RNAs the hammerhead ribozyme is the most chemically modified and structurally studied. Such studies have resulted in improvements in the nuclease resistance of ribozymes, reductions in their size, and improvements in their catalytic efficiency. These improvements have facilitated the use of ribozymes for therapeutic applications, and have allowed us to study how the three-dimensional structure of the enzyme and its array of functional groups interact to create a catalytic site where a phosphodiester bond is cleaved.

Chemical Modification of Hammerhead Ribozymes

Journal of biological …, 1995

A systematic study of selectively modified, 36-mer hammerhead ribozymes has resulted in the identification of a generic, catalytically active and nuclease stable ribozyme motif containing 5 ribose residues, 29 -30 2-O-Me nucleotides, 1-2 other 2-modified nucleotides at positions U4 and U7, and a 3-3-linked nucleotide "cap." Eight 2-modified uridine residues were introduced at positions U4 and/or U7. From the resulting set of ribozymes, several have almost wild-type catalytic activity and significantly improved stability. Specifically, ribozymes containing 2-NH 2 substitutions at U4 and U7, or 2-C-allyl substitutions at U4, retain most of their catalytic activity when compared to the all-RNA parent. Their serum half-lives were 5-8 h in a variety of biological fluids, including human serum, while the all-RNA parent ribozyme exhibits a stability half-life of only ϳ0.1 min. The addition of a 3-3-linked nucleotide "cap" (inverted T) did not affect catalysis but increased the serum half-lives of these two ribozymes to >260 h at nanomolar concentrations. This represents an overall increase in stability/activity of 53,000 -80,000-fold compared to the all-RNA parent ribozyme.