Abstract
By using an in vitro selection procedure, we have previously isolated RNase P ribozyme variants that efficiently cleave an mRNA sequence in vitro. In this study, a ribozyme variant was used to target the overlapping region of the mRNAs encoding human cytomegalovirus (HCMV) major transcription regulatory proteins IE1 and IE2. The variant is about 90 times more efficient in cleaving the IE1/IE2 mRNA sequence in vitro than the ribozyme derived from the wild type RNase P ribozyme. Our results provide the first direct evidence that a point mutation at nucleotide position 80 of RNase P catalytic RNA from Escherichia coli (U80--> C80) increases the rate of chemical cleavage, and another mutation at nucleotide position 188 (C188--> U188) enhances substrate binding of the ribozyme. Moreover, the variant is more effective in inhibiting viral IE1 and IE2 expression and growth in HCMV-infected cells than the wild type ribozyme. A reduction of about 99% in the expression level of IE1 and IE2 and a reduction of 10,000-fold in viral growth were observed in cells that expressed the variant. In contrast, a reduction of less than 10% in IE1/IE2 expression and viral growth was observed in cells that either did not express the ribozyme or produced a catalytically inactive ribozyme mutant. Thus, engineered RNase P ribozyme variants are highly effective in inhibiting HCMV gene expression and growth. These results also demonstrate the feasibility of engineering highly effective RNase P ribozymes for gene targeting applications, including anti-HCMV gene therapy.
Highlights
Human cytomegalovirus (HCMV)1 causes significant morbidity and mortality in immunocompromised or immunologically immature individuals, including neonates and AIDS patients [1, 2]
Engineered RNase P Ribozymes Are Efficient in Cleaving the IE1/IE2 mRNA Sequence—IE1 and IE2, which are the viral immediate early (IE or ␣) gene products and share 85 aminoterminal amino acids due to alternative splicing and polyadenylation of transcripts initiating at a strong promoter-enhancer [1, 28, 29], function as the major transcriptional regulators and are required for the expression of viral early () and late (␥) genes [36, 37]
Our previous studies indicate that expression of an M1GS RNA derived from the wild type M1 RNA sequence inhibits human cytomegalovirus (HCMV) gene expression by 75– 80% and reduces viral growth by 150-fold in cultured cells [23]
Summary
Human cytomegalovirus (HCMV) causes significant morbidity and mortality in immunocompromised or immunologically immature individuals, including neonates and AIDS patients [1, 2]. Compared with conventional antisense DNA and RNA, a ribozyme may have several unique features as it can cleave its target irreversibly, and multiple copies of its substrate can be cleaved by a single ribozyme molecule Both hammerhead and hairpin ribozymes have been shown to cleave viral mRNA sequences and inhibit viral replication in cells infected with human viruses, whereas a ribozyme derived from a group I intron has been used to repair mutant mRNAs in cells [5,6,7,8]. Studies on substrate recognition by M1 RNA and RNase P have led to the development of a general strategy in which M1 RNA and RNase P can be used as gene targeting tools to cleave any specific mRNA sequences [18]. In order to develop this ribozyme for practical use both as a research tool and as a therapeutic agent for gene-targeting applications, further studies are needed to improve M1GS RNA catalytic efficiency in vitro and its efficacy in vivo. By using an in vitro selection procedure, we have recently isolated M1GS ribozyme variants that are more efficient in cleaving a specific mRNA sequence (i.e. TK mRNA) than that derived from the wild type M1 RNA [26]
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