Showing papers by "Cristina Romero-López published in 2005"

Interfering with hepatitis C virus IRES activity using RNA molecules identified by a novel in vitro selection method.

Abstract: Hepatitis C virus (HCV) infection is one of the world's major health problems, and the identification of efficient HCV inhibitors is a major goal. Here we report the isolation of efficient anti-HCV internal ribosome entry site (IRES) RNA molecules identified by a new in vitro selection method. The newly developed procedure consists of two sequential steps that use distinct criteria for selection: selection for binding and selection for cleaving. The selection protocol was applied to a population of more than 10(15) variants of an anti-hepatitis C virus ribozyme covalently linked to an aptamer motif. The ribozyme was directed against positions 357 to 369 of the HCV IRES, and the cleavage substrate was a 691-nucleotide-long RNA fragment that comprises the entire HCV IRES domain. After six selection cycles, seven groups of RNA variants were identified. A representative of each group was tested for its capacity to inhibit IRES activity using in vitro translation assays. All selected RNAs promoted significant inhibition, some by as much as 95%.

Inhibition of HIV-1 replication by RNA targeted against the LTR region.

Abstract: Objective: The use of small RNA molecules able to effect gene inactivation has emerged as a powerful method of gene therapy. These small inhibitory RNAs are widely used for silencing malignant cellular and viral genes. We have assayed a series of inhibitory RNAs named catalytic antisense RNAs, consisting of a catalytic domain, hairpin or hammerhead ribozyme, and an antisense domain. The aim of the present study was to evaluate the effect of these inhibitory RNAs on HIV-1 replication. Methods: A series of expression vectors has been constructed for the intracellular synthesis of inhibitory RNAs, differing in the promoter that drives their synthesis. These inhibitory RNAs were designed to act at two possible cleavage sites in the long terminal repeat (LTR) region and the TAR domain was chosen as a target for the antisense domain. We have evaluated the effects of different inhibitory RNAs in HIV replication via changes in p24 antigen levels. Mobility shift assays have been used to check the binding capacity of inhibitory RNAs. Results: Catalytic antisense RNA designed to target the LTR region of HIV-1 inhibited viral replication in an eukaryotic cell environment by more than 90%. The conventional hairpin and hammerhead ribozymes, however, failed to inhibit viral replication. Conclusions: The data provide preliminary evidence of a new class of inhibitory RNAs that can be used to block HIV replication. The results clearly show the importance of the ex vivo antisense effect in the inhibition achieved. A good correlation was found between the in vitro binding efficiency of the inhibitor RNA to the HIV-1 LTR and the inhibition of viral replication.

Inhibition of HIV-1 replication by an improved hairpin ribozyme that includes an RNA decoy.

Abstract: An anti-Tat hairpin ribozyme and a TAR RNA decoy were combined in one molecule The chimeric molecule strongly inhibited HIV-1 replication (measured as changes in p24 levels in viral replication assays) The inhibitory action of the ribodecozyme (85%) was significantly greater than that shown by ribozyme and a non-catalytic variant carrying the functional decoy RNA domain (55% and 35%, respectively) This represents a significant improvement of the inhibitory efficiency of the ribozyme Suggesting there is an additive inhibitory effect on HIV-1 replication by the catalytic and decoy domains This strategy could be used to create new inhibitor RNAs with enhanced in vivo performance