RNA interference (RNAi) is a widely used gene suppression tool that holds great promise as a novel antiviral approach. However, for error-prone viruses including human immunodeficiency virus type 1(HIV-1), a combinatorial approach against multiple conserved sequences is required to prevent the emergence of RNAi-resistant escape viruses. Previously, we constructed extended short hairpin RNAs (e-shRNAs) that encode two potent small interfering RNAs (siRNAs) (e2-shRNAs). We showed that a minimal hairpin stem length of 43 base pairs (bp) is needed to obtain two functional siRNAs. In this study, we elaborated on the e2-shRNA design to make e-shRNAs encoding three or four antiviral siRNAs. We demonstrate that siRNA production and the antiviral effect is optimal for e3-shRNA of 66 bp. Further extension of the hairpin stem results in a loss of RNAi activity. The same was observed for long hairpin RNAs (lhRNAs) that target consecutive HIV-1 sequences. Importantly, we show that HIV-1 replication is durably inhibited in T cells stably transduced with a lentiviral vector containing the e3-shRNA expression cassette. These results show that e-shRNAs can be used as a combinatorial RNAi approach to target error-prone viruses.
RNAi-based gene therapy is a powerful approach to treat viral infections because of its high efficiency and sequence specificity. The HIV-1-based lentiviral vector system is suitable for the delivery of RNAi inducers to HIV-1 susceptible cells due to its ability to transduce nondividing cells, including hematopoietic stem cells, and its ability for stable transgene delivery into the host cell genome. However, the presence of anti-HIV short hairpin RNA (shRNA) and microRNA (miRNA) cassettes can negatively affect the lentiviral vector titers. We show that shRNAs, which target the vector genomic RNA, strongly reduced lentiviral vector titers but inhibition of the RNAi pathway via saturation could rescue vector production. The presence of miRNAs in the vector RNA genome (sense orientation) results in a minor titer reduction due to Drosha processing. A major cause for titer reduction of miRNA vectors is due to incompatibility of the cytomegalovirus promoter with the lentiviral vector system. Replacement of this promoter with an inducible promoter resulted in an almost complete restoration of the vector titer. We also showed that antisense poly(A) signal sequences can have a dramatic effect on the vector titer. These results show that not all sequences are compatible with the lentiviral vector system and that care should be taken in the design of lentiviral vectors encoding RNAi inducers.
RNA interference (RNAi)-based gene therapy for the treatment of HIV-1 infection provides a novel antiviral approach. For delivery of RNAi inducers to CD4+ T cells or CD34+ blood stem cells, lentiviral vectors are attractive because of their ability to transduce nondividing cells. In addition, lentiviral vectors allow stable transgene expression by inserting their cargo into the host cell genome. However, use of the HIV-1-based lentiviral vector also creates specific problems. The RNAi inducers can target HIV-1 sequences in the genomic RNA of the lentiviral vector. As the RNAi-inducing cassette contains palindromic sequences, the lentiviral vector RNA genome will have a perfect target sequence for the expressed RNAi inducer. Vectors encoding microRNAs face the putative problem that the vector RNA genome can be inactivated by Drosha processing. Here, we describe the design of lentiviral vectors with single or multiple RNAi-inducing antiviral cassettes. The possibility of titer reduction and some effective countermeasures are also presented.
RNA interference or RNAi-based gene therapy for the treatment of HIV-1 infection has recently emerged as a highly effective antiviral approach. The lentiviral vector system is a good candidate for the expression of antiviral short hairpin RNAs (shRNA) in HIV-susceptible cells. However, this strategy can give rise to vector problems because the anti-HIV shRNAs can also target the HIV-based lentiviral vector system. In addition, there may be self-targeting of the shRNA-encoding sequences within the vector RNA genome in the producer cell. The insertion of microRNA (miRNA) cassettes in the vector may introduce Drosha cleavage sites that will also result in the destruction of the vector genome during the production and/or the transduction process. Here, we describe possible solutions to these lentiviral-RNAi problems. We also describe a strategy for multiple shRNA expression to establish a combinatorial RNAi therapy.
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