Design of modified U1i molecules against HIV-1 RNA.

Several gene therapeutic approaches have been proposed to add to current antiretroviral therapy against HIV-1. U1 interference (U1i) is a promising new gene therapy tool that targets mRNAs with modified U1 snRNAs. For efficient inhibition, the 3'-terminal exon of pre-mRNAs must be recognized by the modified U1 snRNA. Subsequent interaction between the U1-associated 70K protein and poly(A) polymerase leads to inhibition of polyadenylation and consequently degradation of the pre-mRNA. We designed 14 new U1i inhibitors against HIV-1 mRNA regions that are 100% complementary to at least 70% of HIV-1 sequences listed in the HIV database. All U1i inhibitors were tested transiently in HIV-1 production assays as well as luciferase reporter experiments and three candidates were examined further in stably lentivirus-transduced T cell lines. We identified U1i-J that targets the region encoding the NF-κB binding sites as the most effective inhibitor that substantially reduced viral protein expression. The potency of J is determined in part by the presence of a duplicated target within the HIV-1 mRNA. The stably transduced SupT1 T cells were challenged with HIV-1 but no antiviral effect was detected. U1i inhibitors can be potent suppressors of HIV-1 production in transient assays but further optimization of this antiviral approach is needed.

Requirements for gene silencing mediated by U1 snRNA binding to a target sequence.

U1 interference (U1i) is a novel method to block gene expression. U1i requires expression of a 5'-end-mutated U1 snRNA designed to base pair to the 3'-terminal exon of the target gene's pre-mRNA that leads to inhibition of polyadenylation. Here, we show U1i is robust (> or =95%) and a 10-nt target length is sufficient for good silencing. Surprisingly, longer U1 snRNAs, which could increase annealing to the target, fail to improve silencing. Extensive mutagenesis of the 10-bp U1 snRNA:target duplex shows that any single mismatch different from GU at positions 3-8, destroys silencing. However, mismatches within the other positions give partial silencing, suggesting that off-target inhibition could occur. The specificity of U1i may be enhanced, however, by the fact that silencing is impaired by RNA secondary structure or by splicing factors binding nearby, the latter mediated by Arginine-Serine (RS) domains. U1i inhibition can be reconstituted in vivo by tethering of RS domains of U1-70K and U2AF65. These results help to: (i) define good target sites for U1i; (ii) identify and understand natural cellular examples of U1i; (iii) clarify the contribution of hydrogen bonding to U1i and to U1 snRNP binding to 5' splice sites and (iv) understand the mechanism of U1i.