Abstract

Live attenuated human immunodeficiency virus type 1 (HIV-1) vaccines are considered unsafe because more quickly replicating pathogenic virus variants may evolve after vaccination. As an alternative vaccine approach, we have previously presented a doxycycline (dox)-dependent HIV-1 variant that was constructed by incorporating the tetracycline-inducible gene expression system (Tet-On system) into the viral genome. Replication of this HIV-rtTA variant is driven by the dox-inducible transcriptional activator rtTA and can be switched on and off at will. A large scale evolution study was performed to test the genetic stability of this conditional live vaccine candidate. In several long term cultures, we selected for HIV-rtTA variants that no longer required dox for replication. These evolved variants acquired a typical amino acid substitution either at position 19 or 37 in the rtTA protein. Both mutations caused rtTA activity and viral replication in the absence of dox. We designed a novel rtTA variant with a higher genetic barrier toward these undesired evolutionary routes. The corresponding HIV-rtTA variant did not lose dox control in long term cultures, demonstrating its improved genetic stability.

Highlights

  • The potential use of this dox-dependent HIV-rtTA virus as a vaccine raises new safety questions concerning the genetic stability of the introduced Tet-On system

  • We recently reported that long term replication of this virus resulted in rearrangement of the tetO elements and amino acid substitutions in the rtTA protein that significantly improve viral replication without losing dox control (20 –22)

  • To test the safety of this dox-dependent HIV-rtTA vaccine candidate, we analyzed the genetic stability of the imposed dox control in long term evolution experiments

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Summary

Introduction

The potential use of this dox-dependent HIV-rtTA virus as a vaccine raises new safety questions concerning the genetic stability of the introduced Tet-On system. We observed the loss of dox control in several cultures, which in all cases resulted from a typical amino acid substitution either at position 19 or 37 in the rtTA protein.

Results
Conclusion

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