Engineering a mini-herpesvirus as a general strategy to transduce up to 180 kb of functional self-replicating human mini-chromosomes.

The engineering of therapeutic human artificial episomal chromosomes, HAECs, requires the development of strategies to deliver large functional self-replicating extrachromosomal DNA in target cells. Members of the herpesviral family are among the largest episomal double-stranded DNA viruses. As model systems of this family of endemic infectious agents, vectors derived from the human herpes 4 Epstein-Barr virus (EBV) were constructed which transferred up to 180 kb of DNA packaged as infectious virions. Such a transduction strategy was based on a non-oncogenic helper-dependent mini-EBV carrying minimal cis elements for latent replication and virus production. After exposure of human B lymphoma and lymphoblastoid cells to mini-EBVs transducing lacZ and human HPRT minigenes, stable cell transformants were selected which carried the delivered multimeric linear DNAs as circular episomes up to 160-180 kb in size. Following transduction of Lesch-Nyhan disease cells with a mini-EBV/HPRT, normal human HPRT function was restored in cells carrying large episomal HPRT minigenes. Direct visualization of the therapeutic mini-EBV by fluorescent in situ hybridization (FISH) on metaphase and interphase nuclei indicated that 99% (556/563) of the transduced mini-EBV DNA was episomal with an average copy number of one to two per nucleus. This system should allow the delivery of large genes in common diseases such as hemophilia A and codelivery of multiple genes in cells from polygenic diseases such as cancer. The extrachromosomal mini-EBV-based strategy offers an alternative to integrative or non-replicating gene therapy infectious vectors, which may be generally applicable to other herpesviruses characterized by different tropisms.