Strong foreign promoters contribute to innate inflammatory responses induced by adenovirus transducing vectors.

E1-deleted adenovirus (FG Ad) transducing vectors are limited for use in vivo by their induction of strong innate and adaptive inflammatory responses. We have examined the contribution of the transgene cassette, particularly the foreign promoter driving transgene expression, in the induction of innate inflammation using a mouse ear model in which swelling is measured as a sensitive surrogate marker of the total innate inflammatory response. The commonly used cytomegalovirus major immediate early (CMV) promoter led to high-level swelling that was independent of transgene expression, while the Rous sarcoma virus and human ubiquitin C promoters led to intermediate levels of swelling and the Ad E1A promoter or no promoter led to equally low levels of swelling. Significant swelling was induced by a virus in which the E1A promoter directed pIX expression, supporting the possibility that activation of expression of Ad genes retained in the vector plays an important role in the inflammatory response. Taken together, our findings support the idea that strong foreign promoters likely play the limiting role in the induction of innate and adaptive immune responses that limit the duration of transgene expression after transduction by FG Ad vectors.

Distance and affinity dependence of triplex-induced recombination.

Triplex-forming oligonucleotides (TFOs) have the potential to serve as gene therapeutic agents on the basis of their ability to mediate site-specific genome modification via induced recombination. However, high-affinity triplex formation is limited to polypurine/polypyrimidine sites in duplex DNA. Because of this sequence restriction, careful analysis is needed to identify suitable TFO target sites within or near genes of interest. We report here an examination of two key parameters which influence the efficiency of TFO-induced recombination: (1) binding affinity of the TFO for the target site and (2) the distance between the target site and the mutation to be corrected. To test the influence of binding affinity, we compared induced recombination in human cell-free extracts by a series of G-rich oligonucleotides with an identical base composition and an increasing number of mismatches in the third strand binding code. As the number of mismatches increased and, therefore, binding affinity decreased, induced recombination frequency also dropped. There was an apparent threshold at an equilibrium dissociation constant (K(d)) of 1 x 10(-)(7) M. In addition, TFO chemical modification with N,N-diethylethylenediamine (DEED) internucleoside linkages to confer improved binding was found to yield increased levels of induced recombination. To test the ability of triplex formation to induce recombination at a distance, episomal targets with informative reporter genes were constructed to contain polypurine TFO target sites at varying distances from the mutations to be corrected. TFO-induced recombination in mammalian cells between a plasmid vector and a donor oligonucleotide was detected at distances ranging from 24 to 750 bp. Together, these results indicate that TFO-induced recombination requires high-affinity binding but can affect sites hundreds of base pairs away from the position of triplex formation.

E1A and E1B proteins inhibit inflammation induced by adenovirus.

Replication-defective human adenovirus (Ad) group C transducing vectors, most of which have the E1A, E1B, and E3 genes deleted, are highly inflammatory despite the fact that the parental viruses typically cause subclinical or mild infections. To investigate this paradox, the roles that the E1A, E1B, and E3 genes play in inflammation were tested by using replication-incompetent viruses carrying a deletion of the preterminal protein gene. The viruses were injected into BALB/c mouse ears, and edema was monitored as a sensitive surrogate marker of inflammation. A virus deleted for the E1A 289R (transcription activating) protein was noninflammatory, and inhibited edema induced by empty virus particles. The E1A 243R and E1B 55-kDa (p53 binding) proteins play the most important roles in inhibition of inflammation by the noninflammatory virus. The E1B 19-kDa antiapoptotic protein inhibited edema when both the E1A 243R and E1B 55-kDa proteins were expressed but strongly induced edema when only one was expressed. E3 proteins had their greatest effect on the inhibition of edema induced by the E1A 289R protein. The results support a model in which inflammation is countered through a mechanism that involves complex genetic interactions between Ad early region proteins and offer promise for the design and construction of noninflammatory Ad gene therapy vectors that are relatively easy to grow and purify.

Inefficient transduction of sheep in utero after intra-amniotic injection of retroviral producer cells.

OBJECTIVE: Our purpose was to test the hypothesis that the intra-amniotic injection of a retroviral vector producer cell line into pregnant sheep will result in retrovirus-mediated transduction and stable gene transfer to the ovine fetus. STUDY DESIGN: Thirteen pregnant ewes at various gestational ages underwent amniocentesis and injection of cells producing the retrovirus vector LIRESgeo, which is derived from Maloney murine leukemia virus and encodes Escherichia coli LacZ (beta-galactosidase) as a marker gene. Pregnant ewes and fetuses were killed, and amniotic fluid, placenta, and fetal tissues were collected and assayed for transgene expression 7 to 77 days after intraamniotic injection. In addition, serum was collected and analyzed for evidence of specific immune responses against the producer cells, and amniotic fluid was collected and analyzed for deleterious effects on producer cell viability, vector production, and vector transduction. RESULTS: Only 1 of 10 fetuses exposed to the retroviral producer cells demonstrated beta-galactosidase activity that correlated with positive immunohistochemistry for LacZ in lung, trachea, pancreas, and small intestine. However, the presence of the LacZ gene could not be confirmed by polymerase chain reaction. Thus, we could not confirm transduction after any of the injections. The retroviral producer cells survived well in amniotic fluid and continued to produce high levels of retroviral vector after intra-amniotic injection, although amniotic fluid inhibited the transducing activity of the vector in a manner dependent on gestational age. CONCLUSIONS: Intra-amniotic retroviral gene transfer with the use of these amphotropic producer cells does not result in reproducible gene transfer in the ovine fetus although amniotic fluid sustains producer cell viability and vector production. Possible reasons for the inefficient transduction are discussed.