Replication-competent retrovirus vectors based on murine leukemia virus (MLV) have been shown to effectively transfer therapeutic genes over multiple serial infections in cell culture and through solid tumors in vivo with a high degree of genomic stability. While simple retroviruses possess a natural tumor selectivity in that they can transduce only actively dividing cells, additional tumor-targeting strategies would nevertheless be advantageous, since tumor cells are not the only actively dividing cells. In this study, we used the promiscuous murine cytomegalovirus promoter, a chimeric regulatory sequence consisting of the hepatitis B virus enhancer II and the human ␣1-antitrypsin (EII-Pa1AT) promoter, and a synthetic regulatory sequence consisting of a series of T-cell factor binding sites named the CTP4 promoter to generate replicating MLV vectors, whereby the last two are transcriptionally restricted to liver-and -catenin/T-cell factor-deregulated cells, respectively. When the heterologous promoters were used to replace almost the entire MLV U3 region, including the MLV TATA box, vector replication was inefficient since nascent virus particle production from infected cells was greatly decreased. Fusion of the heterologous promoters lacking the TATA box to the MLV TATA box, however, generated vectors which replicated with almost-wild-type kinetics throughout permissive cells while exhibiting low or negligible spread in nonpermissive cells. The genomic stability of the vectors was shown to be comparable to that of a similar vector containing wild-type MLV long terminal repeats, and tropism analysis over repeated infection cycles showed that the targeted vectors retained their original specificity.Because simple retroviruses can transduce only actively dividing cells (3,26,36,44), their use in cancer gene therapy has been extensively investigated, and over the last decade, numerous preclinical in vivo studies and clinical trials have been carried out using replication-defective retroviral (RDR) vectors (13). Although promising results have been obtained with animal models, therapeutic benefit in clinical settings has remained elusive, especially for cancer gene therapy, since the infection efficiency of solid tumors is too low (34). Of late, therefore, the use of replication-competent retroviral (RCR) vectors has been advocated, and it has been demonstrated by various groups that these are much more efficacious than their RDR counterparts (15, 23, 26-29, 40-42, 45). Mitotic cells, of course, are not unique to tumors, and although it may be expected that RCR vectors would not replicate efficiently outside of the immune-privileged environment of a solid tumor in a healthy individual, the possibility of spread occurring in dividing cells outside of the tumor mass must nevertheless be considered (7,33,35). Moreover, not least due to recent events demonstrating that retroviral vectors are capable, albeit in rare circumstances, of inducing oncogenesis in humans (19,30), safety is a primary concern in retroviral vect...
