Glucocorticoids inhibit developmental stage-specific osteoblast cell cycle. Dissociation of cyclin A-cyclin-dependent kinase 2 from E2F4-p130 complexes.

Unique cell cycle control is instituted in confluent osteoblast cultures, driving growth to high density. The postconfluent dividing cells share features with cells that normally exit the cell cycle; p27(kip1) is increased, p21(waf1/cip1) is decreased, free E2F DNA binding activity is reduced, and E2F4 is primarily nuclear. E2F4-p130 becomes the predominant E2F-pocket complex formed on E2F sites, but, unlike the complex that typifies resting cells, cyclin A and CDK2 are also present. Administration of dexamethasone at this, but not earlier stages, results in reduction of cyclin A and CDK2 levels with a parallel decrease in the associated kinase activity, dissociation of cyclin A-CDK2 from the E2F4-p130 complexes, and inhibition of G(1)/S transition. The glucocorticoid-mediated cell cycle attenuation is also accompanied by, but not attributable to, increased p27(kip1) and decreased p21(waf1/cip1) levels. The attenuation of osteoblast growth to high density by dexamethasone is associated with severe impairment of mineralized extracellular matrix formation, unless treatment commences in cultures that have already grown to high density. Both the antimitotic and the antiphenotypic effects are reversible, and both are antagonized by RU486. Thus, glucocorticoids induce premature attenuation of the osteoblast cell cycle, possibly contributing to the osteoporosis induced by these drugs in vivo.

Reciprocal enhancement of gene transfer by combinatorial adenovirus transduction and plasmid DNA transfection in vitro and in vivo.

The addition of replication-defective recombinant adenovirus to plasmid transfection (termed here "adenofection") has been shown to increase plasmid transgene expression in limited studies. Similarly, the addition of cationic liposomes to adenovirus increases adenovirus-mediated gene transduction (termed here "lipoduction"). Here we demonstrate that adenofection was effective at enhancing transgene expression when used in conjunction with a variety of different transfection reagents, including a monocationic liposome, a polycationic liposome, an activated dendrimer, a large multilamellar liposomal vesicle, and a protein/amphipathic polyamine complex. The effect was seen regardless of the cellular expression of the adenovirus receptor, CAR, in three different human cancer cell lines derived from rhabdomyosarcomas (Rh18 and RD, CAR-) and cervical carcinoma (HeLa, CAR+). The protein/amphipathic polyamine complex showed an adenofection effect but did not show a lipoduction effect, consistent with different mechanisms of action for adenofection and lipoduction. Using dual-color flow cytometric analysis of cells transfected with a plasmid expressing the enhanced blue fluorescent protein (pEBFP) and a recombinant adenovirus expressing the green fluorescent protein (Ad5-GFP), we demonstrate that adenofection works primarily by increasing gene expression within a cell, whereas lipoduction increases the percentage of cells expressing the transgene. In addition, these studies show that both adenofection and lipoduction can occur simultaneously, further increasing gene transfer. The combination of lipofection and adenovirus transduction also prolonged the duration of transient gene expression and was generally no more toxic than lipofection alone. The enhancement of gene transfer was also seen after injection of complexes directly into subcutaneous human xenograft tumors. Therefore, more effective gene transfer in vitro and in vivo of either plasmid DNA, adenovirus DNA, or both can be achieved by combining liposomal transfection with adenoviral transduction.

Regulated expression of the diphtheria toxin A chain by a tumor-specific chimeric transcription factor results in selective toxicity for alveolar rhabdomyosarcoma cells.

Alveolar rhabdomyosarcoma (ARMS) cells often harbor one of two unique chromosomal translocations, either t(2;13)(q35;q14) or t(1;13)(p36;q14). The chimeric proteins expressed from these rearrangements, PAX3-FKHR and PAX7-FKHR, respectively, are potent transcriptional activators. In an effort to exploit these unique cancer-specific molecules to achieve ARMS-specific expression of therapeutic genes, we have studied the expression of a minimal promoter linked to six copies of a PAX3 DNA binding site, prs-9. In transient transfections, expression of the prs-9-regulated reporter genes was approximately 250-fold higher than expression of genes lacking the prs-9 sequences in cell lines derived from ARMS, but remained at or below baseline levels in other cells. High expression of these prs-9-regulated genes was also observed in a cancer cell line that lacks t(2;13) but was stably transfected with a plasmid expressing PAX3-FKHR. Transfection of a plasmid containing the diphtheria toxin A chain gene regulated by prs-9 sequences (pA3-6PED) was selectively cytotoxic for PAX3-FKHR-expressing cells. This was shown by inhibition of gene expression from cotransfected plasmids and by direct cytotoxicity after transfected cells were isolated by cell sorting. Gene transfer of pA3-6PED may thus be useful as a cancer-specific treatment strategy for t(2;13)- or t(1;13)-positive ARMS. Furthermore, gene transfer of fusion protein-regulated toxin genes might also be applied to the treatment of other cancers that harbor cancer-specific chromosomal translocations involving transcription factors.