Retroviral vectors containing a variant dihydrofolate reductase gene for drug protection and in vivo selection of hematopoietic cells. (1/71)

Transfer of drug resistance genes to hematopoietic cells is being studied as a means to protect against the myelosuppression associated with cancer chemotherapy and as a strategy for the in vivo selection and amplification of genetically modified cells. The goal of this study was to test if retroviral-mediated gene transfer of a dihydrofolate reductase (DHFR) variant (L22Y) could be used for in vivo selection of transduced myeloid cells and to determine what proportion of transduced cells was required for protection from myelosuppression. Based on previous work suggesting that selection with antifolates may also require inhibition of nucleoside transport mechanisms, mice transplanted with DHFR-transduced bone marrow cells were treated with trimetrexate and the nucleoside transport inhibitor prodrug nitrobenzylmercaptopurine riboside phosphate. In vivo selection of transduced myeloid progenitors was seen in the bone marrow and in circulating mature peripheral blood cells following drug treatment. These results show that the novel combination of the L22Y-DHFR cDNA, trimetrexate and nitrobenzylmercaptopurine riboside phosphate can be used to select for transduced myeloid cells, and that this approach warrants further study in large animal models. A bicistronic vector containing a human CD24 reporter gene was used to determine the number of modified cells needed for chemoprotection. Partial protection from neutropenia was seen when greater than 10% of myeloid cells expressed the vector, and high levels of protection were obtained when the proportion exceeded 30%. These results suggest that gene transfer may be useful for myeloprotection in certain pediatric cancers, but that more efficient gene transfer will be required to apply this approach to adult cancer patients.  (+info)

Expression of simple epithelial cytokeratins in mouse epidermal keratinocytes harboring Harvey ras gene alterations. (2/71)

Activation of a Harvey ras (H-ras) protooncogene is a frequent event associated with mouse epidermal carcinogenesis. We report that the transfection of a human H-ras oncogene into an immortalized mouse epidermal cell line (MCA3D) induces the anomalous expression of cytokeratins (CKs) 8 and 18 characteristic of simple epithelia. The comparison of various transfectant cell clones indicated a direct correlation between the levels of CK8 expression and the mutated H-ras p21s. The expression of simple epithelial CKs is also described in cell lines derived from mouse skin carcinomas (HaCa4, CarC) and in keratinocytes transformed in vitro by a chemical carcinogen (PDV, PDVC57), all of which contain altered H-ras genes. The induction of CK8 and CK18 occurs at the mRNA level and, although both CK8 and CK18 mRNAs are expressed, CK18 protein does not accumulate whereas CK8 is incorporated into intermediate filaments. Immunofluorescence studies show that the pattern of CK8 protein expression is heterogeneous; some cells express very low amounts of CK8, whereas others synthesize relatively high levels of this protein. However, selection of strongly CK8-positive cells was found in one case where a more malignant population of cells (PDVC57) was derived by tumor transplantation of PDV. Our results suggest that activation of a H-ras gene can alter the normal differentiation program of epidermal cells and that the ability to synthesize CK8 and CK18 could be related to tumor progression.  (+info)

The tumor promoter 12-O-tetradecanoylphorbol-13-acetate and the ras oncogene modulate expression and phosphorylation of gap junction proteins. (3/71)

Gap junctional intercellular communication is inhibited in response to tumor promoters and oncogene transformation, suggesting that loss of this function is an important step in tumor formation. To elucidate the molecular mechanisms responsible for this inhibition, we examined the expression of gap junction proteins and mRNA in mouse primary keratinocytes after treatment with the tumor promoter 12-O-tetradecanoylphorbol-13-acetate (TPA) and/or ras transformation. During normal cell growth, keratinocytes expression the alpha 1 (connexin 43) and beta 2 (connexin 26) proteins. Within 5 min of TPA treatment, the alpha 1 protein became rapidly phosphorylated on serine residues and its expression was dramatically reduced by 24 h. The beta 2 protein, after an initial increase in expression, was also significantly reduced 24 h after treatment with TPA. ras transformation caused changes similar to those induced by TPA. The alpha 1 protein underwent an increase in serine phosphorylation, although its expression declined only slightly, while beta 2 expression was greatly reduced. The effects of TPA and ras on alpha 1 expression were additive; treatment of ras-transformed cells with TPA resulted in increased alpha 1 phosphorylation, with greatly decreased protein levels, much lower than those generated by either agent alone. These data provide a likely explanation for the similar and synergistic inhibition of gap junctional intercellular communication by phorbol esters and ras.  (+info)

Retroviral recombination during reverse transcription. (4/71)

After mixed infection, up to half of related retroviruses are recombinants. During infection, retroviral RNA genomes are first converted to complementary DNA (cDNA) and then to double-stranded DNA. Thus recombination could occur during reverse transcription, by RNA template switching, or after reverse transcription, by breakage and reunion of DNA. It has not been possible to distinguish between these two potential mechanisms of recombination because both single-stranded cDNA and double-stranded proviral DNA exist in infected cells during the eclipse period. Therefore we have analyzed for recombinant molecules among cDNA products transcribed in vitro from RNA of disrupted virions. Since recombinants from allelic parents can only be distinguished from parental genomes by point mutations, we have examined the cDNAs from virions with distinct genetic structures for recombinant-specific size and sequence markers. The parents share a common internal allele that allows homology-directed recombination, but each contains specific flanking sequences. One parent is a synthetically altered Harvey murine sarcoma virus RNA that lacks a retroviral 3' terminus but carries a Moloney murine retrovirus-derived envelope gene (env) fragment 3' of its transforming ras gene. The other parent is intact Moloney virus. Using a Harvey-specific 5' primer and a Moloney-specific 3' primer, we have found recombinant cDNAs with the polymerase chain reaction, proving directly that retroviruses can recombine during reverse transcription unassisted by cellular enzymes, probably by template switching during cDNA synthesis. The recombinants that were obtained in vitro were identical with those obtained in parallel experiments in vivo.  (+info)

No evidence of clonal dominance in primates up to 4 years following transplantation of multidrug resistance 1 retrovirally transduced long-term repopulating cells. (5/71)

Previous murine studies have suggested that retroviral multidrug resistance 1 (MDR1) gene transfer may be associated with a myeloproliferative disorder. Analyses at a clonal level and prolonged long-term follow-up in a model with more direct relevance to human biology were lacking. In this study, we analyzed the contribution of individual CD34-selected peripheral blood progenitor cells to long-term rhesus macaque hematopoiesis after transduction with a retroviral vector either expressing the multidrug resistance 1 gene (HaMDR1 vector) or expressing the neomycin resistance (NeoR) gene (G1Na vector). We found a total of 122 contributing clones from 8 weeks up to 4 years after transplantation. One hundred two clones contained the G1Na vector, whereas only 20 clones contained the HaMDR1 vector. Here, we show for the first time real-time polymerase chain reaction based quantification of individual transduced cell clones constituting 0.0008% +/- 0.0003% to 0.0041% +/- 0.00032% of primate peripheral blood cells. No clonal dominance was observed. Disclosure of potential conflicts of interest is found at the end of this article.  (+info)

In vitro biological activities of the E6 and E7 genes vary among human papillomaviruses of different oncogenic potential. (6/71)

Human papillomavirus type 16 (HPV-16) and HPV-18 are often detected in cervical carcinomas, while HPV-6, although frequently present in benign genital lesions, is only rarely present in cancers of the cervix. Therefore, infections with HPV-16 and HPV-18 are considered high risk and infection with HPV-6 is considered low risk. We found, by using a heterologous promoter system, that expression of the E7 transforming protein differs between high- and low-risk HPVs. In high-risk HPV-16, E7 is expressed from constructs containing the complete upstream E6 open reading frame. In contrast, HPV-6 E7 was efficiently translated only when E6 was deleted. By using clones in which the coding regions of HPV-6, HPV-16, and HPV-18 E7s were preceded by identical leader sequences, we found that the ability of the E7 gene products to induce anchorage-independent growth in rodent fibroblasts correlated directly with the oncogenic association of the HPV types. By using an immortalization assay of normal human keratinocytes that requires complementation of E6 and E7, we found that both E6 and E7 of HPV-18 could complement the corresponding gene from HPV-16. However, neither E6 nor E7 from HPV-6 was able to substitute for the corresponding gene of HPV-16 or HPV-18. Our results suggest that multiple factors, including lower intrinsic biological activity of E6 and E7 and differences in the regulation of their expression, account for the low activity of HPV-6, in comparison with HPV-16 and HPV-18, in in vitro assays. These same factors may, in part, account for the apparent difference in oncogenic potential between these viruses.  (+info)

Retroviral transfer of a chimeric multidrug resistance-adenosine deaminase gene. (7/71)

A fusion between a selectable multidrug resistance (MDR1) cDNA and an adenosine deaminase (ADA) cDNA concomitantly confers multidrug resistance and ADA activity on transfected cells. We have produced a Harvey murine sarcoma virus-derived, replication-defective, recombinant retrovirus to transduce this chimeric MDR-ADA gene efficiently into a great variety of cells. Infection with the MDR-ADA retrovirus conferred the multidrug resistance phenotype on drug-sensitive cells, therefore allowing selection in the presence of colchicine. Colchicine-resistant cells synthesized large amounts of a membrane-associated 210-kDa MDR-ADA fusion protein that preserved both MDR and ADA functional activities. To monitor expression of the chimeric gene in vivo, Kirsten virus-transformed NIH cells were infected with the MDR-ADA retrovirus, and after drug-selection, injected into athymic nude mice. Tumors developed that contained the bifunctionally active MDR-ADA fusion protein. When these mouse tumor cells were placed in tissue culture without the selecting drug, they did not lose the bifunctionally active MDR-ADA fusion protein. The replication-defective, recombinant MDR-ADA retrovirus should be useful to stably introduce the chimeric MDR-ADA gene into a variety of cell types for biological experiments in vitro and in vivo.  (+info)

Response of mouse skin tumors to doxorubicin is dependent on carcinogen exposure. (8/71)

To investigate the role of carcinogenesis in determining the response of tumors to anticancer drugs, we have used the in vivo model of multistage carcinogenesis of the mouse skin. Mice were initiated with Harvey murine sarcoma virus or single and repeated applications of dimethylbenzanthracene (DMBA). The papillomas which developed as a result of these initiation protocols were monitored quantitatively for their response to the anticancer drug doxorubicin. A single dose of 10 mg/kg doxorubicin is relatively inefficient at reducing the frequency of papillomas arising as a result of either single or repeated applications of the chemical DMBA. However, virally initiated papillomas are sensitive to the single 10-mg/kg dose of doxorubicin and are reduced in frequency by greater than 80%. Repeat treatment with four doses of 5 mg/kg doxorubicin over a 4-week period also reveals differences in the responses of the papillomas to doxorubicin. As with the single dose of doxorubicin, papillomas initiated with multiple applications of DMBA showed only a limited response to four 5-mg/kg doses of doxorubicin. In comparison both the virally initiated and the single DMBA initiated papillomas responded to the four doses of doxorubicin and are reduced in frequency by about 80%. These data show that the response of papillomas to doxorubicin is related to the initiating event. Papillomas derived by viral initiation are most sensitive to doxorubicin while increasing the level of exposure to the chemical carcinogen DMBA increases the proportion of papillomas which do not respond to treatment with doxorubicin. There was no obvious relationship between the method of initiation or the treatment of the mice with doxorubicin and the levels of P-glycoprotein expression observed in the papillomas. All the papillomas expressed detectable levels of P-glycoprotein approaching that of the multidrug resistant cell line, CHRC5.  (+info)