New method for detecting cellular transforming genes.

Tumor induction in athymic nude mice can be used to detect dominant transforming genes in cellular DNA. Mouse NIH 3T3 cells freshly transfected with either cloned Moloney sarcoma proviral DNA or cellular DNA's derived from virally transformed cells induced tumors when injected into athymic nu/nu mice. Tumors were also induced by cells transfected with DNA from two tumor-derived and one chemically transformed human cell lines. The mouse tumors induced by human cell line DNA's contained human DNA sequences, and DNA derived from these tumors was capable of inducing both tumors and foci on subsequent transfection. Tumor induction in nude mice represents a useful new method for the detection and selection of cells transformed by cellular oncogenes.

Characterization of human transforming genes from chemically transformed, teratocarcinoma, and pancreatic carcinoma cell lines.

Dominant transforming genes that were transferred to mouse NIH3T3 cells by cellular DNAs prepared from a chemically transformed human cell line (MNNG-HOS), a human teratocarcinoma cell line (PA1), and a human pancreatic carcinoma cell line (A1165) were characterized (a) analyzing the repetitive human DNA sequences that were associated with the transforming gene and (b) determining their relationship to the oncogenes of the Harvey (rasH) and Kirsten (rasK) sarcoma viruses and to the human neuroblastoma transforming gene (rasN). The results show that the transforming gene activated in the teratocarcinoma cell line is identical to the neuroblastoma transforming gene and that the transforming gene of the pancreatic carcinoma cell line is a human homologue of rasK. In contrast, the transforming gene activated in the chemically transformed human cell line showed no detectable homology to rasK, rasH, and rasN.

Flavone acetic acid directly induces expression of cytokine genes in mouse splenic leukocytes but not in human peripheral blood leukocytes.

Flavone-8-acetic acid (FAA) is a flavonoid drug that augments mouse natural killer activity, induces cytokine gene expression, and synergizes with recombinant interleukin 2 for the treatment of murine renal cancer. However, FAA has been largely inactive in human clinical trials. In the present study we investigated the ability of FAA treatment to directly induce cytokine mRNA expression in total mouse splenic leukocytes and selected leukocyte subsets, as well as in total human peripheral blood leukocytes. Analysis of RNA isolated from FAA-treated mouse splenic leukocytes demonstrated that treatment with greater than or equal to 100 micrograms/ml of FAA induced expression of tumor necrosis factor alpha (TNF-alpha) mRNA by 1 h and induced maximal expression of TNF-alpha, alpha-interferon, and gamma-interferon mRNA within 3 h. The expression of all cytokine genes was diminished by 6 h. Interferon biological activity was detected in the supernatants of mouse splenic or peripheral blood leukocytes after treatment with FAA. These results correlate well with the previously reported induction of cytokine mRNA genes and biological activity by FAA in vivo. In contrast, FAA did not induce detectable mRNA expression or cytokine protein secretion by human peripheral blood leukocytes under similar conditions. These results demonstrate that FAA can directly stimulate cytokine gene expression in mouse but not in human leukocytes. Further studies performed with highly purified positively selected mouse CD4+ or CD8+ splenic T-lymphocytes, as well as purified B-cells, demonstrated that the FAA-induced expression of gamma-interferon mRNA was mainly induced in the CD8+ lymphocyte subset. alpha-Interferon mRNA was expressed largely in the B-cell population, while TNF-alpha mRNA was induced in all leukocyte subsets tested. Therefore, these results suggest that the immunomodulatory effects of FAA in mice are direct, but different cytokines are induced from different leukocyte subsets. Further, the data suggest that flavonoid compounds or analogues that stimulate cytokine gene expression in human cells might be therapeutically active in cancer patients.

Induction of multiple cytokine gene expression and IRF-1 mRNA by flavone acetic acid in a murine macrophage cell line.

Flavone-8-acetic (FAA) acid is a potential chemotherapeutic agent that has demonstrated strong immunomodulatory activity in murine model systems. The immunomodulatory activity of this drug in murine systems has been linked to its ability to rapidly induce cytokine gene expression in vivo and in mouse splenocytes ex vivo. We have now developed a tissue culture model for studying the molecular basis of induction of cytokine expression by FAA. Using the mouse macrophage cell line, ANA-1, we can demonstrate the direct induction of interferon beta (IFN beta), interleukin-6 (IL-6), tumor necrosis factor-alpha (TNF alpha), and interferon response factor-1 (IRF-1) mRNA expression following treatment with FAA. Furthermore, the induction of the IFN beta mRNA can occur in the absence of new protein synthesis. Nuclear run-on experiments indicate that at least part of the induction of IFN beta, IL-6, and TNF alpha mRNA occurs at the transcriptional level while the increase in IRF-1 mRNA appears largely post-transcriptional or due to the production of IFN beta protein. Additionally, experiments using agents that interfere with second messengers demonstrate that activation of the protein kinase C pathway is possibly involved in FAA gene induction. The use of this tissue culture model system should lead to a more complete understanding of the mechanisms involved in FAA-induced gene expression and help determine why this drug is inactive on human cells.

Tumorigenesis by transected cells in nude mice: a new method for detecting cellular transforming genes.

We have demonstrated that NIH 3T3 cells freshly transfected with either a cloned retroviral provirus or cell DNA derived from virally-transformed cells are able to induce tumors when injected subcutaneously into nude mice. Furthermore, cells transfected with DNA derived from at least three transformed human cell lines are able to induce tumors. These latter tumors contain human DNA sequences and DNA isolated from at least some of them is able to induce both foci and tumors in subsequent DNA transfection. Our data suggests that tumor induction by transfected 3T3 cells could serve as a powerful system for the selection of cells transformed by dominant cellular oncogenes. This method oviates the requirement that oncogenes induce clearly defined morphologically-transformed foci in order to be detected, and eliminates the need to maintain morphologically normal cells in tissue culture for many weeks, as well as the necessity of microscopically screning large numbers of tissue culture dishes. The tumors which arise in nude mice grow progressively, have been readily transplantable to other nude mice, and have been readily explantable into tissue culture. In addition, both DNA and RNA can be isolated directly from the mouse tumors to screen for the presence and expression of transfected sequences. We are currently examining other DNA samples from both human tumor-derived cell lines and primary human tumors to determine if this assay will detect and identify additional oncogenes. We are also studying the suitability of other normal cell lines as recipients in this assay, since cell lines which do not show readily discernible morphological transformation in monolayer culture may be suitable as tumor inducers following transfection. This assay should provide a convenient alternative method for detecting transforming genes and may help to increase the number of such sequence which can be identified and analyzed.