Attan Kasid

Gene transfer into humans--immunotherapy of patients with advanced melanoma, using tumor-infiltrating lymphocytes modified by retroviral gene transduction.

BACKGROUND AND METHODS Treatment with tumor-infiltrating lymphocytes (TIL) plus interleukin-2 can mediate the regression of metastatic melanoma in approximately half of patients. To optimize this treatment approach and define the in vivo distribution and survival of TIL, we used retroviral-mediated gene transduction to introduce the gene coding for resistance to neomycin into human TIL before their infusion into patients--thus using the new gene as a marker for the infused cells. RESULTS Five patients received the gene-modified TIL. All the patients tolerated the treatment well, and no side effects due to the gene transduction were noted. The presence and expression of the neomycin-resistance gene were demonstrated in TIL from all the patients with Southern blot analysis and enzymatic assay for the neomycin phosphotransferase coded by the bacterial gene. Cells from four of the five patients grew successfully in high concentrations of G418, a neomycin analogue otherwise toxic to eukaryotic cells. With polymerase-chain-reaction analysis, gene-modified cells were consistently found in the circulation of all five patients for three weeks and for as long as two months in two patients. Cells were recovered from tumor deposits as much as 64 days after cell administration. The procedure was safe according to all criteria, including the absence of infections virus in TIL and in the patients. CONCLUSIONS These studies demonstrate the feasibility and safety of using retroviral gene transduction for human gene therapy and have implications for the design of TIL with improved antitumor potency, as well as for the possible use of lymphocytes for the gene therapy of other diseases.

Evidence that transforming growth factor-β is a hormonally regulated negative growth factor in human breast cancer cells

The hormone-dependent human breast cancer cell line MCF-7 secretes transforming growth factor-beta (TGF-beta), which can be detected in the culture medium in a biologically active form. These polypeptides compete with human platelet-derived TGF-beta for binding to its receptor, are biologically active in TGF-beta-specific growth assays, and are recognized and inactivated by TGF-beta-specific antibodies. Secretion of active TGF-beta is induced 8 to 27-fold under treatment of MCF-7 cells with growth inhibitory concentrations of antiestrogens. Antiestrogen-induced TGF-beta from MCF-7 cells inhibits the growth of an estrogen receptor-negative human breast cancer cell line in coculture experiments; growth inhibition is reversed with anti-TGF-beta antibodies. We conclude that in MCF-7 cells, TGF-beta is a hormonally regulated growth inhibitor with possible autocrine and paracrine functions in breast cancer cells.

Autocrine and paracrine growth regulation of human breast cancer

SummaryWe consider the hypothesis that estrogen control of hormone dependent breast cancer is mediated by autocrine and paracrine growth factors secreted by the breast cancer cells themselves. Though we show direct, unmediated effects of estrogen on specific cell functions, we also provide evidence that human breast cancer cells secrete a collection of growth factors (IGF-I, TGFα, TGFβ, a PDGF-like competency factor, and at least one new epithelial colony stimulating factor). Some of these are estrogen-regulated in hormone dependent cells, and are constitutively increased in cells which acquire independence either spontaneously or byras transfection. Collectively, the secreted growth factors are capable of promoting tumor formation by MCF-7 cells in nude mice, though not to the same extent as estrogens. There would seem to be potential for clinical intervention in the autocrine and paracrine control of breast cancer cells, including some cells which are no longer dependent on estrogens.

Autocrine and paracrine growth regulation of human breast cancer.

Previous work from our laboratory has demonstrated that human breast cancer (BC) cells in culture can be stimulated by physiologic concentrations of estrogen. In an effort to further understand this process, we have examined the biochemical and biological properties of proteins secreted by human BC cells in vitro. We have developed a defined medium system which simultaneously allows the collection of factors secreted by the BC cells, facilitates their purification and allows for an unequivocal assay of their effect on other BC cells. By both biochemical and radioimmunoassay procedures, MCF-7 cells secrete large quantities of IGF-I-like activity. The cells contain receptors for IGF-I and are stimulated by physiologic concentrations of IGF-I. Multiple additional peaks of growth stimulatory activity can be obtained by partial purification of conditioned media from human BC cells by sequential dialysis, acid extraction and Biogel P60 chromatography. These peaks are induced up to 200-fold by physiologic concentrations of estrogen. Several of these peaks cross-react in a radioreceptor assay with EGF and are thus candidates for transforming growth factors. Monoclonal antibodies (MCA) have been prepared which react with secreted proteins from the MCF-7 cells. One of these MCAs binds to material from MCF-7 and ZR-75-1 hormone-dependent BC cells only when these two lines are treated with estrogen but reacts with conditioned medium from several other hormone-independent cell lines in the absence of estrogen stimulation. This MCA is currently undergoing further characterization and evaluation of its biological potency. We conclude that with estrogen stimulation, hormone-dependent human BC cells secrete peptides which when partially purified can replace estrogen as a mitogen. Their role as autocrine or paracrine growth factors and their effects on surrounding nonneoplastic stroma may suggest a means of interfering with tumor proliferation.

Epidermal Growth Factor Receptor Gene Expression in Normal Human Kidney and Renal Cell Carcinoma

The epidermal growth factor receptor (EGFr) is a transmembrane glycoprotein detected on many cells and tissues including neoplastic and normal kidney. EGFr binds the mitogenic polypeptide hormone epidermal growth factor (EGF) as well as EGF-related transforming growth factor-alpha (TGF-alpha). Increases in EGFr gene expression and protein production have been implicated in the development of the malignant phenotype for certain cancers. To determine if alterations in EGFr gene expression are present in human renal cell carcinoma, paired samples of normal and neoplastic renal tissue from ten patients with advanced renal cell carcinoma were analyzed for EGFr mRNA content by Northern blot hybridization. The EGFr gene was constitutively expressed in 90% of normal kidney samples. In seven out of nine evaluable patients, tumors expressed 1.7 to 8.4 times more EGFr mRNA than corresponding normal tissue. Two patients showed no elevation of tumor EGFr mRNA and one patient had no identifiable EGFr transcripts in either neoplastic or normal kidney. Expression of EGFr mRNA was also detected in three tumor-derived and two established renal cell carcinoma cell lines. EGFr transcripts were not found in tumor infiltrating lymphocytes (TIL). These findings suggest that overexpression of EGFr mRNA may be associated with malignant transformation in renal cell carcinomas.

The local effects of cachectin/tumor necrosis factor on wound healing

Previous experimental studies have suggested that tumor necrosis factor (TNF) may have either a beneficial or a detrimental role in wound healing. Control and doxorubicin-treated (6 mg/kg, intravenously) rats underwent paired dorsal 5-cm linear wounds and had either vehicle or recombinant (r)TNF (0.5, 5, or 50 fig) applied locally to the wound. Paired wounds were harvested at 7 and 14 days after wounding and analyzed for wound-bursting strength (WBS) and activity of the gene for type 1 collagen and TNF. Doxorubicin treatment decreased WBS at 14 days but not at 7 days after wounding/Local application of 50 fig of rTNF decreased WBS in saline-treated rats and concentrations of 5 and 50 μg decreased WBS in doxorubicin-treated rats when measured 7 days after wounding. These effects dissipated when WBS was measured 14 days after wounding. Doxorubicin decreased wound collagen gene expression and local TNF treatment decreased wound collagen gene expression in saline-treated rats and further decreased it in doxorubicin-treated rats. The decrement in collagen gene expression induced by rTNF increased as the local dose of rTNF increased. The gene for TNF was not detectable in wounds from normal or doxorubin-treated rats at 3,7,10, or 14 days after wounding. These data suggest that the gene for TNF is not expressed in wounds and that the local application of TNF is detrimental to wound healing as it decreases WBS and activity of the gene for collagen.

Retrovirus-mediated gene transfer into CD4+ and CD8+ human T cell subsets derived from tumor-infiltrating lymphocytes and peripheral blood mononuclear cells

SummaryStudies were undertaken to test the susceptibility of individual T cell subpopulations to retroviral-mediated gene transduction. Gene transfer into human tumor-infiltrating lymphocytes (TIL) or peripheral blood mononuclear cells (PBMC) was carried out by transduction with an amphotropic murine retroviral vector (LNL6 or N2) containing the bacterialneoR gene. The presence of theneoR gene in the TIL population was demonstrated by Southern blot analysis, detection of the enzymatic activity of the gene product and by the ability of transduced TIL to proliferate in high concentrations of G418, a neomycin analog that is toxic to eukaryotic cells. The presence of theneoR gene in TIL did not alter their proliferation or interleukin-2 dependence compared to nontransduced TIL. The differential susceptibility of CD4+ and CD8+ lymphoid cells to the retro-virus-mediated gene transfer was then tested. Transduction of heterogeneous TIL cultures containing both CD4+ and CD8+ cells resulted in gene insertion into both T cell subsets with no preferential transduction frequency into either CD4+ or CD8+ cells. In other experiments highly purified CD4+ and CD8+ T cell subpopulations from either TIL or PBMC could be successfully transduced with theneoR gene as demonstrated by Southern blot analysis and detection of the gene product neophosphotransferase activity. No such activity or vector DNA could be detected in controls of nontransduced cells. In these highly purified cell subsets the distinctive T cell phenotypic markers were continually expressed after transduction, G418 selection and long-term growth. Clinical trials have begun in patients with advanced cancer using heterogeneous populations of CD4+ and CD8+ gene-modified TIL.

Epidermal growth factor receptor gene analysis in renal cell carcinoma

The epidermal growth factor receptor binds the mitogens epidermal growth factor and transforming growth factor-alpha. Increased expression of the epidermal growth factor receptor has been noted in many types of tumors and is associated with gene amplification in several including epidermoid carcinoma, lung carcinoma, breast carcinoma and glioblastoma. We have recently observed increased expression of the epidermal growth factor receptor messenger RNA in neoplastic tissue relative to normal kidney tissue from patients with renal cell carcinoma. To determine if epidermal growth factor receptor gene amplification was present in renal cell carcinoma, DNA was extracted from renal cell carcinoma cell lines and from normal kidney and renal cell carcinoma tissues derived from radical nephrectomy specimens from thirty patients. DNA was analyzed by Southern blot hybridization. There was no epidermal growth factor receptor gene amplification detected in the renal cell carcinoma samples studied, indicating the increased epidermal growth factor gene expression observed in renal cell carcinoma does not occur through gene amplification. Unlike other tumors with enhanced epidermal growth factor receptor gene expression, amplification of this gene does not appear to be a common feature of renal cell carcinoma.

Suramin interference with transforming growth factor-β inhibition of human renal cell carcinoma in culture

Suramin is a polyanionic compound used clinically for the treatment of trypanosomiasis, which is known to inhibit the action of many protein factors in vitro. Transforming growth factor-beta (TGF-beta) is a multifunctional regulatory protein which inhibits the growth of renal cell carcinoma in culture. While suramin at 50-500 micrograms/ml had no significant effect on the growth of renal cell carcinoma in culture in our experiments, it did partially reverse the growth inhibition induced by TGF-beta in the two cell lines tested. This effect apparently is caused by suramins direct interference with 125I-labeled TGF-betas ability to bind to the cell, and not by any effect of suramin on the TGF-beta receptor. Furthermore, suramin dissociates TGF-beta bound to the cell with a t1/2 of less than 30 min. These results are consistent with those previously reported regarding suramins interaction with other protein growth factors, and suggest that suramin may interact with the TGF-beta protein itself to inactivate it.

Transforming growth factor-beta inhibits the growth of renal cell carcinoma in vitro.

Transforming growth factor-beta (TGF-beta) is a bifunctional growth regulatory hormone which inhibits the growth of many normal and neoplastic epithelial cell lines in monolayer culture. Endogenous and exogenous TGF-beta may influence cell proliferation through autocrine and paracrine binding to specific TGF-beta receptors. Growth effects of TGF-beta on human renal cell carcinoma cell lines have not been thus far described. We have studied the effects of TGF-beta on one renal tumor-derived (UOK-39) and one established (SKRC-7) renal cell carcinoma cell line. Exogenous addition of biologically active TGF-beta to cell cultures at concentrations between two and five ng./ml. inhibited the anchorage-dependent growth of UOK-39 by 75% and SKRC-7 by 44%, relative to controls. Low numbers of high affinity TGF-beta receptors were identified on both cell lines in 125I-TGF-beta binding assays. UOK-39 cells bound radiolabeled TGF-beta with higher affinity than SKRC-7 cells, but had fewer receptor sites, by Scatchard analysis of binding data. These results suggest that TGF-beta inhibits proliferation of renal carcinoma cells in vitro which may be mediated through binding of exogenous TGF-beta to functional TGF-beta receptors on the cell surface.