Role of acidic cell organelles in the higher nonmelanoma retention of melanoma markers based on N-(2-dialkylaminoethyl)benzamides and the cytotoxicity of alkylating benzamides.

Melanoma markers based on both N-(2-dialkylaminoethyl)benzamides and lysosomotropic agents comprise a N-(2-dialkylaminoethyl)aminocarbamoyl pharmacophore, suggesting that benzamides and lysosomotropic probes should show affinity to melanoma and acidic cell organelles. We prepared novel fluorescent N-(2-dialkylaminoethyl)benzamides to prove this presumption. Lysosomotropic probes showed a melanin affinity comparable to benzamides. Lysosomal markers and benzamides colocalized in acidic organelles. Various nonmelanoma cell lines showed equal benzamide uptake and retention compared with melanoma cells. In nonmelanoma cells the amount of retained benzamides correlates with the number of acidic cell organelles. Benzamides almost completely failed to accumulate in melanoma cells with neutralized acidic organelles but normal melanin content. In melanoma retention of benzamides, acidic cell organelles are the main determinant. N-(2-dialkylaminoethyl)benzamides are lysosomotropic probes with high accumulation in nonmelanoma tumors with many acidic cell organelles. Alkylating benzamides were reported previously to show a melanoma unselective, in general enhanced cytotoxicity. Alkylating benzamides can act as lysosomotropic detergents or as DNA alkylators. The ability of alkylating benzamides to disrupt the membrane of lysosomes and cause liberation of lysosomal-trapped fluorescent dyes was demonstrated by fluorescence microscopy. Whether they act as an alkylating agent or a lysosomotropic detergent in a specific cell line is dependent on the amount of acidic cell organelles. In cell lines with small amounts of acidic cell organelles alkylating benzamides act as alkylating agents, whereas in cell lines with many acidic cell organelles they act as lysosomotropic detergents. In cell lines with high amounts of acidic cell organelles they do not reach the nucleus.

Radioiodine therapy of hepatoma using targeted transfer of the human sodium/iodide symporter gene.

UNLABELLED: We investigated the feasibility of radioiodine therapy targeting hepatoma cells (MH3924A) by tissue-specific expression of the human sodium/iodide symporter (hNIS) gene directed by the murine albumin enhancer and promoter (mAlb). METHODS: The cell-specific transcriptional activity of mAlb was examined by a luciferase assay in several transiently transfected cell lines. MH3924A cells were stably transfected with the recombinant retroviral vector, in which hNIS complementary DNA expression was driven by mAlb and coupled to hygromycin resistance gene using an internal ribosomal entry site (IRES). Functional hNIS expression in hepatoma cells was confirmed by an iodide uptake assay. In imaging studies, the tumor-bearing ACI rats were intravenously injected with (131)I and imaged with a gamma-camera. Biodistribution was studied at 30 min and at 1, 3, 6, and 25 h after injection of (131)I. Toxic effects of (131)I on hepatoma cells were studied in vitro and in vivo. RESULTS: Stably transfected MH3924A cells concentrated (125)I up to 240-fold higher than the wild-type cells. The iodide uptake in stably transfected cells was inhibited by ouabain and sodium perchlorate but increased by 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid. An in vitro clonogenic assay revealed an 86% decrease in colony number in stably transfected cells after exposure to 3.7 MBq/mL of (131)I and only about 8% in hNIS-negative control cells. Furthermore, the in vivo study showed intense tracer accumulation in hNIS-expressing tumors after administration of (131)I. At 3 h after intraperitoneal injection, the transfected tumors accumulated (131)I 19.2-fold higher than the parental tumors in a biodistribution study. Moreover, administration of a therapeutic dose of (131)I resulted in an inhibition of hNIS-expressing tumor growth, whereas control tumors continued to increase in size. CONCLUSION: A therapeutic effect of (131)I on hepatoma cells in vitro and in vivo has been demonstrated after tumor-specific iodide uptake induced by mAlb-directed hNIS gene expression. Because a stable transformed cell line has been used in these experiments, the clinical potential of this strategy must be evaluated after in vivo transfection of hepatoma cells.

Alkylating benzamides with melanoma cytotoxicity: experimental chemotherapy in a mouse melanoma model.

The in-vivo antineoplastic potential of the alkylating N-(2-dialkylaminoethyl)benzamides BZA1 and BZA2, novel melanoma targeted anticancer drugs, was evaluated in a mouse melanoma model with nude mice bearing subcutaneous SkMel28, B16 or WM266-4. The maximal tolerated dose (MTD) for the intraperitoneal application of both agents was found to be 24 mg/kg. Treatment was initiated with an intraperitoneal injection of 8 mg/kg of BZA1 or BZA2 on days 0, 2 and 4 in the case of B16 melanoma on days 0, 1 and 2 after the onset of the experiment, when the mean tumor diameter ranged within 4-6 mm. The experiment was terminated when the mean tumor diameter in the control group had reached a value of 12 mm. Tumor growth delay of these agents was compared with dacarbazine (3x250 mg/kg), chlorambucil (3x5 mg/kg) and an untreated control group. Significant tumor growth delay was observed under BZA1, BZA2 and dacarbazine treatment compared with the untreated control group in all three evaluated melanomas with insignificant differences among BZA1, BZA2 and dacarbazine. The insignificant effect of chlorambucil and the strong improvement on growth delay achieved with BZA1 and BZA2 demonstrated melanoma targeting characteristics of the N-(2-dialkylaminoethyl)benzamide structure element. Dacarbazine was more effective in the in-vivo antineoplastic assay compared with the in-vitro cytotoxicity studies, probably due to hepatic bioactivation. Similar side effect intensity of BZA2 and dacarbazine was observed, whereas BZA1 was more toxic. BZA2 might represent an alternative antimelanoma drug, especially in patients not responding to dacarbazine.

Transfer of the sFLT-1 gene in Morris hepatoma results in decreased growth and perfusion and induction of genes associated with stress response.

PURPOSE: Inhibition of tumor angiogenesis is emerging as a promising target in the treatment of malignancies. Therefore, monitoring of antiangiogenic approaches with functional imaging and histomorphometrical analyses are desirable to evaluate the biological effects caused by this treatment modality. EXPERIMENTAL DESIGN: Using a bicistronic retroviral vector for transfer of the soluble receptor for the vascular endothelial growth factor (sFLT) hepatoma (MH3924A) cell lines with sFLT expression were generated. In human umbilical vein endothelial cells cultured with conditioned medium of sFLT-expressing hepatoma cells, the inhibitory action of secreted sFLT was determined using a Coulter counter and a thymidine incorporation assay. Furthermore, in vivo experiments were done to measure the effects on tumor growth and perfusion. Finally, the tumors were examined by immunohistochemistry (including computer-assisted morphometry) and DNA chip analysis. RESULTS: Stable sFLT-expressing hepatoma cells inhibited endothelial cell proliferation in vitro. In vivo, growth and perfusion, as measured by H(2)(15)O positron emission tomography, were reduced in genetically modified tumors. However, the immunohistochemically quantified microvascularization and macrovascularization, as indicated by CD31- and alpha-actin-positive area, revealed no significant changes, whereas the number of apoptotic cells was increased in sFLT-expressing tumors, although not significantly. DNA chip analysis of tumors with gene transfer showed an increase of genes related to apoptosis, signal transduction, and oxidative stress. CONCLUSION: Our results suggest that sFLT expression inhibits tumor growth and perfusion and enhances expression of apoptosis-related genes in this model. Enhanced expression of genes for signal transduction, stress, and metabolism indicates tumor defense reactions.

Effects of Pax8 and TTF-1 thyroid transcription factor gene transfer in hepatoma cells: imaging of functional protein-protein interaction and iodide uptake.

UNLABELLED: The thyroid transcription factors TTF-1 and Pax8 cooperate in the transcriptional activation of thyroid-specific genes such as thyroglobulin (Tg), thyroperoxidase (TPO), and sodium/iodide symporter (NIS). METHODS: Dog TTF-1 (dTTF-1) and the human Pax8 (hPax8) gene were transfected in Morris hepatoma (MH3924A) cells to investigate (a) the possible visualization of functional protein-protein interaction and (b) the induction of thyroid-specific gene expression. In MH3924A cell lines expressing dTTF-1, hPax8, or both, the activation of human Tg (hTg), human TPO (hTPO), or rat NIS (rNIS) promoter/enhancer was measured using firefly luciferase reporter constructs. Furthermore, the possible induction of thyroid-specific genes was investigated in iodide uptake and reverse transcription polymerase chain reaction (RT-PCR) experiments. RESULTS: Low transcriptional activation of these constructs was observed in cells expressing either hPax8 or dTTF-1 alone. In contrast, the hTg and hTPO and, to a lesser extent, the rNIS regulatory region were significantly activated in cell lines expressing both transcription factors. Imaging the transcriptional activation of the thyroid-specific regulatory regions by Pax8 and TTF-1 was possible in nude mice implanted with MHhPax8dTTF-1 cells using a cooled charge-coupled device camera. Na(125)I uptake experiments and RT-PCR showed no effect of hPax8 and dTTF-1 on endogenous thyroid-specific gene expression in genetically modified cells. CONCLUSION: The activation of thyroid-specific promoter/enhancer elements in Morris hepatoma cells depends on the functional interaction of hPax8 and dTTF-1. The cooperation of these 2 transcription factors can be visualized in vitro as well as in vivo. With regard to a possible application for radioiodine therapy, further modifications are required.

Tumor-specific gene expression using regulatory elements of the glucose transporter isoform 1 gene.

In order to achieve tumor-specific targeting of adeno-associated virus (AAV)-mediated gene expression, the promoter of the glucose transporter isoform 1 (GLUT1) gene was cloned upstream of the enhanced green fluorescence protein (EGFP) and the herpes simplex virus thymidine kinase (HSVtk) gene. FACS analysis performed at 48 h after transient infection with rAAV/cytomegalovirus (CMV)egfp viral particles revealed an increase of fluorescence in all the cell lines tested. However, EGFP expression under control of the GLUT1 promoter element (rAAV/GTI-1.3egfp) was limited to the tumor cells and oncogene-transformed cells. Evidence for phosphorylation of the HSVtk substrates ganciclovir (GCV) and 125I-deoxycytidine was found in all transfected tumor cell lines compared to noninfected controls (HCT116: 111%; MH3924A: 130%; HaCaT-RT3: 257% increase), but not in HaCaT and HUVEC cells. Furthermore, tumor cells and the oncogene-transformed (ras) cell line HaCaT-RT3 showed a GCV-induced reduction in cell number (HCT116: -71%; MH3924A: -43% and HaCaT-RT3: -31%). No statistically relevant cytotoxic effect was observed in HaCaT (6% decrease) and HUVEC cells (2% decrease). Furthermore, a reduction of 3H-thymidine incorporation into the DNA was seen after treatment with GCV (HCT116: 38%; MH3924A: 33% and HaCaT-RT3: 37% decrease). In a therapy study of HSVtk-expressing tumors with GCV, we achieved total tumor remission.

MIA (melanoma inhibitory activity) promoter mediated tissue-specific suicide gene therapy of malignant melanoma.

Suicide gene therapy of malignant melanoma essentially requires efficient gene transfer and highly selective therapeutic gene expression. To achieve this, recombinant adeno-associated virus (rAAV) particles were constructed containing the tissue-specific promoter of the human melanoma inhibitory activity (hMIA) gene combined with four copies of the enhancer element of the murine tyrosinase gene. Three melanoma and one cervix carcinoma cell line were infected with rAAV particles carrying a reporter gene under control of the enhancer/hMIA promoter in order to determine transcriptional activity and specificity of this system. Viral particles containing the enhancer/hMIA promoter mediated reporter gene activity only in melanoma cells, whereas infection with a cytomegalovirus (CMV)-based promoter construct induced unspecific gene expression. Correspondingly, transient transduction with viral particles bearing the HSVtk gene under the control of the enhancer/MIA promoter elements followed by treatment with ganciclovir (GCV) resulted in growth inhibition only in melanoma cells, whereas the CMV promoter-based construct induced unspecific cytotoxicity. In vivo experiments in nude mice demonstrated that tumors originating from human melanoma cells disappeared after stable, but not transient transduction with vectors bearing the HSVtk gene under the control of the enhancer/hMIA promoter in response to GCV application. In face of higher transduction efficiency, these rAAV particles might therefore be a useful tool for suicide gene therapy of malignant melanoma.

Iodide kinetics and dosimetry in vivo after transfer of the human sodium iodide symporter gene in rat thyroid carcinoma cells.

UNLABELLED: Transfer of the human sodium iodide symporter (hNIS) has been proposed as a new principle of cancer gene therapy. This study evaluates the iodide kinetics and dosimetry of iodide in hNIS-expressing thyroid carcinoma cells under optimized conditions. METHODS: Using a bicistronic retroviral vector for the transfer of the hNIS and the hygromycin resistance gene, hNIS-expressing rat thyroid carcinoma cell lines were generated. Afterward, Na(125)I uptake and efflux were determined in genetically modified and wild-type cells in the presence or absence of modulators of iodide transport. In addition, the (131)I distribution in thyroid-ablated nude mice bearing wild-type and genetically modified thyroid carcinomas was monitored after intraperitoneal administration of (131)I with and without coadministration of lithium carbonate. RESULTS: hNIS-expressing cell lines accumulated up to 49 times more iodide than did noninfected cells, with a maximal iodide uptake after 30 min of incubation. However, a 90% efflux of the radioactivity occurred 20 min after replacement of the medium. In mice, the hNIS-expressing tumors accumulated up to 23 and 19.5 times more iodide than did the wild-type tumors in lithium-treated and control animals, respectively. However, efflux of the radioactivity was also observed in vivo: After 24 h, hNIS-expressing tumors lost 82.5% and 80.4% of the initial activity. Dosimetric calculations showed that 1,650 MBq of (131)I per square meter resulted in 5.4 and 5.2 Gy in hNIS-expressing tumors and 0.24 and 0.26 in wild-type tumors. CONCLUSION: Transduction of the hNIS gene in rat thyroid carcinoma cells induces iodide transport, which is associated with rapid efflux. Application of (131)I in clinically relevant amounts did not result in therapeutically useful absorbed doses in hNIS-expressing tumors in vivo, even under optimized conditions of thyroid ablation and treatment with lithium carbonate.

Fluorophor-labeled spermidine derivatives as fluorescent markers in optical tumor imaging.

Up-regulation of polyamine transporters on the surface of tumor cells and the internalization of biogenic polyamines by active transport processes may be exploited for the accumulation of spermidine derivatives as reporter molecules. We have synthesized and tested fluorophor-labeled spermidine derivatives for the development of a new class of intraoperative tumor imaging agents. In vitro uptake experiments and initial in vivo imaging studies illustrated that fluorophor tagged spermidine derivatives show tumor accumulation.

Tumour-specific activation of the sodium/iodide symporter gene under control of the glucose transporter gene 1 promoter (GTI-1.3).

Targeted transfer of a functionally active sodium iodide symporter (NIS) into tumour cells may be used for radioiodine therapy of cancer. Therefore, we investigated radioiodine uptake in a hepatoma cell line in vitro and in vivo after transfer of the sodium iodide symporter ( hNIS) gene under the control of a tumour-specific regulatory element, the promoter of the glucose transporter 1 gene (GTI-1.3). Employing a self-inactivating bicistronic retroviral vector for the transfer of the hNIS and the hygromycin resistance genes, rat Morris hepatoma (MH3924A) cells were infected with retroviral particles and hNIS-expressing cell lines were generated by hygromycin selection. (125)I(-) uptake and efflux were determined in genetically modified and wild type hepatoma cells. In addition, the iodide distribution in rats bearing wild type and genetically modified hepatomas was monitored. hNIS-expressing MH3924A cell lines accumulated up to 30 times more iodide than wild type hepatoma cells, with a maximal iodide uptake after 30 min incubation time. Competition experiments in the presence of sodium perchlorate revealed a decrease in the iodide uptake (80-84% decrease). Moreover, ouabain led to a loss of accumulated I(-) (81% decrease) whereas 4,4'-diisothiocyano-2,2'-disulphonic acid stilbene (DIDS) increased the I(-) uptake into cells (87% increase). However, a rapid efflux of the radioactivity (70%) was observed 20 min after (125)I(-)-containing medium had been replaced by non-radioactive medium. Lithium had no significant effect on iodide efflux. In rats, the hNIS-expressing tumours accumulated 22 times more iodide than the contralateral wild type tumour. In accordance with the in vitro data, we also observed a rapid efflux of the radioactivity out of the tumour in vivo. Dosimetric calculations resulted in an absorbed dose of 85 mGy in the wild type tumour and 830 mGy in the hNIS-expressing tumour after administration of 18.5 MBq (131)I. In conclusion, transduction of the hNIS gene under the control of the GLUT1 promoter element induces iodide transport in Morris hepatoma cells in vitro and in vivo. However, for therapeutic application additional conditions need to be defined which inhibit the iodide efflux out of the tumour cells.