Inhibition of tumor growth by DT-A expressed under the control of IGF2 P3 and P4 promoter sequences.

The human IGF2 P3 and P4 promoters are highly active in a variety of human cancers. We here present an approach for patient oriented therapy of TCC bladder carcinoma by driving the diphtheria toxin A-chain (DT-A) expression under the control of the IGF2 P3 and P4 promoter regulatory sequences. High levels of IGF2 mRNA expression from P3, P4 or both promoters were detected in 18 TCC samples (n = 29) by ISH or RT-PCR. Normal bladder samples (n = 4) showed no expression from either promoter. The activity and specificity of the IGF2 P3 and P4 regulatory sequences were established in human carcinoma cell lines by means of luciferase reporter gene assay. These sequences were used to design DT-A expressing, therapeutic vectors (P3-DT-A and P4-DT-A). The activity of both was determined in cell lines (in vitro) and the activity of P3-DT-A was determined in a heterotopic animal model (in vivo). The treated cell lines highly responded to the treatment in a dose-response manner, and the growth rate of the developed tumors in vivo was highly inhibited (70%) after intratumoraly injection with P3-DT-A compared to non-treated tumors (P < 0.0002) or tumors treated by luciferase gene expressing LucP3 vector (P < 0.002).

Use of transcriptional regulatory sequences of telomerase (hTER and hTERT) for selective killing of cancer cells.

Telomerase (hTER and hTERT) plays a crucial role in cellular immortalization and carcinogenesis. Telomerase activity can be detected in about 85% of different malignant tumors, but is absent in most normal cells. In situ hybridization analysis showed that high levels of hTER and hTERT expression are present in bladder cancer, while no signal was detected in normal tissue. Therefore, in this work we propose to use hTER and hTERT transcriptional regulatory sequences to control the expression of a cytotoxic gene in bladder tumor cells, resulting in the selective destruction of this cell population. Expression vectors containing the diphtheria toxin A-chain (DT-A) gene were linked to hTER and hTERT transcriptional regulatory sequences, respectively. Inhibition of protein synthesis occurred in bladder and hepatocellular carcinoma cells transfected with the plasmids containing the DT-A gene under the control of the hTER or hTERT promoters in correlation with their activity. These studies support the feasibility of using hTER and hTERT transcriptional regulatory sequences for targeted patient-oriented gene therapy of human cancer.

Characterization of human and mouse H19 regulatory sequences.

H19 is expressed in a large percentage of bladder tumors, but not expressed in healthy bladder tissue. The aim of this study is to define H19 optimal transcriptional regulatory sequences in tumor cells, which can potentially be used to control expression of a toxin gene in constructs to be used in bladder cancer gene therapy trials in mice and human. Transient expression assays revealed that elements responsible for promoter activity are contained within the 85 bp upstream region. The transcriptional activity of this region was strongly inhibited by the methylation of the Hpa II sites. A modest cell specificity is conferred by the upstream sequences. The human and murine promoter activities were significantly increased by the human H19 4.1 kb enhancer sequence. The 85 bp H19 upstream region contains all the elements to interact with the enhancer. We showed that the human H19 promoter is highly active in a murine bladder carcinoma cell line, justifying its use to drive the expression of a cytotoxin gene in gene therapy trials in mice.