A point mutation in the first splice donor leads to reduced oncogenic properties of the adenovirus serotype 12 E1A gene.

Cells transformed by proteins of early regions 1A (E1A) and 1B (E1B) of oncogenic adenovirus serotype 12 (Ad12) grow to tumours in syngeneic, immunocompetent rodents. To gain insight into the mechanisms of oncogenic transformation, we point mutated the first splice donor in the Ad12-E1A gene, leading to the loss of the Ad12-E1A(9.5S) and Ad12-E1A(11S/10S) proteins and to a conservative amino acid (aa) exchange at position aa 30 (valine vs. leucine) in the Ad12-E1A(13S) and Ad12-E1A(12S ) proteins. BMK cells transformed by mutant Ad12-E1A (Ad12-E1Am) plus Ad12-E1B via retrovirus-mediated gene transfer showed features comparable to wild-type Ad12-E1A (Ad12-E1Awt) plus Ad12-E1B-transformed cells: they formed foci in soft agar and produced tumours in immunodeficient nude mice, although after a prolonged latency period. These results suggest that Ad12-E1A(9.5S) and Ad12-E1A(11S/10S) are dispensable for cellular transformation. However, in contrast to Ad12-E1Awt cells, Ad12-E1Am cells failed to grow to tumours in syngeneic, immunocompetent rodents, with the exception of one cell line, which produced tumours in about 50% of the immunocompetent animals. Interestingly, the concentration of the putative tumour suppressor and co-activator p300 was elevated in cell lines expressing high levels of Ad12-E1A and Ad12-E1B due to an increased half-life. These results indicate that p300 is stabilized in Ad12-E1-transformed BMK cells, probably by a mechanism linked to high expression of Ad12-E1A/E1B.

Tumor-specific activation of hTERT-derived promoters by tumor suppressive E1A-mutants involves recruitment of p300/CBP/HAT and suppression of HDAC-1 and defines a combined tumor targeting and suppression system.

Adenovirus (Ad) E1A proteins are transcriptional regulators with antioncogenic but also transforming properties. We have previously shown that transformation-defective Ad5 E1A-derivatives are excellent tumor suppressors. For tumor-specific expression of the E1A-derivatives we intend to use tumor specific human telomerase reverse transcriptase (hTERT) core promoters. Here, we show that Spm2 and other E1A proteins with an intact amino terminus activated all hTERT constructs 10-20-fold in malignant tumor cells but not in primary fibroblasts, without affecting the activity of endogenous telomerase. The transcription rate in tumor cells was in the range of transcription from the SV40 promoter, which qualifies an E1A-hTERT system as a putative tumor targeting/expression system. The activation of the hTERT promoter by E1A was enhanced upon deletion of the Wilms' tumor 1 negative regulatory element and maintained high after deletion of the adjacent c-Myc-responsive E-box, demonstrating an important role of the remaining sequences that contain several Sp1-motifs. E1A-mediated hTERT activation was independent from the presence of the conserved region 3 (CR3) of E1A but dependent on E1A's binding to p300/CBP and recruitment of its histone acetyltransferase activity. Moreover, E1A-Spm2 and histone deacetylase-1 behaved as antagonists with respect to the regulation of transcription from the hTERT promoter. Overall, hTERT promoter/E1A-Spm2 systems may turn out to be excellent tools for transcriptionally targeted anticancer gene therapy.

A parent-of-origin effect in two families with retinoblastoma is associated with a distinct splice mutation in the RB1 gene.

We have identified a splice-site mutation (IVS6+1G-->T) in the RB1 gene, in two unrelated families with incomplete-penetrance retinoblastoma. Analysis of RNA from white blood cells showed that this mutation causes skipping of exon 6. Although this deletion results in a frameshift, most carriers of the mutation did not develop retinoblastoma. Interestingly, the relative abundance of the resultant nonsense messenger RNA varies between members of the same family and is either similar to or considerably lower than the transcript level of the normal allele. Moreover, variation of relative transcript levels is associated with both the sex of the parent that transmitted the mutant allele and phenotypic expression: All eight carriers with similar abundance of nonsense and normal transcript have received the mutant allele from their mother, and only one of them has developed retinoblastoma; by contrast, all eight carriers with reduced abundance of the nonsense transcript have received the mutant allele from their father, and all but two them have retinoblastoma. After treatment with cycloheximide, the relative abundance of transcripts from paternally inherited mutant alleles was partly restored, thus indicating that posttranscriptional mechanisms, rather than transcriptional silencing, are responsible for low levels of mutant messenger RNA. Our data suggest that a specific RB1 mutation can be associated with differential penetrance, on the basis of the sex of the transmitting parent.