Fragile histidine triad expression delays tumor development and induces apoptosis in human pancreatic cancer.

The fragile histidine triad (FHIT) gene is a tumor suppressor gene that is altered by deletion in a large fraction of human tumors, including pancreatic cancer. To evaluate the potential of FHIT gene therapy, we developed recombinant adenoviral and adenoassociated viral (AAV) FHIT vectors and tested these vectors in vitro and in vivo for activity against human pancreatic cancer cells. Our data show that viral FHIT gene delivery results in apoptosis by activation of the caspase pathway. Furthermore, Fhit overexpression enhances the susceptibility of pancreatic cancer cells to exogenous inducers of apoptosis. In vivo results show that FHIT gene transfer delays tumor growth and prolongs survival in a murine model mimicking human disease.

Cooperative action of germ-line mutations in decorin and p53 accelerates lymphoma tumorigenesis.

Ectopic expression of decorin in a wide variety of transformed cells results in growth arrest and the inability to generate tumors in nude mice. This process is caused by a decorin-mediated activation of the epidermal growth factor receptor, which leads to a sustained induction of endogenous p21(WAF1/CIP1) (the cyclin-dependent kinase inhibitor p21) and growth arrest. However, mice harboring a targeted disruption of the decorin gene do not develop spontaneous tumors. To test the role of decorin in tumorigenesis, we generated mice lacking both decorin and p53, an established tumor-suppressor gene. Mice lacking both genes showed a faster rate of tumor development and succumbed almost uniformly to thymic lymphomas within 6 months [mean survival age (T50) approximately 4 months]. Mice harboring one decorin allele and no p53 gene developed the same spectrum of tumors as the double knockout animals, but had a survival rate similar to the p53 null animals (T50 approximately 6 months). Ectopic expression of decorin in thymic lymphoma cells isolated from double mutant animals markedly suppressed their colony-forming ability. When these lymphoma cells were cocultured with fibroblasts derived from either wild-type or decorin null embryos, the cells grew faster in the absence of decorin. Moreover, exogenous decorin proteoglycan or its protein core significantly retarded their growth in vitro. These results indicate that the lack of decorin is permissive for lymphoma tumorigenesis in a mouse model predisposed to cancer and suggest that germ-line mutations in decorin and p53 may cooperate in the transformation of lymphocytes and ultimately lead to a more aggressive phenotype by shortening the tumor latency.

The role of p53, p21WAF1/C1PI, and bcl-2 in radioresistant colorectal carcinoma.

Genetic alterations in the p53 tumor suppressor gene are common in human colorectal cancers, occurring in approximately 70% of tumors. In vitro studies have shown that wild-type p53 is involved in controlling cell cycle checkpoint functions and apoptosis involved in the cytotoxic response induced by ionizing radiation and several anticancer chemotherapeutic agents. Wild-type p53 protein can transcriptionally activate the WAF gene, which encodes a cyclin-dependent kinase inhibitory protein, p21WAF1/C1PI protein, and transcriptionally repress the bcl-2 gene, which encodes an inhibitor of apoptosis. To learn more about the in vivo relationship between p53 protein and the expression of p21WAF1/C1PI and bcl-2 proteins in human colorectal cancers treated with radiation therapy, we examined the expression of these proteins by immunohistochemistry in pre-irradiated biopsy specimens and surgical specimens with residual tumor of 27 patients with colorectal carcinoma. Cell proliferation was measured using Ki-67 expression in the tumor cells. The p53 protein was not detected in normal colorectal mucosa, but it was expressed in 21 of 27 (78%) of pre-irradiated tumor samples and in 19 of 27 (70%) of post-irradiated tumors. Expression of the bcl-2 protein in normal colorectal mucosa was confined to the basal epithelial cells of the crypts. Diffuse bcl-2 staining was detected in tumor cells in 13 of 27 (48%) of pre-irradiated samples and in 14 of 27 (52%) of post-irradiated samples. p21WAF1/C1PI expression was detected in 14 of 27 (52%) of pre-irradiated samples but only in 7 of 27 (26%) of post-irradiated samples. No inverse relationship between expression of p53 protein and abnormal bcl-2 expression was apparent. p21WAF1/C1PI was expressed in most nonproliferating Ki-67-negative epithelial cells at the apical tips of the crypts in normal colorectal mucosa, but not in proliferating Ki-67-positive cells of adjacent adenomatous mucosa. An inverse relationship between Ki-67 and p21WAF1/C1PI expression was observed in normal colorectal mucosa and adjacent adenomatous mucosa. After radiation therapy, p53 protein accumulation did not change among residual tumors in 18 cases (three of which were initially negative and remained negative); in four cases there was a significant increase, and five cases had a substantial decrease of p53 expression. Aberrant bcl-2 expression is not correlated with expression of p53 and does not increase significantly in post-irradiated tumor cells. p21WAF1/C1PI expression is markedly reduced in tumor cells that survive radiation therapy.

Cell cycle-dependent regulation of nuclear p53 traffic occurs in one subclass of human tumor cells and in untransformed cells.

We have analyzed the regulation of subcellular compartmentation of mutant and wild-type (WT) p53 proteins as a function of the cell cycle using immunofluorescence microscopy and referring to different markers of position in the cell cycle in different human cells expressing either mutated (KHOS-240, A 431, and T47-D cells) or WT (WI 38 and MCF-7 cells) p53. The mutant p53 proteins present in the KHOS-240, A 431, and T47-D tumor-derived cell lines enter very rapidly in the nucleus in early postmitotic cells before the chromosomes have fully decondensed; they continue accumulating in this location without any obvious cytoplasmic retention throughout the cell cycle until prophase. Such behavior is similar to that observed for the WT p53 associating with SV40 large T antigen in human WI 38 cells transformed by SV40, but it is in contrast to the behavior of the WT p53 protein present in both the untransformed WI 38 and the tumor-derived MCF-7 cells. In these latter systems, the highest nuclear concentrations of the WT protein are always found in G1 cells that still fail to exhibit a high rate of nuclear cyclin A; past the G1-S transition, the nuclear level of WT p53 tends to decrease, possibly to the benefit of cytoplasmic expression, whereas that of cyclin A concomitantly increases, suggesting that the nuclear accumulation of WT p53 becomes restricted during the phase of DNA replication. As for Saos-2 cells stably transfected with the temperature-sensitive p53Ala-143 mutant, they become arrested before the G1-S transition with a heavy pool of nuclear p53 at 32.5 degrees C, the temperature at which the transcriptional activity of p53Ala-143 is restored. All these data are compatible with the presently acknowledged primary role for WT p53, which would be to brake transit through the G1-S border possibly by directly transactivating the p21cip1 protein.

Mutations clustered in exon 5 of the p53 gene in primary nasopharyngeal carcinomas from southeastern Asia.

Mutations in the p53 tumor suppressor gene play an important role in the development of many common human malignancies. In nasopharyngeal carcinomas (NPC), p53 gene mutations were not detected in primary tumors, with one exception for a primary tumor displaying a p53 mutation at codon 280, whereas p53 mutations were identified in some metastatic and nude mouse-passaged NPC specimens. In the present report, 41 NPC primary tumors of the undifferentiated carcinoma nasopharyngeal type (UCNT; 21 from Hong Kong and 20 from Guangxi, southeastern China) were studied. Four point mutations that result in amino acid substitutions were identified by PCR amplification of exons 2-9 and direct DNA sequencing, combined with PCR-single-strand conformation polymorphism analysis. The 4 mutations detected were clustered within the DNA stretch from codon 175 to 177. Our data, taken together with those of others, suggest that mutation in p53 may occur in NPC at various points during tumorigenesis. Alternative mechanisms of p53 inactivation in NPC are also possible.

Active mariner transposable elements are widespread in natural populations of Drosophila simulans.

The occurrence of active, or autonomous, mariner elements was investigated by crossing white-peach mutant Drosophila simulans females with wild-type males from various geographic origins. From a total of 194 experimental crosses only 17 failed to produce progeny with eye mosaicism (MOS, i.e. pigmented spots in otherwise white-peach eyes). Therefore, active mariner elements inducing somatic excision of the copy inserted at the white locus are abundant in all populations sampled. In the experimental crosses the frequency of mosaic offspring ranged from 0 to 100%, showing that the phenotypic expression is highly variable. The MOS phenotype, measured by the number of spots on the eyes, is quite variable within the progeny of single crosses. Although a difference was observed in the average MOS score (percentage of mosaic flies) between northern and southern populations of France, there was no indication of long range variation between geographic populations. Neither was there a systematic difference between recently collected populations and samples kept several years as isofemale lines.