Heidi Hahn

The patched polymorphism Pro1315Leu (C3944T) may modulate the association between use of oral contraceptives and breast cancer risk.

The gene coding for the human homologue of the Drosophila segment polarity gene patched (PTCH1) is mutated in several common human tumors. In mice, haplodeficiency at the Ptch1 locus results in severe histologic defects in mammary ductal structure. We found no mutations within the coding region of PTCH1 in 17 human primary breast carcinomas. However, the biallelic Pro1315Leu (C3944T) polymorphism of PTCH1 was significantly associated with breast cancer in 41 Bavarian patients compared to 85 healthy controls. We investigated whether this variant influences susceptibility for breast cancer in 611 breast cancer patients diagnosed by age 50 years and 1,057 controls matched by age and study region in Germany and in 1,093 breast cancer patients from the United Kingdom. Allele and genotype frequencies were not different between cases and controls. However, multivariate logistic regression analysis revealed an effect modification of oral contraceptive use (OC) on breast cancer risk by Leu‐carrier status. Compared to women who have Pro/Pro and never used OC, Pro/Pro OC users had an increased odds ratio for breast cancer of 1.7. The odds ratio was also 1.7 for Leu‐carriers who never used OC, but this was attenuated among Leu‐carriers who ever used OC by 20%. The gene‐environmental interaction was confirmed in case‐only analysis of the German and British studies, yielding an interaction odds ratio of 0.7 for premenopausal women (p = 0.06). Longer duration of pill use was associated with a significantly greater risk reduction (p for trend = 0.015). Our novel observation of a differential effect of OC use on breast cancer risk by PTCH1 1315Leu‐carrier status suggests the interesting possibility of the Sonic hedgehog/Patched (SHH/PTCH1) signaling pathway being involved in hormone‐induced development of breast carcinoma.

CDH1 c-160a promotor polymorphism is not associated with risk of stomach cancer

We have combined data from case control studies designed to test the hypothesis that the c‐160a promotor polymorphism in the gene coding for the cell adhesion molecule E‐cadherin (CDH1) is associated with stomach cancer. A total of 899 individuals (433 patients and 466 controls) were analyzed. The genotype frequencies did not differ significantly between cases and controls, and the genotype‐specific risks were not significantly different from unity, with an odds ratio for heterozygotes compared with the common homozygote of 1.3 (95% CI 0.98–1.8) and 1.2 (0.68–2.0) for rare homozygotes compared with common homozygotes. We found no evidence for differences in risk for the intestinal‐ and diffuse‐type histopathologic subgroups.

Molecular characterization of Patched-associated rhabdomyosarcoma

Mutations in the human homologue of Drosophila Patched1 (PTCH1) have been found in several common tumours including basal cell carcinoma, medulloblastoma, and rhabdomyosarcoma (RMS). Medulloblastoma and RMS are also present in the murine model for Ptch1 deficiency. Tumours in heterozygous Ptch1neo67/+ mice consistently exhibit elevated transcript levels of the proto‐oncogene Gli1, of Ptch1 itself, and of the insulin‐like growth factor 2 (Igf2). The present study has investigated additional molecular changes in RMSs of Ptch1 mutant mice by means of microarray analysis and protein expression analysis. The data show activation of the cell survival‐promoting Akt/protein kinase B (Pkb). Furthermore, RMSs express increased levels of the anti‐apoptotic protein Bcl‐2 and of genes and proteins known to inhibit cell proliferation, including Gadd45a and p27kip1. Taken together, the data suggest that the formation of RMSs in Ptch1 mutants is associated with the ability of tumour cells to resist apoptosis. Copyright

Profiling the molecular difference between Patched - and p53 -dependent rhabdomyosarcoma

Rhabdomyosarcoma (RMS) is a highly malignant tumor that is histologically related to skeletal muscle, yet genetic and molecular lesions underlying its genesis and progression remain largely unknown. In this study we have compared the molecular profiles of two different mouse models of RMS, each associated with a defined primary genetic defect known to play a role in rhabdomyosarcomagenesis in man. We report that RMS of heterozygous Patched1 (Ptch1) mice show less aggressive growth and a greater degree of differentiation than RMS of heterozygous p53 mice. By means of cDNA microarray analysis we demonstrate that RMS in Ptch1 mutants predominantly express a number of myogenic markers, including myogenic differentiation 1, myosin heavy chain, actin, troponin and tropomyosin, as well as genes associated with Hedgehog/Patched signaling like insulin-like growth factor 2, forkhead box gene Foxf1 and the growth arrest and DNA-damage-inducible gene Gadd45a. In sharp contrast, RMS in p53 mutants display higher expression levels of cell cycle-associated genes like cyclin B1, cyclin-dependent kinase 4 and the proliferation marker Ki-67. These results demonstrate that different causative mutations lead to distinct gene expression profiles in RMS, which appear to reflect their different biological characteristics. Our results provide a first step towards a molecular classification of different forms of RMS. If the described differences can be confirmed in human RMS our results will contribute to a new molecular taxonomy of this cancer, which will be critical for gene mutation- and expression-specific therapy.

Tumor-associated E-cadherin mutations do not induce Wnt target gene expression, but affect E-cadherin repressors

E-cadherin is a cell–cell adhesion molecule and tumor invasion suppressor gene that is frequently altered in human cancers. It interacts through its cytoplasmic domain with β-catenin which in turn interacts with the Wnt (wingless) signaling pathway. We have compared the effects of different tumor-derived E-cadherin variants with those of normal E-cadherin on Wnt signaling and on genes involved in epithelial mesenchymal transition. We established an in-house cDNA microarray composed of 1105 different, sequence verified cDNA probes corresponding to 899 unique genes that represent the majority of genes known to be involved in cadherin-dependent cell adhesion and signaling (‘Adhesion/Signaling Array’). The expression signatures of E-cadherin-negative MDA-MB-435S cancer cells transfected with E-cadherin variants (in frame deletions of exon 8 or 9, D8 or D9, respectively, or a point mutation in exon 8 (D370A)) were compared to that of wild-type E-cadherin (WT) transfected cells. From the differentially expressed genes, we selected 38 that we subsequently analyzed by quantitative real-time RT-PCR and/or Northern Blot. A total of 92% of these were confirmed as differentially expressed. Most of these genes encode proteins of the cytoskeleton, cadherins/integrins, oncogenes and matrix metalloproteases. No significant expression differences of genes downstream of the Wnt-pathway were found, except in E-cadherin D8 transfected cells where upregulation of three Tcf/Lef-transcribed genes was seen. One possible reason for the lack of expression differences of the Tcf/Lef-regulated genes is upregulation of SFRP1 and SFRP3; both of which are competitive inhibitors of the Wnt proteins. Interestingly, known E-cadherin transcriptional repressors, such as SLUG (SNAI2), SIP1 (ZEB2), TWIST1, SNAIL (SNAI1) and ZEB1 (TCF8), but not E12/E47 (TCF3), had a lack of upregulation in cells expressing mutated E-cadherin compared to WT. In conclusion, E-cadherin mutations have no influence on expression of genes involved in Wnt-signaling, but they may promote their own expression by blocking upregulation of E-cadherin repressors.