Is the gene encoding Chibby implicated as a tumour suppressor in colorectal cancer ?

To construct an infrastructure for genome-wide association studies of common diseases or drug sensitivities, we have been systematically exploring common variants by resequencing genomic regions containing genes in DNA from 24 Japanese individuals. We have analyzed a total of 154 Mb, corresponding to approximately 5% of the human genome, and so far have identified 174,269 single-nucleotide polymorphisms and 16,293 insertion/deletion polymorphisms within gene regions, i.e., one polymorphism in 807 bp on average. Our data are freely available via our web site (http://snp.ims.u-tokyo.ac.jp) and will facilitate studies to identify genes associated with susceptibility to common diseases and genes involved in sensitivity to therapeutic drugs.

Intensive screening for genetic alteration in colorectal cancer led to the identification of two types of colorectal tumours that are distinct by their carcinogenesis processes. The first group, named LOH (for loss of heterozygosity)-positive, is characterized by hyperploidy and allelic losses involving preferentially chromosome 18q and chromosome 17p. More than two-thirds of colorectal cancers belong to this group. The second group, called multiple microsatellite loci (MSI)-positive cancers, is characterized by genetic instability at microsatellite loci. Although colorectal cancer cells are characterized by specific microsatellite alterations, the same four different signalling pathways, WNT/Wingless pathway, K-ras pathway, transforming growth factor (TGF)beta pathway and p53 pathway, could be implicated in tumour progression. The WNT/Wingless pathway could be altered in two different ways according to whether the cancer cells belong to the group of LOH-positive or MSI-positive tumours. LOH-positive tumours activate the WNT/Wingless signalling pathway through an adenomatous polyposis coli (APC) mutation, whereas the MSI-positive tumours activate this pathway through a beta-catenin stabilizing mutation. Beta-catenin and APC mutations were observed as early as the adenomatous stage of colorectal neoplasia. In TGFbeta pathways LOH-positive tumours inactivated SMAD2 (similar to mother against decapentaplegic drosophilia) or SMAD4, whereas in MSI-positive tumours the TGFbeta type II receptor is frequently deleted. Alteration of these genes correlated closely with the progression of the adenoma to cancer. In the p53 pathway LOH-positive tumours showed frequent p53 mutation, whereas MSI-positive tumours demonstrated BAX (BCL-2-associated X protein)-inactivating mutation. These alterations contribute to the adenoma-carcinoma transition.

Chromosomal deletions are the most frequent genetic alterations observed in hepatocellular carcinoma. Loss of heterozygosity on chromosome 4q has been observed in 40% of hepatocellular carcinomas suggesting the presence of a tumor suppressor gene which has not yet been identified. We developed a semi-automated quantitative genotyping method which allowed us to characterize 119 hepatocellular carcinomas with 22 fluorescent microsatellite markers distributed on chromosome 4q. 4q loss was observed in 40% of cases. Among these deletions, 19 cases of partial or interstitial loss made it possible to define two common minimal regions of deletion of 25.1 and 37.6 centimorgans localized between markers D4S414 and D4S430 and between markers D4S3033 and D4S408, respectively. This work represents the first step towards the identification and characterization of new genes involved in hepatic carcinogenesis.