Comparative karyotype using bidirectional chromosome painting: how and why?

Rat is widely used in biomedical and pharmaceutical research but its genome has been significantly less studied than that of the mouse. This represents a major limitation for studying cytogenetic and molecular mechanisms in the rat model. As Muridae species underwent an intense chromosome evolution it is not possible to directly transpose knowledge of the mouse genome to that of the rat. For establishing a comparative karyotype between rat and mouse, painting probes of both species were prepared by PARM-PCR (Priming Authorizing Random Mismatches PCR) from a low copy number of sorted chromosomes, the mouse and rat specific painting probes being then hybridized on rat and mouse metaphases, respectively. The availability of rodent species chromosome painting probes as well as the information obtained by the comparative karyotype and comparative gene mapping data are of great interest to improve knowledge on species evolution but also to better understand carcinogenesis process, as illustrated by our data concerning the cytogenetic characterization of radon-induced rat lung tumors. Detailed methods for obtaining painting probes by PARM-PCR from sorted mouse and rat chromosomes and for their hybridization in homologous or heterologous conditions are described. Usefulness of chromosome painting is illustrated by the characterization of chromosomal abnormalities in a radon-induced rat lung tumor. Advantages and limitations of this technique as compared to classical cytogenetics, FISH and CGH are discussed.

Clonal evolution of a radon-induced rat lung tumor.

Radon gas may represent a source of pulmonary radio-contamination either in mine or in domestic conditions. Since epidemiological studies are controversial, as long as biological markers of the exposure to such agents will not be identified, the question will remain open. We have previously shown a direct dose-dependent relationship between lung cancer occurrence and radon inhalation of rats. In this study, we report a cytogenetic study of a radon-induced rat lung tumor. Chromosome banding and chromosome specific paintings were performed on cultures of both fresh and xenografted tumors. We found by analyzing 17 sub-clones that all karyotypes presented a translocation involving rat chromosomes (RNO) 8 and 20, and a terminal deletion of RNO 15p suggesting a monoclonal origin of this tumor. RNO 15 is homologous to numerous human chromosomes (HSA), in particular to HSA 3p14.2, 3p22-p24.1 and 3p24.2-p24.3, this human chromosome being frequently lost in human lung carcinomas. Besides sharing chromosome alteration involving common features with those found in human lung cancer, this rat lung carcinoma represents a useful model to study tumor progression with respect to clonal evolution.

CGH analysis of radon-induced rat lung tumors indicates similarities with human lung cancers.

Epidemiological studies have shown that inhalation of radon, a radioactive gas, is associated with an increased risk for lung cancer. We have developed a model of radon-induced rat lung tumors to characterize cytogenetic and molecular events involved in radon-induced lung tumorigenesis. Using comparative genomic hybridization (CGH), gains and losses of genetic material were investigated in a series of 13 carcinomas and four adenomas of the lung. Frequent losses occurred at 4q12-21, 5q11-33, and 15q, which are homologous to human chromosome (HSA) bands 7q21-36, 1p31-36/9p21-31, and 13q14.1-14.3/3p14.2, respectively. These regions are frequently (30-80%) deleted in human lung cancer and contain tumor suppressor genes or proto-oncogenes such as MET, CDKN2A/p16/MTS1, CDKN2B/p15/MTS2, FHIT, and RB1 or yet to be identified genes. Frequent gains involved 6, 7q34-qter, and 19q; chromosomes 6 and 7 being homologous to human 2p21-25 and 8q21-24 where the MYCN and MYC oncogenes are located. The genetic similarities between rat and human lung cancer suggest common underlying mechanisms for tumor evolution in both species. Moreover, cytogenetic and molecular genetic analyses of radon-induced rat lung tumors could help to better understand the development and progression of radon-induced lung cancer in man.