Directory to the human genome

Development of molecular genetics

Human genetics has rapidly evolved from vague impression that descendants resemble their parents, to science which is now of utmost importance to the development of new principles and practice in medicine. It was only in the beginning of this century when it was suggested that chromosomes might carry genetic information. During the two last decades researchers have developed amazing methods to study and manipulate genes. This has created new possibilities to diagnose and cure diseases, but also raised ethical and legal questions. These developments are outlined in the present paper.

Molecular cytogenetic analysis of consistent abnormalities at 8q12-q22 in breast cancer

Studies using comparative genomic hybridization (CGH) indicate that portions of chromosome arm 8q from 8q12 to 8qter are present at an increased relative copy number in a broad range of solid tumors. In this study we define an approximately 1 Mb wide region that appears to be frequently abnormal in copy number or structure in breast cancer cell lines and primary tumors. This was accomplished by fluorescence in situ hybridization (FISH) with yeast artificial chromosomes (YACs) mapped to 8q2-q22. Eleven breast cancer cell lines and ten primary tumors were analyzed. A minimal region of rearrangement was localized to the CEPH-YAC 928F9 in three breast cancer cell lines with unbalanced translocation breakpoints mapping in this region. Unbalanced translocations also were detected in two primary tumors mapping between CEPH-YAC clones 890C4 and 936B3, flanking 928F9. An increased copy number in the minimal region was detected in nine cell lines and in multiple primary tumors. This suggests the possibility that a single gene mapping to 928F9 is involved in breast cancer development or progression and may be deregulated by copy number increases in some tumors and by translocation in others. Four expressed sequence tags were mapped to YAC 928F9 and analyzed for rearrangements by Southern analysis and for abnormal expression by Northern analysis.

Using targeted large deletions and high-efficiency N-ethyl-N-nitrosourea mutagenesis for functional analyses of the mammalian genome

The Human Genome Project has generated nucleotide sequences from an estimated 80,000 to 100,000 genes, only a small fraction of which have a known role. Nucleotide sequence information alone is insufficient to predict gene function. One of the most powerful ways of revealing gene function, as demonstrated in bacteria, worms, yeast, and flies, is to generate mutations and characterize them at both the phenotypic and the molecular levels. Given the physiological and anatomical parallels between mouse and human, genotype-phenotype relationships established in mice can be extrapolated to human syndromes. A new method is described for functional genetic analyses in the mouse that uses loxP/Cre engineering to generate coat color-tagged large deletions. The haploid regions can then be dissected by mutagenesis with N-ethyl-N-nitrosourea in phenotype-driven screens to obtain functional information on genes in any desired region of the mouse genome.