The genetic analysis of cancer

Pearson PL, Van der Luijt RB (Utrecht University, Utrecht, the Netherlands). The genetic analysis of cancer (Minisymposium: MEN & VHL). J Intern Med 1998; 243: 413–17. During the past two decades an overwhelming amount of knowledge has been acquired on the molecular genetics of human cancer. It...

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Published in:Journal of internal medicine 1998-06, Vol.243 (6), p.413-417
Main Authors: PEARSON, P. L, VAN DER LUIJT, R. B
Format: Article
Language:English
Subjects:
Biological and medical sciences
cancer genetics
Carcinogenesis, carcinogens and anticarcinogens
DNA repair genes
DNA, Neoplasm - genetics
General aspects
Genes, Tumor Suppressor - genetics
hereditary cancer
Humans
Medical sciences
multistep process
Mutation
Neoplasms - genetics
Proto-Oncogenes - genetics
proto‐oncogenes
Tumors
tumour suppressor genes
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Summary:Pearson PL, Van der Luijt RB (Utrecht University, Utrecht, the Netherlands). The genetic analysis of cancer (Minisymposium: MEN & VHL). J Intern Med 1998; 243: 413–17. During the past two decades an overwhelming amount of knowledge has been acquired on the molecular genetics of human cancer. It is now evident that cancer is essentially a genetic disease, arising from inherited and/or somatically acquired mutations at different genetic loci, and that tumourigenesis is a multistep process. Gene mapping studies of inherited cancer syndromes have resulted in the identification of many genes implicated in the initiation of tumours. Importantly, alterations of the same genes were also found to play a role in the development of common, non‐familial tumours. The genes involved belong to distinct functional classes, and include proto‐oncogenes and tumour suppressor genes, which are regulators of cellular growth and proliferation, cell adhesion and programmed cell death. Another class of cancer susceptibility genes consists of DNA repair genes, which are involved in maintaining genomic stability. In unravelling the genetic basis of cancer, the localization and identification of genes involved in tumourigenesis can be considered as the ‘easy’ part; determination of the normal physiological function of these genes and their precise role in tumourigenesis has proved to be much more difficult. In this review, we highlight some of the major breakthroughs in the field of cancer genetics, and discuss recent insights in the putative role of proto‐oncogenes, tumour suppressor genes and DNA repair genes in the initiation and progression of cancer. Also, we point to some of the challenges to be faced in the coming years.
ISSN:0954-6820
1365-2796
DOI:10.1046/j.1365-2796.1998.00343.x