Somatic mutations in familial adenomatous polyps. Nuclear translocation of beta-catenin requires more than biallelic APC inactivation

Germline mutations of the APC gene cause familial adenomatous polyposis coli (FAP). APC inactivation results in dysregulation of wnt/wingless signaling and contributes to chromosomal instability in vitro. To investigate somatic alterations that follow a known germline mutation and contribute to the transition from normal to neoplastic mucosa, we studied 10 adenomatous polyps from a 27-year-old patient with an APC germline mutation at codon 554. Chromosomal imbalances were analyzed by comparative genomic hybridization; APC and K-ras were screened for somatic mutations. Before DNA analysis, the polyps were bisected to compare the genetic alterations with the corresponding immunohistologic phenotype of beta-catenin, a proto-oncogene product degraded by the APC tumor suppressor. Gains at chromosome 20 were the most frequent chromosomal alterations (6 polyps). Losses were found predominantly at chromosome 4q (3 polyps). A K-ras mutation was seen in 1 polyp, while all polyps displayed somatic intragenic APC mutations. Comparative immunohistologic analysis revealed strong membranous staining for beta-catenin in all adenomatous polyps, but only 1 adenoma showed nuclear accumulation. Our results suggest chromosomal aberrations contribute early to the progression of adenomatous polyps after biallelic APC inactivation. APC inactivation itself is insufficient for immunohistochemically detectable nuclear translocation of beta-catenin.