Correlations of EGFR mutations and increases in EGFR and HER2 copy number to gefitinib response in a retrospective analysis of lung cancer patients.

BACKGROUND: Gefitinib, a small molecule tyrosine kinase inhibitor of the Epidermal Growth Factor Receptor (EGFR), has shown limited efficacy in the treatment of lung cancer. Recognized clinical predictors of response to this drug, specifically female, non-smoker, Asian descent, and adenocarcinoma, together suggest a genetic basis for drug response. Recent studies have addressed the relationship between response and either sequence mutations or increased copy number of specific receptor tyrosine kinases. We set out to examine the relationship between response and the molecular status of two such kinases, EGFR and HER2, in 39 patients treated with gefitinib at the BC Cancer Agency. METHODS: Archival patient material was reviewed by a pathologist and malignant cells were selectively isolated by laser microdissection or manual recovery of cells from microscope slides. Genomic DNA was extracted from 37 such patient samples and exons 18-24, coding for the tyrosine kinase domain of EGFR, were amplified by PCR and sequenced. EGFR and HER2 copy number status were also assessed using FISH in 26 samples. Correlations between molecular features and drug response were assessed using the two-sided Fisher's exact test. RESULTS: Mutations previously correlated with response were detected in five tumours, four with exon 19 deletions and one with an exon 21 missense L858R point mutation. Increased gene copy number was observed in thirteen tumours, seven with EGFR amplification, three with HER2 amplification, and three with amplification of both genes. In our study cohort, a correlation was not observed between response and EGFR mutations (exon 19 deletion p = 0.0889, we observed a single exon 21 mutation in a non-responder) or increases in EGFR or HER2 copy number (p = 0.552 and 0.437, respectively). CONCLUSION: Neither mutation of EGFR nor increased copy number of EGFR or HER2 was diagnostic of response to gefitinib in this cohort. However, validation of these features in a larger sample set is appropriate. Identification of additional predictive biomarkers beyond EGFR status may be necessary to accurately predict treatment outcome.

Uncovering novel inter- and intrachromosomal chromosome 1 aberrations in follicular lymphomas by using an innovative multicolor banding technique.

Follicular lymphoma (FL) is characterized by t(14;18)(q32;q21), which is the initial genetic perturbation in this disease. Additional genetic mutations are required to generate a fully malignant phenotype. Secondary chromosomal alterations seen in FL include prominent involvement of chromosome 1 in the form of balanced or unbalanced translocations, insertions, deletions, and duplications involving both the p and q arms. We investigated a diagnostically well defined set of 55 t(14;18)-positive FL cases with complex karyotypes by means of multicolor karyotyping. Sixteen cases showed involvement of chromosome 1 and were analyzed in further detail by a novel multicolor banding technique for this chromosome. We defined three groups showing varying complexity of chromosome 1 alterations. The first group revealed simple translocations, such as t(1;2), t(1;6), t(1;8), and t(1;17), involving breakpoints on either the p or the q arm of chromosome 1. The second group showed more complex rearrangements with translocations, insertions, regional duplications, and involvement of more than one partner chromosome with either the p or the q arm of chromosome 1. The third group was defined by highly complex rearrangements involving translocations, regional duplications, amplifications, and intrachromosomal band relocations affecting the entire chromosome 1. All three groups shared interchromosomal rearrangements of chromosome 1 with chromosome 8, often involving the MYC protooncogene site, amplification involving region 1q21-q31, and deletion involving region 1p36. Thus, the use of sophisticated multicolor molecular cytogenetic assays in the investigation of malignant lymphoma allows precise characterization of chromosomal alterations and will provide a better understanding of their biology.