Performance Characteristics of a Targeted Sequencing Platform for Simultaneous Detection of Single Nucleotide Variants, Insertions/Deletions, Copy Number Alterations, and Gene Fusions in Cancer Genome.

CONTEXT.­: An increasing number of molecular laboratories are implementing next-generation sequencing platforms to identify clinically actionable and relevant genomic alterations for precision oncology. OBJECTIVE.­: To describe the validation studies as per New York State-Department of Health (NYS-DOH) guidelines for the Oncomine Comprehensive Panel v2, which was originally tailored to the National Cancer Institute Molecular Analysis for Therapy Choice (NCI-MATCH) trial. DESIGN.­: Accuracy, precision, and reproducibility were investigated by using 130 DNA and 18 RNA samples from cytology cell blocks; formalin-fixed, paraffin-embedded tissues; and frozen samples. Analytic sensitivity and specificity were tested by using ATCC and HapMap cell lines. RESULTS.­: High accuracy and precision/reproducibility were observed for single nucleotide variants and insertion/deletions. We also share our experience in the detection of gene fusions and copy number alterations from an amplicon-based sequencing platform. After sequencing analysis, variant annotation and report generation were performed by using the institutional knowledgebase. CONCLUSIONS.­: This study serves as an example for validating a comprehensive targeted next-generation sequencing assay with both DNASeq and RNASeq components for NYS-DOH.

Integrative Molecular Analysis of Patients With Advanced and Metastatic Cancer.

PURPOSE: We developed a precision medicine program for patients with advanced cancer using integrative whole-exome sequencing and transcriptome analysis. PATIENTS AND METHODS: Five hundred fifteen patients with locally advanced/metastatic solid tumors were prospectively enrolled, and paired tumor/normal sequencing was performed. Seven hundred fifty-nine tumors from 515 patients were evaluated. RESULTS: Most frequent tumor types were prostate (19.4%), brain (16.5%), bladder (15.4%), and kidney cancer (9.2%). Most frequently altered genes were TP53 (33%), CDKN2A (11%), APC (10%), KTM2D (8%), PTEN (8%), and BRCA2 (8%). Pathogenic germline alterations were present in 10.7% of patients, most frequently CHEK2 (1.9%), BRCA1 (1.5%), BRCA2 (1.5%), and MSH6 (1.4%). Novel gene fusions were identified, including a RBM47-CDK12 fusion in a metastatic prostate cancer sample. The rate of clinically relevant alterations was 39% by whole-exome sequencing, which was improved by 16% by adding RNA sequencing. In patients with more than one sequenced tumor sample (n = 146), 84.62% of actionable mutations were concordant. CONCLUSION: Integrative analysis may uncover informative alterations for an advanced pan-cancer patient population. These alterations are consistent in spatially and temporally heterogeneous samples.

Detection of BRAF V600 mutations in metastatic melanoma: comparison of the Cobas 4800 and Sanger sequencing assays.

Detection of the BRAF V600E mutation is required for use of the BRAF inhibitor, vemurafenib, in patients with metastatic melanoma. Although the Roche Cobas 4800 BRAF V600 Mutation Test is approved, it detects primarily the single-nucleotide V600E mutation and could miss other potentially relevant V600 mutations. To assess the detection rate of the cobas assay for V600 mutations in clinical specimens, we compared the results of this assay with Sanger sequencing in 295 melanoma FFPE samples. Twenty samples were excluded because of invalid results on the cobas (n = 3), sequencing (n = 15), or both (n = 2). V600 mutations were detected by the cobas test in 96 (34.9%) of 275 samples and by Sanger sequencing in 118 (42.9%) of 275 samples. Thus, relative to Sanger sequencing, the cobas test exhibited 80.5% sensitivity (95% CI, 72.4% to 86.6%) and 99.4% specificity (95% CI, 96.5% to 99.9%). Of 23 samples with positive sequencing results but negative cobas results, 21 harbored dinucleotide mutations (V600E in 6, V600K in 10, and V600R in 5); the other two involved single-nucleotide mutations (V600E and V600G). These findings indicate that the cobas assay may miss many V600 mutations in clinical specimens. In our study, the addition of Sanger sequencing for samples with negative cobas results increased the detection rate to 42.9%. This approach could help maximize the number of patients who benefit from BRAF inhibitor treatment.

Incidence and patterns of ALK FISH abnormalities seen in a large unselected series of lung carcinomas.

BACKGROUND: Anaplastic lymphoma receptor tyrosine kinase (ALK) gene rearrangements have been reported in 2-13% of patients with non-small cell lung cancer (NSCLC). Patients with ALK rearrangements do not respond to EGFR-specific tyrosine kinase inhibitors (TKIs); however, they do benefit from small molecule inhibitors targeting ALK. RESULTS: In this study, fluorescence in situ hybridization (FISH) using a break-apart probe for the ALK gene was performed on formalin fixed paraffin-embedded tissue to determine the incidence of ALK rearrangements and hybridization patterns in a large unselected cohort of 1387 patients with a referred diagnosis of non-small cell lung cancer (1011 of these patients had a histologic diagnosis of adenocarcinoma). The abnormal FISH signal patterns varied from a single split signal to complex patterns. Among 49 abnormal samples (49/1387, 3.5%), 32 had 1 to 3 split signals. Fifteen samples had deletions of the green 5' end of the ALK signal, and 1 of these 15 samples showed amplification of the orange 3' end of the ALK signal. Two patients showed a deletion of the 3'ALK signal. Thirty eight of these 49 samples (38/1011, 3.7%) were among the 1011 patients with confirmed adenocarcinoma. Five of 8 patients with ALK rearrangements detected by FISH were confirmed to have EML4-ALK fusions by multiplex RT-PCR. Among the 45 ALK-rearranged samples tested, only 1 EGFR mutation (T790M) was detected. Two KRAS mutations were detected among 24 ALK-rearranged samples tested. CONCLUSIONS: In a large unselected series, the frequency of ALK gene rearrangement detected by FISH was approximately 3.5% of lung carcinoma, and 3.7% of patients with lung adenocarcinoma, with variant signal patterns frequently detected. Rare cases with coexisting KRAS and EGFR mutations were seen.

Dextrocardia, atrial septal defect, severe developmental delay, facial anomalies, and supernumerary ribs in a child with a complex unbalanced 8;22 translocation including partial 8p duplication.

We report on a child with dextrocardia, atrial septal defect (ASD), severe developmental delay, hypotonia, 13 pairs of ribs, left preauricular choristoma, hirsutism, and craniofacial abnormalities. Prenatal cytogenetic evaluation showed karyotype 46,XY,?dup(8p)ish del(8)pter. Postnatal array CGH demonstrated a 6.8 Mb terminal deletion at 8p23.3-p23, an interstitial 31.1 Mb duplication within 8p23.1-p11, and a terminal duplication of 0.24 Mb at 22q13.33, refining the karyotype to 46,XY,der(8)dup(8)(p23.1p11.1)t(8;22)(p23.1;q13.1).ish der(8)dup(8)(p23.1p11.1)t(8;22)(p23.1;q13.1) (D8S504-,MS607 + ,ARSA + ,D8Z1 + , RP115713 + +). Previous reports of distal 8p deletion, 8p duplication, and distal 22q duplication have shown similar manifestations, including congenital heart disease, intellectual impairment, and multiple minor anomalies. We correlate the patient's clinical findings with these particular areas of copy number. This case study supports the use of aCGH to identify subtle chromosomal rearrangement in infants with cardiac malformation as their most significant or only apparent birth defect. Additionally, it illustrates why aCGH is essential in the description of chromosome rearrangements, even those seemingly visible via routine karyotype. This method shows that there is often greater complexity submicroscopically, essential to an adequate understanding of a patient's genotype and phenotype.

Molecular characterization of an interstitial deletion of 1p31.3 in a patient with obesity and psychiatric illness and a review of the literature.

We report on the clinical and array-based characterization of an interstitial 1p31.3 deletion in a 15-year-old male patient with obesity, behavioral problems including multiple psychiatric diagnoses, mild intellectual impairment, facial dysmorphism, and a strong family history of psychiatric illness. The deletion breakpoints were determined by molecular karyotyping, revealing a 3.2 Mb excision. Patients previously reported with hemizygous deletions including this cytogenetic band had intellectual impairment and some facial features that overlap with our patient's phenotype. However, their deletions were larger, encompassing several cytogenetic bands, making this case the smallest deletion to date that we are aware of sharing these phenotypic characteristics. There are 17 genes that map to the interval. Two genes within the interval, LEPR and PDE4B, are interesting candidates for these phenotypes because of their potential role in obesity and psychiatric illness, respectively. Identification of the smaller deletion underscores the importance of combining clinical investigation and array comparative genomic hybridization analysis for appropriate diagnosis, genetic counseling and potentially for prenatal diagnosis.

Both gene amplification and allelic loss occur at 14q13.3 in lung cancer.

PURPOSE: Because loss of Nkx2-8 increases lung cancer in the mouse, we studied suppressive mechanisms in human lung cancer. EXPERIMENTAL DESIGN: NKX2-8 is located within 14q13.3, adjacent to its close relative TTF1/NKX2-1. We first analyzed LOH of 14q13.3 in forty-five matched human lung cancer and control specimens. DNA from tumors with LOH was then analyzed with high-density single-nucleotide polymorphism (SNP) arrays. For correlation with this genetic analysis, we quantified expression of Nkx2-8 and TTF1 mRNA in tumors. Finally, suppressive function of Nkx2-8 was assessed via colony formation assays in five lung cancer cell lines. RESULTS: Thirteen of forty-five (29%) tumors had LOH. In six tumors, most adenocarcinomas, LOH was caused by gene amplification. The 0.8-Mb common region of amplification included MBIP, SFTA, TTF1, NKX2-8, and PAX9. In 4 squamous or adenosquamous cancers, LOH was caused by deletion. In three other tumors, LOH resulted from whole chromosome mechanisms (14(-), 14(+), or aneuploidy). The 1.2-Mb common region of deletion included MBIP, SFTA, TTF1, NKX2-8, PAX9, SLC25A21, and MIPOL1. Most tumors had low expression of Nkx2-8. Nevertheless, sequencing did not show NKX2-8 mutations that could explain the low expression. TTF1 overexpression, in contrast, was common and usually independent of Nkx2-8 expression. Finally, stable transfection of Nkx2-8 selectively inhibited growth of H522 lung cancer cells. CONCLUSIONS: 14q13.3, which contains NKX2-8, is subject to both amplification and deletion in lung cancer. Most tumors have low expression of Nkx2-8, and its expression can inhibit growth of some lung cancer cells.

Evaluation of the 3M rapid detection test for respiratory syncytial virus (RSV) in children during the early stages of the 2009 RSV season.

We report the results of the 3M rapid detection respiratory syncytial virus (RSV) assay. This study includes pediatric patient results from nasopharyngeal swabs submitted from October to December 2009. There was a sensitivity of 74% and specificity approaching 100% compared to the PCR-based xTAG respiratory viral panel.

Clinical significance of low levels of minimal residual disease at the end of remission induction therapy in childhood acute lymphoblastic leukemia.

Minimal residual disease (MRD) at the end of remission-induction therapy predicts relapse in acute lymphoblastic leukemia (ALL). We examined the clinical significance of levels below the usual threshold value for MRD positivity (0.01%) in 455 children with B-lineage ALL, using polymerase chain reaction amplification of antigen-receptor genes capable of detecting at least 1 leukemic cell per 100 000 normal mononucleated cells (0.001%). Of the 455 clinical samples studied on day 46 of therapy, 139 (30.5%) had MRD 0.001% or more with 63 of these (45.3%) showing levels of 0.001% to less than 0.01%, whereas 316 (69.5%) had levels that were either less than 0.001% or undetectable. MRD measurements of 0.001% to less than 0.01% were not significantly related to presenting characteristics but were associated with a poorer leukemia cell clearance on day 19 of remission induction therapy. Patients with this low level of MRD had a 12.7% (+/- 5.1%; SE) cumulative risk of relapse at 5 years, compared with 5.0% (+/- 1.5%) for those with lower or undetectable MRD (P < .047). Thus, low levels of MRD (0.001%-< 0.01%) at the end of remission induction therapy have prognostic significance in childhood ALL, suggesting that patients with this finding should be monitored closely for adverse events.

Comparison of BIOMED-2 versus laboratory-developed polymerase chain reaction assays for detecting T-cell receptor-gamma gene rearrangements.

Detecting clonal T-cell receptor (TCR)-gamma gene rearrangements (GRs) is an important adjunct test for diagnosing T-cell lymphoma. We compared a recently described assay (BIOMED-2 protocol), which targets multiple variable (V) gene segments in two polymerase chain reaction (PCR) reactions (multi-V), with a frequently referenced assay that targets a single V gene segment in four separate PCR reactions (mono-V). A total of 144 consecutive clinical DNA samples were prospectively tested for T-cell clonality by PCR using laboratory-developed mono-V and commercial multi-V primer sets for TCR-gamma GR. The combination of TCR-beta, mono-V TCR-gamma and multi-V TCR-gamma detected more clonal cases (68/144, 47%) than any individual PCR assay. We detected clonal TCR-beta GR in 47/68 (69%) cases. Using either mono-V or multi-V TCR-gamma primers, the sensitivities for detecting clonality were 52/68 (76%) or 51/68 (75%). Using both mono-V and multi-V TCR-gamma primers improved the sensitivity for detecting clonality, 60/68 (88%). Combining either mono-V or multi-V TCR-gamma primers with TCR-beta primers also improved the sensitivity, 64/68 (94%). Significantly, TCR-gamma V11 GRs could only be detected using the mono-V-PCR primers. We conclude that using more than one T-cell PCR assay can enhance the overall sensitivity for detecting T-cell clonality.

Comparative evaluation of three JAK2V617F mutation detection methods.

The correlation of JAK2V617F with a proportion of chronic myeloproliferative disorders has generated numerous studies focused on the development of molecular-based assays for JAK2V617F detection. The current parallel study comparatively evaluated 3 JAK2V617F molecular detection methods. Genomic DNA from blood or bone marrow was assayed by 3 laboratories using allele-specific polymerase chain reaction (AS-PCR) or kit-based restriction fragment length polymorphism methods, which used polyacrylamide gel or capillary electrophoresis analysis. In addition, samples were sequenced in 2 of the laboratories. Results found 100% concordance among the 3 methods, with analytic sensitivities of 5% for both kit methods and 0.01% for AS-PCR. The kitbased assays detect JAK2V617F with equal sensitivity regardless of analysis method, and, despite greater sensitivity of AS-PCR, all 3 methods yielded 100% concordant results for this 36-sample set. Consistent with other reports, direct sequencing was insufficiently sensitive to serve as an initial diagnostic tool for JAK2V617F detection.

CYP2C9 and VKORC1 genetic polymorphism analysis might be necessary in patients with Factor V Leiden and prothrombin gene G2021A mutation(s).

The annual incidence of venous thromboembolism is approximately 117 per 100,000 persons or about 1 per 1000 person-years, with the majority of the disease occurring in the older age groups. Factor V Leiden gene (most common) and the prothrombin G20210A gene mutation are inherited mild to moderate risk factors for hypercoagulability. The anticoagulant warfarin requires close monitoring of the patient's prothrombin time, normalized as the international normalization ratio. Patients with either Cytochrome P-450 CYP2C9*2, CYP2C9*3, or VKORC1*2 genotype (c.-1639G>A) require significantly reduced doses, and are at a higher risk of serious bleeding. Thirty-five samples in total, 15 with Factor V Leiden, 18 with prothrombin G2021A mutation, and 2 with both were analyzed for 2C9*2, 2C9*3, and VKORC1 (-1639) allele variants by using the Invader CYP2C9 and VKORC1 polymorphism analysis kit. Eight with CYP2C9*2 C/T, 2 with CYP2C9*3 A/C, 5 with VKORC1 (-1639) A/A, and 22 with VKORC1 (-1639) G/A genotypes or 29 out of 35 (83%) samples analyzed were found with CYP2C9*2 C/T, CYP2C9*3 A/C, VKORC1 (-1639) G/A, or/and VKORC1 (-1639) A/A genotypes. CYP2C9*2 C/T, CYP2C9*3 A/C, VKORC1 (-1639) G/A genotyping might be necessary for patients with Factor V Leiden and/or prothrombin G2021A mutation before warfarin anticoagulant therapy.

Profound inhibition of the PCR step of CF V3 multiplex PCR/OLA assay by the use of UV-irradiated plastic reaction tubes.

Supplies, such as bags of plastic reaction tubes, are sometimes left in the laminar flow hoods unintentionally while the ultraviolet (UV) lamp is illuminated overnight. In addition, UV irradiation is used for sterilization and amplicon inactivation to avoid contamination. The oligonucleotide ligation assay (OLA) is a unique approach to mutation detection of point mutations, small deletions, and small insertions. Recently, we encountered problems with this assay and peak heights were much lower or disappeared. After going through systemic trouble-shooting, we found that profound inhibition of the polymerase chain reaction (PCR) step of CF V3 multiplex PCR/OLA assay by the use of UV-irradiated plastic reaction tubes. When UV-irradiated tubes used throughout the assay, tubes exposed for 8 weeks at 0.7 m from the UV source gave a reduction of 60% and 67% in the assay products on the basis of sum of peak heights. Tubes exposed for 3 weeks at 0.1 m from the UV source totally eliminated assay product yielding no peaks. Further experiments showed that the inhibition happened mostly in the PCR step. Burgess and Hall had reported that inhibition of PCR of human glyceraldehydes-3-phosphate dehydrogenase transcripts after UV irradiating the tubes. This showed that the inhibition was not assay-specific. The reason that the inhibition of PCR was more profound could be due to a multiplex PCR assay and small reaction volume. The mechanism of PCR inhibition by UV irradiation is not clear. In conclusion, plastic reaction tubes intended for PCR/OLA assays should not be exposed to UV.

Validation of rapid polymerase chain reaction-based detection of all length polymorphisms in the UGT 1A1 gene promoter.

UDP glucuronosyltransferase (UGT) 1A1 gene promoter polymorphism can affect the expression level of the UGT 1A1 enzyme. The polymorphism consists of an insertion of a TA nucleotide sequence into a (TA)6TAA sequence in the gene promoter resulting in (TA)7TAA (UGT1A1*28). This results in a reduced UGT 1A1 expression with 70% less glucuronidation capacity for bilirubin and other UGT1A1 substrates. Other polymorphisms include (TA)8TAA (UGT1A1*37) and (TA)5TAA (UGT1A1*36). The longer the TA repeats the lower the enzyme expression level. The anticancer agent irinotecan is metabolized to the active SN-38, which is further glucuronidated and detoxified by UGT 1A1. Decreased glucuronidation leads to SN-38 accumulation with severe neutropenia and diarrhea. We have developed a rapid polymerase chain reaction (PCR)-based detection of all length polymorphisms in the UGT 1A1 gene promoter. It uses PCR and DNA fragment analysis using an ABI Genetic Analyzer. Thirty-two blood samples were analyzed for UGT 1A1 promoter polymorphism. We found 2 (TA)(5)TAA/(TA)(5)TAA, 4 (TA)(5)TAA/(TA)(6)TAA, 2 (TA)(5)TAA/(TA)(7)TAA, 9 (TA)(6)TAA/(TA)(6)TAA, 11 (TA)(6)TAA/(TA)(7)TAA, 2 (TA)(7)TAA/(TA)(7)TAA, and 2 (TA)(7)TAA/(TA)(8)TAA in our sample group. To confirm the results, 6 samples with different repeats were also analyzed by DNA sequencing method. This is a rapid and reliable method for analysis of the promoter length polymorphisms of UGT 1A1 gene.

Validation of cystic fibrosis mutation analysis using ABI 3130XL genetic analyzer.

Cystic fibrosis (CF) is one of the most common autosomal recessive diseases in the white population, with a prevalence estimate of 1 in 2500 to 3300 live births. CF is characterized by viscous mucus in the lungs with involvement of digestive and reproductive systems as well as sweat glands (excess salt loss). Treatment for CF patients is palliative. Over 1300 mutations have been identified in the CFTR gene. However, most of the mutations are at frequencies of <0.1% or represent private mutations. Although other methodologies are available for CF testing, the oligonucleotide ligation assay is a unique approach to mutation detection of point mutations, small deletions, and small insertions, and consists of 2 phases. Applied Biosystems 3130 Series Genetic Analyzers are the next-generation platform for low to medium throughput laboratories and deliver improved performance. One disadvantage of the Genetic Analyzers is that there is no template of instrument settings for POP-6 polymer using 36-cm array. The Abbott CF oligonucleotide ligation assay ASRs can be run only using POP-6 polymer. We are the first to have optimized the instrument settings for POP-6 polymer based on the template of Rapidseq36-POP6 for Abbott Diagnostics CF V3 ASRs. Several conditions were tried, and the conditions of sample injection voltage at 10,000 v and sample injection time at 5 seconds gave better results, which were with clearer peaks and lower background signals. Twenty cell line DNA samples from Coriell were analyzed, and the results were matched. In addition, Synthetic Controls from AcroMetrix were analyzed, and the results were same as expected. Also, about 1500 clinical samples were analyzed, and high-quality reportable results were obtained. In conclusion, our modified protocol is robust and reliable on this ABI 3130XL instrument.

Validation of the 2-DeltaDeltaCt calculation as an alternate method of data analysis for quantitative PCR of BCR-ABL P210 transcripts.

Chronic myelogenous leukemia (CML) is a clonal myeloproliferative disorder that is characterized by the presence of a reciprocal translocation between chromosomes 9 and 22 and results in the formation of the Philadelphia (Ph1) chromosome and is present in most of CML patients. The Ph1 chromosome forms a chimeric gene that encodes an abnormal P210 mRNA transcript in most CML patients. Surveillance for minimal residual disease by detection of BCR/ABL transcripts is currently done mostly by quantitative real-time reverse transcriptase polymerase chain reaction (RT-PCR). Quantitation of BCR/ABL transcripts can monitor tumor load and the outcome of therapy. Absolute quantification determines the input copy number of the transcript of interest, usually by plotting the amount of PCR product onto a standard curve based on serial dilutions of the same product cloned in plasmids. Relative quantification describes the change in expression of the target gene in the patient sample relative to that of a control transcript by using the 2-DeltaDeltaCt calculation. The results of real-time RT-PCR for BCR/ABL transcripts are often analyzed by using plasmid DNA standard curves. In the present study, 79 BCR/ABL transcript-positive samples from CML patients who were being monitored for minimal residual disease by real-time quantitative RT-PCR were studied to determine whether the 2-DeltaDeltaCt approach was equivalent to the plasmid standard curve method. BCR/ABL P210 transcripts were quantitated using both the plasmid standard curve method and the 2-DeltaDeltaCt calculation. The comparison of both methods revealed a highly significant and linear correlation between the plasmid standard curve method and the 2-DeltaDeltaCt calculation (R2=0.98, P<0.0001). Furthermore, there was a reduction of preparation time, contamination risk, and reagent usage. The 2-DeltaDeltaCt calculation is a convenient alternative method to derive accurate quantitative information from real time PCR assays.

Rapid polymerase chain reaction-based detection of epidermal growth factor receptor gene mutations in lung adenocarcinomas.

Somatic mutations in the tyrosine kinase domain of the epidermal growth factor receptor (EGFR) gene are present in lung adenocarcinomas that respond to the EGFR inhibitors gefitinib and erlotinib. Two types of mutations account for approximately 90% of mutated cases: short in-frame deletions in exon 19 and a specific point mutation in exon 21 at codon 858 (L858R). Screening for these mutations has been based mainly on direct sequencing. We report here the development and validation of polymerase chain reaction-based assays for these two predominant types of EGFR mutations. The assay for exon 19 mutations is based on length analysis of fluorescently labeled polymerase chain reaction products, and the assay for the exon 21 L858R mutation is based on a new Sau96I restriction site created by this mutation. Using serial dilutions of DNAs from lung cancer cell lines harboring either exon 19 or 21 mutations, we detected these mutations in the presence of up to approximately 90% normal DNA. In a test set of 39 lung cancer samples, direct sequencing detected mutations in 25 cases whereas our assays were positive in 29 cases, including 4 cases in which mutations were not apparent by sequencing. These assays offer higher sensitivity and ease of scoring and eliminate the need for sequencing, providing a robust and accessible approach to the rapid identification of most lung cancer patients likely to respond to EGFR inhibitors.

EGFR gene amplification in breast cancer: correlation with epidermal growth factor receptor mRNA and protein expression and HER-2 status and absence of EGFR-activating mutations.

The human epidermal growth factor receptor (HER) family of receptor tyrosine kinase has been extensively studied in breast cancer; however, systematic studies of EGFR gene amplification and protein overexpression in breast carcinoma are lacking. We studied EGFR gene amplification by chromogenic in situ hybridization (CISH) and protein expression by immunohistochemistry in 175 breast carcinomas, using tissue microarrays. Tumors with >5 EGFR gene copies per nucleus were interpreted as positive for gene amplification. Protein overexpression was scored according to standardized criteria originally developed for HER-2. EGFR mRNA levels, as measured by Affymetrix U133 Gene Chip microarray hybridization, were available in 63 of these tumors. HER-2 gene amplification by fluorescence in situ hybridization (FISH) and protein overexpression by immunohistochemistry were also studied. EGFR gene amplification (copy number range: 7-18; median: 12) was detected in 11/175 (6%) tumors, and protein overexpression was found in 13/175 (7%) tumors. Of the 11 tumors, 10 (91%) with gene amplification also showed EGFR protein overexpression (2+ or 3+ by immunohistochemistry). The EGFR mRNA level, based on Affymetrix U133 chip hybridization data, was increased relative to other breast cancer samples in three of the five tumors showing gene amplification. Exons 19 and 21 of EGFR, the sites of hotspot mutations in lung adenocarcinomas, were screened in the 11 EGFR-amplified tumors but no mutations were found. Three of these 11 tumors also showed HER-2 overexpression and gene amplification. Approximately 6% of breast carcinomas show EGFR amplification with EGFR protein overexpression and may be candidates for trials of EGFR-targeted antibodies or small inhibitory molecules.

KRAS mutations and primary resistance of lung adenocarcinomas to gefitinib or erlotinib.

BACKGROUND: Somatic mutations in the gene for the epidermal growth factor receptor (EGFR) are found in adenocarcinomas of the lung and are associated with sensitivity to the kinase inhibitors gefitinib (Iressa) and erlotinib (Tarceva). Lung adenocarcinomas also harbor activating mutations in the downstream GTPase, KRAS, and mutations in EGFR and KRAS appear to be mutually exclusive. METHODS AND FINDINGS: We sought to determine whether mutations in KRAS could be used to further enhance prediction of response to gefitinib or erlotinib. We screened 60 lung adenocarcinomas defined as sensitive or refractory to gefitinib or erlotinib for mutations in EGFR and KRAS. We show that mutations in KRAS are associated with a lack of sensitivity to either drug. CONCLUSION: Our results suggest that treatment decisions regarding use of these kinase inhibitors might be improved by determining the mutational status of both EGFR and KRAS.