Frederic Waldman

FOXP3-positive regulatory T lymphocytes and epithelial FOXP3 expression in synchronous normal, ductal carcinoma in situ, and invasive cancer of the breast

FOXP3-expressing T regulatory lymphocytes (Tregs) have been described as putative mediators of immune tolerance, and thus facilitators of tumor growth. When found in association with various malignancies, Tregs are generally markers of poor clinical outcome. However, it is unknown whether they are also associated with cancer progression. We evaluated quantitative FOXP3 expression in lymphocytes as well as in epithelial cells in a set of thirty-two breast tumors with synchronous normal epithelium, ductal carcinoma in situ (DCIS), and invasive ductal carcinoma (IDC) components. Tumors were stained for FOXP3 and CD3 expression and Tregs quantified by determining the ratio of colocalized FOXP3 and CD3 relative to 1) total CD3-expressing lymphocytes and 2) to FOXP3-expressing epithelial cells. The median proportion of FOXP3-expressing CD3 cells significantly increased with malignant progression from normal to DCIS to IDC components (0.005, 0.019 and 0.030, respectively; pxa0≤xa00.0001 for normal vs. IDC and pxa0=xa00.004 for DCIS vs. IDC). The median intensity of epithelial FOXP3 expression was also increased with invasive progression and most markedly augmented between normal and DCIS components (0.130 vs. 0.175, pxa0≤xa00.0001). Both Treg infiltration and epithelial FOXP3 expression were higher in grade 3 vs. grade 1 tumors (pxa0=xa00.014 for Tregs, pxa0=xa00.038 for epithelial FOXP3), but did not vary significantly with hormone receptor status, size of invasive tumor, lymph node status, or disease stage. Notably, Treg infiltration significantly correlated with epithelial up-regulation of FOXP3 expression (pxa0=xa00.013 for normal, pxa0=xa00.001 for IDC). These findings implicate both Treg infiltration and up-regulated epithelial FOXP3 expression in breast cancer progression.

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 (nxa0= 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.

Mutational Analysis in Pediatric Thyroid Cancer and Correlations with Age, Ethnicity, and Clinical Presentation

Background: Well-differentiated thyroid cancer (WDTC) incidence in pediatrics is rising, most being papillary thyroid carcinoma (PTC). The objective of the study was to assess the prevalence of different mutations in pediatric WDTC and correlate the genotype with the clinical phenotype. Methods: This is a single-center retrospective study. Thyroid tissue blocks from 42 consecutive pediatric WDTC patients who underwent thyroidectomy between 2001 and 2013 were analyzed at Quest Diagnostics for BRAFV600E, RAS mutations (N,K,H), and RET/PTC and PAX8/PPARγ rearrangements, using validated molecular methods. Thyroid carcinomas included PTC, follicular thyroid carcinoma (FTC), and follicular variant of PTC (FVPTC). Results: Thirty-nine samples (29 females) were genotyped. The mean age at diagnosis was 14.7 years (range 7.9–18.4 years), and most were Hispanic (56.4%) or Caucasian (35.9%). The mean follow-up period was 2.9 years. Mutations were noted in 21/39 (53.8%), with both BRAFV600E (nu2009=u20099), and RET/PTC (nu2009=u20096) detected only in PTC. Mutations were detected in 2/5 FTC (PAX8/PPARγ and NRAS) and 3/6 FVPTC cases (PAX8/PPARγ). Of 28 PTC patients, 57.1% had mutations: 32.1% with BRAFV600E, 21.4% with RET/PTC, and 3.6% with NRAS. Of patients with BRAFV600E, 77.8% were Hispanic and 88.9% were >15 years, while all RET/PTC-positive patients were ≤15 years (pu2009=u20090.003). Tumor size, lymph node involvement, and distant metastasis at diagnosis (or soon after 131I ablation) did not vary significantly based on the mutation. Conclusions: BRAFV600E was the most common mutation, especially in older and Hispanic adolescents. A larger, ethnically diverse pediatric cohort followed long term will enable the genotypic variability, clinical presentation, and response to therapy to be better assessed.

Cost Effectiveness of Sequencing 34 Cancer-Associated Genes as an Aid for Treatment Selection in Patients with Metastatic Melanoma

ObjectiveTo determine whether a next-generation sequencing (NGS) panel of 34 cancer-associated genes would cost-effectively aid in the treatment selection for patients with metastatic melanoma, compared with a single-site BRAF V600 mutation test.MethodsA decision model was developed to estimate the costs and health outcomes of the two test strategies. The cost effectiveness of these two strategies was analyzed from a payer perspective over a 2-year time horizon with model parameters taken from the literature.ResultsIn the base case, the gene sequencing panel strategy resulted in a cost of US

Mutation Yield of a 34-Gene Solid Tumor Panel in Community-Based Tumor Samples

120,022 and 0.721 quality-adjusted life years (QALYs) per patient, whereas the single-site mutation test strategy resulted in a cost of US

Abstract 4675: Detection of ALK, ROS1, and RET translocations in non-small cell lung cancer (NSCLC) patients by intragenic differential expression analysis

128,965 and 0.704 QALYs. Thus, the gene sequencing panel strategy cost US

METHYLATED MARKERS FOR COLORECTAL CANCER

8943 less per patient and increased QALYs by 0.0174 per patient. Sensitivity analyses showed that, compared with the single-site mutation test strategy, the gene sequencing panel strategy had a 90.9xa0% chance of having reduced costs and increased QALYs, with the cost of the gene sequencing panel test having minimal effect on the incremental cost.ConclusionCompared with the single-site mutation test, the use of an NGS panel of 34 cancer-associated genes as an aid in selecting therapy for patients with metastatic melanoma reduced costs and increased QALYs. If the base-case results were applied to the 8900 patients diagnosed with metastatic melanoma in the USA each year, the gene sequencing panel strategy could result in an annual savings of US

UNIVERSAL SANGER SEQUENCING FROM NEXT-GEN SEQUENCING AMPLICONS

79.6 million and a gain of 155 QALYs.

Compositions and methods for screening mutations in thyroid cancer

BackgroundSeveral targeted therapies have been approved for treatment of solid tumors. Identification of gene mutations that indicate response to these therapies is rapidly progressing. A 34-gene next-generation sequencing (NGS) panel, developed and validated by us, was evaluated to detect additional mutations in community-based cancer specimens initially sent to our reference laboratory for routine molecular testing.MethodsConsecutive de-identified clinical specimens (nxa0=xa0121) from melanoma cases (nxa0=xa031), lung cancer cases (nxa0=xa027), colorectal cancer cases (nxa0=xa033), and breast cancer cases (nxa0=xa030) were profiled by NGS, and the results were compared with routine molecular testing.ResultsUpon initial mutation testing, 20xa0% (24/121) were positive. NGS detected ≥1 additional mutation not identified by routine testing in 74xa0% of specimens (90/121). Of the specimens with additional mutations, 16 harbored mutations in National Comprehensive Cancer Network guideline genes. These various additional mutations were in gene regions not routinely covered, in genes not routinely tested, and/or present at low allele frequencies. Moreover, NGS yielded no false negatives. Overall, NGS detected mutations in 59xa0% of the genes (20/34) included in the panel, 75xa0% of which (15/20) were detected in multiple tumor types. Mutations in TP53 were found in 51xa0% of tumors tested (62/121). Mutations in at least one other (non-TP53) gene present in the panel were detected in 64xa0% of cases (77/121).ConclusionThis assay provides improved breadth and sensitivity for profiling clinically relevant genes in these prevalent solid tumor types.

A molecular diagnostic panel for thyroid cancer disease management.

BACKGROUND: ALK, ROS1, and RET translocations are frequently detected in NSCLC patients. Crizotinib, a tyrosine kinase inhibitor (TKI), was approved by the FDA in 2011 to treat NSCLC in patients harboring ALK translocations as detected by an FDA-approved assay. However, the FDA-approved ALK FISH assay is technically challenging, with failures due to pre-analytic variables. Another approach, intragenic differential expression (IDE), detects translocations by comparing expression levels of the 5′ end with the 3′ end of target gene transcripts. In this study we developed and evaluated a rapid IDE assay to screen for ALK, ROS1, and RET translocations, independent of the fusion partner. METHODS: A total of 419 samples (408 randomly-selected NSCLC clinical samples, ALK positive and ROS1 positive cell lines (2 each), and 7 previously-tested RET-positive clinical samples) were used to develop and evaluate performance characteristics of the IDE assays. To determine IDE scores, levels of ALK, ROS1, and RET expression were first determined by quantitative RT-PCR measurement of the 5′- and 3′- ends of the respective transcripts. The differences in expression levels were calculated as ΔCt (Ct5′ - Ct3′). High ΔCt values indicate presumptive presence of gene translocations. 212/408 NSCLC samples were analyzed by ALK FISH and EML4-ALK RT-PCR, and 196/408 samples were analyzed by EML4-ALK RT-PCR. RESULTS: Thirty-one of the 408 (7.6%) clinical samples tested positive for ALK rearrangements by IDE. Among them, 20 were confirmed by FISH and/or EML4-ALK (true positive, 64.5%), while 11 were negative by FISH and/or EML4-ALK (false positive, 35.5%). One of 10 ALK FISH positive samples tested negative by both ALK IDE and EML4-ALK RT-PCR analysis (false negative), while one of 202 FISH-negative sample tested positive by both EML4-ALK and ALK IDE. ALK IDE exhibited 94.5% (189/200) concordance with ALK FISH and 96.0% (356/371) concordance with the EML4-ALK assay. For ROS1, both ROS1-positive cell lines and 4/408 (1.0%) NSCLC samples tested positive for ROS1 by IDE. Among the 4 IDE-positive NSCLC samples, 1 was confirmed by ROS1 FISH. For RET, all 7 known positives and 10/408 (2.5%) NSCLC samples tested positive by IDE. Three of six RET IDE positive NSCLC samples were confirmed by RET FISH. Overall, ALK, ROS1, and RET translocations were mutually exclusive in NSCLC patients. The lung IDE assay had a failure rate of 3.7%. CONCLUSION: These findings demonstrate the feasibility of using IDE to detect ALK, ROS1, and RET gene translocations. These assays may have potential as a screening tool to select patients for further confirmation by FISH for TKI-targeted therapy. The IDE concept can be applied to a wide range of somatic translocations. Citation Format: Shih-Min Cheng, Cindy Barlan, Feras Hantash, Heather R. Sanders, Patricia H. Chan, Vladimira Sulcova, Marc A. Sanidad, Kevin Qu, Joann C. Kelly, Fatih Z. Boyar, Anthony D. Sferruzza, Frederic M. Waldman. Detection of ALK, ROS1, and RET translocations in non-small cell lung cancer (NSCLC) patients by intragenic differential expression analysis. [abstract]. In: Proceedings of the 105th Annual Meeting of the American Association for Cancer Research; 2014 Apr 5-9; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2014;74(19 Suppl):Abstract nr 4675. doi:10.1158/1538-7445.AM2014-4675