Matthew C. Hiemenz

Novel JAK2 rearrangement resulting from a t(9;22)(p24;q11.2) in B-acute lymphoblastic leukemia

Rearrangements of JAK2 are rare and have been described in various hematological neoplasms. We report a novel JAK2 rearrangement resulting from a t(9;22)(p24;q11.2) in a 14-year-old male with a diagnosis of B lymphoblastic leukemia. He was treated with Childrens Oncology Groups protocol (AALL0232) but failed to achieve remission by day 29. He underwent a second induction and entered remission. His clinical course suggested that this JAK2 rearrangement might portend an unfavorable prognosis. This case brings the total number of JAK2 rearranged lymphoblastic leukemia cases in the literature to seven. The molecular genetic and clinicopathologic features of these cases were reviewed.

Building a Robust Tumor Profiling Program: Synergy between Next-Generation Sequencing and Targeted Single-Gene Testing

Next-generation sequencing (NGS) is a powerful platform for identifying cancer mutations. Routine clinical adoption of NGS requires optimized quality control metrics to ensure accurate results. To assess the robustness of our clinical NGS pipeline, we analyzed the results of 304 solid tumor and hematologic malignancy specimens tested simultaneously by NGS and one or more targeted single-gene tests (EGFR, KRAS, BRAF, NPM1, FLT3, and JAK2). For samples that passed our validated tumor percentage and DNA quality and quantity thresholds, there was perfect concordance between NGS and targeted single-gene tests with the exception of two FLT3 internal tandem duplications that fell below the stringent pre-established reporting threshold but were readily detected by manual inspection. In addition, NGS identified clinically significant mutations not covered by single-gene tests. These findings confirm NGS as a reliable platform for routine clinical use when appropriate quality control metrics, such as tumor percentage and DNA quality cutoffs, are in place. Based on our findings, we suggest a simple workflow that should facilitate adoption of clinical oncologic NGS services at other institutions.

Crossing boundaries: a comprehensive survey of medical licensing laws and guidelines regulating the interstate practice of pathology.

In the United States, recent judicial interpretation of interstate licensure laws has found pathologists guilty of malpractice and, more importantly, the criminal practice of medicine without a license. These judgments against pathologists highlight the need for a timely and comprehensive survey of licensure requirements and laws regulating the interstate practice of pathology. For all 50 states, each state medical practice act and state medical board website was reviewed. In addition, each medical board was directly contacted by electronic mail, telephone, or US registered mail for information regarding specific legislation or guidelines related to the interstate practice of pathology. On the basis of this information, states were grouped according to similarities in legislation and medical board regulations. This comprehensive survey has determined that states define the practice of pathology on the basis of the geographic location of the patient at the time of surgery or phlebotomy. The majority of states (n=32) and the District of Columbia allow for a physician with an out-of-state license to perform limited consultation to a physician with the specific state license. Several states (n=5) prohibit physicians from consultation without a license for the specific state. Overall, these results reveal the heterogeneity of licensure requirements between states. Pathologists who either practice in multiple states, send cases to out-of-state consultants, or serve as consultants themselves should familiarize themselves with the medical licensure laws of the states from which they receive or send cases.

Abstract 4916: Development of a NGS-based method for EGFRvIII detection: sequence analysis of the junction

Glioblastoma multiforme (GBM) is the most common and aggressive malignant primary tumor in humans. One of the most common mutations in GBMs is an interstitial deletion in the epidermal growth factor receptor (EGFR), EGFRvIII, which occurs at a frequency of ∼30%. EGFR is a transmembrane tyrosine kinase receptor and the EGFRvIII mutant is characterized by a deletion of 267 amino acids in the extracellular domain leading to ligand independent constitutive activation. The deletion of exons 2-7 leads to an in-frame deletion in EGFR with a novel glycine residue at the junction. The amino acid at the junction of exons 1 and 2 is a valine, making the novel transcript an attractive target for immunotherapy. A custom next generation sequencing (NGS) based assay and bioinformatic pipeline have been developed in our laboratory to detect EGFRvIII from RNA extracted from formalin fixed paraffin embedded tissue. The targets include the exon 1-2 boundary (wild type), the exon 1-8 boundary (EGFRvIII), amplification of various sized RNA fragments to determine RNA degradation and bioavailability, and expression levels of three housekeeping genes. Following cDNA synthesis multiplex PCR of all targets are captured simultaneously for the sequencing library with NGS performed on the Illumina MiSeq. The output from the bioinformatics pipeline includes the sequence and number of reads from the wild-type and mutant, ratio of EGFRvIII reads with respect to total EGFR sequenced, expression of three housekeeping genes and relative amount of bioavailable EGFR RNA. This assay was validated through comparison of NGS sequence results with an established qRT-PCR to detect normal and mutant EGFR. Negative controls from normal brain (temporal lobe excisions from epilepsy patients) and adipose tissue (a tissue with high expression of EGFR) were used to determine whether low-level exon 1-8 fusions from mis-splicing were detectable in normal tissue (Figure 1). Twenty five GBM specimens were sequenced, with 8/25 positive for EGFRvIII (Figure 2), and confirmed by RT-PCR. In addition to detection of the EGFRvIII mutant, relative expression of EGFR is detected in this assay, and when taken together with EGFR amplifications detected by routine NGS panels, we can determine whether the EGFRvIII is present on the amplified or unamplified allele and whether additional mutations are detectable. Detection of EGFRvIII utilizing NGS improves the precision of mutant detection to better serve CART-EGFRvIII clinical trial to ensure the target is present. The NGS assay provides the EGFRvIII/wild-type ratio, relative expression levels for EGFR and EGFRvIII and evaluation of RNA degradation in a single assay. Figure 1A. Baseline in normal samples. EGFRvIII ratio in 18 “normal” brain and 11 adipose tissue samples, plotted without (top panel) and with (bottom panel) a EGFRvIII positive sample. Figure 2. EGFRvIII ratio in 25 GBM samples. Cutoff for EGFRvIII positive is EGFRvIII ratio of 0.3 (30%). Citation Format: Jianhua Zhao, Shrey Sukhadia, Alan Fox, David Lieberman, Barnett Li, Robert D. Daber, Matthew C. Hiemenz, David B. Roth, Maria Martinez-Large, Arati Desai, Donald M. O9Rourke, Marcela V. Maus, Jennifer JD Morrissette. Development of a NGS-based method for EGFRvIII detection: sequence analysis of the junction. [abstract]. In: Proceedings of the 106th Annual Meeting of the American Association for Cancer Research; 2015 Apr 18-22; Philadelphia, PA. Philadelphia (PA): AACR; Cancer Res 2015;75(15 Suppl):Abstract nr 4916. doi:10.1158/1538-7445.AM2015-4916

Next Generation Sequencing for the Detection of Actionable Mutations in Solid and Liquid Tumors

As our understanding of the driver mutations necessary for initiation and progression of cancers improves, we gain critical information on how specific molecular profiles of a tumor may predict responsiveness to therapeutic agents or provide knowledge about prognosis. At our institution a tumor genotyping program was established as part of routine clinical care, screening both hematologic and solid tumors for a wide spectrum of mutations using two next-generation sequencing (NGS) panels: a custom, 33 gene hematological malignancies panel for use with peripheral blood and bone marrow, and a commercially produced solid tumor panel for use with formalin-fixed paraffin-embedded tissue that targets 47 genes commonly mutated in cancer. Our workflow includes a pathologist review of the biopsy to ensure there is adequate amount of tumor for the assay followed by customized DNA extraction is performed on the specimen. Quality control of the specimen includes steps for quantity, quality and integrity and only after the extracted DNA passes these metrics an amplicon library is generated and sequenced. The resulting data is analyzed through an in-house bioinformatics pipeline and the variants are reviewed and interpreted for pathogenicity. Here we provide a snapshot of the utility of each panel using two clinical cases to provide insight into how a well-designed NGS workflow can contribute to optimizing clinical outcomes.

Myeloid lineage switch following chimeric antigen receptor T-cell therapy in a patient with TCF3-ZNF384 fusion-positive B-lymphoblastic leukemia

A pediatric patient diagnosed initially with B‐lymphoblastic leukemia (B‐ALL) relapsed with lineage switch to acute myeloid leukemia (AML) after chimeric antigen receptor T‐cell (CAR‐T) therapy and hematopoietic stem cell transplant. A TCF3‐ZNF384 fusion was identified at diagnosis, persisted through B‐ALL relapse, and was also present in the AML relapse cell population. ZNF384‐rearrangements define a molecular subtype of B‐ALL characterized by a pro‐B‐cell immunophenotype; furthermore, ZNF384‐rearrangements are prevalent in mixed‐phenotype acute leukemias. Lineage switch following CAR‐T therapy has been described in patients with KMT2A (mixed lineage leukemia) rearrangements, but not previously in any patient with ZNF384 fusion.