Novel high-grade endometrial stromal sarcoma: a morphologic mimicker of myxoid leiomyosarcoma

Endometrial stromal sarcomas (ESS) are often underpinned by recurrent chromosomal translocations resulting in the fusion of genes involved in epigenetic regulation. To date, only YWHAE-NUTM2 rearrangements are associated with distinctive high-grade morphology and aggressive clinical behavior. We identified 3 ESS morphologically mimicking myxoid leiomyosarcoma of the uterus and sought to describe their unique histopathologic features and identify genetic alterations using next-generation sequencing. All cases displayed predominantly spindled cells associated with abundant myxoid stroma and brisk mitotic activity. Tumors involved the endometrium and demonstrated tongue-like myometrial infiltration. All 3 were associated with an aggressive clinical course, including multisite bony metastases in 1 patient, progressive peritoneal disease after chemotherapy in another and metastases to the lung and skin in the last patient. All 3 ESS were found to harbor ZC3H7B-BCOR gene fusions by targeted sequencing and fluorescence in situ hybridization. On the basis of the review of these cases, we find that ESS with ZC3H7B-BCOR fusion constitutes a novel type of high-grade ESS and shares significant morphologic overlap with myxoid leiomyosarcoma

Comprehensive Molecular and Clinicopathologic Analysis of 200 Pulmonary Invasive Mucinous Adenocarcinomas Identifies Distinct Characteristics of Molecular Subtypes

PURPOSE: Invasive mucinous adenocarcinoma (IMA) is a unique subtype of lung adenocarcinoma, characterized genomically by frequent KRAS mutations or specific gene fusions, most commonly involving NRG1. Comprehensive analysis of a large series of IMAs using broad DNA- and RNA-sequencing methods is still lacking, and it remains unclear whether molecular subtypes of IMA differ clinicopathologically. EXPERIMENTAL DESIGN: A total of 200 IMAs were analyzed by 410-gene DNA next-generation sequencing (MSK-IMPACT; n = 136) or hotspot 8-oncogene genotyping (n = 64). Driver-negative cases were further analyzed by 62-gene RNA sequencing (MSK-Fusion) and those lacking fusions were further tested by whole-exome sequencing and whole-transcriptome sequencing (WTS). RESULTS: Combined MSK-IMPACT and MSK-Fusion testing identified mutually exclusive driver alterations in 96% of IMAs, including KRAS mutations (76%), NRG1 fusions (7%), ERBB2 alterations (6%), and other less common events. In addition, WTS identified a novel NRG2 fusion (F11R-NRG2). Overall, targetable gene fusions were identified in 51% of KRAS wild-type IMAs, leading to durable responses to targeted therapy in some patients. Compared with KRAS-mutant IMAs, NRG1-rearranged tumors exhibited several more aggressive characteristics, including worse recurrence-free survival (P \u3c 0.0001). CONCLUSIONS: This is the largest molecular study of IMAs to date, where we demonstrate the presence of a major oncogenic driver in nearly all cases. This study is the first to document more aggressive characteristics of NRG1-rearranged IMAs, ERBB2 as the third most common alteration, and a novel NRG2 fusion in these tumors. Comprehensive molecular testing of KRAS wild-type IMAs that includes fusion testing is essential, given the high prevalence of alterations with established and investigational targeted therapies in this subset

Cancer therapy shapes the fitness landscape of clonal hematopoiesis.

Acquired mutations are pervasive across normal tissues. However, understanding of the processes that drive transformation of certain clones to cancer is limited. Here we study this phenomenon in the context of clonal hematopoiesis (CH) and the development of therapy-related myeloid neoplasms (tMNs). We find that mutations are selected differentially based on exposures. Mutations in ASXL1 are enriched in current or former smokers, whereas cancer therapy with radiation, platinum and topoisomerase II inhibitors preferentially selects for mutations in DNA damage response genes (TP53, PPM1D, CHEK2). Sequential sampling provides definitive evidence that DNA damage response clones outcompete other clones when exposed to certain therapies. Among cases in which CH was previously detected, the CH mutation was present at tMN diagnosis. We identify the molecular characteristics of CH that increase risk of tMN. The increasing implementation of clinical sequencing at diagnosis provides an opportunity to identify patients at risk of tMN for prevention strategies

Cancer therapy shapes the fitness landscape of clonal hematopoiesis.

Acquired mutations are pervasive across normal tissues. However, understanding of the processes that drive transformation of certain clones to cancer is limited. Here we study this phenomenon in the context of clonal hematopoiesis (CH) and the development of therapy-related myeloid neoplasms (tMNs). We find that mutations are selected differentially based on exposures. Mutations in ASXL1 are enriched in current or former smokers, whereas cancer therapy with radiation, platinum and topoisomerase II inhibitors preferentially selects for mutations in DNA damage response genes (TP53, PPM1D, CHEK2). Sequential sampling provides definitive evidence that DNA damage response clones outcompete other clones when exposed to certain therapies. Among cases in which CH was previously detected, the CH mutation was present at tMN diagnosis. We identify the molecular characteristics of CH that increase risk of tMN. The increasing implementation of clinical sequencing at diagnosis provides an opportunity to identify patients at risk of tMN for prevention strategies

Expanding the Molecular Characterization of Thoracic Inflammatory Myofibroblastic Tumors beyond ALK Gene Rearrangements

Half of inflammatory myofibroblastic tumors (IMTs) regardless of anatomic location harbor anaplastic lymphoma kinase gene (ALK) rearrangements and overexpress anaplastic lymphoma kinase protein. The wide application of next-generation sequencing and the clinical benefit to tyrosine kinase inhibitors have opened new opportunities for investigation of ALK-negative IMTs

Abstract 3931: BRD4, BRD3, NSD3, and ZNF532 fusions in histologies beyond NUT carcinomas: Investigation of a large pan-cancer cohort

Abstract Background: NUT rearrangements drive NUT carcinomas (NCs), which are rare, poorly differentiated tumors with a survival from diagnosis of ~6-7 months. Common NUT fusion partners (NCFPs) include BRD4, BRD3, NSD3, and ZNF532, which are associated with epigenetic changes leading to tumor growth. Recent clinical trials have aimed to address NCs, but little is known about fusions involving NCFPs in other histologies. We characterized NCFPs in a large, pan-cancer cohort. Methods: The MSK-IMPACT (DNA sequencing; n=71,423) and MSK-Fusion (RNA sequencing; n=10,897) clinical cohorts were mined to identify patients (pts) with all forms of structural variants (SVs) involving NCFPs, detected between April, 2015 and June, 2022. The targeted NGS panels included BRD4 and NSD3 only; detection of BRD3 and ZNF532 SVs was possible for fusions with a partner present on either panel. SVs were manually reviewed to identify in-frame fusions with oncogenic potential if critical domains present in NC fusions were conserved. Pts were followed through July 2022 and manual chart review enabled assessment of treatment history and clinical outcomes. Results: SVs involving NCFP genes were detected in 182 (BRD4=110, NSD3=61, BRD3=8 and ZNF532=3) pts (0.002%). Putative NCFP fusions not involving any of the NUT gene family members comprised a total of 20 fusions with likely oncogenic potential including 11 with BRD4 (55%), 5 with NSD3 (25%), 3 with ZNF532 (15%), and 1 with BRD3 (5%). BRD4::NOTCH3 and ZNF532::MALT1 were the most enriched fusions, present in 3 samples each. The most common histologies were breast (3 ductal; 1 lobular), lung (2 squamous cell carcinoma, 1 adenocarcinoma and 1 mixed histology), and colon and esophageal adenocarcinoma (2 samples each). Median age at diagnosis was 62. 11 (55%) pts were female and 9 (45%) were male. 13 (65%) pts ultimately were diagnosed with stage IV disease and had a median overall survival from stage IV diagnosis of 2.5 years (95% CI: 1.41, NR). DNA sequencing in 19/20 tumors revealed a mean tumor mutational burden (TMB) of 5.0 mut/Mb including 15 with low TMB (10). No tumor showed microsatellite instability (MSI-high). TP53 mutations were the most common co-alteration, found in 11 (58%) cases. 18/20 pts received systemic therapy; 18 (90%) received cytotoxic chemotherapy and/or mAb therapy, including 13 (65%) who received a platinum. 8 pts (40%) received immunotherapy (IO), and 4 (20%) received small molecule inhibitors. No pts received BET inhibitors. Among pts who received IO, median time to treatment discontinuation was 64 days (95% CI: 20, NR). Conclusion: Tumor sequencing from a large cohort reveals potential oncogenic fusions involving BRD4, BRD3, NSD3, and ZNF532 across multiple histologies. Further biological characterization of their oncogenicity and potential targetability is warranted. Citation Format: Ian R. Nykaza, Christopher A. Febres-Aldana, Sabrina T. Lin, Ryma Benayed, Kerry Mullaney, Emiliano Cocco, Alexia Iasonos, Marc Ladanyi, Alexander E. Drilon, Yonina R. Murciano-Goroff. BRD4, BRD3, NSD3, and ZNF532 fusions in histologies beyond NUT carcinomas: Investigation of a large pan-cancer cohort. [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2023; Part 1 (Regular and Invited Abstracts); 2023 Apr 14-19; Orlando, FL. Philadelphia (PA): AACR; Cancer Res 2023;83(7_Suppl):Abstract nr 3931

The value of cell-free DNA for molecular pathology

Over the past decade, advances in molecular biology and genomics techniques have revolutionized the diagnosis and treatment of cancer. The technological advances in tissue profiling have also been applied to the study of cell-free nucleic acids, an area of increasing interest for molecular pathology. Cell-free nucleic acids are released from tumour cells into the surrounding body fluids and can be assayed non-invasively. The repertoire of genomic alterations in circulating tumour DNA (ctDNA) is reflective of both primary tumours and distant metastatic sites, and ctDNA can be sampled multiple times, thereby overcoming the limitations of the analysis of single biopsies. Furthermore, ctDNA can be sampled regularly to monitor response to treatment, to define the evolution of the tumour genome, and to assess the acquisition of resistance and minimal residual disease. Recently, clinical ctDNA assays have been approved for guidance of therapy, which is an exciting first step in translating cell-free nucleic acid research tests into clinical use for oncology. In this review, we discuss the advantages of cell-free nucleic acids as analytes in different body fluids, including blood plasma, urine, and cerebrospinal fluid, and their clinical applications in solid tumours and haematological malignancies. We will also discuss practical considerations for clinical deployment, such as preanalytical factors and regulatory requirements

The value of cell-free DNA for molecular pathology.

Over the past decade, advances in molecular biology and genomics techniques have revolutionized the diagnosis and treatment of cancer. The technological advances in tissue profiling have also been applied to the study of cell-free nucleic acids, an area of increasing interest for molecular pathology. Cell-free nucleic acids are released from tumour cells into the surrounding body fluids and can be assayed non-invasively. The repertoire of genomic alterations in circulating tumour DNA (ctDNA) is reflective of both primary tumours and distant metastatic sites, and ctDNA can be sampled multiple times, thereby overcoming the limitations of the analysis of single biopsies. Furthermore, ctDNA can be sampled regularly to monitor response to treatment, to define the evolution of the tumour genome, and to assess the acquisition of resistance and minimal residual disease. Recently, clinical ctDNA assays have been approved for guidance of therapy, which is an exciting first step in translating cell-free nucleic acid research tests into clinical use for oncology. In this review, we discuss the advantages of cell-free nucleic acids as analytes in different body fluids, including blood plasma, urine, and cerebrospinal fluid, and their clinical applications in solid tumours and haematological malignancies. We will also discuss practical considerations for clinical deployment, such as preanalytical factors and regulatory requirements. Copyright © 2018 Pathological Society of Great Britain and Ireland. Published by John Wiley & Sons, Ltd.We acknowledge the Department of Pathology, Department of Pediatrics and Marie‐José and Henry R. Kravis Center for Molecular Oncology of the Memorial Sloan Kettering Cancer Center, and the Memorial Sloan Kettering Cancer Center Support Grant (NIH/NCI, Grant No. P30CA008748), as well as University of Cambridge, Cancer Research UK, the National Breast Cancer Foundation and the Victorian Cancer Agency, Australia, for their support of the respective authors