Mesenchymal neoplasms with NTRK and other kinase gene alterations

Kinase alterations are increasingly recognised as oncogenic drivers in mesenchymal tumours. Infantile fibrosarcoma and the related renal tumour, congenital mesoblastic nephroma, were among the first solid tumours shown to harbour recurrent tyrosine kinase fusions, with the canonical ETV6::NTRK3 fusion identified more than 20 years ago. Although targeted testing has long been used in diagnosis, the advent of more robust sequencing techniques has driven the discovery of kinase alterations in an array of mesenchymal tumours. As our ability to identify these genetic alterations has improved, as has our recognition and understanding of the tumours that harbour these alterations. Specifically, this study will focus upon mesenchymal tumours harbouring NTRK or other kinase alterations, including tumours with an infantile fibrosarcoma-like appearance, spindle cell tumours resembling lipofibromatosis or peripheral nerve sheath tumours and those occurring in adults with a fibrosarcoma-like appearance. As publications describing the histology of these tumours increase so, too, do the variety kinase alterations reported, now including NTRK1/2/3, RET, MET, RAF1, BRAF, ALK, EGFR and ABL1 fusions or alterations. To date, these tumours appear locally aggressive and rarely metastatic, without a clear link between traditional features used in histological grading (e.g. mitotic activity, necrosis) and outcome. However, most of these tumours are amenable to new targeted therapies, making their recognition of both diagnostic and therapeutic import. The goal of this study is to review the clinicopathological features of tumours with NTRK and other tyrosine kinase alterations, discuss the most common differential diagnoses and provide recommendations for molecular confirmation with associated treatment implications.     

Paediatric and adult soft tissue sarcomas with NTRK1 gene fusions: a subset of spindle cell sarcomas unified by a prominent myopericytic/haemangiopericytic pattern

Neoplasms with a myopericytomatous pattern represent a morphological spectrum of lesions encompassing myopericytoma of the skin and soft tissue, angioleiomyoma, myofibromatosis/infantile haemangiopericytoma and putative neoplasms reported as malignant myopericytoma. Lack of reproducible phenotypic and genetic features of malignant myopericytic neoplasms have prevented the establishment of myopericytic sarcoma as an acceptable diagnostic category. Following detection of a LMNA–NTRK1 gene fusion in an index case of paediatric haemangiopericytoma‐like sarcoma by combined whole‐genome and RNA sequencing, we identified three additional sarcomas harbouring NTRK1 gene fusions, termed 'spindle cell sarcoma, NOS with myo/haemangiopericytic growth pattern'. The patients were two children aged 11 months and 2 years and two adults aged 51 and 80 years. While the tumours of the adults were strikingly myopericytoma‐like, but with clear‐cut atypical features, the paediatric cases were more akin to infantile myofibromatosis/haemangiopericytoma. All cases contained numerous thick‐walled dysplastic‐like vessels with segmental or diffuse nodular myxohyaline myo‐intimal proliferations of smooth muscle actin‐positive cells, occasionally associated with thrombosis. Immunohistochemistry showed variable expression of smooth muscle actin and CD34, but other mesenchymal markers, including STAT6, were negative. This study showed a novel variant of myo/haemangiopericytic sarcoma with recurrent NTRK1 gene fusions. Given the recent introduction of a novel therapeutic approach targeting NTRK fusion‐positive neoplasms, recognition of this rare but likely under‐reported sarcoma variant is strongly encouraged. Copyright © 2016 Pathological Society of Great Britain and Ireland. Published by John Wiley & Sons, Ltd.     

Emerging soft tissue tumors with kinase fusions: An overview of the recent literature with an emphasis on diagnostic criteria

A recent breakthrough in the classification of soft tissue tumors (STT) has been a significant expansion in the number of neoplasms associated with NTRK and other kinase related fusions. This is important not only for diagnostic purposes, but also because it opens new avenues for targeted therapy. Indeed, recent clincal trials have shown significant benefit across multiple tumor‐types, prompting approval of NTRK inhibitors for clinical use in the setting of advanced/metastatic NTRK‐rearranged neoplasms. Despite these therapeutic oportunities, diagnostic challenges have transpired in recognizing these emerging new histologic subtypes of kinase fusions positive‐STT prospectively. This, in part, is attributable to their wide morphologic spectrum, variable risk of malignancy, and non‐specific immunoprofile. As such, recommendations for pathologic criteria and immunohistochemical testing are needed to improve classification and streamline the small subset of potential candidates for further molecular validation. This overview summarizes the key histologic features of various STT associated with NTRK and other kinase fusions, which appear to share a similar morphologic spectrum. Immunohistochemically, many of these tumors, regardless of the kinase fusion type, notably show co‐expression of S100 and CD34; issues related to the utility of pan‐NTRK and NTRK1 immunostaining are therefore summarized. Finally, I discuss the role of confirmatory molecular testing and how, in some instances, this may also be of prognostic value. This review is intended as a critical summary of the current literature to emphasize pathologic criteria for improving recognition of this emerging and complex group of kinase fusion associated STT.     

Targeted next generation sequencing of MLH1‐deficient,MLH1 promoter hypermethylated,and BRAF/RAS‐wild‐type colorectal adenocarcinomas is effective in detecting tumors with actionable oncogenic gene fusions

Oncogenic gene fusions represent attractive targets for therapy of cancer. However, the frequency of actionable genomic rearrangements in colorectal cancer (CRC) is very low, and universal screening for these alterations seems to be impractical and costly. To address this problem, several large scale studies retrospectivelly showed that CRC with gene fusions are highly enriched in groups of tumors defined by MLH1 DNA mismatch repair protein deficiency (MLH1d), and hypermethylation of MLH1 promoter (MLH1ph), and/or the presence of microsatellite instability, and BRAF/KRAS wild‐type status (BRAFwt/KRASwt). In this study, we used targeted next generation sequencing (NGS) to explore the occurence of potentially therapeutically targetable gene fusions in an unselected series of BRAFwt/KRASwt CRC cases that displayed MLH1d/MLH1ph. From the initially identified group of 173 MLH1d CRC cases, 141 cases (81.5%) displayed MLH1ph. BRAFwt/RASwt genotype was confirmed in 23 of 141 (~16%) of MLH1d/MLH1ph cases. Targeted NGS of these 23 cases identified oncogenic gene fusions in nine patients (39.1%; CI95: 20.5%‐61.2%). Detected fusions involved NTRK (four cases), ALK (two cases), and BRAF genes (three cases). As a secondary outcome of NGS testing, we identified PIK3K‐AKT‐mTOR pathway alterations in two CRC cases, which displayed PIK3CA mutation. Altogether, 11 of 23 (~48%) MLH1d/MLH1ph/BRAFwt/RASwt tumors showed genetic alterations that could induce resistance to anti‐EGFR therapy. Our study confirms that targeted NGS of MLH1d/MLH1ph and BRAFwt/RASwt CRCs could be a cost‐effective strategy in detecting patients with potentially druggable oncogenic kinase fusions.     

NTRK3 kinase fusions in Spitz tumours

Oncogenic fusions in TRK family receptor tyrosine kinases have been identified in several cancers and can serve as therapeutic targets. We identified ETV6–NTRK3, MYO5A–NTRK3 and MYH9–NTRK3 fusions in Spitz tumours, and demonstrated that NTRK3 fusions constitutively activate the mitogen‐activated protein kinase, phosphoinositide 3‐kinase and phospholipase Cγ1 pathways in melanocytes. This signalling was inhibited by DS‐6051a, a small‐molecule inhibitor of NTRK1/2/3 and ROS1. NTRK3 fusions expand the range of oncogenic kinase fusions in melanocytic neoplasms and offer targets for a small subset of melanomas for which no targeted options currently exist. Copyright © 2016 Pathological Society of Great Britain and Ireland. Published by John Wiley & Sons, Ltd.     

Dramatic response to entrectinib in a patient with malignant peripheral nerve sheath tumor harboring novel SNRNP70-NTRK3 fusion gene

Neurotropic tropomyosin receptor kinase (NTRK) gene rearrangements have been reported in limited cases of sarcomas; however, to date, there has been only one report of such rearrangements in malignant peripheral nerve sheath tumors (MPNSTs). Herein, we describe a 51-year-old male patient with a buttock tumor arising from the sciatic nerve, which was diagnosed as MPNST with positive S-100 staining, negative SOX10 staining, and loss of trimethylation at lysine 27 of histone H3 (H3K27me3) confirmed by immunohistochemistry. Soon after the resection of the primary tumor, the patient was found to have pulmonary and lymph node metastases. Chemotherapy with eribulin and trabectedin showed limited effects. However, the patient responded rapidly to pazopanib, but severe side effects caused discontinuation of the treatment. RNA panel testing revealed a novel fusion gene between Small Nuclear Ribonucleoprotein U1 Subunit 70 (SNRNP70) gene and NTRK3 gene. Furthermore, loss of NF1, SUZ12, and CDKN2A genes was confirmed by DNA panel testing, which is compatible with a histological diagnosis of MPNST. SNRNP70 possesses a coiled-coiled domain and seems to induce constitutive activation of NTRK3 through dimerization. In fact, immunohistochemistry revealed diffuse staining of pan-TRK within tumor cells. Treatment with entrectinib, which is an NTRK inhibitor, showed a quick and durable response for 10 months. Although NTRK rearrangements are very rare in MPNST, this case highlights the importance of genetic testing in MPNST, especially using an RNA panel for the detection of rare fusion genes.     

Soft tissue tumors characterized by a wide spectrum of kinase fusions share a lipofibromatosis‐like neural tumor pattern

Gene fusions resulting in oncogenic activation of various receptor tyrosine kinases, including NTRK1‐3, ALK, and RET, have been increasingly recognized in soft tissue tumors (STTs), displaying a wide morphologic spectrum and therefore diagnostically challenging. A subset of STT with NTRK1 rearrangements were recently defined as lipofibromatosis‐like neural tumors (LPFNTs), being characterized by mildly atypical spindle cells with a highly infiltrative growth in the subcutis and expression of S100 and CD34 immunostains. Other emerging morphologic phenotypes associated with kinase fusions include infantile/adult fibrosarcoma and malignant peripheral nerve sheath tumor‐like patterns. In this study, a large cohort of 73 STT positive for various kinase fusions, including 44 previously published cases, was investigated for the presence of an LPFNT phenotype, to better define the incidence of this distinctive morphologic pattern and its relationship with various gene fusions. Surprisingly, half (36/73) of STT with kinase fusions showed at least a focal LPFNT component defined as >10%. Most of the tumors occurred in the subcutaneous tissues of the extremities (n = 25) and trunk (n = 9) of children or young adults (<30 years old) of both genders. Two‐thirds (24/36) of these cases showed hybrid morphologies with alternating LPFNT and solid areas of monomorphic spindle to ovoid tumor cells with fascicular or haphazard arrangement, while one‐third (12/36) had pure LPFNT morphology. Other common histologic findings included lymphocytic infiltrates, staghorn‐like vessels, and perivascular or stromal hyalinization, especially in hybrid cases. Mitotic activity was generally low (<4/10 high power fields in 81% cases), being increased only in a minority of cases. Immunoreactivity for CD34 (92% in hybrid cases, 89% in pure cases) and S100 (89% in hybrid cases, 64% in pure cases) were commonly present. The gene rearrangements most commonly involved NTRK1 (75%), followed by RET (8%) and less commonly NTRK2, NTRK3, ROS1, ALK, and MET.     

结直肠癌中错配修复蛋白缺陷与NTRK基因融合的相关性分析

目的探讨结直肠癌中错配修复蛋白缺陷(dMMR)与NTRK基因融合的相关性。方法收集南京大学医学院附属鼓楼医院病理科2015—2019年诊断为结直肠癌的组织蜡块830例, 分别运用免疫组织化学和荧光原位杂交(FISH)检测830例甲醛固定石蜡包埋(FFPE)肿瘤组织中错配修复蛋白表达情况以及NTRK1/2/3基因断裂情况。比较dMMR型和错配修复蛋白无缺陷(pMMR)结直肠癌中NTRK1/2/3基因融合的发生率, 进一步运用FFPE样本进行RNA Seq二代测序检测, 分析融合伴侣和融合方式。结果 830例原发性结直肠癌FFPE样本均成功进行免疫组织化学和FISH检测。dMMR病例82例(9.88%), pMMR病例748例(90.12%)。其中MLH1蛋白缺失比例为9.04%(75/830), PMS2蛋白缺失比例为9.04%(75/830), MSH2蛋白缺失比例为2.53%(21/830), MSH6蛋白缺失比例为4.10%(34/830), MLH1和PMS2共缺失比例为8.67%(72/830), MSH2和MSH6共缺失比例为2.17%(18/830)。伴有dMMR肿瘤与pM...     

An addition to the evolving spectrum of lipofibromatosis and lipofibromatosis-like neural tumor: Molecular findings in an unusual phenotype aid in accurate classification

Lipofibromatosis (LPF) and lipofibromatosis-like neural tumor (LPF-NT) are histologically and prognostically similar neoplasms having differences in immunophenotype as well as molecular biology. In most cases, LPF-NT is driven by fusions in the NTRK gene, whereas LPF has been associated with fusions in a variety of receptor tyrosine kinases. The distinction between the driver fusion event holds clinical significance because of the profound clinical response to tropomyosin receptor kinase (Trk) inhibitors (larotrectinib) in the NTRK-driven tumors. Immunohistochemically, and consistent with its namesake, to-date all reported cases classified as LPF-NT have shown positivity for S100-protein staining. Consequently, as S100-protein staining is widely available, it represents a cost-effective screening tool for LPF-NT where the more specific studies such as the pan-Trk stain or fluorescence in situ hybridization for NTRK rearrangement are not available. Herein, we present a case of presumed LPF-NT harboring the recurrent NTRK1-LMNA fusion, but which was negative for S100-protein immunostaining and was previously classified as classical LPF. This case reveals a potential pitfall in distinguishing these rare subcutaneous tumors by S100-protein staining and highlights the challenges in reconciling the rapid and novel discoveries made in the field of diagnostic pathology.     

Mutations in NTRK3 Suggest a Novel Signaling Pathway in Human Congenital Heart Disease

Congenital heart defects (CHDs) are the most common major birth defects and the leading cause of death from congenital malformations. The etiology remains largely unknown, though genetic variants clearly contribute. In a previous study, we identified a large copy‐number variant (CNV) that deleted 46 genes in a patient with a malalignment type ventricular septal defect (VSD). The CNV included the gene NTRK3 encoding neurotrophic tyrosine kinase receptor C (TrkC), which is essential for normal cardiogenesis in animal models. To evaluate the role of NTRK3 in human CHDs, we studied 467 patients with related heart defects for NTRK3 mutations. We identified four missense mutations in four patients with VSDs that were not found in ethnically matched controls and were predicted to be functionally deleterious. Functional analysis using neuroblastoma cell lines expressing mutant TrkC demonstrated that one of the mutations (c.278C>T, p.T93M) significantly reduced autophosphorylation of TrkC in response to ligand binding, subsequently decreasing phosphorylation of downstream target proteins. In addition, compared with wild type, three of the four cell lines expressing mutant TrkC showed altered cell growth in low‐serum conditions without supplemental neurotrophin 3. These findings suggest a novel pathophysiological mechanism involving NTRK3 in the development of VSDs.     

Novel ZC3H7B‐BCOR,MEAF6‐PHF1, and EPC1‐PHF1 fusions in ossifying fibromyxoid tumors—molecular characterization shows genetic overlap with endometrial stromal sarcoma

PHF1 gene rearrangements have been recently described in around 50% of ossifying fibromyxoid tumors (OFMT) including benign and malignant cases, with a small subset showing EP400‐PHF1 fusions. In the remaining cases no alternative gene fusions have been identified. PHF1‐negative OFMT, especially if lacking S100 protein staining or peripheral ossification, are difficult to diagnose and distinguish from other soft tissue mimics. In seeking more comprehensive molecular characterization, we investigated a large cohort of 39 OFMT of various anatomic sites, immunoprofiles and grades of malignancy. Tumors were screened for PHF1 and EP400 rearrangements by FISH. RNA sequencing was performed in two index cases (OFMT1, OFMT3), negative for EP400‐PHF1 fusions, followed by FusionSeq data analysis, a modular computational tool developed to discover gene fusions from paired‐end RNA‐seq data. Two novel fusions were identified ZC3H7B‐BCOR in OFMT1 and MEAF6‐PHF1 in OFMT3. After being validated by FISH and RT‐PCR, these abnormalities were screened on the remaining cases. With these additional gene fusions, 33/39 (85%) of OFMTs demonstrated recurrent gene rearrangements, which can be used as molecular markers in challenging cases. The most common abnormality is PHF1 gene rearrangement (80%), being present in benign, atypical and malignant lesions, with fusion to EP400 in 44% of cases. ZC3H7B‐BCOR and MEAF6‐PHF1 fusions occurred predominantly in S100 protein‐negative and malignant OFMT. As similar gene fusions were reported in endometrial stromal sarcomas, we screened for potential gene abnormalities in JAZF1 and EPC1 by FISH and found two additional cases with EPC1‐PHF1 fusions. © 2013 Wiley Periodicals, Inc.     

Analysis of NTRK expression in gastric and esophageal adenocarcinoma (AGE) with pan-TRK immunohistochemistry

Small molecule inhibitors such as Larotrectinib have been recently approved in the treatment of patients with fusions of the neurotrophic-tropomyosin receptor tyrosine kinase (NTRK) genes 1-3. These genomic rearrangements have been reported across different tumor subtypes with a high prevalence in rare tumors. However, in gastric and esophageal adenocarcinoma (AGE) NTRK fusions have also been described in a subset of Asian patients. In order to study the prevalence of this alteration in Caucasian patients with AGE we performed immunohistochemistry for pan-NTRK in 438 formalin-fixed paraffin embedded (FFPE) tumor samples. While we found NTRK expression in gastric glands and tumor adjacent nerve tissue, we did not detect this marker in the tumor compartment. Based on our findings NTRK fusions do not seem to play a role in the molecularpathology of Caucasian AEG patients, so that other treatment options are required.