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In cancer cells the small compounds erastin and RSL3 promote a novel type of cell death called ferroptosis, which requires iron‐dependent accumulation of lipid reactive oxygen species. Here we assessed the contribution of lipid peroxidation activity of lipoxygenases (LOX) to ferroptosis in oncogenic Ras‐expressing cancer cells. Several 12/15‐LOX inhibitors prevented cell death induced by erastin and RSL3. Furthermore, siRNA‐mediated silencing of ALOX15 significantly decreased both erastin‐induced and RSL3‐induced ferroptotic cell death, whereas exogenous overexpression of ALOX15 enhanced the effect of these compounds. Immunofluorescence analyses revealed that the ALOX15 protein consistently localizes to cell membrane during the course of ferroptosis. Importantly, treatments of cells with ALOX15‐activating compounds accelerated cell death at low, but not high doses of erastin and RSL3. These observations suggest that tumor ferroptosis is promoted by LOX‐catalyzed lipid hydroperoxide generation in cellular membranes. The lipid‐peroxidizing enzyme (ALOX15) constitutively localizes on the cell membrane in human fibrosarcoma HT1080 cells, and cells with enhanced ALOX15 activity are more sensitive to ferroptosis‐inducing compounds.

Infantile fibrosarcoma and congenital mesoblastic nephroma are tumors of infancy traditionally associated with the ETV6–NTRK3 gene fusion. However, a number of case reports have identified variant fusions in these tumors. In order to assess the frequency of variant NTRK3 fusions, and in particular whether the recently identified EML4–NTRK3 fusion is recurrent, 63 archival cases of infantile fibrosarcoma, congenital mesoblastic nephroma, mammary analog secretory carcinoma and secretory breast carcinoma (tumor types that are known to carry recurrent ETV6–NTRK3 fusions) were tested with NTRK3 break-apart FISH, EML4–NTRK3 dual fusion FISH, and targeted RNA sequencing. The EML4–NTRK3 fusion was identified in two cases of infantile fibrosarcoma (one of which was previously described), and in one case of congenital mesoblastic nephroma, demonstrating that the EML4–NTRK3 fusion is a recurrent genetic event in these related tumors. The growing spectrum of gene fusions associated with infantile fibrosarcoma and congenital mesoblastic nephroma along with the recent availability of targeted therapies directed toward inhibition of NTRK signaling argue for alternate testing strategies beyond ETV6 break-apart FISH. The use of either NTRK3 FISH or next-generation sequencing will expand the number of cases in which an oncogenic fusion is identified and facilitate optimal diagnosis and treatment for patients.

Mesenchymal neoplasms of the uterus (corpus and cervix) encompass a heterogeneous group of tumors with differing morphologies, immunophenotypes and molecular alterations. With the advent of modern molecular techniques, such as next generation sequencing, newly defined genetic abnormalities are being reported in this group of neoplasms. Herein we report the clinicopathological and molecular features of a series of 13 spindle cell sarcomas of the uterus and vagina (10 cervix, 2 uterine corpus, 1 vagina) with morphology resembling fibrosarcoma. After targeted RNA-sequencing, dual FISH fusion and array-CGH analysis, 7 of 13 tumors exhibited NTRK rearrangements (6 TPM3-NTRK1 and 1 EML4-NTRK3 ) and 3 a COL1A1-PDGFB fusion; in the other 3 neoplasms, all of which were positive with S100 (2 diffuse, 1 focal), we identified no rearrangement. All the NTRK fusion-positive sarcomas were located in the cervix and exhibited diffuse staining with Trk while all the other neoplasms were negative. CD34 was diffusely positive in all 3 of the COL1A1-PDGFB fusion sarcomas. The latter molecular abnormality is identical to that commonly found in dermatofibrosarcoma protuberans and has not been reported previously in uterine mesenchymal neoplasms. We suggest that uterine sarcomas with a morphology resembling fibrosarcoma (and in which leiomyosarcoma and the known molecularly confirmed high-grade endometrial stromal sarcomas have been excluded) can be divided into 3 groups:- an NTRK fusion group, a COL1A1-PDGFB fusion group and a group containing neither of these molecular abnormalities which, on the basis of positive staining with S100, could be tentatively classified as malignant peripheral nerve sheath tumor, although additional molecular studies may identify specific genetic alterations necessitating a nomenclature change. We suggest a diagnostic algorithm when reporting such neoplasms. Identification of these newly described fusion-associated sarcomas is important given the potential for targeted treatments.

Myxofibrosarcoma (MFS) is a common adult soft tissue sarcoma characterized by an infiltrative growth pattern and a high local recurrence rate. Here we report the genetic and epigenetic landscape of MFS based on the results of whole-exome sequencing ( N  = 41), RNA sequencing ( N  = 29), and methylation analysis ( N  = 41), using 41 MFSs as a discovery set, and subsequent targeted sequencing of 140 genes in the entire cohort of 99 MFSs and 17 MFSs' data from TCGA. Fourteen driver genes are identified, including potentially actionable therapeutic targets seen in 37% of cases. There are frequent alterations in p53 signaling (51%) and cell cycle checkpoint genes (43%). Other conceivably actionable driver genes including ATRX , JAK1 , NF1 , NTRK1 , and novel oncogenic BRAF fusion gene are identified. Methylation patterns cluster into three subtypes associated with unique combinations of driver mutations, clinical outcomes, and immune cell compositions. Our results provide a valuable genomic resource to enable the design of precision medicine for MFS. Myxofibrosarcoma occurs in adults and is associated with high local relapse. Here, based on exome/transcriptome sequencing and DNA methylation analysis, the authors identify driver genes and methylation clusters associated with unique combinations of mutations, outcomes, and immune cell compositions.

Sclerosing epithelioid fibrosarcoma (SEF) was originally described as a peculiar variant of fibrosarcoma in 1995. Subsequent studies showed that conventional SEF was associated with both immunohistochemical expression of MUC4 and EWSR1 / FUS gene rearrangements with CREB3L1 as the predominant fusion partner. Since then, a distinct group of fibrous tumors characterized by YAP1 :: KMT2A and KMT2A :: YAP1 gene rearrangements and SEF-like morphology has been described. These YAP1 :: KMT2A -rearranged sarcomas were further shown to lack both immunohistochemical expression of MUC4 and canonical EWSR1 / FUS gene rearrangements. To better understand whether the YAP1 :: KMT2A -rearranged sarcomas represent a subset of MUC4-negative SEF or a distinct entity, we studied 22 cases of YAP1 :: KMT2A -rearranged sarcomas, the largest series to date, and performed a literature review of all previously reported next-generation sequencing (NGS)-confirmed cases. These sarcomas often arose in young adults with a median age of 38 years and a male to female (M:F) ratio of 1.4:1. They predominantly involved somatic soft tissue; however, we report the first case of a tumor that primarily developed inside bone. Immunohistochemical studies showed that the tumors often demonstrated expression of YAP1 and EMA, while all tested cases were negative for MUC4. NGS confirmed the presence of YAP1 :: KMT2A gene fusions in all cases, some of which initially had false negative results with targeted FISH and solid tumor panel testing. Clinical follow-up information was available in 14 patients with a median follow-up of 25 months (range 1 to 170 months). Local recurrence occurred in three patients (21%) and metastasis developed in seven patients (50%). DNA methylation analysis further showed that YAP1 :: KMT2A -rearranged sarcomas formed a distinct cluster, which was clearly separate from both conventional SEF and low-grade fibromyxoid sarcoma (LGFMS). These results suggest that YAP1 :: KMT2A -rearranged sarcomas likely represent a unique sarcoma subtype with propensity for aggressive behavior.

The list of potential gene fusions involving sarcomas, and particularly infantile fibrosarcoma-like tumors, continues to expand. The receptor tyrosine kinases are dysregulated in several tumor types, underscoring their roles in neoplasia. In this case presentation, we describe a pulmonary metastasis with two novel gene fusions ( FKBP5 :: PRKCA and in-frame SEPT7 :: RAF1 ) occurring at least two decades after the primary tumor developed.

Compared with transplanted tumors, autochthonous tumors are difficult to cure using experimental radiation therapy in mice. Here we analyzed differences in immune-related gene expression profiles between mouse fibrosarcomas subcutaneously induced by 3-methylcholanthrene (3MC) and their corresponding transplanted tumors. The immune genes examined were Pd1, Pdl1, Pdl2, Cd3d, Cd8a, Cd8b, Ifnγ, Itga2, Gzmb, and Foxp3. Among 12 tumors, one was non-transplantable and showed a benign phenotype with an abundance of DX5+ natural killer cells and CD8+ T cells together with increased IFNγ expression and mRNA levels of all immune genes except for Itga2. The other 11 transplantable tumors showed increased expression of Pd1, Pdl1, Pdl2, Cd3d, Cd8b, and Ifnγ following transplantation into syngeneic mice. These effects of transplantation highlight the relevance of immune gene expression status to the curability of tumors.

With the increasing use of next generation sequencing in soft tissue pathology, particularly in neoplasms not fitting any World Health Organization (WHO) category, the spectrum of EWSR1 fusion-associated soft tissue neoplasms has been expanding significantly. Although recurrent EWSR1::ATF1 fusions were initially limited to a triad of mesenchymal neoplasms including clear cell sarcoma of soft tissue, angiomatoid fibrous histiocytoma and malignant gastrointestinal neuroectodermal tumor (MGNET), this family has been expanding. We herein describe 4 unclassified extra-abdominal soft tissue (n = 3) and bone (n = 1) neoplasms displaying epithelioid and round cell morphology and carrying an EWSR1::ATF1 fusion. Affected were 3 males and 1 female aged 20–56 years. All primary tumors were extra-abdominal and deep-seated (chest wall, mediastinum, deltoid, and parapharyngeal soft tissue). Their size ranged 4.4–7.5 cm (median, 6.2). One patient presented with constitutional symptoms. Surgery with (2) or without (1) neo/adjuvant therapy was the treatment. At last follow-up (8–21 months), 2 patients developed progressive disease (1 recurrence; 1 distant metastasis). The immunophenotype of these tumors is potentially misleading with variable expression of EMA (2 of 3), pankeratin (2 of 4), synaptophysin (2 of 3), MUC4 (1 of 3), and ALK (1 of 3). All tumors were negative for S100 and SOX10. These observations point to the existence of heretofore under-recognized group of epithelioid and round cell neoplasms of soft tissue and bone, driven by EWSR1::ATF1 fusions, but distinct from established EWSR1::ATF1-associated soft tissue entities. Their overall morphology and immunophenotype recapitulate that of the emerging EWSR1/FUS::CREB fusion associated intra-abdominal epithelioid/round cell neoplasms. Our cases point to a potentially aggressive clinical behavior. Recognizing this tumor type is mandatory to delineate any inherent biological and/or therapeutic distinctness from other, better-known sarcomas in the differential diagnosis including sclerosing epithelioid fibrosarcoma.

Infantile fibrosarcoma (IFS) is malignant fibroblastic tumor of infants characterized genetically by ETV6::NTRK3 fusion. Tumors that show morphology indistinguishable from IFS but harbor alternative genetic alterations are uncommon, which have been designated as IFS-like tumors. We report two cases of IFS-like tumors harboring an NTRK1 rearrangement and arsing from genitourinary system. The patients aged 3 and 14 years. One arose in the kidney and one in the paratesticular region. The tumors measured 13 and 3.5 cm in greatest dimension. Both tumors were composed of cellular, mildly atypical, spindle to ovoid cells arranged haphazardly or in intersecting fascicles within a collagenized to myxoid stroma. Mitoses numbered 3 and 5/10 high-power fields. Tumor cells in both neoplasms demonstrated variable co-expression of CD34 and S100 protein, and diffuse and strong cytoplasmic staining for pan-TRK and TrkA. Fluorescence in-situ hybridization demonstrated NTRK1 rearrangement in both tumors. Targeted RNA-sequencing identified CPSF6::NTRK1 fusion and TMP3::NTRK1 fusion. Limited follow-up showed no tumor recurrences or metastases. We expand the clinicopathologic spectrum of IFS-like tumors harboring alternative NTRK1 fusions.

Soft tissue tumors of infancy encompass an overlapping spectrum of diseases that pose unique diagnostic and clinical challenges. We studied genomes and transcriptomes of cryptogenic congenital mesoblastic nephroma (CMN), and extended our findings to five anatomically or histologically related soft tissue tumors: infantile fibrosarcoma (IFS), nephroblastomatosis, Wilms tumor, malignant rhabdoid tumor, and clear cell sarcoma of the kidney. A key finding is recurrent mutation of EGFR in CMN by internal tandem duplication of the kinase domain, thus delineating CMN from other childhood renal tumors. Furthermore, we identify BRAF intragenic rearrangements in CMN and IFS. Collectively these findings reveal novel diagnostic markers and therapeutic strategies and highlight a prominent role of isolated intragenic rearrangements as drivers of infant tumors. Soft tissue tumors in infants encompass an overlapping spectrum of diseases posing unique diagnostic and clinical challenges. Here, the authors investigate the genetic basis of cryptogenic congenital mesoblastic nephroma and infantile fibrosarcoma lacking the canonical NTRK3-ETV6 fusion gene, and identify therapeutically tractable intragenic rearrangements in EGFR and BRAF .