The Recent Advances in Molecular Diagnosis of Soft Tissue Tumors

Soft tissue tumors are rare mesenchymal tumors with divergent differentiation. The diagnosis of soft tissue tumors is challenging for pathologists owing to the diversity of tumor types and histological overlap among the tumor entities. Present-day understanding of the molecular pathogenesis of soft tissue tumors has rapidly increased with the development of molecular genetic techniques (e.g., next-generation sequencing). Additionally, immunohistochemical markers that serve as surrogate markers for recurrent translocations in soft tissue tumors have been developed. This review aims to provide an update on recently described molecular findings and relevant novel immunohistochemical markers in selected soft tissue tumors.


Introduction
Soft tissue tumors comprise a heterogeneous group of tumors with a wide spectrum of differentiation. Soft tissue sarcomas represent less than 1% of all malignant neoplasms [1]. They present diagnostic challenges for pathologists due to the large number of tumor types, the rarity of each tumor type, their considerable morphologic diversity and overlap, and their intrinsic and technological complexity [2]. The classical diagnosis of soft tissue tumors is based on histological findings and ancillary tissue-based tests such as immunohistochemistry. Recent progress in molecular genetics in soft tissue tumors has improved diagnostic precision and refined the classification of these tumors [3].
Molecular genetics and immunohistochemistry are rapidly advancing areas in the diagnosis of soft tissue tumors. Immunohistochemistry plays a crucial role in providing genetic information on tumors. Various types of molecular alterations, including (1) specific chromosomal translocations, (2) specific mutations, (3) gene deletions, (4) gene amplifications, and (5) epigenetic alterations, are efficiently detectable via immunohistochemistry [4]. The classification of soft tissue tumors continues to evolve as new molecular genetic abnormalities are identified [5].
Herein, we review recently described molecular findings and relevant novel immunohistochemical markers in selected soft tissue tumors that can help with diagnosis.

Etiology
The etiology of most benign and malignant soft tissue tumors is unknown. Minorities are associated with germline mutations in tumor suppressor genes and occur in familial cancer syndromes, such as neurofibromatosis type 1, Gardner syndrome, Li-Fraumeni syndrome, Osler-Weber Rendu syndrome, etc. In rare cases (<10%), genetic and environmental factors, immunodeficiency, irradiation, and viral infections have been linked to the development of malignant soft tissue tumors [1].

Molecular Tests
Molecular tests have become increasingly important in diagnosing soft tissue tumors [9,10]. Common molecular methods include conventional cytogenetics, reversetranscriptase polymerase chain reaction (RT-PCR), and fluorescence in situ hybridization (FISH). Conventional cytogenetics requires fresh tissue and is used to evaluate the entire karyotype. In contrast, FISH and RT-PCR are applied to identify specific translocations/amplifications associated with a given tumor type [11,12]. RT-PCR and FISH are considered complementary; the choice of one over the other is largely dictated by the expertise of the laboratory. Particularly, FISH is highly desirable in the evaluation of round cell sarcomas, spindle cell tumors, well-differentiated adipocytic tumors, and myxoid tumors [11].
More recently, next-generation sequencing (NGS) (massively parallel sequencing or deep sequencing) has emerged as a major tool for identifying known or novel molecular alterations in a wide array of soft tissue tumors [13][14][15][16]. NGS is a highly sensitive method for detecting genetic alterations and can help to diagnose more precisely and characterize more detailed genetic alterations. Additionally, NGS will provide further insight into the pathogenesis of soft tissue tumors and the basis for the development of targeted therapies. Current European Society for Medical Oncology (ESMO) guidelines [17] suggest that the morphologic and immunohistochemical analyses should be complemented by molecular pathology: (1) when the specific histologic diagnosis is uncertain, (2) when the clinicopathologic presentation is unusual, or (3) when the genetic information may have prognostic or predictive relevance. If the molecular analysis is not available, it is recommended that you send it to a reference with all molecular analysis equipment.

Immunohistochemistry
Over the last decade, molecular genetic findings have led to the development of novel, inexpensive, and quick diagnostic tests with immunohistochemical stains [18]. Recently described immunohistochemical markers are classified into three general categories: (1)  focal nuclear atypia in both adipocytes and stromal cells [34]. "ALT" and "WDLPS" are synonyms for explaining morphologically and genetically identical lesions. Genetically, amplification of MDM2 in 12q15 is almost always present. In addition, several other genes located in the 12q13-q15 region, including CDK4, TSPAN31, HMGA2, YEATS4, CPM, and FRS2, are commonly coamplified with MDM2 [35,36]. Immunohistochemically, MDM2 and/or CDK4 nuclear immunopositivity is present in most cases [36]. Immunohistochemistry for MDM2 and CDK4 has now become commonly used. However, these antibodies are not exclusively specific since they demonstrate positive staining in malignant peripheral nerve sheath tumors (MPNSTs) [37] and endometrial stromal sarcomas [38]. Nuclear expression of MDM2 in histiocytes in fat necrosis represents another major pitfall. Moreover, MDM2 is also amplified in intimal sarcoma, lowgrade central osteosarcoma, and parosteal osteosarcoma [39][40][41]. Molecular testing for MDM2 amplification should be considered in recurrent lipomas, lipomatous tumors with equivocal cytologic atypia, large lipomatous tumors (>15 cm) without cytologic atypia, and lipomatous tumors lacking cytologic atypia in the retroperitoneum, pelvis, and abdomen [42].

Dedifferentiated Liposarcoma
Dedifferentiated liposarcoma (DDLPS) is an ALT/WDLPS that shows an abrupt transition to non-lipogenic sarcoma of variable histological grade, either in the primary disease or in a recurrence [43]. It should be noted that a well-differentiated component may not be identifiable. The dedifferentiated component may show lipoblastic differentiation [44]. Genetically, DDLPS overlaps with ALT/WDLPS and is characterized by the amplification of MDM2 and CDK4 [35,45]. As in ALT/WDLPS, several other genes from the 12q13-q21 region and other chromosomal regions are variably coamplified with MDM2. The karyotypes and quantitative genomic profiles of DDLPS are often more complicated than those of ALT/WDLPS. Immunohistochemically, nuclear expression of MDM2 and/or CDK4 is observed in the majority of DDLPS cases

Desmoid Fibromatosis
Desmoid fibromatosis is a locally aggressive but non-metastasizing deep-seated (myo)fibroblastic neoplasm with infiltrative growth and a high tendency to local recurrence [59]. The majority (90-95%) of sporadic desmoid tumors result from point mutations of the CTNNB1 gene on 3p21, which encodes β-catenin [60,61]. A minority of desmoid tumors occur in Gardner syndrome and harbor germline mutations of the APC gene on 5q21-q22 [62][63][64]. The activating mutations in CTNNB1 or inactivating mutations in APC interfere with the proteasomal degradation of β-catenin, resulting in the accumulation of β-catenin in the nucleus [65]. Immunohistochemically, nuclear expression of β-catenin is present in~80% of tumors [66].
Importantly, although aberrant nuclear β-catenin is a helpful finding to support the diagnosis, nuclear β-catenin expression is also seen in superficial fibromatoses and some sarcomas and is consequently neither specific nor fully sensitive for desmoid fibromatosis [67,68]. CTNNB1 mutation analysis may be useful in small biopsy specimens and/or in cases of equivocal immunostaining for β-catenin [69,70]. Moreover, desmoid fibromatosis with specific mutations in exon 3 of CTNNB1, particularly S45F, has a greater tendency to local recurrence [71].

Solitary Fibrous Tumor
Solitary fibrous tumor (SFT) is a fibroblastic tumor with prominent, branched, thinwalled, dilated (staghorn) vasculature [72]. The genetic hallmark of SFT is a paracentric inversion involving chromosome 12q, resulting in the fusion of the NAB2 and STAT6 genes [73,74]. Overexpression of the NAB2::STAT6 gene fusion has been reported to induce proliferation in cultured cells and activate the expression of EGR-responsive genes [75]. These results establish NAB2::STAT6 as the defining driver mutation of SFT. Overexpression of ALDH1A1 (ALDH1), EGFR, JAK2, histone deacetylases, and retinoic acid receptors may also contribute to tumorigenesis [76,77]. In addition, TERT promoter mutations [78] and deletions or mutations of TP53 [79] are associated with aggressive behavior and dedifferentiation. Immunohistochemically, the NAB2::STAT6 fusion leads to the nuclear expression of STAT6 [80] (Figure 2). Thus, STAT6 immunohistochemistry is a sensitive and specific surrogate for all fusions [72]. CC34 is typically positive. IGF2 overexpression is consistently detected in SFTs, regardless of anatomical location, and may be associated with triggering hypoglycemia in some patients [76]. STAT6 gene is located on the long arm of chromosome 12 in the same region as MDM2 and is, therefore, coamplified and overexpressed in a subset of DDLPS [81]. Dedifferentiated SFTs show an abrupt transformation into an indistinguishable pleomorphic appearance. Nuclear expression of STAT6 may be lost in dedifferentiated SFT [82]. The behavior of SFTs has been challenging to predict. A new risk stratification model based on patient age, tumor size, necrosis, and mitotic activity has been shown to more accurately predict the prognosis of SFTs [83].

Inflammatory Myofibroblastic Tumor
Inflammatory myofibroblastic tumor (IMT) is a characteristic, rarely metastasizing neoplasm composed of myofibroblastic and fibroblastic spindle cells accompanied by an inflammatory infiltrate of plasma cells, lymphocytes, and/or eosinophils [84]. Genetically, IMTs are heterogeneous. In 50-60% of cases of IMT in children and young adults, the tumors fuse the ALK gene on 2p23 with various partner genes, including TPM3, TPM4, CLTC, and others [85,86]. ALK rearrangement is uncommon in IMTs diagnosed in older adults. ROS1 and NTRK3 gene rearrangements are each found in 5-10% of IMTs [87][88][89]. Very rare cases have RET or PDGFRB gene rearrangements [90]. Epithelioid inflammatory myofibroblastic sarcoma (EIMS) is a rare, aggressive variant dominated by epithelioid cells with amphophilic cytoplasm. EIMS has often been associated with RANBP2::ALK or RRBP1::ALK gene rearrangements [90,91]. Immunohistochemically, ALK expression is detectable in 50-60% of IMT cases ( Figure 3). The ALK immunostaining pattern varies depending on the ALK fusion partner; for example, RANBP2::ALK is correlated with a nuclear membranous pattern, RRBP1::ALK with a perinuclear accentuated cytoplasmic pattern, and CLTC::ALK with a granular cytoplasmic pattern. This is while several other ALK fusion variants illustrate a diffuse cytoplasmic pattern (most commonly seen in IMT) [90]. IGF2 overexpression is consistently detected in SFTs, regardless of anatomical location, and may be associated with triggering hypoglycemia in some patients [76]. STAT6 gene is located on the long arm of chromosome 12 in the same region as MDM2 and is, therefore, coamplified and overexpressed in a subset of DDLPS [81]. Dedifferentiated SFTs show an abrupt transformation into an indistinguishable pleomorphic appearance. Nuclear expression of STAT6 may be lost in dedifferentiated SFT [82]. The behavior of SFTs has been challenging to predict. A new risk stratification model based on patient age, tumor size, necrosis, and mitotic activity has been shown to more accurately predict the prognosis of SFTs [83].

Inflammatory Myofibroblastic Tumor
Inflammatory myofibroblastic tumor (IMT) is a characteristic, rarely metastasizing neoplasm composed of myofibroblastic and fibroblastic spindle cells accompanied by an inflammatory infiltrate of plasma cells, lymphocytes, and/or eosinophils [84]. Genetically, IMTs are heterogeneous. In 50-60% of cases of IMT in children and young adults, the tumors fuse the ALK gene on 2p23 with various partner genes, including TPM3, TPM4, CLTC, and others [85,86]. ALK rearrangement is uncommon in IMTs diagnosed in older adults. ROS1 and NTRK3 gene rearrangements are each found in 5-10% of IMTs [87][88][89]. Very rare cases have RET or PDGFRB gene rearrangements [90]. Epithelioid inflammatory myofibroblastic sarcoma (EIMS) is a rare, aggressive variant dominated by epithelioid cells with amphophilic cytoplasm. EIMS has often been associated with RANBP2::ALK or RRBP1::ALK gene rearrangements [90,91]. Immunohistochemically, ALK expression is detectable in 50-60% of IMT cases ( Figure 3). The ALK immunostaining pattern varies depending on the ALK fusion partner; for example, RANBP2::ALK is correlated with a nuclear membranous pattern, RRBP1::ALK with a perinuclear accentuated cytoplasmic pattern, and CLTC::ALK with a granular cytoplasmic pattern. This is while several other ALK fusion variants illustrate a diffuse cytoplasmic pattern (most commonly seen in IMT) [90].
In ALK-negative cases, IHC for ROS1 and/or molecular assays for non-ALK gene fusions (e.g., NTRK3) may be useful [87,90]. ROS1-rearranged IMT typically shows a cytoplasmic expression of ROS1 [87]. Highly sensitive ALK antibody clones (5A4 and D5F3) can enhance the detection of the ALK protein in IMT [87]. A persistent partial response to the ALK inhibitor crizotinib has been reported in a patient with ALK-translocated IMT [92].  In ALK-negative cases, IHC for ROS1 and/or molecular assays for non-ALK gene fusions (e.g., NTRK3) may be useful [87,90]. ROS1-rearranged IMT typically shows a cytoplasmic expression of ROS1 [87]. Highly sensitive ALK antibody clones (5A4 and D5F3) can enhance the detection of the ALK protein in IMT [87]. A persistent partial response to the ALK inhibitor crizotinib has been reported in a patient with ALK-translocated IMT [92].

Low-Grade Fibromyxoid Sarcoma
Low-grade fibromyxoid sarcoma (LGFMS) is a malignant fibroblastic neoplasm with bland spindle cells that grow in whorling growth pattern, a matrix that can be either collagenous or myxoid, and arcades of small blood vessels [93]. Genetically, LGFMSs exhibit a characteristic t(7;16)(q33;p11) translocation that results in the FUS::CREB3L2 fusion oncogene in > 90% of cases [94][95][96][97]. The FUS::CREB3L2 chimeric protein acts as an aberrant transcription factor, causing deregulated expression of CREB3L2 target genes [97]. Rare cases of LGFMS show the presence of FUS::CREB3L1 or EWSR1::CREB3L1 fusion genes [94,98]. The MUC4 gene on the long arm of chromosome 3 (3q29) is upregulated in LGFMS [97]. Immunohistochemically, tumor cells show strong, diffuse cytoplasmic expression of MUC4 in 100% of LGFMS cases [99,100] (Figure 4). EMA is also expressed in 80% of cases.   MUC4 is a high-molecular-weight transmembrane glycoprotein expressed on the cell membrane of many epithelial cells. It is a highly sensitive and specific marker for LGFMS and can help distinguish LGFMS from histologic mimics, such as soft tissue perineurioma [93]. If MUC4 is negative or unavailable to confirm the diagnosis, identification of FUS::CREB3L2 (or other uncommon variants) offers molecular genetic support for the diagnosis of LGFMS [93].
Cases showing hybrid features of SEF and LGFMS are now well described. Most cases of hybrid SEF/LGFMS show FUS::CREB3L2 gene fusion and MUC4 immunopositivity [96]. A small subset of SEFs lacks MUC4 expression. Recently, recurrent YAP1 and KMT2A gene rearrangements have been identified in MUC4-negative SEFs [108]. SEF has been shown to exhibit more aggressive behavior than LGFMS [109].

Infantile Fibrosarcoma
Conventional fibrosarcoma falls into two main categories: adult and infantile types. Infantile fibrosarcoma (IFS) is a malignant fibroblastic tumor that occurs most frequently in infancy [110]. It is a locally aggressive and rapidly growing tumor that rarely metastasizes. Most of these tumors harbor the ETV6::NTRK3 fusion resulting from t(12;15)(p13;q25). NTRK3 is a receptor tyrosine kinase. The ETV6::NTRK3 fusion gene encodes a constitutively activated chimeric tyrosine kinase that signals via the RAS-MAPK and PI3K signaling pathways to drive cellular transformation and oncogenesis [111]. In addition, EML4::NTRK3 fusion has been reported in rare cases [112]. Alternative gene fusions have been reported in a subset of cases, including NTRK1, NTRK2, BRAF, and MET [113,114]. Immunohistochemically, IFSs with NTRK gene rearrangements are often positive for a pan-TRK antibody [115].
The ETV6::NTRK3 fusion is found in a variety of neoplasms, such as cellular congenital mesoblastic nephroma [111], secretory carcinomas of the breast [116], and salivary glandtype secretory carcinoma [117]. It has been demonstrated that pan-TRK antibodies are not entirely specific for tumors with NTRK rearrangements [115]. Hence, FISH is most often used to confirm the diagnosis. Adult fibrosarcoma is an uncommon sarcoma composed of relatively monomorphic fibroblastic tumor cells with variable collagen production and often herringbone architecture. Its diagnosis is based on the principle of exclusion; true examples are exceedingly rare [118].

Epithelioid Hemangioma
Epithelioid hemangioma is a benign vascular neoplasm consisting of well-formed blood vessels lined by plump, epithelioid (histiocytoid) endothelial cells with abundant eosinophilic cytoplasm and a variable infiltrate of eosinophils [119]. Genetically, epithelioid hemangiomas are characterized by recurrent fusion genes affecting the FOS or FOSB gene in approximately 50% of the cases. The gene partners for FOS include LMNA, MBNL1, VIM, and lincRNA [120,121], whereas FOSB is often fused to ZFP36, WWTR1, or ACTB [122,123]. The key event in the pathogenesis is the dysregulation of the FOS family (FOS, FOSB, FOSL1, and FOSL2) of transcription factors through chromosomal translocation. Immunohistochemically, a subset of cases shows FOS or FOSB expression, which may be diagnostically useful [121,123].
Interestingly, angiolymphoid hyperplasia with an eosinophilia subtype (cutaneous epithelioid hemangioma) may be non-neoplastic as they lack FOS or FOSB gene rearrangement [120]. Although FOSB fusions have not been found in cases of angiolymphoid hyperplasia with eosinophilia, the endothelial cells in this tumor are often positive for FOSB [120,124]. FOSB fusion-associated tumors, particularly ZFP36::FOSB, are more commonly cellular and solid, with some cytologic atypia and occasional necrosis [123].

Pseudomyogenic Hemangioendothelioma
Pseudomyogenic hemangioendothelioma (PHE) is a rarely metastasizing endothelial neoplasm commonly occurring in young adult males [125]. It often presents as multiple discontinuous nodules at different tissue levels and histologically mimics a myoid tumor or epithelioid sarcoma (EPS). PHEs have t(7;19)(q22;q13), resulting in SER-PINE1::FOSB gene fusion [126,127]. An alternative ACTB::FOSB gene fusion was identified in half of the cases [122]. These fusions lead to the upregulation of FOSB, a member of the FOS family of transcription factors that encode leucine zipper proteins that interact with the JUN family to regulate cell proliferation, differentiation, angiogenesis, and survival. Immunohistochemically, nuclear staining for FOSB is present in almost all cases of PHE [124,128]. PHE also shows a nuclear expression of the endothelial transcription factors FLI1 and ERG [129,130]. Approximately 50% of cases are positive for CD31. In addition, SMA is predominantly expressed in one-third of tumors.
The clinicopathologic features and behavior do not differ between PHEs with SER-PINE1::FOSB and ACTB::FOSB fusions are rare, although tumors with the ACTB variant occur more frequently as solitary lesions [122]. Recently, FOSB fusions with WWTR1 or CLTC have been described, the latter in a bone lesion in an adolescent [131,132].
Approximately 20% of ARMS cases are fusion-negative [150]. Fusion-negative ARMS is genetically heterogeneous and may have alternative fusions with other genes (NCOA1 and INO80D). Histologic appearances of ARMS do not predict the presence or type of gene fusion. However, solid growth or mixed embryonal/alveolar patterns show a higher incidence of fusion negativity [150]. Fusion-positive ARMS patients have a poorer outcome than fusion-negative ARMS patients [151].

Spindle Cell/Sclerosing Rhabdomyosarcoma
Spindle cell/sclerosing rhabdomyosarcoma (RMS) is a type of RMS with fascicular spindle cells and/or primitive cells in a prominent hyaline collagenous stroma [152]. Spindle cell/sclerosing RMSs are categorized into three groups based on their genetic background. The first group, congenital/infantile spindle cell RMS, shows gene fusions involving VGLL2, SRF, TEAD1, NCOA2, and CITED2 [153,154]. The second group includes most of the spindle cell/sclerosing RMS in adolescents and young adults and a subset of tumors in older adults, showing the presence of the MYOD1 mutation [154,155]. The third group shows no recurrent, identifiable genetic alterations. Immunohistochemically, spindle cell/sclerosing RMS typically shows diffuse nuclear staining for MyoD1. Myogenin shows only limited expression in most spindle cells/sclerosing RMSs.
Patients with PDGFRA-mutant tumors have a lower risk of metastasis than patients with KIT-mutant tumors [170]. GISTs harboring the PDGFRA D842V mutation have been shown to respond to avapritinib-a novel KIT and PDGFRA inhibitor [171]. Recently, the use of SDHB by immunohistochemistry has been used to stratify GIST into an SDHBretained and an SDHB-deficient group, regardless of whether the responsible mutation was acquired or inherited. This widely available screening approach can facilitate decisions about further molecular testing strategies [172].

Malignant Melanotic Nerve Sheath Tumor
A malignant melanotic nerve sheath tumor (MMNST) is a rare peripheral nerve sheath tumor composed of tumor cells with features of both Schwann cell and melanocytic differentiation [182]. It is most commonly associated with spinal or autonomic nerves near At the molecular level, epithelioid MPNSTs differ from conventional MPNSTs. Approximately 75% of epithelioid MPNST cases show SMARCB1 gene inactivation, resulting in SMARCB1 loss by immunohistochemistry [180]. In contrast to conventional MPNSTs, nuclear staining for H3K27me3 is retained in epithelioid MPNSTs (i.e., normal). MPN-STs showing complete heterologous rhabdomyoblastic differentiation mimic spindle cell RMS. Immunohistochemistry for H3K27me3 reliably distinguishes MPNST with complete heterologous rhabdomyoblastic differentiation from spindle cell RMS [181].

Malignant Melanotic Nerve Sheath Tumor
A malignant melanotic nerve sheath tumor (MMNST) is a rare peripheral nerve sheath tumor composed of tumor cells with features of both Schwann cell and melanocytic differentiation [182]. It is most commonly associated with spinal or autonomic nerves near the midline. MMNSTs are frequently associated with the Carney complex. The majority of MMNSTs have inactivating mutations of the PRKAR1A gene on 17q24.2 [183]. PRKAR1A plays a central role in the development of MMNST. Immunohistochemically, PRKAR1A expression is typically lost in MMNST [183,184]. MMNSTs strongly express S100 protein, SOX10, and various melanocytic markers, including HMB45, Melan-A, and tyrosinase.
Psammoma bodies are found in approximately 50% of cases [182]. There are no clinical distinctions between psammomatous and non-psammomatous MMNSTs [183,184]. In addition, their histologic features do not correlate well with their clinical behavior. MMNSTs often show aggressive behavior [185,186]. It is critical to distinguish MMNST from malignant melanoma. The paravertebral location, heavy melanin pigmentation, psammoma bodies, and loss of PRKAR1A expression suggest the diagnosis of MMNST [184].

Synovial Sarcoma
Synovial sarcoma (SS) is a monomorphic spindle cell mesenchymal neoplasm with variable epithelial differentiation [187]. SS harbors a unique t(X;18)(p11.2;q11.2) translocation [188], by which one of the SSX genes (SSX1, SSX2, or SSX4) on the X chromosome fuses to SS18 on chromosome 18 [189]. Approximately two-thirds of SS cases harbor an SS18::SSX1 fusion, one-third harbor an SS18::SSX2 fusion, and uncommon cases harbor an SS18::SSX4 fusion [189,190]. SS18::SSX functions as an oncogene, and its expression is necessary to maintain the transformed phenotype of SS cells [191,192]. Immunohistochemically, a novel SS18-SSX fusion-specific antibody is highly sensitive (95%) and specific (100%) for SS [193] (Figure 7). Thus, SS18-SSX immunohistochemistry is a useful tool to confirm SS diagnosis, and it can replace molecular testing in most cases [194]. Moderate or strong nuclear staining for the transcriptional corepressor TLE1 is present in the majority of SS cases [195]. However, TLE1 staining is not specific to SS because it can also exist in histological mimics of SS, particularly MPNST and SFT [195]. necessary to maintain the transformed phenotype of SS cells [191,192]. Immunohistochemically, a novel SS18-SSX fusion-specific antibody is highly sensitive (95%) and specific (100%) for SS [193] (Figure 7). Thus, SS18-SSX immunohistochemistry is a useful tool to confirm SS diagnosis, and it can replace molecular testing in most cases [194]. Moderate or strong nuclear staining for the transcriptional corepressor TLE1 is present in the majority of SS cases [195]. However, TLE1 staining is not specific to SS because it can also exist in histological mimics of SS, particularly MPNST and SFT [195]. Interestingly, SS shows correlations between fusion type, tumor histology, and patient sex. Almost all SS18::SSX2 fusion cases show monophasic histology. In contrast SS18::SSX1 fusion cases show an approximate 2:1 ratio of monophasic to biphasic SS [191] Males show a 3:2 ratio of SS18::SSX1 to SS18::SSX2, whereas in females, the ratio is close Interestingly, SS shows correlations between fusion type, tumor histology, and patient sex. Almost all SS18::SSX2 fusion cases show monophasic histology. In contrast, SS18::SSX1 fusion cases show an approximate 2:1 ratio of monophasic to biphasic SS [191]. Males show a 3:2 ratio of SS18::SSX1 to SS18::SSX2, whereas in females, the ratio is close to 1:1. Molecular confirmation (if available) of an SS18::SSX1/2/4 fusion should ideally be performed for optimal diagnostic accuracy [57]. Recently, novel and rare SSX1 fusions to non-SS18 genes have been reported in SS [196].

Epithelioid Sarcoma
Epithelioid sarcoma (EPS) is a malignant mesenchymal neoplasm exhibiting partial or complete epithelioid cytomorphology and evidence of epithelial differentiation [197]. Two clinicopathological subtypes are recognized in EPSs: (1) the classic (or distal) form, characterized by its propensity for acral sites and pseudogranulomatous growth pattern, and (2) the proximal-type (large cell) subtype, occurring mainly in proximal/truncal regions and consisting of nests and sheets of large epithelioid cells. Genetically, approximately 90% of both classic and proximal-type patients have SMARCB1 (INI1) deletion. The SMARCB1 gene (also called BAF47, INI1, or SNF5) at chromosome 22q11.2 encodes a protein part of the SWI/SNF chromatin-remodeling complex present in normal cells. Loss of expression of SWI/SNF chromatin-remodeling complex proteins plays an essential role in tumorigenesis [198]. Immunohistochemically, loss of SMARCB1 expression occurs in the majority of EPS cases [199][200][201]. ERG expression is commonly observed in EPSs, which can lead to confusion with endothelial tumors [202][203][204]. Most EPS cases are positive for cytokeratins and EMA. CD34 is expressed in 50-60% of EPS cases, which helps distinguish EPS from carcinomas.
An extreme minority of EPSs retain SMARCB1 (INI1) protein expression. The biological behavior of SMARCB1 (INI1)-preserved EPS is more aggressive than that of EPS with complete loss of SMARCB1 expression [198].

Extrarenal Rhabdoid Tumor
An extrarenal rhabdoid tumor (ERT) is a highly malignant soft tissue neoplasm composed of characteristic rounded or polygonal rhabdoid cells with glassy eosinophilic cytoplasm containing hyaline-like inclusion bodies, eccentric nuclei, and macronucleoli [205]. It mainly affects infants and children. Morphologically and genetically identical tumors also occur in the kidney and brain. Most ERTs are characterized by biallelic alterations of the SMARCB1 gene, resulting in a loss of expression of SMARCB1 (INI1). Immunohistochemically, the tumors show loss of SMARCB1 (INI1) expression [206,207]. In addition, SALL4 and glypican-3 expressions are frequently observed in ERTs [208,209].
A loss of SMARCB1 expression is also present in EPS, epithelioid MPNST, and myoepithelial carcinoma. When a tumor histologically similar to ERT occurs in adults, pathologists should first consider the possibility of malignant melanoma or other tumor types. Familial cases are typically associated with germline mutations in the SMARCB1 gene [210,211]. Mutations and/or loss of the SMARCA4 gene in 19p13.2 have been reported in rare rhabdoid tumors with retention of SMARCB1 expression [212].
Although the ASPSCR1::TFE3 fusion in sarcomas appears highly specific and sensitive for ASPS, the same gene fusion is also found in a small subset of TFE3-rearranged renal cell carcinomas that affect young patients and have a morphology similar to ASPS [222]. In a clinical study with the c-Met inhibitor crizotinib in ASPS, disease stabilization was reported in most TFE3-rearranged ASPS MET-altered patients [223]. Therefore, c-MET could be a potential therapeutic target in ASPS.

Desmoplastic Small Round Cell Tumor
Desmoplastic small round cell tumor (DSRCT) is a malignant mesenchymal neoplasm of primitive small round tumor cells associated with prominent desmoplastic stroma and polyphenotypic differentiation [224]. It is characterized by a recurrent chromosomal translocation t(11;22)(p13;q12), resulting in the fusion of the EWSR1 gene on 22q12.2 and the WT1 gene on 11p13 [225][226][227][228]. The aberrant transcription of EWSR1::WT1 regulates the expression of various genes and activates the neural reprogramming factor ASCL1 to induce partial neural differentiation [229,230]. Immunohistochemically, DSRCT shows a characteristic polyphenotypic profile expressing epithelial, muscular, and neural markers. A polyclonal antibody to the carboxy (C)-terminus of WT1 is reactive and useful for diagnosis [231].
Recently, there was a report of three unusual tumors affecting the female genital tract with EWSR1::WT1 gene fusion lacking features of DSRCT [232]. These findings suggest the pleiotropy of the EWSR1::WT1 fusion is possible and not restricted to DSRCT. Detection of the EWSR1::WT1 gene fusion can be particularly useful in cases with unusual clinical or histological features [233]. DSRCT is an aggressive disease, despite multimodal therapies [234]. Hence, a better understanding of disease biology is necessary for identifying potential targets in the future [235].

Intimal Sarcoma
Intimal sarcomas are malignant mesenchymal tumors arising within the large blood vessels of the systemic and pulmonary circulations and in the heart [236]. The defining features are primarily intraluminal growth, obstruction of the lumen in the originating vessel, and seeding of tumor emboli in peripheral organs. Genetically, frequent amplifications/gains in the 12q13-q14 region (which contains MDM2 and CDK4) and (co)amplification/gains of PDGFRA, EGFR, and KIT are present [237][238][239][240]. MDM2 and PDGFR pathways may play a role in the pathogenesis of intimal sarcoma. Immunohistochemically, nuclear expression of MDM2 is observed in at least 70% of cases [237,240]. In addition, rare cases containing rhabdomyosarcomatous differentiation are positive for myogenin and MyoD1 [42].

Ewing Sarcoma
Ewing sarcoma (EWS) is a small round cell sarcoma characterized by a fusion of a FET gene family member (most commonly EWSR1) and an ETS gene family member [243]. Further mutations can occur in STAG2 (15-22%), CDKN2A (12%), and TP53 (7%) [244][245][246]. FET::ETS fusion genes encode chimeric transcription factors that function as master regulators to activate and repress thousands of genes. Expression of these aberrant transcription factors is required to develop EWS. The most common translocation (in 85-90% of cases) is t(11;22)(q24;q12), which results in the EWSR1::FLI1 fusion transcript and protein. The second most common is t(21;22)(q22;q12), which results in EWSR1::ERG in 5-10% of EWS cases. Immunohistochemically, strong, diffuse membranous expression of CD99 is observed in approximately 95% of EWSs. NKX2-2, a neuroendocrine/glial transcription factor, has a higher specificity than CD99 [247] (Figure 8). Strong nuclear ERG immunoreactivity is observed in EWS cases with EWSR1::ERG rearrangement [248]. FLI1 is expressed in the majority of EWS cases, regardless of the fusion variant. The adamantinoma-like variant of EWS consistently demonstrates diffuse cytokeratin, p63, and p40 positivity [249]. Because EWSR1 fusions are identified in a diverse array of tumor types, FISH for EWSR1 is not specific for EWS; nonetheless, in the appropriate context, demonstration of EWSR1 rearrangement is sufficient to confirm the diagnosis [250]. A FISH-based approach using break-apart probes for EWSR1 and/or FUS uncovers most EWS cases. However, a minority of cases with complex inversion/insertion, structural rearrangements, or cryptic insertions may be negative by FISH and require RNA-based techniques for molecular diagnosis [251,252].

Round Cell Sarcoma with EWSR1-Non-ETS Fusions
Round cell sarcomas with EWSR1-non-ETS fusions are round, and spindle cell sarcomas with EWSR1 or FUS fusions involving partners irrelevant to the ETS gene family [253]. This category includes EWSR1/FUS::NFATC2 sarcomas [254] and EWSR1::PATZ1 sarcomas [255]. EWSR1/FUS::NFATC2 sarcomas have a preference for the bone and consist of round to spindle cells arranged in cords, nests, and trabeculae on a myxohyaline background. EWSR1::PATZ1 sarcomas usually occur in the deep soft tissue and have diverse morphologic features, with a small round to spindle cells in the fibrous stroma, variable Because EWSR1 fusions are identified in a diverse array of tumor types, FISH for EWSR1 is not specific for EWS; nonetheless, in the appropriate context, demonstration of EWSR1 rearrangement is sufficient to confirm the diagnosis [250]. A FISH-based approach using break-apart probes for EWSR1 and/or FUS uncovers most EWS cases. However, a minority of cases with complex inversion/insertion, structural rearrangements, or cryptic insertions may be negative by FISH and require RNA-based techniques for molecular diagnosis [251,252].
CIC-mutated or rearranged angiosarcomas represent a potential diagnostic pitfall [269]. CIC fusions have also been described in central nervous system tumors [276]. CICrearranged sarcomas are aggressive tumors with frequent metastases and poor outcomes. Their five-year survival rate ranges from 17-43%, and the response to standard EWS chemotherapy regimens is generally poor [267,277].

Sarcoma with BCOR Genetic Alteration
Sarcomas with BCOR genetic alterations are clinically distinct sarcomas arising in soft tissue and bone and divided into two main groups. The first group is characterized by sarcomas with BCOR-related gene fusions (BCOR-fusion sarcomas), most frequently BCOR::CCNB3. The second group shows internal tandem duplication in BCOR (BCOR-ITD sarcomas), described in infantile undifferentiated round cell sarcomas and primitive myxoid mesenchymal tumors of infancy [278,279]. BCOR-fusion and BCOR-ITD sarcomas show a similar gene expression signature [280][281][282][283]. Immunohistochemically, all tumors with various BCOR gene alterations show strong and diffuse nuclear positivity for BCOR (Figure 9). BCOR immunostaining may be diagnostically useful but is not specific [282,284]. Additionally, SATB2, TLE1, and cyclin D1 expressions are present in most sarcomas with BCOR genetic alterations. BCOR::CCNB3 sarcomas also express CCNB3 [284,285]. Pediatric soft tissue tumors with BCOR-ITD show membranous and cytoplasmic expression of EGFR [286].
BCOR family tumors share a morphologic spectrum with a similar immunoprofile and gene expression, suggesting a shared pathogenesis. Since immunohistochemistry for either BCOR or CCNB3 is not completely sensitive and specific, a molecular genetic approach is necessary for diagnosis [284]. BCOR::CCNB3 sarcomas often respond to EWS regimens and have a similar outcome [283]. The outcomes of the other BCOR family tumors need to be better defined. Table 2 shows a summary of molecular genetic alterations and immunohistochemical markers in undifferentiated small round cell sarcomas. BCOR family tumors share a morphologic spectrum with a similar immunoprofile and gene expression, suggesting a shared pathogenesis. Since immunohistochemistry for either BCOR or CCNB3 is not completely sensitive and specific, a molecular genetic approach is necessary for diagnosis [284]. BCOR::CCNB3 sarcomas often respond to EWS regimens and have a similar outcome [283]. The outcomes of the other BCOR family tumors need to be better defined. Table 2 shows a summary of molecular genetic alterations and immunohistochemical markers in undifferentiated small round cell sarcomas.  Nuclear staining [282][283][284][285] 15. Emerging Entities 15.1. EWSR1::SMAD3-Positive Fibroblastic Tumor EWSR1::SMAD3-positive fibroblastic tumor (ESFT) is a benign neoplasm defined by a fusion of exon 7 of EWSR1 with exon 5 of SMAD3 [287][288][289]. It is characterized by small dermal and subcutaneous acral nodules and histological zonation with an acellular hyalinized center and peripheral fascicular spindle cell growth [290]. SMAD3 is a critical signal transducer in the TGF-β/SMAD signaling pathway involved in extracellular matrix synthesis by fibroblasts. Immunohistochemically, the fibroblastic tumor cells consistently show diffuse ERG nuclear expression, which correlates with a significant ERG mRNA upregulation [289].
At the transcriptional level, ESFTs also show overexpression of FN1 (fibronectin) [289]. Based on molecular data and morphologic and clinical similarities, ESFTs have been suggested to be associated with calcifying aponeurotic fibroma, lipofibromatosis, and lipofibromatosis-like neural tumors [289,290]. The diagnosis is primarily based on the detection of EWSR1::SMAD3 fusion [291]. The terminology of this tumor is provisional while the specific features await further determination.

NTRK-Rearranged Spindle Cell Neoplasm
NTRK-rearranged spindle cell neoplasms (other than infantile fibrosarcomas) are an emerging family of rare spindle cell neoplasms defined by NTRK fusions [292]. The tumors are characterized by haphazardly arranged monomorphic spindle cells, infiltrative growth in adipose tissue resembling lipofibromatosis, and characteristic stromal and perivascular keloid collagen. Most tumors harbor NTRK1 fusions with various partners, including LMNA, TPR, or TPM3 [293][294][295]. Rare cases with NTRK2 and NTRK3 fusions have also been reported [296]. The NTRK fusions lead to the activation of the oncogenic signaling pathway via chimeric proteins containing the tropomyosin receptor kinase domains of TRK-A, TRK-B, and TRK-C [297]. Immunohistochemically, most tumors with NTRK fusions are reactive with a monoclonal anti-pan-TRK antibody [117]. The staining can be either cytoplasmic or nuclear [115,298]. Most tumors show frequent coexpression of S100 protein and CD34. TRK-A immunohistochemistry is useful for the detection of NTRK1-rearranged tumors [299].
NTRK fusions have been reported at high frequency in various cancers, such as IFS and secretory breast carcinoma, and at a low frequency in other well-established tumors, such as GISTs [300,301]. Importantly, pan-TRK and TRK-A immunoreactivity are not completely specific, and additional molecular genetic testing is often required for a conclusive diagnosis. Hence, molecular detection of NTRK fusions can be useful in such cases [294,302]. Recently, NTRK-rearranged spindle cell neoplasms are ubiquitous tumors of myofibroblastic lineage with a distinct methylation class [303]. Our understanding of this tumor type is rapidly evolving. Additional genetic alterations will be discovered in further studies.

SWI/SNF Complex-Deficient Neoplasms
The SWItch/sucrose non-fermentable (SWI/SNF) complexes are a family of multisubunit complexes that use the energy of adenosine triphosphate hydrolysis to remodel nucleosomes [304]. Chromatin remodeling processes mediated by the SWI/SNF complexes are critical to the modulation of gene expression across various cellular processes, including stemness, differentiation, and proliferation. Recently, mutations in the genes encoding different subunits of the SWI/SNF complex (SMARCB1, SMARCA4, ARID1A, ARID1B, ARID1, and PBRM) have been identified in many adult malignancies, which include encompassing epithelial and mesenchymal tumors [305,306]. Several SMARCA4-deficient poorly differentiated and undifferentiated carcinomas/sarcomas delineated primarily based on BRG1 protein loss have been characterized in various anatomical locations [307].
Thoracic SMARCA4-deficient undifferentiated tumor is a high-grade malignant neoplasm significantly affecting the thorax in adults. It shows an undifferentiated or rhabdoid phenotype and a lack of SMARCA4 (BRG1), a vital member of the SWI/SNF chromatinremodeling complex [308]. The tumor is driven by biallelic inactivation of SMARCA4, including mainly nonsense and frameshift mutations. Histologically, the tumor consists of diffuse sheets of monomorphic, undifferentiated epithelioid cells with vesicular nuclei and prominent nucleoli, and frequent rhabdoid features. Immunohistochemically, complete loss of SMARCA4 (BRG1) expression is typical ( Figure 10). Additionally, there is a family of tumors defined by SMARCA4 loss, including small cell carcinoma of the ovary, hypercalcemic type [309], and large cell malignancies originating in the uterus [310]. Recently, SMARCA4-deficient sinonasal carcinomas have also been reported [311].
tumor consists of diffuse sheets of monomorphic, undifferentiated epithelioid cells with vesicular nuclei and prominent nucleoli, and frequent rhabdoid features. Immunohistochemically, complete loss of SMARCA4 (BRG1) expression is typical ( Figure  10). Additionally, there is a family of tumors defined by SMARCA4 loss, including small cell carcinoma of the ovary, hypercalcemic type [309], and large cell malignancies originating in the uterus [310]. Recently, SMARCA4-deficient sinonasal carcinomas have also been reported [311].

DICER1-Associated Sarcomas
The DICER1 gene is located on chromosome 14q32.13 and encodes an endoribonuclease in the ribonuclease (RNase) III family required for processing microRNA (miRNA) [312]. Dysregulation of microRNA by DICER1 mutations causes activation of oncogenes and underlies developmental and neoplastic disorders. A wide variety of DICER1-associated sarcomas have been reported in the literature [313]. DECER1-associated sarcomas, regardless of their site of origin, exhibit characteristic morphology that resembles pleuropulmonary blastoma [314]. The morphologic features include a subepithelial layer of malignant mesenchymal cells (cambium layer), areas of rhabdomyoblastic differentiation with positive staining for myogenin and myoD1, cellular/immature and occasionally malignant cartilage, bone/osteoid foci, and areas of anaplasia [315]. If a mesenchymal neoplasm is reported that has a combination of rhabdomyoblastic, cartilaginous, and neuroectodermal elements, a DICER1-associated neoplasm should be considered.
Kommoss et al. [316] reported the clinicopathological and molecular features of DICER1-mutant and DICER1-wild-type embryonal RMS in a series of genitourinary tumors. They suggested that DICER1-mutant ERMS might represent a distinct subtype in the future classification of RMS. Unsupervised hierarchical clustering of array-based whole-genome methylation data of a subset of DICER1-mutant sarcomas has revealed that

DICER1-Associated Sarcomas
The DICER1 gene is located on chromosome 14q32.13 and encodes an endoribonuclease in the ribonuclease (RNase) III family required for processing microRNA (miRNA) [312]. Dysregulation of microRNA by DICER1 mutations causes activation of oncogenes and underlies developmental and neoplastic disorders. A wide variety of DICER1-associated sarcomas have been reported in the literature [313]. DECER1-associated sarcomas, regardless of their site of origin, exhibit characteristic morphology that resembles pleuropulmonary blastoma [314]. The morphologic features include a subepithelial layer of malignant mesenchymal cells (cambium layer), areas of rhabdomyoblastic differentiation with positive staining for myogenin and myoD1, cellular/immature and occasionally malignant cartilage, bone/osteoid foci, and areas of anaplasia [315]. If a mesenchymal neoplasm is reported that has a combination of rhabdomyoblastic, cartilaginous, and neuroectodermal elements, a DICER1-associated neoplasm should be considered.
Kommoss et al. [316] reported the clinicopathological and molecular features of DICER1-mutant and DICER1-wild-type embryonal RMS in a series of genitourinary tumors. They suggested that DICER1-mutant ERMS might represent a distinct subtype in the future classification of RMS. Unsupervised hierarchical clustering of array-based wholegenome methylation data of a subset of DICER1-mutant sarcomas has revealed that they cluster together [317]. Further methylation studies are warranted to determine whether DICER1-mutant sarcomas constitute a distinct, identifiable subclass of sarcomas. Table 3 shows a summary of molecular genetic alterations and immunohistochemical markers in emerging entities.

Conclusions
Advances in molecular techniques have refined the classification of soft tissue tumors. This review summarizes newly recognized and emerging entities, focusing on molecular alterations and antibodies as surrogate markers for molecular genetic techniques. In addition, already well-defined entities with recently described molecular changes are discussed. The critical genetic events driving the biology of soft tissue tumors are still largely unknown. Further studies with careful genomic-morphologic correlation are required to understand soft tissue pathology comprehensively.