Printer Friendly

Soft Tissue Tumor Immunohistochemistry Update: Illustrative Examples of Diagnostic Pearls to Avoid Pitfalls.

Current 2013 World Health Organization (WHO) classification of tumors of soft tissue arranges these tumors into 12 groups according to their histiogenesis as follows: adipocytic, fibroblastic/myofibroblastic, fibrohistiocytic, smoothmuscle, pericytic (perivascular), skeletal-muscle, vascular, chondro-osseous, gastrointestinal stromal, nerve sheath, uncertain differentiation, and undifferentiated/unclassified. (1) Tumor behavior is classified as benign, intermediate (locally aggressive), intermediate (rarely metastasizing), and malignant. In our practice, a general approach to reaching a definitive diagnosis when involving soft tissue tumors is to first consider clinicoradiologic, histomorphologic, and cytomorphologic features of the tumor to generate a pertinent differential diagnosis that includes the potential line of histogenesis and whether the tumor is benign or malignant. Sometimes, the line of histologic differentiation is obvious such as smooth-muscle, skeletal-muscle, vascular, neural, and chondro-osseous lineages. However, when the line of differentiation is not obvious, the histomorphologic pattern encountered may help in determining differential diagnoses for further workup (Table 1). Ancillary testing is often required to confirm the tumor histogenesis when working up a soft tissue tumor. Immunohistochemistry (IHC) plays an important role in the diagnosis of soft tissue tumors. The ultimate goal for a pathologist is to render a specific diagnosis that provides diagnostic, prognostic, and therapeutic information to guide patient care.

This article aims to provide an overview focusing on the current concepts in the classification and diagnosis of soft tissue tumors, incorporating IHC. Although there are some recent reviews addressing this topic (Table 2), this article uses illustrative examples to discuss how to incorporate both traditional and new immunohistochemical markers in the diagnosis of soft tissue tumors. Abundant practical diagnostic pearls, summary tables, and figures are used to demonstrate how to avoid diagnostic pitfalls.

TUMOR WITH ADIPOCYTIC AND/OR SPINDLE CELL MORPHOLOGY

Illustrative Example 1

A 78-year-old man underwent a right-sided forehead mass excision. The initial diagnosis from an outside hospital was dermatofibrosarcoma protuberans (DFSP). The tumor was immunoreactive to cluster of differentiation (CD) 34 while negative for S100 protein, Melan-A, tyrosinase, MART-1 (melanocytic antigen recognized by cytotoxic T lymphocytes 1), human herpesvirus 8, cytokeratin, and smooth muscle actin (SMA). The tumor exhibited a high proliferation index with Ki-67 (methylation-inhibited binding protein 1 [MIB-1]) positivity in the nuclei of 30% of the tumor cells. Was this really a DFSP? The first impression of the tumor under low magnification was spindle cells infiltrating adipose tissue (Figure 1, A). The spindle tumor cells were [CD34.sup.+] (Figure 1, B). Closer look under higher magnification showed moderate to marked cytologic atypia and frequent mitotic activity (Figure 1, C). Further inquiry about clinical history revealed that the patient had a "lipomatous tumor" excised from this area before. Additional immunohistochemical studies showed diffuse MDM2 (mouse double minute 2 homolog) nuclear immunoreactivity in spindle cells (Figure 1, D). The tumor was also positive for amplification of MDM2 (12q15) by fluorescence in situ hybridization (FISH), not shown here. The diagnosis was then changed to dedifferentiated liposarcoma. The pertinent differential diagnoses and the judicial use of immunohistochemical studies will be discussed.

Dermatofibrosarcoma Protuberans.--Conventional DFSP is a low-grade and locally aggressive fibroblastic neoplasm that can be cured by excision with clear surgical margins. (2) It is characteristically superficially located and consists of spindle-shaped tumor cells infiltrating fat lobules with a collagenous stroma and immunoreactivity to CD34, shown in this case. However, the spindle cells in DFSP are monotonous and bland with a storiform pattern that is not identified in this case. Other variants of DFSP include pigmented (also known as Bednar tumor) DFSP, myxoid DFSP, DFSP with myoid differentiation, plaquelike DFSP, giant cell fibroblastoma (juvenile form of DFSP), and fibrosarcomatous DFSP. (3) In 10% to 15% of DFSPs, fibrosarcomatous transformation occurs whereby the tumor exhibits high-grade morphology and loss of CD34 expression, while maintaining the signature COLIAI-PDGFB (platelet-derived growth factor, [beta] polypeptide) fusion gene.

Fibrosarcomatous DFSP shows a similar local recurrence rate to ordinary DFSP but 13% of fibrosarcomatous DFSPs develop distant metastases. (1) Identification of COLIA1-GFB fusion gene is important for managing fibrosarcomatous DFSP because imatinib mesylate, a tyrosine kinase inhibitor, has shown significant activity against PDGFRB (platelet-derived growth factor receptor, [beta]) and benefits the patients with locally advanced and metastatic diseases in clinical trials. (4)

Spindle Cell Lipoma.--Spindle cell lipoma is a benign tumor composed of bland spindle cells admixed with mature adipose tissue in a background of thick and ropey collagen. (3) The spindle cells are positive for CD34 stain. The matrix can also be myxoid. The pleomorphic lipoma is a morphologic continuum of this tumor, exhibiting multinucleated and floretlike cells. Important differential diagnoses of spindle cell lipoma include atypical lipomatous tumor and dedifferentiated liposarcoma.

Atypical Lipomatous Tumor.--Atypical lipomatous tumor is preferred by WHO Classification of Tumours of Soft Tissue and Bone (1) (2013 edition) over the term well-differentiated liposarcoma if the tumor occurs in the extremities because this is a locally aggressive adipocytic neoplasm with no potential for metastasis. We all know that lipomatous tumors are immunoreactive to S100; however, the adipocytic nature of the tumor is usually obvious and does not warrant an S100 stain. The morphologic distinction between benign lipoma and atypical lipomatous tumor relies on the identification of the hallmark diagnostic cells that are the atypical hyperchromatic stromal cells and lipoblasts (Figure 2). The histologic types include adipocytic, sclerosing, spindle cell, and inflammatory variants. When in doubt of this diagnosis, nuclear immunoreactivity of MDM2 and cyclin-dependent kinase 4 (CDK4) are confirmatory, which correspond to amplification of these genes. (3)

MDM2 and CDK4 Immunohistochemical Stain.--The defining genetic feature of atypical lipomatous tumor is the presence of rings or giant markers of chromosome 12 that contain amplification of the 12q14-15 region. The MDM2 gene and its neighboring gene CDK4 are amplified, which can be detected by molecular methods such as reverse transcription-polymerase chain reaction (RT-PCR) and FISH. The resultant MDM2 and CDK4 protein overexpression can be detected by IHC. However, nuclear staining with MDM2 and CDK4 is not entirely specific for atypical lipomatous tumor (Table 3). For example, MDM2 or CDK4 can show positivity in intimal sarcoma, pleomorphic rhabdomyosarcoma, a subset of malignant peripheral nerve sheath tumor, and myxofibrosarcoma. (5-9) Meanwhile, these markers are useful to distinguish atypical lipomatous tumor from lipoma as well as dedifferentiated liposarcoma from undifferentiated sarcoma, especially when both markers show positivity. Please be aware that pleomorphic liposarcoma and myxoid liposarcoma are negative for MDM2 and CDK4. (10)

Dedifferentiated Liposarcoma.--Deep-seated, recurrent atypical lipomatous tumor can undergo dedifferentiation with transformation into nonadipocytic high-grade sarcoma. The current case is an example of a recurrent atypical lipomatous tumor with dedifferentiation. The most common location of dedifferentiated liposarcoma is within the retroperitoneum. Dedifferentiated liposarcoma does occur at rare sites, such as head and neck. (11) An institutional review of adult retroperitoneal sarcomas within the past 10 years shows that liposarcoma is the most common subtype (54.7%; 168 of 307 cases), followed by leiomyosarcoma (26.1%; 80 of 307 cases), which is in keeping with the literature review (45.1% and 21.3% respectively). (12) The incidence rate of dedifferentiated liposarcoma in the retroperitoneum is 15.6% (48 of 307 cases) at Moffitt Cancer Center and 20.9% in the literature. The concurrent atypical lipomatous tumor component may not be sampled by core needle biopsy. Therefore, when facing a high-grade and pleomorphic sarcoma biopsy from the retroperitoneum, judicious use of immunohistochemical stains for MDM2 and CDK4 is helpful in identifying dedifferentiated liposarcoma. We recently summarized a proposed algorithm for the pathology-focused management of retroperitoneal soft tissue sarcoma. (12)

Undifferentiated Sarcoma.--By definition, undifferentiated sarcoma shows no identifiable lineage differentiation. This is a heterogeneous group of tumors that exhibit pleomorphic, round cell, spindle cell, and epithelioid morphology. According to WHO 2013 classification of tumors of soft tissue, "undifferentiated sarcoma" with 12q14-15 amplification (MDM2/CDK4) is now classified as dedifferentiated liposarcoma. Why is it important to distinguish among undifferentiated sarcoma, dedifferentiated liposarcoma, and pleomorphic liposarcoma? The answer is that their associated 5-year survival rates are different: 35% to 60% for undifferentiated sarcoma; 65% for dedifferentiated liposarcoma; and 60% for pleomorphic sarcoma. (13-16)

CD34 Immunostain and Diagnostic Pitfall.--CD34 is a transmembrane glycoprotein expressed by hematopoietic stem cells and endothelial cells with a membranous pattern. It is also typically expressed by solitary fibrous tumor, gastrointestinal stromal tumor, DFSP, epithelioid sarcoma, spindle cell lipoma, synovial sarcoma, and vascular tumors. When the diagnosis is truly one of the above tumors, CD34 will show positivity; however, the converse is not true. For example, the current case is positive for CD34, but the history of "prior removed lipomatous tumor," the high-grade cytomorphology, and positivity for MDM2 confirmed the diagnosis of a dedifferentiated liposarcoma instead of a conventional DFSP or fibrosarcomatous DFSP.

Illustrative Example 2

A 49-year-old woman presented with a right-sided cheek mass. The clinician performed an incisional biopsy to rule out a salivary gland neoplasm. The initial diagnosis from an outside hospital was high-grade solitary fibrous tumor (SFT). The tumor was positive for vimentin and exhibited a high Ki-67 proliferation rate, while it was negative for cytokeratins (AE1/AE3 and CAM 5.2), epithelial membrane antigen (EMA), S100 protein, neuron-specific enolase, chromogranin, SMA, and muscle-specific actin. Immuno-staining for STAT6 (signal transducer and activator of transcription 6), CD34, CD99, or B-cell CLL/lymphoma 2 (Bcl-2) was not performed. Was this really a malignant SFT? The histology was that of a high-grade malignancy composed of spindle cells arranged in SFT-like patternless pattern with tumor necrosis and frequent mitotic activity (Figure 3, A and B). The SFT morphologic pattern is shared by synovial sarcoma. Further IHC and molecular studies confirmed the diagnosis of synovial sarcoma. The pertinent differential diagnoses and the judicial use of immunohistochemical studies will be discussed.

Vimentin and Cytokeratin Immunostains and Their Diagnostic Pitfall.--Vimentin is a type II intermediate filament protein encoded by the VIM gene. Vimentin is expressed in mesenchymal cells but is not specific for mesenchymal cells. It is also expressed in certain types of carcinomas (eg, renal cell carcinoma, spindle cell carcinoma), as well as lymphomas and melanomas. Vimentin positivity has a limited value in the diagnosis of soft tissue tumors; however, if the mesenchymal tissue is negative for vimentin, it may indicate that the tissue is suboptimal for IHC or not of a mesenchymal (soft tissue) differentiation.

Cytokeratins are proteins of keratin-containing intermediate filaments found in the intracytoplasmic cytoskeleton of epithelial tissue, therefore, makers for carcinomas. However, they are also frequently expressed in many sarcomas: synovial sarcoma, epithelioid sarcoma, epithelioid hemangioendothelioma, angiosarcoma, and desmoplastic small round cell tumor. Diffuse broad-spectrum keratin expression is seen in more than 90% of soft tissue myoepithelial tumors. Occasional aberrant expression of keratin is reported in melanomas and certain sarcomas, such as Ewing sarcoma and leiomyosarcoma. (17,18)

Solitary Fibrous Tumor and STAT6 Immunostain.--Solitary fibrous tumor can occur in extrapleural soft tissue. Subcutaneous tissue (40%) and deep tissue of extremities and head and neck area are common sites. It is a spindle cell tumor with fibrous stroma and branching thin-walled vessels. The malignant SFT exhibits hypercellularity, increased mitotic activity (>4/10 high-power fields), tumor necrosis, visible cytologic atypia, and infiltrative margins. Although SFT is immunoreactive to CD34 (90%-95%), EMA, SMA, CD99, and Bcl-2, it is not until recently that STAT6 has been identified as a sensitive and specific marker for diagnosing SFT. (19-21) Overexpression of nuclear STAT6 results from NAB2-STAT6 fusion identified in SFTs. The fusion partners are in close proximity on chromosome band 12q13, precluding identification by conventional FISH analysis. One should be cautious to call an "SFT-look-a-like" tumor an SFT without a positive STAT6 immunostain result. The current tumor was subsequently tested for STAT6 and was negative.

Malignant Peripheral Nerve Sheath Tumor.--Malignant peripheral nerve sheath tumor (MPNST) also shares the SFT morphologic pattern. It is often seen in the setting of neurofibromatosis type 1. It may exhibit an SFT-like appearance. Immunohistochemical staining of S100 protein, Sry-related HMG-BOX gene 10 (SOX-10), and p75 neurotrophin receptor (p75NTR) can be helpful to suggest the diagnosis of MPNST. SOX-10 is a member of the SOX family of transcription factors and is relatively specific for neuroectodermal neoplasms. It is expressed in benign nerve sheath tumors, clear cell sarcoma, and melanoma (including desmoplastic and spindle cell variants). It is more sensitive and specific for the diagnosis of melanocytic and schwannian tumors than S100 protein. It is a relatively more specific marker than S100 in diagnosing MPNST. SOX-10 reactivity can also be seen in astrocytomas, myoepithelial tumors, granular cell tumors, and a subset of breast carcinomas.

Differentiating benign and malignant peripheral nerve sheath neoplasms can be diagnostically challenging. Features favoring malignancy include increased size, rapid growth, infiltrative border, internal necrosis, increased vascularity, and frequent mitotic activity with atypical mitoses. In addition, perivascular hypercellularity, tumor herniation into vascular lumens, necrosis, and expression of p75NTR is more frequently associated with MPNST than cellular schwannoma in a large study. (22) Recently, loss of anti-histone H3 acetyl K27 (H3K27) trimethylation has been reported in 50% of MPNSTs, predominantly in high-grade MPNST. (23)

Synovial Sarcoma and TLE1 Immunostain.--Synovial sarcoma may exhibit an SFT-like appearance with hemangiopericytoma-like vessels and shares the positive immunostain pattern of EMA, CD99, and Bcl-2. However, synovial sarcoma is typically negative for CD34, which is helpful to distinguish it from SFT. (3) Although cytokeratins generally show positivity in synovial sarcoma, the monophasic spindle cell variant of synovial sarcoma is less frequently positive (50%-80%) than its biphasic counterpart. In this case, perhaps the negative cytokeratin and EMA staining patterns misdirected the workup and precluded synovial sarcoma as a critical differential diagnosis. Transducin-like enhancer of split 1 (TLE1) is a new marker for synovial sarcoma. It is a transcriptional repressor essential to hematopoiesis, neuronal differentiation, and terminal epithelial differentiation. It also plays an important role in the synovial sarcoma-associated Wnt/[beta]-catenin signaling pathway. (24) TLE1 positivity is seen in 85% to 97% of synovial sarcomas; however, it has also been reported in endometrial stromal sarcoma, SFT, malignant peripheral nerve sheath tumor, Ewing sarcoma, schwannoma, and epithelioid sarcoma. (25,26) The diagnosis of synovial sarcoma should be further verified by molecular testing. In this case, the tumor is TLE1 positive by IHC (Figure 3, C) and positive for SYT rearrangement by FISH (not shown here), confirming the diagnosis of synovial sarcoma.

Given both are malignant, what is the clinical significance in distinguishing malignant SFT from synovial sarcoma? Synovial sarcoma is one of those sarcomas that are chemosensitive, while conventional chemotherapy is less effective for malignant SFT. In general, precise subclassification would greatly benefit patients with chemosensitive sarcomas, such as synovial sarcoma, Ewing sarcoma, osteosarcoma, rhabdomyosarcoma, desmoplastic small round cell tumor, angiosarcoma, myxoid/round cell liposarcoma, and uterine leiomyosarcoma.

TUMORS WITH A PROMINENT EPITHELIOID MORPHOLOGY

Illustrative Example 3

A 17-year-old boy presented with a 2.5-month history of a gradually enlarging mass at the base of the right side of penis. He underwent an excisional biopsy under the clinical impression of a hematoma or aneurysm. During the operation, the mass was apparently adherent to the corporal tissue. Microscopic examination of the lesion demonstrated an epithelioid neoplasm with tumor necrosis and brisk mitotic activity. The lesional cells were focally positive for pancytokeratin but negative for cytokeratin 5/6 and p63. The tumor was diffusely immunoreactive for vimentin and focally positive for CD31 and erythroblast transformationspecific transcription factor (ERG). Loss of integrase interactor 1 (INI1) expression was seen in most of the tumor cells (Figure 4, A through D). A diagnosis of epithelioid sarcoma of the "proximal type" was rendered.

Epithelioid Sarcoma.--Epithelioid sarcomas are tumors of unknown histogenesis, accounting for less than 1% of all soft tissue sarcomas. They are usually slow growing, with peak incidence in young adult men, and occur predominantly in the extremities. (27) Histologically, the tumor frequently demonstrates a nodular growth pattern, with epithelioid cells surrounding areas of central necrosis/ hyalinization and peripheral spindling, thus reminiscent of granulomas. (28) In contrast to the conventional, "distal-type" epithelioid sarcoma, the proximal variant occurs more commonly in the pelvic and perineal regions, and is characterized by a predominantly large-cell, epithelioid histomorphology, marked cytologic atypia, frequent rhabdoid features, and lack of a granuloma-like pattern in most cases. (29,30) The "proximal type" demonstrates a more aggressive clinical behavior. (30)

INI1 (also known as hSNF5 and SMARCB1) is a member of the SWI/SNF chromatin remodeling complex located on chromosome band 22q11.2. Loss of INI1 expression is observed in more than 90% of both conventional and proximal-type epithelioid sarcomas but not seen in most of its mimickers, thus it is characteristic of these tumors. (31) Notably, other INI1-deficient tumors reportedly include renal medullary carcinomas and a subset of epithelioid malignant peripheral nerve sheath tumors, myoepithelial carcinomas, and extraskeletal myxoid chondrosarcomas. (32)

In addition to cytokeratins, expression of vascular markers, including CD31, CD34, ERG, and Friend leukemia integration 1 transcription factor (FLI1), is a frequent finding in epithelioid sarcomas, with the latter two being reportedly observed in 60% and 70% of cases, respectively. (33-36) It is extremely important to be aware that coexpression of cytokeratin and vascular markers is common in both epithelioid vascular tumors and epithelioid sarcoma when classifying a soft tissue tumor with an epithelioid pattern.

Epithelioid Vascular Tumors.--Epithelioid hemangiomas most frequently occur in the craniofacial regions, especially the forehead, preauricular area and scalp, followed by distal extremities. (37) The penis is an uncommon site of involvement but lesions in this location may be confused with epithelioid hemangioendothelioma or epithelioid angiosarcoma. (38) Histologically, these lesions typically demonstrate well-formed vessels lined by plump, epithelioid cells with copious amphophilic or eosinophilic cytoplasm, often in a nodular or lobular configuration (Figure 5, A through D). These tumors are also referred to as histiocytoid hemangioma given their prominent histiocytoid cytomorphology. Numerous eosinophils and lymphocytes are often present, hence it is also known as angiolymphoid hyperplasia with eosinophilia. The epithelioid endothelial cells may be immunoreactive for keratin, typically in a focal pattern, in addition to vascular markers CD31, ERG, and, to a lesser extent, CD34. (37)

Epithelioid hemangioendothelioma (EHE) is an intermediate-grade malignant angiocentric vascular neoplasm. While it arises more commonly in the superficial or deep soft tissue of the extremities, the tumor can be seen in virtually any body site. (39) Microscopically, EHE is distinctively composed of cords or chains of epithelioid endothelial cells in the background of a myxoid or hyalinized stroma (Figure 6, A and B). The cells typically have abundant eosinophilic cytoplasm that often contains vacuoles (so-called blister cells). The lesional cells are of low nuclear grade but may rarely demonstrate high-grade features (thus named malignant epithelioid hemangioendothelioma by some authorities). Epithelioid hemangioendothelioma expresses typical vascular markers including CD31, CD34, FLI1, and ERG. Epithelial antigens (CK7, CK8, CK18, and EMA) are also expressed in some tumors. (39) A small subset of EHEs are positive for TFE3. Importantly, EHE has a t(1;3)(p36;q23-25) translocation that leads to WWTR1-CAMTA1 fusion in virtually all cases. (40) Nuclear expression of CAMTA1 is extremely helpful in confirming the diagnosis of EHE. (41)

While well-differentiated angiosarcomas typically show vasoformative characteristics, it is not uncommon that these tumors present with a predominantly (or exclusively) epithelioid appearance (Figure 6, C through F). This unique morphologic variant most often arises in the deep soft tissues of the extremities, but a variety of other primary sites have been reported, including the thyroid gland, skin, adrenal glands, and bone. (42) Epithelioid angiosarcoma is highly aggressive, often with early nodal and solid organ metastasis. Histologically, focal areas of irregularly anastomosing vascular formation are typically discernible. Purely epithelioid tumors are uncommon although foci with completely epithelioid appearance may be present. This may become extremely challenging in biopsy specimens with scant pathologic material available. Expression of cytokeratin has been reportedly seen in 35% of cases. (43) The most frequently encountered differential diagnosis includes metastatic carcinoma and, less frequently, epithelioid sarcoma, given the sometime indistinguishable cytomorphology and expression of cytokeratin. A useful histologic hint is that the vasoformative nature (ie, extravasation of blood) is almost always identifiable in angiosarcomas but not in other epithelioid tumors. A panel of IHC stains to include at least vascular markers and INI1 is necessary when working up a malignant epithelioid soft tissue tumor.

It is important to note that while transcription factors FLI1 and ERG have been increasingly used in practice as endothelial markers given their nuclear expression (thus a cleaner staining background), these markers are less specific than CD31. FLI1 is expressed in Ewing sarcoma, subsets of wide range of mesenchymal tumors, subsets of high-grade lymphomas including lymphoblastic lymphomas and diffuse large B-cell lymphomas, and even subsets of carcinomas and melanomas, thus it has limited utility by itself owing to its low specificity. Similarly, ERG is expressed in a subset of Ewing sarcomas (5%-10%), prostatic adenocarcinoma, and a small subset of acute myeloid leukemia. Its specificity depends upon the antibody clone. (26) Thus, these markers should be used and interpreted in the appropriate clinicopathologic settings.

Sclerosing Epithelioid Fibrosarcoma.--Sclerosing epithelioid fibrosarcoma (SEF) is a distinctive fibroblastic neoplasm characterized by epithelioid tumor cells arranged in nests, cords, or sheets embedded within a sclerotic collagenized matrix. This entity most commonly arises in the deep soft tissue of extremities, followed by shoulder, trunk, and head and neck regions, but may rarely occur in the visceral organs or bone. (44,45) The lesional cells demonstrate relatively small, uniform, round/ovoid nuclei and eosinophilic or clear cytoplasm, and lack significant cytologic atypia, thus sometimes closely resembling metastatic lobular carcinoma of the breast (Figure 7, A). The most distinctive immunophenotype of SEF is the expression of mucin 4 (MUC4) (up to 70% of cases), similar to that in low-grade fibromyxoid sarcoma, while staining for cytokeratins is typically negative. Moreover, the t(7;16)(q33;p11) translocation resulting in a FUS-CREB3L2 fusion gene characteristic of low-grade fibromyxoid sarcoma has been detected in some SEF cases. (44) This observation has led some authorities to propose a potential relationship between these 2 tumors.

Other Selected Epithelioid Tumors.--In addition to the aforementioned entities, several benign and malignant soft tissue tumors may demonstrate an epithelioid morphology.

Granular cell tumor commonly affects head and neck regions but can occur in any anatomic site. Granular cell tumor is thought to have neuroectodermal differentiation that is likely schwannian in type, thus is generally positive for S100 protein and SOX-10 (Figure 7, B). (46) The tumor cells are also variably reactive for CD68, neuron-specific enolase, microphthalmia-associated transcription factor (MITF), and transcription factor E3 (TFE3), while negative for MART-1 and human melanoma black 45 (HMB-45).

Glomus tumors are most frequently seen in the distal extremities and consist of cells resembling modified smooth muscle cells of the normal glomus body, thus typically expressing SMA and h-caldesmon. Abundant pericellular production of type IV collagen is another classic feature (Figure 7, C).

Neoplasms with perivascular epithelioid differentiation (PEComas) include angiomyolipoma, clear cell "sugar" tumor of the lung, lymphangioleiomyomatosis, and a group of other tumors with similar histomorphology and immunophenotype. These tumors show a variety of anatomic distributions but most often arise in the retroperitoneal and abdominopelvic regions. They are usually composed of uniform epithelioid cells with round nuclei and abundant granular eosinophilic or clear cytoplasm. The distinctive immunophenotype is the expression of melanocytic markers such as HMB-45 (most sensitive), MART-1 (Melan-A), and MITF, and muscle markers such as SMA and calponin. TFE3 reportedly shows positivity in about 10% of cases. (47)

Alveolar soft part sarcoma (ASPS) most commonly occurs in the deep soft tissue of the thigh or buttock in adults and the head and neck region in children. It is characteristically composed of large, polygonal, uniform epithelioid cells with abundant eosinophilic, granular cytoplasm and is arranged in a distinctive organoid or nesting pattern. The distinguishing phenotype of ASPS is its strong nuclear staining with an antibody raised against the carboxy terminal portion of TFE3 retained in the fusion protein resulting from the ASPSCR1-TFE3 fusion gene. Other nonspecific immunoexpression includes desmin and S100 protein but is usually focal.

Succinate dehydrogenase (SDH)-deficient gastrointestinal stromal tumors (GISTs) are a subgroup of GISTs that occur exclusively in the stomach (so far) with loss of the SDH complex function as its oncogenic mechanism, instead of KIT- or PDGFRA (platelet-derived growth factor A)activating mutations, as seen in most GISTs. They account for most pediatric GISTs and GISTs in association with 2 previously described syndromes: Carney-Stratakis syndrome and Carney triad. (48) Succinate dehydrogenase-deficient GISTs are histologically distinctive with a multinodular architecture and an epithelioid cytomorphology. Loss of SDH subunit B (SDHB) expression by IHC effectively identifies SDH-deficient GISTs, some of which have lossof-function germline mutations in one of the SDH subunits (A, B, C, or D). Like conventional GISTs, they are usually immunoreactive for CD117 and discovered with GIST-1 (DOG1). However, conventional GIST risk stratification based on mitotic activity and tumor size fails to predict progression of this special group of epithelioid GISTs. (49) Therefore, immunohistochemical analysis for SDHB is highly recommended for all epithelioid GISTs to identify this clinically and biologically distinctive group of GISTs.

Malignant epithelioid soft tissue tumors include, but are not limited to, epithelioid MPNST, epithelioid leiomyosarcoma, epithelioid rhabdomyosarcoma, and clear cell sarcoma. Epithelioid MPNST is mostly not associated with NF1. This rare variant (<5%) is unique in that it shows strong and diffuse expression of S100 protein, can be positive for epithelial markers (cytokeratin/EMA), but demonstrates INI1 loss (67%) and lacks staining for melanoma markers. In contrast, conventional (spindle cell) MPNST is positive for S100 protein in less than 50% of cases. (50) SOX-10 reportedly shows positivity in two-thirds of epithelioid MPNSTs. (51) It is noteworthy that glandular differentiation seen in conventional MPNST, particularly in patients with NF1, should not be regarded as epithelioid MPNST. (52) Most clear cell sarcomas display predominant epithelioid morphology, but spindle cell areas are commonly present. Epithelioid leiomyosarcoma mostly occurs in the uterus but can be rarely seen in the external deep soft tissue. (53) Epithelioid rhabdomyosarcoma is a morphologic variant recently described in adults and children that may closely mimic carcinoma or melanoma. Histologically, epithelioid rhabdomyosarcoma displays sheets of large cells with or without rhabdomyoblastic differentiation. The cells invariably express skeletal muscle markers including desmin and myogenin, may show positivity for keratin and EMA, and lack PAX3/7-FOXO1 transcripts characteristic of alveolar rhabdomyosarcoma. (54,55)

Soft tissue tumors showing purely myoepithelial differentiation (myoepithelioma/myoepithelial carcinoma) and those with a mixed epithelial and myoepithelial component (mixed tumor) arise from eccrine sweat glands of the skin, analogous to their salivary gland counterparts. The former may be part of a continuum with mixed tumors (ductal structures but few myoepithelial cells). The cells constituting myoepithelial tumors demonstrate a spectrum of cytomorphology including epithelioid, histiocytoid, plasmacytoid, or spindled, with little matrix or in the background of a chondromyxoid or collagenous/hyalinized stroma. The cells with myoepithelial differentiation may express epithelial markers (cytokeratin and/or EMA), a variety of myoepithelial markers such as S100 protein and glial fibrillary acidic protein (50%), and muscle markers including calponin, SMA, and desmin. (56) SOX10, a panschwannian and melanocytic marker, may also show positivity in myoepithelial cell tumors (Figure 8, A through C). (57) Mixed tumor of skin is morphologically identical to pleomorphic adenoma of the salivary gland, exhibiting secondary structures such as glands/ducts, cysts, keratinous cysts, and foci of squamous differentiation, with a mucoid stroma typically showing cartilaginous metaplasia (hence also known as chondroid syringoma). The inner luminal epithelial cells lack expression of the aforementioned myoepithelial markers.

In summary, epithelioid morphology is a frequent finding in soft tissue tumors and can be seen in mesenchymal neoplasms of virtually all lineages. One should always bear this in mind when working up an unknown soft tissue tumor. Lastly, it is important to note that metastatic carcinoma is far more common than epithelioid mesenchymal tumors, especially in the elderly patients. The histologic features and key immunophenotypes of selective epithelioid soft tissue tumors are summarized in Table 4.

TUMORS WITH MYXOID STROMA

Illustrative Example 4

A 52-year-old woman presented with left lower quadrant abdominal pain. She was found to have cholelithiasis, hiatal hernia, and gastroesophageal reflux. A computed tomography scan was recommended as part of her evaluation for possible laparoscopic cholecystectomy. In this study, a 6-cm mass in the proximal right thigh was discovered. The patient underwent a needle biopsy followed by surgical excision of the right-sided thigh mass. The histologic sections showed a low-grade spindle cell lesion with alternating fibrous and myxoid areas. The lesional cells were diffusely positive for MUC4, thus resulting in a diagnosis of low-grade fibromyxoid sarcoma (Figure 9, A through C).

Myxoid tumors encompass a group of soft tissue neoplasms with a "myxoid" stroma composed of clear, mucuslike substance. The diagnosis of a myxoid tumor is often challenging, as many soft tissue tumors show myxoid changes, and some myxoid tumors are extremely uncommon. Moreover, there is a significant overlap across different entities, especially among the spindle cell tumors with myxoid change for which a recognizable histologic pattern is often lacking. Correlation with clinical and radiologic information and awareness of the entities are crucial in the differential diagnosis. Strategies in the differential diagnosis of myxoid tumors are summarized in Table 5.

Low-Grade Fibromyxoid Sarcoma and MUC4.--Also known as Evans tumor, low-grade fibromyxoid sarcoma (LGFMS) consists of bland fusiform or spindled cells, often in a whirling pattern. The tumor typically demonstrates alternating fibrous and myxoid areas. Hyalinizing spindle cell tumor with giant rosettes is a unique morphologic pattern seen in some LGFMSs that may simulate palisaded granulomas. MUC4 is a highly sensitive (100%) and quite specific marker for LGFMS. (58) A t(7;16)(q32-34;p11) translocation resulting in FUS-CREB3L2 fusion has been found in more than 90% of the cases, with an alternative translocation t(11;16)(p11;p11) FUS-CREB3L1 fusion found in rare tumors. (59) Thus, LGFMS is thought to be closely related to SEF given the same translocations and immunophenotype.

Myxoma.--Myxomas more commonly occur in the extremities (intramuscular, juxtaarticular). They are mostly sporadic but may be rarely associated with other diseases (ie, Mazabraud syndrome, Carney complex). The diagnosis of myxomas is mostly straightforward given their imaging characteristics and histologic appearance of paucicellularity and abundant granular myxoid stroma (Figure 10, A). Cellular myxomas contain similar bland spindle cells and may be difficult to distinguish from other low-grade myxoid lesions, such as low-grade fibromyxoid sarcoma and low-grade myxofibrosarcoma, especially in a small biopsy specimen (Figure 10, B).

Soft Tissue Perineurioma.--Soft tissue perineurioma is a rare benign peripheral nerve sheath tumor showing perineurial cell differentiation. It occurs predominantly in middle-aged adults and arises mainly in subcutaneous tissue in the limbs. Histologically, it is composed of bland spindled cells, with delicate, elongated bipolar cytoplasmic processes arranged in a whorled or storiform architectural pattern. Prominent myxoid stroma is common. Like normal perineurial cells, tumor cells in perineuriomas usually express EMA and claudin-1, the commonly used perineurial markers. However, these markers are unfortunately nonspecific and can be seen in up to 50% of LGFMSs, its major malignant mimic. (60,61)

Nodular Fasciitis.--Nodular fasciitis is a rapidly growing lesion that is almost always smaller than 5 cm. It is composed of variably cellular fibroblasts and myofibroblasts (thus typically strongly and diffusely positive for SMA and muscle-specific actin) in a myxoid stroma, which may be variably collagenized in longstanding lesions (Figure 10, C). The proliferating cells commonly display a tissue culturelike growth pattern, with frequent mitotic figures but no atypical forms. Extravasated red blood cells, lymphocytes, and giant cells are frequently discernible. Nodular fasciitis has been historically regarded as a reactive process, given its self-limiting nature, but is now thought to be neoplastic owing to the identification of recurrent translocation t(17;22)(p13;q13) that results in MYH9-USP6 fusion. (62)

Schwannoma.--Schwannoma is a frequently encountered tumor with a myxoid matrix. Recognition of its biphasic growth pattern characterized by hypercellular Antoni A and myxoid, hypocellular Antoni B areas, in combination with its strong and diffuse S100 immunoreactivity, is typically diagnostic (Figure 10, D).

Myxofibrosarcoma.--Myxofibrosarcoma demonstrates a broad spectrum of cellularity and nuclear pleomorphism, but invariably possesses a curvilinear vascular pattern. The cellularity dictates tumor grade, although the latter does not predict the clinical behavior. (63) The low-grade lesions show prominent elongated, curvilinear, thin-walled blood vessels with perivascular condensation of tumor cells (Figure 10, E), whereas the high-grade neoplasms (previously known as myxoid malignant fibrous histiocytoma) (Figure 10, F) comprise solid sheets of pleomorphic cells but also focally show features of low-grade lesions. There are currently no unique immunophenotypes or molecular genetic abnormalities.

Extraskeletal Myxoid Chondrosarcoma.--Extraskeletal myxoid chondrosarcoma (EMC) is characterized by the abundant chondromyxoid matrix and small, uniform cells with round to oval nuclei. The tumor typically has a multilobular growth pattern, in which the neoplastic cells are interconnected with each other to form cords, chains, or clusters (Figure 11, A and B). Extraskeletal myxoid chondrosarcoma is distinctively hypovascular and lacks well-developed hyaline cartilage. There is no specific IHC marker for EMC. These tumors may express S100 protein (20%), CD117 (30%), and rarely, cytokeratins; and those with rhabdoid features may show loss of INI1. The t(9;22)(q22;q12) translocation resulting in EWSR1-NR4A3 fusion has been found as the sole anomaly, while a number of other rare fusion partners for NR4A3 have been recently identified, including t(9;17)(q22;q11) and t(9;15)(q22;q21). (64)

Chordoma.--Chordoma is a malignant midline bone tumor arising from fetal notochord. It typically affects the base of skull, the vertebral bodies, and the sacrococcygeal bone, but may be rarely seen in the extraaxial skeleton, such as intervertebral discs and presacral soft tissue. The morphologic hallmark is the presence of cords and lobules of "physaliferous cells" separated by fibrous septa in abundant myxoid matrix. The stroma may less commonly have a chondromyxoid appearance, thus resembling a hyaline cartilage tumor (chondroid chordoma). The tumor cells are typically immunoreactive for cytokeratins, EMA, S100 protein, and Brachyury, with the latter being highly specific (Figure 12, A through D). (65) It is noteworthy that the cells of intraosseous benign notochordal cell tumor have the same immunophenotype as chordoma, but the former typically lacks a lobular architecture, fibrous bands, and myxoid matrix. Thus, correlation with imaging studies is crucial when dealing with a limited biopsy specimen.

Other Myxoid Tumors.--Ossifying fibromyxoid tumor is typically a well-circumscribed mass that is characteristically composed of incomplete peripheral metaplastic bone tissue. The tumor contains cords of bland, round or short spindled cells in a stroma ranging from predominantly myxoid to hyalinized. The lesional cells are typically positive for S100 protein and, to a lesser degree, desmin.

Myxoinflammatory fibroblastic sarcoma (MIFS) typically affects lower extremities. It is histologically characterized by epithelioid fibroblasts with macronucleoli mimicking virocytes or Reed-Stenberg cells and a prominent mixed inflammatory infiltrate in a variably myxoid stroma. The lesional cells may be immunoreactive for SMA and CD34. Most MIFSs carry t(1;10)(p22;q24), which results in TGFBR3-MGEA5 fusion. (66)

Aggressive angiomyxoma mostly affects women and arises in the perineal and pelvic regions. It is typically circumscribed but demonstrates peripheral infiltrative margins with extension into adjacent structures. The tumor is hypocellular and composed of monotonous small spindled and stellate fibroblastic cells in the background of myxoid stroma and prominent, dilated, thick-walled vessels. The cells express CD34 but immunohistochemical studies are usually not needed.

Recently, HMGA2, a sensitive but nonspecific marker for aggressive angiomyxoma, has been shown to be useful in evaluating margins and in re-excision specimens when the foci of aggressive angiomyxoma are morphologically subtle. (67)

ROUND CELL TUMORS

Illustrative Example 5

A 10-year-old girl presented with a few months' history of increasing pain and swelling in the left shoulder region. A computed tomography scan showed a large intracapsular, heterogeneous mass with no involvement of bone. A biopsy revealed a small blue round cell tumor that was immunoreactive for CD99 and FLI1. FISH analysis demonstrated EWSR1 gene rearrangement, thus confirming the diagnosis of Ewing sarcoma.

Round cell tumors of soft tissue constitute a divergent group of neoplasms, largely including Ewing sarcoma, rhabdomyosarcoma, desmoplastic small round cell tumor, neuroblastoma, and recently characterized CIC (capicua transcriptional suppressor)-rearranged sarcoma and BCOR (Bcl-6 corepressor)-rearranged sarcoma. (68-70) These tumors morphologically look alike and may share some immunophenotypes but many harbor specific molecular genetic abnormalities. Moreover, hematologic malignancies and metastatic small cell carcinoma should always be within the differential diagnosis during the workup of round cell tumors in the soft tissue.

Ewing Sarcoma.--Ewing sarcoma and primitive neuroectodermal tumor (PNET) were historically thought to be different entities, with the latter demonstrating neuroectodermal differentiation. It is now generally accepted that Ewing sarcoma of bone, extraosseous Ewing sarcoma, PNET, and Askin tumor (PNET of the thoracopulmonary region) are histologic variants of the same tumor spectrum. As many other round cell tumors, Ewing sarcoma typically appears as solid sheets of uniform, small blue round cells with minimal cytoplasm and little extracellular matrix. Diffuse membranous expression of CD99 is characteristic for Ewing sarcoma but not specific. Nuclear FLI1 expression is seen in most Ewing sarcoma cases with the t(11;22)(q24; q12) translocation, whereas ERG immunoreactivity is seen in a small subset of cases harboring the t(21;22)(q22; q12) translocation (Figure 13, A and B). In addition, ERG is expressed in both normal and neoplastic endothelial cells (see previous discussion). It also shows positivity in acute myeloid leukemia and a subset of prostate carcinomas. Focal expression of cytokeratin can also be seen. (71) As previously mentioned, FLI1 is not specific for Ewing sarcoma and is also expressed in most lymphoblastic lymphomas (also [CD99.sup.+]), as well as anaplastic large cell lymphoma and angioimmunoblastic T-cell lymphoma, in addition to its utility as an endothelial marker. The protein is also expressed in a small subset of melanomas, Merkel cell carcinomas, synovial sarcomas, and carcinomas of lung and breast. (72) A recent study (73) has demonstrated that NKX2.2, a homeodomain-containing transcription factor that plays a critical role in neuroendocrine/glial differentiation, is a target of EWSR1-FLI1, a valuable marker for Ewing sarcoma, with a sensitivity of 93% and a specificity of 89%. Moreover, protein kinase C-[beta] (PRKCB) activation is directly regulated by the chimeric oncogene EWSR1-FLI1. PRKCB expression has also been shown to be a sensitive and specific marker for EWSR1 rearrangements and a potential therapeutic target, thus warranting further investigation. (74) While most Ewing sarcomas harbor EWSR1-FLI1 (85%) or EWSR1-ERG (~10%) fusion gene, there is a growing list of additional rare transcripts identified. (71) FISH analysis using break-apart probe is highly sensitive (>90%) in detecting EWSR1 rearrangements but does not identify its translocation partner, whereas RT-PCR analysis is a specific test in identifying the EWSR1-FLI1 fusion gene but has a suboptimal sensitivity (54%) in formalin-fixed paraffin-embedded tissue. (75) The latter also requires abundant lesional tissue, good quality of RNA, and a longer turnaround time.

Rhabdomyosarcoma.--Rhabdomyosarcoma constitutes the single largest category of soft tissue sarcomas in children and young adults. The histologic subtypes with prominent round cell morphology include embryonal and alveolar forms, whereas other rare variants demonstrate either a spindle cell or pleomorphic cytomorphology (spindle cell/ sclerosing rhabdomyosarcoma and pleomorphic rhabdomyosarcoma, respectively).

Embryonal rhabdomyosarcoma is the most common subtype, typically affecting children younger than 10 years and occasionally occurring in adolescents. Head and neck region and genitourinary system are the common sites of involvement. The tumor contains primitive mesenchymal cells admixed with a variable content of rhabdomyoblasts, which demonstrate elongation, more cytoplasmic eosinophilia, and sometimes cross-striation (Figure 13, C). A tumor may be composed exclusively of solid sheets of round cells, thus inviting confusion with alveolar rhabdomyosarcoma. There are no unique molecular genetic abnormalities identified for this variant.

Alveolar rhabdomyosarcoma occurs more commonly in adolescents and young adults and more often affects extremities. The tumor is typically densely cellular and consisting of a monotonous population of primitive round, blue cells (Figure 13, D). Rhabdomyoblastic differentiation may be seen but often to a smaller extent. A t(2;13)(q35;q14) or t(1;13)(p36;q14) translocation resulting in PAX3-FOXO1 or PAX7-FOXO1 fusion genes occurs in most cases. This subtype is clinically more aggressive than the embryonal variant, thus is important to identify.

Desmin is a muscle-specific protein and a key subunit of the intermediate filament in cardiac, skeletal, and smooth muscles. It shows reasonable sensitivity but not specificity for skeletal muscle tumors. Myogenin and myoD1 are transcription factors involved in myogenesis, thus are highly specific for rhabdomyosarcoma (Figure 13, E). It is noteworthy that nonspecific cytoplasmic myoD1 staining is not uncommon and may be misinterpreted as positive. Cytokeratin, neuroendocrine markers, CD20, and S100 protein expression can be occasionally seen, thus it may cause diagnostic confusion.

Desmoplastic Small Round Cell Tumor.--Desmoplastic small round cell tumor (DSRCT) primarily occurs in children and young adults, with a striking predilection for boys. It usually arises in abdomen, retroperitoneum, or pelvis, with widespread serosal implants. The tumor is so named because of prominent stromal desmoplasia (Figure 13, F). Tumor necrosis, frequent mitoses, and cystic degeneration are common. Glandular and pseudorosette formations may be seen. Multiphenotypic differentiation is a distinctive feature of DSRCT, thus epithelial, muscular, and neural markers may have variable immunoreactivity. Nuclear expression of WT1, the hallmark immunophenotype of DSRCT, is characteristically seen when using antibodies raised against the carboxyterminus, but not the amino-terminus, of WT1. (76,77) Of note, dotlike perinuclear reactivity of desmin and coexpression of cytokeratin can be seen in both DSRCT and Wilms tumor. Thus, detection of an EWSR1-WT1 rearrangement resulting from t(11;22)(p13;q12) translocation and selective WT1 carboxy-terminus immunoreactivity (characteristic of DSRCT), but not dual immunoreactivity for the WT1 amino-terminus and carboxy-terminus (characteristic of Wilms tumor), are the most discriminating diagnostic tools for the 2 tumors with overlapping histomorphology. (78)

New Emerging Ewing-Like Sarcomas.--A small subset of round cell sarcomas clinically and histologically mimic Ewing sarcoma but fail to demonstrate any of the reported cytogenetic abnormalities described above. These tumors have also been historically labeled as Ewing-like sarcomas. In 2006, two cases of Ewing-like sarcoma" were found to harbor a recurrent t(4;19)(q35;q13) translocation, which resulted in fusion between CIC, a human homolog of Drosophila capicua, which encodes a high-mobility group box transcription factor, and DUX4, a double homeodomain gene. (79) To date, CIC-DUX4 fusion is the most frequent genetic alteration in EWSR1/FUS-negative undifferentiated small round cell tumors, while a number of other fusion partners for CIC have been recently identified. (80) CIC-rearranged sarcomas primarily occur in soft tissue but may rarely affect bone. These tumors may have variable CD99 immunoreactivity, ranging from negative to focal and/or weak, and to diffuse and/or strong.

More recently, a new subtype of Ewing-like sarcomas has been defined by the fusion of the BCOR (BCL6 corepressor) and CCNB3 genes, which are nonadjacent genes on the X chromosome. (70) Additional fusion partners for BCOR have also been found. (80) The BCOR-rearranged sarcomas more frequently arise in bone than soft tissue, and demonstrate variable CD99 expression as other Ewing-like sarcomas.

Given the overlapping clinical, histologic, and immunophenotypic features of the abovementioned Ewing sarcoma family tumors, CIC- and BCOR-rearranged sarcomas, molecular cytogenetic studies are required to achieve a correct diagnosis, thus allowing prospective therapeutic management in the pursuit of precision medicine.

SUMMARY

Soft tissue tumors represent a heterogeneous group of neoplasms exhibiting a spectrum of histomorphologies, some with overlapping features, and numerous molecular alterations contributing to their diversity. The classification and diagnosis of soft tissue tumors have improved with recent molecular techniques and IHC. It is important to understand not only the diagnostic utility of these recent technologies but also their potential limits and pitfalls. Clinical and radiologic correlation is still a must to render accurate diagnostic, prognostic, and therapeutic information to guide patient care.

Please Note: Illustration(s) are not available due to copyright restrictions.

References

(1.) Fletcher CDM, Bridge JA, Hogendoorn PCW, Mertens F, eds. WHO Classification of Tumours of Soft Tissue and Bone. 4th ed. Lyon, France: IARC Press; 2013. World Health Organization Classification of Tumours; vol 5.

(2.) Farma JM, Ammori JB, Zager JS, et al. Dermatofibrosarcoma protuberans: how wide should we resect? Ann Surg Oncol. 2010;17(8):2112-2118.

(3.) Dodd L, Bui MM. Atlas of Soft Tissue and Bone Pathology: With Histologic, Cytologic, and Radiologic Correlations. New York: Demos Medical; 2015.

(4.) Labropoulos SV, Razis ED. Imatinib in the treatment of dermatofibrosarcoma protuberans. Biologics. 2007;1(4):347-353.

(5.) Stock N, Chibon F, Binh MB, et al. Adult-type rhabdomyosarcoma: analysis of 57 cases with clinicopathologic description, identification of 3 morphologic patterns and prognosis. Am J Surg Pathol. 2009;33(12):1850-1859.

(6.) Bode-Lesniewska B, Zhao J, Speel EJ, et al. Gains of 12q13-14 and overexpression of mdm2 are frequent findings in intimal sarcomas of the pulmonary artery. Virchows Arch. 2001;438(1):57-65.

(7.) Zhang H, Macdonald WD, Erickson-Johnson M, Wang X, Jenkins RB, Oliveira AM. Cytogenetic and molecular cytogenetic findings of intimal sarcoma. Cancer Genet Cytogenet. 2007;179(2):146-149.

(8.) Zhao J, Roth J, Bode-Lesniewska B, Pfaltz M, Heitz PU, Komminoth P. Combined comparative genomic hybridization and genomic microarray for detection of gene amplifications in pulmonary artery intimal sarcomas and adrenocortical tumors. Genes Chromosomes Cancer. 2002;34(1):48-57.

(9.) Kimura H, Dobashi Y, Nojima T, et al. Utility of fluorescence in situ hybridization to detect MDM2 amplification in liposarcomas and their morphological mimics. Int J Clin Exp Pathol. 2013;6(7):1306-1316.

(10.) Binh MB, Sastre-Garau X, Guillou L, et al. MDM2 and CDK4 immunostainings are useful adjuncts in diagnosing well-differentiated and dedifferentiated liposarcoma subtypes: a comparative analysis of 559 soft tissue neoplasms with genetic data. Am J Surg Pathol. 2005;29(10):1340-1347.

(11.) Goldblum JR, Folpe AL, Weiss SW, eds. Enzinger and Weiss's Soft Tissue Tumors. 6th ed. Philadelphia, PA: Elsevier Saunders; 2014.

(12.) Pham V, Henderson-Jackson E, Doepker M, et al. Practical issues for retroperitoneal sarcoma. Cancer Control. 2016;23(3):249-264.

(13.) Henricks WH, Chu YC, Goldblum JR, Weiss SW. Dedifferentiated liposarcoma: a clinicopathological analysis of 155 cases with a proposal for an expanded definition of dedifferentiation. Am J Surg Pathol. 1997;21(3):271-281.

(14.) Gebhard S, Coindre JM, Michels JJ, et al. Pleomorphic liposarcoma: clinicopathologic, immunohistochemical, and follow-up analysis of 63 cases: a study from the French Federation of Cancer Centers Sarcoma Group. Am J Surg Pathol. 2002;26(5):601-616.

(15.) Hornick JL, Bosenberg MW, Mentzel T, McMenamin ME, Oliveira AM, Fletcher CD. Pleomorphic liposarcoma: clinicopathologic analysis of 57 cases. Am J Surg Pathol. 2004;28(10):1257-1267.

(16.) Fletcher CD, Gustafson P, Rydholm A, Willen H, Akerman M. Clinicopathologic re-evaluation of 100 malignant fibrous histiocytomas: prognostic relevance of subclassification. J Clin Oncol. 2001;19(12):3045-3050.

(17.) Gu M, Antonescu CR, Guiter G, Huvos AG, Ladanyi M, Zakowski MF. Cytokeratin immunoreactivity in Ewing's sarcoma: prevalence in 50 cases confirmed by molecular diagnostic studies. Am J Surg Pathol. 2000;24(3):410-416.

(18.) Iwata J, Fletcher CD. Immunohistochemical detection of cytokeratin and epithelial membrane antigen in leiomyosarcoma: a systematic study of 100 cases. Pathol Int. 2000;50(1):7-14.

(19.) Robinson DR, Wu YM, Kalyana-Sundaram S, et al. Identification of recurrent NAB2-STAT6 gene fusions in solitary fibrous tumor by integrative sequencing. Nat Genet. 2013;45(2):180-185.

(20.) Schweizer L, Koelsche C, Sahm F, et al. Meningeal hemangiopericytoma and solitary fibrous tumors carry the NAB2-STAT6 fusion and can be diagnosed by nuclear expression of STAT6 protein. Acta Neuropathol. 2013;125(5):651-658.

(21.) Doyle LA, Fletcher CD. Predicting behavior of solitary fibrous tumor: are we getting closer to more accurate risk assessment? Ann Surg Oncol. 2013; 20(13):4055-4056.

(22.) Pekmezci M, Reuss DE, Hirbe AC, et al. Morphologic and immunohistochemical features of malignant peripheral nerve sheath tumors and cellular schwannomas. Mod Pathol. 2015;28(2):187-200.

(23.) Schaefer IM, Fletcher CD, Hornick JL. Loss of H3K27 trimethylation distinguishes malignant peripheral nerve sheath tumors from histologic mimics. Mod Pathol. 2016;29(1):4-13.

(24.) Kelleher F, O'Donnell CP, Rafee S. Wnt signaling and synovial sarcoma. Sarcoma Res Int. 2014;1(1):5.

(25.) Kosemehmetoglu K, Vrana JA, Folpe AL. TLE1 expression is not specific for synovial sarcoma: a whole section study of 163 soft tissue and bone neoplasms. Mod Pathol. 2009;22(7):872-878.

(26.) Hornick JL. Novel uses of immunohistochemistry in the diagnosis and classification of soft tissue tumors. Mod Pathol. 2014;27(suppl 1):S47-S63.

(27.) Armah HB, Parwani AV. Epithelioid sarcoma. Arch Pathol Lab Med. 2009; 133(5):814-819.

(28.) Cardillo M, Zakowski MF, Lin O. Fine-needle aspiration of epithelioid sarcoma: cytology findings in nine cases. Cancer. 2001;93(4):246-251.

(29.) Guillou L, Wadden C, Coindre JM, Krausz T, Fletcher CD. "Proximal-type" epithelioid sarcoma, a distinctive aggressive neoplasm showing rhabdoid features: clinicopathologic, immunohistochemical, and ultrastructural study of a series. Am J Surg Pathol. 1997;21(2):130-146.

(30.) Chbani L, Guillou L, Terrier P, et al. Epithelioid sarcoma: a clinicopathologic and immunohistochemical analysis of106 cases from the French sarcoma group. Am J Clin Pathol. 2009;131(2):222-227.

(31.) Hornick JL, Dal Cin P, Fletcher CD. Loss of INI1 expression is characteristic of both conventional and proximal-type epithelioid sarcoma. Am J Surg Pathol. 2009;33(4):542-550.

(32.) Hollmann TJ, Hornick JL. INI1-deficient tumors: diagnostic features and molecular genetics. Am J Surg Pathol. 2011;35(10):e47-e63.

(33.) den Bakker MA, Flood SJ, Kliffen M. CD31 staining in epithelioid sarcoma. Virchows Arch. 2003;443(1):93-97.

(34.) Miettinen M, Wang Z, Sarlomo-Rikala M, Abdullaev Z, Pack SD, Fetsch JF. ERG expression in epithelioid sarcoma: a diagnostic pitfall. Am J Surg Pathol. 2013;37(10):1580-1585.

(35.) Smith ME, Brown JI, Fisher C. Epithelioid sarcoma: presence of vascular-endothelial cadherin and lack of epithelial cadherin. Histopathology. 1998;33(5): 425-431.

(36.) Stockman DL, Hornick JL, Deavers MT, Lev DC, Lazar AJ, Wang WL. ERG and FLI1 protein expression in epithelioid sarcoma. Mod Pathol. 2014;27(4):496-501.

(37.) Fetsch JF. Epithelioid hemangioma. In: Fletcher CD, Bridge JA, Hogendoorn PCW, Mertens F, eds. WHO Classification of Tumors of Soft Tissue and Bone. Lyon, France: International Agency for Research on Cancer; 2013:141-142. World Health Organization Classification of Tumours; vol 5.

(38.) Fetsch JF, Sesterhenn IA, Miettinen M, Davis CJ Jr. Epithelioid hemangioma of the penis: a clinicopathologic and immunohistochemical analysis of 19 cases, with special reference to exuberant examples often confused with epithelioid hemangioendothelioma and epithelioid angiosarcoma. Am J Surg Pathol. 2004; 28(4):523-533.

(39.) Weiss SW, Antonescu CR, Bridge JA, Deyrup AT. Epithelioid hemangioendothelioma In: Fletcher CD, Bridge JA, Hogendoorn PCW, Mertens F, eds. WHO Classification of Tumours of Soft Tissue and Bone. Lyon, France: International Agency for Research on Cancer; 2013:155-156. World Health Organization Classification of Tumours; vol 5.

(40.) Errani C, Zhang L, Sung YS, et al. A novel WWTR1-CAMTA1 gene fusion is a consistent abnormality in epithelioid hemangioendothelioma of different anatomic sites. Genes Chromosomes Cancer. 2011;50(8):644-653.

(41.) Doyle LA, Fletcher CD, Hornick JL. Nuclear expression of CAMTA1 distinguishes epithelioid hemangioendothelioma from histologic mimics. Am J Surg Pathol. 2016;40(1):94-102.

(42.) Hart J, Mandavilli S. Epithelioid angiosarcoma: a brief diagnostic review and differential diagnosis. Arch Pathol Lab Med. 2011;135(2):268-272.

(43.) Meis-Kindblom JM, Kindblom LG. Angiosarcoma of soft tissue: a study of 80 cases. Am J Surg Pathol. 1998;22(6):683-697.

(44.) Kindblom LG, Mertens F, Coindre JM, Hornick JL, Meis JM. Sclerosing epithelioid fibrosarcoma. In: Fletcher CD, Bridge JA, Hogendoorn PCW, Mertens F, eds. WHO Classification of Tumours of Soft Tissue and Bone. Lyon, France: International Agency for Research on Cancer; 2013:97-98. World Health Organization Classification of Tumours; vol 5.

(45.) Bai S, Jhala N, Adsay NV, Wei S. Sclerosing epithelioid fibrosarcoma of the pancreas. Ann Diagn Pathol. 2013;17(2):214-216.

(46.) Karamchandani JR, Nielsen TO, van de Rijn M, West RB. Sox10 and S100 in the diagnosis of soft-tissue neoplasms. Applied immunohistochem Mol Morphol. 2012;20(5):445-450.

(47.) Hornick JL, Pan CC. PEComa. In: Fletcher CD, Bridge JA, Hogendoorn PCW, Mertens F, eds. WHO Classification of Tumours of Soft Tissue and Bone. Lyon, France: International Agency for Research on Cancer; 2013:230-231. World Health Organization Classification of Tumours; vol 5.

(48.) Miettinen M, Lasota J. Succinate dehydrogenase deficient gastrointestinal stromal tumors (GISTs): a review. Int J Biochem Cell Biol. 2014;53:514-519.

(49.) Mason EF, Hornick JL. Conventional risk stratification fails to predict progression of succinate dehydrogenase-deficient gastrointestinal stromal tumors: a clinicopathologic study of 76 cases. Am J Surg Pathol. 2016;40(12):1616-1621.

(50.) Jo VY, Fletcher CD. Epithelioid malignant peripheral nerve sheath tumor: clinicopathologic analysis of 63 cases. Am J Surg Pathol. 2015;39(5):673-682.

(51.) Nonaka D, Chiriboga L, Rubin BP. Sox10: a pan-schwannian and melanocytic marker. Am J Surg Pathol. 2008;32(9):1291-1298.

(52.) Woodruff JM, Christensen WN. Glandular peripheral nerve sheath tumors. Cancer. 1993;72(12):3618-3628.

(53.) Yamamoto T, Minami R, 0hbayashi C, Inaba M. Epithelioid leiomyosarcoma of the external deep soft tissue. Arch Pathol Lab Med. 2002;126(4):468-470.

(54.) Jo VY, Marino-Enriquez A, Fletcher CD. Epithelioid rhabdomyosarcoma: clinicopathologic analysis of 16 cases of a morphologically distinct variant of rhabdomyosarcoma. Am J Surg Pathol. 2011;35(10):1523-1530.

(55.) Zin A, Bertorelle R, Dall'Igna P, et al. Epithelioid rhabdomyosarcoma: a clinicopathologic and molecular study. Am J Surg Pathol. 2014;38(2):273-278.

(56.) Hornick JL, Fletcher CD. Cutaneous myoepithelioma: a clinicopathologic and immunohistochemical study of 14 cases. Hum Pathol. 2004;35(1):14-24.

(57.) Miettinen M, McCue PA, Sarlomo-Rikala M, et al. Sox10--a marker for not only schwannian and melanocytic neoplasms but also myoepithelial cell tumors of soft tissue: a systematic analysis of 5134 tumors. Am J Surg Pathol. 2015;39(6): 826-835.

(58.) Doyle LA, Moller E, Dal Cin P, Fletcher CD, Mertens F, Hornick JL. MUC4 is a highly sensitive and specific marker for low-grade fibromyxoid sarcoma. Am J Surg Pathol. 2011;35(5):733-741.

(59.) Mertens F, Fletcher CD, Antonescu CR, et al. Clinicopathologic and molecular genetic characterization of low-grade fibromyxoid sarcoma, and cloning of a novel FUS/CREB3L1 fusion gene. Lab Invest. 2005;85(3):408-415.

(60.) Yang EJ, Hornick JL, Qian X. Fine-needle aspiration of soft tissue perineurioma: a comparative analysis of cytomorphology and immunohistochemistry with benign and malignant mimics. Cancer Cytopathol. 2016;124(9): 651-658.

(61.) Thway K, Fisher C, Debiec-Rychter M, Calonje E. Claudin-1 is expressed in perineurioma-like low-grade fibromyxoid sarcoma. Hum Pathol. 2009;40(11): 1586-1590.

(62.) Bridge JA. The role of cytogenetics and molecular diagnostics in the diagnosis of soft-tissue tumors. Mod Pathol. 2014;27(suppl 1):S80-S97.

(63.) Huang HY, Lal P, Qin J, Brennan MF, Antonescu CR. Low-grade myxofibrosarcoma: a clinicopathologic analysis of 49 cases treated at a single institution with simultaneous assessment of the efficacy of 3-tier and 4-tier grading systems. Hum Pathol. 2004;35(5):612-621.

(64.) Lucas DR, Stenman G. Extraskeletal myxoid chondrosarcoma. In: Fletcher CD, Bridge JA, Hogendoorn PCW, Mertens F, eds. WHO Classification of Tumours of Soft Tissue and Bone. Lyon, France: International Agency for Research on Cancer; 2013:223-224. World Health Organization Classification of Tumours; vol 5.

(65.) Wei S, Siegal GP. Atlas of Bone Pathology. New York: Springer; 2013.

(66.) Antonescu CR, Zhang L, Nielsen GP, Rosenberg AE, Dal Cin P, Fletcher CD. Consistent t(1;10) with rearrangements of TGFBR3 and MGEA5 in both myxoinflammatory fibroblastic sarcoma and hemosiderotic fibrolipomatous tumor. Genes Chromosomes Cancer. 2011;50(10):757-764.

(67.) McCluggage WG, Connolly L, McBride HA. HMGA2 is a sensitive but not specific immunohistochemical marker of vulvovaginal aggressive angiomyxoma. Am J Surg Pathol. 2010;34(7):1037-1042.

(68.) Yoshimoto M, Graham C, Chilton-MacNeill S, et al. Detailed cytogenetic and array analysis of pediatric primitive sarcomas reveals a recurrent CIC-DUX4 fusion gene event. Cancer Genet Cytogenet. 2009;195(1):1-11.

(69.) Italiano A, Sung YS, Zhang L, et al. High prevalence of CIC fusion with double-homeobox (DUX4) transcription factors in EWSR1-negative undifferentiated small blue round cell sarcomas. Genes Chromosomes Cancer. 2012;51(3): 207-218.

(70.) Pierron G, Tirode F, Lucchesi C, et al. A new subtype of bone sarcoma defined by BCOR-CCNB3 gene fusion. Nat Genet. 2012;44(4):461-466.

(71.) Wei S, Siegal GP. Round cell tumors of bone: an update on recent molecular genetic advances. Adv Anat Pathol. 2014;21(5):359-372.

(72.) Rossi S, 0rvieto E, Furlanetto A, Laurino L, Ninfo V, Dei Tos AP. Utility of the immunohistochemical detection of FLI-1 expression in round cell and vascular neoplasm using a monoclonal antibody. Mod Pathol. 2004;17(5):547-552.

(73.) Yoshida A, Sekine S, Tsuta K, Fukayama M, Furuta K, Tsuda H. NKX2.2 is a useful immunohistochemical marker for Ewing sarcoma. Am J Surg Pathol. 2012; 36(7):993-999.

(74.) Surdez D, Benetkiewicz M, Perrin V, et al. Targeting the EWSR1-FLI1 oncogene-induced protein kinase PKC-beta abolishes ewing sarcoma growth. Cancer Res. 2012;72(17):4494-4503.

(75.) Bridge RS, Rajaram V, Dehner LP, Pfeifer JD, Perry A. Molecular diagnosis of Ewing sarcoma/primitive neuroectodermal tumor in routinely processed tissue: a comparison of two FISH strategies and RT-PCR in malignant round cell tumors. Mod Pathol. 2006;19(1):1-8.

(76.) Hill DA, Pfeifer JD, Marley EF, et al. WT1 staining reliably differentiates desmoplastic small round cell tumor from Ewing sarcoma/primitive neuroectodermal tumor: an immunohistochemical and molecular diagnostic study. Am J Clin Pathol. 2000;114(3):345-353.

(77.) Barnoud R, Sabourin JC, Pasquier D, et al. Immunohistochemical expression of WT1 by desmoplastic small round cell tumor: a comparative study with other small round cell tumors. Am J Surg Pathol. 2000;24(6):830-836.

(78.) Arnold MA, Schoenfield L, Limketkai BN, Arnold CA. Diagnostic pitfalls of differentiating desmoplastic small round cell tumor (DSRCT) from Wilms tumor (WT): overlapping morphologic and immunohistochemical features. Am J Surg Pathol. 2014;38(9):1220-1226.

(79.) Kawamura-Saito M, Yamazaki Y, Kaneko K, et al. Fusion between CIC and DUX4 up-regulates PEA3 family genes in Ewing-like sarcomas with t(4;19)(q35; q13) translocation. Hum MolGenet. 2006;15(13):2125-2137.

(80.) Machado I, Navarro S, Llombart-Bosch A. Ewing sarcoma and the new emerging Ewing-like sarcomas: (CIC and BCOR-rearranged-sarcomas)--a systematic review. Histol Histopathol. 2016;31(11):1169-1181.

(81.) Miettinen M. Immunohistochemistry of soft tissue tumours: review with emphasis on 10 markers. Histopathology. 2014;64(1):101-118.

(82.) Parham DM. Immunohistochemical markers of soft tissue tumors: pathologic diagnosis, genetic contributions, and therapeutic options. Anal Chem Insights. 2015;10(suppl 1):1-10.

(83.) Lin G, Doyle LA. An update on the application of newly described immunohistochemical markers in soft tissue pathology. Arch Pathol Lab Med. 2015;139(1):106-121.

Shi Wei, MD, PhD; Evita Henderson-Jackson, MD; Xiaohua Qian, MD, PhD; Marilyn M. Bui, MD, PhD

Accepted for publication January 30, 2017.

From the Department of Pathology, The University of Alabama at Birmingham, Birmingham (Dr Wei); the Departments of Anatomic Pathology (Drs Henderson-Jackson and Bui) and Sarcoma (Dr Bui), Moffitt Cancer Center, Tampa, Florida; Department of Pathology, Brigham and Women's Hospital, and Harvard Medical School, and Dana Farber Cancer Institute, Boston, Massachusetts (Dr Qian); and the Department of Cytopathology Fellowship, Morsani College of Medicine at the University of South Florida, Tampa (Dr Bui).

The authors have no relevant financial interest in the products or companies described in this article.

This manuscript was presented in part at the First Chinese American Pathologists Association (CAPA) Diagnostic Pathology Course: Best Practices in Immunohistochemistry in Surgical Pathology and Cytopathology; August 22-24, 2015; lushing, New York.

Reprints: Marilyn M. Bui, MD, PhD, Department of Anatomic Pathology & Sarcoma, Moffitt Cancer Center, 12902 Magnolia Dr, Tampa, FL 33612 (email: Marilyn.bui@moffitt.org).

Caption: Figure 1. Dedifferentiated liposarcoma misdiagnosed as dermatofibrosarcoma protuberans. A, The tumor shows adipocytic and spindle cell morphology mimicking dermatofibrosarcoma protuberans. B, The spindle cells are immunoreactive to cluster of differentiation 34 (CD34). C, The spindle cells exhibit moderate to severe cytologic atypia and frequent mitotic activity. D, Immunohistochemical study is positive for mouse double minute 2 homolog (MDM2) (hematoxylin-eosin, original magnifications X10 [A] and X20 [C]; original magnifications x10 [B] and X40 [D]).

Caption: Figure 2. Atypical lipomatous tumor. There is a highly atypical large stromal cell with hyperchromatic nuclei that is also multinucleated. There is a lipoblast that has sharply marginated cytoplasmic vacuoles scalloping the large and hyperchromatic nucleus (hematoxylin-eosin, original magnification X40).

Caption: Figure 3. Synovial sarcoma misdiagnosed as malignant solitary fibrous tumor. A, A highly cellular spindle cell neoplasm with a rich vascular network ranging from small vessels to large, ectatic ones with sinusoidal spaces. Areas of necrosis are present. B, The neoplastic cells show pale eosinophilic cytoplasm with inconspicuous borders and round to oval nuclei, granular chromatin, small nucleoli, and numerous atypical mitoses. C, The tumor cells are positive for TLE1 stain (hematoxylin-eosin, original magnifications X10 [A] and X40 [B]; original magnification X20 [C]).

Caption: Figure 4. Epithelioid sarcoma. A, The tumor shows epithelioid morphology and moderate to severe cytologic atypia. The lesional cells are positive for cytokeratin (B) and erythroblast transformation-specific transcription factor (ERG) (C) and demonstrate loss of nuclear integrase interactor 1 (INI1) (D) (hematoxylin-eosin, original magnification X200 [A]; original magnifications X200 [B through D]).

Caption: Figure 5. Epithelioid hemangioma of the penis. A, Sections show a multinodular lesion in the dermis. B, A high-power view demonstrates pleomorphic epithelioid cells with eosinophils. C, The lesional cells are focally positive for pancytokeratin (not shown), and they are diffusely immunoreactive for erythroblast transformation-specific transcription factor (ERG) (D), with a low Ki-67 proliferation index (<5%) and (not shown) retained nuclear integrase interactor 1 (INI1) (hematoxylin-eosin, original magnifications X20 [A] and X200 [B]; original magnification X40 [C and D]).

Caption: Figure 6. Epithelioid vascular tumors. A, Epithelioid hemangioendoethelioma is composed of epithelioid cells with abundant eosinophilic cytoplasm that often contains vacuoles. B, The endothelial nature of the cells is confirmed by erythroblast transformation-specific transcription factor (ERG) staining. C, Epithelioid angiosarcoma demonstrates focal vasoformative features. The tumor is diffusely positive for CD31 (D) and Friend leukemia integration 1 transcription factor (FLI1) (E), with a variable CD34 expression (F) (hematoxylin-eosin, original magnification X200 [A] and X100 [C]; original magnification X200 [B]; original magnification X20 [D through F]).

Caption: Figure 7. Selected epithelioid tumors. A, Sclerosing epithelioid fibrosarcoma shows cytologically atypical cells in the background of collagenized stroma. B, Granular cell tumor demonstrates large cells with small nuclei and abundant granular cytoplasm. C, Glomus tumor shows small, uniform cells (hematoxylin-eosin, original magnifications X200 [A and B] and X100 [C]).

Caption: Figure 8. Myoepithelial tumors. A, Myoepithelioma exhibits nests of myoepithelial cells in a chondromyxoid stroma. B, Myoepithelial carcinoma shows significant cytologic atypia, frequent mitoses, and calponin expression (C) (hematoxylin-eosin, original magnifications X40 [A] and X200 [B]; original magnification X200 [C]).

Caption: Figure 9. Low-grade fibromyxoid sarcoma (LGFMS). A and B, LGFMS exhibits alternating fibrous and myxoid areas and mucin 4 (MUC4) expression (C) (hematoxylin-eosin, original magnification X100 [A and B]; original magnification X100 [C]).

Caption: Figure 10. Selected myxoid tumors: myxoma (A), cellular myxoma (B), nodular fasciitis (C), schwannoma (D), low-grade myxofibrosarcoma (E), and high-grade myxofibrosarcoma (F) (hematoxylin-eosin, original magnification X100 [A through F]).

Caption: Figure 11. Extraskeletal myxoid chondrosarcoma. A, Tumor shows cords and chains of small, uniform cells with round to oval nuclei and abundant chondromyxoid matrix. B, The lesional cells may occasionally express cytokeratin (hematoxylin-eosin, original magnification X200 [A]; original magnification X400 [B]).

Caption: Figure 12. Chordoma. A, This tumor shows characteristic "physaliferous cells." The stroma may less commonly have a chondromyxoid appearance (chondroid chordoma) (B). The tumor cells are typically immunoreactive for cytokeratin (C) and S100 protein (D) (hematoxylin-eosin, original magnification X200 [A and B]; original magnification X200 [C and D]).

Caption: Figure 13. Selected round cell tumors. A, Ewing sarcoma consists of solid sheets of small, blue, round cells with geographic necrosis and nuclear expression of Friend leukemia integration 1 transcription factor (FLI1) (B). C, Embryonal rhabdomyosarcoma demonstrates primitive mesenchymal cells with round and spindled nuclei as well as numerous rhabdomyoblasts. D, Alveolar rhabdomyosarcoma shows monotonous round cells with an "alveolar" growth pattern and strong myoD1 nuclear expression (E). F, Desmoplastic small round cell tumor exhibits nests of round cells separated by a prominent, densely collagenized stroma (hematoxylin-eosin, original magnifications X200 [A and D], X400 [C], and X100 [F]; original magnifications X200 [B] and X400 [E]).
Table 1. Differential Diagnosis by Histologic Pattern

Histologic     Differential
Pattern

Adipocytic     Lipoma, hibernoma, spindle cell lipoma, atypical
               lipomatous tumor/well-differentiated liposarcoma,
               myxoid liposarcoma, dedifferentiated liposarcoma,
               and pleomorphic liposarcoma

Spindle cell   Desmoid tumor (fibromatosis), fibroma, nodular
               fasciitis, low-grade fibromyxoid sarcoma,
               dermatofibrosarcoma protuberance, solitary
               fibrous tumor, fibrosarcoma, leiomyoma,
               leiomyosarcoma, spindle cell/sclerosing
               rhabdomyosarcoma, gastrointestinal stromal tumor,
               schwannoma, neurofibroma, malignant peripheral
               nerve sheath tumor, synovial sarcoma, spindle
               cell lipoma, dedifferentiated liposarcoma,
               and undifferentiated spindle cell sarcoma

Myxoid         Myxoma, soft tissue perineurioma, superficial and
               deep angiomyxoma, myxoid liposarcoma, low-grade
               fibromyxoid sarcoma, myxofibrosarcoma,
               myoepithelioma/myoepithelial carcinoma/mixed
               tumor, extraskeletal myxoid chondrosarcoma,
               and chordoma

Round cell     Ewing sarcoma, embryonal rhabdomyosarcoma, alveolar
               rhabdomyosarcoma, myxoid/round cell liposarcoma,
               extraskeletal myxoid chondrosarcoma, desmoplatic
               small round cell tumor, and undifferentiated round cell
               sarcoma

Epithelioid    Sclerosing epithelioid fibrosarcoma, glomus tumor,
               granular cell tumor, PEComa, rhabdomyoma,
               myoepithelioma/myoepithelial carcinoma/mixed tumor,
               epithelioid hemangioendothelioma, epithelioid
               angiosarcoma, epithelioid leiomyosarcoma, epithelioid
               sarcoma, clear cell sarcoma, and alveolar soft part
               sarcoma

Pleomorphic    Pleomorphic liposarcoma, dedifferentiated liposarcoma,
               pleomorphic rhabdomyosarcoma, myxofibrosarcoma,
               extraskeletal osteosarcoma, and undifferentiated
               pleomorphic sarcoma

Abbreviation: PEComa, perivascular epithelioid cell tumor.

Table 2. Recent Review Articles on Immunohistochemistry (IHC)
of Soft Tissue Tumors

Source, y                 Markers Discussed

Hornick, (26) 2014        Seven lineage-restricted transcription
                          factors (myogenin [MYF4], myoDI [MYF3],
                          FLI1, ERG, Brachyury, SOX10, SATB2), 8
                          proteins correlating molecular alteration
                          markers ([beta]-catenin, MDM2/CDK4, SMARCB1
                          [INI1], SDHB, TFE3, ALK, STAT6), and 4
                          markers identified by gene expression
                          profile (DOG1, TLE1, MUC4, GRIA2)

Miettinen, (81) 2014      Six basic panel markers (CD34, desmin, EMA,
                          keratin cocktail AE1/AE3, S100 protein,
                          [alpha]-SMA), and 4 specific tumor-type
                          markers (CD31, ERG, KIT, DOG1/Ano-1)

Parham, (82) 2015         Thirty-nine selected cell-type markers
                          (germ cells: [alpha]-fetoprotein, 0CT3/4,
                          SALL4m, CD30, PLAP;epithelial cells:
                          cytokeratin, EMA;muscle cells: actin,
                          caldesmon, desmin, myoglobin, myogenin,
                          myoD;hematopoietic cells: CD45, CD20,
                          CD79a, CD15, CD1a, CD68, CD3,
                          myeloperoxidase, TdT, CD21, CD23,
                          CD36;endothelial cells: Von Willebrand
                          factor, CD31, CD34, ERG; neuroendocrine
                          cells: neuron-specific endolase, CD56,
                          CD57, PGP5.5, synaptophysin, chromogranin,
                          neuro N, neurofilaments;melanocytic cells:
                          S100, HMB-45, MITF, Melan-A) and 18 fusion
                          gene product markers or surrogates detected
                          by IHC (FLI1, ERG, AP1 [beta], TLE1, ALK,
                          ROS1, NR4A3, BCL2, WT1, MYC, NUT, BCL6,
                          TFE3, ZAP70, MUC4

Lin and Doyle,(83) 2015   Thirteen new markers (ERG, MYC, MDM2/CDK4,
                          STAT6, MUC4, DOG1, SDHB/A, INI1, TLE1,
                          TFE3, SOX10, NY-ES0-1)

Source, y                 Reference

Hornick, (26) 2014        Mod Pathol. 2014;27(suppl 1):S4-S63

Miettinen, (81) 2014      Histopathology. 2014;64(1):101-118

Parham, (82) 2015         Anal Chem Insights. 2015;10(suppl 1):1-10

Lin and Doyle,(83) 2015   Arch Pathol Lab Med. 2015;139(1):106-121

Abbreviations: EMA, epithelial membrane antigen;ERG, erythroblast
transformation-specific transcription factor;MITF, micropthalmia
transcription factor;PLAP, placental alkaline phosphatase;SMA, smooth
muscle actin.

Table 3. MDM2 Positivity by IHC and FISH in Soft Tissue and
Bone Tumors

Tumor Type                                 MDM2 by     MDM2 by IHC
                                             FISH

ALT/WD liposarcoma                            +        + (nuclear)
Dedifferentiated liposarcoma                  +        + (diffuse,
                                                         nuclear)
Pleomorphic rhabdomyosarcoma                  -             +
Intimal sarcoma                               +       + (up to 70%)
Malignant peripheral nerve sheath tumor       -        + (subset)
Myxofibrosarcoma                              -        + (subset)
Low-grade central osteosarcoma                +             +
Conventional osteosarcoma                  + (10%)          -
Parosteal osteosarcoma                     + (>85%)         +
Undifferentiated high-grade pleomorphic    + (17%)          -
  sarcoma of bone

Abbreviations: ALT/WD, atypical lipomatous tumor/well
differentiated; FISH, fluorescence in situ hybridization; IHC,
immunohistochemistry; MDM2, mouse double minute 2 homolog; +,
positive; -, negative.

Table 4. Salient Histologic Features and Key Immunophenotyes of
Selected Epithelioid Soft Tissue Tumors

Tumor Type             Clinical Characteristics

Epithelioid            Extremities (distal)
sarcoma                Pelvic and perineal regions
                       (proximal)

Epithelioid            Head and neck, distal extremities,
hemangioma             penis

Epithelioid            Any anatomic site
hemangioendothelioma

Epithelioid            Highly aggressive
angiosarcoma

Sclerosing
epithelioid
fibrosarcoma

Glomus tumor           Mostly distal extremities

Granular cell          More common in head and neck
tumor

PEComa                 More common in the
                       retroperitoneal and
                       abdominopelvic regions

Alveolar soft          Most common in deep soft tissue
part sarcoma           of the thigh/buttock

Myoepithelioma/        Cutaneous
myoepithelial
carcinoma

Epithelioid            Not associated with NF1
MPNST

Clear cell             Young adults, mostly distal
sarcoma                extremities (ankle or foot)

Epithelioid            Wide age range
RMS

SDH-deficient          Stomach
GIST

Tumor Type             Histologic Hints

Epithelioid            Granulomatous (distal type)
sarcoma

Epithelioid            Well-formed vascular channels
hemangioma             with a prominent inflammatory
                       infiltrate including eosinophils

Epithelioid            Angiocentric, cords or chains of
hemangioendothelioma   cells with a myxoid or
                       hyalinized stroma

Epithelioid            At least focally vasoformative
angiosarcoma

Sclerosing             Small epithelioid cells with a
epithelioid            sclerotic collagenized stroma
fibrosarcoma

Glomus tumor           Small, uniform cells

Granular cell          Abundant granular cytoplasm
tumor

PEComa                 Uniform cells with round nuclei
                       and abundant granular
                       eosinophilic or clear cytoplasm

Alveolar soft          Large, uniform cells with
part sarcoma           abundant eosinophilic, granular
                       cytoplasm, arranged in an
                       organoid or nesting pattern

Myoepithelioma/        Epithelioid, histiocytoid,
myoepithelial          plasmacytoid, or spindled cells,
carcinoma              with little matrix or a
                       chondromyxoid or collagenous
                       stroma

Epithelioid            Uniform cells with abundant
MPNST                  eosinophilic cytoplasm,
                       rounded nuclei with vesicular
                       chromatin, arranged in sheets,
                       nests, or cords within a
                       collagenous or myxoid stroma

Clear cell             Spindle cell areas commonly
sarcoma                present

Epithelioid            Large cells with or without
RMS                    rhabdomyoblastic differentiation

SDH-deficient          Multinodular
GIST

Tumor Type             Key IHC/Molecular Studies

Epithelioid            * Keratin
sarcoma                * Vascular marks
                       * INI1 loss

Epithelioid            * Vascular markers
hemangioma             * Keratin (focal)

Epithelioid            * Vascular markers
hemangioendothelioma   * Keratin (less common)
                       * TFE3 (small subset)
                       * t(1;3)(p36;q23-25) WWTR1-
                       CAMTA1 fusion

Epithelioid            * Vascular markers
angiosarcoma           * Keratin (35%)

Sclerosing             * MUC4
epithelioid            * t(7;16)(q33;p11) FUS-CREB3L2
fibrosarcoma           fusion

Glomus tumor           * SMA, h-caldesmon
                       * Type IV collagen

Granular cell          * S100, SOX10
tumor                  * CD68, NSE, MITF, TFE3

PEComa                 * HMB-45, Mart-1, MITF
                       * SMA, calponin.
                       * TFE3 (10%)

Alveolar soft          * TFE3 (C-terminal)
part sarcoma           * t(X;17)(p11;q25) ASPSCR1-
                       TFE3 fusion

Myoepithelioma/        * Myoepithelial markers (S100,
myoepithelial          GFAP)
carcinoma              * Muscle markers (calponin,
                       SMA, desmin)
                       * Keratin and EMA
                       * SOX10

Epithelioid            * S100 (strong and diffuse),
MPNST                  SOX10
                       * INI1 loss
                       * Can be positive for keratin/
                       EMA

Clear cell             * Melanocytic markers and
sarcoma                SOX10
                       * t(12;22)(q13;q12) EWSR1-
                       ATF1 fusion

Epithelioid            * Skeletal muscle markers (ie,
RMS                    desmin and myogenin)

SDH-deficient          * CD117, DOG1, SDHB loss
GIST

Abbreviations: EMA, epithelial membrane antigen; GFAP, glial
fibrillary acidic protein; GIST, gastrointestinal stromal tumor; IHC,
immunohistochemistry; MPNST, malignant peripheral nerve sheath
tumor; MUC4, mucin 4; NSE, neuron-specific enolase; PEComa,
perivascular epithelioid cell differentiation; RMS, rhabdomyosarcoma;
SDH, succinate dehydrogenase; SDHB, SDH subunit B; SMA, smooth muscle
actin.

Table 5. Strategies in the Differential Diagnosis of Myxoid Soft
Tissue Tumors

Cellularity   Cytomorphology   Useful Histologic Clues

Low           Spindle          Paucicellular/slightly cellular
                               Lack of curvilinear vessels
              Spindle          Infiltrative margin
                               Dilated, thick-walled vessels

Moderate      Spindle          Small (<5 cm)
                               Tissue culturelike pattern
                               Extravasated blood cells
              Spindle          Alternating fibrous and myxoid
                               areas

              Spindle          Slender cells with bipolar
                               cytoplasmic processes in a
                               whorled or storiform pattern
              Spindle          Antoni A and Antoni B
                               Hyalinized vessels
              Round-spindle    Incomplete peripheral
                               metaplastic bone
              Round            Chicken-wire vessels
                               Lipoblasts

              Round            Cells arranged in cords,
                               chains, or small clusters

              Epithelioid      Physaliferous cells

High          Epithelioid      Macronucleoli
                               Mixed inflammatory infiltrate
              Spindle          Curvilinear vessels,
                               pleomorphic
                               (cellularity dictates grade)

Cellularity   Cytomorphology   Key IHC/Molecular Studies

Low           Spindle          GNAS point mutations

              Spindle          CD34/HMGA2

Moderate      Spindle          SMA, MSA
                               t(17;22)(p13;q13) MYH9-USP6
                               fusion
              Spindle          MUC4
                               t(7;16)(q33;p11) FUS-CREB3L2
                               fusion
              Spindle          EMA, claudin1

              Spindle          S100

              Round-spindle    S100

              Round            S100 (variable)
                               t(12;16)(q13;p11) FUS-DDITS
                               fusion
                               t(12;22)(q13;q12) EWSR1-
                               DDITS fusion
              Round            S100 (~20%)
                               CD117 (30%) EWSR1-
                               NR4A3 fusion
              Epithelioid      Keratins, EMA, S100,
                               Brachyury

High          Epithelioid      t(1;10)(p22-31;q24-25)
                               TGFBR3-MGEA5 fusion
              Spindle          N/A

Cellularity   Cytomorphology   Tumor Type

Low           Spindle          Myxoma/cellular myxoma

              Spindle          Aggressive angiomyxoma

Moderate      Spindle          Nodular fasciitis

              Spindle          Low-grade fibromyxoid
                               sarcoma

              Spindle          Soft tissue perineurioma

              Spindle          Schwannoma

              Round-spindle    Ossifying fibromyxoid tumor

              Round            Myxoid liposarcoma

              Round            Extraskeletal myxoid
                               chondrosarcoma

              Epithelioid      Chordoma

High          Epithelioid      Myxoinflammatory
                               fibroblastic sarcoma
              Spindle          Myxofibrosarcoma

Abbreviations: EMA, epithelial membrane antigen; IHC,
immunohistochemistry; MSA, muscle/specific actin; MUC4, mucin 4; N/A,
not applicable; SMA, smooth muscle actin.
COPYRIGHT 2017 College of American Pathologists
No portion of this article can be reproduced without the express written permission from the copyright holder.
Copyright 2017 Gale, Cengage Learning. All rights reserved.

Article Details
Printer friendly Cite/link Email Feedback
Author:Wei, Shi; Henderson-Jackson, Evita; Qian, Xiaohua; Bui, Marilyn M.
Publication:Archives of Pathology & Laboratory Medicine
Article Type:Report
Date:Aug 1, 2017
Words:11924
Previous Article:Evaluation of Testing of Acute Leukemia Samples: Survey Result From the College of American Pathologists.
Next Article:Fabry Nephropathy.
Topics:

Terms of use | Privacy policy | Copyright © 2018 Farlex, Inc. | Feedback | For webmasters