Inflammatory myofibroblastic tumors (IMTs) are rare soft tissue neoplasms that usually occur in the lung, abdomen, and pelvis, and can involve any location including extremities. IMTs affect primarily children and adolescents, although they may arise in the eighth decade of life.[9]
Histologically, IMT is typically composed of myofibroblastic spindle cells in an inflamed stroma of plasma cells, lymphocytes, and eosinophils.[8] Three basic patterns have been defined, which are often seen in combination within the same tumor: a myxoid/vascular pattern, a compact spindle cell pattern, and a fibromatosis-like pattern.[10] In the present case, the compact spindle cell pattern was predominant with areas of plate-like collagen and inflammatory infiltration, therefore, IMT should be considered.
Based on typical morphological features, immunohistochemical positive reactivity for ALK is an important diagnostic clue for IMTs. The marker is relatively specific for IMT among the series of fibroblastic-myofibroblastic tumors and other mesenchymal mimics of IMT, while smooth muscle markers (including Desmin, h-caldesmon, and SMA), CD34, and MDM2 are expressed variably, which are not distinct for IMTs.[7, 11, 12]
ALK gene rearrangement was identified in approximately 50% of IMTs, and the recognition of ALK gene rearrangements could be helpful to differentiate this entity from other mimics. In some cases, ALK IHC staining was negative, as well as in the present case, however, the diagnosis of IMT could not be excluded. Furthermore, the FISH or NGS assay should be performed for ALK gene. Recent advances have revealed that IMTs harbored other multiple potentially actionable kinase fusions, such as PDGFRB, RET, ROS1, and NTRK3, which had expanded the molecular spectrum of IMTs. [4, 6–8, 11, 13, 14] The recognition of such gene fusions was helpful to identify the ALK-negative IMT.
ROS1 rearrangement has been found not only in the epithelial tumors, such as non-small cell lung cancer (NSCLC), ovarian cancer, gastric adenocarcinoma, and colorectal cancer, but also in some mesenchymal tumors, such as IMT, angiosarcoma, and leiomyosarcoma.[14–17] In IMT, ROS1 fusion was reported in about 10% of cases to date, and fusions of ROS1 with SLC12A2, YWHAE1, TFG, and FN1 have been described previously.[4–6, 8, 11, 18] According to the literatures, the IMTs with ROS1 fusion usually occurred in children and adolescents. The average age was 17 years old. The IMTs with ROS1 fusion was reported in some unusual anatomic sites, such as liver, pharynx, buttock, esophagus, pelvis, and scapula, except for lung and abdominal. The involved breakpoint of ROS1 fusions in IMTs invariably occurs at the exons 32–37, which encodes the variable region of ROS1 kinase protein in the transmembrane region of the plasma membrane. The DNA fragment involving the ROS1 3’ region (that encodes the intracellular kinase domain) fused to partner genes leading to promote tumorigenicity.[4, 6, 11, 16, 18–23]
In this case, a novel ROS1 fusion, TPD52L2-ROS1, was revealed by NGS, which has not been reported in IMT and other tumors. TPD52L2 gene belongs to the D52 protein family genes (including TPD52, TPD52L1, and TPD52L2). The rearrangement fusion of this family gene was rare. To date, there was no report about TPD52L2 gene fusion in the tumor, except for our case. Meanwhile, TPD52L1-ROS1 fusion was reported in NSCLC, and the breakpoint of ROS1 and TPD52L1 was located in intron 32 and intron 3, respectively.[24]
The TPD52L2 protein, a cell cycle-regulated protein, retains its coiled-coil domain (amino acids 38–82) that is necessary for homo- and heterodimerization.[25] The fusion gene could encode TPD52L2-ROS1 chimeric protein which contains the ROS1 kinase domain in the C-terminal and the part of TPD52L2 protein (amino acids 1–125) in the N-terminal. According to the previous reports, all known ROS1 chimeric partners contain dimerization domains that turn the fusion kinase into homodimers leading to a constitutively activated state. Notably, an optimistic clinical response was observed after using the receptor tyrosine kinases inhibitor (Anlotinib and Crizotinib) in the present case. We inferred that the TPD52L2-ROS1 chimeric protein could involve in the kinase activation and tumor development.
The differential diagnosis of IMT depends on the site, age, morphologic characteristics, and molecular features. ALK IHC staining could be a useful marker for the diagnosis of this neoplasm. However, the diagnosis of ALK-negative spindle cell neoplasm with inflammation could be a significant challenge, especially, when tumors arose in older patients or at unusual anatomic sites, or tumors showed atypical spindle cells. In the present case, the spectrum of differential diagnosis is broad and includes benign and malignant neoplasm, such as nodular fasciitis, low-grade follicular dendritic cell sarcoma, low-grade myofibroblastic sarcoma, synovial sarcoma, and some other high-grade sarcomas.
When IMT is composed of relatively uniform, plump myofibroblastic spindle cells and infiltrative border, especially in young adults' extremities, it could be misdiagnosed as nodular fasciitis. Nodular fasciitis shows a cell culture-like growth pattern and is often bordered by thin-walled capillaries that resemble granulation tissue. Moreover, these lesions often present with rapid clinical growth. The immunohistochemical staining profile of nodular fasciitis is non-specific. However, the diagnosis of nodular fasciitis can be excluded when ALK staining is positive. USP6 rearrangements in nodular fasciitis play a key role in the differential diagnostic process. Low-grade follicular dendritic cell sarcoma is characteristic of the admixture of cellular fascicles of bland spindle cells and chronic inflammation, and the nuclear of tumor cells harbor fine chromatin. However, the positive expression of follicular dendritic cell markers, including CD21 and CD35, could be found in follicular dendritic cell sarcoma, instead of IMT. In addition, low-grade myofibroblastic sarcoma (LGMS) could be misdiagnosed as IMT. LGMS usually affects older adults and has a predilection for the head and neck region. LGMS tends to be a more uniform pattern with higher cellularity, more prominent nuclear atypia, more frequent mitoses, and a more widely infiltrative growth pattern than IMT. Immunohistochemical stains for myofibroblast-associated markers are not particularly useful in making the distinction between IMT and LGMS. ALK expression is not found in LGMS, which could be used as an adjunct to differential diagnosis. Synovial sarcoma should be considered in the differential diagnosis, and both are predominant in young adults, especially, when the tumor is characterized by monophasic spindle cells and inflammatory infiltration. Synovial sarcoma is positive for CD99, TLE1, focally AE1/AE3, and EMA, and has a characteristic SS18-SSX gene fusion. When the arrangement of tumor cells is compact and characterized by nuclear pleomorphism, some high-grade sarcomas should also be distinguished from IMT. Dedifferentiated liposarcoma could be a pitfall, given a great proportion of IMT shows MDM2 positive. Nevertheless, dedifferentiated liposarcoma usually occurs in the retroperitoneum in an older age group, and the area of well-differentiated liposarcoma components could be observed.
In summary, we report a rare case of ALK-negative IMT harboring a previously undescribed TPD52L2-ROS1 fusion which expands our understanding of the spectrum of gene fusions in this type of fibroblastic/myofibroblastic neoplasm. NGS has been an essential approach to reveal novel gene fusions in soft tissue tumors. In addition to IMT, receptor tyrosine kinase gene fusion has been reported in a variety of soft tissue neoplasms, such as S100/CD34-positive spindle cell mesenchymal neoplasm. Such advances expand our understanding of molecular pathogenesis to these types of mesenchymal tumors and might avoid diagnostic pitfalls, on the other hand, give the patients promising therapeutic strategies.