Abstract
The molecular genetic changes that have been described in sarcomas over the past era have aided our understanding of their pathogenesis. The majority of sarcomas carry nonspecific genetic changes within a background of a complex karyotype. These constitute the challenges in sarcoma research for unraveling a putative multistep genetic model, such as for chondrosarcoma, and finding targets for therapeutic strategies. Approximately 15–20% of mesenchymal tumors carry a specific translocation within a relatively simple karyotype. The resulting fusion products act either as transcription factors upregulating genes responsible for tumor growth, as for instance in Ewing sarcoma, or translocate a highly active promoter in front of an oncogene driving tumor formation, as for instance in aneurysmal bone cyst. In addition, a small subset of mesenchymal tumors have specific somatic mutations driving oncogenesis. The specific genetic changes unraveled so far had great impact on the classification of bone and soft tissue tumors. In addition, these changes can assist the pathologist in the differential diagnosis of some of these entities, especially within the groups of small blue round cell tumors and spindle cell tumors, if performed in specialized centers. While a putative association between certain fusion products and outcome is still under debate, the role of predicting response of targeted therapy has been well established for KIT and PDGFRA mutations in gastrointestinal stromal tumors.
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Introduction
More and more knowledge has become available aiding our understanding of the genetic background of cancer. Chromosomal translocations or gene mutations can give the cells in which they arise a growth advantage, ultimately leading to cancer. For bone and soft tissue tumors, an increasing amount of tumor-specific genetic data has become available. Approximately 15–20% of mesenchymal tumors carry a specific translocation [1] and have relatively simple karyotypes. These translocations are restricted to specific tumor types; in Ewing sarcoma, synovial sarcoma, and myxoid liposarcoma up to 90–95% of the tumors carry a tumor type-specific translocation. In addition, some tumors carry specific somatic gene mutations (e.g., KIT or PDGFRA mutations in gastrointestinal stromal tumors). In contrast, in the more frequent sarcomas such as osteosarcoma, chondrosarcoma, leiomyosarcoma, or high-grade pleomorphic sarcoma, more complex karyotypes are found with numerous gains and losses, without specific genetic alterations [2].
These molecular data help us to understand the pathogenesis of sarcomas. Moreover, they constitute the basis of the 2002 WHO classification of bone and soft tissue tumors, integrating morphology with genetics [3, 4]. Tumor-specific molecular changes have found their way in daily clinical practice as molecular diagnostic tools to assist the pathologist in diagnosing these lesions, but may also serve as markers to detect minimal residual disease and to predict clinical outcome, although the latter is still somewhat controversial. Finally, our increasing knowledge of the genetic background of sarcomas, including the ones without specific genetic changes, will hopefully enable the development of more types of targeted therapeutic strategies.
Clues about sarcoma pathogenesis
Sarcomas with specific reciprocal translocations
For translocation-derived sarcomas, such as Ewing sarcoma, the occurrence of the translocation is considered a very early step in tumorigenesis [5]. In many of the translocations in sarcomas, the EWSR1 or the FUS gene is involved. These promiscuous genes are strongly homologous and encode RNA-binding proteins. Most probably, EWSR1 and FUS have a similar effect when they are involved in a chromosomal translocation. The type of DNA-binding domain originating from the fusion partner probably determines the tumor type that is induced by the translocation.
These hybrid oncoproteins subsequently act as aberrant transcription factors dysregulating gene expression patterns initiating tumor formation. Target genes of the EWSR1-ETS fusion products were shown to stimulate cell proliferation (upregulation of PDGF-C, CCDN1, c-MYC), evade growth inhibition (downregulation of cyclin-dependent kinase inhibitors and TGF-beta receptor type II), escape from senescence (upregulation of hTERT), escape from apoptosis (repression of IGFBP-3 promoter), induce angiogenesis (VEGF), invasion and metastases (MMPs) [6].
Alternative to aberrant transcription factor activity of fusion products, some other mechanisms of translocation-based tumorigenesis have been described. One of the genes involved in a translocation can be placed under control of the other gene involved in the translocation, which usually leads to over expression. The growth factor PDGFB is placed under control of the COL1A1 promoter in the COL1A1-PDGFB fusion in dermatofibrosarcoma protuberans [7]. This leads to autocrine stimulation and tumor cell proliferation through the PDGF receptor [7, 8]. Similarly, in aneurysmal bone cyst, many different translocations have been described [9, 10], all resulting in oncogenic activation of the USP6 (TRE2 and TRE17) gene on chromosome 17p13 by placing it under transcriptional control of other, highly active promoters [11]. The mechanism by which upregulation of USP6, involved in actin remodeling [12], causes ABC formation is so far unknown. Finally, in congenital fibrosarcoma, the ETV6-NTRK3 fusion product represents a chimeric tyrosine kinase in itself leading to constitutively active Ras/MAPK mitogenic pathway and PI3K/Akt pathway-mediated cell survival [13].
Sarcomas with specific somatic mutations
In addition, some mesenchymal tumors carry specific somatic mutations that upon their discovery elucidated the pathogenesis of these tumors. For instance, KIT mutations in GIST revealed its relation with the interstitial cells of Cajal. Another example is fibrous dysplasia, a benign fibro-osseous lesion in the medulla of the bone. Polyostotic fibrous dysplasia can be associated with endocrine abnormalities and cafe au lait pigmentation in nonhereditary Mc Cune Albright Syndrome (Online Mendelian inheritance in man NCBI number MIM 174800). Fibrous dysplasia has for long been regarded a nonneoplastic process. Its neoplastic nature was suggested by the occurrence of clonal chromosomal abnormalities found in cytogenetic studies [14]. Fibrous dysplasia is characterized by activating mutations in the Gs alpha (GNAS1) gene localized on chromosome 20q12–q13.3, encoding the alpha subunit of the stimulatory guanine nucleotide-binding protein (G-protein) [15]. G-proteins couple extracellular receptors to intracellular effector enzymes and ion channels, mediating the cellular response to an external stimulus. The identification of GNAS1 mutations also in Mc Cune Albright syndrome (postzygotic) and nonskeletal-isolated endocrine lesions clarified that these disorders represent a spectrum of phenotypic expressions of the same basic disorder, probably reflecting different patterns of somatic mosaicism [15]. Moreover, GNAS1 mutations are also found in (intramuscular and cellular) myxomas [16] and the cooccurrence of fibrous dysplasia and myxomas is known as Mazabraud syndrome [17]. Interestingly, GNAS1 mutations are found in the cooccurring myxomas as well and are absent in a morphological mimic of myxoma: low-grade myxofibrosarcoma [18]. Finally, inactivating mutations of the hSNF5/INI1 gene are found in rhabdoid tumors. hSNF5 is a core member of the SWI/SNF chromatin remodeling complex and hSNF5 loss leads to epigenetically based changes in transcription resulting in cell cycle progression [19] and genomically stable tumors [20].
Sarcomas with more or less specific amplifications
While in principle not tumor specific, some sarcomas are characterized by a highly reproducible amplification such as in case of atypical lipomatous tumor/ well-differentiated liposarcoma/dedifferentiated liposarcoma the amplification of CDK4 and MDM2 [21–23]. While most if not all of the aforementioned tumors harbor such an amplification and as such it can be used to recognize a lipogenic origin in the dedifferentiated areas of dedifferentiated liposarcoma, it is by no means tumor specific as similar amplifications occur for instance in osteosarcoma or chondrosarcoma [24]. This genetic marker however is in context quite useful for diagnostic purposes.
Sarcomas with nonspecific complex karyotypes
The more frequent sarcomas, like high-grade pleomorphic sarcoma, myxofibrosarcoma [25] or leiomyosarcoma [26], have complex karyotypes lacking specific genetic aberrations.
For instance, for chondrosarcoma development, a multistep genetic model is presumed. Chondrosarcomas can be either central (arising in the medullar cavity of bone) or peripheral (at the surface of bone). Peripheral chondrosarcomas arise secondarily within the cartilaginous cap of a benign osteochondroma. Osteochondromas can occur within an autosomal dominantly inherited syndrome, Multiple Osteochondromas, in which mutations occur in either EXT1 or EXT2 [27]. These encode glycosyltransferases catalyzing heparan sulphate chain elongation on heparan sulphate proteoglycans, which are important for cellular signaling of Hedgehog, Fibroblast Growth Factor, Wnt, Bone Morphogenetic Protein and Transforming Growth Factor beta. Thus, while it is clear that inactivation of EXT underlies osteochondroma development [28, 29], so far, unidentified additional genetic changes are required for malignant transformation towards secondary peripheral chondrosarcoma, resulting in more complex karyotypes including near-haploidy and polyploidization [30, 31]. In contrast, in the more common central chondrosarcoma EXT is not involved [32]. Instead, complex karyotypes are found especially in high-grade chondrosarcoma [31, 33, 34], and 96% of them contains alterations at some level in the pRb pathway [35]. Thus, the genetic background of tumors without specific genetic aberrations is slowly being elucidated.
Classification of sarcomas
Since soft tissue tumors are relatively rare compared with epithelial malignancies, they are generally regarded difficult by surgical pathologists. Soft tissue tumors constitute a very heterogeneous group of tumors containing >100 histological types and subtypes. The considerable morphological overlap between the different diagnostic entities further adds to difficulties in classification [36]. Classification is however essential since these different entities require different treatment strategies and have a different outcome. In classifying tumors, the pathologist can be assisted by immunohistochemistry and molecular diagnostics [37]. Immunohistochemistry is used to confirm the line of differentiation, while molecular techniques can identify specific chromosomal translocations or mutations. The 2002 WHO classification of bone and soft tissue tumors is mainly based on the integration of morphology and genetics [36]. This classification is at present widely accepted and used.
Use of specific molecular changes in differential diagnosis
The differential diagnosis among the groups of small blue round cell tumors and spindle cell tumors can be very difficult for pathologists due to the high number of entities and their morphological overlap. Although the morphology and immunohistochemistry remain at the cornerstone of the diagnosis, the detection of specific genetic alterations, either translocations or somatic mutations, can be very helpful. Molecular diagnostics is especially important in those cases with unusual morphology, immunohistochemistry or clinical presentation.
The term “small blue round cell” tumor encompasses a heterogeneous group of tumors that share the presence of undifferentiated small round cells with scant cytoplasm at histology. The differential diagnosis includes Ewing sarcoma/PNET, neuroblastoma, non-Hodgkin lymphoma, poorly differentiated (round cell) synovial sarcoma, rhabdomyosarcoma, small cell osteosarcoma, desmoplastic round cell tumor, and mesenchymal chondrosarcoma (Table 1). Due to the absence of distinguishing morphological features, their distinction can be difficult. Using immunohistochemistry and conventional histochemical stainings, many of these entities can already be distinguished. In addition, molecular diagnostics can be used to detect specific reciprocal translocations in Ewing sarcoma, rhabdomyosarcoma, synovial sarcoma or desmoplastic small round cell tumor. Either (Real-Time) PCR [38] on RNA isolated from frozen or paraffin-embedded tumor tissue,or FISH on paraffin-embedded slides can be used to detect these translocations. Especially in case of poorly differentiated synovial sarcoma versus Ewing sarcoma /PNET the morphology and the immunohistochemical profile can be identical requiring the demonstration of a EWSR1 or SS18 rearrangement to come to a correct diagnosis and therapy.
Spindle cell tumors share, as their name implies, a spindle cell morphology of the tumor cells. The differential diagnosis includes monophasic synovial sarcoma, leiomyosarcoma, solitary fibrous tumor, malignant peripheral nerve sheath tumor, clear cell sarcoma, fibrohistiocytic tumors, dedifferentiated liposarcoma, spindle cell rhabdomyosarcoma, and in abdominal localization, gastrointestinal stromal tumor (Table 2). Monophasic synovial sarcoma and clear cell sarcoma carry specific chromosomal translocations that can be used. This is especially helpful in the distinction of MPNST and monophasic synovial sarcoma, which can be morphologically and immunohistochemically indistinguishable. KIT or PDGFRA mutation analysis can be helpful to diagnose gastrointestinal stromal tumor, especially in the small proportion in which CD117 is negative. The diagnosis of dedifferentiated liposarcoma especially if the well-differentiated liposarcoma component is not present at morphology can be facilitated by demonstrating the 12q13 amplification that is characteristic for these lesions, either by immunohistochemistry or FISH for amplification of MDM2 [39, 40].
Detection of minimal residual disease
Following exciting results in molecular screening of lymph nodes for micrometastases of colonic cancer and bone marrow for minimal residual disease after lymphoma treatment, efforts have been made to do the same for sarcomas harboring a tumor-specific translocation as for instance Ewing sarcomas [41, 42]. Presence of tumor cells in bone marrow but not in blood was claimed to be associated with adverse prognosis [43], while others showed an increased risk of systemic relapses associated with bone marrow micrometastasis and circulating tumor cells in localized Ewing tumor.[44]. Tumor cells were shown to be present in a subset of stem cell harvests of Ewings sarcoma patients and their persistence following transplantation was claimed to be associated with relapse. Large prospective multinational randomized trials have been designed such as the EuroEwing 99 trial to investigate these questions. Although this trial is now open for 10 years, still, the data are not mature to draw final conclusions with regard to this question, implying that when a difference is present, this should be minimal at best for the individual patient. For alveolar rhabdomyosarcoma, molecular markers have been advocated for early detection of tumor relapses as well as using a reverse transcriptase-polymerase chain reaction method [45].
Prediction of outcome
Some tumors like Ewing sarcoma or synovial sarcoma may carry individually one of a spectrum of tumor specific cytogenetic or molecular genetic abnormalities. In retrospective studies, it has been claimed that the prognoses for these tumor entities was influenced by the specific molecular-defined translocation type [46–48]. These appeared in these first studies a powerful prognostic indicator and in case of synovial sarcoma even a predictor of the biphasic versus the monophasic subtype. In due course however, based on either prospectively collected cases treated in the context of a clinical trial or large national sarcoma databases, the prognostic value of these subtypes of translocations has been questioned for both tumor types [49–52]. Next to the specific translocations, some sarcomas, especially well documented in Ewing sarcoma, harbor numerical chromosomal abnormalities, deletions of the p16 region or additional point mutations in p53 [53–57]. These abnormalities are most often grossly overlooked when applying an RT-PCR approach just focusing on the known fusion breakpoints. An important role in tumor progression and prognosis has been claimed for these additional, nontumor-specific events. In case of metastatic GIST, the prognosis is highly correlated to the response to tyrosine kinase-inhibiting drugs [58]. While also immunohistochemical phenotypic markers have been studied with potential prognostic impact [59], these failed to show prognostic impact in contrast to clinical [60] and morphological [61] parameters. Here, especially the type of mutation in KIT or PDGFRA appears to have an important impact on response to tyrosine kinase inhibition [62, 63]while additional molecular events superimposed to the original tumor-specific ones like those described earlier for Ewing sarcoma are increasingly more of interest in studying resistance [64,65] and tumor progression [66].
Identification of molecular targets for treatment
With the identification of some of the specific changes in sarcomas, therapeutic targets were disclosed. The most well-known example is KIT/PDGFRA mutations in gastrointestinal stromal tumors of which the constitutively active signaling and subsequent tumor growth can be inhibited using tyrosine kinase inhibitors such as imatinib (STI571, Gleevec) [67]. Also, specific translocations have revealed targets for therapy. The COL1A1-PDGFB fusion product in dermatofibrosarcoma protuberans signals through the PDGF receptor in an autocrine loop [8], of which the signaling can be blocked using tyrosine kinase inhibitors acting at PDGFR such as imatinib. Imatinib treatment of this superficially located low-grade sarcoma can be beneficial to reduce tumor size in otherwise inoperable tumors.
Conclusion
Molecular and cytogenetic studies performed over the past decades have been proven to have major impact in identification, classification, and in some cases, prognostication of a large variety of sarcomas. With regard to diagnosis, the use of molecular techniques for an array of tumor entities has found their way into routine clinicopathological practice. Like the treatment of sarcomas, the application of molecular techniques needs to be under strict protocol and in morphological context in order to avoid disastrous mistakes in tumor classification. Here, a need for vigorous (multi) national quality control assessments, centralization not only of treatment but also of (molecular) diagnosis and development of (multi) national guidelines [68–71] is a future view which needs attention of the pathology community as well as health-care decision makers.
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Bovée, J.V.M.G., Hogendoorn, P.C.W. Molecular pathology of sarcomas: concepts and clinical implications. Virchows Arch 456, 193–199 (2010). https://doi.org/10.1007/s00428-009-0828-5
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DOI: https://doi.org/10.1007/s00428-009-0828-5