Rhabdomyosarcoma

Rhabdomyosarcoma, or RMS, is an aggressive and highly malignant form of cancer that develops from skeletal (striated) muscle cells that have failed to fully differentiate. It is generally considered to be a disease of childhood, as the vast majority of cases occur in those below the age of 18. It is commonly described as one of the 'small, round, blue cell tumours of childhood' due to its appearance on an H&E stain. Despite being a relatively rare cancer, it accounts for approximately 40% of all recorded soft tissue sarcomas. Rhabdomyosarcoma, or RMS, is an aggressive and highly malignant form of cancer that develops from skeletal (striated) muscle cells that have failed to fully differentiate. It is generally considered to be a disease of childhood, as the vast majority of cases occur in those below the age of 18. It is commonly described as one of the 'small, round, blue cell tumours of childhood' due to its appearance on an H&E stain. Despite being a relatively rare cancer, it accounts for approximately 40% of all recorded soft tissue sarcomas. RMS can occur in any site on the body, but is primarily found in the head, neck, orbit, genitourinary tract, genitals, and extremities. There are no clear risk factors for RMS, but the disease has been associated with some congenital abnormalities. Signs and symptoms vary according to tumor site, and prognosis is closely tied to the location of the primary tumor. Common site of metastasis include the lungs, bone marrow, and bones. There are many classification systems for RMS and a variety of defined histological types. Embryonal rhabdomyosarcoma is the most common type and comprises about 60% of cases. Patient outcomes vary considerably, with 5 years survival rates between 35% and 95% depending on the type of RMS involved, so clear diagnosis is critical for effective treatment and management. Accurate and quick diagnosis is often difficult due to the heterogeneity of RMS tumors and a lack of strong genetic markers of the disease. Treatment usually involves a combination of surgery, chemotherapy, and radiation. Sixty percent to 70% of newly diagnosed patients with nonmetastatic disease can be cured using this combined approach to therapy. Despite aggressive multimodality treatment, less than 20% of patients with metastatic RMS are able to be cured of their disease. Given the difficulty in diagnosing rhabdomyosarcoma, definitive classification of subsets has proven difficult. As a result, classification systems vary by institute and organization. However, rhabdomyosarcoma can be generally divided into three histological subsets: There is also an extremely rare subtype of RMS that has been described as sclerosing rhabdomyosarcoma by Folpe, et al, but it is not a currently recognized subtype by the NCI or WHO. This subtype has characteristic histology involving hyaline sclerosis and pseudovascular development. Its origins are unclear, but some studies have pointed to an association with embryonal RMS. Multiple classification systems have been proposed for guiding management and treatment, and the most recent and widely used classification system is the 'International Classification of Rhabdomyosarcoma' or ICR. It was created by the IRSG in 1995 after their series of four multi-institutional trials aimed at studying the presentation, histology, epidemiology, and treatment of RMS (IRSG I–IV). The ICR system is based on prognostic indicators identified in IRSG I–IV. Pleomorphic rhabdomyosarcoma usually occurs in adults rather than children, and is therefor not included in this system. Sclerosing rhabdomyosarcoma is also not included in this system due to its rare presentation and weak classification schema. RMS can occur in almost any soft-tissue site in the body; the most common primary sites are genitourinary (24%), parameningeal (16%), extremity (19%), orbit (9%), other head and neck (10%), and miscellaneous other sites (22%). RMS often presents as a mass, but signs and symptoms can vary widely depending on the site of the primary tumor. Genitourinary tumors may present with hematuria, urinary tract obstruction, and/or a scrotal or vaginal mass. Tumors that arise in the retroperitoneum and mediastinum can become quite large before producing signs and symptoms. Parameningeal tumors may present with cranial nerve dysfunction, symptoms of sinusitis, ear discharge, headaches, and facial pain. Orbital tumors often present with orbital swelling and proptosis. Extremity tumors generally present as a rapidly enlarging, firm mass in the relevant tissue. The cancer's prevalence in the head, face, and neck will often allow for earlier signs of the disease simply due to the obvious nature of tumors in these locations. Despite the varying presentation and typically aggressive nature of the disease, RMS has the potential to be diagnosed and treated early. The fourth IRSG study found that 23% of patients were diagnosed in time for a complete resection of their cancer, and 15% had resection with only minimal remnants of the diseased cells. There are multiple genetic lesions associated with rhabdomyosarcoma, but there has been little consistent data demonstrating an association between specific genetic abnormalities and outcome. However, alveolar and embryonal types of RMS can be distinguished cytogenetically, and identification of specific genetic lesions can allow for accurate classification of the ARMS subtype when the histopathological findings are equivocal or unclear. This is valuable for clinical practice as the alveolar type presents a higher risk to the patient and will often require more aggressive treatment than the embryonal type. Thus, ARMS is also referred to as Fusion Positive rhabdomyosarcoma (FP-RMS). Up to 90% of alveolar RMS cases present with a translocations of t(2;13)(q35,q14) or, less commonly, t(1;13)(p36,q15). Both involve the translocation of a DNA binding domain of either PAX3 or PAX7, a member of the Paired Box family of transcription factors, to a transactivation site on FOXO1 (previously known as FKHR), a member of the forkhead/HNF-3 transcription factor family. The t(2;13) translocation results in a fusion of the PAX3 gene with FOXO1, while the t(1;13) translocation involves the fusion of PAX7 with FOXO1. PAX3 has a demonstrated role in muscle cell development, which supports its potential role in RMS. The t(2;13) translocation can result in the PAX3-FKHR fusion product, which is indicative of classic cystic ARMS. Cases of FP-RMS are associated with a poorer prognosis than fusion-negative RMS. The fusion protein presents a potential therapeutic target, and in recent years more research has been conducted to clarify the role of PAX3-FOXO1 in FP-RMS. PAX3-FOXO1 is now known to drive key oncogenes such as MYC and MYCN by creating long-distance genetic interactions by super enhancers. In this context, PAX3-FOXO1 both (1) drives the expression of MYC, MYCN and even MYOD1 (a transcription factor highly expressed in all RMS subtypes) but also (2) co-binds with these master transcription factors at super enhancers to support cancer growth. Furthermore, it was demonstrated that FP-RMS subtypes were especially sensitive to inhibitors (such as JQ1) of a super enhancer bound protein BRD4.