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Synovial sarcoma : translating gene expression into patient careTerry, Jefferson 05 1900 (has links)
Synovial sarcoma is a soft tissue tumor defined by the presence of t(X;18)(p11.2;q11.2), fusing the SYT (SS18) gene on chromosome 18 and one of three SSX genes on chromosome X. T(X;18) results in production of a fusion protein (SYT-SSX) that is thought to underlie synovial sarcoma pathogenesis through aberrant targeting of both activating (trithorax, SWI/SNF) and repressing (Polycomb) transcription factors when expressed in a stem or progenitor-like cellular background.
Clinically, synovial sarcomas present considerable diagnostic and therapeutic challenges. Whereas the classical biphasic histology is distinctive, the more common monophasic histology can be difficult to differentiate from other spindle cell tumors. In these situations, detection of t(X;18) is the gold standard for diagnosis, but it is a specialized and time-consuming process. Immunohistochemistry can be helpful, but no marker that is both highly sensitive and specific is available. Here I describe a fluorescence in situ hybridization based method employing an SYT break-apart probe set that can expedite detection of t(X;18). I also report that TLE1, which was identified in gene expression studies as a good discriminator of synovial sarcoma from other mesenchymal tumors, is a highly sensitive and specific immunohistochemical marker for synovial sarcoma. Both of these novel diagnostic techniques are applicable to small tissue samples such as core needle biopsies and are now being used clinically.
The diagnosis of synovial sarcoma carries a poor prognosis and the 10-year overall survival rate is approximately 50%, most of whom are young adults. The addition of chemotherapy to surgical resection (the mainstay of treatment) does not appear to improve overall survival. Thus, there is a strong need for development of a clinically effective systemic therapy to improve patient outcome. I describe preclinical studies that demonstrate the Hsp90 inhibitor 17-allylamino-17-demethoxygeldanamycin (17-AAG) inhibits proliferation of synovial sarcoma by inducing apoptosis and that this is associated with degradation of multiple receptor tyrosine kinases and disruption of the SYT-SSX-β-catenin interaction. I also identify a subset of synovial sarcoma cells, typified by expression of CD133, which exhibit stem-like properties and are relatively resistant to doxorubicin but susceptible to 17-AAG at clinically relevant concentrations.
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Synovial sarcoma : translating gene expression into patient careTerry, Jefferson 05 1900 (has links)
Synovial sarcoma is a soft tissue tumor defined by the presence of t(X;18)(p11.2;q11.2), fusing the SYT (SS18) gene on chromosome 18 and one of three SSX genes on chromosome X. T(X;18) results in production of a fusion protein (SYT-SSX) that is thought to underlie synovial sarcoma pathogenesis through aberrant targeting of both activating (trithorax, SWI/SNF) and repressing (Polycomb) transcription factors when expressed in a stem or progenitor-like cellular background.
Clinically, synovial sarcomas present considerable diagnostic and therapeutic challenges. Whereas the classical biphasic histology is distinctive, the more common monophasic histology can be difficult to differentiate from other spindle cell tumors. In these situations, detection of t(X;18) is the gold standard for diagnosis, but it is a specialized and time-consuming process. Immunohistochemistry can be helpful, but no marker that is both highly sensitive and specific is available. Here I describe a fluorescence in situ hybridization based method employing an SYT break-apart probe set that can expedite detection of t(X;18). I also report that TLE1, which was identified in gene expression studies as a good discriminator of synovial sarcoma from other mesenchymal tumors, is a highly sensitive and specific immunohistochemical marker for synovial sarcoma. Both of these novel diagnostic techniques are applicable to small tissue samples such as core needle biopsies and are now being used clinically.
The diagnosis of synovial sarcoma carries a poor prognosis and the 10-year overall survival rate is approximately 50%, most of whom are young adults. The addition of chemotherapy to surgical resection (the mainstay of treatment) does not appear to improve overall survival. Thus, there is a strong need for development of a clinically effective systemic therapy to improve patient outcome. I describe preclinical studies that demonstrate the Hsp90 inhibitor 17-allylamino-17-demethoxygeldanamycin (17-AAG) inhibits proliferation of synovial sarcoma by inducing apoptosis and that this is associated with degradation of multiple receptor tyrosine kinases and disruption of the SYT-SSX-β-catenin interaction. I also identify a subset of synovial sarcoma cells, typified by expression of CD133, which exhibit stem-like properties and are relatively resistant to doxorubicin but susceptible to 17-AAG at clinically relevant concentrations.
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Synovial sarcoma : translating gene expression into patient careTerry, Jefferson 05 1900 (has links)
Synovial sarcoma is a soft tissue tumor defined by the presence of t(X;18)(p11.2;q11.2), fusing the SYT (SS18) gene on chromosome 18 and one of three SSX genes on chromosome X. T(X;18) results in production of a fusion protein (SYT-SSX) that is thought to underlie synovial sarcoma pathogenesis through aberrant targeting of both activating (trithorax, SWI/SNF) and repressing (Polycomb) transcription factors when expressed in a stem or progenitor-like cellular background.
Clinically, synovial sarcomas present considerable diagnostic and therapeutic challenges. Whereas the classical biphasic histology is distinctive, the more common monophasic histology can be difficult to differentiate from other spindle cell tumors. In these situations, detection of t(X;18) is the gold standard for diagnosis, but it is a specialized and time-consuming process. Immunohistochemistry can be helpful, but no marker that is both highly sensitive and specific is available. Here I describe a fluorescence in situ hybridization based method employing an SYT break-apart probe set that can expedite detection of t(X;18). I also report that TLE1, which was identified in gene expression studies as a good discriminator of synovial sarcoma from other mesenchymal tumors, is a highly sensitive and specific immunohistochemical marker for synovial sarcoma. Both of these novel diagnostic techniques are applicable to small tissue samples such as core needle biopsies and are now being used clinically.
The diagnosis of synovial sarcoma carries a poor prognosis and the 10-year overall survival rate is approximately 50%, most of whom are young adults. The addition of chemotherapy to surgical resection (the mainstay of treatment) does not appear to improve overall survival. Thus, there is a strong need for development of a clinically effective systemic therapy to improve patient outcome. I describe preclinical studies that demonstrate the Hsp90 inhibitor 17-allylamino-17-demethoxygeldanamycin (17-AAG) inhibits proliferation of synovial sarcoma by inducing apoptosis and that this is associated with degradation of multiple receptor tyrosine kinases and disruption of the SYT-SSX-β-catenin interaction. I also identify a subset of synovial sarcoma cells, typified by expression of CD133, which exhibit stem-like properties and are relatively resistant to doxorubicin but susceptible to 17-AAG at clinically relevant concentrations. / Medicine, Faculty of / Pathology and Laboratory Medicine, Department of / Graduate
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SS18-SSX, the Oncogenic Fusion Protein in Synovial Sarcoma, Is a Cellular Context-Dependent Epigenetic Modifier / 滑膜肉腫特異的融合タンパクSS18-SSXは細胞背景依存性のエピゲノム修飾因子であるTamaki, Sakura 23 March 2016 (has links)
京都大学 / 0048 / 新制・課程博士 / 博士(医科学) / 甲第19632号 / 医科博第70号 / 新制||医科||5(附属図書館) / 32668 / 京都大学大学院医学研究科医科学専攻 / (主査)教授 斎藤 通紀, 教授 小川 誠司, 教授 野田 亮 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM
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Studies of transforming growth factor alpha in normal and abnormal growthHallbeck, Anna-Lotta January 2007 (has links)
Regulation of growth is of fundamental importance for development of the organism and to maintain health. The induction of cell proliferation and matrix production are influenced by several different signaling systems, most importantly by growth factors. The human HER-family of growth factor ligands and receptors is one of the most studied and, at present, one of the most complex including 4 tyrosine kinase receptors and at least 11 different ligands cooperating in the transfer of signals. The HER-family growth responses are also influenced by other intercellular and extracellular signals, including matrix components, cytokines and hormones mediating e.g. inflammation. HER-1 (EGFR) is one of the best known and most extensively studied growth factor receptors. TGF-alpha is possibly the most potent HER-1 ligand and influences wound healing, epidermal maintenance, gastrointestinal function, lactation, pulmonary function and more. Several studies have shown important regulatory functions for some inflammatory cytokines on TGF-alpha production in white blood cells. HER-1 is widespread in epithelial cells but also in mesenchymal cells such as fibroblasts, osteogenic and chondrogenic cells. Consequently, many tumors arising from these cell types express HER family members and often show TGF-alpha and/or HER activation. Indeed, mammary cancer development has been shown when over expressing both TGF-alpha and HER-2 in mouse mammary cells in vivo. In recent years the first HER-1 and HER-2 inhibitors have come into clinical practice for treatment of breast cancer, lung cancer and gastrointestinal cancers, sometimes with great success. However, more knowledge is needed concerning the inflammatory regulation of HER-family expression including where and how the ligands and receptors cooperate. Therefore we were interested in studying the role of TGF-alpha in normal and abnormal growth. First we showed that the acute inflammatory cytokine IL-6 regulates TGF-alpha expression in U-937-1 monocytoid cells. Secondly, we detected a possible long-term enhancing influence of singledose UVR on HER-1 expression in normal human melanocytes. We continued thirdly by revealing TGF-alpha production concomitant with HER-2 in normal human synovia and release of soluble TGF-alpha into the synovial fluid. Both TGF-alpha and HER-2 production were significantly increased in inflammatory joint conditions, e.g. RA. Fourthly, we demonstrated expression of TGF-alpha, HER-1 and HER-2 in synovial sarcoma cells in culture; the observed HER-2 phosphorylation was dependent on ligand induced HER-1 activation. The presented results indicate that TGF-alpha expression can be enhanced by acute inflammatory cytokine IL-6, possibly contributing to growth stimulatory effects assigned to IL-6 itself. The acute effects of UVR on melanocytes mediate up-regulated steady-state expression of HER-1, constituting a potential target for locally produced TGF-alpha that may induce melanocyte proliferation. TGF-alpha and HER-2 seem to have a role in the maintenance of synovial joint tissues. Upregulation of TGF-alpha and HER-2 in inflammatory joint conditions, e.g. RA, represents a novel mechanism for synovial proliferation contributing to joint deterioration. TGF-alpha, HER1 and HER-2 may have a role in synovial sarcoma proliferation; further investigation is needed to evaluate HER-family inhibitors as a possible treatment alternative in this type of cancer.
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Synovial sarcoma : molecular, biological and clinical implications /Törnkvist, Maria, January 2004 (has links)
Diss. (sammanfattning) Stockholm : Karol. inst., 2004. / Härtill 4 uppsatser.
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Radiothérapie interne vectorisée appliquée aux synovialosarcomes : mise en place d'une étude de phase 1 / Vectorized radionuclide therapy applied to synovial sarcoma : implementation of a phase 1 studyGiraudet, Anne-Laure 26 November 2018 (has links)
La radiothérapie interne vectorisée (RIV) permet une irradiation systémique la plus élective possible des lésions métastatiques de cancers. Nous rapportons une étude de phase I avec première injection à l’homme mise en place au Centre Léon Bérard pour le traitement de patients porteurs de métastases de synovialosarcomes. Sur un schéma théranostique, une étape d’imagerie et de dosimétrie était réalisée afin d’étudier la biodistribution du radiopharmaceutique diagnostique (RPD) compagnon du radiopharmaceutique thérapeutique (RPT). En cas de biodistribution favorable (fixation tumorale supérieure aux organes sains environnant) permettant d’envisager la RIV avec un effet tumoricide tout en limitant les effets secondaires de l’irradiation de tissus sains, les patients recevaient le RPT. Au total 20 patients ont été inclus. Dix d’entre eux étaient éligibles à la phase thérapeutique : 2 n’ont pas pu être traités du fait d’une progression de la maladie et 8 ont été traités, incluant 1 patiente ayant pu recevoir une 2ème injection de RPT du fait d’une stabilisation de la maladie. Les effets secondaires ont été principalement hématologiques. Les réponses au traitement ont été des stabilisations transitoires. Face à ces résultats modestes, nous avons réalisé une étude dosimétrique plus approfondie pour mieux les comprendre. Nous discuterons des voies possibles pour optimiser ce traitement en s’appuyant notamment sur les études de RIV ayant montré de réels bénéfices pour les patients / Vectorized Radionuclide Therapy allows a more elective systemic irradiation of metastatic cancer lesions. We are reporting a first in human phase I study set up at the Léon Bérard Cancer Centre for the treatment of patients with synovialosarcoma metastases. Following a theranostic scheme, an imaging and dosimetry step was performed to study the biodistribution of the diagnostic radiopharmaceutical (DRP) companion of the therapeutic radiopharmaceutical (TRP). In case of favorable biodistribution (tumor uptake greater that surrounding healthy organs tracer uptake) allowing IVR to be considered with a tumoricidal effect while limiting the side effects of irradiated healthy tissues, patients received the TRP. A total of 20 patients were included. Ten of them were eligible for the therapeutic phase: 2 could not be treated due to disease progression and 8 were treated, including 1 patient who received a 2nd injection after disease stabilization. The side effects were mainly hematological. Treatment responses were transient stabilizations. In response to these modest results, we conducted a more in-depth dosimetric study to better understand them. We will discuss possible ways to optimize this treatment, based in particular on RIV studies that have shown real benefits for patients
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