Your search keyword '"Llombart-Bosch Antonio"' showing total 22 results

1. Sarcomas with EWSR1::Non-ETS Fusion (EWSR1::NFATC2 and EWSR1::PATZ1).

Author

Machado I, Llombart-Bosch A, Charville GW, Navarro S, Domínguez Franjo MP, Bridge JA, and Linos K

Subjects

Humans, Transcription Factors, Prognosis, Biomarkers, Tumor genetics, Repressor Proteins genetics, Kruppel-Like Transcription Factors genetics, NFATC Transcription Factors genetics, RNA-Binding Protein EWS genetics, Sarcoma diagnosis, Sarcoma genetics, Sarcoma pathology

Abstract

The wide application of increasingly advanced molecular studies in routine clinical practice has allowed a detailed, albeit still incomplete, genetic subclassification of undifferentiated round cell sarcomas. The WHO classification continues to include provisional molecular entities, whose clinicopathologic features are in the early stages of evolution. This review focuses on the clinicopathologic, molecular, and prognostic features of undifferentiated round cell sarcomas with EWSR1/FUS::NFATC2 or EWSR1::PATZ1 fusions. Classic histopathologic findings, uncommon variations, and diagnostic pitfalls are addressed, along with the utility of recently developed immunohistochemical and molecular markers., (Copyright © 2023 Elsevier Inc. All rights reserved.)

Published

2024

2. Intimal Sarcoma with MDM2/CDK4 Amplification and p16 Overexpression: A Review of Histological Features in Primary Tumor and Xenograft, with Immunophenotype and Molecular Profiling.

Author

Giner F, Machado I, Rubio-Martínez LA, López-Guerrero JA, Claramunt-Alonso R, Navarro S, Ferrández A, Mayordomo-Aranda E, and Llombart-Bosch A

Subjects

Humans, Heterografts, Proto-Oncogene Proteins B-raf genetics, Proto-Oncogene Proteins p21(ras) genetics, Mutation, Receptor Protein-Tyrosine Kinases metabolism, Proto-Oncogene Proteins c-mdm2 genetics, Proto-Oncogene Proteins c-mdm2 metabolism, Gene Amplification, Biomarkers, Tumor genetics, Biomarkers, Tumor analysis, Cyclin-Dependent Kinase 4 genetics, Cyclin-Dependent Kinase 4 metabolism, Sarcoma pathology, Soft Tissue Neoplasms genetics

Abstract

Intimal sarcomas (IS) are rare malignant mesenchymal tumors arising in large blood vessels of the systemic and pulmonary circulation and also in the heart. They are morphologically similar to other spindle cell, poorly differentiated sarcomas. The prognosis is poor and depends mainly on surgical options. Three cases of IS were collected from two institutions. Clinical data were retrieved and histological study was performed. A wide immunohistochemical panel was analyzed. FISH of MDM2 gene was performed, and a molecular study with NGS was implemented in all cases. The mean age of our cases was 54 years. Histologically, the tumors presented a diffuse growth pattern with heterogeneous atypical epithelioid or spindle cells and extensive thrombosed areas. All cases presented intense immunoexpression for MDM2, CDK4, CD117, c-myc, PDGFRA, and p16. PDGFRA, HTERT, and pan-TRK gained expression, while p16 lost intensity, being weaker in both the local recurrences and xenografts. The three cases showed amplification of MDM2 by FISH. NGS analysis revealed amplifications in the CDK4 , PDGFRA , and KIT genes, together with BRAF mutation and KRAS amplification. P16 was expressed in all cases, losing intensity in local recurrence and xenografts. Two new alterations, a BRAF mutation and a KRAS amplification, were detected by NGS in different tumors, opening up new therapeutic options for these patients.

Published

2023

3. Extraskeletal myxoid chondrosarcoma: p53 and Ki-67 offer prognostic value for clinical outcome - an immunohistochemical and molecular analysis of 31 cases.

Author

Giner F, López-Guerrero JA, Machado I, Rubio-Martínez LA, Espino M, Navarro S, Agra-Pujol C, Ferrández A, and Llombart-Bosch A

Subjects

Humans, Ki-67 Antigen metabolism, Tumor Suppressor Protein p53 genetics, Prognosis, Margins of Excision, Repressor Proteins metabolism, Chondrosarcoma genetics, Sarcoma pathology, Soft Tissue Neoplasms

Abstract

Extraskeletal myxoid chondrosarcoma (EMC) is a rare malignant soft tissue tumor of unpredictable clinical behavior. The morphological spectrum of EMC based on histology alone can be difficult. There is no precise immunohistochemical (IHC) profile that together with the clinical parameters is able to predict the clinical outcome. We studied 31 cases confirmed as EMC. Clinical and follow-up data were recorded. Histopathological, molecular, and IHC studies were performed. Association among histopathological parameters was assessed using a chi-square test to determine homogeneity or linear trend for ordinal variables. The Kaplan-Meier proportional risk test (log rank) was used to study the impact of the histological, IHC, and molecular factors on progression-free survival (PFS) and disease-specific survival (DSS). Most EMCs showed a typical architectural pattern. Only a few cases presented an atypical histology (higher cellularity and solid pattern). IHC positivity (focal or diffuse) was present for CDK4 (100%), STAT-6 (90%), CD117 (84%), HNK-1 (81%), SATB2 (68%), and S-100 (58%). Synaptophysin and INSM1 were expressed in 22.6% and 38.7% of cases respectively. The EWSR1::NR4A3 rearrangement was found in 19 cases and 7 tumors presented the TAF15::NR4A3 fusion. Positive surgical margins together with atypical histology and expression of p53 and Ki67 correlated with worse clinical prognosis. EMCs express several IHC markers which are also seen in other soft tissue sarcomas. The molecular detection of NR4A3 rearrangement supports the differential diagnosis. Positive surgical margins together with atypical histology and positive expression of p53 and Ki-67 seem to predict a poor clinical outcome with worse prognosis, increased rate of recurrence, metastasis, and poor overall survival., (© 2022. The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature.)

Published

2023

4. Ki-67 immunoexpression and radiological assessment of necrosis improves accuracy of conventional and modified core biopsy systems in predicting the final grade assigned to adult-soft tissue sarcomas. An international collaborative study.

Author

Machado I, Cruz J, Righi A, Gambarotti M, Ferrari C, Ruengwanichayakun P, Giner F, Rausell N, Lavernia J, Sugita S, Najera L, Suarez L, Sanjuan X, García JAN, García Del Muro FJ, Gómez-Mateo MC, Valladares MM, Ramos-Oliver I, Romagosa C, Parafioriti A, Elisabetta A, di Bernardo A, Navarro S, Hasegawa T, Arana E, and Llombart-Bosch A

Subjects

Adult, Biomarkers, Tumor metabolism, Biopsy, Large-Core Needle, Female, Humans, Male, Necrosis metabolism, Necrosis pathology, Retrospective Studies, Sarcoma pathology, Soft Tissue Neoplasms pathology, Ki-67 Antigen metabolism, Sarcoma metabolism, Soft Tissue Neoplasms metabolism

Abstract

Based on the French Federation Nationale des Centers de Lutte Contre le Cancer (FNCLCC) grading system, this study assesses the accuracy of conventional and modified core biopsy (CB) systems in predicting the final grade (low vs high) assigned to the resected specimen. Substituting Ki-67 immunoexpression for mitotic count, and radiological for histological assessment of necrosis, we used two modified FNCLCC CB grading systems: (1) Ki-67 immunoexpression alone, and (2) Ki-67 plus radiological assessment of necrosis. We graded 199 soft tissue sarcomas (STS) from nine centers, and compared the results for the conventional (obtained from local histopathology reports) and modified CB systems with the final FNCLCC grading of the corresponding resected specimens. Due to insufficient sample quality or lack of available radiologic data, five cases were not evaluated for Ki67 or radiological assessment of necrosis. The conventional FNCLCC CB grading system accurately identified 109 of the 130 high-grade cases (83.8%). The CB grading matched the final FNCLCC grading (low vs high) in 175 (87.9%) of the 199 resected tumors; overestimating the final grade in three cases and underestimating in 21 cases. Modified system 1 (Ki-67) accurately identified 117 of the 130 high-grade cases (90.0%). The CB grading matched the final FNCLCC grading (low vs high) in 175 (89.7%) of the 195 evaluated cases; overestimating seven and underestimating 13 cases. Modified system 2 (Ki-67 plus radiological necrosis) accurately identified 120 of the 130 high-grade cases (92.3%). This last matched the final FNCLCC grading (low vs high) in 177 (91.2%) of the 194 evaluated cases; overestimating seven and underestimating 10 cases. Modified system 2 obtained highest area under ROC curves, although not statistically significant. Underestimated CB grades did not correlate with histological subtypes, although many of the discrepant cases were myxoid tumors (myxofibrosarcomas or myxoid liposarcomas), leiomyosarcomas or undifferentiated pleomorphic/spindle cell sarcomas. Using modified FNCLCC CB grading systems to replace conventional mitotic count and histologic assessment of necrosis may improve the distinction between low and high-grade STS on CB. Our study confirms that classifying grade 1 as low grade and grades 2 and 3 as high grade improves correlation between CB and final grade by up to 21%, irrespective of CB system used. A higher than expected Ki-67 score in a low-grade sarcoma diagnosed on CB should raise concern that a higher-grade component may not have been sampled. Furthermore, correlation of all clinicopathological and radiological findings at multidisciplinary meetings is essential to assess the histological grade on CB as accurately as possible., (Copyright © 2021 Elsevier GmbH. All rights reserved.)

Published

2021

5. Ewing sarcoma and the new emerging Ewing-like sarcomas: (CIC and BCOR-rearranged-sarcomas). A systematic review.

Author

Machado I, Navarro S, and Llombart-Bosch A

Subjects

Animals, Humans, Sarcoma pathology, Sarcoma, Ewing pathology, Cyclin B genetics, Oncogene Proteins, Fusion genetics, Proto-Oncogene Proteins genetics, Repressor Proteins genetics, Sarcoma genetics, Sarcoma, Ewing genetics

Abstract

Ewing-like sarcomas (ELS) are a heterogenous group of tumors that frequently affect pediatric and young adult patients. Accurate classification and distinction from the Ewing sarcoma family of tumor (ESFT) is decisive in patient management. ELS share a significant morphologic, immunohistochemical and clinical overlap with ESFT, thus the differential diagnosis is challenging, especially with atypical ESFT and tumors with unusual immunoprofiles or uncommon clinicoradiological findings. A subset of ELS harboring the CIC-DUX4 or BCOR-CCNB3 fusions has been described recently. The spectrum of ELS is now expanding, and additional gene fusion partners besides DUX4 or CCNB3 have been detected, and the terms CIC or BCOR-rearranged sarcomas have recently been proposed. We review the clinical, histological, phenotypic and molecular findings of ESFT and these new emerging ELS.

Published

2016

6. Soft tissue myoepithelial carcinoma with rhabdoid-like features and EWSR1 rearrangement: Fine needle aspiration cytology with histologic correlation.

Author

Machado I, López-Soto MV, Rubio L, Navarro L, and Llombart-Bosch A

Subjects

Abdominal Neoplasms genetics, Abdominal Neoplasms pathology, Abdominal Neoplasms surgery, Abdominal Wall pathology, Abdominal Wall surgery, Aged, Biomarkers, Tumor genetics, Biopsy, Fine-Needle, Chondrosarcoma genetics, Chondrosarcoma pathology, Chondrosarcoma surgery, Diagnosis, Differential, Humans, Immunohistochemistry, Male, Myoepithelioma genetics, Myoepithelioma pathology, Myoepithelioma surgery, Neoplasm Proteins genetics, Neoplasms, Connective and Soft Tissue genetics, Neoplasms, Connective and Soft Tissue pathology, Neoplasms, Connective and Soft Tissue surgery, Rhabdoid Tumor genetics, Rhabdoid Tumor pathology, Rhabdoid Tumor surgery, Sarcoma genetics, Sarcoma pathology, Sarcoma surgery, Soft Tissue Neoplasms genetics, Soft Tissue Neoplasms pathology, Soft Tissue Neoplasms surgery, Abdominal Neoplasms diagnosis, Chondrosarcoma diagnosis, Myoepithelioma diagnosis, Neoplasms, Connective and Soft Tissue diagnosis, Rhabdoid Tumor diagnosis, Sarcoma diagnosis, Soft Tissue Neoplasms diagnosis

Abstract

A new case of soft tissue myoepithelial carcinoma (MEC) with rhabdoid-like differentiation is presented including cytologic, histopathologic, immunohistochemical, and molecular biologic features. A 45-year-old woman was admitted to the Hospital with nodular mass involving the lower part of the abdominal wall. Fine-needle aspiration cytology showed a round cell tumor with abundant cytoplasm in the myxoid background. The nuclei were uniform, round to ovoid, with finely distributed chromatin, nucleoli, and pale, vacuolated, or eosinophilic cytoplasm with rhabdoid-like appearance resembling a soft tissue malignant rhabdoid tumor. The surgically removed tumor was poorly demarcated, yellow, soft, and myxoid. The histopathology revealed sheets of poorly differentiated round malignant cells with focal myxoid stroma and rhabdoid-like morphology. Immunohistochemistry showed positivity for CK (AE1/AE3), EMA, S100, vimentin, CD99, and SMA; however desmin, CD34, and gliofibrilar acid protein (GFAP) were negative. Tumor cells revealed loss of INI1 expression. The EWSR1 gene rearrangement was detected by fluorescence in situ hybridization (FISH), but molecular biology failed to detect EWSR1/ETS, EWSR1/NR4A3, EWSR1/DDIT3, EWSR1/ATF1, EWSR1-POU5F1, EWSR1/ZNF444, EWSR1-PBX1 gene fusions. The final diagnosis was soft tissue malignant myoepithelioma with rhabdoid changes and EWSR1 gene rearrangement. The differential diagnosis included soft tissue malignant rhabdoid tumor, cellular extraskeletal myxoid chondrosarcoma, proximal epithelioid sarcoma, and other soft tissue tumor with EWSR1 rearrangement. To our knowledge, this is the first case of MEC with rhabdoid features and description of fine-needle aspiration cytology., (© 2015 Wiley Periodicals, Inc.)

Published

2015

7. Immunoreactivity using anti-ERG monoclonal antibodies in sarcomas is influenced by clone selection.

Author

Machado I, Mayordomo-Aranda E, Scotlandi K, Picci P, and Llombart-Bosch A

Subjects

Brain Neoplasms metabolism, Brain Neoplasms pathology, Gastrointestinal Stromal Tumors metabolism, Gastrointestinal Stromal Tumors pathology, Humans, Kidney Neoplasms metabolism, Kidney Neoplasms pathology, Retrospective Studies, Rhabdoid Tumor metabolism, Rhabdoid Tumor pathology, Sarcoma metabolism, Sarcoma pathology, Sensitivity and Specificity, Transcriptional Regulator ERG, Antibodies, Monoclonal, Brain Neoplasms diagnosis, Gastrointestinal Stromal Tumors diagnosis, Immunohistochemistry methods, Kidney Neoplasms diagnosis, Rhabdoid Tumor diagnosis, Sarcoma diagnosis, Trans-Activators metabolism

Abstract

The aim of the present study was to explore ERG immunoreactivity in a series of sarcomas, GIST and malignant rhabdoid tumor (MRT), considering the not fully elucidated specificity and sensitivity of this antibody. Paraffin-embedded tissue microarrays from those tumors were stained with anti-ERG against the C-terminus [(EPR3864(2)] and N-terminus (Clone 9FY). EPR3864(2) was positive in almost all angiosarcomas, and MRT.GIST were positive in a large proportion of cases (38.4%), and more than half the synovial sarcomas (52.7%) revealed EPR3864(2) staining. Several chondrosarcomas, osteosarcomas, rhabdomyosarcoma and Ewing's sarcoma family of tumors (ESFT) presented EPR3864(2) expression in a lower number of cases. 9FY was positive in most of the angiosarcomas; however, only sporadic ESFT and synovial sarcoma were positive and the other tumors tested were negative. Fourteen ESFT with EWSR1/Fli-1 gene fusion presented positive nuclear staining for EPR3864(2). Similarly, 5 ESFT with EWSR1/Fli-1 gene fusion presented positive staining for 9FY. We must stress that the difference between the present and previous studies may be due to the source of the anti-ERG employed, anti-ERG against C or N-terminus, protein cross-reactivity and dilution. In conclusion, specificity for ERG staining in sarcomas should be considered with caution and the immunoexpression is undoubtedly influenced by clone and antibody selection., (Copyright © 2014 Elsevier GmbH. All rights reserved.)

Published

2014

8. Tumor response assessment by modified Choi criteria in localized high-risk soft tissue sarcoma treated with chemotherapy.

Author

Stacchiotti S, Verderio P, Messina A, Morosi C, Collini P, Llombart-Bosch A, Martin J, Comandone A, Cruz J, Ferraro A, Grignani G, Pizzamiglio S, Quagliuolo V, Picci P, Frustaci S, Dei Tos AP, Casali PG, and Gronchi A

Subjects

Humans, Probability, Prognosis, Proportional Hazards Models, Retrospective Studies, Risk, Sarcoma mortality, Sarcoma pathology, Sarcoma drug therapy

Abstract

Background: The objective of this study was to compare the prognostic relevance of Response Evaluation Criteria in Solid Tumors (RECIST) versus Choi criteria for the assessment of response in patients with high-risk soft tissue sarcoma of the extremities or trunk wall who received preoperative chemotherapy with or without radiotherapy in a phase 3 trial., Methods: Patients received 3 cycles of preoperative epirubicin + ifosfamide with or without radiotherapy. The diagnostic concordance between RECIST and Choi criteria and their correlation with overall survival (OS) and freedom from progression (FFP) were evaluated in a univariate Cox regression model., Results: In 243 of 321 eligible patients, RECIST, Choi criteria, and histology were predictive for OS and FFP. In the subgroup of 69 patients who received chemotherapy alone and were evaluable by both RECIST and Choi criteria, Choi criteria were associated significantly with OS and FFP, whereas RECIST predicted only FFP, and the pattern of agreement observed between the 2 criteria was unsatisfactory. On a dichotomous scale, comparing objective response (complete and partial responses) and lack of response (stable and progressive disease) to preoperative chemotherapy according to RECIST and Choi criteria, only Choi criteria were predictive of OS and FFP, and fair agreement between RECIST and Choi criteria was observed. When lack of progression and progression were compared (complete and partial responses + stable disease vs progressive disease), both assessment criteria were significantly predictive of OS and FFP, and there was substantial agreement between the 2 criteria., Conclusions: Response to chemotherapy with or without radiotherapy was associated with a better outcome in patients with high-risk soft tissue sarcoma. Choi criteria were better predictors than RECIST in patients who received preoperative chemotherapy alone., (Copyright © 2012 American Cancer Society.)

Published

2012

9. Preclinical xenograft models of human sarcoma show nonrandom loss of aberrations.

Author

Kresse SH, Meza-Zepeda LA, Machado I, Llombart-Bosch A, and Myklebost O

Subjects

Adolescent, Adult, Aged, Animals, Child, Chromosome Aberrations, Comparative Genomic Hybridization, Female, Humans, Male, Mice, Mice, SCID, Middle Aged, Neoplasm Transplantation, Disease Models, Animal, Sarcoma genetics, Transplantation, Heterologous

Abstract

Background: Human tumors transplanted into immunodeficient mice (xenografts) are good preclinical models, and it is important to identify possible systematic changes during establishment and passaging in mice., Methods: High-resolution microarray-based comparative genomic hybridization (array CGH) was used to investigate how well a series of sarcoma xenografts, including 9 patient/xenograft pairs and 8 early versus late xenograft passage pairs, represented the patient tumor from which they originated., Results: In all analyses, the xenografts were more similar to their tumor of origin than other xenografts of the same type. Most changes in aberration patterns were toward a more normal genome complement, and the increased aberrations observed were mostly toward more loss. In general, the changes were scattered over the genome, but some changes were significant in osteosarcomas. These were rather focused and consistent with amplifications frequent in patient samples, involving the genes platelet-derived growth factor receptor A (PDGFRA), cysteine-rich hydrophobic domain 2 (CHIC2), FIP-like 1 (FIP1L1), ligand of numb-protein X1 (LNX1), RAS-like family 11 member B (RASL11B), and sec1 family domain containing 2 (SCFD2), probably a sign of continued tumor progression. Some changes that disappeared may have been involved in host-stroma interactions or chemotherapy resistance, possibly because of the absence of selection in the mouse., Conclusions: Direct xenografts reflected well the genomic patterns of their tumors of origin. The few significant aberrations that were lost during passaging in immune-defective mice may have been caused by the lack of selection in the new host, whereas aberrations that were gained appeared to be the result of general tumor progression rather than model-specific artifacts., (Copyright © 2011 American Cancer Society.)

Published

2012

10. Pleomorphic hyalinizing angiectatic tumor: a report of 3 new cases, 1 with sarcomatous myxofibrosarcoma component and another with unreported soft tissue palpebral location.

Author

Illueca C, Machado I, Cruz J, Almenar S, Noguera R, Navarro S, and Llombart-Bosch A

Subjects

Adult, Antigens, Neoplasm biosynthesis, Chromosomes, Human, Pair 22 genetics, Female, Humans, Immunohistochemistry methods, Middle Aged, Polyploidy, Fibroma genetics, Fibroma metabolism, Fibroma pathology, Hyalin metabolism, Sarcoma genetics, Sarcoma metabolism, Sarcoma pathology, Soft Tissue Neoplasms genetics, Soft Tissue Neoplasms metabolism, Soft Tissue Neoplasms pathology

Abstract

Pleomorphic hyalinizing angiectatic tumor (PHAT) is an uncommon soft tissue tumor usually located in extremities or trunk. We report 3 new cases with histopathologic diagnosis of PHAT, one with recurrence and sarcomatous myxofibrosarcoma component and another with unreported soft tissue palpebral location. Clinical data, histopathology, immunohistochemistry, fluorescence in situ hybridization, and follow-up data are described. The histopathology showed a tumor with angiectatic blood vessel proliferation and perivascular hyaline material associated with focal pleomorphic cells. The recurrent tumor revealed a histopathologic pattern corresponding to a myxofibrosarcoma. Vimentin and CD99 were positive in tumor cells and CD34 was strongly positive in the tumor cells from the recurrence. Ki-67 was poor positive but with increased positivity in the recurrence. The positivity of p53 and chromosome 22 polysomy were detected in the recurrence. At present, the 3 patients are free of disease and no metastases have been detected. Indeed, the possibility that PHAT may represent a histopathologic pattern and not a true neoplastic entity with specific genetic alterations cannot be excluded at present, and further studies are required.

Published

2012

11. Pulmonary artery sarcoma with angiosarcoma phenotype mimicking pleomorphic malignant fibrous histiocytoma: a case report

Author

Bohn Olga L, de León Eric, Lezama Oscar, Rios-Luna Nina P, Sánchez-Sosa Sergio, and Llombart-Bosch Antonio

Subjects

Pulmonary artery, Sarcoma, Angiosarcoma, Immunohistochemistry, Pathology, RB1-214

Abstract

Abstract Primary sarcomas of the major blood vessels can be classified based on location in relationship to the wall or by histologic type. Angiosarcomas are malignant neoplasms that arise from the endothelial lining of the blood vessels; those arising in the intimal compartment of pulmonary artery are rare. We report a case of pulmonary artery angiosarcoma in a 36-year old female with pulmonary masses. The patient had no other primary malignant neoplasm, thus excluding a metastatic lesion. Gross examination revealed a thickened right pulmonary artery and a necrotic and hemorrhagic tumor, filling and occluding the vascular lumen. The mass extended distally, within the pulmonary vasculature of the right lung. Microscopically, an intravascular undifferentiated tumor was identified. The tumor cells showed expression for vascular markers VEGFR, VEGFR3, PDGFRa, FGF, Ulex europaeus, FVIII, FLI-1, CD31 and CD34; p53 was overexpressed and Ki67 proliferative rate was increased. Intravascular angiosarcomas are aggressive neoplasms, often associated with poor outcome. Virtual slide The virtual slide(s) for this article can be found here: http://www.diagnosticpathology.diagnomx.eu/vs/2315906377648045.

Published

2012

12. miR-486-5p expression is regulated by DNA methylation in osteosarcoma

Author

Namløs, Heidi M., Skårn, Magne, Ahmed, Deeqa, Grad, Iwona, Andresen, Kim, Kresse, Stine H., Munthe, Else, Serra, Massimo, Scotlandi, Katia, Llombart-Bosch, Antonio, Myklebost, Ola, Lind, Guro E., and Meza-Zepeda, Leonardo A.

Published

2022

13. The genomic landscape of the Ewing Sarcoma family of tumors reveals recurrent STAG2 mutation.

Author

Brohl, Andrew S, Solomon, David A, Chang, Wendy, Wang, Jianjun, Song, Young, Sindiri, Sivasish, Patidar, Rajesh, Hurd, Laura, Chen, Li, Shern, Jack F, Liao, Hongling, Wen, Xinyu, Gerard, Julia, Kim, Jung-Sik, Lopez Guerrero, Jose Antonio, Machado, Isidro, Wai, Daniel H, Picci, Piero, Triche, Timothy, Horvai, Andrew E, Miettinen, Markku, Wei, Jun S, Catchpool, Daniel, Llombart-Bosch, Antonio, Waldman, Todd, and Khan, Javed

Subjects

Cell Line, Tumor, Humans, Neoplasm Proteins, Antigens, Nuclear, Disease-Free Survival, Gene Deletion, Mutation, Genome, Human, Adolescent, Adult, Child, Child, Preschool, Infant, Female, Male, High-Throughput Nucleotide Sequencing, Sarcoma, Ewing, Antigens, Nuclear, Cell Line, Tumor, Preschool, Genome, Human, Sarcoma, Ewing, Genetics, Developmental Biology

Abstract

The Ewing sarcoma family of tumors (EFT) is a group of highly malignant small round blue cell tumors occurring in children and young adults. We report here the largest genomic survey to date of 101 EFT (65 tumors and 36 cell lines). Using a combination of whole genome sequencing and targeted sequencing approaches, we discover that EFT has a very low mutational burden (0.15 mutations/Mb) but frequent deleterious mutations in the cohesin complex subunit STAG2 (21.5% tumors, 44.4% cell lines), homozygous deletion of CDKN2A (13.8% and 50%) and mutations of TP53 (6.2% and 71.9%). We additionally note an increased prevalence of the BRCA2 K3326X polymorphism in EFT patient samples (7.3%) compared to population data (OR 7.1, p = 0.006). Using whole transcriptome sequencing, we find that 11% of tumors pathologically diagnosed as EFT lack a typical EWSR1 fusion oncogene and that these tumors do not have a characteristic Ewing sarcoma gene expression signature. We identify samples harboring novel fusion genes including FUS-NCATc2 and CIC-FOXO4 that may represent distinct small round blue cell tumor variants. In an independent EFT tissue microarray cohort, we show that STAG2 loss as detected by immunohistochemistry may be associated with more advanced disease (p = 0.15) and a modest decrease in overall survival (p = 0.10). These results significantly advance our understanding of the genomic and molecular underpinnings of Ewing sarcoma and provide a foundation towards further efforts to improve diagnosis, prognosis, and precision therapeutics testing.

Published

2014

14. Soft Tissue Sarcomas with Chromosomal Alterations in the 12q13-15 Region: Differential Diagnosis and Therapeutic Implications.

Author

Lavernia, Javier, Claramunt, Reyes, Romero, Ignacio, López-Guerrero, José Antonio, Llombart-Bosch, Antonio, and Machado, Isidro

Subjects

ONCOGENES, IMMUNOHISTOCHEMISTRY, DIFFERENTIAL diagnosis, SOFT tissue tumors, GENE amplification, SARCOMA, LIPOSARCOMA

Abstract

Simple Summary: The chromosomal region 12q13-15 is rich in oncogenes (MDM2, CDK4, STAT6, DDIT3, and GLI1). Amplification of MDM2 and CDK4 genes can be detected in various mesenchymal and nonmesenchymal neoplasms. Therefore, gene amplification alone is not entirely specific for making a definitive diagnosis and requires the integration of clinical, radiological, morphological, and immunohistochemical findings. Despite the diagnostic implications that the overlap of genetic alterations in neoplasms with changes in genes within the 12q13-15 region could create, the discovery of coamplifications of MDM2 with CDK4 and GLI1 offers new therapeutic targets in neoplasms with MDM2/CDK4 amplification. In this review, we delve into the diagnosis and therapeutic implications of neoplasms with genetic alterations involving the chromosomal region 12q13-15, mainly MDM2, CDK4, and GLI1. The chromosomal region 12q13-15 is rich in oncogenes and contains several genes involved in the pathogenesis of various mesenchymal neoplasms. Notable genes in this region include MDM2, CDK4, STAT6, DDIT3, and GLI1. Amplification of MDM2 and CDK4 genes can be detected in various mesenchymal and nonmesenchymal neoplasms. Therefore, gene amplification alone is not entirely specific for making a definitive diagnosis and requires the integration of clinical, radiological, morphological, and immunohistochemical findings. Neoplasms with GLI1 alterations may exhibit either GLI1 rearrangements or amplifications of this gene. Despite the diagnostic implications that the overlap of genetic alterations in neoplasms with changes in genes within the 12q13-15 region could create, the discovery of coamplifications of MDM2 with CDK4 and GLI1 offers new therapeutic targets in neoplasms with MDM2/CDK4 amplification. Lastly, it is worth noting that MDM2 or CDK4 amplification is not exclusive to mesenchymal neoplasms; this genetic alteration has also been observed in other epithelial neoplasms or melanomas. This suggests the potential use of MDM2 or CDK4 inhibitors in neoplasms where alterations in these genes do not aid the pathological diagnosis but may help identify potential therapeutic targets. In this review, we delve into the diagnosis and therapeutic implications of tumors with genetic alterations involving the chromosomal region 12q13-15, mainly MDM2, CDK4, and GLI1. [ABSTRACT FROM AUTHOR]

Published

2024

15. Malignant PEComa With Metastatic Disease at Diagnosis and Resistance to Several Chemotherapy Regimens and Targeted Therapy (m-TOR Inhibitor).

Author

Machado, Isidro, Cruz, Julia, Lavernia, Javier, Rayon, José M., Poveda, Andrés, and Llombart-Bosch, Antonio

Subjects

CELL tumors, EPITHELIAL cells, HISTOLOGY, IMMUNOHISTOCHEMISTRY, TUMOR diagnosis

Abstract

Perivascular epithelioid cell tumors (PEComas) are infrequent neoplasms with peculiar myomelanocytic differentiation. The aggressive abdominopelvic variant is rare, with only a small number of published cases. We present an additional case of this unusual variant, which showed an aggressive histologic and clinical behavior with multiple liver metastases and resistance to several therapies. We also discuss the histological and immunohistochemical profiles as well as the differential diagnosis. [ABSTRACT FROM AUTHOR]

Published

2017

16. Reexpression of LSAMP inhibits tumor growth in a preclinical osteosarcoma model.

Author

Barøy, Tale, Kresse, Stine H., Skårn, Magne, Stabell, Marianne, Castro, Russell, Lauvrak, Silje, Llombart-Bosch, Antonio, Myklebost, Ola, and Meza-Zepeda, Leonardo A.

Subjects

SARCOMA, OSTEOSARCOMA, GENE expression, CELL lines, APOPTOSIS

Abstract

Background Osteosarcomas are the most common primary malignant tumors of bone, showing complex chromosomal rearrangements with multiple gains and losses. A frequent deletion within the chromosomal region 3q13.31 has been identified by us and others, and is mainly reported to be present in osteosarcomas. The purpose of the study was to further characterize the frequency and the extent of the deletion in an extended panel of osteosarcoma samples, and the expression level of the affected genes within the region. We have identified LSAMP as the target gene for the deletion, and have studied the functional implications of LSAMPreexpression. Methods LSAMP copy number, expression level and protein level were investigated by quantitative PCR and western blotting in an osteosarcoma panel. The expression of LSAMP was restored in an osteosarcoma cell line, and differences in proliferation rate, tumor formation, gene expression, migration rate, differentiation capabilities, cell cycle distribution and apoptosis were investigated by metabolic dyes, tumor formation in vivo, gene expression profiling, time-lapse photography, differentiation techniques and flow cytometry, respectively. Results We found reduced copy number of LSAMP in 45/76 osteosarcoma samples, reduced expression level in 25/42 samples and protein expression in 9/42 samples. By restoring the expression of LSAMP in a cell line with a homozygous deletion of the gene, the proliferation rate in vitro was significantly reduced and tumor growth in vivo was significantly delayed. In response to reexpression of LSAMP, mRNA expression profiling revealed consistent upregulation of the genes hairy and enhancer of split 1 (HES1), cancer/testis antigen 2 (CTAG2) and kruppel-like factor 10 (KLF10). Conclusions The high frequency and the specificity of the deletion indicate that it is important for the development of osteosarcomas. The deletion targets the tumor suppressor LSAMP, and based on the functional evidence, the tumor suppressor function of LSAMP is most likely exerted by reducing the proliferation rate of the tumor cells, possibly by indirectly upregulating one or more of the genes HES1, CTAG2 or KLF10. To our knowledge, this study describes novel functions of LSAMP, a first step to understanding the functional role of this specific deletion in osteosarcomas. [ABSTRACT FROM AUTHOR]

Published

2014

17. Immunohistochemical Study of Correlation Between Histologic Subtype and Expression of Epithelial-Mesenchymal Transition-Related Proteins in Synovial Sarcomas.

Author

Subramaniam, Manish Mani, Navarro, Samuel, and Llombart-Bosch, Antonio

Subjects

*PROTEIN metabolism, *IMMUNOHISTOCHEMISTRY, *ANTIGENS, *CELL physiology, *CHI-squared test, *FISHER exact test, *GLYCOPROTEINS, *PROBABILITY theory, *RESEARCH funding, *SARCOMA, *TUMOR markers, *PHENOTYPES, *DATA analysis software, *TISSUE arrays, *DIAGNOSIS

Abstract

Context.--Synovial sarcomas are mesenchymal tumors with epithelial nature and comprise biphasic and monophasic fibrous subtypes. However, factors determining epithelial or spindle cell differentiation are still unexplored. Aberrant epithelial-mesenchymal transition has been implicated in the pathogenesis of diverse human malignancies. Objective.--To analyze the correlation between cellular phenotype and expression of proteins associated with different epithelial-mesenchymal transition-related pathways. Design.--Immunohistochemical analysis of E-cadherin, Snail, Slug, and dysadherin, components of the Wnt/wingless and PI3K/Akt pathways, was performed on 14 biphasic and 27 monophasic fibrous tumors. Results.--In monophasic fibrous tumors, increased expression of Snail (17 of 27; 63%), Slug (18 of 27; 67%), and dysadherin (14 of 27; 52%) and activation of Wnt (nucleocytoplasmic β-catenin accumulation in 63%; n = 27; and positive expression of GSK3 and pGSK3 in 24 of 27 [89%] and 21 of 27 [78%], respectively) and PI3K/Akt (Akt: 22 of 27 [81%]; pAkt: 25 of 27 [93%]; and PI3K: 20 of 27 [74%]) signaling correlated significantly with inactivated Ecadherin expression (1 of 27; 4%) (all P < .05). In contrast, preserved E-cadherin expression (12 of 14; 86%) in the glandular component of the biphasic subtype was associated with significantly decreased Snail (3 of 14; 21%) (P = .02) and dysadherin (2 of 14; 14%) expression (P < .001). Conclusions.--Overexpression of Snail, Slug, and dysadherin and activation of Wnt and PI3K/Akt signaling was associated with inactivated E-cadherin in the spindle cells of monophasic fibrous synovial sarcomas, further supporting the hypothesis that this subtype may have developed through neoplastic epithelial-mesenchymal transition. [ABSTRACT FROM AUTHOR]

Published

2011

18. Immunohistochemical analysis of NKX2.2, ETV4, and BCOR in a large series of genetically confirmed Ewing sarcoma family of tumors.

Author

Machado, Isidro, Yoshida, Akihiko, López-Guerrero, José Antonio, Nieto, María Gema, Navarro, Samuel, Llombart-Bosch, Antonio, and Picci, Piero

Subjects

*IMMUNOHISTOCHEMISTRY, *TUMORS, *SARCOMA, *BONES, *CANCER chemotherapy, *PEDIATRICS, *PATIENTS

Abstract

Ewing sarcoma is an aggressive neoplasm of pediatric and adolescent patients. Immunohistochemistry (IHC) can be used to support the morphologic diagnosis of Ewing sarcoma family of tumors (ESFT) in a convincing clinical/radiological context. Although neither NKX2.2 nor CD99 alone are entirely specific, when combined, the diagnostic specificity is high. The aim of the present study was to investigate the IHC expression of NKX2.2, ETV4 and BCOR in a large series of genetically confirmed ESFT. The results for CD99 and CAV-1 immunoreactivity, and the histological and fusion gene subtypes were retrieved from our previous study. NKX2.2 demonstrated moderate or strong nuclear positivity in 91.2% of the tumors. The staining intensity was heterogeneous. Many of the ESFT with negative NKX2.2 immunoreactivity were in bone. Strong/moderate ETV4 nuclear expression was detected in two small round cell tumors, both were negative for NKX2.2. No relationships could be found between expression of NKX2.2 and the histological subgroups or ESFT gene fusion subtypes. BCOR was negative in all ESFT. In conclusion, NKX2.2, ETV4 and BCOR IHC may be helpful in daily practice for distinguishing ESFT from CIC or BCOR -associated sarcomas, especially in hospitals without access to molecular assays. In addition, the combination of strong CD99 membranous positivity and nuclear NKX2.2 positivity seems to be very reliable for ESFT diagnosis in an appropriate clinicoradiological setting. So far no antibody is entirely specific for ESFT diagnosis, and the IHC or molecular results in round cell tumors of bone may be strongly influenced by decalcification processes. [ABSTRACT FROM AUTHOR]

Published

2017

19. Ewing-like sarcoma with CIC-DUX4 gene fusion in a patient with neurofibromatosis type 1. A hitherto unreported association.

Author

Tardío, Juan C., Machado, Isidro, Navarro, Lara, Idrovo, Franklin, Sanz-Ortega, Julián, Pellín, Antonio, and Llombart-Bosch, Antonio

Subjects

*SARCOMA, *GENE fusion, *NEUROFIBROMATOSIS, *HISTOPATHOLOGY, *BRAIN cancer, *CANCER chemotherapy, *PATIENTS

Abstract

Sarcoma with CIC-DUX4 gene fusion is emerging as the most prevalent subset of Ewing-like undifferentiated small round cell sarcomas with around 50 cases published. We report hereby the case of a 40-year-old male who presented a CIC-DUX4 sarcoma in deep soft tissues in his thigh. He had been diagnosed with neurofibromatosis type 1 at age 19 and over the years underwent resection of multiple neural neoplasms, including two malignant peripheral nerve sheath tumors with classical spindle-cell histopathology. The CIC-DUX4 sarcoma was treated with surgical resection, radiation and chemotherapy, but lung and brain metastases developed and the patient died from the disease 14 months after diagnosis. This is the first case of sarcoma with CIC-DUX4 gene fusion reported in a patient with NF1. Whether this association is coincidental or CIC-DUX4 sarcomas could be related to NF1 remains to be clarified. Study of alternative molecular alterations in EWSR1 -negative undifferentiated small round cell sarcomas is clinically relevant, since CIC-DUX4 sarcomas seem to be a very aggressive subset with poor response to the presently used therapeutic regimens. [ABSTRACT FROM AUTHOR]

Published

2015

20. Cytogenetic and molecular findings related to rhabdomyosarcoma. An analysis of seven cases

Author

Gil-Benso, Rosario, López-Ginés, Concha, Carda, Carmen, López-Guerrero, JoséAntonio, Ferrer, Jaime, Pellín-Pérez, Antonio, and Llombart–Bosch, Antonio

Subjects

*RHABDOMYOSARCOMA, *SARCOMA

Abstract

Rhabdomyosarcoma (RMS) is the most common soft-tissue sarcoma in childhood. Histologically, it is subdivided histologically into two main subtypes: alveolar (ARMS) and embryonal (ERMS). ARMS is characterized by t(2;13)(q35;q14) or its variant t(1;13)(p36;q14), which fuse PAX3 and PAX7, respectively, with FKHR to produce chimeric genes. ERMS is frequently associated with loss of heterozygosity of 11p15.5. We investigated seven RMS (three ARMS and four ERMS) by means of cytogenetic, fluorescence in situ hybridization, and molecular analyses, including the study of the main genes implicated in the G1- to S-phase cell cycle transition, and correlated these studies with pathologic findings and clinical outcome. All tumors showed clonal, numerical, and structural chromosomal abnormalities. Two ARMS had the t(2;13)(q35;q14) and the third a PAX7/FKHR fusion, a cryptic t(1;13)(p36;q14), undetected by cytogenetic techniques, but revealed by reverse transcriptase polymerase chain reaction. One ERMS showed a der(11)t(3;11)(p21;p15) as a sole structural anomaly. Gene amplification was seen in four tumors, as double minutes or in the form of homogeneously staining regions. Overexpression of MYCN oncogene was found in two ARMS; N-myc DNA probe detected oncogene amplification located on the double minutes of these cases. Analysis of the regulatory genes responsible for G1- to S-phase transition showed a homozygous deletion of the 9p21 locus genes in a spindle-cell ERMS. [Copyright &y& Elsevier]

Published

2003

21. Estudio de la heterogeneidad fenotípica del sarcoma de Ewing en xenotrasplantes

Author

Mayordomo Aranda, Empar, Llombart Bosch, Antonio, Machado Puerto, Isidro, and Departament de Patologia

Subjects

sarcoma de ewing, sarcoma, inmunohistoquímica, UNESCO::CIENCIAS MÉDICAS, xenotrasplantes, TMA, CIENCIAS MÉDICAS [UNESCO], PDX

Abstract

Los Tumores de la Familia del Sarcoma de Ewing (TFSE) son neoplasias malignas de hueso y de partes blandas, poco frecuentes (entre el 6-8% de los tumores malignos primarios de hueso) y que afectan principalmente a pacientes en edad de crecimiento, adolescentes y adultos jóvenes (1, 2). El término engloba a tres tumores que durante años han sido considerados por separado por su morfología característica, pero que forman un espectro morfológico, de biología e histogénesis comunes (3). Dichos tumores son los Sarcomas de Ewing clásicos, los atípicos y los tumores neuroectodérmicos primitivos periféricos (PNET). Desde el punto de vista morfológico son neoplasias constituidas por células pequeñas, redondas y azules, de núcleos densos y escaso citoplasma, pudiendo ser éste eosinófilo o claro, debido a la presencia de glucógeno PAS+. Ocasionalmente muestra rosetas neuroectodérmicas o variantes morfológicas atípicas, con células de mayor tamaño, desmoplasia, patrón hemangiopericítico, etc. La característica genética del SE es la translocación recíproca t (11; 22) (q24; q12), resultando en la fusión de los genes EWSR1 y FLI1, identificados en el 90% de los casos (8). La segunda anomalía molecular más común es la t (21; 22) (q22; q12), que fusiona los genes EWSR1 y ERG presente en el 5% de los casos (9). Solo un pequeño porcentaje de SE muestra fusiones de EWSR1 con otros miembros de la familia de factores de transcripción (ETS), como ETV1 (7p22) (10), E1A-F (17q21) (11) y FEV (2q35 - 36) (12). El diagnóstico de los TFSE es en ocasiones complicado, por tanto, para su diagnóstico, no sólo una morfología característica sino un panel amplio de marcadores inmunohistoquímicos y estudio molecular. En la actualidad no existe un anticuerpo específico de SE aunque se han postulado como los más característicos: CD99, CAV-1, FLI1, HNK1 y ERG (el subtipo c-terminal) (27) Existen numerosas vías de señalización alteradas en el sarcoma de Ewing, por un lado la pérdida de factores que inhiben la proliferación por distintas vías (por ejemplo CDKN2A (p16) y TP53) y por otro, la sobreexpresión de receptores de membrana, con función tirosinquinasa, que dan lugar a la proliferación descontrolada de estos sarcomas (principalmente cKIT e IGF1R) (54). Conocer estas vías de señalización resulta clave para avanzar en el tratamiento de estas neoplasias. Para ello se propone estudiar factores reguladores tanto de la apoptosis, como de la proliferación, en una serie de SE, generando xenotrasplantes derivados de pacientes. A la vez que validamos una experiencia in vivo y estudiamos la biología de estos tumores en esta plataforma animal experimental. Las principales moléculas implicadas en el mecanismo de anti-apoptosis en los TFSE son BCL2, caspasa 8 y el receptor del factor de crecimiento insulínico 1 (IGF1R). Asimismo estudiaremos moléculas que permitan al SE interactuar con el mesénquima circundante y avanzar; hemos seleccionado Ezrina, por estar relacionada con las metástasis y un pronóstico desfavorable en sarcomas de alto grado, como osteosarcomas, los sarcomas de Ewing metastásicos y los sarcomas indiferenciados de alto grado (67). Así como SIRT1 o sirtuina1, cuya expresión nuclear en los TFSE, se ha observado en aquellos casos metastásicos de inicio y en las metástasis con respecto a sus tumores originales (78). SIRT1 interviene junto con LSD1 en el control de la expresión de determinados genes entre ellos HEY, participando en la inactivación de p53. (78). Su inactivación ofrece, por tanto opciones terapéuticas en esos tumores (79) dado que se han identificado inhibidores de LSD1 (HCI-2509), permitiendo modificar todos los perfiles transcripcionales promovidos por EWSR1-FLI y EWSR1-ERG y retrasar significativamente la tumorigénesis in vivo (84). La vía de señalización IGF1-R/PI3K/AKT/mTOR es una de las principales en el SE, que regula múltiples funciones celulares manteniendo la proliferación celular, previniendo la apoptosis y aumentando la angiogénesis (85). Además, la producción de IGF1 por el estroma ha sido relacionada con la interacción de las células tumorales con el ambiente, aumentando su capacidad de invasión y metástasis. El bloqueo de esta vía de señales ha ampliado el abanico de opciones terapéuticas en el SE (86-89). Pueden ser estudiadas por inmunohistoquímica (85) lo que ha permitido determinar su valor pronóstico. ERBB4 es un receptor de membrana de la familia de los receptores del factor de crecimiento epidérmico (EGFR), cuya sobreexpresión de ERBB4 favorece la invasión y el crecimiento y su bloqueo, reduce significativamente la aparición de metástasis in vivo. Su expresión no ha sido evaluada hasta la fecha, en los SE. FOXO1 FOXO1 pertenece al grupo de factores de transcripción Forkhead box O (98). Se ha descrito como un gen supresor tumoral, promoviendo la apoptosis y bloqueando la actividad de las quinasas dependientes de ciclinas (99) . La fusión EWSR1-FLI1 interfiere en la expresión de algunos genes, entre ellos FOXO1 (100) , de manera que reduce su expresión y por tanto reduce la apoptosis. Se ha visto que el bloqueo de EWS-FLI1 con RNA de interferencia (siRNA) aumenta la expresión de FOXO1 y disminuye la proliferación de las células (101). Existe en el SE otras vías de inactivación de FOXO 1, a nivel proteico, por la degradación de la proteína en el núcleo. Esta degradación está favorecida por una vía PI3K/AKT activa y por la desacetilasas como SIRT1, ambas vías activas en los SE. Reparación del ADN PARP1 Poli (ADP-ribosa) polimerasa, enzima reguladora implicada en la transcripción y reparación del ADN (103), se ha estudiado tanto en neoplasias sólidas, fundamentalmente en el cáncer de mama BRCA1 mutado (104) y triple negativos (105), como en el cáncer de próstata (106), en el neuroblastoma (107), en gliomas (108), melanomas (109) y en el sarcoma de Ewing (109-112). La reparación del ADN a través de mecanismos que implican roturas de la doble cadena del ADN, como la recombinación homóloga, está muy inhibida en los carcinomas sólidos con mutación en BCRA1 o en BCRA2. Estas células compensan el déficit de reparación del ADN mediante la sobreactivación de PARP, cuya capacidad de reparación del ADN ocurre a través de la rotura simple de una sola cadena (104) . Los inhibidores de PARP bloquean este mecanismo y favorecen que, de una manera selectiva, la célula cancerosa entre en apoptosis al no poder reparar el ADN de ninguna de las maneras (110) . En el SE, el defecto es diferente (111) . No se ha visto un defecto de reparación en el ADN, sino una hipersensibilidad a los complejos ADN-PARP que impiden a la célula entrar en apoptosis. Mediante ensayos de inmunoprecipitación se ha demostrado en cultivos que las células que expresan estas proteínas quiméricas muestran un reducido crecimiento cuando son tratadas con Olaparib (potente inhibidor de PARP1 y PARP2); algo que no ocurre en las líneas celulares de osteosarcoma (SAOS-2) ni de rabdomiosarcoma (A-204). Olaparib asociado a la quimioterapia convencional utilizada en el SE, reduce significativamente el crecimiento tumoral in vitro, frente a cualquiera de los dos de forma aislada (114). SA2 Forma parte de las cohesinas, un complejo de proteínas encargadas de la unión y separación de las cromátides hermanas en la mitosis, a la vez que participan organizando la interfase (115). Concretamente SA2 participa en la separación de los centrómeros (116). Se ha descrito que la inactivación de SA2 provoca aneuploidía en el cáncer humano (118). Recientemente se ha estudiado el papel de SA2 en cáncer de mama, observándose que la disminución de la inmunoexpresión se asocia con enfermedad mamaria maligna y un curso particularmente desfavorable (119). En los SE se ha estudiado el estado mutacional de SA2 y su correlación con la expresión inmunohistoquímica de la proteína (120). El estudio revela que cuando existe mutación del gen la proteína no se expresa, hecho que ocurre fundamentalmente en tumores de estadios avanzados. La expresión de la proteína en el tiempo y en distintas situaciones clínicas no ha sido estudiada. p53 La proteína p53 está codificada por el gen TP53 (considerado el guardián del genoma) y es la responsable de impedir el crecimiento celular e inducir apoptosis. TP53 está alterado entre el 5% y el 20% de los TFSE según las series; tanto en forma de mutación puntual, como de deleción (126, 129) y su pérdida de función ha sido definida como una de las responsables de la progresión de estas neoplasias (129-131). No obstante, p53 no se considera un marcador pronóstico estable, dado que los resultados en las series han sido contradictorios (58, 125, 130, 132); no demostrándose diferencias significativas en las grandes series, entre presencia o no de mutación y evolución clínica adversa (58, 132). Hasta la fecha no se ha estudiado el cambio de expresión y/o de estatus mutacional en el tiempo; así como tampoco la persistencia o cambio de dicho estado en las recidivas o metástasis con respecto al tumor original. Ki67 El índice de proliferación Ki67 (o MIB-1) es un marcador que define las células que están en forma activa en ciclo y se están replicando. En los TFSE se ha descrito una expresión variable e irregular según las series (132, 133); a la vez que se ha definido como factor pronóstico independiente en los casos de SE inicialmente localizado, de supervivencia libre de enfermedad (SLE) y de supervivencia global (SG). Así mismo, se ha asociado a factor pronóstico los subtipos de fusión entre los genes EWSR1 y los distintos factores de transcripción de la familia de ETS. La fusión tipo 1 que une el exón 7 del gen EWSR1 con el exón 6 del gen FLI es, la más frecuente y la de mejor pronóstico, asociándose a un menor grado de expresión de Ki67 (134). Sigue sin definirse en la actualidad un porcentaje de expresión de Ki67 que prediga qué casos van a ir peor y sea de utilidad en el diagnóstico diario. YB-1 La proteína de unión Y-Box 1 (YB-1) está codificada por el gen YBX1 y participa en la transcripción del ADN, en el procesamiento del ARN y en la traducción del mismo (139, 140). YB-1 juega un papel importante como oncogen en la invasión celular y en la resistencia a la quimioterapia (141, 142); así como activando aquellos genes relacionados con la transición epitelio-mesénquima, como los factores de transcripción Snail y Twist (141) y activando la vía AKT/ mTOR y por tanto, con la capacidad infiltrativa de estas neoplasias (143) ). En los sarcomas se ha demostrado que la expresión de YB-1, tanto en cultivos celulares como en xenotrasplantes, se relaciona con una mayor capacidad metastásica (144). De tal forma que si se bloquea la expresión de YB1 (YB1 Knock-down) el tumor crece, pero no metastatiza. BRAF BRAF es un oncogén crítico para la proliferación y supervivencia de las células del melanoma a través de la activación de la vía RAF /MEK / ERK de la vía de las quinasas activadoras de la mitosis (MAPK) (163, 164), siendo un objetivo atractivo para la terapia anti-melanoma. Estudios recientes revelan que más de la mitad de los melanomas presentan una mutación activante en el amino ácido V600 del gen BRAF (BRAF V600E) (165). Existen inhibidores específicos de la mutación y otros por debajo de la señalización de BRAF capaces de bloquear dicha mutación y sus efectores (inhibidores de MEK) como son RAF-265 (Novartis), XL281 (Exelixis), PLX4032 (Plexxikon/Roche) y GSK2118436 (GSK). Estos inhibidores están siendo utilizados en ensayos clínicos en enfermedad avanzada (160). La mutación de BRAF y consecuentemente su sobreexpresión, no ha sido extensamente estudiada en el SE, siendo su expresión baja en la única serie publicada (166). Es interesante por tanto estudiar su expresión en nuestros casos, no sólo de forma estática, sino dinámica en el tiempo. En la actualidad, un tercio de los SE presentan metástasis al diagnóstico; siendo por tanto su pronóstico malo, sin haberse encontrado mejoría en los últimos 30 años a pesar de haberse identificado nuevas dianas terapéuticas y existir abundantes estudios al respecto. Tampoco somos capaces de predecir qué tumores inicialmente localizados van a ser mejor respondedores al tratamiento adyuvante, ni cuáles van a progresar a pesar del tratamiento. En la actualidad se estima que hasta un 30% de estos pacientes con enfermedad localizada evolucionan mal (167). Así mismo, sigue siendo todavía una incógnita, tanto el origen del tumor, como su desigual evolución en los diferentes pacientes. Es necesario, por tanto, realizar un estudio de la heterogeneidad tanto morfológica como fenotípica, en el origen y en la evolución en el tiempo, con vistas a determinar cambios en la biología, genética y epigenética tumorales y poder realizar una medicina personalizada en cada paciente. Los modelos de injertos de tumores en animales proporcionan una plataforma experimental valiosa, que permiten, evaluar la morfología tridimensional de una neoplasia poco frecuente (177), su relación con el componente estromal (178), la angiogénesis (179), el potencial invasivo o la capacidad metastásica. Además de permitir la caracterización de neoplasias mediante diversos procedimientos como histopatología, inmunohistoquímica (IHC) (180-182), microscopía electrónica (EM), citogenética (hibridación convencional y fluorescente in situ (FISH) (183, 184), la biología molecular y la expresión génica (185), no sólo de la neoplasia original, sino también de los pasajes posteriores del tumor debido a la buena preservación de la morfología a lo largo de las generaciones (179-181).Los ratones desnudos atímicos (nu/nu) se caracterizan por tener un deficiente sistema inmune, por lo que han sido ampliamente utilizados para crecer en ellos tumores derivados de pacientes (186). Existe en nuestro grupo una amplia experiencia en utilización de ratones atímicos en la investigación de sarcomas (178, 179, 181, 186-190). La tecnología de micromatrices de tejidos (TMA) permite la evaluación de histopatología e IHC en una gran cohorte de tumores en una sola laminilla, ahorrando costes, tiempo y fundamentalmente tejido. La combinación de modelos de xenoinjerto de SE, incluyendo generaciones sucesivas de pases de ratones en combinación con la tecnología TMA, no se ha informado hasta ahora. Por tanto, nos hemos planteado la siguiente hipótesis y objetivos: Hipótesis de trabajo La hipótesis de trabajo que se pretende demostrar es que existen diferencias fenotípicas en el sarcoma de Ewing que justifican una diferente evolución en el paciente. Objetivos Objetivo general 1. Caracterizar in vivo, una serie de TFSE tanto en su forma original, como a lo largo de los pases una vez xenotransplantados, para detectar posibles cambios en la expresión proteica de marcadores biológicos, que puedan justificar la heterogeneidad de comportamiento clínico y su evolución. Objetivos específicos 1. Caracterizar in vivo una serie de TFSE, tanto en su forma original como a lo largo de los pases una vez xenotransplantados, para detectar posibles cambios en su morfología. 2. Validar una plataforma experimental animal y estudiar la biología tumoral en ratones atímicos. 3. Estudiar la presencia de metástasis realizando el estudio autópsico de cada uno de los animales. 4. Estudiar los principales marcadores inmunohistoquímicos disponibles para el diagnóstico de los TFSE, así como su validez en los distintos subtipos histológicos y a lo largo de los pases. 5. Estudiar la expresión de marcadores biológicos y vías de señalización de relevancia en el SE. 6. Evaluar las diferencias de expresión en tumores inicialmente localizados y metastásicos para detectar posibles diferencias fenotípicas que justifiquen una distinta agresividad clínica entre ambos. 7. Evaluar el cambio de expresión de los marcadores en los distintos pases. 8. Detectar cambios en el fenotipo de un tumor con respecto a sus metástasis. 9. Validación in sílico de marcadores diferencialmente expresados en distintas formas clínicas de SE o con variación a lo largo de los pases. Tumors of the Ewing Sarcoma Family (SE) are rare malignant neoplasms of bone and soft tissues, between 6-8% of primary malignant tumors of bone, that mainly affect patients of growing age, adolescents and young adults (1, 2). The term encompasses three tumors that for years have been considered separately for their characteristic morphology, but which form a morphological spectrum, of common biology and histogenesis (3). These tumors are classic Ewing Sarcomas, atypical and peripheral primitive neuroectodermal tumors (PNET). From the morphological point of view, they are neoplasms constituted by small, round and blue cells, with dense nuclei and scarce cytoplasm, which may be eosinophilic or clear, due to the presence of PAS + glycogen. Occasionally shows neuroectodermal rosettes or atypical morphological variants, with larger cells, desmoplasia, hemangiopericitic pattern, etc. The genetic characteristic of the SE is the reciprocal translocation t (11; 22) (q24; q12), resulting in the fusion of the EWSR1 and FLI1 genes, identified in 90% of the cases (8). The second most common molecular anomaly is t (21; 22) (q22; q12), which fuses the EWSR1 and ERG genes present in 5% of cases (9). Only a small percentage of SE shows fusions of EWSR1 with other members of the family of transcription factors (ETS), such as ETV1 (7p22) (10), E1A-F (17q21) (11) and FEV (2q35-36) (12). The diagnosis of ES is sometimes difficult, therefore, for its diagnosis, not only a characteristic morphology but a broad panel of immunohistochemical markers and molecular study are needed. There is no specific antibody of ES, although they have been postulated as the most characteristic: CD99, CAV-1, FLI1, HNK1 and ERG (the c-terminal subtype) (27) There are numerous altered signaling pathways in ES, on the one hand the loss of factors that inhibit proliferation by different pathways (for example CDKN2A (p16) and TP53) and, on the other, overexpression of membrane receptors, with tyrosine kinase function, which give rise to the uncontrolled proliferation of these sarcomas (mainly cKIT and IGF1R) (54). Knowing these signaling pathways is the key to advance in the treatment of these neoplasms. For this purpose, it is proposed to study regulatory factors of both apoptosis and proliferation in a series of ESs, generating patients derived xenografts. At the same time that we validate an in vivo experience and study the biology of these tumors in this experimental animal platform. The main molecules involved in the mechanism of anti-apoptosis in the TFES are BCL2, caspase 8 and the insulin growth factor receptor 1 (IGF1R). We will also study molecules that allow the ES to interact with the surrounding mesenchyme and infiltrate; we have selected Ezrin, because it is related to metastasis and an unfavorable prognosis in high-grade sarcomas, such as osteosarcomas, metastatic ES and high-grade undifferentiated sarcomas (67). As well as SIRT1 or sirtuin1, whose nuclear expression in ESFT has been observed in those metastatic cases of onset and metastasis with respect to their original tumors (78). SIRT1 intervenes with LSD1 in the control of the expression of certain genes including HEY, participating in the inactivation of p53. (78). Its inactivation offers, therefore, therapeutic options in these tumors (79) given that inhibitors of LSD1 (HCI-2509) have been identified, allowing to modify all the transcriptional profiles promoted by EWSR1-FLI and EWSR1-ERG and significantly delay in vivo tumorigenesis. (84). The IGF1-R / PI3K / AKT / mTOR signaling pathway is one of the main signaling pathways in the ES, which regulates multiple cellular functions by maintaining cell proliferation, preventing apoptosis and increasing angiogenesis (85). In addition, the production of IGF1 by the stroma has been related to the interaction of tumor cells with the environment, increasing their capacity for invasion and metastasis. The blockade of this signal pathway has widened the range of therapeutic options in the ES (86-89). They can be studied by immunohistochemistry (85) which has allowed to determine its prognostic value. ERBB4 is a membrane receptor of the family of epidermal growth factor receptors (EGFR), whose overexpression of ERBB4 favors invasion and growth and its blockade significantly reduces the appearance of metastasis in vivo. Its expression has not been evaluated to date, in the ESs. FOXO1 FOXO1 belongs to the group of transcription factors Forkhead box O (98). It has been described as a tumor suppressor gene, promoting apoptosis and blocking the activity of cyclin-dependent kinases (99). The EWSR1-FLI1 fusion interferes with the expression of some genes, including FOXO1 (100), in a way that reduces its expression and therefore reduces apoptosis. It has been shown that blocking EWS-FLI1 with interfering RNA (siRNA) increases the expression of FOXO1 and decreases the proliferation of cells (101). In the ES there are other routes of inactivation of FOXO1, at the protein level, by the degradation of the protein in the nucleus. This degradation is favored by an active PI3K / AKT pathway and by deacetylases such as SIRT1, both active pathways in ES. DNA repair PARP1 Poly (ADP-ribose) polymerase, a regulatory enzyme involved in the transcription and repair of DNA (103), has been studied in both solid neoplasms, mainly in BRCA1 breast cancer (104) and triple negative (105), and in prostate cancer (106), in neuroblastoma (107), in gliomas (108), melanomas (109) and in Ewing's sarcoma (109-112). DNA repair through mechanisms involving DNA double-strand breaks, such as homologous recombination, is highly inhibited in solid carcinomas with mutation in BCRA1 or in BCRA2. These cells compensate for the DNA repair deficit by over-activating PARP, whose capacity for DNA repair occurs through the single break of a single chain (104). PARP inhibitors block this mechanism and favor that, in a selective way, the cancer cell enters into apoptosis when it can not repair DNA in any of the ways (110). In the ES, the defect is different (111). We have not seen a repair defect in the DNA, but a hypersensitivity to DNA-PARP complexes that prevent the cell from entering apoptosis. By immunoprecipitation assays it has been demonstrated in cultures that cells expressing these chimeric proteins show reduced growth when treated with Olaparib (potent inhibitor of PARP1 and PARP2); something that does not occur in the osteosarcoma cell lines (SAOS-2) or rhabdomyosarcoma (A-204). Olaparib associated with conventional chemotherapy used in the ES, significantly reduces tumor growth in vitro, compared to either of them in isolation (114). SA2 It is part of the cohesins, a complex of proteins responsible for the union and separation of sister chromatids in mitosis, while participating in the organization of the interface (115). Specifically SA2 participates in the separation of the centromeres (116). It has been described that the inactivation of SA2 causes aneuploidy in human cancer (118). Recently the role of SA2 in breast cancer has been studied, observing that the decrease in immunoexpression is associated with unfavorable course (119). In the ES, the mutational status of SA2 and its correlation with the immunohistochemical expression of the protein have been studied (120). The study reveals that when there is mutation of the gene, the protein is not expressed, a fact that occurs mainly in tumors of advanced stages. The expression of the protein in time and in different clinical situations has not been studied. p53 The p53 protein is encoded by the TP53 gene (considered the guardian of the genome) and is responsible for preventing cell growth and inducing apoptosis. TP53 is altered between 5% and 20% of the ES according to the series; both in the form of point mutation, and deletion (126, 129) and its loss of function has been defined as one of those responsible for the progression of these neoplasms (129-131). However, p53 is not considered a stable prognostic marker, given that the results in the series have been contradictory (58, 125, 130, 132); no significant differences were demonstrated in the large series, between presence or absence of mutation and adverse clinical evolution (58, 132). To date, the change of expression and / or mutational status over time has not been studied; as well as the persistence or change of this state in recurrences or metastasis in comparison to the original tumor. Ki67 The Ki67 proliferation index (or MIB-1) is a marker that defines the cells that are active in cycle and are replicating. In the ES, a variable and irregular expression has been described according to the series (132, 133); At the same time, it has been defined as an independent prognostic factor in cases of initially localized SE, disease-free survival (SLE) and overall survival (OS). Likewise, the fusion subtypes between the EWSR1 genes and the different transcription factors of the ETS family have been associated with prognostic factors. The type 1 fusion that binds exon 7 of the EWSR1 gene with exon 6 of the FLI gene is the most frequent and the one with the best prognosis, being associated with a lower degree of Ki67 expression (134). An expression percentage of Ki67 that predicts which cases will go worse and is useful in the daily diagnosis remains undefined. YB-1 The Y-Box 1 binding protein (YB-1) is encoded by the YBX1 gene and participates in the transcription of DNA, RNA processing and translation (139, 140). YB-1 plays an important role as an oncogene in cell invasion and resistance to chemotherapy (141, 142); as well as activating those genes related to the epithelial-mesenchymal transition, such as the transcription factors Snail and Twist (141) and activating the AKT / mTOR pathway and, therefore, with the infiltrative capacity of these neoplasms (143)). In sarcomas it has been shown that the expression of YB-1, both in cell cultures and in xenotransplantation, is related to a greater metastatic capacity (144). In such a way that if the expression of YB1 (YB1 Knock-down) is blocked, the tumor grows but does not metastasize. BRAF BRAF is a critical oncogene for the proliferation and survival of melanoma cells through the activation of the RAF / MEK / ERK pathway of the mitosis activating kinases (MAPK) pathway (163, 164), being an attractive target for therapy. Recent studies reveal that more than half of melanomas have an activating mutation in the amino acid V600 of the BRAF gene (BRAF V600E) (165). There are specific inhibitors of the mutation and others below the BRAF signaling such as RAF-265 (Novartis), XL281 (Exelixis), PLX4032 (Plexxikon / Roche) and GSK2118436 (GSK) These inhibitors are being used in clinical trials in advanced disease (160). The BRAF mutation and consequently its overexpression, has not been extensively studied in the ES, its expression being low in the only published series (166). It is therefore interesting to study its expression in our cases, not only in a static way, but in time. Currently, one third of the ES present metastasis at diagnosis; therefore, its prognosis is bad, without having seen improvement in the last 30 years, despite having identified new therapeutic targets and there are abundant studies on this subject. Neither are we able to predict which tumors initially located will be better responders to adjuvant treatment, nor which ones will progress despite treatment. It is currently estimated that up to 30% of these patients with localized disease develop poorly (167). Likewise, the origin of the tumor and its unequal evolution in the different patients remain unknown. It is necessary, therefore, to carry out a study of both morphological and phenotypic heterogeneity, in the origin and evolution over time, with a view to determining changes in tumor biology, genetics and epigenetics and being able to perform a personalized medicine in each patient. PDX provide a valuable experimental platform, which allow us to evaluate the three-dimensional morphology of a rare neoplasm (177), its relationship with the stromal component (178), angiogenesis (179), the invasive potential or the metastatic capacity. In addition to allowing the characterization of neoplasms by various procedures such as histopathology, immunohistochemistry (IHC) (180-182), electron microscopy (EM), cytogenetics (conventional hybridization and fluorescent in situ (FISH) (183, 184), molecular biology and gene expression (185), not only of the original neoplasia, but also of the posterior passages of the tumor due to the good preservation of the morphology throughout the generations (179-181). Nude athymic mice (nu / nu) are characterized by having a poor immune system, which is why they have been widely used to grow tumors derived from patients (186). Our group has extensive experience in the use of athymic mice in the investigation of sarcomas (178, 179 , 181, 186-190). Tissue microarray technology (TMA) allows the evaluation of histopathology and IHC in a large cohort of tumors in a single slide, saving costs, time and fundamentally tissue. The combination of ES xenograft models, including successive generations of mouse passages in combination with TMA technology, has not been reported so far. Therefore, we have considered the following hypothesis and objectives: Hypothesis The hypothesis consist of demonstrating that phenotypical differences exist in the ES that justify a different evolution in the patient. Goals Main goal 1. Characterize in vivo, a series of ES both, in its original form, and throughout the passages once xenotransplanted, to detect possible changes in the protein expression of biological markers, which may justify the heterogeneity of clinical behavior and its evolution . Specific goals 1. Characterize in vivo a series of ES, both in its original form and throughout the passes once xenotransplanted, to detect possible changes in its morphology. 2. Validate an animal experimental platform and study tumor biology in athymic mice. 3. Study the presence of metastasis by performing the autopsy study of each of the animals. 4. Study the main immunohistochemical markers available for the diagnosis of ES, as well as their validity in the different histological subtypes and throughout the passages. 5. Study the expression of biological markers and signaling pathways of relevance in the SE. 6. To evaluate the expression differences in initially localized and metastatic tumors to detect possible phenotypic differences that justify a different clinical aggressiveness between both. 7. Evaluate the change of expression of the markers in the different passages. 8. Detect changes in the phenotype of a tumor from its metastasis. 9. In-vitro validation of differentially expressed markers in different clinical forms of ES or with variation throughout the passages.

Published

2019

22. Expresión de citoquinas en el mecanismo de crecimiento tumoral utilizando un modelo de xenotrasplante de sarcomas humanos en ratones atímicos

Author

Giner Segura, Francisco, Llombart Bosch, Antonio, López Guerrero, José Antonio, and Departament de Patologia

Subjects

sarcoma, UNESCO::CIENCIAS MÉDICAS, xenotrasplante, UNESCO::CIENCIAS DE LA VIDA, CIENCIAS MÉDICAS [UNESCO], CIENCIAS DE LA VIDA [UNESCO], citoquina

Abstract

Los sarcomas son tumores muy agresivos si bien relativamente infrecuentes. Suelen afectar a una población de edad bastante precoz y su tratamiento ademas de la radioterapia y cirugía es limitado , por ello se hace indispensable un estudio intensivo de su biología en busca de nuevas terapias ,como pudiera ser la respuesta inmune, para mejorar la superviviencia, que es actualmente desfavorable en estadios II y III de la enfermedad y ademas la presencia de metástasis (estadio IV) se asocia a un pronostico infausto en la mayoría de lo casos (1). Las quimiocinas comprenden una familia de aproximadamente 50 citocinas, que están implicadas en muchos procesos biológicos, tales como la migración de leucocitos , embriogénesis, angiogénesis, hematopoyesis, aterosclerosis, crecimiento tumoral, metástasis e infección por HIV (2). Estas quimiocinas se clasifican en dos grandes grupos basándose en su función y en el patrón de expresión: quimiocinas homeostáticas e inflamatorias (3). Las quimiocinas homeostáticas se expresan constitutivamente en ciertos tejidos, y juegan un papel importante y vital en el desarrollo y mantenimiento (homeostasis) del sistema inmune y hematopoyético. Por otro lado, las quimiocinas inflamatorias no se expresan constitutivamente, siendo inducibles por estímulos inflamatorios. Su expresión está estrechamente controlada por citocinas proinflamatorias que se expresan a nivel local. También las quimiocinas y sus receptores estimulan el crecimiento tumoral así como la migración e invasión neoplásica (3). Actualmente, se está estudiando la expresión de las distintas quimiocinas y sus receptores en múltiples neoplasias y entre ellas los sarcomas, en donde se encuentran logrando protagonismo notable en este campo con algunas publicaciones en revistas de alto impacto (4) Nosotros nos proponemos estudiar la expresión de tres quimiocinas relacionadas directamente en los procesos de proliferación tumoral, angiogénesis y metástasis. Para ello analizaremos el papel que desempeñan durante las primeras fases de crecimiento tumoral escogiendo un modelo mixto: sarcoma humano con crecimiento in vivo mediante xenoinjertos en ratones atímicos. Nos centraremos en el estudio de la expresión de los ligandos de las tres quimiocinas siguientes: 1.1. CXCL1/2/3 Estas quimiocinas tienen de receptor a CXCR2, y promueven la quimiotaxis de neutrófilos y es responsable de la actividad angiogénica y quimiotáctica de las células endoteliales (5). El reclutamiento de neutrófilos juega un importante papel en la actividad angiogénica del homólogo murino CXCL1/ proteína-2 inflamatoria macrofágica(MIP-2) (6). De hecho, los neutrófilos pueden sintetizar y almacenar moléculas angiogénicas, como el factor de crecimiento endotelial vascular (VEGF)-A. Sin embargo, estas quimiocinas no solo atraen a las células tumorales sino que también pueden contribuir directamente a la transformación y crecimiento tumoral. De hecho, las quimiocinas GRO (CXCL1/2/3) juegan un papel fundamental en la quimiotaxis y metástasis de varias líneas celulares y actuan como factores de crecimiento autocrino en el melanoma y otros tumores (7). La sobreexpresión de CXCL1/GRO-α en melanocitos se asocia a una activación constitutiva del factor κB nuclear aumentando la progresión nuclear (8). Una mutación puntual en CXCR2 genera una señal constitutiva, promoviendo la transformación celular de preneoplásica a neoplásica. Además , se ha demostrado que CXCL1/GRO-α no sólo se une a CXCR2 sino también al GPCR codificado por el tumorigénico virus herpes-8 asociado al sarcoma de Kaposi (9). Además de la anteriormente descritas CXCR1 y CXCR2, se identificó otro receptor quimiocina ligando, llamado receptor antígeno Duffy para quimiocinas (DARC) (3). 1.2. CXCL9 y CXCL10 Estas pertenecen al grupo de las quimiocinas CXC ELR-. En este grupo se encuentran las quimiocinas CXCL9/Mig, CXCL10/IP-10, CXCL11/I-TAC y su receptor CXCR3 que tienen un poder angiostático en la angiogénesis y son producidas in vitro por una gran variedad de células, incluyendo células endoteliales, fibroblastos, células mononucleares y tumorales, y su presencia ha sido confirmada en varios tipos de tejidos tumorales (10). Estas quimiocinas inhiben la actividad angiogénica de las quimiocinas CXC ELR+ en los ensayos in vitro en la quimiotaxis de células endoteliales y en el modelo in vivo en la cornea de la rata. El mecanismo responsable del bloqueo de los ligandos CXCR1 y CXCR2 por los ligandos de CXCR3 no están bien entendidos todavía. CXCR3-B y la unión GAG sobre células endoteliales están probablemente involucrados en mediar la actividad angiostática (11). Hay al menos tres variantes de ensamblaje de CXCR3, llamadas CXCR3-A, CXCR3-B y CXCR3-alt. CXCR3-A está involucrado en la actividad quimiotáctica de las quimiocinas CXC IFN-γ sobre los linfocitos T activados y células NK. Clásicamente, el reclutamiento de esas células facilita la inmunidad antitumoral produciendo una regresión tumoral (12). CXCR3-B se postula que media la actividad angiostática de CXCL4/PF-4, CXCL9, CXCL10, y CXCL11 sobre células endoteliales. La expresión de CXCR3 en células endoteliales es ciclo-celular dependiente y limitada a la fase S/G2-M. Aunque la mayoría de receptores quimiotácticos están emparejados con las proteínas toxinas-sensitiva G pertussis, se ha publicado que CXCR3-A y CXCR3-B median su función recíproca a través de diferentes proteínas G emparejadas. Algunos tejidos como el corazón, riñón, hígado y músculo esquelético expresan ambas variantes de ensamblaje CXCR3. Otros tejidos como la placenta, expresan sólo CXCR3-A, mientras que las células endoteliales vasculares expresan selectivamente CXCR3-B (13). La relativa expresión de estas dos variantes en el cáncer de mama sugiere ser importante en la regulación de su proliferación en respuesta a CXCL10. De hecho, tras la disminución de CXCR3-By CXCL10 se produce un aumento en la proliferación del cáncer de mama, lo que confirma el papel de CXCR3-B en la inhibición del crecimiento celular y sugiere la participación de CXCR3-A u otro receptor CXCL10 que promueva la proliferación celular (3). El papel de la expresión de CXCR3 en la biología tumoral ha sido investigado por otros grupos de trabajo en las metástasis. La expresión constitutiva de CXCR3 en melanomas, carcinomas de colon y mama aceleran las metástasis a ganglios linfáticos (14). Por otro lado, el antagonismo de CXCR3 produjo una inhibición de las metástasis pulmonares en el cáncer de mama en un modelo murino (15). Esto sugeriría un papel de CXCR3 en conducir células CXCR3 positivas hacia sitios donde IFN-γ es abundante, como se describió previamente en CXCL12/SDF-1 en el eje CXCR4. De hecho, CXCL10/IP-10 se detectó en sitios metastáticos en células de carcinoma colo-rectal, y promociona la invasión tumoral. Esto indica que los ligandos CXCR3 tienen efectos opuestos sobre el microambiente de las células tumorales (antimaligno) y sobre las células tumorales (promaligno). Esta dicotomía de los ligandos CXCR3/CXCR3 también sugiere que la aplicación de estos ligandos CXCR3 como potenciales agentes terapéuticos en cáncer, podrían ser problemáticos (3). Un tercer receptor CXCR3, CXCR3-alt tiene la actividad funcional reducida y media efectos quimiotácticos inducidos por CXCL11/I-TAC. Una razón mayor para reducir la actividad quimiotáctica puede ser una expresión más baja de la proteína en superficie de CXCR3-alt, comparado con la que rellena el receptor. Además, se ha sugerido la existencia de otro receptor funcional para CXCL10/IP-10 presente en células epiteliales y endoteliales que no sea CXCR3-A (16). 2. Metodología: Para llevar a cabo la presente propuesta de proyecto de tesis doctoral será necesario llevar a cabo la siguiente metodología: - Xenotransplantes de sarcomas humanos en ratones atímicos - Estudios histológicos - Inmunohistoquímica - Inmunofluorescencia - Microscopía electrónica - ELISA - PCR cuantitativa. 2.1. Xenotransplantes de sarcomas humanos en ratones atímicos. Se llevarán a cabo implantes subcutáneos de sarcomas humanos (de 0.2-0.3 cm3 de tamaño) en la espalda de ratones atímicos (athymic Balb-c nude mice) en condiciones de esterilidad. Dichos animales se sacrificarán a las 24 h, 48, 72h (96h), 7, 14(10), 21 y 28 días del xenoinjerto. A partir de las muestras tumorales y plasma murino obtenidas se procederá a llevar a cabo los estudios histológicos, inmunofenotípicos y moleculares. 2.2. Estudios histológicos Las muestras de tejido obtenidas se fijarán en 10% de formaldehído, se incluirán en parafina, y se teñirán con hematoxilina-eosina para el estudio histológico. En este estudio se tendrán en cuenta características, como: presencia de necrosis, distribución de capilares, interacción del tumor con el tejido circundante del huésped, con la zona de necrosis y vasos sanguíneos. Se excluyen del estudio aquellas muestras que carezcan de células tumorales no necrosadas. El estudio histológico e inmunofenotípico se pretende llevar a cabo sobre los siguientes sarcomas: sarcoma de Ewing/PNET, condrosarcoma grado 2, condrosarcoma grado 3, osteosarcoma osteogénico , fibrosarcoma, sarcoma sinovial monofásico y tumor del estroma gastrointestinal (GIST). 2.3. Inmunohistoquímica La inmunohistoquímica se llevará a cabo mediante el método indirecto de peroxidasa sobre secciones de parafina. Se llevará a cabo una recuperación antigénica inducida por calor en autoclave de 1.5 atmósferas durante 3 min en una solución de tampón citrato. La reacción antígeno-anticuerpo se visualizará mediante una reacción cromogénica con un conjugado de avidina-biotina-peroxidasa (LSAB). Los controles negativos se llevarán a cabo sustituyendo el anticuerpo primario con tampón salino de fosfato. Entre los anticuerpos que se testarán se incluyen: CXCL9, CXCL10, CXCL1/2/3, VEGF, KDR, Flt1, Flt4, VE-CAD, PDGFRA, HIF-1 y Ki67. Cada uno de los anticuerpos serán testados con tejidos controles positivos en cada uno de los procedimientos. 2.4. Inmunofluorescencia Marcaremos con dos colores fluorescentes (rojo-verde), dos proteínas distintas la misma sección histológica del tumor. Uno de los colores detecta una quimiocina y otro un antígeno característico del tipo de sarcoma. Para ello, seguiremos el protocolo de la casa comercial R&D Systems. Primero, desparafinaremos las secciones en xilol y rehidrataremos con etanol y agua destilada. Realizaremos la recuperación antigénica con tampón citrato incubando 10min hirviendo en microondas. Incubaremos el anticuerpo primario durante la noche (14-20h). Lavaremos con PBS y posteriormente incubaremos el anticuerpo secundario fluorescente durante 60min. Lavaremos con PBS y cubriremos las muestras con Mowiol. Las secciones se guardarán en frío (3-4ºC) y protegidas de la luz. Finalmente, se tomarán fotografías de las áreas más representativas en el microscopio confocal de todos los planos del corte en parafina (Leica M165). 2.5. Microscopía electrónica Para llevar a cabo los estudios de microscopia electrónica, los tejidos se fijarán en gluteraldehido, se post-fijarán en una solución de tetraóxido de osmio tamponado y se incluirán en la resina Eponato 12. Los tejidos se cortarán en secciones semifinas de 1µm y se teñirán con azul de toluidina para resaltar los campos más representativos del tumor. Posteriormente se realizarán cortes ultrafinos con un ultramicrotomo Reichert Ultracut Ultramicrotome (Leica, Inc., Deinfield, Illinois) y se teñirán con acetato de citrato y uranilo, para a continuación analizar las muestras con un microscopio electrónico (JEOL JEM 1010, Tokyo). 2.6. ELISA Adicionalmente a las muestras de tejido, se recogerán muestras de suero de los animales de experimentación sobre los que se establecerán los niveles de expresión de factores de crecimiento en suero tanto de origen humano como de ratón. 2.7. PCR cuantitativa Además de los parámetros anteriormente mencionados se procederá a analizar los niveles de expresión de determinados genes de expresión mediante RT-PCR cuantitativa. Para ello, se procederá a extraer RNA de cada una de las muestras analizadas y mediante sondas TaqMan evaluar sus niveles de expresión. Se tomará como muestra calibrador el tumor antes del xenoinjerto y para realizar los cálculos de expresión el método del 2-Ct. Entre los genes a analizar destacan: -Factores de crecimiento y receptores: EFNA2 (Ephrin A2), EFNA5 (Ephrin A5), EFNB2 (Ephrin B2), EPHB4 (Ephrin B4), FGF1 (aFGF), FGF2 (bFGF), FGF4, FGF6, FGF7, FGFR1, FGFR2 (KGFR), FGFR3, FGFR4 , PDGFA, PDGFB, PDGFRA, PDGFRB, PF4 (Platelet factor 4), TGFA, TGFB1, TGFB2, TGFB3, TGFBR1, TGFBR2, TGFBR3, FIGF (VEGFD), FLK1 (KDR), FLT1 (VEGFR2), PGF, VEGF, VEGFB, VEGFC, CD36, EDG1, EGF, EGFR, GRO1, HGF (Scatter factor), IGF1, TEK (Tie-2), TIE. -Citocinas y quimiocinas: CXCL9, CXCL10, CXCL1/2/3, CSF3, IFNA1, IFNB1, IFNG, IL10, IL12A, IL8, MDK, NRP1 (neuropilin-1), PRL (prolactin), PTN (pleiotrophin), SCYA2, SPARC, TNFA, TNFSF15 (VEGI). - Factores de transcripción: ERBB2, ETS1, HIF1A, ID1, ID3, MADH1 (SMAD1) 3. Objetivos: 3.1. Estudiar la expresión de estas tres quimiocinas (CXCL1/2/3, CXCL9 y CXCL10) en diferentes sarcomas, correlacionando la inmunohistoquímica convencional con el método indirecto de peroxidasa, y la inmunofluorescencia indirecta. 3.2. Estudiar el patrón de expresión de las quimiocinas en los sarcomas xenotransplantados en ratones atímicos en los primeros días de desarrollo: entre las 24 horas y los 30 días en cortes de tiempo sucesivos señalar los cortes de sacrifico tumoral. 3.3. Observar el papel que desempeñan dichas quimiocinas en la angiogénesis y crecimiento tumoral en las primeras días del crecimiento neoplásico tras el injerto. Así como analizar el papel que desempeña la necrosis tumoral, el estroma murino peritumoral y el árbol vascular en el crecimiento de los sarcomas. 3.4. Buscar una correlación entre la expresión de quimiocinas en las técnicas inmunohistoquímicas sobre el tejido tumoral incluido en parafina, y otras técnicas de biología molecular como ELISA y PCR cuantitativa sobre dichas quimiocinas en el suero de ratones atímicos. 3.5. Observar los cambios morfológicos y ultraestructurales que se producen en los sarcomas durante los primeros días y semanas del crecimiento tumoral. 4. Bibliografía: 1. Pathology and Genetics of Tumours of Soft Tissue and Bone (WHO). Edited by Christopher D.M. Fletcher, Krisjnan Unni and Fredrik Mertens, 2002. 2. Struyf S, Proost P, Van Damme J, Regulation of the immune response by the interaction of chemokines and proteases, Adv. Immunol. 81 (2003) 1-44. 3. Vandercapellen J, Van Damme J, Struyf S, The role of CXC chemokines and their receptors in cancer, Cancer Letters. 267 (2008) 226-244. 4. 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Published

2014