Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: UMLS:C0029463 (osteosarcoma)
 16,637 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

158 cases of the Cooperative Ewing's Sarcoma Trials (CESS 81/86), which have been documented at the Pediatric Tumor Registry, Kiel, were studied by conventional light microscopy and immunohistochemistry. There were 77 cases of typical Ewing's sarcoma with 70 cases being located in the skeleton and 7 in soft tissues. Of the 14 cases of atypical Ewing's sarcoma 7 cases each were localized in bone and in soft tissue, respectively. In contrast to typical Ewing's sarcoma, cells of atypical Ewing's sarcoma were larger and displayed more heterochromatin. Both, typical and atypical Ewing's sarcoma reacted positively for vimentin. Other stains were negative, notably the neuron specific enolase (NSE). In 55 cases a diagnosis of malignant peripheral neuroectodermal tumor (MPNT) was made. Histologically most of these tumors resembled atypical Ewing's sarcoma. By immunohistochemistry positive reactions were found for NSE, vimentin, protein S-100, neurofilaments and glial fibrillary acidic protein. In 3 cases a diagnosis of small cell osteosarcoma was made. There were 2 cases of undifferentiated sarcoma of bone, 2 cases of soft tissue sarcoma of undetermined histogenesis and 2 cases of rhabdomyosarcoma. Of the 4 tumors which could be investigated for response to polychemotherapy, 1 each corresponded to grade II and III, respectively, and 2 to grade IV according to the classification of histologic grade of regression established by Salzer-Kuntschik et al. (1983).
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PMID:[Cooperative Ewing's Sarcoma Studies 81/86: pathologico-anatomic and immunohistochemical findings and differential diagnosis of Ewing sarcoma]. 306 61

Directional tag PCR subtractive hybridization was applied to construct a cDNA library generated from three different human osteosarcoma (OS) target cell lines (OHS, SaOS-2 and KPDXM) from which normal osteoblast (NO) sequences were subtracted. After two consecutive subtractive steps more than 98% of the common mRNAs species were depleted, leading to effective enrichment of the remaining target sequences. After differential screening of 960 clones, 81 candidates were further studied by Northern blot analysis and 73 represented separate mRNA species. Fifty-three of these showed enriched mRNA levels, of which 36 represented known and 17 not previously published cDNAs or EST sequences. The mRNAs showed a 1.4- to 504-fold enrichment compared to the mRNA levels in NO cells. The known mRNAs are: Ribosomal protein S11, KSP-37, Tethering factor SEC34, FXYD6, Alpha enolase, G-s-alpha, GPR85, DAF, RPL35A, GIF, TAPA-1, ANAPC11, DCI, hsp27, MRPS7 homolog, eIF p110 subunit, DPH2L, HMG-14, FB1 protein, chondroitin-6-sulphonase, calgizzarin, RNA polymerase II subunit, RPL13A, DHS, gp96, HHP2, acidic ribosomal phosphoprotein P2, ANT-2, ARF1, AFG3L2, SKD3, phosphoglucoisomerase, GST pi, CKI gamma 2, DNA polymerase delta small subunit and TRAP delta. Sections of human osteosarcoma biopsies and a xenograft were studied by in situ analysis. Seven cDNAs highly expressed in Northern blot analysis were tested. Their in situ expression differed between the xenograft and human sections as did that of collagen I. In the xenograft made from one of the target cell lines (OHS), a fair to strong representation of 3 cloned mRNAs was observed while collagen I mRNA was not detectable. We conclude that the molecular heterogeneity of these tumors is considerable. These results ought to have implications for future work to describe phenotypic subtypes with the aim of improving the diagnosis of human osteosarcomas.
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PMID:Molecular heterogeneity in human osteosarcoma demonstrated by enriched mRNAs isolated by directional tag PCR subtraction cloning. 1289 94