Genomic instability in giant cell tumor of bone. A study of 52 cases using DNA ploidy, relocalization FISH, and array‐CGH analysis

Moskovszky, Linda; Szuhai, Károly; Krenács, Tibor; Hogendoorn, Pancras C.W.; Szabó, Miklós; Benassi, Maria Serena; Kopper, László; Füle, Tibor; Szepes, Zoltán

doi:10.1002/gcc.20656

Cited by 46 publications

(30 citation statements)

References 41 publications

(49 reference statements)

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“…Eusomic polysomy has been seen in several tetraploid nonrecurrent cases, and balanced aneusomy has been found more frequently in diploid recurrent than in diploid nonrecurrent cases. These findings suggest that chromosomal abnormalities superimposed on telomeric associations might be responsible for the aggressive behavior of GCTB [31]. The expression of proteins involved in cell cycle regulation/oncogenesis, such as p53, p63, ki-67, cyclinD1, or Bcl-2, are not predictive for the clinical behaviour of GCTB [32].…”

Section: Prognosismentioning

confidence: 82%

Histological and clinical characteristics of malignant giant cell tumor of bone

et al. 2012

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Malignant giant cell tumors of bone (MGCTB) are rare, and the diagnosis can be difficult due to the occurrence of a variety of malignant tumors containing giant cells. To better understand its clinicopathological features, we have reviewed our experience with 17 cases of MGCTB. Five cases were primary malignant giant cell tumor of bone (PMGCTB), and 12 cases were giant cell tumors of bone initially diagnosed as benign but malignant in a recurrent lesion (secondary MGCTB, SMGCTB). The patients included six women and 11 men (age ranged from 17 to 52 years; mean, 30.5 years). The tumor arose in the femur (six cases), the tibia (seven cases), the humerus (three cases), and the fibula (one case). Microscopically, PMGCTB showed both conventional giant cell tumor and malignant sarcoma features. SMGCTB were initially diagnosed as conventional giant cell tumor of bone, the recurrent lesion showing malignant features. Histologically, the malignant components included osteosarcoma (11 cases), undifferentiated high-grade pleomorphic sarcoma (two cases), and fibrosarcoma (four cases). SMGCTB cases showed strong expression of p53. Follow-up information revealed that four patients died of lung metastasis, two patients are alive with lung metastases, and 11 patients are alive without tumor. MGCTB should be considered as a high-grade sarcoma. It must be distinguished from GCTB and other malignant tumors containing giant cells. p53 might play a role in the malignant transformation of GCTB.

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Section: Prognosismentioning

confidence: 82%

Histological and clinical characteristics of malignant giant cell tumor of bone

et al. 2012

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“…A p53 mutation has also been reported in bone and soft tissue sarcomas [12]. However, a p53 mutation has rarely been reported in malignant or benign GCT [13,14]. A p53 point mutation as well as p53 overexpression in stromal cells has been reported in a case of recurrent GCT diagnosed as malignant GCT [14].…”

Section: Discussionmentioning

confidence: 97%

A case of secondary malignant giant-cell tumor of bone with p53 mutation after long-term follow-up

Saito¹,

Mitomi²,

Izumi³

et al. 2011

Human Pathology

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“…We have previously shown that random aneusomy is a feature of the CD68-negative mononuclear stromal cell population of giant cell tumour of bone, and that this feature correlates with biological aggressiveness, with chromosomal gain and loss turning into clonal but random genetic aberrations in malignant cases. 2 In this study, we show that there is a strong correlation between chromosomal instability and centrosome amplification, suggesting a possible involvement of the latter in generating chromosomal instability in giant cell tumour of bone. However, relocalization studies and immunocytochemistry, in combination with FISH, showed no association between centrosome amplification and chromosome number alteration, indicating that alternative causative mechanisms are responsible for generating genetic instability in giant cell tumour of bone.…”

Section: Discussionmentioning

confidence: 49%

“…24 Membrane and cytoplasmic expression of CTNNB1, a member of the Wnt signalling pathway, has been observed in giant cell tumour of bone; although the failure of this signalling route (usually with the nuclear accumulation of CTNNB1) is well known to cause aneusomies and tetrasomies, 25 no significant correlation has been observed between CTNNB1 positivity and the degree of aneusomy in giant cell tumour of bone, or between CTNNB1 expression and giant cell tumour of bone recurrence. 2,26 One of the most commonly observed genetic aberrations in giant cell tumour of bone is telomeric association. Telomeric association alone, however, does not have a role in the development of genetic instability.…”

Section: Discussionmentioning

confidence: 99%

“…1 The mixed mononuclear cell population in giant cell tumour of bone includes both reactive CD68-positive macrophages and proliferating stromal cells. 2,3 Recently, it was shown that the rate of chromosomal aneusomy in the CD68-negative stromal cell population is higher in recurrent compared with nonrecurrent giant cell tumour of bones; chromosomal aneusomy was found to be clonal in most malignant cases of giant cell tumour of bone, suggesting that chromosomal instability may be responsible for aggressive behaviour. 2 Possible mechanisms that might contribute to chromosomal instability in giant cell tumour of bone include loss of mitotic checkpoint function, defective kinetochore function and abnormal amplification of centrosomes.…”

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confidence: 99%

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