Archival surgical specimens from 1,210 female breast cancer patients treated between 1968 and 1971 and with a 19-year follow-up were reanalyzed with special reference to several parameters, such as size of the primary tumor, axillary nodal involvement, histologic grade, degree of inflammatory infiltrate (LPI) of the tumor and expression of the neu oncoprotein (p185) as detected by immunohistochemistry. In a multifactorial analysis the 4 former factors were found to be independent prognostic parameters. Over-expression of p185 was found to be related to tumor size and grade and to LPI but not to pathologic nodal status. Over-expression of p185 showed a negative impact upon survival in node-positive but not in node-negative patients. However, in the subset of node-negative patients without LPI, p185 over-expression showed the same correlation with a poor prognosis as in node-positive patients. In contrast, in node-negative and LPI-positive patients, p185 over-expression correlated with a good prognosis. Also, the prognosis of patients with positive nodes, presence of LPI and no p185 over-expression was similar to that of patients with negative nodes, absence of LPI and p185 over-expression.
Recent findings have indicated that TP53 inactivation in sarcomas may result from mutation and/or deletion of the TP53 gene or, alternatively, from binding to the MDM2 gene products. To investigate further a possible role of the two genes in sarcomas, 24 large and deep‐seated lipomas and 74 liposarcomas of various subtypes were analysed for mdm2 and p53 overexpression by immunocytochemistry. Nineteen cases of the same series were also molecularly analysed for both MDM2 gene amplification and TP53 mutations, and a further ten cases for non‐random chromosomal abnormalities. In the retroperitoneal well‐differentiated–dedifferentiated (WD–DD) group, 15/16 WD and 8/8 DD liposarcomas displayed the mdm2+/p53+ phenotype, consistent with MDM2 gene amplification in the absence of TP53 mutations. In the non‐retroperitoneal WD–DD group, 5/11 WD liposarcomas also retained the mdm2+/p53+ phenotype whereas all DD liposarcomas showed an immunophenotype and, when assessed, a genotype consistent with mutant TP53. Null mdm2 immunophenotype, coupled with evidence of a specific chromosome translocation t(12;16), was constantly observed in both the usual and the cellular subtypes of myxoid liposarcoma, three cases of which also showed TP53 alterations at the genetic or protein level. Neither mdm2 nor p53 overexpression was observed in the lipomas. The results show the existence of three main pathogenetically distinct groups of liposarcoma. The first retroperitoneal WD–DD group, which represents a novel class of tumours within a single histological category of sarcoma, where MDM2‐mediated inactivation of p53 could be related to the pathogenetic mechanism. The second is the non‐retroperitoneal WD–DD group, where the TP53 mutations appear to correlate with the dedifferentiation process. The third is the myxoid group, which is characterized by its own unique cytogenetic profile and never shows any involvement of TP53 or MDM2 genes. As for diagnostic significance, the absence of mdm2 and p53 reactivity in lipomas seems to represent a useful marker for differential diagnosis from lipoma‐like WD liposarcomas. © 1997 by John Wiley & Sons, Ltd.
The use of cfDNA quantification to predict adenocarcinoma at an early stage in high-risk (aged >50 years and FOBT positive) subjects seems to be promising but needs more sensitive methods to improve cfDNA detection.
Cytogenetic and molecular analyses of thyroid tumors have indicated that these neoplasms represent a good model for analyzing human epithelial cell multistep carcinogenesis. They comprise, in fact, a broad spectrum of lesions with different phenotypes and variable biological and clinical behavior. Molecular analysis has detected specific genetic alterations in the different types of thyroid tumors. In particular, the well-differentiated carcinomas of the papillary type are characterized by activation of the receptor tyrosine kinases (RTKs), RET and NTRK1 proto-oncogenes. Cytogenetic analysis of these tumors has contributed to defining the chromosomal mechanisms leading to RTK oncogenic activation. In the majority of cases, intrachromosomal inversions of chromosome 10 and chromosome 1 led to the formation of RET-derived and NTRK1-derived oncogenes, respectively. Interestingly, molecular analysis of these oncogenes revealed their nature of chimeric fusion proteins all sharing the tyrosine kinase (TK) domains of the respective proto-oncogenes. Moreover, the sequencing of the oncogenic rearrangements led to the identification of a breakpoint cluster region in both RTK proto-oncogenes. Exposure to ionizing radiation is associated with papillary carcinomas and RET activation has been suggested to be related to this event. Conversely, RAS point mutations are frequently observed in tumors with follicular histology and have been associated with metastatic dissemination. Iodide-deficient areas seem to provide a higher frequency of RAS positive follicular carcinomas. Finally, a high prevalence of TPS3 point mutations has been detected only in undifferentiated or anaplastic carcinomas and found to correlate inversely with 8CL2 expression. All of these findings are contributing to the definition of genetic and environmental factors relevant for the pathogenesis of thyroid tumors. Moreover, the characterization of specific genetic lesions could provide significant molecular tools for a better differential diagnosis and for the development of novel therapeutic avenues for thyroid cancer.
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