Although our results are in line with previous findings of the presence of wild-type P53 in TGCTs, they show that a high level of P53 does not relate directly to treatment sensitivity of these tumors, and inactivation of P53 is not a common event in the development of cisplatin resistance.
Summary Loss of heterozygosity (LOH) frequently occurs in squamous cell carcinomas of the uterine cervix and indicates the probable sites of tumour-suppressor genes that play a role in the development of this tumour. To define the localization of these tumour-suppressor genes, we studied loss of heterozygosity in 64 invasive cervical carcinomas (stage IB and IIA) using the polymerase chain reaction with 24 primers for polymorphic repeats of known chromosomal localization. Chromosomes 3, 11, 13, 16 and 17, in particular, were studied. LOH was frequently found on chromosome 11, in particular at 11 q22 (46%) and 11 q23.3 (43%). LOH on chromosome 11p was not frequent. On chromosome 17p1 3.3, a marker (Dl 7S513) distal to p53 showed 38% LOH, whereas p53 itself showed only 20% LOH. On the short arm of chromosome 3, LOH was frequently found (41%) at 3p21.1. The f-catenin gene is located in this chromosomal region. Therefore, expression of f-catenin protein was studied in 39 cases using immunohistochemistry. Staining of 1-catenin at the plasma membrane of tumour cells was present in 38 cases and completely absent in only one case. The tumour-suppressor gene on chromosome 3p21.1 may be ,B-catenin in this one case, but (an)other tumour-suppressor gene(s) must also be present in this region. For the other chromosomes studied, 1 3q (BRCA-2) and 16q (E-cadherin), only sporadic losses (< 15% of cases) were found. Expression of E-cadherin was found in all of 37 cases but in six cases the staining was very weak. No correlation was found between clinical and histological parameters and losses on chromosome 3p, 1 1 q and 1 7p. In addition to LOH, microsatellite instability was found in one tumour for almost all loci and in eight tumours for one to three loci. In conclusion, we have identified three loci with frequent LOH, which may harbour new tumour-suppressor genes, and found microsatellite instability in 14% of cervical carcinomas.
Oosterhuis JW, Kersemaekers AMF, Jacobsen GK, Timmer A, Steyerberg EW, Molier M, van Weeren PC, Stoop H, Looijenga LHJ. Morphology of testicular parenchyma adjacent to germ cell tumours. An interim report. APMIS 2003;111:32-42.A comparative morphological analysis of parenchyma adjacent to testicular germ cell tumours (TGCT) was performed in a series of 181 orchidectomy specimens: 86 with seminomas (Se), 72 with nonseminomatous germ cell tumours (NS) and 23 with combined tumours (CT, which have a Se and a NS component). The following morphological features were semiquantitatively scored: spermatogenesis (modified Johnsen score); amount of tubular atrophy; amount of carcinoma in situ (CIS); amount of intertubular tissue. Absence and presence was scored for the following features: lymphocytic infiltrate surrounding and invading CIS; intratubular seminoma (ISe); intratubular nonseminoma (INS); microlithiasis; diffuse and nodular hyperplasia of Leydig cells; angioinvasiveness; testicular angiopathy. Using non-parametric statistics these features were correlated with each other and with tumour type, tumour size and age of the patient. Se-patients presented at significantly higher age than NS-patients (36 vs 29 years, pΩ0.001). The age of patients with CT (32 years) was in between that of Se-and NS-patients. No correlation was found between patient age and tumour size. Parenchyma adjacent to Se, compared to parenchyma adjacent to NS had the following significant differences: a lower Johnsen score (5.6 vs 7.2, pΩ0.005); less frequent (85% vs 97% of specimens, pΩ0.016) and a lesser amount of CIS (26% vs 32% of tubules, pΩ0.015); more frequent peri-(80% vs 60% of specimens, pΩ0.001) and intratubular (68% vs 30% of specimens, pΩ0.001) lymphocytic infiltrates; more extensive tubular atrophy (36% vs 15% of tubules, pΩ0.001); and a larger area of intertubular tissue (42% vs 34% of parenchyma area, pΩ0.016). The pooled Se and CT had a significantly higher frequency of ISe than the NS (31% vs 17% of specimens, pΩ0.036). With one exception INS was only found adjacent to NS or CT, with a frequency of 16%, and 20% of the specimens, respectively. It was significantly associated with angio-invasiveness. In specimens lacking angio-invasion the frequency of INS was 6%. The correlation of INS with tumour size and patient age was studied in a series of 145 NS and CT (95 from the original series supplemented by 50 newer cases). In this series INS was significantly associated with smaller tumours and younger patients. Extensive tubular atrophy was significantly correlated with higher age, the diagnosis of Se, a low Johnsen score, and the presence of angiopathy. The more tubular atrophy, the less CIS (both in incidence and amount). Inversely, a higher Johnsen score is associated with smaller tumours, the diagnosis of NS or CT, a higher incidence and a larger amount of CIS, and little tubular atrophy. Tubules with mature spermatogenesis were found in 42% of the specimens regardless of tumour type. We conclude that ISe and INS are probably fr...
In a minority of cervical carcinomas, a distinct adenocarcinoma and squamous cell carcinoma component can be recognized. These tumors are considered collision tumors; the differential diagnosis is adenosquamous carcinoma. To investigate whether the squamous and adenocarcinoma component are of multiclonal or monoclonal origin, we used loss of heterozygosity (LOH) as a method to establish clonality. Each tumor component of two tumors with a distinct adenocarcinoma and squamous cell carcinoma component were microdissected and the presence of LOH was studied for nine chromosomes, i.e., 1, 2, 3, 6, 11, 15, 17, 18, and X, which are known to contain frequent LOH in cervical cancer. The tumor of patient AK13 showed identical LOH in both the adenocarcinoma and squamous cell carcinoma tissue with various microsatellite markers on chromosomes 1, 2, 6, 18, and X. For markers on chromosomes 3 and 15, different LOH patterns were found in both components. The squamous epithelium showed LOH on chromosome 3, whereas the adenocarcinoma component had LOH on chromosome 15. For patient AK18 the LOH pattern on chromosomes 6p and 17 was the same in the adenocarcinoma and the squamous cell carcinoma component. The adenocarcinoma component showed additional LOH on chromosomes 6q and chromosome 11q. The tumor of patient AK18 showed common boundaries of LOH in both components on chromosome 17q, between markers D17S578 and D17S250. In conclusion, the squamous cell carcinoma and adenocarcinoma components in both tumors most likely have one cell of origin because many genetic alterations are the same in each component. The presence of genetic changes uniquely associated with one of the tumors favors a diversion of developmental pathways.
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