Thymidylate synthetase allelic imbalance in clear cell renal carcinoma.

PURPOSE: To investigate the allelic status of the thymidylate synthetase (TYMS) gene, located at chromosome band 18p11.32, in renal cell carcinoma (RCC). TYMS is a key target of the 5-fluorouracil (5-FU)-based class of drugs, frequently considered in combination therapies in advanced RCC. TYMS variants, such as the TYMS polymorphic 5'-untranslated region variable number tandem repeat sequence (VNTR), are under investigation to guide 5-FU treatment. Yet, no information is available with regard to changes in TYMS allele frequencies in RCC malignances. METHODS: Blood and matched tumor samples were collected from 41 histological proven clear cell RCC affected patients (30 males, 11 females.). TYMS VNTR genotype was first determined in blood to identify heterozygotes employing PCR techniques. To evaluate for allelic imbalance, fragment analysis was performed both in blood and matched tumor DNA of the heterozygote patients. Microsatellite analysis, employing the markers D18S59 and D18S476 mapping, respectively, at the TYMS locus (18p11.32) and 1.5 Mb downstream of the TYMS gene sequence (18p11.31), was performed to confirm TYMS allelic imbalance in tumors. RESULTS: Germ-line TYMS VNTR distribution was: 2R/2R (19.5%), TYMS 2R/3R (36.6%) and TYMS 3R/3R (43.9%). Allelic imbalance for the TYMS tandem repeat region was detected in 26.6% of the heterozygote patients. Microsatellite analysis confirmed the allelic imbalance detected by TYMS VNTR analysis and revealed that the overall frequence of allelic imbalance of chromosome band 18p11.32 was 35%, while the overall allelic imbalance of chromosome band 18p11.31 was 28%. CONCLUSIONS: By focusing on the TYMS polymorphic variants in renal cancer, we here provide evidence, to our knowledge, for the first time showing loss of 18p11.32 and 18p11.31 in renal cell carcinomas. As allelic imbalances involving TYMS locus may be an important variable affecting 5-FU responsiveness, this study may contribute to explain different responses of advanced RCC in combined chemotherapeutic regimens incorporating fluoropyridines.

Human immunodeficiency virus type 1 Tat protein modulates cell cycle and apoptosis in Epstein-Barr virus-immortalized B cells.

Patients infected with human immunodeficiency virus type 1 (HIV-1) develop a spectrum of B cell lymphoproliferative disorders ranging from polyclonal B cell activation to B cell lymphomas. While a direct role of Epstein-Barr virus (EBV) is well recognized for most of these lesions, recent findings have suggested that transactivator HIV-1 Tat protein might be involved in the pathogenesis of B cell lymphomas. Tat-expressing EBV-positive B cells were generated by transduction with a retroviral Tat-encoding vector. B(Tat+) cells expressed lower levels of anti-apoptotic protein Bcl-2 than parental and control B(Tat-) cells, generated by transduction with an empty retroviral vector, and were more prone to apoptosis upon serum withdrawal, as assessed by analysis of annexin V-stained cells and cleavage of poly-ADP-ribose-polymerase by caspase 3. Nevertheless, in serum starvation, B(Tat-) cells mainly exhibited the Rb hypo-phosphorylated form, underwent cell cycle arrest, and grew in single cell suspension, while B(Tat+) cells displayed the Rb hyper-phoshorylated form, progressed throughout the cell cycle, and retained the ability to grow in small clumps. Finding that B(Tat+) cells maintained proliferative capacity upon serum withdrawal suggests that cells expressing Tat have growth advantages among the EBV-driven cell proliferations and may originate B cell clones with more oncogenic potential.