Caspase-2 is involved in cell death induction by taxanes in breast cancer cells.

BACKGROUND: We studied the role of caspase-2 in apoptosis induction by taxanes (paclitaxel, novel taxane SB-T-1216) in breast cancer cells using SK-BR-3 (nonfunctional p53, functional caspase-3) and MCF-7 (functional p53, nonfunctional caspase-3) cell lines. RESULTS: Both taxanes induced apoptosis in SK-BR-3 as well as MCF-7 cells. Caspase-2 activity in SK-BR-3 cells increased approximately 15-fold within 48 h after the application of both taxanes at the death-inducing concentration (100 nM). In MCF-7 cells, caspase-2 activity increased approximately 11-fold within 60 h after the application of taxanes (300 nM). Caspase-2 activation was confirmed by decreasing levels of procaspase-2, increasing levels of cleaved caspase-2 and the cleavage of caspase-2 substrate golgin-160. The inhibition of caspase-2 expression using siRNA increased the number of surviving cells more than 2-fold in MCF-7 cells, and at least 4-fold in SK-BR-3 cells, 96 h after the application of death-inducing concentration of taxanes. The inhibition of caspase-2 expression also resulted in decreased cleavage of initiator caspases (caspase-8, caspase-9) as well as executioner caspases (caspase-3, caspase-7) in both cell lines after the application of taxanes. In control cells, caspase-2 seemed to be mainly localized in the nucleus. After the application of taxanes, it was released from the nucleus to the cytosol, due to the long-term disintegration of the nuclear envelope, in both cell lines. Taxane application led to some formation of PIDDosome complex in both cell lines within 24 h after the application. After taxane application, p21WAF1/CIP1 expression was only induced in MCF-7 cells with functional p53. However, taxane application did not result in a significant increase of PIDD expression in either SK-BR-3 or MCF-7 cells. The inhibition of RAIDD expression using siRNA did not affect the number of surviving SK-BR-3 and MCF-7 cells after taxane application at all. CONCLUSION: Caspase-2 is required, at least partially, for apoptosis induction by taxanes in tested breast cancer cells. We suggest that caspase-2 plays the role of an apical caspase in these cells. Caspase-2 seems to be activated via other mechanism than PIDDosome formation. It follows the release of caspase-2 from the nucleus to the cytosol.

Contribution of the ß-ureidopropionase (UPB1) gene alterations to the development of fluoropyrimidine-related toxicity.

BACKGROUND: An impairment of the 5-fluorouracil (5-FU) catabolic pathway, represented by alterations in the dihydropyrimidine dehydrogenase (DPYD) gene, is considered a crucial factor contributing to the development of 5-FU-related toxicity. The ß-ureidopropionase (BUP1) enzyme catalyzes the final step in the 5-FU catabolic pathway; however, alterations in the UPB1 gene coding for the BUP1 enzyme have not yet been analyzed in fluoropyrimidine (FP)-treated patients suffering from 5-FU-related toxicity. METHODS: We have performed a mutation analysis of the entire coding sequence of UPB1 based on denaturing high-performance liquid chromatography in 113 cancer patients treated by FP-containing regimes. These patients included 67 individuals suffering from severe 5-FU-related toxicity and 46 individuals with excellent tolerance of chemotherapy. RESULTS: Nine UPB1 variants were detected in the subpopulation of patients with severe toxicity, including a novel mutation affecting the coding sequence (c.872_873+11del13). An analysis of UPB1 variants on 5-FU-related toxicity in the population of all analyzed patients revealed an association between the c.-80C>G (rs2070474) variant and gastrointestinal toxicity. A strong positive correlation was found between the carriers of the c.-80 GG genotype and the development of severe (grade 3-4) mucositis (OR = 7.5; 95% CI = 2.60 - 21.60; p = 0.0002). CONCLUSION: Our results suggest that UPB1 variants may contribute to the development of 5-FU-related toxicity in some FP-treated patients; however, the role of UPB1 alterations is probably less significant than that of DPYD alterations.

Contribution of dihydropyrimidinase gene alterations to the development of serious toxicity in fluoropyrimidine-treated cancer patients.

PURPOSE: Decreased 5-fluorouracil catabolism has been considered a major factor contributing to fluoropyrimidine (FP)-related toxicity. Alterations in the dihydropyrimidine dehydrogenase gene coding for the first and rate-limiting enzyme of FP catabolic pathway could explain toxicity in only a limited proportion of FP-treated patients. The importance of gene variants in dihydropyrimidinase (DPYS) coding for subsequent catabolic enzyme of FP degradation is not fully understood. METHODS: We performed genotyping of DPYS based on denaturing high-performance liquid chromatography in 113 cancer patients including 67 with severe FP-related toxicity and 46 without toxicity excellently tolerating FPs treatment. RESULTS: We detected nine DPYS variants including four located in non-coding sequence (c.-1T>C, IVS1+34C>G, IVS1-58T>C, and novel IVS4+11G>T), four silent (c.15G>A, c.216C>T, and novel c.105C>T and c.324C>A), and one novel missense variant c.1441C>T (p.R481W). All novel alterations were detected once only in patients without toxicity. The c.-1T>C and IVS1-58T>C variants were found to modify the risk of toxicity. The CC carriers of the c.-1C alleles were at higher risk of mucositis (OR = 4.13; 95% CI = 1.51-11.31; P = 0.006) and gastrointestinal toxicity (OR = 3.54; 95% CI = 1.59-7.88; P = 0.002), whereas the presence of the IVS1-58C allele decreased the risk of gastrointestinal toxicity (OR = 0.4; 95% CI = 0.17-0.93; P = 0.03) and leucopenia (OR = 0.29; 95% CI = 0.08-1.01; P = 0.05). CONCLUSIONS: Our results indicate that missense and nonsense variants in DPYS are infrequent, however, the development of serious primarily gastrointestinal toxicity could be influenced by non-coding DPYS sequence variants c.-1T>C and IVS1-58T>C.

Lack of large intragenic rearrangements in dihydropyrimidine dehydrogenase (DPYD) gene in fluoropyrimidine-treated patients with high-grade toxicity.

PURPOSE: Deficiency of dihydropyrimidine dehydrogenase (DPD) has been associated with severe fluoropyrimidines (FP) toxicity. Mutations in DPD-coding gene (DPYD) were shown to increase the risk of severe toxicity in FP-treated cancer patients. However, the majority of DPYD alterations characterized in these patients has been considered as polymorphisms and known deleterious mutations are rare and present in only limited subgroup of patients with high toxicity. Recently, the common fragile site FRA1E was mapped within DPYD locus but intragenic rearrangements in DPYD gene were not studied so far. METHODS: We performed the analysis of intragenic rearrangements of DPYD using multiplex ligation-dependent probe amplification in 68 patients with high-grade gastrointestinal and/or hematological toxicity developed at the beginning of FP treatment. RESULTS: We did not detect any deletion/duplication of one or more DPYD exons in analyzed patients. CONCLUSIONS: We assume that rearrangements in DPYD gene play insignificant role in the development of serious FP-related toxicity.