Gene polymorphism profiles of drug-metabolising enzymes GSTM1, GSTT1 and GSTP1 in an Argentinian population.

BACKGROUND: Glutathione S-transferases (GSTs) are drug-metabolising enzymes involved in biotransformation of carcinogens, drugs, xenobiotics and oxygen free radicals. Polymorphisms of GST genes contribute to inter-individual and population variability in the susceptibility to environmental risk factors, cancer predisposition and pharmacotherapy responses. However, data about GST variability in Argentina are lacking. AIM: The purpose was to determine the prevalence of GSTM1, GSTT1 and GSTP1 polymorphisms in the general population from a central region of Argentina and to perform inter-population comparisons. SUBJECTS AND METHODS: GSTM1 and GSTT1 gene deletions and GSTP1 c.313A > G were genotyped by PCR assays in 609 healthy and unrelated Argentinians. RESULTS: The frequencies of variant genotypes in Argentinians were GSTM1-null (45%), GSTT1-null (17%) and GSTP1-GG (11%). GSTM1-present genotype was significantly associated with GSTP1-AG or GSTP1-GG variants (p = 0.037; p = 0.034, respectively). Comparison with worldwide populations demonstrated that the GST distributions in Argentina are similar to those reported for Italy and Spain, whereas significant differences were observed regarding Asian and African populations (p < 0.001). CONCLUSION: This study has determined, for the first time, the normative profile of three pharmacogenetically relevant polymorphisms (GSTM1, GSTT1 and GSTP1) in the largest Argentinian cohort described to date, providing the basis for further epidemiological and pharmacogenetic studies in this country.

Analysis association between mitochondrial genome instability and xenobiotic metabolizing genes in human breast cancer.

The aim of this study was to determine the existence of association between the genetic polymorphisms of metabolizing genes GSTM-1, GSTT-1, and NAT-2, and the presence of mitochondrial genome instability (mtGI) in breast cancer cases. Ninety-four pairs of tumoral/nontumoral breast cancer samples were analyzed. Our samples showed 40.42% of mtGI by analysis of two D-loop region markers, a (CA)n mtMS starting at the 514-bp position, and four informative MnlI sites between the 16,108-16,420-bp. GSTM-1 null genotype has shown a significant association with mtGI presence (chi(2) = 7.62; P = 0.006) in breast cancer cases; moreover, these genotypes also are related to an increased risk for mtDNA damage (odds ratio [OR] = 3.71 [1.41-9.88]; 95% Cornfield confidence interval [CI]). These results suggest that the absence of GSTM-1 enzymatic activity favors chemical actions in damaging the mtDNA. Analysis of GSTT-1 and NAT-2 polymorphisms showed no association with mtGI (chi(2) = 0.03; P = 0.87 and chi(2) = 2.76; P = 0.09, respectively). The analysis of invasive breast cancer cases showed mtGI in 74.36% of ILC cases (29 of 39 samples), and in only 18.75% (9 out of 48) IDC cases; this result suggests a possible relation between mtDNA mutations and variations in molecular pathways of tumor development.

Correlation analysis between mtDNA 4977-bp deletion and ageing.

Mitochondrial DNA 4977-bp deletion (common deletion) has been associated with ageing human tissues and a few studies have demonstrated their presence in breast cancer patients too; however, no previous publication evaluated both topics in the same samples group. First, when analyzing 95 breast cancer patients, we found a higher percentage of cases carrying the deletion in non-tumoral tissue 73.68% (70/95) than in the tumoral counterparts 45.26% (43/95), showing that the 4977-bp deletion is a phenomenon which commonly appear first in the non-tumoral breast tissue rather than tumoral tissue. Secondly, we analyzed and compared the ageing related distribution of the common deletion rates, in a control group of 199 samples (ages ranging from 10 to 80 years), with those found in cancer patients. Significant correlation was observed in control cases, between individual age ranges and rates of deletion (chi2: 23.21 and p<0.01). In contrast, non-tumoral breast tissue did not show a pattern of correlation, chi2: 0.042 and p: 0.837. However, interestingly, we found that the risk of having deleted mtDNAs was higher for non-tumoral breast samples than for the control group samples, OR: 2.32 [1.22-4.42, 95% CI]; this could be reflecting that other mechanisms are involved in mitochondrial genome deletion increased rate detected in breast cancer cases, than the normal ageing process.

Y chromosome instability in testicular cancer.

Approximately 15-25% of male infertility cases carry extensive azoospermic factor (AZF) deletions. Moreover, about 80% of Finnish testicular germ cell tumors (TGCT) and about 23-25% of TGCTs from other geographic regions carry short and interstitial AZF deletions. In infertility cases the AZF deficiency occurs in the germ cells of the proband father giving rise to mosaic sperm populations comprising non-deleted and deleted sperms. Fertilization of an oocyte by a Y deleted sperm will give rise to an AZF-deleted and infertile F1 male. In TGCTs the AZF deletions take place in the initial stages of embryogenesis producing individuals that are a mosaic of Y deleted and non-deleted cell lineages. Carcinoma in situ (CIS) is a premalignant lesion that some believe may develop in gonads of male embryos before the ninth week of age due to transformation of a totipotent primordial germ cell. If the transformed cell carries AZF deletions the resultant CIS will also have Y deletions. CIS will differentiate into seminoma or into embryonal carcinoma and non-seminomas in about 1 x 10(-3) of the young adults carrying premalignant CIS outgrowths; if the CIS lesion has AZF deletions the derived forms of testicular cancer will also exhibit these deletions. AZF deletions play no role in the development of testicular cancers. On the other hand, they are a marker of Y chromosome instability and eventually of a more generalized pattern of genome instability associated with the appearance of TGCT. Genetic factors such as malfunction of metabolizing genes, DNA repairing genes, Y-linked or X-linked genes have been considered as possible causes of AZF deletions in testicular cancer. Yet, the exact identification of the genes involved remains elusive. AZF deletions have also been identified in non-Hodgkin lymphomas and in colorectal cancers, two forms of malignancy that have been found to be associated with TGCTs.

Sensitization to oxaliplatin in HCT116 and HT29 cell lines by metformin and ribavirin and differences in response to mitochondrial glutaminase inhibition.

AIM OF STUDY: In the present study, we evaluated the effect of ribavirin and metformin on the sensitivity of oxaliplatin and 5-fluorouracil (5-FU) on colon cancer. MATERIALS AND METHODS: Cell viability of two commercially available colon cancer cell lines (HT29 and HCT116) were analyzed by sulforhodamine B (SRB) assay. RESULTS: A clinically achievable and nontoxic concentration of ribavirin and metformin showed a significant synergistic effect on oxaliplatin in HT29 and HCT116 cell lines. Ribavirin showed a synergistic effect on oxaliplatin in HT29 (R = 2.93, P < 0.001) and HCT116 (R = 1.71, P < 0.001), while only in HT29 metformin synergized with oxaliplatin by 2.66 (± 0.28, P < 0.01). In addition, both cell lines showed significant differences in response to Compound 968, inhibitor of mitochondrial glutaminase activity. CONCLUSION: The data suggested that these cell lines not only turn to metabolic different sustainability process after oxaliplatin treatment but that they also have different basal metabolic requirements of glutamine in vitro which can be exploits in the future for colorectal cancer (CRC) treatment and further studies are required.

Mosaic AZF deletions and susceptibility to testicular tumors.

We tested for azoospermia factor (AZF) deletions 17 loci corresponding to AZF subintervals a-d in 17 cases of testicular tumors occurring in Finns. While DNA samples from 48 CEPH and 32 Finnish males showed no deletions, patients with testicular cancer displayed AZF deletion mosaicisms in various non-tumor tissues (13 cases) and specific deletion haplotypes in tumor tissues (10 cases). Two of the cases with AZF deletions were testicular non-Hodgkin lymphomas indicating that Y-microdeletions appear also in malignancies other than seminoma and non-seminoma tumors. In good agreement with this assumption, we detected one AZF deletion in normal cells from 1 of 5 HNPCC cases, heterozygous for an MLH1 mutation. We propose that AZF deletions occur in early embryogenesis due to mutations of TSPY, mismatch repair (MMR), or X-specific genes. Since fathers of testicular, tumor cases did not exhibit AZF deletions, we assumed they were not carriers of the mutation inducing AZF deletion-mosaicisms. Therefore, tumor cases should have received the MMR gene or X mutations via the maternal lineage, or for the case of TSPY and MMR genes via a sperm carrying a mutation occurred in the paternal germ-cell line. We consider AZF microdeletions in non-tumor cells to be part of a broader pattern of chromosome instability producing susceptibility to testicular tumors. Clonal transformation and expansion of one of these tumor-susceptible cell lineages give rise to testicular tumors showing genome anomalies characteristic of testicular cancers (i12p, LOH and genetic imbalance for various autosomal regions, Y- and autosomal MSI, specific AZF deletion haplotypes).