Browsing by Author "Tanic, Nikola (7801574805)"

Multiple cancers represent 2.42% of all human cancers and are mainly double or triple cancers. Many possible causes of multiple malignancies have been reported such as genetic alterations, exposure to anti-cancer chemotherapy, radiotherapy, immunosuppressive therapy and reduced immunologic response. We report a female patient with multiple sclerosis and quadruple cancers of different embryological origin. Patient was diagnosed with stage III (T3, N1a, MO) medullary thyroid carcinoma (MTC), multicentric micropapillary thyroid carcinoma, scapular and lumbar melanomas (Clark II, Breslow II), and lobular invasive breast carcinoma (T1a, NO, MO). All tumors present in our patient except micropapillary thyroid carcinomas were investigated for gene alterations known to have a key role in cancer promotion and progression. Tumor samples were screened for the p16 alterations (loss of heterozygosity and homozygous deletions), loss of heterozygosity of PTEN, p53 alterations (mutational status and loss of heterozygosity) and mutational status of RET, HRAS and KRAS. Each type of tumor investigated had specific pattern of analyzed genetic alterations. The most prominent genetic changes were mutual alterations in PTEN and p53 tumor suppressors present in breast cancer and two melanomas. These co-alterations could be crucial for promoting development of multiple malignancies. Moreover the insertion in 4th codon of HRAS gene was common for all tumor types investigated. It represents frameshift mutation introducing stop codon at position 5 which prevents synthesis of a full-length protein. Since the inactivated RAS enhances sensitivity to tamoxifen and radiotherapy this genetic alteration could be considered as a good prognostic factor for this patient.

The purpose of this study was to detect the level of genomic instability and p53 alterations in anaplastic astrocytoma and primary glioblastoma patients, and to evaluate their impact on glioma pathogenesis and patients outcome. AP-PCR DNA profiling revealed two types of genetic differences between tumor and normal tissue: qualitative changes which represent accumulation of changes in DNA sequence and are the manifestation of microsatellite and point mutation instability (MIN-PIN) and quantitative changes which represent amplifications or deletions of existing chromosomal material and are the manifestation of chromosomal instability (CIN). Both types of alterations were present in all analyzed samples contributing almost equally to the total level of genomic instability, and showing no differences between histological subtypes. p53 alterations were detected in 40% of samples, predominantly in anaplastic astrocytoma. The higher level of genomic instability was observed in elderly patients (> 50. years) and patents with primary glioblastoma. Level of genomic instability had no impact on patients' survival, while presence of p53 alterations seemed to be a favorable prognostic factor in this case. Our results indicate that extensive genomic instability is one of the main features of malignant gliomas. © 2012 Elsevier Inc.

The purpose of this study was to detect the level of genomic instability and p53 alterations in anaplastic astrocytoma and primary glioblastoma patients, and to evaluate their impact on glioma pathogenesis and patients outcome. AP-PCR DNA profiling revealed two types of genetic differences between tumor and normal tissue: qualitative changes which represent accumulation of changes in DNA sequence and are the manifestation of microsatellite and point mutation instability (MIN-PIN) and quantitative changes which represent amplifications or deletions of existing chromosomal material and are the manifestation of chromosomal instability (CIN). Both types of alterations were present in all analyzed samples contributing almost equally to the total level of genomic instability, and showing no differences between histological subtypes. p53 alterations were detected in 40% of samples, predominantly in anaplastic astrocytoma. The higher level of genomic instability was observed in elderly patients (> 50. years) and patents with primary glioblastoma. Level of genomic instability had no impact on patients' survival, while presence of p53 alterations seemed to be a favorable prognostic factor in this case. Our results indicate that extensive genomic instability is one of the main features of malignant gliomas. © 2012 Elsevier Inc.

Multidrug resistance (MDR) is the main obstacle to a successful chemotherapy of lung cancer. We tested the potential of sulfinosine and curcumin, alone and in combination, for modulating MDR in the human resistant, non-small cell lung carcinoma cell line (NCI-H460/R). First, we determined the mutational status of the p53 gene in NCI-H460/R cells by PCR-SSCP and DNA sequencing and identified mutations which could at least partially contribute to the development of the MDR phenotype. The effects of sulfinosine and curcumin were studied, both separately and in combination, at the level of cytotoxicity, cell cycle distribution and gene expression. Sulfinosine displayed dose-dependent growth inhibition in both resistant and control sensitive cell lines, whereas curcumin considerably inhibited their growth only at relatively high doses. When sulfinosine was combined with a low dose of curcumin the drugs exerted a synergistic cytotoxic effect in NCI-H460/R cells. The expression of MDR-related genes mdr1, gst-π and topo IIα, was altered by sulfinosine and curcumin. The most pronounced effect was observed when the agents were applied together. Sulfinosine and curcumin caused perturbations in cell cycle distribution in the NCI-H460/R cell line. The combination of the two drugs induced a more pronounced cell cycle arrest in S and G2/M in NCI-H460/R cells. Our results show that sulfinosine and curcumin overcome MDR in non-small cell lung carcinoma cell line (NSCLC), especially in combination despite the presence of a mutated p53 gene. ©2008 Landes Bioscience.

Multidrug resistance (MDR) is the main obstacle to a successful chemotherapy of lung cancer. We tested the potential of sulfinosine and curcumin, alone and in combination, for modulating MDR in the human resistant, non-small cell lung carcinoma cell line (NCI-H460/R). First, we determined the mutational status of the p53 gene in NCI-H460/R cells by PCR-SSCP and DNA sequencing and identified mutations which could at least partially contribute to the development of the MDR phenotype. The effects of sulfinosine and curcumin were studied, both separately and in combination, at the level of cytotoxicity, cell cycle distribution and gene expression. Sulfinosine displayed dose-dependent growth inhibition in both resistant and control sensitive cell lines, whereas curcumin considerably inhibited their growth only at relatively high doses. When sulfinosine was combined with a low dose of curcumin the drugs exerted a synergistic cytotoxic effect in NCI-H460/R cells. The expression of MDR-related genes mdr1, gst-π and topo IIα, was altered by sulfinosine and curcumin. The most pronounced effect was observed when the agents were applied together. Sulfinosine and curcumin caused perturbations in cell cycle distribution in the NCI-H460/R cell line. The combination of the two drugs induced a more pronounced cell cycle arrest in S and G2/M in NCI-H460/R cells. Our results show that sulfinosine and curcumin overcome MDR in non-small cell lung carcinoma cell line (NSCLC), especially in combination despite the presence of a mutated p53 gene. ©2008 Landes Bioscience.

Anaplastic thyroid carcinoma (ATC) is a rare, but aggressive and chemoresistant tumor with dismal prognosis. Most ATCs harbor mutations that activate RAS/MAPK/ERK and PI3K/AKT/mTOR pathways. Therefore, we investigated and correlated the expression of phosphatase and tensin homolog, pERK, and pAKT proteins as well as mutations of BRAF, RAS, and p53 genes in samples of patients with ATC. Furthermore, we evaluated the potential of inhibition of these pathways on chemosensitization of ATC using 2 thyroid carcinoma cell lines (FRO and SW1736). Our results revealed a negative correlation between the activity of RAS-MAPK-ERK and PI3K-AKT-mTOR pathways in samples of patients. To be specific, the PI3K-AKT-mTOR pathway was suppressed in patients with activated NRAS or high pERK expression. In vitro results suggest that the inhibition of either RAS-MAPK-ERK or PI3K-AKT-mTOR components may confer sensitivity of thyroid cancer cells to classic chemotherapeutics. This may form a basis for the development of novel genetic-based therapeutic approach for this cancer type. © 2014 Elsevier Inc.

Tamoxifen is a standard therapeutical treatment in patients with estrogen receptor positive breast carcinoma. However, less than 50% of estrogen receptor positive breast cancers do not respond to tamoxifen treatment whereas 40% of tumors that initially respond to treatment develop resistance over time. The underlying mechanisms for tamoxifen resistance are probably multifactorial but remain largely unknown. The primary aim of this study was to investigate the impact of PTEN tumor suppressor gene on acquiring resistance to tamoxifen by analyzing loss of heterozygosity (LOH) and immunohystochemical expression of PTEN in 49 primary breast carcinomas of patients treated with tamoxifen as the only adjuvant therapy. The effect of PTEN inactivation on breast cancer progression and disease outcome was also analyzed. Reduced or completely lost PTEN expression was observed in 55.1% of samples, while 63.3% of samples displayed LOH of PTEN gene. Inactivation of PTEN immunoexpression significantly correlated with the PTEN loss of heterozygosity, suggesting LOH as the most important genetic mechanism for the reduction or complete loss of PTEN expression in primary breast carcinoma. Most importantly, LOH of PTEN and consequential reduction of its immunoexpression showed significant correlation with the recurrence of the disease. Besides, our study revealed that LOH of PTEN tumor suppressor was significantly associated with shorter disease free survival, breast cancer specific survival and overall survival. In summary, our results imply that LOH of PTEN could be used as a good prognostic characteristic for the outcome of breast cancer patients treated with tamoxifen. © 2012 Landes Bioscience.

Tamoxifen is a standard therapeutical treatment in patients with estrogen receptor positive breast carcinoma. However, less than 50% of estrogen receptor positive breast cancers do not respond to tamoxifen treatment whereas 40% of tumors that initially respond to treatment develop resistance over time. The underlying mechanisms for tamoxifen resistance are probably multifactorial but remain largely unknown. The primary aim of this study was to investigate the impact of PTEN tumor suppressor gene on acquiring resistance to tamoxifen by analyzing loss of heterozygosity (LOH) and immunohystochemical expression of PTEN in 49 primary breast carcinomas of patients treated with tamoxifen as the only adjuvant therapy. The effect of PTEN inactivation on breast cancer progression and disease outcome was also analyzed. Reduced or completely lost PTEN expression was observed in 55.1% of samples, while 63.3% of samples displayed LOH of PTEN gene. Inactivation of PTEN immunoexpression significantly correlated with the PTEN loss of heterozygosity, suggesting LOH as the most important genetic mechanism for the reduction or complete loss of PTEN expression in primary breast carcinoma. Most importantly, LOH of PTEN and consequential reduction of its immunoexpression showed significant correlation with the recurrence of the disease. Besides, our study revealed that LOH of PTEN tumor suppressor was significantly associated with shorter disease free survival, breast cancer specific survival and overall survival. In summary, our results imply that LOH of PTEN could be used as a good prognostic characteristic for the outcome of breast cancer patients treated with tamoxifen. © 2012 Landes Bioscience.