Because existing surgical and management methods can consistently cure only early-stage ovarian cancer, novel strategies for early detection are required. Silencing of tumor suppressor genes such as p16 INK4a , VHL, and hMLH1 have established promoter hypermethylation as a common mechanism for tumor suppressor inactivation in human cancer and as a promising target for molecular detection in bodily fluids. Using sensitive methylation-specific PCR, we screened matched tumor, preoperative serum or plasma, and peritoneal fluid (washes or ascites) DNA obtained from 50 patients with ovarian or primary peritoneal tumors for hypermethylation status of the normally unmethylated BRCA1 and RAS association domain family protein 1A tumor suppressor genes. Hypermethylation of one or both genes was found in 34 tumor DNA (68%). Additional examination of one or more of the adenomatous polyposis coli, p14 ARF , p16INK4a , or death associated protein-kinase tumor suppressor genes revealed hypermethylation in each of the remaining 16 tumor DNA, which extended diagnostic coverage to 100%. Hypermethylation was observed in all histologic cell types, grades, and stages of ovarian tumor examined. An identical pattern of gene hypermethylation was found in the matched serum DNA from 41 of 50 patients (82% sensitivity), including 13 of 17 cases of stage I disease. Hypermethylation was detected in 28 of 30 peritoneal fluid DNA from stage IC-IV patients, including 3 cases with negative or atypical cytology. In contrast, no hypermethylation was observed in nonneoplastic tissue, peritoneal fluid, or serum from 40 control women (100% specificity). We conclude that promoter hypermethylation is a common and relatively early event in ovarian tumorigenesis that can be detected in the serum DNA from patients with ovary-confined (stage IA or B) tumors and in cytologically negative peritoneal fluid. Analysis of tumor-specific hypermethylation in serum DNA may enhance early detection of ovarian cancer.
Purpose: Breast cancer is the most common malignancy in American women and the second leading cause of death from cancer. The genetic and epigenetic alterations that initiate and drive cancer can be used as targets for detection of neoplasia in bodily fluids. Tumor cell-specific aberrant promoter hypermethylation can be detected in nipple aspirate and ductal lavage from breast cancer patients. In this study, we examine serum, a more readily accessible bodily fluid known to contain neoplastic DNA from individuals with cancer, for methylation-based detection of breast neoplasia.Experimental Design: We examined the promoter methylation status of three normally unmethylated biologically significant cancer genes, RAS association domain family protein 1A (RASSF1A), adenomatous polyposis coli (APC), and death-associated protein kinase (DAP-kinase), by sensitive methylation-specific PCR in 34 breast tumor and paired preoperative serum DNA. The 34 patients comprised 7 ductal carcinoma in situ (CIS), 3 lobular CIS, 5 stage I and 15 stage II to IV invasive ductal carcinomas, and 4 invasive lobular carcinomas. Normal and benign tissue and serum control DNA were also examined to determine the specificity of hypermethylation.Results: Hypermethylation of one or more genes was found in 32 of 34 (94%) breast tumor DNA. APC was hypermethylated in 15 of 34 (47%), RASSF1A in 22 of 34 (65%), and DAP-kinase in 17 of 34 (50%) tumors. Twentysix (76%) of the corresponding serum DNA were positive for promoter hypermethylation, including ductal CIS, lobular CIS, stage I disease, and lobular carcinoma patients. No hypermethylation of APC, RASSF1A, or DAP-kinase was observed in serum DNA from normal healthy women and patients with inflammatory breast disease or nonneoplastic breast tissue specimens. A gene unmethylated in the tumor DNA was always found to be unmethylated in the matched serum DNA (100% specificity).Conclusions: Tumor cell specific promoter hypermethylation of APC, RASSF1A, and DAP-kinase is present in ductal CIS, lobular CIS, and all grades and stages of invasive breast cancer. Hypermethylation can be detected by methylation-specific PCR analysis in serum DNA from patients with preinvasive and early-stage breast cancer amenable to cure. If confirmed in additional studies, hypermethylation-based screening of serum, a readily accessible bodily fluid, may enhance early detection of breast cancer.
Purpose: Promoter hypermethylation is an important mechanism of inactivation of tumor suppressor genes in cancer cells. Kidney tumors are heterogeneous in their histology, genetics, and clinical behavior. To gain insight into the role of epigenetic silencing of tumor suppressor and cancer genes in kidney tumorigenesis, we determined a hypermethylation profile of kidney cancer.Experimental Design: We examined the promoter methylation status of 10 biologically significant tumor suppressor and cancer genes in 100 kidney tumors (50 clear cell, 20 papillary, 6 chromophobe, 5 collecting duct, 5 renal cell unclassified, 7 oncocytoma, 6 transitional cell carcinomas of the renal pelvis, and 1 Wilms' tumor) by methylationspecific PCR. The hypermethylation profile was examined with regard to clinicopathological characteristics of the kidney cancer patients.Results: Hypermethylation of one or more genes was found in 93 (93%) of 100 tumors. A total of 33% of kidney tumors had one gene, 35% two genes, 14% three genes, and 11% four or more genes hypermethylated. The frequency of hypermethylation of the 10 genes in the 100 tumor DNAs was VHL 8% (all clear cell), p16INK4a 10%, p14 ARF 17%, APC 14%, MGMT 7%, GSTP1 12%, RAR2 12%, RASSF1A 45%, E-cadherin 11%, and Timp-3 58%. Hypermethylation was observed in all of the histological cell types and grades and stages examined. No hypermethylation was observed in specimens of normal kidney or ureteral tissue from 15 patients. Hypermethylation of VHL was specific to clear cell tumors. RASSF1A methylation was detected at a significantly higher frequency in papillary renal cell tumors and in high-grade tumors of all cell types. MGMT methylation was more frequent in nonsmokers. Simultaneous methylation of five or more genes was observed in 3 (3%) of 100 tumors and may indicate a methylator phenotype in kidney cancer. In addition, the CpG island in the promoter of the fumarate hydratase (FH) tumor suppressor gene was bisulfite sequenced and was found to be unmethylated in 15 papillary renal tumors.Conclusions: Promoter hypermethylation is common, can occur relatively early, may disrupt critical pathways, and, thus, likely plays an important role in kidney tumorigenesis. A hypermethylation profile may be useful in predicting a patient's clinical outcome and provide molecular markers for diagnostic and prognostic approaches to kidney cancer.
Aberrant promoter hypermethylation is a common mechanism for inactivation of tumor suppressor genes in cancer cells. To generate a global profile of genes silenced by hypermethylation in renal cell cancer (RCC), we did an expression microarray-based analysis of genes reactivated in the 786-0, ACHN, HRC51, and HRC59 RCC lines after treatment with the demethylating drug 5-aza-2 deoxycytidine and histone deacetylation inhibiting drug trichostatin A. Between 111 to 170 genes were found to have at least 3-fold upregulation of expression after treatment in each cell line. To establish the specificity of the screen for identification of genes, epigenetically silenced in cancer cells, we validated a subset of 12 up-regulated genes. Three genes (IGFBP1, IGFBP3, and COL1A1) showed promoter methylation in tumor DNA but were unmethylated in normal cell DNA. One gene (GDF15) was methylated in normal cells but more densely methylated in tumor cells. One gene (PLAU) showed cancer cell-specific methylation that did not correlate well with expression status. The remaining seven genes had unmethylated promoters, although at least one of these genes (TGM2) may be regulated by RASSF1A, which was methylated in the RCC lines. Thus, we were able to show that up-regulation of at least 6 of the 12 genes examined was due to epigenetic reactivation. The IGFBP1, IGFBP3, and COL1A1 gene promoter regions were found to be frequently methylated in primary renal cell tumors, and further study will provide insight into the biology of the disease and facilitate translational studies in renal cancer. (Cancer Res 2006; 66(10): 5021-8)
Cisplatin-based chemotherapy is the paradigm of non-smallcell lung cancer (NSCLC) treatment; however, it also induces de novo DNA-hypermethylation, a process that may be involved in the development of drug-resistant phenotypes by inactivating genes required for drug-cytotoxicity. By using an expression microarray analysis, we aimed to identify those genes reactivated in a set of two cisplatin (CDDP) resistant and sensitive NSCLC cell lines after epigenetic treatment. Gene expression, promoter methylation and CDDP-chemoresponse were further analyzed in three matched sets of sensitive/resistant cell lines, 23 human cancer cell lines and 36 NSCLC specimens. Results revealed specific silencing by promoter hypermethylation of IGFBP-3 in CDDP resistant cells, whereas IGFBP-3 siRNA interference, induced resistance to CDDP in sensitive cells (Po0.001). In addition, we found a strong correlation between methylation status and CDDP response in tumor specimens (Po0.001). Thus, stage I patients, whose tumors harbor an unmethylated promoter, had a trend towards increased disease-free survival (DFS). We report that a loss of IGFBP-3 expression, mediated by promoter-hypermethylation, results in a reduction of tumor cell sensitivity to cisplatin in NSCLC. Basal methylation status of IGFBP-3 before treatment may be a clinical biomarker and a predictor of the chemotherapy outcome, helping to identify patients who are most likely to benefit from CDDP therapy alone or in combination with epigenetic treatment.
Lung cancer is the top cause of cancer-related deceases. One of the reasons is the development of resistance to the chemotherapy treatment. In particular, cancer stem cells (CSCs), can escape treatment and regenerate the bulk of the tumor. In this article, we describe a comparison between cancer cells resistant to cisplatin and CSCs, both derived from the non-small-cell lung cancer cell lines H460 and A549. Cisplatin-resistant cells were obtained after a single treatment with the drug. CSCs were isolated by culture in defined media, under nonadherent conditions. The isolated CSCs were clonogenic, could be differentiated into adherent cells and were less sensitive to cisplatin than the original cells. Cisplatin resistant and CSCs were able to generate primary tumors and to metastasize when injected into immunodeficient Nu/Nu mice, although they formed smaller tumors with a larger latency than untreated cells. Notably, under appropriated proportions, CSCs synergized with differentiated cells to form larger tumors. CSCs also showed increased capacity to induce angiogenesis in Nu/Nu mice. Conversely, H460 cisplatin-resistant cells showed increased tendency to develop bone metastasis. Gene expression analysis showed that several genes involved in tumor development and metastasis (EGR1, COX2, MALAT1, AKAP12, ADM) were similarly induced in CSC and cisplatin-resistant H460 cells, in agreement with a close similarity between these two cell populations. Cells with the characteristic growth properties of CSCs were also isolated from surgical samples of 18 out of 44 lung cancer patients. A significant correlation (P = 0.028) was found between the absence of CSCs and cisplatin sensitivity.
The 'cancer cell fusion' theory is controversial due to the lack of methods available to identify hybrid cells and to follow the phenomenon in patients. However, it seems to be one of the best explanations for both the origin and metastasis of primary tumors. Herein, we co-cultured lung cancer stem cells with human monocytes and analyzed the dynamics and properties of tumor-hybrid cells (THC), as well as the molecular mechanisms beneath this fusion process by several techniques: electron-microscopy, karyotyping, CRISPR-Cas9, RNA-seq, immunostaining, signaling blockage, among others. Moreover, mice models were assessed for in vivo characterization of hybrids colonization and invasiveness. Then, the presence of THCs in bloodstream and samples from primary and metastatic lesions were detected by FACS and immunofluorescence protocols, and their correlations with TNM stages established. Our data indicate that the generation of THCs depends on the expression of CD36 on tumor stem cells and the oxidative state and polarization of monocytes, the latter being strongly influenced by microenvironmental fluctuations. Highly oxidized M2-like monocytes show the strongest affinity to fuse with tumor stem cells. THCs are able to proliferate, colonize and invade organs. THC-specific cell surface signature CD36 + CD14 + PANK + allows identifying them in matched primary tumor tissues and metastases as well as in bloodstream from patients with lung cancer, thus functioning as a biomarker. THCs levels in circulation correlate with TNM classification. Our results suggest that THCs are involved in both origin and spread of metastatic cells. Furthermore, they might set the bases for future therapies to avoid or eradicate lung cancer metastasis.
While it is well known that sepsis inhibits serum IGF-I and its gene expression in the liver, the effect on pituitary GH and IGF-binding protein-3 (IGFBP-3) is poorly understood. The GH-IGF-I-IGFBP-3 response to different doses of lipopolysaccharide (LPS) administration has been investigated in adult male rats. Two experiments were performed, administration of low doses of LPS (5, 10, 50 and 100 µg/kg) and high doses of LPS (100, 250, 500 and 1000 µg/kg). Rats received two i.p. injections of LPS (at 1730 h and 0830 h the following day) and were killed 4 h after the second injection. LPS administration induced a biphasic response in serum concentrations of GH, with an increase at the 10 µg/kg dose, followed by a decrease at higher doses (100 µg/kg on up). Pituitary GH mRNA was also increased by the administration of 10 and 50 µg/kg LPS, whereas at higher doses LPS did not modify pituitary GH mRNA. We also analyzed the GH response to LPS in primary pituitary cell cultures. When exposed to LPS, in the culture medium, there was an increase in GH release at the concentration of 0·1 and 10 ng/ml, whereas more concentrated LPS did not modify GH release. Serum concentrations of IGF-I declined in a dose-dependent fashion after LPS administration in the rats injected with 10 µg/kg LPS on up. This decrease is secondary to modifications in its synthesis in the liver, since endotoxin injection decreased both IGF-I and its mRNA in the liver. The liver GH receptor mRNA was also decreased by LPS administration, but only in the animals injected with high LPS doses. There was a decrease in both the IGFBP-3 serum levels and its gene expression in the liver with all LPS doses studied. These data suggest a biphasic LPS effect on pituitary GH, a stimulatory effect at low doses and an inhibitory effect at higher doses, whereas it has a clear inhibitory effect on IGF-I and IGFBP-3 synthesis in the liver. The decrease in liver IGFBP-3 mRNA and in serum concentrations of IGFBP-3 in the rats injected with LPS may contribute to the decrease in serum concentrations of IGF-I.
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