Microenvironment Promotes Tumor Cell Reprogramming in Human Breast Cancer Cell Lines

The microenvironment drives mammary gland development and function, and may influence significantly both malignant behavior and cell growth of mammary cancer cells. By restoring context, and forcing cells to properly interpret native signals from the microenvironment, the cancer cell aberrant behavior can be quelled, and organization re-established. In order to restore functional and morphological differentiation, human mammary MCF-7 and MDA-MB-231 cancer cells were allowed to grow in a culture medium filled with a 10% of the albumen (EW, Egg White) from unfertilized chicken egg. That unique microenvironment behaves akin a 3D culture and induces MCF-7 cells to produce acini and branching duct-like structures, distinctive of mammary gland differentiation. EW-treated MDA-MB-231 cells developed buds of acini and duct-like structures. Both MCF-7 and MDA-MB-231 cells produced β-casein, a key milk component. Furthermore, E-cadherin expression was reactivated in MDA-MB-231 cells, as a consequence of the increased cdh1 expression; meanwhile β-catenin – a key cytoskeleton component – was displaced behind the inner cell membrane. Such modification hinders the epithelial-mesenchymal transition in MDA-MB-231 cells. This differentiating pathway is supported by the contemporary down-regulation of canonical pluripotency markers (Klf4, Nanog). Given that egg-conditioned medium behaves as a 3D-medium, it is likely that cancer phenotype reversion could be ascribed to the changed interactions between cells and their microenvironment.     

Quantitative Proteomics of the Neisseria Gonorrhoeae Cell Envelope and Membrane Vesicles for the Discovery of Potential Therapeutic Targets

Neisseria gonorrhoeae (GC) is a human-specific pathogen, and the agent of a sexually transmitted disease, gonorrhea. There is a critical need for new approaches to study and treat GC infections because of the growing threat of multidrug-resistant isolates and the lack of a vaccine. Despite the implied role of the GC cell envelope and membrane vesicles in colonization and infection of human tissues and cell lines, comprehensive studies have not been undertaken to elucidate their constituents. Accordingly, in pursuit of novel molecular therapeutic targets, we have applied isobaric tagging for absolute quantification coupled with liquid chromatography and mass spectrometry for proteome quantitative analyses. Mining the proteome of cell envelopes and native membrane vesicles revealed 533 and 168 common proteins, respectively, in analyzed GC strains FA1090, F62, MS11, and 1291. A total of 22 differentially abundant proteins were discovered including previously unknown proteins. Among those proteins that displayed similar abundance in four GC strains, 34 were found in both cell envelopes and membrane vesicles fractions. Focusing on one of them, a homolog of an outer membrane protein LptD, we demonstrated that its depletion caused loss of GC viability. In addition, we selected for initial characterization six predicted outer membrane proteins with unknown function, which were identified as ubiquitous in the cell envelopes derived from examined GC isolates. These studies entitled a construction of deletion mutants and analyses of their resistance to different chemical probes. Loss of NGO1985, in particular, resulted in dramatically decreased GC viability upon treatment with detergents, polymyxin B, and chloramphenicol, suggesting that this protein functions in the maintenance of the cell envelope permeability barrier. Together, these findings underscore the concept that the cell envelope and membrane vesicles contain crucial, yet under-explored determinants of GC physiology, which may represent promising targets for designing new therapeutic interventions.Neisseria gonorrhoeae (GC)¹ is an obligate human pathogen and the etiological agent of gonorrhea, a sexually transmitted disease. GC infection remains a significant health and economic burden worldwide (1). It is also the second most commonly reported infectious disease in the United States (2). Gonorrhea ranges from clinically asymptomatic to local genital infections to disseminated bloodstream infections. Asymptomatic infections often have devastating consequences on women''s health including pelvic inflammatory disease, ectopic pregnancy, and infertility (3). Additionally, GC infections facilitate transmission and acquisition of HIV (4). For all of these reasons it is critical to provide effective treatments against gonorrhea. Currently, a dual therapy with cephalosporin and either azithromycin or doxycycline is recommended (5). However, over the past several years treatment failures associated with GC strains displaying decreased susceptibility to extended spectrum cephalosporins have been reported from various parts of the world (6–9). This is especially concerning because no other antibiotics are clinically useful in these cases, and because no appropriate vaccine exists (10). The escalating problem of the spread of antimicrobial resistance in GC, and the importance of the development of new approaches to study, treat, and prevent GC infection, have been recognized by the World Health Organization and by the Centers for Disease Control and Prevention (11, 12).We propose that largely unexplored proteins localized to bacterial cell envelope and naturally released membrane vesicles are particularly promising as potential novel molecular targets for therapeutic interventions against gonorrhea. The small fraction of known components of the GC cell envelope (outer membrane, periplasm, cytoplasmic membrane) plays a fundamental role in establishing infection by enabling the microbes to adhere to and invade host cells, facilitating nutrient acquisition, host tissue destruction, and suppression of immune responses (3, 13–15). Further, GC, like many other Gram-negative bacteria, produces membrane vesicles (MVs), which are nano-sized bilayered proteolipids (16). Naturally produced MVs are potentially an effective way to deliver toxins, enzymes, and other effectors to host tissues. Additionally, evidence from various studies support that MVs participate in intercellular communication and horizontal gene transfer (16–21). In GC, MVs are necessary for biofilm formation, which is thought to play an important role in asymptomatic infection in women, resistance to antimicrobial agents, and suppression of host immune defenses (22–24). MVs may also contribute to the serum resistance by providing an enhanced ability to bind and eliminate bactericidal factors (17).Although the potential importance of proteins localized to the GC cell envelope and MVs has been reported previously (25, 26), only two proteomic studies have been published addressing GC membrane composition (27, 28). Most studies have focused on extensive characterization of factors involved in direct host cell interaction: protruding surface proteins (pili), outer membrane adhesins Opa, porins P.IA and P.IB, lipooligosaccharide, and several iron utilization proteins (3, 4, 15, 29–32). Many of these vital virulence factors undergo phase and/or antigenic variation, making them poor drug or vaccine targets. Therefore, the pursuit for novel and constitutively expressed proteins—therapeutic targets in GC—is of utmost importance.Accordingly, in this study we applied global and unbiased proteomics to compare the composition of both the cell envelopes and MVs isolated from four GC strains: FA1090, F62, MS11, and 1291. Specifically, we used isotope tagging for relative and absolute quantification (iTRAQ) coupled with multidimensional liquid chromatography and tandem mass spectrometry (2D-LC/MS/MS). This approach allowed us to determine a uniformly and differentially expressed repertoire of proteins. Focusing on a homolog of LPS transport protein, LptD (OstA, Imp), which was identified in both the cell envelopes and MVs fractions, and ubiquitously expressed among analyzed strains, we showed that its depletion led to loss of GC viability. Finally, we selected for initial characterization six predicted outer membrane proteins, which were present at similar levels in the GC cell envelopes. We generated Δngo1344, Δngo1955, Δngo1985, Δngo2111, Δngo2121, and Δngo2139 mutant strains and examined their sensitivity toward different cell envelope-perturbing agents as well as chloramphenicol. These studies showed that the lack of NGO1985 resulted in dramatically decreased GC viability, suggesting that this protein functions in the maintenance of the cell envelope permeability barrier. Overall, these findings further support our hypothesis that the conserved proteins may represent promising targets for designing new therapeutic interventions.     

A Multistep Model for Paclitaxel-Induced Apoptosis in Human Breast Cancer Cell Lines

Despite extensive previous investigation, the events occurring between paclitaxel-induced mitotic arrest and the subsequent onset of apoptosis remain incompletely understood. In the present study, the sequential morphological and biochemical changes that occur after paclitaxel treatment were examined in MDA-MB-468 (p53 mutant) and MCF-7 (p53 wild-type) breast cancer cells. Flow cytometry indicated that paclitaxel induces tetraploidy that persists until the onset of apoptosis in both cell lines. Light and electron microscopy indicated that the cells transiently arrest in mitosis and then enter a multinucleated interphase state characterized by the absence of punctate staining for CENP-F, a G(2) marker, but the presence of cyclin E, a G(1) cyclin, and p21(waf1/cip1), a cyclin-dependent kinase inhibitor. Despite high p21(waf1/cip1) levels, paclitaxel-treated cells incorporated thymidine into DNA. Aphidicolin inhibited this DNA synthesis but not the subsequent onset of apoptosis. Conversely, the broad-spectrum caspase inhibitor benzyloxycarbonyl-val-ala-asp(OMe)-fluoromethylketone inhibited apoptosis and enhanced the number of multinucleated cells but did not facilitate generation of octaploid cells. These results are consistent with a multistep model in which breast cancer cells exposed to paclitaxel undergo an aberrant mitotic exit; proceed through a tetraploid, multinucleated G(1) state; initiate an aphidicolin-suppressible process of DNA repair; and subsequently undergo apoptosis.     

人体乳腺癌细胞系Bcap－37和MCF－7的细胞遗传学研究

应用低温同步法与秋水酰胺处理,对人体乳腺癌细胞系Ｂｃａｐ－３７和ＭＣＦ－７的中期及早中期细胞进行Ｇ－显带分析。研究表明,Ｂｃａｐ－３７细胞染色体众数为６３,可识别其结构的标记染色体１７条;ＭＣＦ－７细胞染色体众数为５６,可识别其结构的标记染色体１３条。结合文献报道以及本研究结果显示,乳腺癌中最常涉及到第１、３、５、７、１１、１３和１７号染色体结构及数目的异常,染色体断裂点１ｐ１１（１ｑ１１）、１ｐ１３、３ｐ２１、３ｑ１１、５ｑ１１、６ｑ１３、６ｑ２３、７ｑ２２、１１ｐ１３和１１ｐ１５也经常涉及;它们可能与癌相关基因的激活和抗癌基因的丢失有关,从而在乳腺癌发生发展中起一定作用。     

Vitamin C Effect on Mitoxantrone-Induced Cytotoxicity in Human Breast Cancer Cell Lines

In recent years the use of natural dietary antioxidants to minimize the cytotoxicity and the damage induced in normal tissues by antitumor agents is gaining consideration. In literature, it is reported that vitamin C exhibits some degree of antineoplastic activity whereas Mitoxantrone (MTZ) is a synthetic anti-cancer drug with significant clinical effectiveness in the treatment of human malignancies but with severe side effects. Therefore, we have investigated the effect of vitamin C alone or combined with MTZ on MDA-MB231 and MCF7 human breast cancer cell lines to analyze their dose-effect on the tumor cellular growth, cellular death, cell cycle and cell signaling. Our results have evidenced that there is a dose-dependence on the inhibition of the breast carcinoma cell lines, MCF7 and MDA-MB231, treated with vitamin C and MTZ. Moreover, their combination induces: i) a cytotoxic effect by apoptotic death, ii) a mild G2/M elongation and iii) H2AX and mild PI3K activation. Hence, the formulation of vitamin C with MTZ induces a higher cytotoxicity level on tumor cells compared to a disjointed treatment. We have also found that the vitamin C enhances the MTZ effect allowing the utilization of lower chemotherapic concentrations in comparison to the single treatments.     

Accumulation of Oxidatively Induced DNA Damage in Human Breast Cancer Cell Lines Following Treatment with Hydrogen Peroxide

Breast cancer is a leading cause of cancer deaths in women. Although the causes of this disease are largely unknown, inefficient repair of oxidatively induced DNA lesions has been thought to play a major role in the transformation of normal breast tissue to malignant breast tissue. Previous studies have revealed higher levels of 8-hydroxyguanine in malignant breast tissue compared to non-malignant breast tissue. Furthermore, some breast cancer cell lines have greatly reduced capacity to repair this lesion suggesting that oxidatively induced DNA lesions may be elevated in breast cancer cells. We used liquid chromatography/mass spectrometry and gas chromatography/mass spectrometry to measure the levels of 8-hydroxy-2’-deoxyadenosine, (5’S)-8,5’-cyclo-2’-deoxyadenosine, 2,6-diamino-4-hydroxy-5-formamidopyrimidine, and 4,6-diamino-5-formamidopyrimidine in MCF-7 and HCC1937 breast cancer cell lines before and after exposure to H2O2 followed by a DNA repair period. We show that H2O2-treated HCC1937 and MCF-7 cell lines accumulate significantly higher levels of these lesions than the untreated cells despite a 1 h repair period. In contrast, the four lesions did not accumulate to any significant level in H2O2-treated non-malignant cell lines, AG11134 and HCC1937BL. Furthermore, MCF-7 and HCC1937 cell lines were deficient in the excision repair of all the four lesions studied. These results suggest that oxidatively induced DNA damage and its repair may be critical in the etiology of breast cancer.     

Metabolic-Pathway-Based Subtyping of Triple-Negative Breast Cancer Reveals Potential Therapeutic Targets

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Effect of Amniotic Membrane Proteins in Human Cancer Cell Lines: An Exploratory Study

Human amniotic membrane (hAM) has recently drawn attention as an upcoming anti-cancer therapy. Regarding the strategies which have already investigated, little is known about hAM protein extracts (hAMPE) effect on cancer. So, this work aims to study the effect of hAMPE in metabolic activity of several human cancer cell lines. hAMPE were mechanically obtained, thus avoiding the effect of detergents and other reagents commonly used in protein extraction under the cell lines studied. After quantification of proteins in hAMPE, their effect on the metabolic activity of 21 human cancer cell lines was assessed by 3-(4,5-dimethylthia-zolyl-2)2,5-diphenyltetrazolium bromide (MTT) assay. Our results indicate that there is an inhibition of metabolic activity until 25 and 50 % in two and seven cell lines, respectively. Five cell lines proved to be very sensitive to hAMPE, being its metabolic activity more than 50 % inhibited. Our results show that hAMPE can inhibit the metabolic activity of some human cancer cell lines. However, research about this cell line-dependent response to hAMPE becomes indispensable.     

Systematic Identification of Combinatorial Drivers and Targets in Cancer Cell Lines

There is an urgent need to elicit and validate highly efficacious targets for combinatorial intervention from large scale ongoing molecular characterization efforts of tumors. We established an in silico bioinformatic platform in concert with a high throughput screening platform evaluating 37 novel targeted agents in 669 extensively characterized cancer cell lines reflecting the genomic and tissue-type diversity of human cancers, to systematically identify combinatorial biomarkers of response and co-actionable targets in cancer. Genomic biomarkers discovered in a 141 cell line training set were validated in an independent 359 cell line test set. We identified co-occurring and mutually exclusive genomic events that represent potential drivers and combinatorial targets in cancer. We demonstrate multiple cooperating genomic events that predict sensitivity to drug intervention independent of tumor lineage. The coupling of scalable in silico and biologic high throughput cancer cell line platforms for the identification of co-events in cancer delivers rational combinatorial targets for synthetic lethal approaches with a high potential to pre-empt the emergence of resistance.     

Performance Comparison of Digital microRNA Profiling Technologies Applied on Human Breast Cancer Cell Lines

MicroRNA profiling represents an important first-step in deducting individual RNA-based regulatory function in a cell, tissue, or at a specific developmental stage. Currently there are several different platforms to choose from in order to make the initial miRNA profiles. In this study we investigate recently developed digital microRNA high-throughput technologies. Four different platforms were compared including next generation SOLiD ligation sequencing and Illumina HiSeq sequencing, hybridization-based NanoString nCounter, and miRCURY locked nucleic acid RT-qPCR. For all four technologies, full microRNA profiles were generated from human cell lines that represent noninvasive and invasive tumorigenic breast cancer. This study reports the correlation between platforms, as well as a more extensive analysis of the accuracy and sensitivity of data generated when using different platforms and important consideration when verifying results by the use of additional technologies. We found all the platforms to be highly capable for microRNA analysis. Furthermore, the two NGS platforms and RT-qPCR all have equally high sensitivity, and the fold change accuracy is independent of individual miRNA concentration for NGS and RT-qPCR. Based on these findings we propose new guidelines and considerations when performing microRNA profiling.     

Clinical Proteomics Identifies Urinary CD14 as a Potential Biomarker for Diagnosis of Stable Coronary Artery Disease

Inflammation plays a key role in coronary artery disease (CAD) and other manifestations of atherosclerosis. Recently, urinary proteins were found to be useful markers for reflecting inflammation status of different organs. To identify potential biomarker for diagnosis of CAD, we performed one-dimensional SDS-gel electrophoresis followed by liquid chromatography coupled with tandem mass spectrometry (LC-MS/MS). Among the proteins differentially expressed in urine samples, monocyte antigen CD14 was found to be consistently expressed in higher amounts in the CAD patients as compared to normal controls. Using enzyme-linked immunosorbent assays to analyze the concentrations of CD14 in urine and serum, we confirmed that urinary CD14 levels were significantly higher in patients (n = 73) with multi-vessel and single vessel CAD than in normal control (n = 35) (P < 0.001). Logistic regression analysis further showed that urinary CD14 concentration level is associated with severity or number of diseased vessels and SYNTAX score after adjustment for potential confounders. Concomitantly, the proportion of CD14+ monocytes was significantly increased in CAD patients (59.7 ± 3.6%) as compared with healthy controls (14.9 ± 2.1%) (P < 0.001), implicating that a high level of urinary CD14 may be potentially involved in mechanism(s) leading to CAD pathogenesis. By performing shotgun proteomics, we further revealed that CD14-associated inflammatory response networks may play an essential role in CAD. In conclusion, the current study has demonstrated that release of CD14 in urine coupled with more CD14+ monocytes in CAD patients is significantly correlated with severity of CAD, pointing to the potential application of urinary CD14 as a novel noninvasive biomarker for large-scale diagnostic screening of susceptible CAD patients.     

Metastasis-related Plasma Membrane Proteins of Human Breast Cancer Cells Identified by Comparative Quantitative Mass Spectrometry

The spread of cancer cells from a primary tumor to form metastasis at distant sites is a complex multistep process. The cancer cell proteins and plasma membrane proteins in particular involved in this process are poorly defined, and a study of the very early events of the metastatic process using clinical samples or in vitro assays is not feasible. We have used a unique model system consisting of two isogenic human breast cancer cell lines that are equally tumorigenic in mice; but although one gives rise to metastasis, the other disseminates single cells that remain dormant at distant organs. Membrane purification and comparative quantitative LC-MS/MS proteomics identified 13 membrane proteins that were expressed at higher levels and three that were underexpressed in the metastatic compared with the non-metastatic cell line from a total of 1919 identified protein entries. Among the proteins were ecto-5′-nucleotidase (CD73), NDRG1, integrin β1, CD44, CD74, and major histocompatibility complex class II proteins. The altered expression levels of proteins identified by LC-MS/MS were validated using flow cytometry, Western blotting, and immunocyto- and immunohistochemistry. Analysis of clinical breast cancer biopsies demonstrated a significant correlation between high ecto-5′-nucleotidase and integrin β1 expression and poor outcome, measured as tumor spread or distant recurrence within a 10-year follow-up. Further the tissue analysis suggested that NDRG1, HLA-DRα, HLA-DRβ, and CD74 were associated with the ER⁻/PR⁻ phenotype represented by the two cell lines. The study demonstrates a quantitative and comparative proteomics strategy to identify clinically relevant key molecules in the early events of metastasis, some of which may prove to be potential targets for cancer therapy.Breast cancer is the most common malignant disease among women in Western countries, occurring in approximately one in 11 women (1). In this disease, malignant cells often disseminate to regional lymph nodes and establish distant metastases, preferentially in the bone, lung, and liver, resulting in poor outcome and high mortality (2, 3).Metastases are established through a complex set of events that is yet not fully understood but requires detachment of single cells from the primary tumor, penetration of the tissue matrix, and migration of these cells to distant locations where they induce angiogenesis and undergo expansive growth (4). Some disseminated cancer cells seem to be capable of maintaining dormancy in distant organs without establishing metastases but may suddenly become activated many years after resection of the primary tumor (5). The dormancy may be caused by environmental signals, either lack of those inducing differentiation or the presence of signals stimulating growth arrest. Cellular factors and changes in the microenvironment, such as inflammation or a change in hormonal status, might eventually induce proliferation, differentiation, and subsequent metastatic growth, whereas other disseminated cancer cells remain dormant for a lifetime (6).Traditional models of metastasis suggest that a subpopulation of cells in the primary tumor acquire metastatic capacity late in tumorigenesis, but gene expression profiles and cellular studies have recently provided evidence for a possible alternative model that suggests the metastatic capacity is acquired early in tumorigenesis (7). Stem cell populations have been identified in a range of hematopoietic and solid tumors and might represent the cells of origin for these tumors but might also be responsible for metastasis (8). Although a preserved genetic signature between the primary tumor and the metastasis has been found, other studies provide evidence of a gradual acquisition of genomic changes because distant metastases may not uniformly share mutations and often differ extensively from the primary tumor, reflecting the extent of genetic instability of breast cancer (9, 10). Only few studies provide proteomic characteristics of metastatic versus primary tumor of breast cancer because of the difficulties of obtaining high quality human tumor samples with full clinical histories and the absence of directly relevant in vitro assays (11, 12).The two isogenic cell lines M-4A4 and NM-2C5, which were derived from the MDA-MB-435 cell line and originated from a highly aggressive human invasive ductal carcinoma, provide an interesting model of the metastatic process (13). M-4A4 and NM-2C5, when inoculated into the mammary fat pad of nude mice, showed equal tumorigeneity, but although M-4A4 established easily detectable metastases restricted to lymph nodes and lungs, NM-2C5 cells disseminated to distal organs, but the cells remained dormant and did not establish metastasis (14). There is an ongoing debate on whether the parent cell line MDA-MB-435 can be defined as a breast cancer cell line because it, along with breast- and epithelia-specific markers, also expresses melanoma-specific genes (15). However, MDA-MB-435 can be induced to express breast differentiation-specific proteins and secrete milk lipids as observed in other well established breast cancer cell lines and has therefore been considered as an excellent model of a highly malignant and dedifferentiated breast cancer (16). Regardless of this debate, our model system remains valuable in the context of cancer metastasis, but the results should, as always when using cell line models, be supported by studies of clinically relevant human tissue specimens.M-4A4 and NM-2C5 have been extensively compared using gene expression analysis identifying a panel of differentially expressed genes (13, 17–20). However, because the proteome is so much more complex than the genome, similar studies at the protein level with special focus on plasma membrane proteins may add valuable biological insight and identify cell surface molecules that might be targeted with drugs or antibodies to inhibit the metastatic process.Comparative quantitative proteomics using stable isotope labeling with amino acids in cell culture (SILAC)¹ and LC-MS/MS allows a study of proteins with quantitatively different expression levels on metastasizing versus non-metastasizing cells. We used this technique to identify a panel of plasma membrane proteins showing altered expression in cells capable of forming metastasis. Validation studies at the protein and RNA expression level of the cell lines indicate that several of the identified proteins may be important for establishing metastasis in distant organs and thus have potential in target-specific therapy. Therefore, to further evaluate the clinical relevance of a selected number of the candidates identified by our analysis, their expression levels were evaluated in a panel of primary breast cancer biopsies and corresponding axillary lymph node metastasis from patients with known clinical outcomes. The results demonstrated the power of this systematic stepwise strategy for identifying targets of potential clinical value.     

Generation of Breast Cancer Stem Cells by Steroid Hormones in Irradiated Human Mammary Cell Lines

Exposure to ionizing radiation was shown to result in an increased risk of breast cancer. There is strong evidence that steroid hormones influence radiosensitivity and breast cancer risk. Tumors may be initiated by a small subpopulation of cancer stem cells (CSCs). In order to assess whether the modulation of radiation-induced breast cancer risk by steroid hormones could involve CSCs, we measured by flow cytometry the proportion of CSCs in irradiated breast cancer cell lines after progesterone and estrogen treatment. Progesterone stimulated the expansion of the CSC compartment both in progesterone receptor (PR)-positive breast cancer cells and in PR-negative normal cells. In MCF10A normal epithelial PR-negative cells, progesterone-treatment and irradiation triggered cancer and stemness-associated microRNA regulations (such as the downregulation of miR-22 and miR-29c expression), which resulted in increased proportions of radiation-resistant tumor-initiating CSCs.     

Cdx2 Polymorphism Affects the Activities of Vitamin D Receptor in Human Breast Cancer Cell Lines and Human Breast Carcinomas

Vitamin D plays a role in cancer development and acts through the vitamin D receptor (VDR). It regulates the action of hormone responsive genes and is involved in cell cycle regulation, differentiation and apoptosis. VDR is a critical component of the vitamin D pathway and different common single nucleotide polymorphisms have been identified. Cdx2 VDR polymorphism can play an important role in breast cancer, modulating the activity of VDR. The objective of this study is to assess the relationship between the Cdx2 VDR polymorphism and the activities of VDR in human breast cancer cell lines and carcinomas breast patients. Cdx2 VDR polymorphism and antiproliferative effects of vitamin D treatment were investigated in a panel of estrogen receptor-positive (MCF7 and T-47D) and estrogen receptor-negative (MDA-MB-231, SUM 159PT, SK-BR-3, BT549, MDA-MB-468, HCC1143, BT20 and HCC1954) human breast cancer cell lines. Furthermore, the potential relationship among Cdx2 VDR polymorphism and a number of biomarkers used in clinical management of breast cancer was assessed in an ad hoc set of breast cancer cases. Vitamin D treatment efficacy was found to be strongly dependent on the Cdx2 VDR status in ER-negative breast cancer cell lines tested. In our series of breast cancer cases, the results indicated that patients with variant homozygote AA were associated with bio-pathological characteristics typical of more aggressive tumours, such as ER negative, HER2 positive and G3. Our results may suggest a potential effect of Cdx2 VDR polymorphism on the efficacy of vitamin D treatment in aggressive breast cancer cells (estrogen receptor negative). These results suggest that Cdx2 polymorphism may be a potential biomarker for vitamin D treatment in breast cancer, independently of the VDR receptor expression.     

结/直肠癌的潜在治疗靶点

传统的结/直肠癌化疗药物,作用选择性较低,副反应明显,疗效欠佳,患者病死率居高不下.寻找新型治疗药物,十分必要.在结/直肠癌发病机制的探索过程中,研究者发现:一些分子的变化影响着疾病进程,对病情起指示作用,有可能成为治疗靶点.围绕这些分子设计药物,制定治疗方案,有望提高疗效,改善病人生存质量,降低不良反应的发生.本文就结/直肠癌的部分潜在治疗靶点:EGFR,VEGF,HADC,COX-2,PPARγ及galectin-3做一综述.