Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
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Target Concepts:
Gene/Protein
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Query: UMLS:C0017638 (
glioma
)
30,880
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Estramustine-binding protein (EMBP) is a M(r) 46,000 heterodimeric protein originally isolated from prostatic tissue. It has a demonstrated high affinity for, and selective binding of, estramustine, which is a derivative of 17 beta-estradiol and nornitrogen mustard with antimitotic activity. In this study, we have analysed the expression of an EMBP-like protein in astrocytoma specimens. Immunohistochemistry revealed a pronounced reactivity for EMBP in astrocytoma grades III-IV as well as in metastatic
prostatic adenocarcinoma
used as positive control. In astrocytoma grades I-II, the expression was weak. The EMBP-like protein was quantified by radioimmunoassay in astrocytoma tumor tissue with higher concentrations in malignant astrocytoma, grades III-IV, compared to grades I-II tumors. Western immunoblotting of immunoaffinity purified EMBP-like protein under nonreducing conditions revealed an immunoreactivity corresponding to M(r) 138,000 and 200,000, indicating a different structure of EMBP in astrocytoma compared to prostatic tissue. Specific binding and the presence of saturable binding sites for 3H-labeled estramustine were demonstrated in astrocytoma tissues expressing EMBP-like protein. Scatchard plot analysis showed a Kd at approximately 30 nM, which suggests a binding affinity for estramustine in the same range as previously reported for EMBP in the prostate. Moreover, the number of estramustine binding sites/g tumor as calculated from the Scatchard plots was well correlated with the EMBP levels determined in the radioimmunoassay. In conclusion, an EMBP-like protein is expressed in astrocytoma. This protein may be responsible for the specific binding of estramustine in the tumor tissue. Whether this specific binding of estramustine is of importance for the cytotoxic effect in
glioma
cells remains to be evaluated.
...
PMID:Estramustine-binding protein and specific binding of the anti-mitotic compound estramustine in astrocytoma. 806 65
Using the technique of differential hybridization of a human fetal brain library, we have identified a novel gene, brain 3 (BR-3). This gene is not expressed in normal human brain tissue samples but is expressed at high levels in human low-grade
glioma
tissue samples. We have cloned and sequenced the full-length cDNA corresponding to this gene. Data base search analysis indicated that the BR-3 gene has strong homology to a genomic sequence present on chromosome 1 but no homology to expressed genes. Open reading frame analysis has indicated the presence of a 71 amino acids long protein sequence. A data base search for the protein sequence homology showed no similarity to known sequences. Expression analysis of BR-3 indicated that it is expressed at high level in six out of seven low-grade
glioma
samples analyzed. In addition low levels of BR-3 gene expression was observed in six out of seven anaplastic astrocytoma tissue samples analyzed. BR-3 expression was observed in four of eight glioblastoma samples analyzed. Expression analysis of normal human tissues indicated that it is expressed in kidney, skeletal muscle, lung, spleen and heart. No expression of the BR-3 gene was observed in brain, liver or testes tissue. To understand the role of the BR-3 gene in cancer in general, we studied its expression in other cancer cell lines. Except for lung and ovarian carcinoma, the BR-3 gene is expressed in breast carcinoma, colon
adenocarcinoma, prostatic
adenocarcinoma, and pancreatic adenocarcinoma tissue samples. On the basis of its sequence, unique expression pattern, we conclude that BR-3 gene product may play a critical role in the genesis of human gliomas tumors.
...
PMID:Molecular characterization of a novel human brain tumor-associated gene BR-3. 1216 25
Since cloning (1996) and characterization of the sodium iodide symporter (NaIS) gene, several investigators have studied the possibility of novel cytoreductive gene therapy based on NaIS gene. The NaIS present in membranes of the thyroid cells is responsible for the capacity of the thyroid to concentrate iodide. The strategies of these methods explore NaIS gene transfer into non-thyroidal cancer cells. NaIS gene transfer has been shown to be capable of inducing radioiodine accumulation in vitro in several non-thyroidal cell lines. Successful transfection with NaIS gene was demonstrated in human ovarian
adenocarcinoma, prostatic
adenocarcinoma, human
glioma
, melanoma, colon carcinoma, lung or mammary gland cell lines. NaIS transfected tumor cells accumulated radioiodine highly enough to elicit therapeutic response to 131I in vitro and in vivo. These data have suggested potential role of NaIS as a novel cancer therapy approach for a targeting radiotherapy for non-thyroidal cancers.
...
PMID:[Sodium-iodide cotransporter in gene therapy]. 1218 68
The Na(+)/I(-) symporter (NIS) is the plasma membrane glycoprotein that mediates the active uptake of I(-) in the thyroid, ie, the crucial first step in thyroid hormone biosynthesis. NIS also mediates I(-) uptake in other tissues, such as salivary glands, gastric mucosa, and lactating (but not nonlactating) mammary gland. The ability of thyroid cancer cells to actively transport I(-) via NIS provides a unique and effective delivery system to detect and target these cells for destruction with therapeutic doses of radioiodide. Breast cancer is the only malignancy other than thyroid cancer to have been shown to functionally express NIS endogenously. The considerable potential diagnostic and therapeutic use of radioiodide in breast cancer is currently being assessed. On the other hand, exogenous NIS gene transfer has successfully been carried out into a variety of other cell lines and tumors, including A375 human melanoma tumors, and SiHa cervix cancer, human
glioma
, and hepatoma cell lines. Most notably, significant radioiodine therapy results have been obtained in the NIS-transfected human
prostatic adenocarcinoma
cell line LNCaP and in NIS-transfected myeloma cells, both of which exhibited prolonged retention of radio iodide even in the absence of I(-) organification. The therapeutic potential of alternative NIS-transported radioisotopes with different decay properties and a shorter, physical half-life than 131I(-), such as beta-emitter 188Rhenium (188ReO(4)-) and alpha-emitter 211Astatine (211At(-)), has been evaluated. In conclusion, it is clear that the remarkable progress made in the last few years in the molecular characterization of NIS has created new opportunities for the development of diagnostic and therapeutic applications for NIS in nuclear medicine.
...
PMID:The Na/I symporter (NIS): imaging and therapeutic applications. 1473 56
Non-coding RNAs occupy a significant fraction of the human genome. Their biological significance is backed up by a plethora of emerging evidence. One of the most robust approaches to demonstrate non-coding RNA's biological relevance is through their prognostic value. Using the rich gene expression data from The Cancer Genome Altas (TCGA), we designed Advanced Expression Survival Analysis (AESA), a web tool which provides several novel survival analysis approaches not offered by previous tools. In addition to the common single-gene approach, AESA computes the gene expression composite score of a set of genes for survival analysis and utilizes permutation test or cross-validation to assess the significance of log-rank statistic and the degree of over-fitting. AESA offers survival feature selection with post-selection inference and utilizes expanded TCGA clinical data including overall, disease-specific, disease-free, and progression-free survival information. Users can analyse either protein-coding or non-coding regions of the transcriptome. We demonstrated the effectiveness of AESA using several empirical examples. Our analyses showed that non-coding RNAs perform as well as messenger RNAs in predicting survival of cancer patients. These results reinforce the potential prognostic value of non-coding RNAs. AESA is developed as a module in the freely accessible analysis suite MutEx.
Abbreviation:
ACC: Adrenocortical Carcinoma (n = 92); BLCA: Bladder Urothelial Carcinoma (n = 412); BRCA: Breast Invasive Carcinoma (n = 1098); CESC: Cervical Squamous Cell Carcinoma and Endocervical Adenocarcinoma (n = 307); CHOL: Cholangiocarcinoma (n = 51); COAD: Colon Adenocarcinoma (n = 461); DLBC: Lymphoid Neoplasm Diffuse Large B-cell Lymphoma (n = 58); ESCA: Oesophageal Carcinoma (n = 185); GBM: Glioblastoma Multiforme (n = 617); HNSC: Head and Neck Squamous Cell Carcinoma (n = 528); KICH: Kidney Chromophobe (n = 113); KIRC: Kidney Renal Clear Cell Carcinoma (n = 537); KIRP: Kidney Renal Papillary Cell Carcinoma (n = 291); LAML: Acute Myeloid Leukaemia (n = 200); LGG: Brain Lower Grade
Glioma
(n = 516); LIHC: Liver Hepatocellular Carcinoma (n = 377); LUAD: Lung Adenocarcinoma (n = 585); LUSC: Lung Squamous Cell Carcinoma (n = 504); MESO: Mesothelioma (n = 87); OV: Ovarian Serous Cystadenocarcinoma (n = 608) PAAD: Pancreatic Adenocarcinoma (n = 185); PCPG: Pheochromocytoma and Paraganglioma (n = 179); PRAD:
Prostate Adenocarcinoma
(n = 500); READ: Rectum Adenocarcinoma (n = 172); SARC: Sarcoma (n = 261); SKCM: Skin Cutaneous Melanoma (n = 470); STAD: Stomach Adenocarcinoma (n = 443); TGCT: Testicular Germ Cell Tumours (n = 150); THCA: Thyroid Carcinoma (n = 507) THYM: Thymoma (n = 124); UCEC: Uterine Corpus Endometrial Carcinoma (n = 560); UCS: Uterine Carcinosarcoma (n = 57); UVM: Uveal Melanoma (n = 80).
...
PMID:Advancing Pan-cancer Gene Expression Survial Analysis by Inclusion of Non-coding RNA. 3160 16
