Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:O76050 (neu)
 3,969 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Chemotherapeutic drug resistance is a major clinical problem and cause for failure in the therapy of human cancer. One of the goals of molecular oncology is to identify the underlying mechanisms, with the hope that more effective therapies can be developed. Several mechanisms have been suggested to contribute to chemoresistance: 1) amplification or overexpression of the P-glycoprotein family of membrane transporters (eg, MDR1, MRP, LRP) which decrease the intracellular accumulation of chemotherapy; 2) changes in cellular proteins involved in detoxification (eg, glutathione S-transferase pi, metallothioneins, human MutT homologue, bleomycin hydrolase, dihydrofolate reductase) or activation of the chemotherapeutic drugs (DT-diaphorase, nicotinamide adenine dinucleotide phosphate:cytochrome P-450 reductase); 3) changes in molecules involved in DNA repair (eg, O6-methylguanine-DNA methyltransferase, DNA topoisomerase II, hMLH1, p21WAF1/CIP1; 4) activation of oncogenes such as Her-2/neu, bcl-2, bcl-XL, c-myc, ras, c-jun, c-fos, MDM2, p210 BCR-abl, or mutant p53. An overview of these resistance mechanisms is presented, with a particular focus on the role of oncogenes. Some current strategies attempting to reverse their effects are discussed.
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PMID:Role of oncogenes in resistance and killing by cancer therapeutic agents. 909 Apr 98

Extensive research has led to accumulation of common hereditary evidence concerning ovarian and breast cancer, suggesting that these two cancers can be considered as one type. Subsequently, women with breast cancer are susceptible to the risk of developing ovarian cancer. Highly expressed oncogenes such as bcl-2, HER2/neu and others or mutated suppressor genes such as p53 or BRCA1 have been characterised as hereditary susceptibility genes leading to syndromes such as breast/ovarian cancer syndrome, Li-Fraumeni and others. Furthermore, these genetic alterations can cause potent chemoresistance by inhibiting induction of apoptosis after DNA damage caused by chemotherapy and/or radiotherapy. Presently, molecular onco-biology has enabled us not only to detect susceptibility to ovarian and breast cancer but also ways to inhibit their further progression or even circumventing chemoresistance mechanisms after their development by gene therapy using delivery vectors such as liposomes or viruses, by which we can replace wild-type tumour suppressor genes or by using antigene, antisense oligonucleotides and antisense RNA leading to reduced oncogene expression, enabling induction of apoptosis after DNA damage into chemoresistant tumour cells. Furthermore efflux-genes such as MDR-1 or MRP can be circumvented, suicide-genes can be employed which can facilitate sensitivity by encoding enzymes capable of converting inactive forms of a drug into toxic antimetabolites and immunotherapy can be achieved, by transfection of tumour cells with adenoviral vectors encoding immunomodulators such as IL-2 or MHC molecules. Thus, molecular biology appears to be a very strong element for the screening, diagnosis, therapy and prognosis of ovarian and breast cancer. However, consistent future research is greatly needed because many points concerning ovarian and breast cancer genetics are still unknown. Finally, we strongly believe that gene therapy could be extremely useful when is combined with conventional therapy against ovarian and breast tumours.
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PMID:Molecular aspects of breast and ovarian cancer. 937 59

Recent studies have identified some of the genetic alterations involved in endometrial carcinoma development. Transforming genes, including K-ras and c-erbB2/neu oncogenes and the p53, PTEN and hMLH1 tumor suppressor genes, are the most frequently altered. In addition, endometrial carcinomas express high levels of chemoresistance markers, including the MDR-1 or the MRP genes. The genetic background of an endometrial cancer patient may include high-penetrance genes such as the DNA mismatch repair genes causing microsatellite instability, and low-penetrance genes such as those involved in estrogen-metabolism. The spectrum of several molecular lesions suggest a model for endometrial tumorigenesis through two divergent pathways, and which may improve the design of more rational therapeutic agents.
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PMID:Advances in the molecular genetics of endometrial cancer (Review). 1052 15

Resistance of tumor cells to several structurally unrelated classes of natural products, including anthracyclines, taxanes, and epipodophyllotoxines, is often referred as multidrug resistance (MDR). This is associated with ATP-binding cassette transporters, which function as drug efflux pumps such as P-glycoprotein (Pgp) and multidrug resistance-associated protein 1 (MRP1). Because of the hypothesis in the early eighties that blockade of these efflux pumps by modulators would improve the effect of chemotherapy, extensive effort has been put to visualize these pumps using nuclear imaging with several specific tracers, using both SPECT and PET techniques. The methods and possibilities to visualize these pumps in both the tumor and the blood-brain barrier will be discussed. Because of the fact that the addition of Pgp or MRP modulators has not shown any clinical benefit in patient outcome, these specific MDR tracers are not routinely used in clinical practice. Evidence emerges that combination of chemotherapeutic drugs involved in MDR with the so-called targeted agents can improve patient outcome. The concept of molecular imaging can also be used to visualize the targets for these agents, such as HER2/neu and angiogenic factors such as vascular endothelial growth factor (VEGF). Potentially visualizing molecular drug targets in the tumor can function as biomarkers to support treatment decision for the individual patient.
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PMID:Multidrug resistance in oncology and beyond: from imaging of drug efflux pumps to cellular drug targets. 1994 18