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Showing 3 results for Gene Therapy

Noori Daloii Mr, Ebrahimzadeh Vesal E,
Volume 67, Issue 1 (4-2009)
Abstract

The prostate is a small gland located below the bladder and upper part of the urethra. In developed countries prostate cancer is the second common cancer (after skin cancer), and also the second leading cause of cancer death (after lung cancer) among men. The several studies have been shown prostate cancer familial aggregation. The main reason for this aggregation is inheritance included genes. The family history is an important risk factor for developing the disease. The genes AR, CYP17, SRD5A2, HSD3B1 and HSD3B2 are all intimately involved in androgen metabolism and cell proliferation in the prostate. Each shows intraspecific polymorphism and variation among racial-ethnic groups that is associated with the risk of prostate cancer. Some of genes expressed in the prostate are in association with the production of seminal fluid and also with prostate cancer. Epigenetic modifications, specifically DNA hypermethylation, are believed to play an important role in the down-regulation of genes important for protection against prostate cancer. In prostate cancer numerous molecular and genetic aberrations have been described. It is now well established that cancer cells exhibit a number of genetic defects in apoptotic pathways. In this review article, the most recent data in molecular genetic, prevention and especially gene therapy in prostate cancer are introduced.


Noori Daloii Mr, Maheronnaghsh R, Sayyah Mk,
Volume 69, Issue 6 (9-2011)
Abstract

Background: With approximately 386,000 deaths per year, esophageal cancer is the 6th most common cause of death due to cancer in the world. This cancer, like any other cancer, is the outcome of genetic alterations or environmental factors such as tobacco smoke and gastro-esophageal reflux. Tobacco smoking is a major etiologic factor for esophageal squamous cell carcinoma in western countries, and it increases the risk by approximately 3 to 5 folds. Chronic gastro-esophageal reflux usually leads to the replacement of squamous mucosa by intestinal-type Barrett’s metaplastic mucosa which is considered the most important factor causing esophageal adenocarcinoma. In contrast to esophageal adenocarcinoma, different risk factors and mechanisms, such as mutations in oncogenes and tumor suppressor genes, play an important role in causing esophageal squamous cell carcinoma. Molecular studies on esophageal cancers have revealed frequent genetic abnormalities in esophageal squamous cell carcinoma and adenocarcinoma, including altered expression of p53, p16, cyclin D1, EGFR, E-cadherin, COX-2, iNOS, RARs, Rb, hTERT, p21, APC, c-MYC, VEGF, TGT-α and NF-κB. Many studies have focused on the role of different polymorphisms such as aldehyde dehydrogenase 2 and alcohol dehydrogenase 2 in causing esophageal cancer. Different agents including bestatin, curcumin, black raspberries, 5-lipoxygenase (LOX) and COX-2 inhibitors have been found to play a role in inhibiting esophageal carcinogenesis. Different gene therapy approaches including p53 and p21WAF1 replacement gene therapies and therapy by suicide genes have also been experimented. Moreover, efforts have been made to use nanotechnology and aptamer technology in this regard.


Hadis Soleimanzadeh, Nahid Nasiri ,
Volume 81, Issue 2 (5-2023)
Abstract

Thalassemia is an autosomal recessive hereditary disease that occurs due to a decrease in the synthesis of Please recheck. In beta thalassemia, defects in β-globin synthesis lead to an imbalance of β- and α-globin chains and the accumulation of α4 chains in the erythroid precursor which leads to ineffective erythropoiesis, shortened red blood cell survival, and finally clinical symptoms such as delayed sexual and physical maturation, endocrine dysfunction, cardiomyopathy, liver disease, bone deformities and hepatosplenomegaly. Current treatments such as transfusion, iron chelating agents and allogeneic stem cell hematopoietic transplantation have limitations in their use, including iron overload, lack of a human leukocyte antigen (HLA) matched compatible donor, and graft versus host disease (GVHD). Gene therapy is a new therapeutic option for beta thalassemia patients that induces the continuous expression of beta globin chains in the patient’s hematopoietic stem cells. The idea of gene therapy was first proposed in the early 1970s, and the ultimate goal of this treatment method is to express the defective gene in the target cell in a way that can reduce the symptoms of the disease or eliminate them (symptoms) altogether. There are two general methods for gene therapy: the integrating vector, in which the desired gene is inserted into the genome of the target cell and its lifelong expression follows, is the non-integrating method, in which the vector doesn’t integrate into the genome of the target cell and the cytoplasmic form enables gene expression. The first beta thalassemia gene therapy was performed in France in 2006, and in this clinical trial, the first patient with the E/β0 thalassemia was treated at the age of 18. Gene therapy for beta-thalassemia has been approved by the food and drug administration in 2022 for patients aged 12 years and older who have a non β0/β0 phenotype. It seems that this therapeutic option is the definitive treatment method for blood transfusion-dependent beta-thalassemia patients.     However, this treatment method still has limitations: high cost, sensitivity of lentiviral vector production, and the possibility of integration of the vector near the proto-oncogene and its activation are some of them.


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