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Gene therapy- Methods, Status and Limitations. Methods of gene delivery (therapeutic constructs). It Includes two methods: Nonviral gene-delivery systems Virus-Mediated gene-delivery systems. Non viral gene-delivery systems. Naked DNA injection Gene gun
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Methods of gene delivery (therapeutic constructs) It Includes two methods: • Nonviral gene-delivery systems • Virus-Mediated gene-delivery systems
Non viral gene-delivery • systems • Naked DNA injection • Gene gun • Lipofection
Naked DNA gene therapy • This is the simplest method i.e. the direct introduction of therapeutic DNA into target cells. • Very cheap.
Gene transfer through Liposomes • Positively charged lipid droplets can interact with negatively charged DNA to wrap it up and deliver to cells. • Inside liposomes DNA is resistant to degradation and is capable of passing the DNA through the target cell's membrane. • Used in cystic fibrosis, cancer, parkinson’s disease. Therapeutic drugs
Non viral gene-delivery • systems • Advantages: • DNA can be of any size • Non-infectious and • Can’t replicate; no inflammatory • response • Disadvantages: • low efficiency • non-specific
Virus-mediated gene-delivery systems • Include Biological vehicles (vectors) such as viruses and bacteria. • Viruses are currently the most efficient means of gene transfer. • Viruses attack their hosts and introduce their genetic material containing genetic material into the host cell as part of their replication cycle.
Some viral vectors used in gene therapy are: • Retroviruses • Adenoviruses • Adeno-associated viruses • Herpes simplex virus
Single most optimal vector for all gene therapies • No optimal gene therapy vector. • Different sites on the body requires different vectors different durations of treatment . • For example treatment of cancer requires short-term efficiency, just enough to kill the cancer cells; whereas, treatment of Huntington's disease would likely require life-long gene expression from a single injection.
Successful Gene Therapy for Severe Combine Immunodeficiency • SCID caused by a number of defects: Example: ADA (adenosine deaminase) gene defect. X – linked SCID. • Lack of functional lymphocytes. • No T-cell dependent antibody response. • Block the DNA Synthesis. • No cell mediated immune response.
The First Case • The first gene therapy was performed on September 14th, 1990 • Ashanti DeSilva was treated for SCID • Sever combined immunodeficiency • Doctors removed her white blood cells, inserted the missing gene into the WBC, and then put them back into her blood stream. • This strengthened her immune system • Only worked for a few months
Gene Therapy Successes Ashanti de Silva successfully treated for ADA deficiency - 1990 Photo courtesy of Van de Silva Ryes Evans successfully treated for SCID - 2001
Current status in GT • August 30,2006, Researchers at the National Cancer Institute (NCI), part of the National Institutes of Health, successfully reengineer immune cells, called lymphocytes, to target and attack cancer cells in patients with advanced metastatic melanoma.
May 1, 2007): A team of British doctors from Moorfields Eye Hospital and University College in London conduct first human gene therapy trials to treat Leber's congenital amaurosis, a type of inherited childhood blindness caused by a single abnormal gene. • 28 April 2008, UK researchers from the UCL institute of Opthalmology and Moorfields Eye Hospital NIHR Biomedical research centre have announced results of World’s first gene therapy for inherited bilndness .
Current status in GT in India • Very little gene therapy work being done in India • Metro heart Institute in Noida is used the GT in production of vascular endothelial growth protein. • Indian dept. of Bio-tech. has been given the permission to use the GT for treat renal cell carcinoma, colon, breast, & lung cancer by country’s regulators
Hurdles In Gene Therapy • Short lived nature of gene therapy • Immune response • Problems with viral vectors • Insertional mutagenesis.
Major Problems that Scientists Must Overcome • Identify more efficient ways to deliver the genes to the patients’ genetic material • Develop vectors that can specifically focus on the targeted cells • Ensure that vectors will successfully insert the desired genes into each of these target cells
Deliver genes to a precise location in the patient’s DNA • Ensure that transplanted genes are precisely controlled by the body’s normal physiologic signals