Gene therapy is a groundbreaking treatment method diverging from conventional drug compounds. Instead, it utilizes genes or short oligonucleotide sequences as therapeutic agents. This innovative technique targets defective genes contributing to disease development. The core principle involves introducing one or more foreign genes into an organism, aiming to address hereditary or acquired genetic defects. This is achieved by packaging DNA encoding a therapeutic protein within a "vector," facilitating the transportation of DNA into cells. The expression of the inserted DNA by cell machinery treats the disease with minimal toxicity. The first FDA-approved gene therapy experiment occurred in 1990 on ADA-SCID, following the treatment of Ashanti DeSilva. Subsequently, around 1700 clinical trials employing various techniques and genes for numerous diseases have been conducted. Although successful trials have been reported for diseases like ADA-SCID, X-linked SCID, Leber's congenital amaurosis, Parkinson's disease, multiple myeloma, chronic and acute lymphocytic leukemia, and adrenoleukodystrophy, FDA approval is pending. Ongoing research explores gene therapy for diseases like Haemophilia, Tyrosinemia, Hyperbilirubinemia (Criglar-Nijjar Syndrome), Cystic Fibrosis, and various cancers. Despite three decades of research, only one product, Glybera, received FDA approval in November 2012 and might be available in late 2013. Glybera has the potential to cure lipoprotein lipase deficiency (LPLD), a rare disease.
Gene therapy encompasses several approaches for rectifying faulty genes, with the most common involving the insertion of a normal gene into a specific genome location. It is classified into two types:
Somatic gene therapy targets the somatic cells of a patient for foreign gene transfer. The effects of the foreign gene are limited to the individual patient, not inherited by offspring or later generations.
In germ line gene therapy, functional genes to be integrated into genomes are inserted into germ cells, such as sperm or eggs. This approach makes the therapy heritable.
Gene Augmentation Therapy (GAT) involves adding functional alleles to treat inherited disorders resulting from a genetic deficiency. GAT is applicable to autosomal recessive disorders, while dominantly inherited disorders pose challenges for this approach.
This strategy employs genes encoding toxic compounds (suicide genes) or prodrugs to eliminate transfected or transformed cells. Particularly prevalent in cancer gene therapies, it utilizes compounds like thymidine kinase (TK) and prodrug ganciclovir. TK phosphorylates ganciclovir, leading to chain termination upon its incorporation into DNA.
Targeted inhibition focuses on blocking the expression of diseased genes or new genes producing harmful proteins. Particularly effective for treating infectious diseases and certain cancers.
This approach corrects defective genes to restore function either at the genetic level through homologous recombination or at the mRNA level using therapeutic ribozymes or RNA editing.
Classical gene therapy involves delivering therapeutic genes and optimizing their expression within the target cell. Foreign genes carry out functions such as producing lacking proteins, generating toxins to eliminate diseased cells, or activating immune cells to aid in diseased cell elimination.
Non-classical gene therapy inhibits the expression of genes associated with pathogenesis or corrects genetic defects to restore normal gene expression.
There are two main gene therapy approaches:
In ex vivo gene therapy, genes are transferred to cultured cells, selected, multiplied, and reintroduced into the patient. Autologous cells are used to avoid immune rejection. This approach is applicable to tissues like hematopoietic and skin cells. Figure 8-1.5.1 illustrates the schematic diagram for ex vivo gene transfer.
In in vivo gene therapy, cloned genes are directly transferred into patient tissues, particularly suitable for tissues where individual cells cannot be cultured in vitro efficiently (e.g., brain cells). Liposomes and viral vectors, especially recombinant retrovirus-infected cells (vector-producing cells or VPCs), are used for gene transfer to surrounding disease cells.
In Vivo
Ex Vivo
Therapeutic genes necessitate specific delivery to target sites for different diseases. The table below outlines diseases and their corresponding target sites for gene therapy:
Target Cells for Gene Transfer:
Disease: Cancer
Disease: Inherited Monogenic Disease
Disease: Infectious Disease
Disease: Cardiovascular Disease
Disease: Rheumatoid Arthritis
Disease: Cubital Tunnel Syndrome
Gene therapy utilizes vectors for gene delivery, classified into two types:
Viral Vectors
Non-viral Vectors
Note: Table 2 presents vectors employed in gene therapy, adapted from AR Prabhakar in Gene Therapy and its Implications in Dentistry, International Journal of Clinical Pediatric Dentistry, 2011; 4(2):85-92.
Direct Gene Transfer Methods:
These methods are also employed to transfer genes directly into target cells.
Retroviruses, Adenoviruses, and Adeno-Associated Viruses (AAV)
Viral vectors play a crucial role in gene therapy, with some commonly used viral vectors being retroviruses, adenoviruses, and adeno-associated viruses (AAV). Less commonly used viral vectors include those derived from the Herpes simplex virus (HSV-1) and the baculovirus.
Adenoviral Vectors
Adenoviruses, large linear double-stranded DNA viruses, are popular gene transfer vectors. They are the second most commonly used vector for gene therapy in diseases like cystic fibrosis and certain cancers.
Adenovirus Entry Mechanism:
Adenoviral DNA Structure:
Classes of Adenoviral Vectors:
First Generation Adenoviral Vectors:
Second Generation Adenoviral Vectors:
Third Generation Adenoviral Vectors (Gutless Adenovirus):
Tumor Retroviruses (e.g., Moloney's Murine Leukemia Virus):
Recombinant Lentiviruses:
Herpes Simplex Virus Vectors (HSV-1):
Baculovirus:
Simian Virus 40 Vectors (SV40):
1. Direct Injection/Particle Bombardment:
2. Microinjection:
3. Particle Bombardment Method:
4. Liposomes Mediated:
Advantages:
Disadvantages:
Gene Therapy Application:
Advantages:
Disadvantages:
Enhancement:
Introduction:
For Viral Gene Delivery System:
For Non-viral Gene Delivery System:
Proton Sponge Hypothesis:
Flip-Flop Mechanism:
Pore Formation:
Photochemical Internalization:
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