Published On: 4th March, 2024
ABSTRACT
After the discovery of the CRISPR-Cas9[1] technique in 2012 the field of genome editing has grown vastly in all directions, it has intrigued many scientists and clinical industries to invest capital and time into it leading to discoveries of many other effective techniques in genome editing. It has various applications like human gene therapy, crop improvement, disease modeling, neuroscience, and drug discovery. Biomedicine and genome therapy being the most promising and valuable genres of all, in this article we try to summarize the current knowledge and applications of gene editing and how it will shape the future of medicine and therapy.
KEYWORDS – Gene editing techniques, CRISPR, therapeutic gene editing, immunotherapy.
INTRODUCTION
The human genome project was completed in 2003 but only left us with the basic knowledge of a healthy individual’s genomic data, often faults and errors are observed in the genetic mapping of certain individuals; Gene aberrations have a huge impact on the livelihood of a population, it causes abnormalities and incurable diseases like cystic fibrosis, sickle cell disease, and genetic syndromes like down’s and turner’s. These abnormalities can be due to numerous reasons like exposure to UVR, carcinogens, and even random mutations. Genome editing is the technique that is being used and researched over the past decade to help tackle these obstacles. The existing genome of a diseased individual is altered to eliminate abnormalities or add missing pieces to the gene sequence.
GENE EDITING TECHNIQUES
Although CRISPR is an excellent tool for editing many newer and more effective technologies have been discovered since its discovery. Base editing[2][3] is a more recent cutting-edge technology that operates by chemically altering the gene sequence rather than double-strand break repairs.
The most recent tool that even eliminates the limitations of base editing is Prime editing[4] which works just like CRISPR tech but without the use of double-strand break repairs making it more
efficient and reliable.
FIGURE [5] – Mechanisms of different genome editing tools.
THERAPEUTIC ASPECT OF GENOME EDITING
Gene editing therapy has shown effective responses for the treatment of various conditions like thalassemia, sickle cell disease, and AIDS. It is being used now in numerous fields like cancer research, cardiovascular diseases, hematological diseases, metabolic conditions, neurodegenerative syndromes, and hereditary diseases.
TABLE [6] – List of some of the recent therapeutic gene editing studies in in vivo preclinical and clinical models
|
Disease |
Target organ |
Gene editing tool |
Delivery system |
Therapeutic modality |
|
Hemophilia A and B |
Mouse liver |
ZFN |
Systemic injection of AAV8 |
HDR- and HITI- dependent gene insertion |
|
Hunter’s syndrome |
Mouse liver |
ZFN |
Systemic injection of AAV2/AAV8 |
NHEJ- or HDR- mediated integration into albumin locus |
|
Congenital muscular dystrophy type1A |
Mouse muscle |
CRISPR/dCas 9 |
Intramuscular or systemic injection of AAV9 |
CRISPR activator- based gene upregulation |
|
Retinitis pigmentosa |
Transgenic mouse model with human Rhodopsin ge ne |
CRISPR/Cas9 |
Electroporation of Cas9 and dual gRNAs in mouse retina |
NHEJ-based gene knockdown |
|
Retinitis pigmentosa |
Mouse retina |
CRISPR/Cas9 |
Subretinal injection of AAV8 |
NHEJ-mediated targeted Nre inactivati on |
|
Disease |
Target organ |
Gene editing tool |
Delivery system |
Therapeutic modality |
|
Oxygen- induced retinopathy |
Mouse eye |
CRISPR/Cas9 |
Intravitreal injection of rAAV1 |
NHEJ-based mutant gene disruption |
|
Primary open- angle glaucoma |
Mouse eye |
CRISPR/Cas9 |
Intravitreal injection of Adenovirus (Ad5) |
NHEJ-based mutant gene disruption |
|
Huntington disease |
Mouse brain |
CRISPR/Cas9 |
Stereotactic injection of AAV1 |
SNP-based allele- specific editing of Htt gene |
|
Rett syndrome |
Mouse brain |
CRISPR/Cas9 |
Stereotactic injection of AAV1/2 |
NHEJ-based disruption of multiple genes |
|
Cardiac syndrome |
Mouse heart |
CRISPR/Cas9 |
Systemic injection of AAV9 |
NHEJ-based mutant gene knockdown |
|
Dystrophic cardiomyopat hy |
Mouse heart |
CRISPR/Cas9 |
Retro-orbital and intraperitoneal injection of AAV rh74 |
NHEJ-based mutant Dmd exon 23 excision |
|
Cancer |
Programmed death1 ligand (PD-L1) tumor xenograft |
CRISPR/Cas9 |
Lentiviral delivery |
PD-1-deficient CAR-T cells |
|
HIV |
HIV-infected humanized mouse |
CRISPR/Cas9 |
Intravenous injection of AAV- DJ/8 |
HIV-1 proviral DNA excision |
|
Disease |
Target organ |
Gene editing tool |
Delivery system |
Therapeutic modality |
|
|
spleen, brain, heart, lungs, and so on |
|
|
|
|
β-Thalassemia |
Rhesus macaques |
Transposase |
Intravenous injection of HDAd5/35++ vect or |
Transposase-based gene integration |
FUTURE OF GENOME EDITING
Genome editing in cancer immunotherapy
One potential application of immunotherapy is using genetically engineered T cells, which are known as chimeric antigen receptor (CAR) T cells. These cells can target tumor-associated antigens and
potentially lead to an enhanced response to therapy.[7]
Figure [8] – Production of CAR T cell products.
Medical applications
The earliest trials used ZFNs to knock out the CCR5 co-receptor gene in T cells of HIV-positive patients, thereby making the T cells resistant to the virus. The results were encouraging, and an extension to earlier hematopoietic precursors is planned. TALENs have been used to enhance the efficacy of therapeutic CAR T cells, and at least two trials using CRISPR-Cas9 for this purpose have been approved. [9]
Viral diseases
Genome editing has the potential to become a powerful tool in antiviral therapy. It works by modifying genes that are necessary for viral invasion and replication in host cells. By editing these genes, we can produce virus-resistant immune or stem/progenitor cells that can prevent or alleviate viral diseases.[10]
CONCLUSION AND DISCUSSION
CRISPR-Cas systems can screen disease-causing mutations and detect viral nucleic acids like SARS- CoV-2, aiding in the diagnosis of rare genetic diseases. Gene editing has the potential to be a rapid and accurate diagnostic tool for diseases. It is most inspiring in the field of gene or cell therapy.
Despite significant progress in clinical applications, the field of gene-editing therapeutics needs to address several issues before we hit the ultimate goal of curing all genetic disorders. Scientists should continue to increase the accuracy and efficiency of existing gene-editing agents in parallel with innovations and developments of novel technologies.
ABBREVIATIONS
CRISPR – Clustered regularly interspaced short palindromic repeats UVR – Ultraviolet radiations
ZFN – Zinc finger nucleases
NHEJ nonhomologous end joining
TALEN – Transcription activator-like effector nucleases
REFERENCES
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