Gene Editing — Unlocking the Potential Within
The editing of genes alters a living cell’s genetic material (DNA or RNA). In order to add, delete, or replace individual genetic bases and sequences, it utilizes a variety of different methods and techniques. In medicine, the gene-editing process has facilitated the study of diseases in detail, helping clinicians and researchers to understand their root causes.
The most significant aspect of gene editing is this emphasis on causes as well as on treatment. Although gene editing has been used mainly as medical biotechnology, it also has exciting applications in many other areas, including agriculture and biofuels, where it can produce more disease-resistant strains of crops or algae.
n the late 1900s, the first technologies for genome editing were established. More recently, DNA editing has been made simpler than ever by a modern genome editing technique named CRISPR, invented in 2009.
Correcting Genetic Mistakes to Invention of Gene Therapy:
In the genetic discovery period of the mid-20th century, researchers discovered that the sequence of bases in DNA is transmitted from parent to offspring. Recognition of the latter led to the inescapable conjecture that the means to fix those errors would come with the discovery of “molecular errors” that cause genetic diseases and thus allow disease prevention or reversal.
Process:
Genome editing is a procedure where the genetic code of an organism is modified. Researchers use enzymes to ‘cut’ DNA to create a double-strand break (DSB). Non-homologous end joining (NHEJ) or homology-directed repair occurs via DSB repair (HDR). NHEJ creates random gene knockout mutations, while HDR uses extra DNA to construct a desired sequence within the genome (gene knock-in).
There are four Gene Editing Techniques: Tools to Change the Genome:
- Restriction Enzymes: the native Gene editor
- Zinc Finger Nucleases (ZFNs): Increasing identification
- TALENs Gene Editing: Potentiality within single nucleotide
- CRISPR-Cas9 Gene Editing: The game-changer
Conclusion:
Advances in genome editing methods have opened new doors to what genome editing can do to solve medicine, agriculture, and beyond problems. CRISPR has fully revolutionized what genome editing, by growing the pace and scope of research, will mean for our future. In its role in drug development, diagnostics, and gene drives, we are already feeling the impact of CRISPR, just to name a few. At this pace, don’t be shocked if in the near future you see more discussion about genome editing.
