What Happens When CRISPR Backfires?

Seeker

25 Sept 201803:31

Summary

TLDRThe video discusses the revolutionary gene-editing technology CRISPR, highlighting its potential to treat diseases and its recent setbacks in human trials due to safety concerns. New studies show that CRISPR can unintentionally kill cells and raise cancer risks by favoring defective cells, along with causing larger-than-expected DNA deletions. As researchers explore alternatives like the RNA-editing tool REPAIR, the importance of careful evaluation of CRISPR’s safety and efficacy is emphasized. The video invites viewers to stay updated on CRISPR developments and its implications for both human health and agriculture.

Takeaways

🔬 CRISPR technology, specifically CRISPR-Cas9, is designed to cut DNA at specific locations to modify genes.
⚠️ The process of using CRISPR is not as simple or safe as initially thought, with potential risks involved.
🧬 Since its introduction in 2013, CRISPR has been explored for treating various inherited disorders and diseases.
🛑 Human trials for CRISPR applications have faced delays, with a clinical hold placed on the first proposed trial in the US.
📊 Recent studies indicate that CRISPR's cutting mechanism may lead to cell death or halted growth, raising safety concerns.
💔 CRISPR can leave more defective cells alive than healthy ones, potentially increasing cancer risk, which contradicts its therapeutic goals.
🔍 New research shows that CRISPR can cause larger deletions in DNA than previously recognized, affecting the accuracy of gene editing.
⚗️ Alternative gene-editing technologies, such as REPAIR, are being developed, which use different enzymes and methods.
🔄 REPAIR works with RNA and allows for temporary or reversible changes, offering a potentially safer option.
🌱 Beyond human applications, CRISPR has the potential to enhance agricultural practices by creating genetically modified crops.

Q & A

What is CRISPR and how does it function?
-CRISPR, specifically CRISPR-Cas9, is a gene-editing technology that cuts DNA at specific locations to disable or modify genes. It works by targeting a section of DNA representing a certain gene and induces repair processes in the cell.
What are some potential applications of CRISPR?
-CRISPR has potential applications in treating inherited disorders, cancer, and other diseases for which there are currently no treatment options.
Why have human trials for CRISPR been delayed?
-Human trials have been delayed due to new studies suggesting risks associated with CRISPR, such as damaging healthy cells and inadvertently increasing cancer risks.
What is the role of the p53 gene in the context of CRISPR?
-The p53 gene helps regulate a cell's life cycle and prevent cancer. CRISPR may leave more defective p53 cells alive, raising the risk of cancer instead of decreasing it.
What concerns have arisen regarding the accuracy of CRISPR?
-Recent research shows that CRISPR can cause larger deletions in DNA than previously thought, affecting about 20% of cells. This could lead to significant unintended consequences, including cancer risk.
What is the new genetic editing tool mentioned as a potential alternative to CRISPR?
-The new genetic editing tool is called REPAIR, which uses Cas13 to work with RNA instead of DNA, allowing for temporary or reversible changes.
How does REPAIR differ from CRISPR?
-Unlike CRISPR, which permanently alters DNA, REPAIR can make temporary changes and is more precise, targeting individual base pairs rather than larger sections of DNA.
What are some risks associated with CRISPR's cutting function?
-Risks include the potential for killing healthy cells, causing unintended mutations, and inadvertently increasing the risk of cancer due to the survival of defective cells.
What caution should be taken when using CRISPR technology?
-There needs to be a careful analysis and understanding of CRISPR's risks and benefits before proceeding with human trials, given its permanent impact on the genome.
What broader applications might CRISPR have beyond human health?
-CRISPR technology could also be used in agriculture to produce genetically modified crops, enhancing food production and resilience.