CRISPR gene editing - what is it?

John Innes Centre

30 Sept 202204:21

Summary

TLDRThis video explains CRISPR gene editing as a revolutionary method for improving plants through precise genetic mutations. Unlike traditional breeding and mutation techniques that rely on random changes, CRISPR utilizes guide RNA and the Cas9 enzyme to target specific DNA sequences, allowing for quicker and more accurate development of desirable traits in crops. With the increasing need for sustainable food production amid climate challenges, CRISPR offers a promising solution, significantly reducing the time required for breeding new plant varieties from years to just a few, thereby enhancing food security.

Takeaways

🌱 Crispr gene editing is a modern method for developing better plants by utilizing mutations.
🧬 Mutations are natural changes in the genetic sequence of DNA, occurring frequently in all organisms.
📄 If printed, the genetic sequence of a wheat plant would stack as tall as The Shard in London.
🌾 On average, a single wheat cell contains about 90 mutations compared to its mother plant.
🍽️ Our ancestors selected plants with beneficial mutations, leading to improved food traits like size and taste.
🥦 Mutations in Brassica plants have resulted in various vegetables such as broccoli, kale, and cauliflower.
🧪 Traditional plant breeding combines traits from two different plants, while mutation breeding uses chemicals or radiation.
⏳ Mutation breeding can be slow, often taking many years to identify desirable mutations.
✂️ The Crispr system consists of guide RNA and Cas9, which work together to make precise cuts in DNA.
⚡️ Crispr allows for targeted mutations, drastically reducing the breeding time from 8-15 years to just a few years.

Q & A

What is CRISPR gene editing?
-CRISPR gene editing is a modern method of modifying DNA in plants by making precise cuts at specific locations in the genetic sequence, allowing for targeted mutations.
How does traditional plant breeding differ from mutation breeding?
-Traditional plant breeding combines desirable traits from two separate plants of the same species, while mutation breeding introduces random mutations through chemicals or radiation to create new varieties.
What are the two components of the CRISPR system?
-The two components of the CRISPR system are guide RNA, which searches for the specific DNA sequence, and Cas9, which cuts the DNA at the targeted location.
Why is CRISPR considered more efficient than traditional mutation breeding?
-CRISPR is considered more efficient because it allows for precise targeting of mutations, significantly reducing the time needed to develop new plant varieties from 8-15 years to just a few years.
How do mutations contribute to plant variation?
-Mutations introduce genetic variations in plants, which have historically been selected by our ancestors for traits that improved food quality, such as size and taste.
What is the significance of genetic variation in crops like wheat?
-Genetic variation is significant because it helps ensure the adaptability and resilience of crops, with each wheat cell containing an average of 90 mutations from the mother plant.
What challenge do plant breeders face in the context of climate change?
-Plant breeders face the challenge of needing to produce more food sustainably to meet the demands of a growing population while adapting to the impacts of climate change.
Can CRISPR introduce multiple mutations like traditional mutation breeding?
-No, CRISPR typically introduces a single, targeted mutation at a time, unlike traditional mutation breeding, which can create many random mutations.
What are some crops developed through traditional mutation breeding?
-Many varieties of cereal, fruit, and vegetable crops, including several barley varieties used in beer production, have been developed through traditional mutation breeding methods.
How does the natural repair process of plants work after CRISPR cuts the DNA?
-After CRISPR cuts the DNA, the plant attempts to repair itself, and during this process, it can make mistakes that result in mutations, which are the intended outcomes of the gene editing.