Biologist Explains One Concept in 5 Levels of Difficulty - CRISPR | WIRED

WIRED17 minutes read

CRISPR is a powerful gene-editing tool with vast potential in biomedical science, though ethical concerns surrounding its use in humans, particularly in germline editing, persist. While precision and technical challenges exist, CRISPR's versatility extends beyond medicine to applications like using DNA as a hard drive and predicting diseases based on genetic variations.

Insights

  • CRISPR, a powerful gene-editing tool, holds immense potential in biomedical science for targeting specific mutations in diseases like cancer, despite ethical concerns regarding its use in humans, especially germline editing.
  • The evolution of CRISPR technology beyond Cas9 to various bacterial species highlights the complexity and versatility of genome editing, emphasizing the importance of distinguishing between editing somatic and germline cells while underscoring the need for continued research funding to unlock new possibilities in genome engineering.

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Recent questions

  • What is CRISPR?

    Tool for gene editing, biomedical applications, and precision cuts.

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Summary

00:00

Unveiling CRISPR: Biomedical Tool with Boundless Potential

  • Neville Sanjana, a biologist at New York University and the New York Genome Center, aims to explain CRISPR in five levels of complexity.
  • CRISPR is a biomedical tool enabling gene editing, crucial for understanding diseases like autism and cancer.
  • CRISPR is a molecular pair of scissors that edits the genome by making precise cuts and changes.
  • Potential uses of CRISPR include targeting tumor cells to fix mutations like p53 in cancer.
  • Ethical concerns arise regarding CRISPR's use in humans, especially in germline editing and access to the technology.
  • The state of genetics is not advanced enough to allow precise changes like choosing eye color using CRISPR.
  • CRISPR's precision can be affected by genetic variations, necessitating thorough genome sequencing before use.
  • Despite technical challenges, CRISPR holds immense potential for various applications beyond biomedical science.
  • CRISPR's versatility may extend to using DNA as a hard drive, diagnostics, and tracking cells in embryos.
  • CRISPR's future may involve predicting diseases based on genetic variations and functional screens, advancing genetic understanding.

13:39

Unraveling Genetics: CRISPR's Evolution and Potential

  • The complexity of genetics makes it challenging to alter visible traits like eye color or height due to the intricate nature of the genes controlling these characteristics. Scientists emphasize the importance of distinguishing between editing somatic cells, which impact individuals directly, and germline cells, which can affect future generations, highlighting the need to focus on somatic cell editing for human gene editing. The evolution of CRISPR technology has expanded beyond the initial Cas9 enzyme, with various versions found in different bacterial species, such as Streptococcus pyogenes and Staphylococcus aureus, each offering unique capabilities for genome editing, including targeting different genomic regions and even RNA instead of DNA.
  • The vast metagenomic diversity of CRISPR systems presents numerous unexplored possibilities, such as RNA-targeting CRISPR, showcasing the importance of funding basic science to uncover new avenues in genome engineering. Understanding CRISPR and genome editing is crucial in today's biology-centric world, offering insights into self-understanding and the fundamental components of human existence, with endless potential for further discoveries and advancements in the field.
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