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Related Concept Videos

What is Genetic Engineering?00:49

What is Genetic Engineering?

Overview
In-vitro Mutagenesis01:16

In-vitro Mutagenesis

To learn more about the function of a gene, researchers can observe what happens when the gene is inactivated or “knocked out,” by creating genetically engineered knockout animals. Knockout mice have been particularly useful as models for human diseases such as cancer, Parkinson’s disease, and diabetes.
Recombinant DNA01:09

Recombinant DNA

Overview
CRISPR01:59

CRISPR

Genome editing technologies allow scientists to modify an organism’s DNA via the addition, removal, or rearrangement of genetic material at specific genomic locations. These types of techniques could potentially be used to cure genetic disorders such as hemophilia and sickle cell anemia. One popular and widely used DNA-editing research tool that could lead to safe and effective cures for genetic disorders is the CRISPR-Cas9 system. CRISPR-Cas9 stands for Clustered Regularly Interspaced Short...

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Related Experiment Video

Updated: Jun 17, 2026

Mouse Genome Engineering Using Designer Nucleases
12:04

Mouse Genome Engineering Using Designer Nucleases

Published on: April 2, 2014

Genome engineering.

Peter A Carr1, George M Church

  • 1Massachusetts Institute of Technology, Media Lab, Center for Bits and Atoms, Massachusetts, Cambridge, USA. carr@media.mit.edu

Nature Biotechnology
|December 17, 2009
PubMed
Summary
This summary is machine-generated.

Genetic engineering tools have advanced significantly, enabling precise DNA assembly and targeted genome modifications. This progress opens new possibilities for biological research and societal applications.

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Area of Science:

  • Genetics
  • Molecular Biology
  • Bioengineering

Background:

  • Genetic engineering has evolved over 50 years, with tools advancing in scale and precision.
  • The field is experiencing rapid growth in DNA synthesis capacity and cost reduction.

Purpose of the Study:

  • To highlight advancements in genetic engineering tools and their impact.
  • To explore new opportunities in genome engineering arising from technological progress.

Main Methods:

  • Rapid de novo DNA assembly generation.
  • Integration of randomness and selection in engineering approaches.
  • Targeting large numbers of specific genomic sites.

Main Results:

  • Increased capacity for large-scale DNA synthesis.
  • Demonstrated power of combining random and selection-based engineering.
  • Precise targeting of multiple genomic locations.

Conclusions:

  • Current genetic engineering offers unprecedented design originality.
  • New avenues for biological understanding and societal benefit are emerging.
  • Technological advancements are driving innovation in genome engineering.