Trapping viruses in DNA 'cages' to inhibit infections
07 September 2021
Half-shell Heroes
DNA origami – designing sequences of DNA to fold into tiny useful structures – is reaching an exciting stage: fine-tuning. Tweaking designs could make all the difference when putting devices like this to task inside our bodies. Pictured using cryogenic electron microscopy, this 'nano-shell' is designed to trap virus particles – it’s 10,000 times smaller than a crane claw in an amusement arcade game. Starting with an icosahedron shape (a ball made with 20 triangular faces), biotechnologists found the key to getting the triangular plates of DNA to stick together precisely is a slightly bumpy, bevelled surface. They're now able to make these open shells big enough to engulf viruses, successfully trapping hepatitis particles in lab-grown cells. The next challenge is to test and tweak the shells again, lining them with antibodies to recognise viruses inside living tissues, and trapping them before they can spread their infection.
Written by
- Video from work by Christian Sigl and colleagues
- Department of Physics, Technical University of Munich, Munich, Germany
- Video copyright held by the original authors
- Research published in Nature Materials, June 2021
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