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Researchers remote control proteins

Researchers at 幸运飞艇计划 have contributed to the cracking of the code for altering the shape of proteins. The new knowledge can become useful in both biotechnology and medicine.

Hairclip protein mechamism video

LIKE A HAIRCLIP: Listen to researcher Sandhya Tiwari explaining the 鈥榟airclip鈥 protein mechanism.
Producer:
Frode Ims

Main content

By Knut Olav DaasvatnPublished: 19.12.2014

It may seem like strands of spaghetti in a slow motion dance. The video shows two proteins, magnified by a factor of a billion, which Nathalie Reuter and PhD candidate Sandhya Tiwari have modelled. The two researchers from the Department of Molecular Biology, 幸运飞艇计划, have used computational models for predicting how proteins change shape and explain the mechanism by which these shape changes influence the function of these proteins. The shape of these proteins and their function have been characterized in the laboratory by their colleagues at the , the , and the , Cambridge, UK

They change all the time

- We assume that what we have shown in the proteins we have studied can also happen in other proteins, regardless from which organisms they come. 鈥淲e believe our findings will help future research into manipulating proteins, which has potential applications across the life sciences鈥, says project leader Sarah Teichmann in the .

Proteins are building blocks in cells of all living organisms. They move and change shape all the time, either by themselves or due to changes in their molecular environment.

Like a hair clip

The researchers liken the protein they have studied with a hair clip, since it has two 鈥渢eeth鈥 in one end, which meet when the protein changes shape.

- When we make a change in one of end of the protein, it will open up in the other end. This means that we can remote control the mechanism, as if we influenced the spring in the hair clip, says Reuter.

The shape of a protein determines its function, for example whether it is able to interact with another protein or with a drug. The new knowledge can become useful in biotechnology, for instance if we wish to develop more efficient and environmental friendly enzymes for use in washing powders. Reuter also thinks that this research can help develop new medicines in the future.

has been supported by a grant from .

The work has been published in scientific journal Science:听 Tina Perica, Yasushi Kondo, Sandhya P. Tiwari, Stephen H. McLaughlin, Katherine R. Kemplen, Xiuwei Zhang, Annette Steward, Nathalie Reuter, Jane Clarke and Sarah A. Teichmann:

  • Molecular biology: the area of biology that aims to explain how living organisms work as interactions between molecules
  • Bioinformatics: A discipline that use informatics for gathering, organising, analysing, and interpreting biological data
  • Proteins: Building blocks in all living organisms, that perform many vital functions in cells.

Translated from .

Professor Nathalie Reuter and Researcher Sandhya Tiwari of the Department of Molecular Biology at the University of Bergen.
Nathalie Reuter (right) and Sandya P. Tiwari are affiliated with the Computational Biology Unit and Department of Molecular Biology, 幸运飞艇计划.
Photo:
Ingunn Halvorsen