Swedish researchers have found a new way of identifying proteins without looking at their structure which could support drug development
All living cells contain proteins with different functions, depending on the type of cell.
Researchers at the University of Gothenburg have discovered a way to identify proteins even without looking at their structure. The method is faster, easier and more reliable than previous methods.
Currently, the general view is that each protein’s structure is what controls its function in cells.
The atomic sequences, meaning how the atoms are arranged in the proteins, create the protein’s structure and shape. But there are many proteins that lack a well-defined structure.
Researcher Gergely Katona has developed a new method where proteins are scanned based on the number of amino acids (or the number of different atoms) they contain in order to identify them and their function instead of identifying them based on their structure.
With this scanning method, the researchers were able to predict relatively reliably which combination of amino acids is needed to bind to the protein survivin.
The outcome was a reliability of about 80%, which is better than when you use the protein’s primary structures for identification.
Several thousand peptides containing 15 amino acids were tested and the researchers were able to conclude that it was the amino acid content that affected their binding to survivin, while the structure of the peptides had almost no significance.
Katona said: “[Simply] counting things has often been a successful method in science.
“Here we counted the number of amino acids and were able to predict the function of the protein surprisingly well.”
- Single protein causes the fibrosis death spiral
- Scientists discover new protein activity in telomeres
- New method precisely locates gene activity and proteins across tissues
- Glowing protein improves deep-tissue images
The researchers see advantages with this method of scanning proteins.
Machine learning (AI) also speeds up the process of linking the number and type of amino acids to a certain function.
This in turn means that the development of new biological drugs can be accelerated.
In the researchers’ experiments with this new scanning method, a completely new function of the protein survivin was also discovered.
Survivin is mainly prominent in embryo cells and prevents programmed cell death. But in cancerous tumours, survivin becomes unregulated and thus facilitates the development of the cancer.
The researchers have now seen that survivin directly influences another protein, PRC2, which switches off and on various functions in the DNA in the cell, like a kind of programming.
Dysfunctional PRC2 can also be linked to various forms of cancer.
Today’s cancer drugs target both survivin and PRC2, but with the newly discovered link between survivin and PRC2, the drugs may need to be designed differently to avoid serious side effects.
Katona said: “We saw that if we suppressed the level of survivin, activity in PRC2 increased.
“The dream for pharmaceutical companies is to find the right targets in the atomic sequences to be able to balance the two proteins.”
The results are published in iScience.
Image: The illustration shows how different areas of PRC2 (the one on the right side) binds to survivin. The researchers chopped the PRC2 sequence into units of 15 amino acids and arranged them on a grid. Each pixel in that grid is 1 unit. The colour shows binding strength to survivin. Blue means the unit in that pixel doesn’t bind/binds weakly to survivin, and the bright pink pixels are the strongest binders. Credit: Atsarina Larasati Anindya.