New technique can measure thousands of proteins in a few minutes

Researchers from Charité - Universitätsmedizin Berlin and the Francis Crick Institute have developed a mass spectrometry-based technique capable of measuring samples containing thousands of proteins within just a few minutes.

It is faster and cheaper than a conventional blood count. To demonstrate the technique's potential, the researchers used blood plasma collected from COVID-19 patients. Using the new technology, they identified eleven previously unknown proteins which are markers of disease severity. The work has been published in Nature Biotechnology.

Thousands of proteins are active inside the human body at any given time, providing its structure and enabling reactions that are essential to life.

The body raises and lowers the activity levels of specific proteins as required, including when responding to external factors such as pathogens and drugs. The detailed patterns of the proteins found inside cells, tissues, and blood samples can therefore help researchers to better understand diseases or make diagnoses and prognoses.

In order to obtain this 'protein fingerprint', researchers use mass spectrometry, a technology known to be both time-consuming and cost-intensive.

'Scanning SWATH', a new mass-spectrometry-based technology, promises to change this. Developed under the leadership of Prof. Dr. Markus Ralser, Director of Charité's Institute of Biochemistry, this technology, which is much faster and cost-effective than previous methods, enables researchers to measure several hundred samples per day.

"In order to speed up this technology, we changed the mass spectrometer's electric fields. The data produced are of such extreme complexity that humans can no longer analyze them," explains Einstein Professor Prof. Ralser, who is also a Group Leader at the Francis Crick Institute in London.

He adds: "We therefore developed computer algorithms that are based on neural networks and which use these data to extract the relevant biological information. This enables us to identify thousands of proteins in parallel and greatly reduces measuring timescales. Fortunately, this method is also more precise."

This high-throughput technology has a broad range of potential applications, ranging from basic research and large-scale drug development to the identification of biological markers (biomarkers), which can be used to estimate an individual patient's risk. The technology's suitability for the latter was demonstrated by the researchers' study on COVID-19.

As part of this research, the team analyzed blood plasma samples from 30 Charité inpatients with COVID-19 of varying degrees of disease severity, comparing the protein patterns obtained with those of 15 healthy individuals. The actual measurements conducted on individual samples only took a few minutes.

The researchers were able to identify a total of 54 proteins whose serum levels varied according to the severity of COVID-19. While 43 of these proteins had already been linked to disease severity during earlier studies, no such relationship had been established for 11 of the proteins identified.

Several of the previously unknown proteins associated with COVID-19 are involved in the body's immune response to pathogens which increases clotting tendency.

"In the shortest of timeframes, we discovered protein fingerprints in blood samples which we are now able to use to categorize COVID-19 patients according to severity of disease," says one of the study's lead authors, Dr. Christoph Messner, who is a researcher at Charité's Institute of Biochemistry and the Francis Crick Institute.

He continues: "This type of objective assessment can be extremely valuable, as patients will occasionally underestimate the severity of their disease. However, in order to be able to use mass spectrometry analysis for the routine categorization of COVID-19 patients, this technology will need to be refined further and turned into a diagnostic test. It may also become possible to use rapid protein pattern analysis to predict the likely course of a case of COVID-19. While the initial findings we have collected are promising, further studies will be needed before this can be used in routine practice."

Prof. Ralser is convinced that mass spectrometry-based investigations of the blood could one day complement conventional blood count profiles.

Proteome analysis is now cheaper than a complete blood count. By identifying many thousands of proteins at the same time, the proteomic analysis also produces far more information. I, therefore, see enormous potential for widespread use, for instance in the early detection of diseases. We will therefore continue to use our studies to develop proteome technology for this type of application."

Dr. Markus Ralser, Professor, Director of Institute of Biochemistry, Charité - Universitätsmedizin Berlin

Source:
Journal reference:

Messner, C.B., et al. (2021) Ultra-fast proteomics with Scanning SWATH. Nature Biotechnology. doi.org/10.1038/s41587-021-00860-4.

Comments

The opinions expressed here are the views of the writer and do not necessarily reflect the views and opinions of AZoLifeSciences.
Post a new comment
Post

While we only use edited and approved content for Azthena answers, it may on occasions provide incorrect responses. Please confirm any data provided with the related suppliers or authors. We do not provide medical advice, if you search for medical information you must always consult a medical professional before acting on any information provided.

Your questions, but not your email details will be shared with OpenAI and retained for 30 days in accordance with their privacy principles.

Please do not ask questions that use sensitive or confidential information.

Read the full Terms & Conditions.

You might also like...
Yeast Proteins Found to Offer Powerful Emulsifying Action