Summary
Knowledge of protein structure is fundamental for the understanding of biology, disease mechanisms, drug development, and biotechnology. Recent progress with electron cryogenic microscopy (cryo-EM) simplified and tremendously accelerated the determination of protein structures including multiple protein conformations. Many functionally important protein conformations and protein-protein complexes are transient and are not easily accessible by conventional cryo-EM. These transient states can, however, be freeze-trapped and their structures solved to high resolution using the time-resolved cryo-EM (trEM). Despite its long history and high interest from the cryo-EM community, technical difficulties prevented the spread of the methodology, and no commercial devices enabling trEM sample preparation exists. During the ERC-CoG project, we developed a new approach to the preparation of trEM samples which has advantages over the other reported technologies. In this POC project, we propose to undertake steps that will explore the suitability of our technology for application to a wide variety of protein samples and to evaluate the commercial potential of the technology with aim of bringing it to cryo-EM users rapidly. To achieve this, we plan to (1) expand the number of protein samples to be tested on our instrument thus enabling rapid user access and simultaneous validation of the methodology, (2) perform additional research to further improve the method by addressing the remaining bottlenecks, (3) make steps towards defining the best process and materials for industrial production of microfluidic chips, and (4) redesign the time-resolved plunger into a compact pre-industrial prototype. These steps will broadly validate, improve, and derisk the technology to make it more attractive to cryo-EM instrumentation-making companies to bring the technology to the cryo-EM community.
Unfold all
/
Fold all
More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/101123392 |
| Start date: | 01-02-2024 |
| End date: | 31-07-2025 |
| Total budget - Public funding: | - 150 000,00 Euro |
Cordis data
Original description
Knowledge of protein structure is fundamental for the understanding of biology, disease mechanisms, drug development, and biotechnology. Recent progress with electron cryogenic microscopy (cryo-EM) simplified and tremendously accelerated the determination of protein structures including multiple protein conformations. Many functionally important protein conformations and protein-protein complexes are transient and are not easily accessible by conventional cryo-EM. These transient states can, however, be freeze-trapped and their structures solved to high resolution using the time-resolved cryo-EM (trEM). Despite its long history and high interest from the cryo-EM community, technical difficulties prevented the spread of the methodology, and no commercial devices enabling trEM sample preparation exists. During the ERC-CoG project, we developed a new approach to the preparation of trEM samples which has advantages over the other reported technologies. In this POC project, we propose to undertake steps that will explore the suitability of our technology for application to a wide variety of protein samples and to evaluate the commercial potential of the technology with aim of bringing it to cryo-EM users rapidly. To achieve this, we plan to (1) expand the number of protein samples to be tested on our instrument thus enabling rapid user access and simultaneous validation of the methodology, (2) perform additional research to further improve the method by addressing the remaining bottlenecks, (3) make steps towards defining the best process and materials for industrial production of microfluidic chips, and (4) redesign the time-resolved plunger into a compact pre-industrial prototype. These steps will broadly validate, improve, and derisk the technology to make it more attractive to cryo-EM instrumentation-making companies to bring the technology to the cryo-EM community.Status
SIGNEDCall topic
ERC-2023-POCUpdate Date
12-03-2024
Images
No images available.
Geographical location(s)
