Summary
Mitochondria and Endoplasmic Reticulum (ER) Contact sites (MERCs) are points in which the surfaces of the two organelles run in parallel. MERCs gained attention recently due to their fundamental contribution to several cell processes, such as Ca2+ and lipid homeostasis, mitochondrial fission, and apoptosis. To execute and regulate these processes, MERCs must be dynamic and react to the needs and metabolic state of the cell. Interestingly, the organelles stay separated by a narrow cleft, usually 10-50 nm apart. The width of the MERCs gap and its size (i.e. area of a membrane involved in the contacts) are the critical parameters that determine their cellular functions. Despite the literature on MERCs has grown considerably, the precise molecular structure and role of MERCs are poorly defined.
In the proposed project I will investigate the regulation of MERCs plasticity by small molecule compounds. Using a high-content phenotypic screening approach, based on a FRET mitochondria-ER proximity probe, I will identify the compounds affecting MERCs structure. These bioactive hits will be validated through biochemical, confocal and electron microscopy assays. Moreover, I will search for the protein target of the hit molecule using the methodology developed during my PhD. Finally, I will evaluate the capability of the identified hit molecules to act as therapeutic lead compounds for pathological conditions by testing the identified molecules on cells with defective MERCs. Therefore, this project will open new research paths related to both MERCs structure and function.
I will obtain deep knowledge of mitochondrial biology and high content screening, which will complement my current expertise obtained during PhD. Besides, I will develop transferable skills needed to successfully accomplish the proposed project. The project also brings the benefits to the European Research Area, since it builds international collaboration and transfers knowledge between two research areas/teams.
In the proposed project I will investigate the regulation of MERCs plasticity by small molecule compounds. Using a high-content phenotypic screening approach, based on a FRET mitochondria-ER proximity probe, I will identify the compounds affecting MERCs structure. These bioactive hits will be validated through biochemical, confocal and electron microscopy assays. Moreover, I will search for the protein target of the hit molecule using the methodology developed during my PhD. Finally, I will evaluate the capability of the identified hit molecules to act as therapeutic lead compounds for pathological conditions by testing the identified molecules on cells with defective MERCs. Therefore, this project will open new research paths related to both MERCs structure and function.
I will obtain deep knowledge of mitochondrial biology and high content screening, which will complement my current expertise obtained during PhD. Besides, I will develop transferable skills needed to successfully accomplish the proposed project. The project also brings the benefits to the European Research Area, since it builds international collaboration and transfers knowledge between two research areas/teams.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/896745 |
| Start date: | 01-08-2021 |
| End date: | 31-07-2023 |
| Total budget - Public funding: | 183 473,28 Euro - 183 473,00 Euro |
Cordis data
Original description
Mitochondria and Endoplasmic Reticulum (ER) Contact sites (MERCs) are points in which the surfaces of the two organelles run in parallel. MERCs gained attention recently due to their fundamental contribution to several cell processes, such as Ca2+ and lipid homeostasis, mitochondrial fission, and apoptosis. To execute and regulate these processes, MERCs must be dynamic and react to the needs and metabolic state of the cell. Interestingly, the organelles stay separated by a narrow cleft, usually 10-50 nm apart. The width of the MERCs gap and its size (i.e. area of a membrane involved in the contacts) are the critical parameters that determine their cellular functions. Despite the literature on MERCs has grown considerably, the precise molecular structure and role of MERCs are poorly defined.In the proposed project I will investigate the regulation of MERCs plasticity by small molecule compounds. Using a high-content phenotypic screening approach, based on a FRET mitochondria-ER proximity probe, I will identify the compounds affecting MERCs structure. These bioactive hits will be validated through biochemical, confocal and electron microscopy assays. Moreover, I will search for the protein target of the hit molecule using the methodology developed during my PhD. Finally, I will evaluate the capability of the identified hit molecules to act as therapeutic lead compounds for pathological conditions by testing the identified molecules on cells with defective MERCs. Therefore, this project will open new research paths related to both MERCs structure and function.
I will obtain deep knowledge of mitochondrial biology and high content screening, which will complement my current expertise obtained during PhD. Besides, I will develop transferable skills needed to successfully accomplish the proposed project. The project also brings the benefits to the European Research Area, since it builds international collaboration and transfers knowledge between two research areas/teams.
Status
CLOSEDCall topic
MSCA-IF-2019Update Date
28-04-2024
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