Summary
Symbiotic bacteria play critical roles in animal evolution, development and metabolism. The molecular and cellular mechanisms underlying these fundamental interactions, however, are largely unknown.
To fill this major knowledge gap, I will establish the bacteria-Hydractinia symbiosis as a new model system to fully characterize key cross-kingdom signalling molecules and response mechanisms. The results of my ERC proposal (MORPHEUS) will lead to ground-breaking insights into molecular drivers of eukaryotic morphogenesis, illuminate the evolutionary history of developmental signals for animals – including humans – and provide new chemical scaffolds with intrinsic biological activities that are urgently needed for drug discovery.
The marine colonial hydroid Hydractinia belongs to an early branching metazoan lineage, dating back more than 500 million years. The organism reproduces through a larval stage, which upon perception of yet unidentified bacterial morphogenic signals, produced within marine bacterial biofilms, undergoes transformation into the mature organism. In the absence of the bacterial signals, the larva fails to settle and eventually dies. This fundamental process is the basis of this proposal. Capitalizing from my recent pioneering work, I will address the following pressing research questions: Which bacterial signals ensure larval recruitment and metamorphosis? How are bacterial signalling molecules perceived? How is the system protected against alien species? I will apply an innovative combination of state-of-the-art methodologies developed within the fields of natural product and synthetic organic chemistry, microbiology and molecular biology to pursue an in-depth biochemical analysis of this paradigmatic system. Results of MORPHEUS will be transformative for many scientific branches across biological and chemical disciplines, and directly impact the development of sustainable anti-biofouling and drug discovery strategies.
To fill this major knowledge gap, I will establish the bacteria-Hydractinia symbiosis as a new model system to fully characterize key cross-kingdom signalling molecules and response mechanisms. The results of my ERC proposal (MORPHEUS) will lead to ground-breaking insights into molecular drivers of eukaryotic morphogenesis, illuminate the evolutionary history of developmental signals for animals – including humans – and provide new chemical scaffolds with intrinsic biological activities that are urgently needed for drug discovery.
The marine colonial hydroid Hydractinia belongs to an early branching metazoan lineage, dating back more than 500 million years. The organism reproduces through a larval stage, which upon perception of yet unidentified bacterial morphogenic signals, produced within marine bacterial biofilms, undergoes transformation into the mature organism. In the absence of the bacterial signals, the larva fails to settle and eventually dies. This fundamental process is the basis of this proposal. Capitalizing from my recent pioneering work, I will address the following pressing research questions: Which bacterial signals ensure larval recruitment and metamorphosis? How are bacterial signalling molecules perceived? How is the system protected against alien species? I will apply an innovative combination of state-of-the-art methodologies developed within the fields of natural product and synthetic organic chemistry, microbiology and molecular biology to pursue an in-depth biochemical analysis of this paradigmatic system. Results of MORPHEUS will be transformative for many scientific branches across biological and chemical disciplines, and directly impact the development of sustainable anti-biofouling and drug discovery strategies.
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More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/802736 |
| Start date: | 01-02-2019 |
| End date: | 31-10-2024 |
| Total budget - Public funding: | 1 498 750,00 Euro - 1 498 750,00 Euro |
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Original description
Symbiotic bacteria play critical roles in animal evolution, development and metabolism. The molecular and cellular mechanisms underlying these fundamental interactions, however, are largely unknown.To fill this major knowledge gap, I will establish the bacteria-Hydractinia symbiosis as a new model system to fully characterize key cross-kingdom signalling molecules and response mechanisms. The results of my ERC proposal (MORPHEUS) will lead to ground-breaking insights into molecular drivers of eukaryotic morphogenesis, illuminate the evolutionary history of developmental signals for animals – including humans – and provide new chemical scaffolds with intrinsic biological activities that are urgently needed for drug discovery.
The marine colonial hydroid Hydractinia belongs to an early branching metazoan lineage, dating back more than 500 million years. The organism reproduces through a larval stage, which upon perception of yet unidentified bacterial morphogenic signals, produced within marine bacterial biofilms, undergoes transformation into the mature organism. In the absence of the bacterial signals, the larva fails to settle and eventually dies. This fundamental process is the basis of this proposal. Capitalizing from my recent pioneering work, I will address the following pressing research questions: Which bacterial signals ensure larval recruitment and metamorphosis? How are bacterial signalling molecules perceived? How is the system protected against alien species? I will apply an innovative combination of state-of-the-art methodologies developed within the fields of natural product and synthetic organic chemistry, microbiology and molecular biology to pursue an in-depth biochemical analysis of this paradigmatic system. Results of MORPHEUS will be transformative for many scientific branches across biological and chemical disciplines, and directly impact the development of sustainable anti-biofouling and drug discovery strategies.
Status
SIGNEDCall topic
ERC-2018-STGUpdate Date
27-04-2024
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