Difference between revisions of "Deciphering the Rules of Nucleus Architecture with Synthetic Cells and Organelles"
(Created page with "{{subst:project boilerplate}} {{Project |Title=Deciphering the Rules of Nucleus Architecture with Synthetic Cells and Organelles |Agency=NSF |Grant number=MCB-2152267 |Start d...") |
|||
| Line 1: | Line 1: | ||
{{righttoc}} | {{righttoc}} | ||
The goal of this propoject is to decipher the fundamental principles for compartmentalization in cells by building and modeling synthetic cells and organelles from the bottom-up. Working with Imperial College London, will are developing new synthetic biology, microfluidics, biomembrane engineering, and mathematical modelling platform technologies. These are being used to make and model synthetic nuclei that will be used to address fundamental questions relating to its central role in all eukaryotes, by taking an "understanding by building" approach. This research aims to establish a new framework for understanding cell biology fundamentals, that can be used in future studies by us and others. By the end of the project, we will have developed a technological toolkit to probe the principles underpinning compartmentalization in cells, and use these to answer key unanswered biological questions that are uniquely placed to be addressed using our approach. | |||
{| cellpadding=0 cellspacing=0 width=80% | {| cellpadding=0 cellspacing=0 width=80% | ||
| Line 11: | Line 11: | ||
| | | | ||
Collaborators: | Collaborators: | ||
* Yuval Elani (Imperial College) | |||
* Tom Ellis (Imperial College) | |||
Past participants: | Past participants: | ||
| Line 17: | Line 19: | ||
=== Objectives === | === Objectives === | ||
[[Image: | [[Image:bbsrc-synnucleus.png|right|400px]] | ||
Caltech's activities in this collabrative proposal with Imperial College London are focused on the following objectives: | |||
* Development of model-based analysis, design and systems optimization for synthetic organelles. This work will leverage prior work in open-source software tools for modeling of biomolecular systems and will result in extended modeling and analysis tools that will be made available for distribution both to the project and the public. | |||
* Systematic exploration of the effects of compartmentalization on coupled biochemical processes, using the experimental platforms developed at Imperial to validate and build on modeling predictions. | |||
=== References === | === References === | ||
{{project paper list}} | {{project paper list}} | ||
[[Category: | [[Category:Active projects]] | ||
[[Category:Biocircuits projects]] | |||
{{Project | {{Project | ||
|Title=Deciphering the Rules of Nucleus Architecture with Synthetic Cells and Organelles | |Title=Deciphering the Rules of Nucleus Architecture with Synthetic Cells and Organelles | ||
Revision as of 20:42, 11 December 2021
The goal of this propoject is to decipher the fundamental principles for compartmentalization in cells by building and modeling synthetic cells and organelles from the bottom-up. Working with Imperial College London, will are developing new synthetic biology, microfluidics, biomembrane engineering, and mathematical modelling platform technologies. These are being used to make and model synthetic nuclei that will be used to address fundamental questions relating to its central role in all eukaryotes, by taking an "understanding by building" approach. This research aims to establish a new framework for understanding cell biology fundamentals, that can be used in future studies by us and others. By the end of the project, we will have developed a technological toolkit to probe the principles underpinning compartmentalization in cells, and use these to answer key unanswered biological questions that are uniquely placed to be addressed using our approach.
|
Current participants:
Additional participants:
|
Collaborators:
Past participants: |
Objectives
Caltech's activities in this collabrative proposal with Imperial College London are focused on the following objectives:
- Development of model-based analysis, design and systems optimization for synthetic organelles. This work will leverage prior work in open-source software tools for modeling of biomolecular systems and will result in extended modeling and analysis tools that will be made available for distribution both to the project and the public.
- Systematic exploration of the effects of compartmentalization on coupled biochemical processes, using the experimental platforms developed at Imperial to validate and build on modeling predictions.
References
None to date
Research supported by the National Science Foundation award number 2152267.
|
|
|
