> By 2021, these engineered bacteria could be simulated in unprecedented detail. Every gene, every major protein, and nearly every metabolic reaction in JCVI-syn3A.
I think the crux is here:
> Even after years of study, 91 of JCVI-syn3A's genes remain unannotated, of which roughly one-third are essential. Deleting any single one kills the cell, yet we have no idea what they do – representing some of biology's most fundamental unsolved puzzles.
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I think minimal cells and virtual cells are especially exciting as they open up a path to create fully controlled experimental environments for biochemistry from the ground up.
Right now sooo much time in biochemistry goes into working around the limitations of what already happens to be present in an organism. E.g. we may know 5% of mechanisms that go on in a cell, but the remaining 95% percent of mechanisms that go on may still brick your experiment, and without knowing about them you essentially have to shrug and trial and error your way through them.
In contrast in a synthetic minimal cell, we could start out with an organism where we know 95% of the mechanisms that are going on, and then study new mechanisms one gene at a time, steadily building up to bigger and bigger mechanisms.
Strangely it seems to me that a lot of effort is going more into being able to simulate full cells that contain unknown mechanisms, rather than trying to use the capabilities to create hypothesis to uncover the unknown mechanisms. Yes, that probably expedites the path towards simulating much bigger human cells, but ultimately still leaves us in the dark on most fronts.
> Strangely it seems to me that a lot of effort is going more into being able to simulate full cells that contain unknown mechanisms, rather than trying to use the capabilities to create hypothesis to uncover the unknown mechanisms. Yes, that probably expedites the path towards simulating much bigger human cells, but ultimately still leaves us in the dark on most fronts.
I imagine it's much easier to create and test hypotheses about the unknown mechanisms, when you can view them in context of a larger system, with reasonable performance, allowing you to metaphorically "grab them in your palm" and tweak on the fly. We work better when we explore things, instead of immediately taking on problems that are at the limit of our computational tools, requiring individual brains (and tons of paperwork) to make up for the difference.
In this sense, researching the nano-scale basics, and aiming to simulate micro-scale cellular systems, are actually aligned - as long as they're not cutting too much corners, the latter is creating space for former work to be done efficiently.
>Strangely it seems to me that a lot of effort is going more into being able to simulate full cells that contain unknown mechanisms, rather than trying to use the capabilities to create hypothesis to uncover the unknown mechanisms. Yes, that probably expedites the path towards simulating much bigger human cells, but ultimately still leaves us in the dark on most fronts.
Seems the result of this general trend in science towards brute prediction and abandoning the goal of explanation or understanding.
Check out Michael Levin’s lab for a refreshing and amazing example of a group that’s bucking the trend.
They are doing tons of experiments by starting with the premise that cells and their networks have intelligence, then using tools from behavioral science to convince them to do what the experimenters want (e.g. “grow an eye here”). I’ve been convinced by Levin’s talks that this is a more promising area of research than genetics.
> By 2021, these engineered bacteria could be simulated in unprecedented detail. Every gene, every major protein, and nearly every metabolic reaction in JCVI-syn3A.
I think the crux is here:
> Even after years of study, 91 of JCVI-syn3A's genes remain unannotated, of which roughly one-third are essential. Deleting any single one kills the cell, yet we have no idea what they do – representing some of biology's most fundamental unsolved puzzles.
---
I think minimal cells and virtual cells are especially exciting as they open up a path to create fully controlled experimental environments for biochemistry from the ground up.
Right now sooo much time in biochemistry goes into working around the limitations of what already happens to be present in an organism. E.g. we may know 5% of mechanisms that go on in a cell, but the remaining 95% percent of mechanisms that go on may still brick your experiment, and without knowing about them you essentially have to shrug and trial and error your way through them.
In contrast in a synthetic minimal cell, we could start out with an organism where we know 95% of the mechanisms that are going on, and then study new mechanisms one gene at a time, steadily building up to bigger and bigger mechanisms.
Strangely it seems to me that a lot of effort is going more into being able to simulate full cells that contain unknown mechanisms, rather than trying to use the capabilities to create hypothesis to uncover the unknown mechanisms. Yes, that probably expedites the path towards simulating much bigger human cells, but ultimately still leaves us in the dark on most fronts.