Fantastic - the nitroplast joining a pretty exclusive club there.
Bigelowii itself seems very interesting, even without this nitrogen fixing organelle, having two completely different phases to it's life - one in a weird dodecahedral calcareous shell and one without as a mobile flagellate. Apparently it can exist and reproduce in either form, and occasionally switch forms. It took scientists a long while to realize the two forms are actually the same species.
I've had cells growing fine in 20 L Cytiva wave bags and then fail to grow in 20 L Sartorius wave bags. Anyone that tells you they know how a cell grows is lying to themselves :)
Since computational biology is all about simulation, do the chloroplast, the mitochondria, and now the nitro-last, have definitions that could be actively simulated ?
Comparing it to CO2 is facile, the problem there involves the equilibrium state (or lack thereof) between what is emitted and what is able to remove it.
Excess levels of bio-available nitrogen are quickly reduced by *gestures vaguely at biosphere*.
Bigelowii itself seems very interesting, even without this nitrogen fixing organelle, having two completely different phases to it's life - one in a weird dodecahedral calcareous shell and one without as a mobile flagellate. Apparently it can exist and reproduce in either form, and occasionally switch forms. It took scientists a long while to realize the two forms are actually the same species.
Deuce Bigelowii.
Huh.
The "tokoroten" noodles are just agar.
Pretty much everyone in biology tries growing cells in agar, right? Surely that can't have been an amazing discovery?
https://en.wikipedia.org/wiki/Plastid
Edit: "It was a type of algae called Braarudosphaera bigelowii. Hagino fondly just calls it Bigelowii."
Is this pronounced bigggie-lowie?
Excess levels of bio-available nitrogen are quickly reduced by *gestures vaguely at biosphere*.