10/ This first micropublication is just the beginning.
Understanding how proteins respond to magnetic fields may help uncover natural magnetosensitive molecules and how magnetic fields can be used to influence biological function.
9/ On the molecular side, future work will also mutate residues around the flavin inside the protein.
Goal: understand how small changes in chemical environment shape magnetic sensitivity.
This helps reveal the molecular basis of magnetosensitivity in proteins.
8/ So far, measurements were only done at magnetic fields stronger than Earthβs field.
Next: test how the protein behaves in extremely weak or near-zero magnetic fields.
New instrumentation is already being built, including a hypomagnetic setup.
7/ Conclusion: the study shows that MagLOV2 behaves in a way consistent with radical-pair theory when exposed to weak magnetic fields, now demonstrated inside living cells.
That makes it a useful experimental system for studying magnetic-field-sensitive chemistry in biology.
6/ In the radical-pair mechanism, light excitation can trigger an electron transfer that creates a pair of radicals whose electron spins are correlated.
External magnetic fields can influence how those spins evolve, which can change the outcome of the chemical process.
5/ Panel B tracks fluorescence from the same bacterial colony at two magnetic field strengths.
When the field turns ON (shaded regions), fluorescence increases at 1.0 mT but decreases at 2.5 mT.
A sign flip consistent with predictions from radical-pair quantum models.
4/ At very low magnetic field strengths, fluorescence increases as the field becomes stronger. However, at moderately higher field strengths, the trend reverses: fluorescence decreases as the magnetic field strength increases.
3/ To do this, the team built a custom magneto-fluorescence imaging platform they call the "Bacterioscope."
It combines controlled magnetic fields, synchronized illumination, and fluorescence imaging to track how living bacterial colonies respond to magnetic fields in real time.
2/ In this study, the fluorescent protein MagLOV2 was characterized for how its brightness changes depending on the strength of an applied external magnetic field in living bacterial cells.
We have been funding the @quantumbioorg.bsky.social since its launch.
Their new micropublication shows that MagLOV2 exhibits magnetic field dependent fluorescence in living bacterial cells, with behavior consistent with the radical pair mechanism.
Breakdown of the work below 𧡠1/10
Choose quantum biology.
Science advances not only by discovering new phenomena, but by developing new ways to think about them.
>> Biological sensitivity to weak magnetic fields has been observed for decades! <<
What remains unclear is the mechanism. Let's figure it out.
What if the default in science was: methods open, data shared, results visible as they happen?
What if we could open up research to allow for faster feedback, discoveries that don't stop at one lab, and real-time collaboration across researchers?
The science doesn't change. The feedback loop does.
Interested in discussing science and quantum biology?
The Science Working Group is a mix of people from different backgrounds who meet weekly to discuss papers and ideas, explore where the field is headed, bring scientific context into DAO discussions, and more.
Join us: quantumbiology.community
βThe main bottleneck of modern science is not talent or tools. It is process.β
This piece explores how science could move faster if we shared results sooner, tested ideas in smaller steps, and focused more on learning than publishing.
If youβre curious, give it a read!
2/ The winning essays tackle questions about how quantum phenomena might operate in living systems, offering thoughtful perspectives on where the field could be headed.
Congratulations to all eight winners, and a special nod to our ecosystemβs own Dr. Michael Montague for earning third place.
1/ >> News from the world of quantum biology.
This essay competition recently announced its winners, and it reflects the growing energy around the field. When nearly a hundred thinkers from across the globe engage seriously with this question, it shows that quantum biology is drawing attention.
New friends at the Quantum Biology Institute!
The Institute hosted a lab tour as part of an event organized by Founders, Friends, and Fermentation, bringing together founders, researchers, and operators interested in quantum biology, biomanufacturing, and the future of the bioeconomy.
These findings contribute to ongoing efforts to experimentally investigate magnetic-field-sensitive processes under physiologically relevant conditions.
The results suggest that the sensitivity of MagLOV2 to magnetic fields is consistent with an underlying quantum mechanism that operates in the complex environment of a living cell.
This complex response is consistent with established models of a process known as the βradical pair mechanismβ, which is a leading hypothesis for how biological molecules can be affected by weak magnetic fields.
However, at moderately higher field strengths, the trend exhibits non-monotonic behavior: the fluorescence switches from increasing to decreasing as the magnetic field strength increases, before eventually leveling off.
In this study, the fluorescent protein MagLOV2 was characterized for how its brightness changes depending on the strength of an applied external magnetic field in living bacterial cells. At very low magnetic field strengths, fluorescence increases as the field becomes stronger.
The Quantum Biology Institute has released its first micropublication!
Check it out! www.biorxiv.org/content/10.6...
To the first of many! Details below β¬οΈ
Check out this piece on Lean Science written by one of our co-founders. Dr. Ale Lodesani.
It explores how science could move faster if we shared results sooner, tested ideas in smaller steps, and focused more on learning than publishing.
If youβre curious, give it a read:
Science evolves when its tools evolve. Weβve expanded what we can measure and compute, yet the systems that coordinate funding and collaboration are only beginning to change. As those systems evolve, discovery can move faster and open the door to a broader range of ideas. Let's decentralize science.
Join us this Thursday, February 19 at 9am PT / 12pm ET for our weekly community call.
Weβll be joined by the @quantumbioorg.bsky.social team, the DAOβs grant recipient, who will share an update on the progress theyβve made since beginning their work.
π Link in our Discord below!
Happy Valentine's Day!
Quantum biology shows up in more places than people may expect.
What other biological processes do you think might be quantum?
3/ This approach doesnβt replace rigor - it strengthens it by increasing learning speed and collaboration.
DeSci is about upgrading the process of science so knowledge can move at the pace discovery deserves.
