Excited to be starting my group “Ecophotonics” with a Minerva FastTrack fellowship! Big thanks to @vignolinilab.bsky.social for your support! Also grateful to my PhD supervisor Malte Gather, and collaborators & students from marine biology to physics. 🧪👩🏼🔬💡https://www.mpikg.mpg.de/6920542/ecophotonics
Magnetically sensitive proteins could lead to new imaging tools and remote-controlled drugs | Science | AAAS 🧪 www.science.org/content/arti...
‘Remote controlled’ proteins illuminate living cells www.nature.com/articles/d41... 🧪
For the history, and where this is all heading see this thread: bsky.app/profile/andr...
Our research on magneto-sensitive fluorescent proteins and some of their applications has now been published!
Huge thank you to the many many people involved in making this happen. 🧪
www.nature.com/articles/s41...
Our next student-led seminar is coming up! Organised by James Bridson (Oxford) & Sam Kemery (Bristol), we’re excited to welcome Assistant Professor Jennifer Brophy as our speaker.
Jenn is a plant synthetic biologist at Stanford University. The lab's work explores how the form of a plant affects...
Great news! @mariaingaramo.bsky.social 's company (Nonfiction Labs) made a remote-controlled antibody.
Its binding turns on and off with a magnet.
This is a HUGE step towards our dream of magnetically controlled drugs. Imagine a cancer drug that ONLY attacks the tumor, not the rest of your body.
The Oxford team: Mark Hankins, Kevin Henbest, Madhavi Krishnan, Harrison Steel, Andrew Baldwin, Justin Benesch, Christiane Timmel, Chris Schofield, Achillefs Kapanidis, Stuart Mackenzie, Stuart Peirson, Sabine Huth-Rauschenbach. Photo credit: Thomas Player, University of Oxford.
Oxford researchers will lead a new £6M BBSRC-funded project nature’s “quantum compass” to uncover, how animals sense Earth’s magnetic field and turn this knowledge into innovative biotechnologies. 🧭 #QuantumBiology #BBSRC #OxfordResearch
Read more: eng.ox.ac.uk/news/new-pro...
1 week left to apply for a postdoctoral position in my group to lead the experimental component of a 5 year BBSRC project on synthetic microbial communities
www.ucl.ac.uk/work-at-ucl/...
Hi could you add me please! ORCID: orcid.org/0000-0002-23... Thank you 😊
Generative design of synthetic gene circuits for functional and evolutionary properties https://www.biorxiv.org/content/10.1101/2025.09.26.678595v1
🚨 We’re hiring!
The OPIG group is looking for multiple postdocs to join OpenBind, an open science initiative generating foundational structural biology data to power the next era of AI/ML for drug discovery.
opig.stats.ox.ac.uk
openbind.uk
It’s an exciting possibility!
Has been so cool to follow this fantastic work, congrats! Conclusion mentions “improving the release efficiency by enhancing the specific heat absorption rate of the nanoparticles” could this enable multiplexed control - different frequencies activating different nanoparticles in the same cell?
We’ve developed the first-ever method to control nucleic acid activity and gene-expressing synthetic cells with a deeply tissue penetrating alternating magnetic field 🧬 🧪 🧲!!!
Published in *Nature Chemistry*
Led by Ellen Parkes
@syncelleu.bsky.social #chemsky
www.nature.com/articles/s41...
A. Structure of AsLOV2 PDB~2V1A (Halavaty, 2007) with mutations resulting in MagLOV~2 highlighted. Spin transitions driven by radio-frequency (RF) fields in the presence of a static magnetic field are optically detected via fluorescence measurements on an otherwise standard widefield microscope. Similar effects have recently been observed in other protein systems (Burd 2025, Meng 2025, Feder 2025). B. Simplified photocycle diagram in the case of a large external magnetic field. C. A single cell expressing MagLOV 2 displaying an MFE of ~50% (measured as a change in fluorescence intensity in the presence of an applied field). For MFE measurements, the magnetic field was switched between 0 mT and 10 mT. D. Black dots: data from a single cell expressing MagLOV 2 displaying an ODMR signal with ~10% contrast. The static field B_0 is ~21.6 mT. Blue line (shade): the mean (std) of all single cell data in a field of view (~1000 cells). E. The static magnetic field B_0 was varied by adjusting the magnet's position, and ODMR spectra recorded. Red-lines are Lorentzian fits. Blue line is a theoretical prediction (i.e. is not a fit) of the expected resonance frequency of an electron spin with $\bar\gamma_e$=28 MHz/mT.
Electronics, radio electronics, optical parts, and an animal sized MRI coil are assembled to perform fluorescence MRI measurements using MagLOV.
MagLOV quantum sensing update! Much improved imaging (>10% single cell ODMR contrast), detailed characterisation and simulation, and new experimental demonstrations taking us a step closer to applications.
www.biorxiv.org/content/10.1...
SI: www.biorxiv.org/content/10.1...
Now out in JACS. pubs.acs.org/doi/full/10....
Grateful to thoughtful reviewers who found some errors in our model and encouraged us to make a better one! A renaissance in magnetobiology is coming...
Advertisement for PhD position
My lab at @ethzurich.bsky.social is looking for a motivated PhD student. We develop chemical tools for advanced fluorescence microscopy 🔬 and work at the interface of synthetic chemistry ⚗️ and protein engineering 🦠. Sharing with skilled Master students appreciated. More info at tinyurl.com/2dbjk5ty
NEW PREPRINT! Do you think we can do better when characterising resource competition properties of gene circuit modules? If no, think again; if yes, you’re in for a pitch how exactly we can do that – automated culturing, cybergenetic control and all! 1/
doi.org/10.1101/2025...
And as we showed MagLOV by itself has a spin resonance dependent fluorescence www.biorxiv.org/content/10.1...
Maurer et al. showed EYFP can be driven into a metastable state arxiv.org/abs/2411.16835
Hot on the heels of @adamezracohen.bsky.social and @kxiang.bsky.social work, unpacking the flavin-fluorescent protein mechanism in detail www.biorxiv.org/content/10.1...
@nahal75bagheri.bsky.social and @scburd.bsky.social rd.bsky.social show MagLOV resonance can be transferred to mScarlet www.biorxiv.org/content/10.1...
New spin resonance measurements with fluorescent proteins out this month from Burd et al., following the still mind-blowing result from @andrewgyork.bsky.social and @mariaingaramo.bsky.social that if you create a selection pressure for a quantum system, nature will oblige! 🧪
New preprint 🎇 We developed oligonucleotide PROTACs (OligoPROTACs), which show comparable activity to small molecule equivalents - but can be *switched off*, using DNA nanotech, to restore protein levels!
Last of Disha's trilogy!
#chemsky 🧪 @uclchemistry.bsky.social chemrxiv.org/engage/chemr...
How do tiny magnetic fields affect biochemistry? Overflowing with pride over Katherine Xiang's study on a giant magnetic field effect in a red fluorescent protein, www.biorxiv.org/content/10.1...
Legitmately thrilled to share our latest work, in which @fernpizza.bsky.social solved an experimental challenge in plasmid biology as old as the field: measuring how plasmids compete and evolve within individual cells!
Bravo @plos.org!
US exec orders "stand in direct conflict with our core values, our mission, edit policies"
"PLOS will not compromise on issues of scientific rigor & editorial integrity... we seek diversity because more expert voices make for better science"
theplosblog.plos.org/2025/02/plos...
Experimental evolution of evolvability | Science www.science.org/doi/10.1126/...
