Congrats, Can! Great paper!!

Check out 2 papers and a related Perspective on tissue regeneration in @science.org this week
Species-specific oxygen sensing governs the initiation of vertebrate limb regeneration | Science www.science.org/doi/10.1126/...

Thanks a lot for your kind words, Mekayla. This is really an amazing study, glad we could contribute a small bit to it. Congrats again to the whole team!!

We are hiring!

Proud to share this work with @kevinchalut.bsky.social and Byron Mui. Why do some injuries scar while others regenerate? Using digit tip models, we show the ECM is a key driver. HA-rich ECM promotes regeneration, and boosting it can shift healing away from fibrosis. www.science.org/doi/10.1126/...

As every year, we had an exciting practical at @pdncambridge.bsky.social where vet students are shown how to handle reptiles. Big thanks to #AmazingReptiles !!

Let's get this hashtag started! The 2026 Santa Cruz Developmental Biology Meeting is happen this August! We will share updates using #SCDB26.

Can't wait!

scdb2026.sites.ucsc.edu

Aurora B controls microtubule stability to regulate abscission dynamics in stem cells Mouse embryonic stem cells remain connected by bridges for hours after cell division. In this paper, Kodba et al. show that a high Aurora B activity at the bridge leads to microtubule stabilization. S...

Very excited that the lab's first paper is out! We showed that in stem cells, Aurora B controls abscission dynamics by regulating microtubules stability and MCAK recruitment. Very happy with this streamlined version of our 2024 preprint.
www.cell.com/cell-reports...

Excited to share our work on epithelial multilayering - identifying why stem cell stay in the basal layer and how and why differentiating cells move up. Great collab with @manningresearch.bsky.social and Niessen labs! Check out preprint and great summary below www.biorxiv.org/content/10.6...

Excited to share this new work from Ana Raffaelli, in collaboration with Ewa Paluch's lab and involving several of my colleagues at Cyclana Bio. In this paper, we show that basement membrane mechanics instructs developmental signalling and fate patterning.
www.biorxiv.org/content/10.6...

🚨 New Preprint from the Paluch & Chalut Labs 🚨
Ana Raffaelli et al show that the stiffness of substrate (in vitro) / basal membrane (in vivo) determine how cells interpret biochemical signals (BMP4) and which fates they acquire
#mechanobiology #hESCs #substratemechanics
doi.org/10.64898/202...

Congrats, Rashmi! Well deserved!!

Congrats, Rashmi! Well deserved!!

In frog brains (orange-blue), developing axons from the eye (yellow-white) follow a specific path to reach their final destination. Along the way, they make a characteristic turn. This turning is mediated by both chemical and mechanical signals. The exact nature of this chemo-mechanical coupling is what the researchers in this study aimed to understand.

During #brain development, axons grow along precise pathways. Scientists have now discovered that tissue stiffness & chemical signalling interact with each other.

👉 mpzpm.mpg.de/news/news-de...

@fau.de @embl.org @franzelab.bsky.social

#research #neuroscience

Presenting our latest results!!

Glad to have been part of the team! Huge thanks to everyone especially @evapillai.bsky.social @niklasgampl.bsky.social and @franzelab.bsky.social !!!

#xenopus #mechanobiology

#Frogpower here

Thanks, Elias!

Very excited to share our latest work on the interplay between chemical and mechanical signals orchestrating brain development 🧠⚙️! This was a great team effort and I am grateful to have been a part of it!! @evapillai.bsky.social @sudimukherjee.bsky.social @franzelab.bsky.social

🚨Why can’t mammals regenerate legs or arms like frog tadpoles or salamanders?
Our preprint tackles (part of) this BIG question with surprising findings about oxygen sensing
🔗 www.biorxiv.org/content/10.1...
Happy New Year, everyone! 🎉
🐭 vs 🐸 #evodevo #regenerative #cellbio 🧵👇

I'd like to thank everyone who contributed to this tour de force, especially Eva and Sudi, our collaborators for their input (Christine Holt, @ben-fabry.bsky.social , @kevinchalut.bsky.social and many others), and our funders @erc.europa.eu @humboldt-foundation.de @dfg.de @wellcometrust.bsky.social

Accurate brain wiring is mechanochemical!
Environmental stiffness shapes chemical cues, and Piezo 1 tunes tissue mechanics via adhesions, controlling the expression of guidance cues in axon pathfinding.

Long-range chemical signalling in vivo is regulated by mechanical signals!

Building on our ex vivo results, we stiffened a local brain region – using sustained compression. This significantly increased Sema3A expression, showing that tissue mechanics instruct chemical guidance cues in vivo.

Is stiffness alone enough to change chemical guidance cues? Embedding soft brain regions in stiff 3D gels incresed levels of chemical guidance cues (using #HCRimaging) compared with soft 3D gels.

Lower N-cadherin and NCAM1 levels result in softer brains AND a decrease in Sema3A. Changing tissue stiffness seems to be enough to alter chemical guidance cue expression.

How does Piezo1 regulate brain #stiffness? Softening is not due to fewer cells, softer cells, or cytoskeletal changes. What changes is cell-cell #adhesion! Reducing Piezo1 decreases N-cadherin and NCAM1 (two major adhesion proteins).

Piezo1 regulates the mechanical landscape of the brain. Depleting it results in softer brain tissue (which isn’t just a consequence of decreasing chemical guidance cues).

Downregulating Piezo1 in the developing brain strongly reduces the expression of long-range chemical guidance cues, such as Semaphorin 3A (Sema3A) and Slit 1.
Piezo 1 isn’t just mechanical - it shapes the chemical landscape essential for long-range axon navigation.

🧠 In the developing #Xenopus brain, retinal ganglion axons follow a precise path to the optic tectum. Reducing #Piezo1, a mechanosensitive ion channel, in axons or surrounding tissues, result in axons stalling, wandering, or misrouting.

Long-range chemical signalling in vivo is regulated by mechanical signals - Nature Materials Tissue stiffness mediated by Piezo1 is shown to regulate the expression of diffusive guidance cues in the developing Xenopus laevis brain, revealing a crosstalk between mechanical signals and long-ran...

Paper alert: Our study led by @evapillai.bsky.social and @sudimukherjee.bsky.social showing that mechanical properties of the #brain actively shape the molecular landscape during development and #axonpathfinding is finally out! www.nature.com/articles/s41... @pdncambridge.bsky.social @fau.de @MPZPM

Thanks, Thomas! I really enjoyed my stay. Lots of good discussions with great people.