Very proud of this work and all the efforts from my team and collaborators on this! You can now use DGRs for in vivo targeted hypermutagenesis in E. coli. We also included some early proof of concept in Yeast thanks to @seth-shipman.bsky.social !

Congrats to Chase Morgan @phagemorgan.bsky.social and the phage team!

Want to highlight parallel work too from @aharms485.bsky.social lab that pulled AdfM out of a phage genome screen and independently named it the same! www.biorxiv.org/content/10.1...

Happy to have contributed to this work, @kevincorbett.bsky.social

How diverse is bacterial immunity ?

We report in @science.org how language models allowed us to predict 2.4M antiphage proteins spanning >23K novel potential systems.
👏 @emordret.bsky.social, @alexhv.bsky.social & al doi.org/10.1126/scie...

Explore them here defensefinder.mdmlab.fr/wiki/refseq_...

Congrats Peter!

Bacterial 2′,3′-cGAMP activates a SAVED effector to form membrane-disrupting filaments and restrict phage replication Tak et al. discover that bacteria use 2′,3′-cGAMP, the same signaling molecule employed by mammalian cGAS-STING, for phage defense. In response to phage, 2′,3′-cGAMP activates filament formation of Ca...

Happy to share the final version of my postdoc work on bacterial CBASS immunity with @aaronwhiteley.bsky.social published in @cp-cellhostmicrobe.bsky.social

www.cell.com/cell-host-mi...

Excited to share the first preprint from the lab! We show that ApeA defends against RNA phage infection by cleaving the phage genome:

www.biorxiv.org/content/10.6...

Our work on bacterial Schlafens in phage defense is out today @natmicrobiol.nature.com!

Check out the final version here:
rdcu.be/e7Bmz

We are looking for postdocs and students to expand our team! Official postings are coming soon.

Please reach out if you're interested!
#phage #phagesky #microsky

After >10 years of our lab studying bacterial cGAS-like enzymes, @hobbslabutah.bsky.social finally reconstitutes viral sensing in vitro and discovers how these ancient receptors sense phage protease enzymes to detect virion assembly and activate antiviral immunity

www.biorxiv.org/content/10.6...

Very excited to see this work out today!

Discovering viral immune antagonists directly from predicted protein structures. 🤩 www.science.org/doi/10.1126/...

Huge thanks to the amazing collaborators! 🤗

Out today: We discovered new viral proteins that target immune signaling molecules, solely based on their AlphaFold-predicted shapes

www.science.org/doi/10.1126/...

Congrats Nitzan Tal and coauthors! Thank you Kranzusch lab for the fun collaboration!

Linking below previous thread on our findings

Stunning new structural analysis and mechanism for Tmn anti-phage defense by @fnobrega.bsky.social

www.biorxiv.org/content/10.6...

The giant viruses surprised us at almost every turn of this project, but ultimately led us down a very rewarding path. Happy to share this work is now available online 🧪

How is Condensin II activated during mitosis? 🧬

@damlatetiker.bsky.social Samejima et al. uncover how Condensin II autoinhibition is relieved by the mitotic activator M18BP1, and reveal that M18BP1 also forms a composite DNA anchor with the NCAPG2–NCAPH2 subcomplex to stabilize DNA loops in vitro.

A DNA damage-activated kinase controls bacterial immune pathway expression www.biorxiv.org/content/10.64898/2026.02...

Vibrant color portrait of Jane S. Richardson, the visionary biophysicist and artist who revolutionized structural biology with her invention of ribbon diagrams. She gazes warmly at the camera with a bright, knowing smile that radiates quiet brilliance and decades of curiosity. Her silver-blonde hair woven with gentle waves. Large, elegant dangling earrings catch the light, and she wears a richly patterned brown blouse embroidered with intricate turquoise paisley motifs and delicate beadwork that echoes the molecular elegance she has spent her life depicting. Behind her floats a luminous, dreamlike backdrop of glowing molecular structures--interlocking hexagonal and ribbon-like forms in electric blues, teals, and greens--blending science and art in a single, living canvas.

Hand-drawn and hand-colored (by Jane Richardson) scientific artwork known as a Richardson ribbon diagram (or “ribbon model”), one of the iconic visual inventions of Jane Richardson that transformed the way we see and understand protein structures. A graceful, three-dimensional tangle of protein backbone ribbons twists and spirals through space, rendered in soft pencil lines and luminous watercolor hues. Smooth golden-brown coils represent α-helices that curl like elegant ribbons, while broad teal-green arrows trace the flat, pleated strands of β-sheets slicing through the molecule with directional purpose. Thin, looping golden threads connect the secondary structures, creating a delicate, almost dance-like choreography of biology’s hidden architecture. The entire form is framed by a simple olive-green mat and dark border, giving the drawing the quiet dignity of both fine art and precise scientific illustration—a timeless bridge between molecular reality and human imagination.

Jane Richardson was born #OTD in 1941

+ Developed the Richardson (ribbon) diagram to represent proteins' 3D structure (becoming a standard representation for protein structures)
+ MacArthur Fellow, 1985
+ Elected, Nat'l Academy of Sciences, 1991
+ President, Biophysical Society, 2012

#WomenInSTEM

Pleased to announce that I've joined the editorial board of the Biochemical Journal portlandpress.com/biochemj as an associate editor. I'd love to receive manuscripts focussed on CRISPR, anti-viral defence, archaean biochemistry and nucleic acid processing enzymes.
@biochemsoc.bsky.social

Congratulations to Doi Basu @dwaipayanbasu.bsky.social for publishing his first first-author paper from the lab!
The cryoEM structure of a tubulin-like protein from bacteriophage Goslar forms "microtubules" with nine protofilaments!
authors.elsevier.com/a/1mM253SNvc...

Congrats Doi and Kevin!

Versatile NTP recognition and domain fusions expand the functional repertoire of the ParB-CTPase fold beyond chromosome segregation | PNAS Nucleotide triphosphate (NTP)-dependent molecular switches regulate essential cellular processes by cycling between active and inactive states thro...

Now published. Thank you very much to our collaborative team, and very supportive editors and reviewers!!!

www.pnas.org/doi/10.1073/...

Preprint: Systematic discovery of TIR-based immune signaling systems in bacteria

Conservation of TIR-derived signals accross the tree of life! We found bacterial TIR immune systems that signal via canonical cADPR (like in humans) and 2'cADPR (a plant immune signal).

Documented 11 Thoeris types

Systematic discovery of TIR-based immune signaling systems in bacteria Toll/interleukin-1 receptor (TIR) domains are important for immune signaling across humans, plants and bacteria. These domains were recently found to produce immune signaling molecules in plant immuni...

I’m happy to share our new preprint! We uncovered the full diversity of bacterial TIR-based antiviral immune signaling, massively expanded the known diversity of Thoeris systems, and revealed conservation of TIR-derived immune signals across the tree of life.

www.biorxiv.org/content/10.6...

🧬🛡️How are new immune mechanisms created?

We show how Lamassu antiphage system, originated from a DNA-repair complex and evolved into a compact and modular immune machine, wt Dinshaw Patel lab in @pnas.org.
👏 @matthieu-haudiquet.bsky.social, Arpita Chakravarti & all authors!

doi.org/10.1073/pnas...

🚨Preprint alert - this is a big one! We transfer the revolutionary power of TnSeq to bacteriophages.

Our HIDEN-SEQ links the "dark matter" genes of your favorite phage to any selectable phenotype, guiding the path from fun observations to molecular mechanisms.

A thread 1/8

Bacteria can sense when a virus starts shredding their genome — by detecting methylated mononucleotides.
Here’s the story of how we discovered the Metis defense system 👇
www.biorxiv.org/content/10.1...

Very cool findings!!!

You’ve heard of ubiquitination, meet deazaguanylation: Doug Wassarman in our lab discovered phage defense pathways have co-opted Q nucleobase biosynthetic enzymes to catalyze a new form of protein conjugation chemistry @science.org

www.science.org/doi/10.1126/...

Another important contribution from Sorek and Blokesch labs.

This engineering strategy with synthetic inhibitors could yield more powerful phages than natural inhibitors, since the latter sometimes trigger other defense systems..

A widespread family of viral sponge proteins reveals specific inhibition of nucleotide signals in anti-phage defense Chang et al. discover anti-CBASS 4 (Acb4), a family of viral sponges that inhibits bacterial immunity by sequestering nucleotide immune signals. Acb4 homologs in phages that infect hosts across all ma...

The beautiful, ever-expanding universe of viral proteins targeting nucleotide immune signals!

Paper by @reneechang.bsky.social in @cp-molcell.bsky.social on a nucleotide sponge www.cell.com/molecular-ce...

and preprint by @doudna-lab.bsky.social on viral nucleases www.biorxiv.org/content/10.1...