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
Very excited to see this work out today!
Discovering viral immune antagonists directly from predicted protein structures. π€© www.science.org/doi/10.1126/...
Huge thanks to the amazing collaborators! π€
CBASS is a cyclic nucleotide-based antiviral system in bacteria that is related to cGAS-STING signaling in animals. One of the big questions is how CBASS is activated during phage infection? We made some progress on this during my final year in the Kranzusch lab.
www.biorxiv.org/content/10.6...
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...
@nitzantal.bsky.social @romihadary.bsky.social @soreklab.bsky.social use structure prediction and in silico binding site analysis to discover viral immune evasion proteins! Exciting for our lab @reneechang.bsky.social @riveralopz.bsky.social to help with this project.
www.science.org/doi/10.1126/...
Excited to see our paper out in @science.org π§½β¨
Congrats @nitzantal.bsky.social !
Congratulations to Sonomi Yamaguchi for her paper at @nature.com. Sonomi discovered Clover defense and explained how nucleotide signals control each step of viral sensing, immune regulation, and viral restriction β named for her beautiful "four-leaf" structures π
www.nature.com/articles/s41...
Excited to share our new paper led by a wonderful Jing Liu on designing de novo IDRsπ§ͺπ₯οΈ
Chemical inhibition of a bacterial immune system
Small molecules inhibit type II Thoeris anti-phage systems from diverse bacteria. One compound, IP6C, improves phage-therapy against P. aeruginosa & is effective against Thoeris in polymicrobial communities
www.cell.com/cell-host-mi...
Another amazing work by @ostermanilya.bsky.social! A new NADβΊ-depleting defense system and its phage antagonists, revealing an exciting bacterialβphage arms race. π‘οΈβοΈ Congrats Ilya and coauthors!
Our new paper is out in Nature π. We show that m1Ξ¨ in mRNA vaccines doesnβt just quiet immunity, it also directly enhance translation by reshaping ribosome dynamics in a sequence-dependent way π§¬
Full paper : rdcu.be/eY5gx
βUp βtill now, we couldnβt detect it, because we didnβt look at the garbage cans of cells.β
Yifat Merbl found a new trick of the immune system, and is part of Natureβs 10, a list of people who shaped science in 2025
go.nature.com/3XZQdgY
Bacterial genomes encode a rich repertoire of antiphage systems, but we still know surprisingly little about when these systems are actually expressed.
In this preprint, Lucas Paoli et al, ask what shapes antiphage systems expression in native contexts.
www.biorxiv.org/content/10.6...
Incredible to learn how far-reaching and diverse Thoeris really is! TIRs play key roles across kingdoms, and this work beautifully highlights their bacterial origins.
Congrats @erezyirmiya.bsky.social & Azita! ππ
π§¬π‘οΈHow 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.
π @matthieu-haudiquet.bsky.social, Arpita Chakravarti & all authors!
doi.org/10.1073/pnas...
Our nuclease-protease story is out! We explored a fascinating case of coevolution and modularity in prokaryotic immune systems: www.science.org/doi/10.1126/...
Thanks to wonderful coauthors/collaborators/friends, the whole @doudna-lab.bsky.social and everyone at @innovativegenomics.bsky.social
So proud of @nitzantal.bsky.social ππ»such an inspiring and brilliant scientist!
An incredible story revealing a novel defense system that senses DNA shredding during phage infection β beautifully solved by @ostermanilya.bsky.social ! π§¬β¨
Today in @nature.com , we highlight how a cousin of CRISPR-Cas10, mCpol, establishes an evolutionary trap in anti-phage immune systems.
Check out @erinedoherty.bsky.social and my work from @doudna-lab.bsky.social lab here:
www.nature.com/articles/s41...
Our story describing the Panoptes bacterial immune defense system is now finally peer-reviewed and published today! www.nature.com/articles/s41...
Effector-triggered immunity (ETI) indirectly detects pathogen effector activity on the host cell.
Kevin Barthes,Tanita Wein and I examine how prokaryotic and eukaryotic viruses deploy similar effectors that activate ETI, underscoring its central role across the tree of life.
tinyurl.com/mr3a3xh2
π’ New preprint alert!
We designed synthetic proteins that can block bacterial immune systems, allowing phages + plasmids to overcome natural defenses.
This could transform phage therapy + genetic engineering.
Hereβs what we found π§΅
Preprintπ: www.biorxiv.org/content/10.1...
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It was such a fun & inspiring journeyπ Huge thanks to @reneechang.bsky.social- it was a pleasure working on this together! Special thanks to all amazing contributors Nathalie Bechon, @nitzantal.bsky.social, @ostermanilya.bsky.social, @erezyirmiya.bsky.social, Jeremy Garb, @amitaig.bsky.social.
8/
Remarkably, 65 sponges inhibit β₯1 immune system, and 25 block multiple π§¬. They evolved specificity & diversity, a striking example of the phageβbacteria arms race βοΈ. Sponges appear key for phages, shaping many bacteriaβvirus interactions, and new families keep being discovered!
7/
Tad2 homologs that bind N7-cADPR π§½, neutralizing Type IV Thoeris β the first anti-defense protein discovered for this system. Evidence for this novel function was collected both in vivo using multiple infection assays and in vitro with biochemical experiments.
6/
We found the first Pycsar-targeting sponges, from the Tad2 family! Using mutation analysis, we showed that MoTad2 binds Pycsar molecules in a pocket distinct from its Type II Thoeris target π§½.
5/
We discovered 10 Acb2 homologs that inhibit Type I Thoeris! A new function for this family π One was crystallized bound to its target molecule 3β²cADPR, thanks to the expertise of @reneechang.bsky.social β revealing how this sponge works.
4/
84 homologs were screened experimentally against 7 immune systems, including different types of Thoeris, CBASS & Pycsar β using a high-throughput 96-well infection assay π§ͺ (developed with @nitzantal.bsky.social & Jeremy Garb).
3/
A few homologs from each family already showed intriguing diversity in specificity to signals, which made us excited to systematically explore the full range of sponge diversity.
We collected thousands of Tad1, Tad2 & Acb2 homologs, built phylogenetic trees, and tested representatives' functionπ³βοΈ
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Phages must fight back! βοΈ
Sponges 𧽠are viral proteins that bind signaling molecules, preventing activation of defenses. The first families discovered were Tad1 & Tad2 (anti-Thoeris & CBASS) and Acb2 (anti-CBASS).
