"The selfish ribosome" paper is now published in @plosbiology.org . Have a look! Many thanks to the editors and reviewers!
doi.org/10.1371/jour...

Excited to share our new findings in @science.org on how the DRT3 bacterial defense system uses a reverse transcriptase that builds DNA repeats without a nucleic acid template. Microbes never cease to amaze!

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

Our ms on re-sampling 4 years apart vibrio phage in natural environments is now out with some improvements. First, clearer evidence of cryptic population dynamics between phage and vibrio, presumably because of genetic diversity. www.nature.com/articles/s41...

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_...

New preprint alert!!! 🚀🤓 We are very happy to finally share this with the world — the result of seven years of work and a new tool to study integrons and discover new functions encoded in these bacterial platforms.

If you want to know more, here is a thread 🧵
www.biorxiv.org/content/10.6...

New preprint out on bioRxiv!

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

Can conjugative plasmids be used to control plasmid and pathogen spread?

Follow me down the rabbit hole that led to this story 🧵

A short research stay in 2019 (back in the pre-COVID era) at José R. Penadés lab turned into the third chapter of my PhD and today it finally sees the light.

Poly-immunity arrays associated with Rhs toxins confer wide protection against competitors Martinkus et al. show that Photorhabdus and Xenorhabdus species encode arrays of immunity genes whose protein products neutralize toxins secreted by competitors. These arrays, often linked to Xer pass...

Happy to share the last work of @jmartinkus.bsky.social, led by @dukasju.bsky.social
Immunity arrays associated with Rhs and CDI toxins and linked to a novel genetic element (XPC cassette) confer protection against competitors. @currentbiology.bsky.social
Kudos !!
www.cell.com/current-biol...

Taming wild replicons: evolution and domestication of large extrachromosomal replicons Bacterial genomes often contain extrachromosomal replicons (ERs), ranging from small, mobile plasmids to large, stably inherited elements, such as meg…

Taming wild replicons: evolution and domestication of large extrachromosomal replicons

#MicroSky

www.sciencedirect.com/science/arti...

Bacterial natural transformation drives cassette shuffling and simplifies recombination in chromosomal integrons Abstract. Integrons act as biobanks of gene cassettes conferring functions crucial for bacterial defense, including protection against phages and antibioti

Our new paper is out in @narjournal.bsky.social We show that natural transformation enables bacteria to shuffle integron cassettes, boosting their phenotypic diversity.
academic.oup.com/nar/article/... 1/5

Methanobrevibacter smithii

Curious about the top methane-maker in your gut? Meet this month's featured microbe and find out! 🦠💨🔥 in @cp-trendsmicrobiol.bsky.social #archaeasky
@sgribaldo.bsky.social @pasteur.fr
🔗 Full article linked in reply👇
www.sciencedirect.com/science/arti...

Jumbo phage–mediated transduction of genomic islands | PNAS Bacteria acquire new genes by horizontal gene transfer, typically mediated by mobile genetic elements (MGEs). While plasmids, bacteriophages, and c...

@prczhaoyansong.bsky.social’s deep dive into the dark matter of compost communities is now out 🎉 Genomic islands hijack jumbo phages—whose capsids enable transfer of large tracts of DNA—shedding new light on the scale & scope of phage-mediated gene flow 😎

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

Antiviral reverse transcriptases reveal the evolutionary origin of telomerase Defense-associated reverse transcriptases (DRTs) employ diverse and distinctive mechanisms of cDNA synthesis to protect bacteria against viral infection. However, much of DRT family diversity remains ...

1/10 Genome maintenance by telomerase is a fundamental process in nearly all eukaryotes. But where does it come from?

Today, we report the discovery of telomerase homologs in a family of antiviral RTs, revealing an unexpected evolutionary origin in bacteria.
www.biorxiv.org/content/10.1...

Ecological constraints foster both extreme viral-host lineage stability and mobile element diversity in a marine community Phages are typically viewed as very rapidly evolving biological entities. Little is known, however, about whether and how phages can establish long-term genetic stability. We addressed this eco-evolut...

Phages evolve fast, or do they?
In oysters, some stay identical for years.
With >1,200 phages & 600 Vibrio genomes, we reveal long-term stability and new mobile elements.
Proud of this collaborative work across our teams (Roscoff-UdeM and @epcrocha.bsky.social www.biorxiv.org/cgi/content/...

Uridine as a potentiator of aminoglycosides through activation of carbohydrate transporters Uridine boosts aminoglycoside treatment efficiency against antibiotic-susceptible as well as antibiotic-resistant E. coli strains.

So excited our antibiotic potentiation story is out 🤩 Led by the extraordinary @manonlang.bsky.social with @fox-science.bsky.social & @amazeld.bsky.social +amazing collaborators @immunobladder.bsky.social @imaneelmeouche.bsky.social 🦠 We believe it can make a difference in #AMR infections!

Bacteriophages infecting an Escherichia coli bacterium. Credit: Institut Pasteur/Chantal Le Bouguénec (Pathogenic Gram-Positive Bacteria Biology Unit) and Laurent Debarbieux (Molecular Biology of the Gene in Extremophiles Unit). Imaging by Perrine Bomme, Ultrastructural Microscopy Platform. Colorization by Jean-Marc Panaud.

🧬 Bacteria fight both antibiotics and viruses with the same genetic tool: integrons!

New study (Institut Pasteur, CNRS, Université Paris Cité & Montréal): ~10% of gene cassettes may defend against phages.

🛠️ One step closer to smarter therapies.

🔗 www.pasteur.fr/en/research-...

😜😜 Thanks Basile

Sedentary chromosomal integrons as biobanks of bacterial antiphage defense systems Integrons are genetic systems that drive bacterial adaptation by acquiring, expressing, and shuffling gene cassettes. While mobile integrons are well known for spreading antibiotic resistance genes, t...

At least 10% of the V. cholerae integron cassettes have novel antiphage activities (see below). Considering that there are 25,000 distinct cassettes of unknown function, integrons constitute an extraordinary and almost inexhaustible reservoir of antiphage functions!

Our paper on how integrons are biobanks of novel minimal defense systems is now out www.science.org/doi/10.1126/... Two main conclusions on this excellent work led by @eloilittner.bsky.social @baptistedarracq.bsky.social 1/n

Sedentary chromosomal integrons as biobanks of bacterial antiphage defense systems Integrons are genetic systems that drive bacterial adaptation by acquiring, expressing, and shuffling gene cassettes. While mobile integrons are well known for spreading antibiotic resistance genes, t...

Our paper is published back2back with one from @amazeld.bsky.social and @epcrocha.bsky.social labs where @baptistedarracq.bsky.social, @eloilittner.bsky.social and co. show that Sedentary Chromosomal Integrons are biobanks of phage defense systems. www.science.org/doi/10.1126/...

Mobile integrons encode phage defense systems Integrons are bacterial genetic elements that capture, stockpile, and modulate the expression of genes encoded in integron cassettes. Mobile integrons (MIs) are borne on plasmids, acting as a vehicle ...

🧪
Finally out after peer review, our work showing that "Mobile #Integrons carry Phage Defense Systems" is now published in Science 🎉

Short 🧵
www.science.org/doi/10.1126/...

Mobile integrons encode phage defense systems Integrons are bacterial genetic elements that capture, stockpile, and modulate the expression of genes encoded in integron cassettes. Mobile integrons (MIs) are borne on plasmids, acting as a vehicle ...

Have also a look at our back-to-back study for mobile integrons by Nicolas Kieffer from @jaescudero.bsky.social group !
www.science.org/doi/10.1126/...
+ a similar story in V. parahaemolyticus by @landongetz.bsky.social from @themaxwelllab.bsky.social
www.nature.com/articles/s41...

An enormous thanks for the great co-first author @eloilittner.bsky.social and for our supervisors @celineloot.bsky.social @epcrocha.bsky.social @amazeld.bsky.social @fredoleroux.bsky.social. Many thanks to all co-authors !!

On the bioinformatic side, eloilittner.bsky.social found a diverse arsenal of anti-phage defenses in SCIs. Strikingly, systems in integrons are always compact (< 3 genes), and smaller than their homologs outside integrons (likely due to cassette size constraints)

The integron of our favorite model Vibrio cholerae was mostly “dark matter” as most cassettes had no known role. We found this intriguing and cloned 88 cassettes, testing them for phage resistance. We found 16 defensive cassettes and named the systems after gallic mythology

Sedentary chromosomal integrons as biobanks of bacterial antiphage defense systems Integrons are genetic systems that drive bacterial adaptation by acquiring, expressing, and shuffling gene cassettes. While mobile integrons are well known for spreading antibiotic resistance genes, t...

White smoke, we have a new pope and also 16 new anti-phages systems in sedentary integrons (SCIs) !
In collaboration with the Rocha lab, we show in our new paper that cassettes of these large platforms encode many known anti-phage defenses, and uncovered 16 new ones.
www.science.org/doi/10.1126/...

Alt : Structure of the apo Lamassu protein complex. Schematic model of the active LmuA tetramer nuclease (top right). Lamassu icon (top left).

Glad to share the work of @yli18smc.bsky.social and co on Lamassu, a bacterial defense system related to Rad50/Mre11 (RM). While RM carefully trims DNA ends for repair, Lamassu chops up the host chromosome. Our study reveals how it is regulated to minimize damage, activating only during infection.