Thrilled to present our comparative study on the evolution of zygotic genome activation (ZGA)!! 🥚🧬

Amazing PhD work of @campobes.bsky.social together with @fedemantica.bsky.social and many collaborators! @melisupf.bsky.social @crg.eu. Thread below 1/15

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

muchas felicidades para ti y todo tu equipo, Alex!

Rapid compensatory evolution within a multiprotein complex preserves telomere integrity Intragenomic conflict with selfish genetic elements spurs adaptive changes in subunits of essential multiprotein complexes. Whether and how these adaptive changes disrupt interactions within such comp...

How to keep in step when your (protein) partner speeds up…

Here we investigated the adaptive remodeling of a protein-protein interaction surface essential for telomere protection.

Congrats to whole team!

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

Visualisierung von Ubiquitin-vermittelter Regulation Eine enorm vielseitige Möglichkeit Proteine und Membranfunktionen zu regulieren, basiert auf der Vermittlung des kleinen Proteins Ubiquitin. Die Biochemikerin Brenda Schulman stellt die Zusammenhänge ...

Last call! 📢 Don’t miss Brenda Schulman at the upcoming Hans Tuppy Lecture tommorrow, sharing fresh insights into the dynamic regulation of the ubiquitin–proteasome system! @univie.ac.at @mpibiochem.bsky.social www.oeaw.ac.at/detail/veran...

From nematode to Nobel: How community-shared resources fueled the rise of Caenorhabditis elegans as a research organism | PNAS Experimental organisms such as the nematode Caenorhabditis elegans are fundamental to biological discovery. The success of C. elegans research has ...

C. elegans researchers were early adopters of open science: "The development of common resources and the belief that research findings and mutant strains should be freely shared has propelled worm research to the forefront"
www.pnas.org/doi/10.1073/...

Evolution of taste processing shifts dietary preference - Nature Calcium imaging of taste neurons and the ventral brain provides insight into evolutionary divergence of food choice in Drosophila species, supporting a role of sensorimotor processing in addition to p...

Thrilled to share our new paper!
With @tomtom-auer.bsky.social team, we asked how #evolution reshapes what animals #eat to match their ecological niches. Using pan-neuronal Ca2+ imaging, we show that the changes are in how the brain processes #taste.
Link @nature.com: www.nature.com/articles/s41...

Happy to share that my PhD project is finally published!🪱✨
Selfish genes are found across the tree of life. They can disrupt inheritance patterns and at the same time act as units for molecular innovation. Here we tried to answer one big question: how do selfish genes emerge in the first place?

The Vienna BioCenter Summer School 2026 call is now open for talented undergrads, it's a great opportunity for students who are interested in graduate study in the life sciences. Georg Busslinger from CeMM is recruiting! Please share
https://training.vbc.ac.at/summer-school/

🚨 New paper alert!

Scientists in the Burga lab show for the first time how toxin-antidote elements—selfish genetic elements that perpetuate by poisoning those embryos that don’t inherit them—evolved from normal cellular proteins. More: https://imba.science/3M3fRyq

Polina drove this project and made the critical observations that revealed the entire evolutionary path. I couldn’t be prouder (also, she’s my first student!). Polina is on the job market, and any lab would be incredibly lucky to have someone with her talent!

So grateful to all our collaborators (Ben-David & Dong Labs) and lab members who helped drive this project. But I especially want to thank Polina Tikanova @polinatikanova.bsky.social @imbavienna.bsky.social @oeaw.bsky.social @vbcscitraining.bsky.social

Our results also uncover an even deeper principle. Nematode and plant F-box proteins are thought to engage in arms races with parasitic elements. In this conflict, accidental targeting of self-proteins is inevitable—making the birth of selfish genes a by-product of innate immunity.

This interaction suppressed the toxicity of future paralogs via ubiquitin-mediated degradation, allowing alleles to persist long enough to evolve selfish behavior. These results also support the idea that novelty can arise largely through neutral steps (positive selection is not always the answer!)

What triggered this recurrent shift in function? All the evidence points to a fortuitous binding event: a fast-evolving F-box protein latched onto the tRNA synthetase.

To tackle this, we studied selfish genes segregating in wild populations of the nematode C. tropicalis. There, we found that a core gene—a tRNA synthetase essential from bacteria to humans—gave rise to three independent toxin–antidote selfish systems in a single species.

This question is surprisingly hard to answer. Selfish genes evolve rapidly in an arms race with host defenses, obscuring their origins. And their earliest steps often involve deleterious alleles that should be purged by selection—making the rise of selfishness both unlikely and paradoxical.

Recurrent evolution of selfishness from an essential tRNA synthetase in Caenorhabditis tropicalis - Nature Ecology & Evolution In Caenorhabditis tropicalis, three toxin–antidote elements arose via gene duplication from the essential tRNA-synthetase subunit FARS-3. The ancestral antidote probably acquired affinity for FARS-3, ...

www.nature.com/articles/s41...

🪱 Selfish genes are everywhere and drive some of biology’s biggest innovations (CRISPR, antibody recombination, epigenetics). Yet almost no one asks the obvious question: how does a selfish gene begin? Our new manuscript uncovers how selfishness can emerge directly from the host genome.

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