Anna Kanevskaya
@annakanevskaya.bsky.social
Postdoc | bacterial defence systems ⚔️🛡️🦠
Congratulations!!! Fantastic news!
September 4, 2025 at 2:47 PM
Congratulations!!! Fantastic news!
I'm using clariostar plus - it works perfectly
May 14, 2025 at 4:56 PM
I'm using clariostar plus - it works perfectly
Thank you so much, Daan!
May 14, 2025 at 10:53 AM
Thank you so much, Daan!
Thank you so much for sharing, François! I posted a thread with more details on my page — very glad to share this work and would be happy to discuss it!
April 7, 2025 at 1:44 PM
Thank you so much for sharing, François! I posted a thread with more details on my page — very glad to share this work and would be happy to discuss it!
We describe this beautiful mechanism in our preprint:
www.biorxiv.org/content/10.1...
Huge thanks to all co-authors — and especially to my advisor, Andrey Kulbachinskiy — for invaluable support and collaboration!!!
www.biorxiv.org/content/10.1...
Huge thanks to all co-authors — and especially to my advisor, Andrey Kulbachinskiy — for invaluable support and collaboration!!!
www.biorxiv.org
April 7, 2025 at 1:12 PM
We describe this beautiful mechanism in our preprint:
www.biorxiv.org/content/10.1...
Huge thanks to all co-authors — and especially to my advisor, Andrey Kulbachinskiy — for invaluable support and collaboration!!!
www.biorxiv.org/content/10.1...
Huge thanks to all co-authors — and especially to my advisor, Andrey Kulbachinskiy — for invaluable support and collaboration!!!
SPARHA represents a two-component defense system based on a suicidal cellular response, in which activation of the HNH effector by the pAgo sensor leads to filament formation, promoting efficient degradation of invading nucleic acids.
April 7, 2025 at 1:09 PM
SPARHA represents a two-component defense system based on a suicidal cellular response, in which activation of the HNH effector by the pAgo sensor leads to filament formation, promoting efficient degradation of invading nucleic acids.
We further show that activation of SPARHA by the interfering plasmid depends on the binding of guide RNAs derived from the plasmid origin of replication.
April 7, 2025 at 1:08 PM
We further show that activation of SPARHA by the interfering plasmid depends on the binding of guide RNAs derived from the plasmid origin of replication.
In cells, SPARHA is activated in the presence of invaders, cleaving cellular DNA and conferring protection to the bacterial population via an abortive infection mechanism.
April 7, 2025 at 1:08 PM
In cells, SPARHA is activated in the presence of invaders, cleaving cellular DNA and conferring protection to the bacterial population via an abortive infection mechanism.
Target DNA recognition induces conformational changes of SPARHA, freeing the HNH domains and promoting their dimerization. Subsequent association of HNH dimers leads to formation of right-handed HNH-pAgo filaments containing dimeric active sites capable of double-stranded DNA cleavage.
April 7, 2025 at 1:07 PM
Target DNA recognition induces conformational changes of SPARHA, freeing the HNH domains and promoting their dimerization. Subsequent association of HNH dimers leads to formation of right-handed HNH-pAgo filaments containing dimeric active sites capable of double-stranded DNA cleavage.
Unlike the DREN domain of SPARDA systems, the HNH nuclease of SPARDA is highly active in the absence of short pAgo but is kept in a silent state by pAgo until target recognition. Using SEC, TEM, AF3 modeling, and site-directed mutagenesis, we were able to reveal the activation mechanism of SPARHA.
April 7, 2025 at 1:06 PM
Unlike the DREN domain of SPARDA systems, the HNH nuclease of SPARDA is highly active in the absence of short pAgo but is kept in a silent state by pAgo until target recognition. Using SEC, TEM, AF3 modeling, and site-directed mutagenesis, we were able to reveal the activation mechanism of SPARHA.
Now, we present SPARHA, a new defense system from a distinct clade of short pAgos associated with predicted HNH nuclease effectors. SPARHA is activated after guide RNAs binding and target DNA recognition, leading to cleavage of dsDNA substrates.
April 7, 2025 at 1:05 PM
Now, we present SPARHA, a new defense system from a distinct clade of short pAgos associated with predicted HNH nuclease effectors. SPARHA is activated after guide RNAs binding and target DNA recognition, leading to cleavage of dsDNA substrates.
Previously, we characterized the SPARDA system: a complex of short pAgo and DREN nuclease, which cleaves DNA and RNA substrates upon target DNA recognition and is activated in the presence of plasmids or phages, inducing cell death or dormancy. www.nature.com/articles/s41...
DNA-targeting short Argonautes complex with effector proteins for collateral nuclease activity and bacterial population immunity - Nature Microbiology
DNA recognition by Argonaute proteins activates effector nucleases that trigger indiscriminate DNA and RNA cleavage and induce abortive infection.
www.nature.com
April 7, 2025 at 1:04 PM
Previously, we characterized the SPARDA system: a complex of short pAgo and DREN nuclease, which cleaves DNA and RNA substrates upon target DNA recognition and is activated in the presence of plasmids or phages, inducing cell death or dormancy. www.nature.com/articles/s41...
Congrats!!! Absolutely amazing!
January 31, 2025 at 11:59 PM
Congrats!!! Absolutely amazing!