Your search keyword '"Brouns, Stan J.J."' showing total 8 results

1. Bacterial homologs of innate eukaryotic antiviral defenses with anti-phage activity highlight shared evolutionary roots of viral defenses.

Author

van den Berg, Daan F., Costa, Ana Rita, Esser, Jelger Q., Stanciu, Ilinka, Geissler, Jasper Q., Zoumaro-Djayoon, Adja Damba, Haas, Pieter-Jan, and Brouns, Stan J.J.

Abstract

Prokaryotes have evolved a multitude of defense systems to protect against phage predation. Some of these resemble eukaryotic genes involved in antiviral responses. Here, we set out to systematically project the current knowledge of eukaryotic-like antiviral defense systems onto prokaryotic genomes, using Pseudomonas aeruginosa as a model organism. Searching for phage defense systems related to innate antiviral genes from vertebrates and plants, we uncovered over 450 candidates. We validated six of these phage defense systems, including factors preventing viral attachment, R-loop-acting enzymes, the inflammasome, ubiquitin pathway, and pathogen recognition signaling. Collectively, these defense systems support the concept of deep evolutionary links and shared antiviral mechanisms between prokaryotes and eukaryotes. [Display omitted] • Bacterial homologs of eukaryotic innate immunity genes examined in P. aeruginosa • Over 400 eukaryotic-like bacterial antiviral candidates were identified • Six eukaryotic-like phage defense systems validated to have strong anti-phage activity • Findings underscore the shared evolutionary roots of viral defenses across the domains Van den Berg et al. discover several bacterial homologs of eukaryotic antiviral defenses and demonstrate the anti-phage activity for six previously uncharacterized systems. These findings highlight the shared evolutionary roots and common mechanisms for viral defense across prokaryotes and eukaryotes. [ABSTRACT FROM AUTHOR]

Published

2024

2. RNAi: Prokaryotes Get in on the Act

Author

van der Oost, John and Brouns, Stan J.J.

Subjects

*PROKARYOTES, *ARCHAEBACTERIA, *BACTERIA, *IMMUNITY, *VIRUSES, *PLASMIDS, *RNA, *DNA

Abstract

The small CRISPR-derived RNAs of bacteria and archaea provide adaptive immunity by targeting the DNA of invading viruses and plasmids. now report on a new variant CRISPR/Cas complex in the archaeon Pyrococcus furiosus that uses guide RNAs to specifically target and cleave RNA not DNA. [ABSTRACT FROM AUTHOR]

Published

2009

3. Repetitive DNA Reeling by the Cascade-Cas3 Complex in Nucleotide Unwinding Steps.

Author

Loeff, Luuk, Brouns, Stan J.J., and Joo, Chirlmin

Subjects

*DNA, *NUCLEOTIDES, *FLUORESCENCE resonance energy transfer, *CRISPRS, *HELICASES

Abstract

Summary CRISPR-Cas provides RNA-guided adaptive immunity against invading genetic elements. Interference in type I systems relies on the RNA-guided Cascade complex for target DNA recognition and the Cas3 helicase/nuclease protein for target degradation. Even though the biochemistry of CRISPR interference has been largely covered, the biophysics of DNA unwinding and coupling of the helicase and nuclease domains of Cas3 remains elusive. Here, we employed single-molecule Förster resonance energy transfer (FRET) to probe the helicase activity with high spatiotemporal resolution. We show that Cas3 remains tightly associated with the target-bound Cascade complex while reeling the DNA using a spring-loaded mechanism. This spring-loaded reeling occurs in distinct bursts of 3 bp, which underlie three successive 1-nt unwinding events. Reeling is highly repetitive, allowing Cas3 to repeatedly present its inefficient nuclease domain with single-strand DNA (ssDNA) substrate. Our study reveals that the discontinuous helicase properties of Cas3 and its tight interaction with Cascade ensure controlled degradation of target DNA only. [ABSTRACT FROM AUTHOR]

Published

2018

4. Cas3-Derived Target DNA Degradation Fragments Fuel Primed CRISPR Adaptation.

Author

Künne, Tim, Kieper, Sebastian N., Bannenberg, Jasper W., Vogel, Anne I.M., Miellet, Willem R., Klein, Misha, Depken, Martin, Suarez-Diez, Maria, and Brouns, Stan J.J.

Subjects

*CRISPRS, *GENE targeting, *IMMUNOLOGIC memory, *PROKARYOTES, *VIRAL mutation, *DNA damage

Abstract

Summary Prokaryotes use a mechanism called priming to update their CRISPR immunological memory to rapidly counter revisiting, mutated viruses, and plasmids. Here we have determined how new spacers are produced and selected for integration into the CRISPR array during priming. We show that Cas3 couples CRISPR interference to adaptation by producing DNA breakdown products that fuel the spacer integration process in a two-step, PAM-associated manner. The helicase-nuclease Cas3 pre-processes target DNA into fragments of about 30–100 nt enriched for thymine-stretches in their 3′ ends. The Cas1-2 complex further processes these fragments and integrates them sequence-specifically into CRISPR repeats by coupling of a 3′ cytosine of the fragment. Our results highlight that the selection of PAM-compliant spacers during priming is enhanced by the combined sequence specificities of Cas3 and the Cas1-2 complex, leading to an increased propensity of integrating functional CTT-containing spacers. [ABSTRACT FROM AUTHOR]

Published

2016

5. Two Distinct DNA Binding Modes Guide Dual Roles of a CRISPR-Cas Protein Complex.

Author

Blosser, Timothy R., Loeff, Luuk, Westra, Edze R., Vlot, Marnix, Künne, Tim, Sobota, Małgorzata, Dekker, Cees, Brouns, Stan J.J., and Joo, Chirlmin

Subjects

*DNA-binding proteins, *PROKARYOTES, *GENETIC mutation, *NUCLEOTIDE sequence, *ESCHERICHIA coli

Abstract

Summary Small RNA-guided protein complexes play an essential role in CRISPR-mediated immunity in prokaryotes. While these complexes initiate interference by flagging cognate invader DNA for destruction, recent evidence has implicated their involvement in new CRISPR memory formation, called priming, against mutated invader sequences. The mechanism by which the target recognition complex mediates these disparate responses—interference and priming—remains poorly understood. Using single-molecule FRET, we visualize how bona fide and mutated targets are differentially probed by E. coli Cascade. We observe that the recognition of bona fide targets is an ordered process that is tightly controlled for high fidelity. Mutated targets are recognized with low fidelity, which is featured by short-lived and PAM- and seed-independent binding by any segment of the crRNA. These dual roles of Cascade in immunity with distinct fidelities underpin CRISPR-Cas robustness, allowing for efficient degradation of bona fide targets and priming of mutated DNA targets. [ABSTRACT FROM AUTHOR]

Published

2015

6. Short prokaryotic Argonaute systems trigger cell death upon detection of invading DNA.

Author

Koopal, Balwina, Potocnik, Ana, Mutte, Sumanth K., Aparicio-Maldonado, Cristian, Lindhoud, Simon, Vervoort, Jacques J.M., Brouns, Stan J.J., and Swarts, Daan C.

Subjects

*ARGONAUTE proteins, *CELL death, *SINGLE-stranded DNA, *DNA, *NUCLEIC acids, *NAD (Coenzyme)

Abstract

Argonaute proteins use single-stranded RNA or DNA guides to target complementary nucleic acids. This allows eukaryotic Argonaute proteins to mediate RNA interference and long prokaryotic Argonaute proteins to interfere with invading nucleic acids. The function and mechanisms of the phylogenetically distinct short prokaryotic Argonaute proteins remain poorly understood. We demonstrate that short prokaryotic Argonaute and the associated TIR-APAZ (SPARTA) proteins form heterodimeric complexes. Upon guide RNA-mediated target DNA binding, four SPARTA heterodimers form oligomers in which TIR domain-mediated NAD(P)ase activity is unleashed. When expressed in Escherichia coli , SPARTA is activated in the presence of highly transcribed multicopy plasmid DNA, which causes cell death through NAD(P)+ depletion. This results in the removal of plasmid-invaded cells from bacterial cultures. Furthermore, we show that SPARTA can be repurposed for the programmable detection of DNA sequences. In conclusion, our work identifies SPARTA as a prokaryotic immune system that reduces cell viability upon RNA-guided detection of invading DNA. [Display omitted] • Short prokaryotic Argonaute and TIR-APAZ proteins form a heterodimeric SPARTA complex • RNA-guided ssDNA target binding unleashes TIR domain-mediated NAD(P)ase activity • Highly transcribed multicopy invading DNAs activate SPARTA, which triggers cell death • SPARTA can be repurposed for sequence-specific NA detection Upon RNA-guided detection of invading DNA, short prokaryotic Argonaute and the associated proteins trigger NAD(P)+ depletion, leading to the removal of invaded cells from bacterial cultures. [ABSTRACT FROM AUTHOR]

Published

2022

7. CRISPR Immunity Relies on the Consecutive Binding and Degradation of Negatively Supercoiled Invader DNA by Cascade and Cas3

Author

Westra, Edze R., van Erp, Paul B.G., Künne, Tim, Wong, Shi Pey, Staals, Raymond H.J., Seegers, Christel L.C., Bollen, Sander, Jore, Matthijs M., Semenova, Ekaterina, Severinov, Konstantin, de Vos, Willem M., Dame, Remus T., de Vries, Renko, Brouns, Stan J.J., and van der Oost, John

Subjects

*PROKARYOTE physiology, *BACTERIAL loci, *BACTERIAL genetics, *ESCHERICHIA coli, *NUCLEOPROTEINS, *DNA denaturation, *NON-coding RNA, *NUCLEOTIDE sequence

Abstract

Summary: The prokaryotic CRISPR/Cas immune system is based on genomic loci that contain incorporated sequence tags from viruses and plasmids. Using small guide RNA molecules, these sequences act as a memory to reject returning invaders. Both the Cascade ribonucleoprotein complex and the Cas3 nuclease/helicase are required for CRISPR interference in Escherichia coli, but it is unknown how natural target DNA molecules are recognized and neutralized by their combined action. Here we show that Cascade efficiently locates target sequences in negatively supercoiled DNA, but only if these are flanked by a protospacer-adjacent motif (PAM). PAM recognition by Cascade exclusively involves the crRNA-complementary DNA strand. After Cascade-mediated R loop formation, the Cse1 subunit recruits Cas3, which catalyzes nicking of target DNA through its HD-nuclease domain. The target is then progressively unwound and cleaved by the joint ATP-dependent helicase activity and Mg2+-dependent HD-nuclease activity of Cas3, leading to complete target DNA degradation and invader neutralization. [ABSTRACT FROM AUTHOR]

Published

2012

8. Direct Visualization of Native CRISPR Target Search in Live Bacteria Reveals Cascade DNA Surveillance Mechanism.

Author

Vink, Jochem N.A., Martens, Koen J.A., Vlot, Marnix, McKenzie, Rebecca E., Almendros, Cristóbal, Estrada Bonilla, Boris, Brocken, Daan J.W., Hohlbein, Johannes, and Brouns, Stan J.J.

Subjects

*DNA, *MOBILE genetic elements, *DNA probes, *ARMS race, *VISUALIZATION

Abstract

CRISPR-Cas systems encode RNA-guided surveillance complexes to find and cleave invading DNA elements. While it is thought that invaders are neutralized minutes after cell entry, the mechanism and kinetics of target search and its impact on CRISPR protection levels have remained unknown. Here, we visualize individual Cascade complexes in a native type I CRISPR-Cas system. We uncover an exponential relation between Cascade copy number and CRISPR interference levels, pointing to a time-driven arms race between invader replication and target search, in which 20 Cascade complexes provide 50% protection. Driven by PAM-interacting subunit Cas8e, Cascade spends half its search time rapidly probing DNA (∼30 ms) in the nucleoid. We further demonstrate that target DNA transcription and CRISPR arrays affect the integrity of Cascade and affect CRISPR interference. Our work establishes the mechanism of cellular DNA surveillance by Cascade that allows the timely detection of invading DNA in a crowded, DNA-packed environment. • 20 Cascade complexes are required to provide 50% protection • Cascade spends equal time probing DNA (∼30 ms) and diffusing to a next site • Cas8e dynamically associates with Cascade in cells • CRISPR target search and invader replication compete in a kinetic "arms race" Vink et al. tracked single CRISPR RNA-surveillance complexes (Cascade) in the native host cell and determined the influence of Cascade copy numbers, PAM scanning speed, and the presence of CRISPR arrays and transcription on their ability to find and clear invading mobile genetic elements from the cell. [ABSTRACT FROM AUTHOR]

Published

2020