Literature DB >> 32325050

Listeria Phages Induce Cas9 Degradation to Protect Lysogenic Genomes.

Beatriz A Osuna1, Shweta Karambelkar1, Caroline Mahendra1, Kathleen A Christie2, Bianca Garcia3, Alan R Davidson4, Benjamin P Kleinstiver2, Samuel Kilcher5, Joseph Bondy-Denomy6.   

Abstract

Bacterial CRISPR-Cas systems employ RNA-guided nucleases to destroy phage (viral) DNA. Phages, in turn, have evolved diverse "anti-CRISPR" proteins (Acrs) to counteract acquired immunity. In Listeria monocytogenes, prophages encode two to three distinct anti-Cas9 proteins, with acrIIA1 always present. However, the significance of AcrIIA1's pervasiveness and its mechanism are unknown. Here, we report that AcrIIA1 binds with high affinity to Cas9 via the catalytic HNH domain. During lysogeny in Listeria, AcrIIA1 triggers Cas9 degradation. During lytic infection, however, AcrIIA1 fails to block Cas9 due to its multi-step inactivation mechanism. Thus, phages encode an additional Acr that rapidly binds and inactivates Cas9. AcrIIA1 also uniquely inhibits a highly diverged Cas9 found in Listeria (similar to SauCas9) and Type II-C Cas9s, likely due to Cas9 HNH domain conservation. In summary, Listeria phages inactivate Cas9 in lytic growth using variable, narrow-spectrum inhibitors, while the broad-spectrum AcrIIA1 stimulates Cas9 degradation for protection of the lysogenic genome.
Copyright © 2020 Elsevier Inc. All rights reserved.

Entities:  

Keywords:  CRISPR-Cas; Cas9; Listeria; anti-CRISPR; bacteriophage; lysogen; prophage

Mesh:

Year:  2020        PMID: 32325050      PMCID: PMC7351598          DOI: 10.1016/j.chom.2020.04.001

Source DB:  PubMed          Journal:  Cell Host Microbe        ISSN: 1931-3128            Impact factor:   21.023


  48 in total

1.  Phage AcrIIA2 DNA Mimicry: Structural Basis of the CRISPR and Anti-CRISPR Arms Race.

Authors:  Liang Liu; Maolu Yin; Min Wang; Yanli Wang
Journal:  Mol Cell       Date:  2018-12-31       Impact factor: 17.970

2.  Integration-proficient plasmids for Pseudomonas aeruginosa: site-specific integration and use for engineering of reporter and expression strains.

Authors:  T T Hoang; A J Kutchma; A Becher; H P Schweizer
Journal:  Plasmid       Date:  2000-01       Impact factor: 3.466

Review 3.  Diversity, classification and evolution of CRISPR-Cas systems.

Authors:  Eugene V Koonin; Kira S Makarova; Feng Zhang
Journal:  Curr Opin Microbiol       Date:  2017-06-09       Impact factor: 7.934

4.  Construction, characterization, and use of two Listeria monocytogenes site-specific phage integration vectors.

Authors:  Peter Lauer; Man Yin Nora Chow; Martin J Loessner; Daniel A Portnoy; Richard Calendar
Journal:  J Bacteriol       Date:  2002-08       Impact factor: 3.490

5.  Characterization and electrotransformation of Lactobacillus crispatus isolated from chicken crop and intestine.

Authors:  S S Beasley; T M Takala; J Reunanen; J Apajalahti; P E J Saris
Journal:  Poult Sci       Date:  2004-01       Impact factor: 3.352

Review 6.  An updated evolutionary classification of CRISPR-Cas systems.

Authors:  Kira S Makarova; Yuri I Wolf; Omer S Alkhnbashi; Fabrizio Costa; Shiraz A Shah; Sita J Saunders; Rodolphe Barrangou; Stan J J Brouns; Emmanuelle Charpentier; Daniel H Haft; Philippe Horvath; Sylvain Moineau; Francisco J M Mojica; Rebecca M Terns; Michael P Terns; Malcolm F White; Alexander F Yakunin; Roger A Garrett; John van der Oost; Rolf Backofen; Eugene V Koonin
Journal:  Nat Rev Microbiol       Date:  2015-09-28       Impact factor: 60.633

7.  A Broad-Spectrum Inhibitor of CRISPR-Cas9.

Authors:  Lucas B Harrington; Kevin W Doxzen; Enbo Ma; Jun-Jie Liu; Gavin J Knott; Alireza Edraki; Bianca Garcia; Nadia Amrani; Janice S Chen; Joshua C Cofsky; Philip J Kranzusch; Erik J Sontheimer; Alan R Davidson; Karen L Maxwell; Jennifer A Doudna
Journal:  Cell       Date:  2017-08-24       Impact factor: 41.582

8.  Computational design of anti-CRISPR proteins with improved inhibition potency.

Authors:  Jan Mathony; Zander Harteveld; Carolin Schmelas; Julius Upmeier Zu Belzen; Sabine Aschenbrenner; Wei Sun; Mareike D Hoffmann; Christina Stengl; Andreas Scheck; Sandrine Georgeon; Stéphane Rosset; Yanli Wang; Dirk Grimm; Roland Eils; Bruno E Correia; Dominik Niopek
Journal:  Nat Chem Biol       Date:  2020-04-13       Impact factor: 15.040

9.  Proteins and DNA elements essential for the CRISPR adaptation process in Escherichia coli.

Authors:  Ido Yosef; Moran G Goren; Udi Qimron
Journal:  Nucleic Acids Res       Date:  2012-03-08       Impact factor: 16.971

10.  Widespread anti-CRISPR proteins in virulent bacteriophages inhibit a range of Cas9 proteins.

Authors:  Alexander P Hynes; Geneviève M Rousseau; Daniel Agudelo; Adeline Goulet; Beatrice Amigues; Jeremy Loehr; Dennis A Romero; Christophe Fremaux; Philippe Horvath; Yannick Doyon; Christian Cambillau; Sylvain Moineau
Journal:  Nat Commun       Date:  2018-07-25       Impact factor: 14.919
View more
  22 in total

1.  Critical Anti-CRISPR Locus Repression by a Bi-functional Cas9 Inhibitor.

Authors:  Beatriz A Osuna; Shweta Karambelkar; Caroline Mahendra; Anne Sarbach; Matthew C Johnson; Samuel Kilcher; Joseph Bondy-Denomy
Journal:  Cell Host Microbe       Date:  2020-04-22       Impact factor: 21.023

Review 2.  Structure-based functional mechanisms and biotechnology applications of anti-CRISPR proteins.

Authors:  Ning Jia; Dinshaw J Patel
Journal:  Nat Rev Mol Cell Biol       Date:  2021-06-04       Impact factor: 94.444

Review 3.  Structures and Strategies of Anti-CRISPR-Mediated Immune Suppression.

Authors:  Tanner Wiegand; Shweta Karambelkar; Joseph Bondy-Denomy; Blake Wiedenheft
Journal:  Annu Rev Microbiol       Date:  2020-06-05       Impact factor: 15.500

Review 4.  Alternative functions of CRISPR-Cas systems in the evolutionary arms race.

Authors:  Prarthana Mohanraju; Chinmoy Saha; Peter van Baarlen; Rogier Louwen; Raymond H J Staals; John van der Oost
Journal:  Nat Rev Microbiol       Date:  2022-01-06       Impact factor: 60.633

5.  Discovery of potent and versatile CRISPR-Cas9 inhibitors engineered for chemically controllable genome editing.

Authors:  Guoxu Song; Fei Zhang; Chunhong Tian; Xing Gao; Xiaoxiao Zhu; Dongdong Fan; Yong Tian
Journal:  Nucleic Acids Res       Date:  2022-03-21       Impact factor: 16.971

6.  Prophage integration into CRISPR loci enables evasion of antiviral immunity in Streptococcus pyogenes.

Authors:  Andrew Varble; Edmondo Campisi; Chad W Euler; Pascal Maguin; Albina Kozlova; Jessica Fyodorova; Jakob T Rostøl; Vincent A Fischetti; Luciano A Marraffini
Journal:  Nat Microbiol       Date:  2021-11-24       Impact factor: 17.745

7.  The novel anti-CRISPR AcrIIA22 relieves DNA torsion in target plasmids and impairs SpyCas9 activity.

Authors:  Kevin J Forsberg; Danica T Schmidtke; Rachel Werther; Ruben V Uribe; Deanna Hausman; Morten O A Sommer; Barry L Stoddard; Brett K Kaiser; Harmit S Malik
Journal:  PLoS Biol       Date:  2021-10-13       Impact factor: 8.029

8.  Machine learning predicts new anti-CRISPR proteins.

Authors:  Simon Eitzinger; Amina Asif; Kyle E Watters; Anthony T Iavarone; Gavin J Knott; Jennifer A Doudna; Fayyaz Ul Amir Afsar Minhas
Journal:  Nucleic Acids Res       Date:  2020-05-21       Impact factor: 16.971

Review 9.  Type II anti-CRISPR proteins as a new tool for synthetic biology.

Authors:  Yadan Zhang; Mario Andrea Marchisio
Journal:  RNA Biol       Date:  2020-10-13       Impact factor: 4.652

Review 10.  Anti-CRISPRs go viral: The infection biology of CRISPR-Cas inhibitors.

Authors:  Yuping Li; Joseph Bondy-Denomy
Journal:  Cell Host Microbe       Date:  2021-01-13       Impact factor: 21.023
View more

北京卡尤迪生物科技股份有限公司 © 2022-2023.