Senén D. Mendoza scite author profile

All viruses require strategies to inhibit or evade the immunity pathways of cells they infect. The viruses that infect bacteria, bacteriophages (phages), must avoid nucleic-acid targeting immune pathways such as CRISPR-Cas (clustered regularly interspaced short palindromic repeats and CRISPR-associated genes) and restriction-modification (R-M) systems to replicate efficiently 1 . Here, we show that jumbo phage ΦKZ, infecting Pseudomonas aeruginosa, segregates its DNA from immunity nucleases by constructing a proteinaceous nucleus-like compartment. ΦKZ resists many DNA-targeting immune systems in vivo, including two CRISPR-Cas3 subtypes, Cas9, Cas12a, and the restriction enzymes HsdRMS and EcoRI. Cas and restriction enzymes are unable to access the phage DNA throughout the infection, but engineered re-localization of EcoRI inside the compartment enables phage targeting and cell protection. Moreover, ΦKZ is sensitive to the RNA targeting CRISPR-Cas enzyme, Cas13a, likely due to phage mRNA localizing to the cytoplasm. Collectively, we propose that Pseudomonas jumbo phages evade a broad spectrum of DNA-targeting nucleases through the assembly of a protein barrier around their genome.

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Bacteriophage genome engineering with CRISPR–Cas13a

Guan

Oromí-Bosch²,

Mendoza

et al. 2022

Nat Microbiol

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RNA targeting with CRISPR-Cas13a facilitates bacteriophage genome engineering

Guan

Bosch²,

Mendoza

et al. 2022

Preprint

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The viruses that infect bacteria, bacteriophages (or phages), possess numerous genes of unknown function. Genetic tools are required to understand their biology and enhance their efficacy as antimicrobials. Pseudomonas aeruginosa jumbo phage ΦKZ and its relatives are a broad host range phage family that assemble a proteinaceous “phage nucleus” structure during infection. Due to the phage nucleus, DNA-targeting CRISPR-Cas is ineffective against this phage and thus there are currently no reverse genetic tools for this family. Here, we develop a DNA phage genome editing technology using the RNA-targeting CRISPR-Cas13a enzyme as a selection tool, an anti-CRISPR gene (acrVIA1) as a selectable marker, and homologous recombination. Precise insertion of foreign genes, gene deletions, and the addition of chromosomal fluorescent tags into the ΦKZ genome were achieved. Deletion of phuZ, which encodes a tubulin-like protein that centers the phage nucleus during infection, led to the mispositioning of the phage nucleus but surprisingly had no impact on phage replication, despite a proposed role in capsid trafficking. A chromosomal fluorescent tag placed on gp93, a proposed “inner body” protein in the phage head revealed a protein that is injected with the phage genome, localizes with the maturing phage nucleus, and is massively synthesized around the phage nucleus late in infection. Successful editing of two other phages that resist DNA-targeting CRISPR-Cas systems [OMKO1 (ΦKZ-like) and PaMx41] demonstrates the flexibility of this method. RNA-targeting Cas13a system holds great promise for becoming a universal genetic editing tool for intractable phages. This phage genetic engineering platform enables the systematic study of phage genes of unknown function and the precise modification of phages for use in a variety of applications.

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Structural toggle in the RNaseH domain of Prp8 helps balance splicing fidelity and catalytic efficiency

Mayerle

Raghavan

Ledoux

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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Pre-mRNA splicing is an essential step of eukaryotic gene expression that requires both high efficiency and high fidelity. Prp8 has long been considered the "master regulator" of the spliceosome, the molecular machine that executes pre-mRNA splicing. Cross-linking and structural studies place the RNaseH domain (RH) of Prp8 near the spliceosome's catalytic core and demonstrate that alleles that map to a 17-aa extension in RH stabilize it in one of two mutually exclusive structures, the biological relevance of which are unknown. We performed an extensive characterization of alleles that map to this extension and, using in vitro and in vivo reporter assays, show they fall into two functional classes associated with the two structures: those that promote error-prone/efficient splicing and those that promote hyperaccurate/inefficient splicing. Identification of global locations of endogenous splice-site activation by lariat sequencing confirms the fidelity effects seen in our reporter assays. Furthermore, we show that error-prone/efficient RH alleles suppress a mutant deficient at promoting the first catalytic step of splicing, whereas hyperaccurate/inefficient RH alleles exhibit synthetic sickness. Together our data indicate that RH alleles link splicing fidelity with catalytic efficiency by biasing the relative stabilities of distinct spliceosome conformations. We hypothesize that the spliceosome "toggles" between such error-prone/efficient and hyperaccurate/inefficient conformations during the splicing cycle to regulate splicing fidelity.

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Senén D. Mendoza

A bacteriophage nucleus-like compartment shields DNA from CRISPR nucleases

Bacteriophage genome engineering with CRISPR–Cas13a

RNA targeting with CRISPR-Cas13a facilitates bacteriophage genome engineering

Structural toggle in the RNaseH domain of Prp8 helps balance splicing fidelity and catalytic efficiency

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