Architecture and self-assembly of the jumbo bacteriophage nuclear shell

Laughlin, Thomas G.; Deep, Amar; Prichard, Amy; Seitz, Christian; Gu, Yajie; Enüstün, Eray; Suslov, Sergey; Khanna, K. N.; Birkholz, Erica A.; Armbruster, Emily; McCammon, J. Andrew; Amaro, Rommie E.; Pogliano, Joe; Corbett, K.D.; Villa, Elizabeth

doi:10.1101/2022.02.14.480162

Cited by 14 publications

(25 citation statements)

References 97 publications

(131 reference statements)

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“…Here we characterize Goslar infecting E. coli and demonstrate that this phage also has a complex replication cycle with both a nucleus-like compartment and a tubulin-based cytoskeleton that rotates it (Figure 7). Our findings regarding the Goslar phage nucleus are supported by our recent work showing that Goslar chimallin shares high structural homology with chimallin from other jumbo phages like 20142-1, and assembles into a flexible lattice that is the primary component of the Goslar nuclear shell (Laughlin et al, 2022). Surprisingly, Goslar PhuZ filaments assemble a vortex-like cytoskeletal structure in which filaments wrap around the entire phage nucleus and project radially toward the membrane (Figure 7).…”

Section: Discussionsupporting

confidence: 84%

A cytoskeletal vortex drives phage nucleus rotation during jumbo phage replication in E. coli

et al. 2022

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Section: Discussionsupporting

confidence: 84%

A cytoskeletal vortex drives phage nucleus rotation during jumbo phage replication in E. coli

et al. 2022

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“…Indeed, we previously reported that experimentally arrested infections left a stable DNA puncta at the pole, with no degradation of phage DNA by restriction enzymes 5 . This protective structure could be the “round compartments” 25 or “unidentified spherical bodies” 26 revealed by recent electron microscopy studies. The experiments reported here identified some of the likely IB protein components of this structure and uncovered a novel immune strategy that apparently destabilizes it, rendering the phage DNA susceptible to cytoplasmic nucleases.…”

Section: Discussionmentioning

confidence: 96%

A family of novel immune systems targets early infection of nucleus-forming jumbo phages

Guan

Hareendranath

et al. 2022

Preprint

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Jumbo bacteriophages of the ΦKZ-like family are characterized by large genomes (>200 kb) and the remarkable ability to assemble a proteinaceous nucleus-like structure. The nucleus protects the phage genome from canonical DNA-targeting immune systems, such as CRISPR-Cas and restriction-modification. We hypothesized that the failure of common bacterial defenses creates selective pressure for immune systems that target the unique jumbo phage biology. Here, we identify the "jumbo phage killer" (Juk) immune system that is deployed by a clinical isolate of Pseudomonas aeruginosa to resist ΦKZ. Juk immunity rescues the cell by preventing early phage transcription, DNA replication, and nucleus assembly. Phage infection is first sensed by JukA (formerly YaaW), which localizes rapidly to the site of phage infection at the cell pole, triggered by ejected phage factors. The effector protein JukB is recruited by JukA, which is required to enable immunity and the subsequent degradation of the phage DNA. JukA homologs are found in several bacterial phyla and are associated with numerous other putative effectors, many of which provided specific anti-ΦKZ activity when expressed in P. aeruginosa. Together, these data reveal a novel strategy for immunity whereby immune factors are recruited to the site of phage protein and DNA ejection to prevent phage progression and save the cell.

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“…A remarkable case of enzyme exaptation for a structural role in viruses are the major proteins of the nucleus-like shell formed by certain jumbo phages for protection of the virus DNA from cellular defense systems, such as restriction endonucleases and CRISPR-Cas (Guan and Bondy-Denomy, 2020). Structural comparisons showed that the major shell protein, chimallin, comprises two domains, the N-terminal domain with an α+β fold similar to that of an uncharacterized bacterial protein, and the C-terminal domain that is derived from a GCN5-related Nacetyltransferase most similar to E. coli AtaT and homologous to tRNA-acetylating toxins (Laughlin et al, 2022). Notably, as in many other cellular enzymes exapted by viruses, the acetyltransferase active site residues of chimallin are mutated, apparently abrogating the enzymatic activity.…”

Section: Exaptation Accompanied By Radical Functional Changementioning

confidence: 99%