Single Phage Proteins Sequester TIR- and CGAS-generated Signaling Molecules

Overview

Journal bioRxiv

Date 2023 Nov 28

PMID 38014003

Authors

Dong Li

Yu Xiao

Weijia Xiong

Iana Fedorova

Yu Wang

Xi Liu

Erin Huiting

Jie Ren

Zirui Gao

Xingyu Zhao

Xueli Cao

Yi Zhang

Joseph Bondy-Denomy

Yue Feng

Affiliations

Soon will be listed here.

Abstract

Prokaryotic anti-phage immune systems use TIR (toll/interleukin-1 receptor) and cGAS (cyclic GMP-AMP synthase) enzymes to produce 1"-3'/1"-2' glycocyclic ADPR (gcADPR) and cyclid di-/trinucleotides (CDNs and CTNs) signaling molecules that limit phage replication, respectively . However, how phages neutralize these common systems is largely unknown. Here, we show that Thoeris anti-defense proteins Tad1 and Tad2 both have anti-CBASS activity by simultaneously sequestering CBASS cyclic oligonucleotides. Strikingly, apart from binding Thoeris signals 1"-3' and 1"-2' gcADPR, Tad1 also binds numerous CBASS CDNs/CTNs with high affinity, inhibiting CBASS systems using these molecules and . The hexameric Tad1 has six binding sites for CDNs or gcADPR, which are independent from two high affinity binding sites for CTNs. Tad2 also sequesters various CDNs in addition to gcADPR molecules, inhibiting CBASS systems using these CDNs. However, the binding pockets for CDNs and gcADPR are different in Tad2, whereby a tetramer can bind two CDNs and two gcADPR molecules simultaneously. Taken together, Tad1 and Tad2 are both two-pronged inhibitors that, alongside anti-CBASS protein 2, establish a paradigm of phage proteins that flexibly sequester a remarkable breadth of cyclic nucleotides involved in TIR- and cGAS-based anti-phage immunity.

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