TIR domains produce histidine-ADPR as an immune signal in bacteria

Dziugas Sabonis; Carmel Avraham; Renee B. Chang; Allen Lu; Ehud Herbst; Arunas Silanskas; Deividas Vilutis; Azita Leavitt; Erez Yirmiya; Hunter C. Toyoda; Audrone Ruksenaite; Mindaugas Zaremba; Ilya Osterman; Gil Amitai; Philip J. Kranzusch; Rotem Sorek; Giedre Tamulaitiene

doi:10.1038/s41586-025-08930-2

TIR domains produce histidine-ADPR as an immune signal in bacteria

Dziugas Sabonis, Carmel Avraham, Renee B. Chang, Allen Lu, Ehud Herbst, Arunas Silanskas, Deividas Vilutis, Azita Leavitt, Erez Yirmiya, Hunter C. Toyoda, Audrone Ruksenaite, Mindaugas Zaremba, Ilya Osterman, Gil Amitai, Philip J. Kranzusch, Rotem Sorek, Giedre Tamulaitiene

Department of Molecular Genetics

Weizmann Institute of Science

Research output: Contribution to journal › Article › peer-review

Abstract

Toll/interleukin-1 receptor (TIR) domains are central components of pattern recognition immune proteins across all domains of life^1,2. In bacteria and plants, TIR-domain proteins recognize pathogen invasion and then produce immune signalling molecules exclusively comprising nucleotide moieties^{2, 3, 4–5}. Here we show that the TIR-domain protein of the type II Thoeris defence system in bacteria produces a unique signalling molecule comprising the amino acid histidine conjugated to ADP-ribose (His-ADPR). His-ADPR is generated in response to phage infection and activates the cognate Thoeris effector by binding a Macro domain located at the C terminus of the effector protein. By determining the crystal structure of a ligand-bound Macro domain, we describe the structural basis for His-ADPR and its recognition and show its role by biochemical and mutational analyses. Our analyses furthermore reveal a family of phage proteins that bind and sequester His-ADPR signalling molecules, enabling phages to evade TIR-mediated immunity. These data demonstrate diversity in bacterial TIR signalling and reveal a new class of TIR-derived immune signalling molecules that combine nucleotide and amino acid moieties.

Original language	English
Pages (from-to)	467-473
Number of pages	7
Journal	Nature
Volume	642
Issue number	8067
DOIs	https://doi.org/10.1038/s41586-025-08930-2
State	Published - 30 Apr 2025

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10.1038/s41586-025-08930-2

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Sabonis, D., Avraham, C., Chang, R. B., Lu, A., Herbst, E., Silanskas, A., Vilutis, D., Leavitt, A., Yirmiya, E., Toyoda, H. C., Ruksenaite, A., Zaremba, M., Osterman, I., Amitai, G., Kranzusch, P. J., Sorek, R., & Tamulaitiene, G. (2025). TIR domains produce histidine-ADPR as an immune signal in bacteria. Nature, 642(8067), 467-473. https://doi.org/10.1038/s41586-025-08930-2

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title = "TIR domains produce histidine-ADPR as an immune signal in bacteria",

abstract = "Toll/interleukin-1 receptor (TIR) domains are central components of pattern recognition immune proteins across all domains of life1,2. In bacteria and plants, TIR-domain proteins recognize pathogen invasion and then produce immune signalling molecules exclusively comprising nucleotide moieties2, 3, 4–5. Here we show that the TIR-domain protein of the type II Thoeris defence system in bacteria produces a unique signalling molecule comprising the amino acid histidine conjugated to ADP-ribose (His-ADPR). His-ADPR is generated in response to phage infection and activates the cognate Thoeris effector by binding a Macro domain located at the C terminus of the effector protein. By determining the crystal structure of a ligand-bound Macro domain, we describe the structural basis for His-ADPR and its recognition and show its role by biochemical and mutational analyses. Our analyses furthermore reveal a family of phage proteins that bind and sequester His-ADPR signalling molecules, enabling phages to evade TIR-mediated immunity. These data demonstrate diversity in bacterial TIR signalling and reveal a new class of TIR-derived immune signalling molecules that combine nucleotide and amino acid moieties.",

author = "Dziugas Sabonis and Carmel Avraham and Chang, {Renee B.} and Allen Lu and Ehud Herbst and Arunas Silanskas and Deividas Vilutis and Azita Leavitt and Erez Yirmiya and Toyoda, {Hunter C.} and Audrone Ruksenaite and Mindaugas Zaremba and Ilya Osterman and Gil Amitai and Kranzusch, {Philip J.} and Rotem Sorek and Giedre Tamulaitiene",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive licence to Springer Nature Limited 2025.",

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day = "30",

doi = "10.1038/s41586-025-08930-2",

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T1 - TIR domains produce histidine-ADPR as an immune signal in bacteria

AU - Sabonis, Dziugas

AU - Avraham, Carmel

AU - Chang, Renee B.

AU - Lu, Allen

AU - Herbst, Ehud

AU - Silanskas, Arunas

AU - Vilutis, Deividas

AU - Leavitt, Azita

AU - Yirmiya, Erez

AU - Toyoda, Hunter C.

AU - Ruksenaite, Audrone

AU - Zaremba, Mindaugas

AU - Osterman, Ilya

AU - Amitai, Gil

AU - Kranzusch, Philip J.

AU - Sorek, Rotem

AU - Tamulaitiene, Giedre

PY - 2025/4/30

Y1 - 2025/4/30

N2 - Toll/interleukin-1 receptor (TIR) domains are central components of pattern recognition immune proteins across all domains of life1,2. In bacteria and plants, TIR-domain proteins recognize pathogen invasion and then produce immune signalling molecules exclusively comprising nucleotide moieties2, 3, 4–5. Here we show that the TIR-domain protein of the type II Thoeris defence system in bacteria produces a unique signalling molecule comprising the amino acid histidine conjugated to ADP-ribose (His-ADPR). His-ADPR is generated in response to phage infection and activates the cognate Thoeris effector by binding a Macro domain located at the C terminus of the effector protein. By determining the crystal structure of a ligand-bound Macro domain, we describe the structural basis for His-ADPR and its recognition and show its role by biochemical and mutational analyses. Our analyses furthermore reveal a family of phage proteins that bind and sequester His-ADPR signalling molecules, enabling phages to evade TIR-mediated immunity. These data demonstrate diversity in bacterial TIR signalling and reveal a new class of TIR-derived immune signalling molecules that combine nucleotide and amino acid moieties.

AB - Toll/interleukin-1 receptor (TIR) domains are central components of pattern recognition immune proteins across all domains of life1,2. In bacteria and plants, TIR-domain proteins recognize pathogen invasion and then produce immune signalling molecules exclusively comprising nucleotide moieties2, 3, 4–5. Here we show that the TIR-domain protein of the type II Thoeris defence system in bacteria produces a unique signalling molecule comprising the amino acid histidine conjugated to ADP-ribose (His-ADPR). His-ADPR is generated in response to phage infection and activates the cognate Thoeris effector by binding a Macro domain located at the C terminus of the effector protein. By determining the crystal structure of a ligand-bound Macro domain, we describe the structural basis for His-ADPR and its recognition and show its role by biochemical and mutational analyses. Our analyses furthermore reveal a family of phage proteins that bind and sequester His-ADPR signalling molecules, enabling phages to evade TIR-mediated immunity. These data demonstrate diversity in bacterial TIR signalling and reveal a new class of TIR-derived immune signalling molecules that combine nucleotide and amino acid moieties.

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U2 - 10.1038/s41586-025-08930-2

DO - 10.1038/s41586-025-08930-2

M3 - مقالة

SN - 0028-0836

VL - 642

SP - 467

EP - 473

JO - Nature

JF - Nature

IS - 8067

ER -

TIR domains produce histidine-ADPR as an immune signal in bacteria

Abstract

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