Amine-recognizing domain in diverse receptors from bacteria and archaea evolved from the universal amino acid sensor

Bacteria possess various receptors that sense different signals and transmit information to enable an optimal adaptation to the environment. A major limitation in microbiology is the lack of information on the signal molecules that activate receptors. Signals recognized by sensor domains are poorly...

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Veröffentlicht in:	Proceedings of the National Academy of Sciences - PNAS 2023-10, Vol.120 (42), p.e2305837120-e2305837120
Hauptverfasser:	Cerna-Vargas, Jean Paul, Gumerov, Vadim M, Krell, Tino, Zhulin, Igor B
Format:	Artikel
Sprache:	eng
Schlagworte:	Aerobic microorganisms Amines Amino acid sequence Amino acids Amino Acids - metabolism Anaerobic microorganisms Archaea Archaea - genetics Archaea - metabolism Bacteria Bacteria - genetics Bacteria - metabolism Bacterial Proteins - metabolism Binding Biogenic amines Biogenic Amines - metabolism Biological Sciences Chemoreception Chemoreceptors Evolution Histidine Homeostasis Humans Kinases Microbiology Microorganisms Osmoprotectants Prokaryotes Receptors Sensors Substrates
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creator	Cerna-Vargas, Jean Paul Gumerov, Vadim M Krell, Tino Zhulin, Igor B
description	Bacteria possess various receptors that sense different signals and transmit information to enable an optimal adaptation to the environment. A major limitation in microbiology is the lack of information on the signal molecules that activate receptors. Signals recognized by sensor domains are poorly reflected in overall sequence identity, and therefore, the identification of signals from the amino acid sequence of the sensor alone presents a challenge. Biogenic amines are of great physiological importance for microorganisms and humans. They serve as substrates for aerobic and anaerobic growth and play a role of neurotransmitters and osmoprotectants. Here, we report the identification of a sequence motif that is specific for amine-sensing sensor domains that belong to the Cache superfamily of the most abundant extracellular sensors in prokaryotes. We identified approximately 13,000 sensor histidine kinases, chemoreceptors, receptors involved in second messenger homeostasis and Ser/Thr phosphatases from 8,000 bacterial and archaeal species that contain the amine-recognizing motif. The screening of compound libraries and microcalorimetric titrations of selected sensor domains confirmed their ability to specifically bind biogenic amines. Mutants in the amine-binding motif or domains that contain a single mismatch in the binding motif had either no or a largely reduced affinity for amines. We demonstrate that the amine-recognizing domain originated from the universal amino acid-sensing Cache domain, thus providing insight into receptor evolution. Our approach enables precise "wet"-lab experiments to define the function of regulatory systems and therefore holds a strong promise to enable the identification of signals stimulating numerous receptors.
doi_str_mv	10.1073/pnas.2305837120
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The screening of compound libraries and microcalorimetric titrations of selected sensor domains confirmed their ability to specifically bind biogenic amines. Mutants in the amine-binding motif or domains that contain a single mismatch in the binding motif had either no or a largely reduced affinity for amines. We demonstrate that the amine-recognizing domain originated from the universal amino acid-sensing Cache domain, thus providing insight into receptor evolution. 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The screening of compound libraries and microcalorimetric titrations of selected sensor domains confirmed their ability to specifically bind biogenic amines. Mutants in the amine-binding motif or domains that contain a single mismatch in the binding motif had either no or a largely reduced affinity for amines. We demonstrate that the amine-recognizing domain originated from the universal amino acid-sensing Cache domain, thus providing insight into receptor evolution. 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The screening of compound libraries and microcalorimetric titrations of selected sensor domains confirmed their ability to specifically bind biogenic amines. Mutants in the amine-binding motif or domains that contain a single mismatch in the binding motif had either no or a largely reduced affinity for amines. We demonstrate that the amine-recognizing domain originated from the universal amino acid-sensing Cache domain, thus providing insight into receptor evolution. 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subjects	Aerobic microorganisms Amines Amino acid sequence Amino acids Amino Acids - metabolism Anaerobic microorganisms Archaea Archaea - genetics Archaea - metabolism Bacteria Bacteria - genetics Bacteria - metabolism Bacterial Proteins - metabolism Binding Biogenic amines Biogenic Amines - metabolism Biological Sciences Chemoreception Chemoreceptors Evolution Histidine Homeostasis Humans Kinases Microbiology Microorganisms Osmoprotectants Prokaryotes Receptors Sensors Substrates
title	Amine-recognizing domain in diverse receptors from bacteria and archaea evolved from the universal amino acid sensor
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