Architecture of the Soluble Receptor Aer2 Indicates an In-Line Mechanism for PAS and HAMP Domain Signaling

Airola, Michael V.; Huh, Doowon; Sukomon, Nattakan; Widom, Joanne; Sircar, Ria; Borbat, Peter P.; Freed, Jack H.; Watts, Kylie J.; Crane, Brian R.

doi:10.1016/j.jmb.2012.12.011

Cited by 45 publications

(84 citation statements)

References 57 publications

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“…3). Many of these contain sensory and signal-transducing domains that have been thoroughly studied in the context of bacterial two-component signal transduction systems (53,54). This connection suggests that DUF835 proteins are involved in signal transduction pathways.…”

Section: Resultsmentioning

confidence: 99%

Proposed Role for KaiC-Like ATPases as Major Signal Transduction Hubs in Archaea

Makarova

Galperin

Koonin

2017

mBio

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All organisms must adapt to ever-changing environmental conditions and accordingly have evolved diverse signal transduction systems. In bacteria, the most abundant networks are built around the two-component signal transduction systems that include histidine kinases and receiver domains. In contrast, eukaryotic signal transduction is dominated by serine/threonine/tyrosine protein kinases. Both of these systems are also found in archaea, but they are not as common and diversified as their bacterial and eukaryotic counterparts, suggesting the possibility that archaea have evolved other, still uncharacterized signal transduction networks. Here we propose a role for KaiC family ATPases, known to be key components of the circadian clock in cyanobacteria, in archaeal signal transduction. The KaiC family is notably expanded in most archaeal genomes, and although most of these ATPases remain poorly characterized, members of the KaiC family have been shown to control archaellum assembly and have been found to be a stable component of the gas vesicle system in Halobacteria. Computational analyses described here suggest that KaiC-like ATPases and their homologues with inactivated ATPase domains are involved in many other archaeal signal transduction pathways and comprise major hubs of complex regulatory networks. We predict numerous input and output domains that are linked to KaiC-like proteins, including putative homologues of eukaryotic DEATH domains that could function as adapters in archaeal signaling networks. We further address the relationships of the archaeal family of KaiC homologues to the bona fide KaiC of cyanobacteria and implications for the existence of a KaiCbased circadian clock apparatus in archaea.IMPORTANCE Little is currently known about signal transduction pathways in Archaea. Recent studies indicate that KaiC-like ATPases, known as key components of the circadian clock apparatus in cyanobacteria, are involved in the regulation of archaellum assembly and, likely, type IV pili and the gas vesicle system in Archaea. We performed comprehensive comparative genomic analyses of the KaiC family. A vast protein interaction network was revealed, with KaiC family proteins as hubs for numerous input and output components, many of which are shared with twocomponent signal transduction systems. Putative KaiC-based signal transduction systems are predicted to regulate the activities of membrane-associated complexes and individual proteins, such as signal recognition particle and membrane transporters, and also could be important for oxidative stress response regulation. KaiC-centered signal transduction networks are predicted to play major roles in archaeal physiology, and this work is expected to stimulate their experimental characterization.

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Section: Resultsmentioning

confidence: 99%

Proposed Role for KaiC-Like ATPases as Major Signal Transduction Hubs in Archaea

Makarova

Galperin

Koonin

2017

mBio

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“…The P. aeruginosa chemoreceptor, Aer-2, is the only other system where functioning of the poly-HAMP module has been studied. In Aer-2, the PAS-sensing domain appeared to regulate the alternative HAMP structure of the successive C-terminal HAMP domains through an in-line mechanism (40). In the case of DhNik1p, the absence of any input sensor domain made the system more interesting and intriguing.…”

Section: Discussionmentioning

confidence: 99%

Differential Role of HAMP-like Linkers in Regulating the Functionality of the Group III Histidine Kinase DhNik1p

Kaur

Singh

Rathore

et al. 2014

Journal of Biological Chemistry

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“…1c) (14). The heme itself appears to shift ϳ2.0 Å upon ligand binding, and the heme pocket adjusts accordingly (14).…”

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confidence: 97%

“…In the absence of ligand, the I␤ Trp residue W283 appears to rotate ϳ90°, and an adjacent Leu residue, L264 on H␤, contracts toward the heme iron center to occupy the position where CN Ϫ was bound ( Fig. 1c) (14). The heme itself appears to shift ϳ2.0 Å upon ligand binding, and the heme pocket adjusts accordingly (14).…”

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confidence: 99%

“…There are currently two structures for the Aer2 PAS domain: one contains cyanide bound to ferric heme (cyanomet, or Fe 3ϩ -CN; PDB entry 3VOL) (13) (Fig. 1b), and the other contains unliganded ferric heme (Fe 3ϩ ; PDB entry 4HI4) (14). These structures revealed several unusual PAS features, including an extended C␣/D␣ helix, a short 3 10 helix, called E (that replaces E␣), heme coordination via a His residue on E, and potential O 2 stabilization via the indole group of a Trp residue on I␤ (Fig.…”

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Gas Sensing and Signaling in the PAS-Heme Domain of the Pseudomonas aeruginosa Aer2 Receptor

et al. 2017

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The Aer2 chemoreceptor from Pseudomonas aeruginosa contains a PAS sensing domain that coordinates b-type heme and signals in response to the binding of O 2 , CO, or NO. PAS-heme structures suggest that Aer2 uniquely coordinates heme via a His residue on a 3 10 helix (H234 on E), stabilizes O 2 binding via a Trp residue (W283), and signals via both W283 and an adjacent Leu residue (L264). Ligand binding may displace L264 and reorient W283 for hydrogen bonding to the ligand. Here, we clarified the mechanisms by which Aer2-PAS binds heme, regulates ligand binding, and initiates conformational signaling. H234 coordinated heme, but additional hydrophobic residues in the heme cleft were also critical for stable heme binding. O 2 appeared to be the native Aer2 ligand (dissociation constant [K d ] of 16 M). With one exception, mutants that bound O 2 could signal, whereas many mutants that bound CO could not. W283 stabilized O 2 binding but not CO binding, and it was required for signal initiation; W283 mutants that could not stabilize O 2 were rapidly oxidized to Fe(III). W283F was the only Trp mutant that bound O 2 with wildtype affinity. The size and nature of residue 264 was important for gas binding and signaling: L264W blocked O 2 binding, L264A and L264G caused O 2 -mediated oxidation, and L264K formed a hexacoordinate heme. Our data suggest that when O 2 binds to Aer2, L264 moves concomitantly with W283 to initiate the conformational signal. The signal then propagates from the PAS domain to regulate the C-terminal HAMP and kinase control domains, ultimately modulating a cellular response.IMPORTANCE Pseudomonas aeruginosa is a ubiquitous environmental bacterium and opportunistic pathogen that infects multiple body sites, including the lungs of cystic fibrosis patients. P. aeruginosa senses and responds to its environment via four chemosensory systems. Three of these systems regulate biofilm formation, twitching motility, and chemotaxis. The role of the fourth system, Che2, is unclear but has been implicated in virulence. The Che2 system contains a chemoreceptor called Aer2, which contains a PAS sensing domain that binds heme and senses oxygen. Here, we show that Aer2 uses unprecedented mechanisms to bind O 2 and initiate signaling. These studies provide both the first functional corroboration of the Aer2-PAS signaling mechanism previously proposed from structure as well as a signaling model for Aer2-PAS receptors.KEYWORDS chemoreceptor, PAS domain, signal transduction, Pseudomonas aeruginosa, heme, oxygen P seudomonas aeruginosa is a common environmental bacterium and a significant cause of opportunistic human disease. It survives in complex environments with the aid of 26 chemoreceptors and four chemosensory systems that collectively sense environmental conditions and modify bacterial behavior. The roles of three of these chemosensory systems are known: one modulates type IV pili production and twitching motility (Pil-Chp system), another controls biofilm formation (Wsp system), and a third

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Architecture of the Soluble Receptor Aer2 Indicates an In-Line Mechanism for PAS and HAMP Domain Signaling

Cited by 45 publications

References 57 publications

Proposed Role for KaiC-Like ATPases as Major Signal Transduction Hubs in Archaea

Proposed Role for KaiC-Like ATPases as Major Signal Transduction Hubs in Archaea

Differential Role of HAMP-like Linkers in Regulating the Functionality of the Group III Histidine Kinase DhNik1p

Gas Sensing and Signaling in the PAS-Heme Domain of the Pseudomonas aeruginosa Aer2 Receptor

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