Signal transduction and oligomerization – the role of a phototransducer signaling domain

The signal transduction pathway of halophilic archaea remains a fascinating example of adaptation to extreme environments. Despite similarities with bacterial taxis systems, its structural and dynamics patterns during signal relay remain debatable. The currently investigated SRII/HtrII phototaxis system of Natronomonas pharaonis shows remarkable similarities with chemoreceptors in its membrane and HAMP domains functioning design. By combining site-directed spin labeling (SDSL) with electron paramagnetic resonance (EPR) spectroscopy we investigate the kinase control domain (i.e. signaling domain) of NpSRII/HtrII both in terms of dynamic and structural properties. Our data, as provided by continuous wave and pulse (DEER) EPR techniques, builds on current dynamics based signaling models for HAMP domains (such as the “frozen–dynamic” or two-state equilibrium models). We present an expanded mechanism for signal propagation throughout the signaling domain, where salt and temperature variations trigger subtle shifts in dynamics. Extreme dynamics motional ranges (compact or highly-dynamic) associate with a specific flagellar signaling state, here the kinase-off response, where a more moderate dynamics motion (dynamic) associates with the kinase-on response. Structurally, we reference our data on PML and ND reconstituted NpSRII/HtrII to the EcTsr crystal structure and the NpHtrII homology model. We show that, despite a difference in packing, NpHtrII oligomerizes in a similar manner as EcTsr, even in the absence of stabilizing structures such as the CheA/CheW baseplate. The presence of trimers-of-dimers but also dimers-of-dimers in membrane sheet samples exposes the high affinity with which NpHtrII signaling domains interact. We hope our structural and dynamics details will push further not just drug design but also environmental preservation efforts where taxis systems drive colonization and virulence of pathogens in plants, animals and humans alike

Clustering and Dynamics of Phototransducer Signaling Domains Revealed by Site-Directed Spin Labeling Electron Paramagnetic Resonance on SRII/HtrII in Membranes and Nanodiscs

In halophilic archaea the photophobic response is mediated by the membrane-embedded 2:2 photoreceptor/-transducer complex SRII/HtrII, the latter being homologous to the bacterial chemoreceptors. Both systems bias the rotation direction of the flagellar motor via a two-component system coupled to an extended cytoplasmic signaling domain formed by a four helical antiparallel coiled-coil structure. For signal propagation by the HAMP domains connecting the transmembrane and cytoplasmic domains, it was suggested that a two-state thermodynamic equilibrium found for the first HAMP domain in <i>Np</i>SRII/<i>Np</i>HtrII is shifted upon activation, yet signal propagation along the coiled-coil transducer remains largely elusive, including the activation mechanism of the coupled kinase CheA. We investigated the dynamic and structural properties of the cytoplasmic tip domain of <i>Np</i>HtrII in terms of signal transduction and putative oligomerization using site-directed spin labeling electron paramagnetic resonance spectroscopy. We show that the cytoplasmic tip domain of <i>Np</i>HtrII is engaged in a two-state equilibrium between a dynamic and a compact conformation like what was found for the first HAMP domain, thus strengthening the assumption that dynamics are the language of signal transfer. Interspin distance measurements in membranes and on isolated 2:2 photoreceptor/transducer complexes in nanolipoprotein particles provide evidence that archaeal photoreceptor/-transducer complexes analogous to chemoreceptors form trimers-of-dimers or higher-order assemblies even in the absence of the cytoplasmic components CheA and CheW, underlining conservation of the overall mechanistic principles underlying archaeal phototaxis and bacterial chemotaxis systems. Furthermore, our results revealed a significant influence of the <i>Np</i>HtrII signaling domain on the <i>Np</i>SRII photocycle kinetics, providing evidence for a conformational coupling of SRII and HtrII in these complexes