Signal amplification and transduction in phytochrome photosensors

Takala, Heikki; Björling, Alexander; Berntsson, Oskar; Lehtivuori, Heli; Niebling, Stephan; Hoernke, Maria; Kosheleva, Irina; Henning, Robert H.; Menzel, Andreas; Ihalainen, Janne A.; Westenhoff, Sebastian

doi:10.1038/nature13310

Cited by 307 publications

(738 citation statements)

References 35 publications

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“…Conversion of the hairpin from β-stranded to helical then impacts the OPM by reversibly altering the GAF/ PHY domain connections. This β-strand to helical refolding was recently confirmed by low-resolution paired Pr and Pfr crystal structures of the PSM from Dr-BphP, which in turn, supported a large-scale separation of the sister PHY domains within the dimer (29). Our analyses of Arabidopsis PhyB support this model for Phys with PAS/GAF/PHY domain architectures and extend it to other PSM features that promote the Pr/Pfr transitions and stabilize the two end states (Fig.…”

Section: Resultssupporting

confidence: 66%

“…Together, these effects presumably melt the GAF/ hairpin interaction, including the D307/R582 salt bridge, to permit helical refolding of the stem. As proposed (7,29), this refolding also would swivel the main-chain positions of the melted strands-β ent and -β exit with respect to the GAF domain and swap the positions of R582 and S584 to now allow hydrogen bonding between S584 and D307 (Fig. 5).…”

Section: Resultsmentioning

confidence: 99%

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Crystal structure of the photosensing module from a red/far-red light-absorbing plant phytochrome

Burgie

Bussell

Walker

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

190

305

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Many aspects of plant photomorphogenesis are controlled by the phytochrome (Phy) family of bilin-containing photoreceptors that detect red and far-red light by photointerconversion between a dark-adapted Pr state and a photoactivated Pfr state. Whereas 3D models of prokaryotic Phys are available, models of their plant counterparts have remained elusive. Here, we present the crystal structure of the photosensing module (PSM) from a seed plant Phy in the Pr state using the PhyB isoform from Arabidopsis thaliana. The PhyB PSM crystallized as a head-to-head dimer with strong structural homology to its bacterial relatives, including a 5(Z)syn, 10(Z)syn, 15(Z)anti configuration of the phytochromobilin chromophore buried within the cGMP phosphodiesterase/adenylyl cyclase/FhlA (GAF) domain, and a well-ordered hairpin protruding from the Phy-specific domain toward the bilin pocket. However, its Per/Arnt/Sim (PAS) domain, knot region, and helical spine show distinct structural differences potentially important to signaling. Included is an elongated helical spine, an extended β-sheet connecting the GAF domain and hairpin stem, and unique interactions between the region upstream of the PAS domain knot and the bilin A and B pyrrole rings. Comparisons of this structure with those from bacterial Phys combined with mutagenic studies support a toggle model for photoconversion that engages multiple features within the PSM to stabilize the Pr and Pfr end states after rotation of the D pyrrole ring. Taken together, this Arabidopsis PhyB structure should enable molecular insights into plant Phy signaling and provide an essential scaffold to redesign their activities for agricultural benefit and as optogenetic reagents.G iven the importance of sunlight to their survival and growth, plants have adopted a collection of photoreceptors and interconnected signaling cascades to optimize their photosynthetic potential and synchronize their lifecycles with circadian and seasonal rhythms. Chief among these are the phytochromes (Phys), a family of bilin (or open-chain tetrapyrrole)-containing red/far-red light-absorbing photoreceptors that provides spatial and time-dependent information by sensing the fluence rate, direction, duration, and color of a plant's light environment (1, 2). This information then regulates nearly all aspects of plant growth and development from seed germination to senescence. Notably, seed plants typically express three Phy isoforms (PhyA, PhyB, and PhyC) that control distinct and overlapping photoresponses, with PhyB having a dominant role in green tissues (2, 3).Phys are homodimers with each sister polypeptide divided into an N-terminal photosensory module (PSM) that absorbs light followed by an output module (OPM) that promotes dimerization and presumably, relays the light signals (1, 4). The PSM sequentially contains a Per/Arnt/Sim (PAS) domain of unknown function, a cGMP phosphodiesterase/adenylyl cyclase/FhlA (GAF) domain that cradles the bilin, and a Phy-specific (PHY) domain that stabilizes the photoactivated ...

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Section: Resultssupporting

confidence: 66%

Section: Resultsmentioning

confidence: 99%

Crystal structure of the photosensing module from a red/far-red light-absorbing plant phytochrome

Burgie

Bussell

Walker

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

190

305

View full text Add to dashboard Cite

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“…S1). These distances turned out to fit nicely in the 10-40 Å spread between the α-helices of the Deinococcus BphP in the dark and lit states (41). Whether proteins whose homodimers are separated by larger distances can be made light-responsive is unclear.…”

Section: Discussionmentioning

confidence: 88%

“…Our demonstration that homodimeric bacteriophytochromes are amenable to protein engineering (24) and recent progress in structural understanding of dark-to-light conformational changes (41) should encourage design of new NIRW light-activated proteins. Because activities of many signal transduction components depend on homodimerization, including membrane receptors, cyclic nucleotide phosphodiesterases, certain protein phosphatases, proteases, nucleases, and transcription factors, we expect significant expansion of the optogenetic toolset involving NIRW light.…”

Section: Discussionmentioning

confidence: 99%

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Engineering adenylate cyclases regulated by near-infrared window light

Ryu

Kang

Nelson

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

104

111

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Bacteriophytochromes sense light in the near-infrared window, the spectral region where absorption by mammalian tissues is minimal, and their chromophore, biliverdin IXα, is naturally present in animal cells. These properties make bacteriophytochromes particularly attractive for optogenetic applications. However, the lack of understanding of how light-induced conformational changes control output activities has hindered engineering of bacteriophytochromebased optogenetic tools. Many bacteriophytochromes function as homodimeric enzymes, in which light-induced conformational changes are transferred via α-helical linkers to the rigid output domains. We hypothesized that heterologous output domains requiring homodimerization can be fused to the photosensory modules of bacteriophytochromes to generate light-activated fusions. Here, we tested this hypothesis by engineering adenylate cyclases regulated by light in the near-infrared spectral window using the photosensory module of the Rhodobacter sphaeroides bacteriophytochrome BphG1 and the adenylate cyclase domain from Nostoc sp. CyaB1. We engineered several light-activated fusion proteins that differed from each other by approximately one or two α-helical turns, suggesting that positioning of the output domains in the same phase of the helix is important for light-dependent activity. Extensive mutagenesis of one of these fusions resulted in an adenylate cyclase with a sixfold photodynamic range. Additional mutagenesis produced an enzyme with a more stable photoactivated state. When expressed in cholinergic neurons in Caenorhabditis elegans, the engineered adenylate cyclase affected worm behavior in a light-dependent manner. The insights derived from this study can be applied to the engineering of other homodimeric bacteriophytochromes, which will further expand the optogenetic toolset.phytochrome | protein engineering | adenylyl cyclase | cAMP | locomotion

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It's a two‐way street: Photoswitching and reversible changes of the protein matrix in photoswitchable fluorescent proteins and bacteriophytochromes

Rodrigues

Stiel

2023

FEBS Letters

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Chromophore‐bearing proteins that are (reversibly) altered after light illumination are major functional components of nature. They gained considerable attention in the last decades since the dynamic interactions of the chromophore and protein matrix can be used to control downstream effects altering the functionality of proteins, cells, or complete organisms with light (optogenetics). Additionally, the photophysical effects can be employed to add capabilities to optical imaging. For example, light can be used to reversibly switch the signal on or off (e.g., fluorescence). In this article, we review chromophore and protein matrix interactions, focusing on photoswitching fluorescent proteins of the GFP family (RSFPs) and natively photoswitching bacteriophytochromes (BphPs). This review aims to provide an in‐depth understanding of the dynamic interplay between photoswitching photophysics and the protein matrix and a thorough discussion on how this connection has been harnessed for the development of optogenetic and imaging tools.

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Signal amplification and transduction in phytochrome photosensors

Cited by 307 publications

References 35 publications

Crystal structure of the photosensing module from a red/far-red light-absorbing plant phytochrome

Crystal structure of the photosensing module from a red/far-red light-absorbing plant phytochrome

Engineering adenylate cyclases regulated by near-infrared window light

It's a two‐way street: Photoswitching and reversible changes of the protein matrix in photoswitchable fluorescent proteins and bacteriophytochromes

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