Conformational differences between the Pfr and Pr states in Pseudomonas aeruginosa bacteriophytochrome

Femtosecond photodynamics of the red/green cyanobacteriochrome NpR6012g4 from Nostoc punctiforme. 2. reverse dynamics

Phytochromes are red/far-red photosensory proteins that utilize photoisomerization of a linear tetrapyrrole (bilin) chromophore to photoconvert reversibly between red- and far-red-absorbing forms (P(r) and P(fr), respectively). Cyanobacteriochromes (CBCRs) are related photosensory proteins with more diverse spectral sensitivity. The mechanisms that underlie this spectral diversity have not yet been fully elucidated. One of the main CBCR subfamilies photoconverts between a red-absorbing 15Z ground state, like the familiar P(r) state of phytochromes, and a green-absorbing photoproduct ((15E)P(g)). We have previously used the red/green CBCR NpR6012g4 from the cyanobacterium Nostoc punctiforme to examine ultrafast photodynamics of the forward photoreaction. Here, we examine the reverse reaction. Using excitation-interleaved transient absorption spectroscopy with broadband detection and multicomponent global analysis, we observed multiphasic excited-state dynamics. Interleaved excitation allowed us to identify wavelength-dependent shifts in the ground-state bleach that equilibrated on a 200 ps time scale, indicating ground-state heterogeneity. Compared to the previously studied forward reaction, the reverse reaction has much faster excited-state decay time constants and significantly higher photoproduct yield. This work thus demonstrates striking differences between the forward and reverse reactions of NpR6012g4 and provides clear evidence of ground-state heterogeneity in the phytochrome superfamily.

Structure-guided engineering enhances a phytochrome-based infrared fluorescent protein

Phytochrome is a multidomain dimeric red light photoreceptor that utilizes a chromophore-binding domain (CBD), a PHY domain, and an output module to induce cellular changes in response to light. A promising biotechnology tool emerged when a structure-based substitution at Asp-207 was shown to be an infrared fluorophore that uses a biologically available tetrapyrrole chromophore. We report multiple crystal structures of this D207H variant of the Deinococcus radiodurans CBD, in which His-207 is observed to form a hydrogen bond with either the tetrapyrrole A-ring oxygen or the Tyr-263 hydroxyl. Based on the implications of this duality for fluorescence properties, Y263F was introduced and shown to have stronger fluorescence than the original D207H template. Our structures are consistent with the model that the Y263F change prevents a red light-induced far-red light absorbing phytochrome chromophore configuration. With the goal of decreasing size and thereby facilitating use as a fluorescent tag in vivo, we also engineered a monomeric form of the CBD. Unexpectedly, photoconversion was observed in the monomer despite the lack of a PHY domain. This observation underscores an interplay between dimerization and the photochemical properties of phytochrome and suggests that the monomeric CBD could be used for further studies of the photocycle. The D207H substitution on its own in the monomer did not result in fluorescence, whereas Y263F did. Combined, the D207H and Y263F substitutions in the monomeric CBD lead to the brightest of our variants, designated Wisconsin infrared phytofluor (Wi-Phy).

Temperature-scan cryocrystallography reveals reaction intermediates in bacteriophytochrome

Light is a fundamental signal that regulates important physiological processes such as development and circadian rhythm in living organisms. Phytochromes form a major family of photoreceptors responsible for red light perception in plants, fungi and bacteria. They undergo reversible photoconversion between red-absorbing (Pr) and far-red-absorbing (Pfr) states, thereby ultimately converting a light signal into a distinct biological signal that mediates subsequent cellular responses. Several structures of microbial phytochromes have been determined in their dark-adapted Pr or Pfr states. However, the structural nature of initial photochemical events has not been characterized by crystallography. Here we report the crystal structures of three intermediates in the photoreaction of Pseudomonas aeruginosa bacteriophytochrome (PaBphP). We used cryotrapping crystallography to capture intermediates, and followed structural changes by scanning the temperature at which the photoreaction proceeded. Light-induced conformational changes in PaBphP originate in ring D of the biliverdin (BV) chromophore, and E-to-Z isomerization about the C(15) = C(16) double bond between rings C and D is the initial photochemical event. As the chromophore relaxes, the twist of the C(15) methine bridge about its two dihedral angles is reversed. Structural changes extend further to rings B and A, and to the surrounding protein regions. These data indicate that absorption of a photon by the Pfr state of PaBphP converts a light signal into a structural signal via twisting and untwisting of the methine bridges in the linear tetrapyrrole within the confined protein cavity.

Phytochrome structure and photochemistry: recent advances toward a complete molecular picture

Phytochromes are nature's primary photoreceptors dedicated to detecting the red and far-red regions of the visible light spectrum, a region also essential for photosynthesis and thus crucial to the survival of plants and other photosynthetic organisms. Given their roles in measuring competition and diurnal/seasonal light fluctuations, understanding how phytochromes work at the molecular level would greatly aid in engineering crop plants better suited to specific agricultural settings. Recently, scientists have determined the three-dimensional structures of prokaryotic phytochromes, which now provide clues as to how these modular photoreceptors might work at the atomic level. The models point toward a largely unifying mechanism whereby novel knot, hairpin, and dimeric interfaces transduce photoreversible bilin isomerization into protein conformational changes that alter signal output.

Phytochrome signaling: solving the Gordian knot with microbial relatives

Phytochromes encompass a diverse collection of biliproteins that regulate numerous photoresponses in plants and microorganisms. Whereas the plant versions have proven experimentally intractable for structural studies, the microbial forms have recently provided important insights into how these photoreceptors work at the atomic level. Here, we review the current understanding of these microbial phytochromes, which shows that they have a modular dimeric architecture that propagates light-driven rotation of the bilin to distal contacts between adjacent signal output domains. Surprising features underpinning this signaling include: a deeply buried chromophore; a knot and hairpin loop that stabilizes the photosensing domain; and an extended helical spine that translates conformational changes in the photosensing domain to the output domain. Conservation within the superfamily both in modular construction and sequence strongly suggests that higher plant phytochromes work similarly as light-regulated toggle switches.

Bacterial phytochromes: more than meets the light

Phytochromes are environmental sensors, historically thought of as red/far-red photoreceptors in plants. Their photoperception occurs through a covalently linked tetrapyrrole chromophore, which undergoes a light-dependent conformational change propagated through the protein to a variable output domain. The phytochrome composition is modular, typically consisting of a PAS-GAF-PHY architecture for the N-terminal photosensory core. A collection of three-dimensional structures has uncovered key features, including an unusual figure-of-eight knot, an extension reaching from the PHY domain to the chromophore-binding GAF domain, and a centrally located, long α-helix hypothesized to be crucial for intramolecular signaling. Continuing identification of phytochromes in microbial systems has expanded the assigned sensory abilities of this family out of the red and into the yellow, green, blue, and violet portions of the spectrum. Furthermore, phytochromes acting not as photoreceptors but as redox sensors have been recognized. In addition, architectures other than PAS-GAF-PHY are known, thus revealing phytochromes to be a varied group of sensory receptors evolved to utilize their modular design to perceive a signal and respond accordingly. This review focuses on the structures of bacterial phytochromes and implications for signal transmission. We also discuss the small but growing set of bacterial phytochromes for which a physiological function has been ascertained.

Receptor domains of two-component signal transduction systems

Two-component signal transduction systems are found ubiquitously in prokaryotes, and in archaea, fungi, yeast and some plants, where they regulate physiologic and molecular processes at both transcriptional and post-transcriptional levels. Two-component systems sense changes in environmental conditions when a specific ligand binds to the receptor domain of the histidine kinase sensory component. The structures of many histidine kinase receptors are known, including those which sense extracellular and cytoplasmic signals. In this review, we discuss the basic architecture of two-component signalling circuits, including known system ligands, structure and function of both receptor and signalling domains, the chemistry of phosphotransfer, and cross-talk between different two-component pathways. Given the importance of these systems in regulating cellular responses, many biochemical techniques have been developed for their study and analysis. We therefore also review current methods used to study two-component signalling, including a new affinity-based proteomics approach used to study inducible resistance to the antibiotic vancomycin through the VanSR two-component signal transduction system.

Two ground state isoforms and a chromophore D-ring photoflip triggering extensive intramolecular changes in a canonical phytochrome

Phytochrome photoreceptors mediate light responses in plants and in many microorganisms. Here we report studies using (1)H-(13)C magic-angle spinning NMR spectroscopy of the sensor module of cyanobacterial phytochrome Cph1. Two isoforms of the red-light absorbing Pr ground state are identified. Conclusive evidence that photoisomerization occurs at the C15-methine bridge leading to a β-facial disposition of the ring D is presented. In the far-red-light absorbing Pfr state, strong hydrogen-bonding interactions of the D-ring carbonyl group to Tyr-263 and of N24 to Asp-207 hold the chromophore in a tensed conformation. Signaling is triggered when Asp-207 is released from its salt bridge to Arg-472, probably inducing conformational changes in the tongue region. A second signal route is initiated by partner swapping of the B-ring propionate between Arg-254 and Arg-222.

Structure of the chromophore binding pocket in the Pr state of plant phytochrome phyA

A homology structural model was generated for plant phytochrome phyA utilizing the crystal structure of the sensory module of cyanobacterial phytochrome Cph1 (Cph1Δ2). As chromophores, either the native phytochromobilin cofactor (PΦB) or phycocyanobilin (PCB), the natural cofactor in Cph1, was incorporated. These homology models were further optimized by molecular dynamics (MD) simulations revealing a satisfying overall agreement with the crystal structure of Cph1Δ2. Notable differences in the PΦB adduct of phyA result from a restructuring of the small helical segment α(7) that leads to displacements of a few amino acids away from the cofactor. This repositioning of residues also include aspartate 218 such that, instead of its carbonyl function as in Cph1Δ2, an additional water molecule forms hydrogen bonds with the ring B and C NH groups. To validate the phyA structural model in the chromophore binding pocket, Raman spectra of the cofactor were calculated by means of the quantum mechanics/molecular mechanics (QM/MM) hybrid methodology and compared with the experimental resonance Raman (RR) spectra. The satisfactory overall agreement between calculated and experimental spectra is taken as an indication for the good quality of the structural model. Moreover, the methine bridge stretching modes and the effects of isotopic labeling at selected positions of the chromophore are very well reproduced to allow confirming even details of the methine bridge geometry as predicted by the homology model. Specifically, it is demonstrated that the experimental RR spectra are consistent with a torsional angle of ring D with respect to ring C that is distinctly higher for phyA-PCB (45°) and phyA-PΦB (42°) than for Cph1Δ2 (30°). Raman spectra calculated from different points of the MD trajectory display variations of the mode frequencies and intensities reflecting the structural fluctuations from snapshot to snapshot. The snapshot spectrum of the lowest energy structure and the sum of all snapshot spectra afford an equally good description of the experimental data. Particularly large variations between the snapshots are noted for the N-H in-plane bending mode of the pyrrole rings B and C, which reflect alterations of the hydrogen bond interactions brought about by fluctuations of water molecules in the cofactor cavity. This overestimation of the water molecule mobility is a consequence of the deficiency of the current QM/MM methodology that, due to the lack of appropriate protein force fields, cannot adequately account for the electrostatics in the cofactor pocket.

Phytochrome: structural basis for its functions

Phytochrome mediates various physiological as well as developmental responses to light stimuli in plants. Phytochrome is a soluble chromoprotein consisting of the N-terminal photosensory and C-terminal dimerization moieties. Close homologues of plant phytochromes are widely found in prokaryotes. Recently, the crystal structures of the core photosensory module of bacterial phytochromes are resolved. Intriguingly, three sub-domains (PAS, GAF and PHY) in the module are connected by unusual structures named 'light-sensing knot' and 'tongue', which are in tight contact with the chromophore. These findings enable us to review previous data on the structure-function relationships in phytochrome. Consequently, functional importance of these peculiar structures is further highlighted. Thus, the three-dimensional structure provides a framework for understanding how phytochrome processes the light signals.

Biliverdin amides reveal roles for propionate side chains in bilin reductase recognition and in holophytochrome assembly and photoconversion

Linear tetrapyrroles (bilins) perform important antioxidant and light-harvesting functions in cells from bacteria to humans. To explore the role of the propionate moieties in bilin metabolism, we report the semisynthesis of mono- and diamides of biliverdin IXalpha and those of its non-natural XIIIalpha isomer. Initially, these were examined as substrates of two types of NADPH-dependent biliverdin reductase, BVR and BvdR, and of the representative ferredoxin-dependent bilin reductase, phycocyanobilin:ferredoxin oxidoreductase (PcyA). Our studies indicate that the NADPH-dependent biliverdin reductases are less accommodating to amidation of the propionic acid side chains of biliverdin IXalpha than PcyA, which does not require free carboxylic acid side chains to yield its phytobilin product, phycocyanobilin. Bilin amides were also assembled with BV-type and phytobilin-type apophytochromes, demonstrating a role for the 8-propionate in the formation of the spectroscopically native P(r) dark states of these biliprotein photosensors. Neither ionizable propionate side chain proved to be essential to primary photoisomerization for both classes of phytochromes, but an unsubstituted 12-propionate was required for full photointerconversion of phytobilin-type phytochrome Cph1. Taken together, these studies provide insight into the roles of the ionizable propionate side chains in substrate discrimination by two bilin reductase families while further underscoring the mechanistic differences between the photoconversions of BV-type and phytobilin-type phytochromes.

A brief history of phytochromes

Photosensory proteins enable living things to detect the quantity and quality of the light environment and to transduce that physical signal into biochemical outputs which entrain their metabolism with the ambient light environment. Phytochromes, which photoconvert between red-absorbing P(r) and far-red-absorbing P(fr) states, are the most extensively studied of these interesting proteins. Critical regulators of a number of key adaptive processes in higher plants, including photomorphogenesis and shade avoidance, phytochromes are widespread in photosynthetic and nonphotosynthetic bacteria, and even in fungi. Cyanobacterial genomes also possess a plethora of more distant relatives of phytochromes known as cyanobacteriochromes (CBCRs). Biochemical characterization of representative CBCRs has demonstrated that this class of photosensors exhibits a broad range of wavelength sensitivities, spanning the entire visible spectrum. Distinct protein-bilin interactions are responsible for this astonishing array of wavelength sensitivities. Despite this spectral diversity, all members of the extended family of phytochrome photosensors appear to share a common photochemical mechanism for light sensing: photoisomerization of the 15/16 double bond of the bilin chromophore.

Sensor domains of two-component regulatory systems

Two-component systems regulate crucial cellular processes in microorganisms, and each comprises a homodimeric histidine kinase receptor and a cytoplasmic response regulator. Histidine kinases, often membrane associated, detect environmental input at sensor domains and propagate resulting signals to catalytic cytoplasmic transmitter domains. Recent studies on the great diversity of sensor domains reveal patterns of domain organization and biochemical properties that provide insight into mechanisms of signaling. Despite the enormous sequence variability found within sensor input domains, they fall into a relatively small number of discrete structural classes. Subtle rearrangements along a structurally labile dimer interface, in the form of possible sliding or rotational motions, are propagated from the sensor domain to the transmitter domain to modulate activity of the receptor.

Structural basis for the photoconversion of a phytochrome to the activated Pfr form

Phytochromes are a collection of bilin-containing photoreceptors that regulate numerous photoresponses in plants and microorganisms through their ability to photointerconvert between a red light-absorbing, ground state Pr and a far-red light-absorbing, photoactivated state Pfr1,2. While the structures of several phytochromes as Pr have been determined3-7, little is known about the structure of Pfr and how it initiates signaling. Here, we describe the three-dimensional solution structure of the bilin-binding domain as Pfr using the cyanobacterial phytochrome from Synechococcus OSB’. Contrary to predictions, light-induced rotation of the A but not the D pyrrole ring is the primary motion of the chromophore during photoconversion. Subsequent rearrangements within the protein then affect intra- and interdomain contact sites within the phytochrome dimer. From our models, we propose that phytochromes act by propagating reversible light-driven conformational changes in the bilin to altered contacts between the adjacent output domains, which in most phytochromes direct differential phosphotransfer.

Structure and function of plant photoreceptors

Signaling photoreceptors use the information contained in the absorption of a photon to modulate biological activity in plants and a wide range of organisms. The fundamental-and as yet imperfectly answered-question is, how is this achieved at the molecular level? We adopt the perspective of biophysicists interested in light-dependent signal transduction in nature and the three-dimensional structures that underpin signaling. Six classes of photoreceptors are known: light-oxygen-voltage (LOV) sensors, xanthopsins, phytochromes, blue-light sensors using flavin adenine dinucleotide (BLUF), cryptochromes, and rhodopsins. All are water-soluble proteins except rhodopsins, which are integral membrane proteins; all are based on a modular architecture except cryptochromes and rhodopsins; and each displays a distinct, light-dependent chemical process based on the photochemistry of their nonprotein chromophore, such as isomerization about a double bond (xanthopsins, phytochromes, and rhodopsins), formation or rupture of a covalent bond (LOV sensors), or electron transfer (BLUF sensors and cryptochromes).