On the binding of BODIPY-GTP by the photosensory protein YtvA from the common soil bacterium Bacillus subtilis

The YtvA protein, which is one of the proteins that comprises the network carrying out the signal transfer inducing the general stress response in Bacillus subtilis, is composed of an N-terminal LOV domain (that binds a flavin [FMN]) and a C-terminal STAS domain. This latter domain shows sequence features typical for a nucleotide (NTP) binding protein. It has been proposed (FEBS Lett., 580 [2006], 3818) that BODIPY-GTP can be used as a reporter for nucleotide binding to this site and that activation of the LOV domain by blue light is reflected in an alteration of the BODIPY-GTP fluorescence. Here we confirm that BODIPY-GTP indeed binds to YtvA, but rather nonspecifically, and not limited to the STAS domain. Blue-light modulation of fluorescence emission of YtvA-bound BODIPY-GTP is observed both in the full-length YtvA protein and in a truncated protein composed of the LOV-domain plus the LOV-STAS linker region (YtvA(1-147)) as a light-induced decrease in fluorescence emission. The isolated LOV domain (i.e. without the linker region) does not show such BODIPY-GTP fluorescence changes. Dialysis experiments have confirmed the blue-light-induced release of BODIPY-GTP from YtvA.     

Tryptophan Fluorescence in the Bacillus subtilis Phototropin‐related Protein YtvA as a Marker of Interdomain Interaction¶

The Bacillus subtilis protein YtvA, related to plant phototropins (phot), binds flavin mononucleotide (FMN) within the N‐terminal light, oxygen and voltage (LOV) domain. The blue light‐triggered photocycle of YtvA and phot involves the reversible formation of a covalent photoadduct between FMN and a cysteine (cys) residue. YtvA contains a single tryptophan, W103, localized on the LOV domain and conserved in all phot‐LOV domains. In this study, we show that the fluorescence parameters of W103 in YtvA‐LOV are markedly different from those observed in the full‐length YtvA. The fluorescence quantum yields are ca 0.03 and 0.08, respectively. In YtvA‐LOV, the maximum is redshifted (ca 345 vs 335 nm) and the average fluorescence lifetime shorter (2.7 vs 4.7 ns). These data indicate that W103 is located in a site of tight contact between the two domains of YtvA. In the FMN‐cys adduct, selective excitation of W103 at 295 nm results in minimal changes of the fluorescence parameters with respect to the dark state. On 280 nm excitation, however, there is a detectable decrease in the fluorescence emitted from tyrosines, with concomitant increase in W103 fluorescence. This effect is reversible in the dark and might arise from a light‐regulated energy transfer process from a yet unidentified tyrosine to W103.     

Initial characterization of a blue-light sensing, phototropin-related protein from Pseudomonas putida: a paradigm for an extended LOV construct

The open reading frame PP2739 from Pseudomonas putida KT2440 encodes a 151 amino acid protein with sequence similarity to the LOV domains of the blue-light sensitive protein YtvA from Bacillus subtilis and to the phototropins (phot) from plants. This sensory box LOV protein, PpSB2-LOV, comprises a LOV core, followed by a C-terminal segment predicted to form an alpha-helix, thus constituting a naturally occurring paradigm for an extended LOV construct. The recombinant PpSB2-LOV shows a photochemistry very similar to that of YtvA and phot-LOV domains, yet the lifetime for the recovery dark reaction, taurec=114 s at 20 degrees C, resembles that of phot-LOV domains (5-300 s) and is much faster than that of YtvA or YtvA-LOV (>3000 s). Time-resolved optoacoustics reveals phot-like, light-driven reactions on the ns-micros time window with the sub-nanosecond formation of a flavin triplet state (PhiT=0.46) that decays into the flavin-cysteine photoadduct with 2 micros lifetime (Phi390=0.42). The fluorescence spectrum and lifetime of the conserved W97 resembles the corresponding W103 in full-length YtvA, although the quantum yield, PhiF, is smaller (about 55% of YtvA) due to an enhanced static quenching efficiency. The anisotropy of W97 is the same as for W103 in YtvA (0.1), and considerably larger than the value of 0.06, found for W103 in YtvA-LOV. Different to YtvA and YtvA-LOV, the fluorescence for W97 becomes larger upon photoproduct formation. These data indicate that W97 is located in a similar environment as W103 in full-length YtvA, but undergoes larger light-driven changes. It is concluded that the protein segment located C-terminally to the LOV core (analogous to an interdomain linker) is enough to confer to the conserved tryptophan the fluorescence characteristics typical of full-length YtvA. The larger changes experienced by W97 upon light activation may reflect a larger conformational freedom of this protein segment in the absence of a second domain.     

Quantum Mechanics/Molecular Mechanics Study on the Photoreactions of Dark‐ and Light‐Adapted States of a Blue‐Light YtvA LOV Photoreceptor

The dark‐ and light‐adapted states of YtvA LOV domains exhibit distinct excited‐state behavior. We have employed high‐level QM(MS‐CASPT2)/MM calculations to study the photochemical reactions of the dark‐ and light‐adapted states. The photoreaction from the dark‐adapted state starts with an S₁→T₁ intersystem crossing followed by a triplet‐state hydrogen transfer from the thiol to the flavin moiety that produces a diradical intermediate, and a subsequent internal conversion that triggers a barrierless C−S bond formation in the S₀ state. The energy profiles for these transformations are different for the four conformers of the dark‐adapted state considered. The photochemistry of the light‐adapted state does not involve the triplet state: photoexcitation to the S₁ state triggers C−S bond cleavage followed by recombination in the S₀ state; both these processes are essentially barrierless and thus ultrafast. The present work offers new mechanistic insights into the photoresponse of flavin‐containing blue‐light photoreceptors.     

Characterization of an Unusual LOV Domain Protein in the α-Proteobacterium Rhodobacter sphaeroides

The facultatively phototrophic purple bacterium Rhodobacter sphaeroides 2.4.1 harbors a LOV (light, oxygen and voltage) domain protein, which shows a particular structure. LOV domains perceive blue light by a noncovalently bound flavin and transmit the signal to various coupled output domains. Proteins, that harbor a LOV core, function e.g. as phototropins or circadian clock regulators. Jα helices, which act as linker between the LOV core and the output domain, were shown to be involved in the light-dependent activation of the output domain. Like PpSB2 from Pseudomonas putida , the LOV domain protein of R. sphaeroides is not coupled to an effector domain and harbors an extended C-terminal α helix. We expressed the R. sphaeroides LOV domain recombinantly in Escherichia  coli . The protein binds an FMN as a cofactor and shows a photocycle typical for LOV domain containing proteins. In R. sphaeroides , we detected the protein as well in the cytoplasm as in the membrane fraction, which was not reported for other bacterial LOV domain proteins.     

Light‐Regulated Tetracycline Binding to the Tet Repressor

Elucidation of the signal‐transmission pathways between distant sites within proteins is of great importance in medical and bioengineering sciences. The use of optical methods to redesign protein functions is emerging as a general approach for the control of biological systems with high spatiotemporal precision. Here we report the detailed thermodynamic and kinetic characterization of novel chimeric light‐regulated Tet repressor (TetR) switches in which light modulates the TetR function. Light absorbed by flavin mononucleotide (FMN) generates a signal that is transmitted to As‐LOV and YtvA‐LOV fused TetR proteins (LOV=light–oxygen–voltage), in which it alters the binding to tetracycline, the TetR ligand. The engineering of light‐sensing protein modules with TetR is a valuable tool that deepens our understanding of the mechanism of signal transmission within proteins. In addition, the light‐regulated changes of drug binding that we describe here suggest that engineered light‐sensitive proteins may be used for the development of novel therapeutic strategies.     

Mutational effects on protein structural changes and interdomain interactions in the blue-light sensing LOV protein YtvA

Mutagenesis studies on the phototropin-related protein YtvA from Bacillus subtilis have revealed the role of selected structural elements in interdomain communication. The LOV (light, oxygen, voltage) domain of YtvA undergoes light-driven reactions similar to that of phot-LOV, with reversible formation of a covalent flavin-cysteine adduct. The mutated proteins Ytva-E105L and YtvA-E56Q have been studied by UV fluorescence and circular dichroism (CD) spectroscopy. E105 (L in phototropin) is located at the solvent-exposed surface of the LOV domain central beta-sheet, demonstrated to participate in interdomain interaction in phototropin. CD data show that YtvA-E105L has a lower alpha-helix content in the dark and undergoes larger light-driven conformational changes than YtvA-WT. The E56Q mutation breaks the E56-K97 salt bridge, a structural element highly conserved within the LOV series. In YtvA-E56Q the CD spectrum is the same as in YtvA-WT, although the conserved W103 becomes more exposed to the solvent and the dark-recovery kinetics is slower. These results indicate that the E56-K97 salt bridge stabilizes locally the protein structure and participates in the regulation of the photocycle but has negligible effects on the overall structure. The E105L mutation, instead, highlights the involvement of the central beta-sheet in the light-driven conformational changes in LOV proteins.     

LOV-like flavin-Cys adduct formation by introducing a Cys residue in the BLUF domain of TePixD

BLUF and LOV are blue-light sensor domains that possess flavin as a common chromophore but exhibit distinct photoreactions. Ile66 located in the BLUF domain of a cyanobacterial photosensor protein, TePixD, was replaced with Cys to mimic the LOV domain. Light-induced Fourier transform infrared spectra of the I66C TePixD showed that a flavin-Cys adduct, typical of the photoinduced intermediates of LOV domains, was formed in the I66C BLUF domain. This result demonstrates that different types of flavin photoreactions can be realized in the same domain if key amino acids are properly arranged near the flavin and the domain structure itself is not a crucial factor to determine the photoreaction type.     

The LOV2 domain of phototropin: a reversible photochromic switch

Light, oxygen, or voltage (LOV) domains constitute a new class of photoreceptor proteins that are sensitive to blue light through a noncovalently bound flavin chromophore. Blue-light absorption by the LOV2 domain initiates a photochemical reaction that results in formation of a long-lived covalent adduct between a cysteine and the flavin cofactor. We have applied ultrafast spectroscopy on the photoaccumulated covalent adduct state of LOV2 and find that, upon absorption of a near-UV photon by the adduct state, the covalent bond between the flavin and the cysteine is broken and the blue-light-sensitive ground state is regained on an ultrafast time scale of 100 ps. We thus demonstrate that the LOV2 domain is a reversible photochromic switch, which can be activated by blue light and deactivated by near-UV light.     

Modulation of the photocycle of a LOV domain photoreceptor by the hydrogen-bonding network

An extended hydrogen-bonding (HB) network stabilizes the isoalloxazine ring of the flavin mononucleotide (FMN) chromophore within the photosensing LOV domain of blue-light protein receptors, via interactions between the C(2)═O, N(3)H, C(4)═O, and N(5) groups and conserved glutamine and asparagine residues. In this work we studied the influence of the HB network on the efficiency, kinetics, and energetics of a LOV protein photocycle, involving the reversible formation of a FMN-cysteine covalent adduct. The following results were found for mutations of the conserved amino acids N94, N104, and Q123 in the Bacillus subtilis LOV protein YtvA: (i) Increased (N104D, N94D) or strongly reduced (N94A) rate of adduct formation; this latter mutation extends the lifetime of the flavin triplet state, i.e., adduct formation, more than 60-fold, from 2 μs for the wild-type (WT) protein to 129 μs. (ii) Acceleration of the overall photocycle for N94S, N94A, and Q123N, with recovery lifetimes 20, 45, and 85 times faster than for YtvA-WT, respectively. (iii) Slight modifications of FMN spectral features, correlated with the polarization of low-energy transitions. (iv) Strongly reduced (N94S) or suppressed (Q123N) structural volume changes accompanying adduct formation, as determined by optoacoustic spectroscopy. (v) Minor effects on the quantum yield, with the exception of a considerable reduction for Q123N, i.e., 0.22 vs 0.49 for YtvA-WT. The data stress the importance of the HB network in modulating the photocycle of LOV domains, while at the same time establishing a link with functional responses.     

Functional Characterization of a LOV‐Histidine Kinase Photoreceptor from Xanthomonas citri subsp. citri

The blue‐light (BL) absorbing protein Xcc‐LOV from Xanthomonas citri subsp. citri is composed of a LOV‐domain, a histidine kinase (HK) and a response regulator. Spectroscopic characterization of Xcc‐LOV identified intermediates and kinetics of the protein's photocycle. Measurements of steady state and time‐resolved fluorescence allowed determination of quantum yields for triplet (Φ_T = 0.68 ± 0.03) and photoproduct formation (Φ₃₉₀ = 0.46 ± 0.05). The lifetime for triplet decay was determined as τ_T = 2.4–2.8 μs. Fluorescence of tryptophan and tyrosine residues was unchanged upon light‐to‐dark conversion, emphasizing the absence of significant conformational changes. Photochemistry was blocked upon cysteine C76 (C76S) mutation, causing a seven‐fold longer lifetime of the triplet state (τ_T = 16–18.5 μs). Optoacoustic spectroscopy yielded the energy content of the triplet state. Interestingly, Xcc‐LOV did not undergo the volume contraction reported for other LOV domains within the observation time window, although the back‐conversion into the dark state was accompanied by a volume expansion. A radioactivity‐based enzyme function assay revealed a larger HK activity in the lit than in the dark state. The C76S mutant showed a still lower enzyme function, indicating the dark state activity being corrupted by a remaining portion of the long‐lived lit state.     

A Blue Light-inducible Phosphodiesterase Activity in the Cyanobacterium Synechococcus elongatus

A blue light-inducible phosphodiesterase (PDE) activity, specific for the hydrolysis of cyclic di-GMP (c-di-GMP), has been identified in a recombinant protein from Synechococcus elongatus. Blue light (BL) activation is accomplished by a light, oxygen, voltage (LOV) domain, found in plant phototropins and bacterial BL photoreceptors. The genome of S. elongatus contains two genes coding for proteins with LOV domains fused to EAL domains (SL1 and SL2). In both cases, a GGDEF motif is placed in between the LOV and the EAL motifs. Such arrangement is frequently found with diguanylate-cyclase (DGC) functions that form c-di-GMP. Cyclic di-GMP acts as a second messenger molecule regulating biofilm formation in many microbial species. Both enzyme activities modulate the intracellular level of this second messenger, although in most proteins only one of the two enzyme functions is active. Both S. elongatus LOV-GGDEF-EAL proteins were expressed in full length or as truncated proteins. Only the SL2 protein, expressed as a LOV-GGDEF-EAL construct, showed an increase of PDE activity upon BL irradiation, demonstrating this activity for the first time in a LOV-domain protein. Addition of GTP or c-di-GMP did not affect the observed enzymatic activity. In none of the full-length or truncated proteins was a DGC activity detected.     

Characterization of the Blue–Light‐Activated Adenylyl Cyclase mPAC by Flash Photolysis and FTIR Spectroscopy

The recently discovered photo‐activated adenylyl cyclase (mPAC from Microcoleus chthonoplastes) is the first PAC that owes a light‐, oxygen‐ and voltage‐sensitive (LOV) domain for blue‐light sensing. The photoreaction of the mPAC receptor was studied by time‐resolved UV/vis and light‐induced Fourier transform infrared (FTIR) absorption difference spectroscopy. The photocycle comprises of the typical triplet state LOV₇₁₅ and the thio‐adduct state LOV₃₉₀. While the adduct state decays with a time constant of 8 s, the lifetime of the triplet state is with 656 ns significantly shorter than in all other reported LOV domains. The light‐induced FTIR difference spectrum shows the typical bands of the LOV₃₉₀ and LOV₄₅₀ intermediates. The negative S‐H stretching vibration at 2573 cm^?1 is asymmetric suggesting two rotamer configurations of the protonated side chain of C194. A positive band at 3632 cm^?1 is observed, which is assigned to an internal water molecule. In contrast to other LOV domains, mPAC exhibits a second positive feature at 3674 cm^?1 which is due to the O‐H stretch of a second intrinsic water molecule and the side chain of Y476. We conclude that the latter might be involved in the dimerization of the cyclase domain which is crucial for ATP binding.     

The Evolution and Functional Role of Flavin‐based Prokaryotic Photoreceptors

Flavin‐based photoreceptor proteins of the LOV (light, oxygen and voltage) superfamily are ubiquitous and appear to be essential blue‐light sensing systems not only in plants, algae and fungi, but also in prokaryotes, where they are represented in more than 10% of known species. Despite their broad occurrence, only in few cases LOV proteins have been correlated with important phenomena such as bacterial infectivity, selective growth patterns or/and stress responses; nevertheless these few known roles are helping us understand the multiple ways by which prokaryotes can exploit these soluble blue‐light photoreceptors. Given the large number of sequences now deposited in databases, it becomes meaningful to define a signature for bona fide LOV domains, a procedure that facilitates identification of proteins with new properties and phylogenetic analysis. The latter clearly evidences that a class of LOV proteins from alpha‐proteobacteria is the closest prokaryotic relative of eukaryotic LOV domains, whereas cyanobacterial sequences cluster with the archaeal and the other bacterial LOV domains. Distance trees built for LOV domains suggest complex evolutionary patterns, possibly involving multiple horizontal gene transfer events. Based on available data, the in vivo relevance and evolution of prokaryotic LOV is discussed.     

Solving Blue Light Riddles: New Lessons from Flavin‐binding LOV Photoreceptors

Detection of blue light (BL) via flavin‐binding photoreceptors (Fl‐Blues) has evolved throughout all three domains of life. Although the main BL players, that is light, oxygen and voltage (LOV), blue light sensing using flavins (BLUF) and Cry (cryptochrome) proteins, have been characterized in great detail with respect to structure and function, still several unresolved issues at different levels of complexity remain and novel unexpected findings were reported. Here, we review the most prevailing riddles of LOV‐based photoreceptors, for example: the relevance of water and/or small metabolites for the dynamics of the photocycle; molecular details of light‐to‐signal transduction events; the interplay of BL sensing by LOV domains with other environmental stimuli, such as BL plus oxygen‐mediating photodamage and its impact on microbial lifestyles; the importance of the cell or chromophore redox state in determining the fate of BL‐driven reactions; the evolutionary pathways of LOV‐based BL sensing and associated functions through the diverse phyla. We will discuss major novelties emerged during the last few years on these intriguing aspects of LOV proteins by presenting paradigmatic examples from prokaryotic photosensors that exhibit the largest complexity and richness in associated functions.     

Primary processes during the light-signal transduction of phototropin

Phototropin is a blue-light photoreceptor in plants that mediates phototropism, chloroplast relocation, stomata opening and leaf expansion. Phototropin molecule has two photoreceptive domains named LOV1 (light-oxygen-voltage) and LOV2 in the N-terminus and a serine/threonine kinase domain in the C-terminus, and acts as a blue light-regulated kinase. Each LOV domain binds a flavin mononucleotide as a chromophore and undergoes unique cyclic reactions upon blue-light absorption that comprises a cysteinyl-flavin adduct formation through a triplet-excited state and a successive adduct break to revert to the initial ground state. The molecular reactions underlying the photocycle are reviewed and one of the probable molecular schemes is presented. Adduct formation alters the secondary protein structure of the LOV domains. This structural change could be transferred to the linker between the kinase domain and involved in the photoregulation of the kinase activity. The structural changes as well as the oligomeric structures seem to differ between LOV1 and LOV2, which may explain the proposed roles of each domain in the photoregulation of the kinase activity. The photoregulation mechanism of phototropin kinase is reviewed and discussed in reference to the regulation mechanism of protein kinase A, which it resembles.     

Indication for a radical intermediate preceding the signaling state in the LOV domain photocycle

The blue light photoreceptor phototropin mediates crucial processes in plants leading to optimization of photosynthesis. Phototropin comprises two flavin mononucleotide-binding LOV (light-, oxygen-, or voltage-sensitive) domains. The LOV domains undergo a photocycle upon illumination, in which two intermediates have been detected by UV/Vis spectroscopy. The triplet excited state of flavin is formed and decays within a few microseconds into a photoadduct with an adjacent cysteine, which represents the signaling state of the LOV domain. For bond formation of the photoadduct, several reaction pathways have been proposed, but evidence for an intermediate at ambient conditions has not been found. Here, we performed nanosecond time-resolved UV/Vis spectroscopy on the phototropin-LOV1 domain from Chlamydomonas reinhardtii. We designed a flow cell which was used to efficiently replace the sample after each photoexcitation because the cycling time is in the order of hundreds of seconds. The comparison of difference spectra of the wild type with those of the C57S mutant that produces only the triplet excited state revealed the existence of an additional intermediate between the triplet and the adduct state. This intermediate exhibits spectral properties similar to a neutral flavin radical. This finding supports a reaction mechanism involving a neutral radical pair.     

Activation of the General Stress Response of Bacillus subtilis by Visible Light

A key challenge for microbiology is to understand how evolution has shaped the wiring of regulatory networks. This is amplified by the paucity of information of power‐spectra of physicochemical stimuli to which microorganisms are exposed. Future studies of genome evolution, driven by altered stimulus regimes, will therefore require a versatile signal transduction system that allows accurate signal dosing. Here, we review the general stress response of Bacillus subtilis, and its upstream signal transduction network, as a candidate system. It can be activated by red and blue light, and by many additional stimuli. Signal integration therefore is an intricate function of this system. The blue‐light response is elicited via the photoreceptor YtvA, which forms an integral part of stressosomes, to activate expression of the stress regulon of B. subtilis. Signal transfer through this network can be assayed with reporter enzymes, while intermediate steps can be studied with live‐cell imaging of fluorescently tagged proteins. Different parts of this system have been studied in vitro, such that its computational modeling has made significant progress. One can directly relate the microscopic characteristics of YtvA with activation of the general stress regulon, making this system a very well‐suited system for network evolution studies.