Mutational and structural studies of the PixD BLUF output signal that affects light-regulated interactions with PixE

PixD (Slr1694) is a BLUF (blue-light-using FAD) photoreceptor used by the cyanobacterium Synechocystis sp. PCC6803 to control phototaxis toward blue light. In this study, we probe the involvement of a conserved Tyr8-Gln50-Met93 triad in promoting an output signal upon blue light excitation of the bound flavin. Analysis of acrylamide quenching of Trp91 fluorescence shows that the side chain of this residue remains partially solvent exposed in both the lit and dark states. Mutational analysis demonstrates that substitution mutations at Tyr8 and Gln50 result in the loss of the photocycle while a mutation of Met93 does not appreciably disturb the formation of the light-excited state and only minimally accelerates its decay from 5.7 to 4.5 s. However, mutations of Tyr8, Gln50, and Met93 disrupt the ability of PixD dimers to interact with PixE to form a higher-order PixD(10)-PixE(5) complex, which is indicative of a lit conformational state. Solution nuclear magnetic resonance spectroscopy and X-ray crystallographic analyses confirm that a Tyr8 to Phe mutation is locked in a pseudo-light-excited state revealing flexible areas in PixD that likely constitute part of an output signal upon light excitation of wild-type PixD.     

A PixD--PapB Chimeric Protein Reveals the Function of the BLUF Domain C-Terminal α-Helices for Light Signal Transduction

Blue light-using flavin (BLUF) proteins form a subfamily of blue light photoreceptors, are found in many bacteria and algae, and are further classified according to their structures. For one type of BLUF-containing protein, e.g. PixD, the central axes of its two C-terminal α-helices are perpendicular to the β-sheet of its N-terminal BLUF domain. For another type, e.g. PapB, the central axes of its two C-terminal α-helices are parallel to its BLUF domain β-sheet. However, the functional significance of the different orientations with respect to phototransduction is not clear. For the study reported herein, we constructed a chimeric protein, Pix0522, containing the core of the PixD BLUF domain and the C-terminal region of PapB, including the two α-helices, and characterized its biochemical and spectroscopic properties. Fourier transform infrared spectroscopy detected similar light-induced conformational changes in the C-terminal α-helices of Pix0522 and PapB. Pix0522 interacts with and activates the PapB-interacting enzyme, PapA, demonstrating the functionality of Pix0522. These results provide direct evidence that the BLUF C-terminal α-helices function as an intermediary that accepts the flavin-sensed blue light signal and transmits it downstream during phototransduction.     

Tryptophan at position 104 is involved in transforming light signal into changes of beta-sheet structure for the signaling state in the BLUF domain of AppA

AppA is a member of an FAD-based new class blue-light sensory protein known as sensor of blue light using FAD (BLUF) protein. The spectroscopic properties of an AppA BLUF domain (AppA126), in which the tryptophan residue at position 104 had been replaced with alanine (W104A), were characterized. The W104A mutant AppA126 showed a nearly normal absorption red shift in the FAD UV-visible absorption upon illumination; however, the light state relaxed to the dark state at a rate approximately 150 times faster than that of wild-type AppA126. Light-induced structural changes of FAD and apoprotein in the wild-type and mutant AppA126 were studied by means of light-induced Fourier transform infrared (FTIR) difference spectroscopy using AppA126, in which the apoprotein had been selectively labeled with 13C. The light-induced FTIR spectrum of the W104A mutant AppA126 revealed bands corresponding to a C4 = O stretch of the FAD isoalloxazine ring and structural changes of apoprotein, but with some alterations in the bands' features. Notably, however, prominent protein bands at 1,632(+)/1,619(-) cm(-1) caused by changes in the beta-sheet structure were eliminated by the mutation, indicating that Trp104 is responsible for transforming the light signal into a specific beta-sheet structure change in the apoprotein of the AppA BLUF domain in the signaling state.     

Light-induced conformational change and transient dissociation reaction of the BLUF photoreceptor Synechocystis PixD (Slr1694)

The light-induced reaction of the BLUF (blue light photoreceptor using flavin adenine dinucleotide) photoreceptor PixD from Synechocystis sp. PCC6803 (Slr1694) was investigated using the time-resolved transient grating method. A conformational change coupled with a volume contraction of 13 mL mol^− 1 was observed with a time constant of 45 ms following photoexcitation. At a weak excitation light intensity, there were no further changes in volume and diffusion coefficient (D). The determined D-value (3.7 × 10^− 11 m² s^− 1) suggests that PixD exists as a decamer in solution, and this oligomeric state was confirmed by size-exclusion chromatography and blue native polyacrylamide gel electrophoresis. Surprisingly, by increasing the excitation laser power, we observed a large increase in D with a time constant of 350 ms following the volume contraction reaction. The D-value of this photoproduct species (7.5 × 10^− 11 m² s^− 1) is close to that of the PixD dimer. Combined with transient grating and size-exclusion chromatography measurements under light-illuminated conditions, the light-induced increase in D was attributed to a transient dissociation reaction of the PixD decamer to a dimer. For the M93A-mutated PixD, no volume or D-change was observed. Furthermore, we showed that the M93A mutant did not form the decamer but only the dimer in the dark state. These results indicate that the formation of the decamer and the conformational change around the Met residue are important factors that control the regulation of the downstream signal transduction by the PixD photoreceptor.     

Fate determination of the flavin photoreceptions in the cyanobacterial blue light receptor TePixD (Tll0078)

PixD (Tll0078, Slr1694) is a BLUF (sensor of blue light using FAD)-type blue light receptor protein of the thermophilic cyanobacterium Thermosynechococcus elongatus BP-1 and the mesophilic cyanobacterium Synechocystis sp. PCC 6803. BLUF protein is known to show light-induced approximately 10 nm red shift of flavin absorption that is coupled with strengthening of the hydrogen bond between the O(4) of the isoalloxazine ring and a certain amino acid residue. According to the 3D structure of TePixD we determined, O(4) of the ring is linked to Gln50 and Asn32. A survey of flavin-interacting residues by site-directed mutagenesis showed that Gln50 but not Asn32 is essential for the normal red-shifting photoreaction. Here, we further studied the role of Gln50 and its close neighbor Tyr8. All the mutated proteins of Gln50 and Tyr8 (Q50A, Q50N, Y8A and Y8F) lost the normal red-shifting photoreaction. Y8A, Y8F and Q50N, instead, showed a light-induced flavin triplet state and a low yield of subsequent flavin reduction that is analogous to the photocycle of the LOV (light-oxygen-voltage-sensing) domain of phototropins, while Q50A did not. Fourier-transform infrared (FT-IR) analysis of N32A showed that O(4) of the ring is hydrogen-bonded to Asn32 both in the light and dark. These results, together with the 3D structure, indicate that the hydrogen bond network of Tyr8-Gln50-O(4)/N(5) (flavin) is critical for the light reaction of the BLUF domain. Based on the structural and functional similarities of the BLUF and the LOV domain of phototropins, we propose that the interaction between apoprotein and N(5) of flavin determines the photoreaction of the flavin-binding sensors.     

Biochemical and functional characterization of BLUF-type flavin-binding proteins of two species of cyanobacteria

BLUF (a sensor of Blue-Light Using FAD) is a novel putative photoreceptor domain that is found in many bacteria and some eukaryotic algae. As found on genome analysis, certain cyanobacteria have BLUF proteins with a short C-terminal extension. As typical examples, Tll0078 from thermophilic Thermosynechococcus elongatus BP-1 and Slr1694 from mesophilic Synechocystis sp. PCC 6803 were comparatively studied. FAD of both proteins was hardly reduced by exogenous reductants or mediators except methylviologen but showed a typical spectral shift to a longer wavelength upon excitation with blue light. In particular, freshly prepared Tll0078 protein showed slow but reversible aggregation, indicative of light-induced conformational changes in the protein structure. Tll0078 is far more stable as to heat treatment than Slr1694, as judged from flavin fluorescence. The slr1694-disruptant showed phototactic motility away from the light source (negative phototaxis), while the wild type Synechocystis showed positive phototaxis toward the source. Yeast two-hybrid screening with slr1694 showed self-interaction of Slr1694 (PixD) with itself and interaction with a novel PatA-like response regulator, Slr1693 (PixE). These results were discussed in relation to the signaling mechanism of the "short" BLUF proteins in the regulation of cyanobacterial phototaxis.     

Crystal structures of the AppA BLUF domain photoreceptor provide insights into blue light-mediated signal transduction

Proteins containing a sensor of blue light using FAD (BLUF) domain control diverse cellular processes, such as gene expression, nucleotide metabolism and motility, by relaying blue light signals to distinct output units. Despite its crucial and widespread functions, the mechanism of BLUF signal transduction has remained elusive. We determined crystal structures of the dark-adapted state and of a photo-excited, red-shifted photocycle intermediate of the BLUF unit of AppA, a purple bacterial photoreceptor involved in the light-dependent regulation of photosynthesis gene expression. In contrast to a recently published crystal structure of the AppA BLUF domain determined in the presence of detergent molecules, our structural model of the dark state corresponds well to those reported for the BLUF domains of Tll0078 and BlrB. This establishes that a highly conserved methionine (Met106 in AppA) is next to the active site glutamine (Gln63 in AppA), which is of relevance for the latter's orientation in the dark state and for the mechanism of the photoreaction. The comparison of the dark-adapted and photointermediate state structures shows light-induced conformational alterations, which suggest a path for signal propagation. In particular, we observe a significant movement of the Met106 side-chain. Met106 thereby changes its mode of interaction with Gln63, which supports a light-dependent rotation of the latter. In view of other BLUF structures available, our data further suggest that the hydrogen bond between Asn45 and the backbone carbonyl of His105 breaks upon illumination. The ensuing extensive structural rearrangement of beta-strand 5 is predicted to involve a flip of Met106 out of the flavin-binding pocket and Trp104 moving in to fill the void. We propose that the blue light signal is transmitted towards the surface of the BLUF domain via His44, which serves as a reporter of active site changes.     

Structural requirements for key residues and auxiliary portions of a BLUF domain

BlrB in Rhodobacter sphaeroides is a single domain, flavin-based blue light sensor protein in the BLUF family of photoreceptors. Consistent with other members of this family, blue light excitation induces a putative signaling state characterized by a 10 nm red shift in the UV-visible absorbance spectrum. Structural and spectroscopic characterization of truncated BlrB constructs establishes that the C-terminal 50 amino acids of this protein are essential to its structural integrity despite not being part of the canonical BLUF domain architecture. Mutagenesis studies support the critical roles of Tyr9, Asn33, and Gln51 for flavin binding and the integrity of the BLUF domain fold. Comparison of solution NMR spectra of BlrB acquired under dark and light conditions indicates very limited light-dependent conformational changes except for a few interesting residues: Trp92, Met94, and Ile127. Notably, the Ile127 side chain experiences significant chemical shift changes despite the fact that it is far ( approximately 15 A) from the flavin chromophore in the C-terminal extension. These data suggest that the light-induced signal is propagated from the flavin through the beta sheet to the last two alpha helices in the C-terminal extension, potentially providing a mechanism to transmit this change to initiate a cellular response to blue light.     

Adenosine diphosphate moiety does not participate in structural changes for the signaling state in the sensor of blue-light using FAD domain of AppA

A sensor of blue light using FAD (BLUF) protein is a flavin adenine dinucleotide (FAD) based new class blue-light sensory flavoprotein. The BLUF domain of AppA was reconstituted in vitro from apoprotein and flavin adenine dinucleotide, flavin adenine mononucleotide or riboflavin. The light-induced FTIR spectra of the domain reconstituted from various flavins and the 13C-labeled apoprotein showed that identical light-induced structural changes occur in both the flavin chromophore and protein for the signaling state in all of the reconstituted holoproteins. The results showed that an adenosine 5'-dinucleotide moiety is not required for signaling-state formation in a BLUF domain.     

Light induced structural changes of a full-length protein and its BLUF domain in YcgF(Blrp), a blue-light sensing protein that uses FAD (BLUF)

Blue-light sensing proteins that use FAD (BLUF) are members of a blue-light receptor family that is widely distributed among microorganisms. The Escherichia coli YcgF protein is a BLUF protein consisting of the N-terminal FAD-binding hold (BLUF domain) and the C-terminal EAL domain. The EAL domain of YcgF is predicted to have cyclic-di-GMP phosphodiesterase activity. Light-induced structural changes for the signaling state formation were studied using the light-induced Fourier transform infrared (FTIR) difference spectroscopy of both the full-length YcgF protein (YcgF-Full) and its BLUF domain (YcgF-BLUF). YcgF-Full and YcgF-BLUF showed identical UV-visible absorption spectra of flavin in the dark state and a light-induced absorption red shift for the signaling state, which relaxed to the dark state showing identical kinetics. The light-induced FTIR difference spectrum of YcgF-Full, however, was markedly different from that of YcgF-BLUF. The spectrum of YcgF-BLUF lacked most of the IR bands that were induced in the YcgF-Full spectrum. These bands were assigned to the light-induced structural changes of the protein. However, the bands for the C4=O stretching of a FAD isoalloxazine ring were induced at the same frequency with the same band intensity in the spectra for YcgF-Full and YcgF-BLUF. Furthermore, the YcgF-Full spectrum resembled that of the YcgF-BLUF when illuminated at medium-low temperatures because of the selective suppression of protein bands. The possibility that full-length-specific protein bands are predominantly ascribed to structural changes of the C-terminal EAL domain in the signaling state as a consequence of light excitation of the N-terminal BLUF domain is discussed.     

Structure of a cyanobacterial BLUF protein, Tll0078, containing a novel FAD-binding blue light sensor domain

The sensor proteins for blue light using the FAD (BLUF) domain belong to the third family of the photoreceptor proteins using a flavin chromophore, where the other two families are phototropins and cryptochromes. As the first structure of this BLUF domain, we have determined the crystal structure of the Tll0078 protein from Thermosynechococcus elongatus BP-1, which contains a BLUF domain bound to FAD, at 2A resolution. Five Tll0078 monomers are located around the non-crystallographic 5-fold axis to form a pentamer, and two pentamers related by 2-fold non-crystallographic symmetry form a decameric assembly. The monomer consists of two domains, the BLUF domain at the N-terminal region and the C-terminal domain. The overall structure of the BLUF domain consists of a five-stranded mixed beta-sheet with two alpha-helices running parallel with it. The isoalloxazine ring of FAD is accommodated in a pocket formed by several highly conserved amino acid residues in the BLUF domain. Of these, the three apparent key residues (Asn31, Asn32 and Gln50) were substituted with Ala. Mutant proteins of N31A and N32A showed a nearly normal 10nm spectral shift of the flavin upon illumination, while the Q50A mutant did not exhibit such a shift at all. On the basis of the crystal structure, we discussed a possible role of Gln50, which is structurally and functionally linked with the critical Tyr8 (FAD-Gln50-Tyr8 network), with regard to the light-induced spectral shift of the BLUF proteins.     

Biochemical and physiological characterization of a BLUF protein-EAL protein complex involved in blue light-dependent degradation of cyclic diguanylate in the purple bacterium Rhodopseudomonas palustris

Organisms adapt their physiologies in response to the quality and quantity of environmental light. Members of a recently identified photoreceptor protein family, BLUF domain proteins, use a flavin chromophore to sense blue light. Herein, we report that PapB, which contains a BLUF domain, controls the biofilm formation of the purple photosynthetic bacterium Rhodopseudomonas palustris. Purified PapB undergoes a typical BLUF-type photocycle, and light-excited PapB enhances the phosphodiesterase activity of the EAL domain protein, PapA, which degrades the second messenger, cyclic dimeric GMP (c-di-GMP). PapB directly interacts with PapA in vitro in a light-independent manner and induces a conformational change in the preformed PapA-PapB complex. A PapA-PapB docking simulation, as well as a site-directed mutagenesis study, identified amino acids partially responsible for the interaction between the PapA EAL domain and the two C-terminal α-helices of the PapB BLUF domain. Thus, the conformational change, which involves the C-terminal α-helices, transfers the flavin-sensed blue light signal to PapA. Deletion of papB in R. palustris enhances biofilm formation under high-intensity blue light conditions, indicating that PapB functions as a blue light sensor, which negatively regulates biofilm formation. These results demonstrate that R. palustris can control biofilm formation via a blue light-dependent modulation of its c-di-GMP level by the BLUF domain protein, PapB.     

A LOV protein modulates the physiological attributes of Xanthomonas axonopodis pv. citri relevant for host plant colonization

Recent studies have demonstrated that an appropriate light environment is required for the establishment of efficient vegetal resistance responses in several plant-pathogen interactions. The photoreceptors implicated in such responses are mainly those belonging to the phytochrome family. Data obtained from bacterial genome sequences revealed the presence of photosensory proteins of the BLUF (Blue Light sensing Using FAD), LOV (Light, Oxygen, Voltage) and phytochrome families with no known functions. Xanthomonas axonopodis pv. citri is a Gram-negative bacterium responsible for citrus canker. The in silico analysis of the X. axonopodis pv. citri genome sequence revealed the presence of a gene encoding a putative LOV photoreceptor, in addition to two genes encoding BLUF proteins. This suggests that blue light sensing could play a role in X. axonopodis pv. citri physiology. We obtained the recombinant Xac-LOV protein by expression in Escherichia coli and performed a spectroscopic analysis of the purified protein, which demonstrated that it has a canonical LOV photochemistry. We also constructed a mutant strain of X. axonopodis pv. citri lacking the LOV protein and found that the loss of this protein altered bacterial motility, exopolysaccharide production and biofilm formation. Moreover, we observed that the adhesion of the mutant strain to abiotic and biotic surfaces was significantly diminished compared to the wild-type. Finally, inoculation of orange (Citrus sinensis) leaves with the mutant strain of X. axonopodis pv. citri resulted in marked differences in the development of symptoms in plant tissues relative to the wild-type, suggesting a role for the Xac-LOV protein in the pathogenic process. Altogether, these results suggest the novel involvement of a photosensory system in the regulation of physiological attributes of a phytopathogenic bacterium. A functional blue light receptor in Xanthomonas spp. has been described for the first time, showing an important role in virulence during citrus canker disease.     

Structural Refinement of a Key Tryptophan Residue in the BLUF Photoreceptor AppA by Ultraviolet Resonance Raman Spectroscopy

The flavin-adenine-dinucleotide-binding BLUF domain constitutes a new class of blue-light receptors, and the N-terminal domain of AppA is a representative of this family. The BLUF domain is of special interest because it uses a rigid flavin rather than an isomerizable chromophore, such as a rhodopsin or phytochrome, for its light-activation process. Crystal and solution structures of several BLUF domains were recently obtained, and their overall structures are consistent. However, there is a key ambiguity regarding the position of a conserved tryptophan (Trp-104 in AppA), in that this residue was found either close to flavin (Trp_in conformation) or exposed to the solvent (Trp_out conformation). The location of Trp-104 is a crucial factor in understanding the photocycle mechanism of BLUF domains, because this residue has been shown to play an essential role in the activation of AppA. In this study, we demonstrated a Trp_in conformation for the BLUF domain of AppA through direct observation of the vibrational spectrum of Trp-104 by ultraviolet resonance Raman spectroscopy, and also observed light-induced conformational and environmental changes in Trp-104. This study provides a structural basis for future investigations of the photocycle mechanism of BLUF proteins.     

The critical role of a hydrogen bond between Gln63 and Trp104 in the blue-light sensing BLUF domain that controls AppA activity

AppA is a novel blue-light receptor that controls photosynthetic gene expression in the purple bacterium Rhodobacter sphaeroides. The photocycle reaction of the light-sensing domain, BLUF, is unique in the sense that a few hydrogen bond rearrangements are accompanied by only slight structural changes of the bound chromophore. However, the exact features of the hydrogen bond network around the active site are still the subject of some controversy. Here we present biochemical and genetic evidence showing that either Gln63 or Trp104 in the active site of the BLUF domain is crucial for light sensing, which in turn controls the antirepressor activity of AppA. Specifically, the Q63L and W104A mutants of AppA are insensitive to blue light in vivo and in vitro, and their activity is similar to that of the light-adapted wild-type AppA. Based on spectroscopic and structural information described previously, we conclude that light-dependent formation and breakage of the hydrogen bond between Gln63 and Trp104 are critical for the light-sensing mechanism of AppA.     

Photoreactions of Tyr8- and Gln50-mutated BLUF domains of the PixD protein of Thermosynechococcus elongatus BP-1: photoconversion at low temperature without Tyr8

We studied the photoreaction of a blue-light sensor PixD protein of Thermosynechococcus elongatus that has the blue-light-using flavin (BLUF) domain. The Tyr8 and Gln50 residues of the protein were modified to phenylalanine, alanine, or asparagine (Y8F, Y8A, Q50N, and Q50A) by site-directed mutagenesis. The following results were obtained. (1) At room temperature, blue-light illumination induced the red shift of the absorption bands of flavin in the wild-type (WT) protein but not in the Y8F, Y8A, Q50A, and Q50N mutant proteins, as reported [Okajima, K., et al. (2006) J. Mol. Biol. 363, 10-18]. (2) At 80 K, neither the Q50N nor the Q50A mutant protein accumulated the red-shifted form. (3) At 80 K, the Y8F protein photoaccumulated the red-shifted forms to an extent that was half that in the WT protein at a 43-fold slower rate, and the Y8A protein to the one-fourth the extent at a 137-fold slower rate. (4) The red-shifted form in the Y8F protein was stable below 240 K and became unstable above 240 K in the dark. (5) The illumination of the Y8F protein at 150 K accumulated the red-shifted form at the beginning, and the prolonged illumination accumulated the flavin anions by the secondary photoreaction. (6) The results indicate that Tyr8 is not indispensable for the accumulation of the red-shifted form at least at 80 K. (7) Photoconversion mechanisms in the WT and Tyr8-mutated proteins are discussed in relation to the schemes with and without the electron transfer between Tyr8 and flavin in the first step of the photoconversion.     

Coupling between the BLUF and EAL domains in the blue light-regulated phosphodiesterase BlrP1

The first biochemical and structural characterization of the full-length active photoreceptor BlrP1 from Klebsiella pneumoniae was recently reported by Barends et al. [Nature 459:1015–1018, (2009)]. The light-regulated catalytic function of its C-terminal c-di-guanosine monophosphate phosphodiesterase, the EAL (Glu-Ala-Leu) domain, is activated by the N-terminal sensor of blue light using the flavin adenine dinucleotide (BLUF) domain. We performed molecular dynamics simulations on the dimeric BlrP1 protein in order to examine the coupling regions that are presumably involved in transmitting light-induced structural changes which occur in the BLUF domain to the EAL domain. According to the results of simulations and an analysis of the hydrogen bonding between the respective polypeptide chains, the region containing the site on the α3α4 loop of BLUF is responsible for communication between the photosensing and catalytic domains in the dimeric BlrP1 protein.