Cyanobacteriochromes (CBCRs) are cyanobacterial members of the phytochrome superfamily of photosensors. Like phytochromes, CBCRs convert between two photostates by photoisomerization of a covalently bound linear tetrapyrrole (bilin) chromophore. Although phytochromes are red/far-red sensors, CBCRs exhibit diverse photocycles spanning the visible spectrum and the near-UV (330-680 nm). Two CBCR subfamilies detect near-UV to blue light (330-450 nm) via a "two-Cys photocycle" that couples bilin 15Z/15E photoisomerization with formation or elimination of a second bilincysteine adduct. On the other hand, mechanisms for tuning the absorption between the green and red regions of the spectrum have not been elucidated as of yet. CcaS and RcaE are members of a CBCR subfamily that regulates complementary chromatic acclimation, in which cyanobacteria optimize light-harvesting antennae in response to green or red ambient light. CcaS has been shown to undergo a green/red photocycle: reversible photoconversion between a green-absorbing 15Z state ( 15Z P g ) and a red-absorbing 15E state ( 15E P r ). We demonstrate that RcaE from Fremyella diplosiphon undergoes the same photocycle and exhibits light-regulated kinase activity. In both RcaE and CcaS, the bilin chromophore is deprotonated as 15Z P g but protonated as 15E P r . This change of bilin protonation state is modulated by three key residues that are conserved in green/red CBCRs. We therefore designate the photocycle of green/red CBCRs a "protochromic photocycle," in which the dramatic change from green to red absorption is not induced by initial bilin photoisomerization but by a subsequent change in bilin protonation state.light sensing | phycobiliprotein | signal transduction | spectral tuning | two-component signaling P hytochrome photosensors initially were discovered in plants and later found in cyanobacteria, nonoxygenic photosynthetic bacteria, nonphotosynthetic bacteria, fungi, and algae (1, 2). These photoreceptors bind linear tetrapyrrole (bilin) chromophores within a conserved GAF (cGMP phosphodiesterase/adenylyl cyclase/FhlA) domain via a covalent thioether linkage to a conserved Cys residue (Fig. S1A)(3-6). Upon illumination, phytochromes reversibly convert between a red-absorbing dark state and a far-red-absorbing photoproduct. This red/far-red photocycle is triggered by photoisomerization of the bilin 15,16-double bond between the 15Z and 15E configurations (7,8), with 15Z giving red absorption and 15E far-red absorption (4, 6, 9). In phytochromes, the conjugated π system of the bilin is protonated in both photostates, and this protonation is necessary to maintain the red and far-red absorption (10-12). Conserved GAF residues supply a hydrogen bond network to tune the chemical and spectral properties of the bilin (Fig. S1B).* Cyanobacteriochromes (CBCRs) are widespread cyanobacterial photosensors with phytochrome-related GAF domains (1,2,13,14). Although CBCRs also convert between two photostates via bilin photoisomerization at C15, they exhibit much more spe...
The cyanobacterial phototaxis regulator protein, TePixJ, is a member of the subfamily of cyanobacteriochromes that binds phycoviolobilin (PVB) as a chromophore and exhibits reversible photoconversion between blue light-absorbing (Pb) and green light-absorbing (Pg) forms. We reconstituted the PVB-binding photoactive holocomplex in vivo and in vitro. Coexpression of the apoprotein and phycocyanobilin (PCB) in Escherichia coli (in vivo reconstitution) produced a mixture of the PCB-bound and PVB-bound holoproteins. Reconstitution in vitro of the apoprotein and synthetic PCB quickly generated a photoactive complex, which covalently bound PCB and exhibited partially reversible photoconversion between two species by UV-vis spectroscopy (with a λ(max) values of 430 and 545 nm). Further incubation produced slow isomerization of PCB to PVB with concomitant improvement of photoreactivity. Site-directed mutagenesis confirmed that Cys522, and a second conserved Cys (Cys494), are both essential for the assembly of the photoactive complex. Fourier transform infrared (FTIR) spectroscopy revealed green light-induced cross-linking, and blue light-induced release, of a thiol group, possibly that of Cys494. These results suggest that the Pb/Pg-type cyanobacteriochrome TePixJ is assembled in at least three steps: (i) rapid and stable chromophorylation of PCB, (ii) additional photoreversible chromophorylation, and (iii) subsequent slow isomerization of PCB to PVB. In addition to its known autolyase activity with Cys522 and photoreversible isomerase activity (of the Z and E isomers at C15 and C16 of PCB), the GAF domain of TePixJ therefore appears to have other roles: as an isomerase (converting PCB to PVB) and as a photoreversible autolyase with a second conserved Cys residue.
The widely distributed phytochrome photoreceptors carry a bilin chromophore, which is covalently attached to the protein during a lyase reaction. In plant phytochromes, the natural chromophore is coupled by a thioether bond between its ring A ethylidene side chain and a conserved cysteine residue within the so-called GAF domain of the protein. Many bacterial phytochromes carry biliverdin as natural chromophore, which is coupled in a different manner to the protein. In phytochrome Agp1 of Agrobacterium tumefaciens, biliverdin is covalently attached to a cysteine residue close to the N terminus (position 20). By testing different natural and synthetic biliverdin derivatives, it was found that the ring A vinyl side chain is used for chromophore attachment. Only those bilins that have ring A vinyl side chain were covalently attached, whereas bilins with an ethylidene or ethyl side chain were bound in a noncovalent manner. Phycocyanobilin, which belongs to the latter group, was however covalently attached to a mutant in which a cysteine was introduced into the GAF domain of Agp1 (position 249). It is proposed that the regions around positions 20 and 249 are in close contact and contribute both to the chromophore pocket. In competition experiments it was found that phycocyanobilin and biliverdin bind with similar strength to the wild type protein. However, in the V249C mutant, phycocyanobilin bound much more strongly than biliverdin. This finding could explain why during phytochrome evolution in cyanobacteria, the chromophore-binding site swapped from the N terminus into the GAF domain.Phytochromes are biliprotein photoreceptors that were discovered in plants (1) but were recently also found in bacteria (2-4), fungi (5), and slime molds (6). The photocycle of phytochromes has two long-lived forms, the red-absorbing form (Pr), 1
Phytochrome photoreceptors undergo reversible photoconversion between the red-absorbing form, Pr, and the far-red-absorbing form, Pfr. The first step in the conversion from Pr to Pfr is a Z to E isomerization around the C15؍C16 double bond of the bilin chromophore. We prepared four synthetic biliverdin (BV) derivatives in which rings C and D are sterically locked by cyclizing with an additional carbon chain. In these chromophores, which are termed 15Za, 15Zs, 15Ea, and 15Es, the C15؍C16 double bond is in either the Z or E configuration and the C14 -C15 single bond in either the syn or anti conformation. The chromophores were assembled with Agrobacterium phytochrome Agp1, which incorporates BV as natural chromophore. All locked BV derivatives bound covalently to the protein and formed adducts with characteristic spectral properties. The 15Za adduct was spectrally similar to the Pr form and the 15Ea adduct similar to the Pfr form of the BV adduct. Thus, the chromophore of Agp1 adopts a C15؍C16 Z configuration and a C14 -C15 anti conformation in the Pr form and a C15؍C16 E configuration and a C14 -C15 anti conformation in the Pfr form. Both the 15Zs and the 15Es adducts absorbed only in the blue region of the visible spectra. All chromophore adducts were analyzed by size exclusion chromatography and histidine kinase activity to probe for protein conformation. In either case, the 15Za adduct behaved like the Pr and the 15Ea adduct like the Pfr form of Agp1. Replacing the natural chromophore by a locked 15Ea derivative can thus bring phytochrome holoprotein in the Pfr form in darkness. In this way, physiological action of Pfr can be studied in vivo and separated from Pr/Pfr cycling and other light effects.Phytochromes are photoreceptors of plants, bacteria, and fungi with a bilin chromophore that absorb light in the red and far-red region (1). The natural chromophore differs between species: land plants use phytochromobilin (2) and cyanobacteria use phycocyanobilin (3), whereas other bacteria use biliverdin (BV) 1 (4). The natural chromophore attaches covalently to a cysteine residue by an autocatalytical process, although in vitro adducts with non-covalently bound chromophores may also be spectrally active (5, 6). Agrobacterium phytochrome Agp1, which is used in the present study, belongs to the BV binding phytochromes and attaches its chromophore to Cys-20 (5, 7) via the ring A vinyl side chain of BV (8). Upon assembly, the red absorption maximum ( max ) of the chromophore shifts toward a longer wavelength, accompanied by an absorbance increase, to form the red-absorbing Pr. Light absorption of Pr initiates photoconversion into the Pfr form, which results in a further ϳ50 -70-nm red shift of max . Light absorption of Pfr initiates the reverse photoconversion into Pr. For plant phytochromes it has been shown that the first step of the Pr to Pfr photoconversion is a Z to E isomerization of the chromophore around the C15ϭC16 double bond (9), which occurs in the picosecond time scale (10, 11). Isomerization is ...
Agp1 is a canonical biliverdin-binding bacteriophytochrome from the soil bacterium Agrobacterium fabrum that acts as a light-regulated histidine kinase. Crystal structures of the photosensory core modules (PCMs) of homologous phytochromes have provided a consistent picture of the structural changes that these proteins undergo during photoconversion between the parent red light-absorbing state (Pr) and the far-red light-absorbing state (Pfr). These changes include secondary structure rearrangements in the so-called tongue of the phytochromespecific (PHY) domain and structural rearrangements within the long ␣-helix that connects the cGMP-specific phosphodiesterase, adenylyl cyclase, and FhlA (GAF) and the PHY domains. We present the crystal structures of the PCM of Agp1 at 2.70 Å resolution and of a surface-engineered mutant of this PCM at 1.85 Å resolution in the dark-adapted Pr states. Whereas in the mutant structure the dimer subunits are in anti-parallel orientation, the wild-type structure contains parallel subunits. The relative orientations between the PAS-GAF bidomain and the PHY domain are different in the two structures, due to movement involving two hinge regions in the GAF-PHY connecting ␣-helix and the tongue, indicating pronounced structural flexibility that may give rise to a dynamic Pr state. The resolution of the mutant structure enabled us to detect a sterically strained conformation of the chromophore at ring A that we attribute to the tight interaction with Pro-461 of the conserved PRXSF motif in the tongue. Based on this observation and on data from mutants where residues in the tongue region were replaced by alanine, we discuss the crucial roles of those residues in Pr-to-Pfr photoconversion.
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