Cyanobacteriochromes from Gloeobacterales Provide New Insight into the Diversification of Cyanobacterial Photoreceptors.

The phytochrome superfamily comprises three groups of photoreceptors sharing a conserved GAF (cGMP-specific phosphodiesterases, cyanobacterial adenylate cyclases, and formate hydrogen lyase transcription activator FhlA) domain that uses a covalently attached linear tetrapyrrole (bilin) chromophore to sense light. Knotted red/far-red phytochromes are widespread in both bacteria and eukaryotes, but cyanobacteria also contain knotless red/far-red phytochromes and cyanobacteriochromes (CBCRs). Unlike typical phytochromes, CBCRs require only the GAF domain for bilin binding, chromophore ligation, and full, reversible photoconversion. CBCRs can sense a wide range of wavelengths (ca. 330-750 nm) and can regulate phototaxis, second messenger metabolism, and optimization of the cyanobacterial light-harvesting apparatus. However, the origins of CBCRs are not well understood: we do not know when or why CBCRs evolved, or what selective advantages led to retention of early CBCRs in cyanobacterial genomes. In the current work, we use the increasing availability of genomes and metagenome-assembled-genomes from early-branching cyanobacteria to explore the origins of CBCRs. We reaffirm the earliest branches in CBCR evolution. We also show that early-branching cyanobacteria contain late-branching CBCRs, implicating early appearance of CBCRs during cyanobacterial evolution. Moreover, we show that early-branching CBCRs behave as integrators of light and pH, providing a potential unique function for early CBCRs that led to their retention and subsequent diversification. Our results thus provide new insight into the origins of these diverse cyanobacterial photoreceptors.

Light sensing and responses in fungi.

Light controls important physiological and morphological responses in fungi. Fungi can sense near-ultraviolet, blue, green, red and far-red light using up to 11 photoreceptors and signalling cascades to control a large proportion of the genome and thereby adapt to environmental conditions. The blue-light photoreceptor functions directly as a transcriptional regulator in the nucleus, whereas the red-light-sensing and far-red-light-sensing phytochrome induces a signalling pathway to transduce the signal from the cytoplasm to the nucleus. Green light can be sensed by retinal-binding proteins, known as opsins, but the signalling mechanisms are not well understood. In this Review, we discuss light signalling processes in fungi, their signalling cascades and recent insights into the integration of light signalling pathways with other regulatory circuits in fungal cells.

Aureochromes - Blue Light Receptors.

A variety of living organisms including bacteria, fungi, animals, and plants use blue light (BL) to adapt to changing ambient light. Photosynthetic forms (plants and algae) require energy of light for photosynthesis, movements, development, and regulation of activity. Several complex light-sensitive systems evolved in eukaryotic cells to use the information of light efficiently with photoreceptors selectively absorbing various segments of the solar spectrum, being the first components in the light signal transduction chain. They are most diverse in algae. Photosynthetic stramenopiles, which received chloroplasts from red algae during secondary symbiosis, play an important role in ecosystems and aquaculture, being primary producers. These taxa acquired the ability to use BL for regulation of such processes as phototropism, chloroplast photo-relocation movement, and photomorphogenesis. A new type of BL receptor - aureochrome (AUREO) - was identified in Vaucheria frigida in 2007. AUREO consists of two domains: bZIP (basic-region leucine zipper) domain and LOV (light-oxygen-voltage-sensing) domain, and thus this photoreceptor is a BL-sensitive transcription factor. This review presents current data on the structure, mechanisms of action, and biochemical features of aureochromes.

Light regulates motility, attachment and virulence in the plant pathogen Pseudomonas syringae pv tomato DC3000.

Pseudomonas syringae pv tomato DC3000 (Pto) is the causal agent of the bacterial speck of tomato, which leads to significant economic losses in this crop. Pto inhabits the tomato phyllosphere, where the pathogen is highly exposed to light, among other environmental factors. Light represents a stressful condition and acts as a source of information associated with different plant defence levels. Here, we analysed the presence of both blue and red light photoreceptors in a group of Pseudomonas. In addition, we studied the effect of white, blue and red light on Pto features related to epiphytic fitness. While white and blue light inhibit motility, bacterial attachment to plant leaves is promoted. Moreover, these phenotypes are altered in a blue-light receptor mutant. These light-controlled changes during the epiphytic stage cause a reduction in virulence, highlighting the relevance of motility during the entry process to the plant apoplast. This study demonstrated the key role of light perception in the Pto phenotype switching and its effect on virulence.

Distance-tree analysis, distribution and co-presence of bilin- and flavin-binding prokaryotic photoreceptors for visible light.

In recent years it has become increasingly evident that prokaryotic organisms can sense and react to light stimuli via a variety of photosensory receptors and signal transduction pathways. There are two main superfamilies of non-membrane-bound photoreceptors: the bilin-binding phytochrome-related proteins based on GAF (cGMP-specific phosphodiesterases, cyanobacterial adenylate cyclases, and transcription activator FhlA) domains (bilin-GAF proteins), and the flavin-binding proteins (FL-Blues), photoperceptive thanks to their LOV (Light, Oxygen and Voltage) and BLUF (Blue Light sensing Using Flavins) domains. In this manuscript we present a comprehensive scenario of the existence of bilin-GAF, LOV and BLUF proteins in the prokaryotic world and inspect possible phylogenetic pathways, also defining novel criteria for identifying gene (and protein) sequences based on experimentally assessed photochemical events. As a whole we have inspected almost 2000 proteins recovered in 985 bacteria and 16 archaea. For LOV and BLUF proteins, ten and, respectively, twelve superconserved amino acids have been identified, which were used as criterion for selection. A similarly strict parameter cannot be applied to the more variegate family of bilin-GAF domains. The co-presence of bilin-GAF and FL-Blues occurs in 22% of the analyzed bacteria, with emphasis on the bilin-GAF/LOV co-presence in cyanobacteria and of bilin-GAF/BLUF in the Bacteroidetes/Chlorobi group. For construction of phylogeny/distance-trees we used the neighboring-method to obtain a branching pattern, limited to photosensing domains. We observed that in many cases organisms belonging to the same phylum are neighbors, but clustering mostly occurs according to the type of functional domain associated with the photosensing modules.

The growing family of photoactive yellow proteins and their presumed functional roles.

For several years following the discovery and characterization of the first PYP, from Halorhodospira halophila, it was thought that this photoactive protein was quite unique, notwithstanding the isolation of two additional examples in rapid succession. Mainly because of genomic and metagenomic analyses, we have now learned that more than 140 PYP genes occur in a wide variety of bacteria and metabolic niches although the protein has not been isolated in most cases. The amino acid sequences and physical properties permit their organization into at least seven groups that are also likely to be functionally distinct. Based upon action spectra and the wavelength of maximum absorbance, it was speculated nearly 20 years ago but never proven that Hr. halophila PYP was involved in phototaxis. Nevertheless, in only one instance has the functional role and interaction partner for a PYP been experimentally proven, in Rs. centenum Ppr. Genetic context is one of several types of evidence indicating that PYP is potentially involved in a number of diverse functional roles. The interaction with other sensors to modulate their activity stands out as the single most prominent role for PYP. In this review, we have attempted to summarize the evidence for the functional roles and interaction partners for some 26 of the 35 named species of PYP, which should be considered the basis for further focused molecular and biochemical research.

Phototaxis in the cyanobacterium Synechocystis sp. PCC 6803: role of different photoreceptors.

The second cyanobacterial phytochrome Cph2 from Synechocystis sp. PCC 6803 was suggested as a part of a light-stimulated signal transduction chain inhibiting movement toward blue light. Cph2 has the two bilin binding sites, cysteine-129 and cysteine-1022, that might be involved in sensing of red/far-red and blue light, respectively. Here, we present data on wavelength dependence of the phototaxis inhibition under blue light, indicating that Cph2 itself is the photoreceptor for this blue light response. We found that inhibition of blue-light phototaxis in wild-type cells occurred below the transition point of about 470 nm. Substitution of cysteine-1022 with valine led to photomovement of the cells toward blue light (cph2(-) mutant phenotype). Analysis of mutants lacking cysteine-129 in the N-terminal chromophore binding domain indicated that this domain is also important for Cph2 function or folding of the protein. Furthermore, putative blue-light and phytochrome-like photoreceptors encoded by the Synechocystis sp. PCC 6803 genome were inactivated in wild-type and cph2 knockout mutant background. Our results suggest that none of these potential photoreceptors interfere with Cph2 function, although inactivation of taxD1 as well as slr1694 encoding a BLUF protein led to cells that reversed the direction of movement under blue light illumination in mutant strains of cph2.

Circular dichroism of the photoreceptor pigment oxyblepharismin.

Circular dichroism (CD) was used to study the structure of oxyblepharismin (OxyBP), the photoreceptor chromophore for the photophobic response of the blue form of Blepharisma japonicum. Both the chromophore associated to its native protein and the free chromophore in ethanol solution were investigated. CD spectra in the far-UV range indicate that OxyBP induces a slight increase in the alpha-helix content of the protein matrix. CD spectra in the near-UV and visible region of the spectrum show that OxyBP adopts a chiral conformation with a preferential geometry not only when associated to its protein matrix, but also when isolated and dissolved in ethanol. This experimental result is related to the existence of a high-energy interconversion barrier between two enantiomeric structures of the molecule and discussed on the basis of an asymmetric biosynthesis of its precursor, blepharismin.

Stark spectroscopy on photoactive yellow protein, E46Q, and a nonisomerizing derivative, probes photo-induced charge motion.

The change in the electrostatic properties on excitation of the cofactor of wild-type photoactive yellow protein (WT-PYP) have been directly determined using Stark-effect spectroscopy. We find that, instantaneously on photon absorption, there is a large change in the permanent dipole moment, /Delta(-->)mu/, (26 Debye) and in the polarizability, (-)Deltaalpha, (1000 A(3)). We expect such a large degree of charge motion to have a significant impact on the photocycle that is associated with the important blue-light negative phototactic response of Halorhodospira halophila. Furthermore, changing E46 to Q in WT-PYP does not significantly alter its electrostatic properties, whereas, altering the chromophore to prevent it from undergoing trans-cis isomerization results in a significant diminution of /Delta(-->)mu/ and (-)Deltaalpha. We propose that the enormous charge motion that occurs on excitation of 4-hydroxycinnamyl thioester, the chromophore in WT-PYP, plays a crucial role in initiating the photocycle by translocation of the negative charge, localized on the phenolate oxygen in the ground state, across the chromophore. We hypothesize that this charge motion would consequently increase the flexibility of the thioester tail thereby decreasing the activation barrier for the rotation of this moiety in the excited state.