Proteins containing GGDEF domains are encoded in the majority of sequenced bacterial genomes. In several species, these proteins have been implicated in biosynthesis of exopolysaccharides, formation of biofilms, establishment of a sessile lifestyle, surface motility, and regulation of gene expression. However, biochemical activities of only a few GGDEF domain proteins have been tested. These proteins were shown to be involved in either synthesis or hydrolysis of cyclic-bis(335) dimeric GMP (c-di-GMP) or in hydrolysis of cyclic AMP. To investigate specificity of the GGDEF domains in Bacteria, six GGDEF domain-encoding genes from randomly chosen representatives of diverse branches of the bacterial phylogenetic tree, i.e., Thermotoga, DeinococcusThermus, Cyanobacteria, spirochetes, and ␣ and ␥ divisions of the Proteobacteria, were cloned and overexpressed. All recombinant proteins were purified and found to possess diguanylate cyclase (DGC) activity involved in c-di-GMP synthesis. The individual GGDEF domains from two proteins were overexpressed, purified, and shown to possess a low level of DGC activity. The oligomeric states of full-length proteins and individual GGDEF domains were similar. This suggests that GGDEF domains are sufficient to encode DGC activity; however, enzymatic activity is highly regulated by the adjacent sensory protein domains. It is shown that DGC activity of the GGDEF domain protein Rrp1 from Borrelia burgdorferi is strictly dependent on phosphorylation status of its input receiver domain. This study establishes that majority of GGDEF domain proteins are c-di-GMP specific, that c-di-GMP synthesis is a wide-spread phenomenon in Bacteria, and that it is highly regulated.
Light is an essential environmental factor, and many species have evolved the capability to respond to it. Blue light is perceived through three flavin-containing photoreceptor families: cryptochromes, light-oxygen-voltage, and BLUF (sensor of blue light using flavin adenine dinucleotide, FAD) domain proteins. BLUF domains are present in various proteins from Bacteria and lower Eukarya. They are fully modular and can relay signals to structurally and functionally diverse output units, most of which are implicated in nucleotide metabolism. We present the high resolution crystal structure of the dark resting state of BlrB, a short BLUF domain-containing protein from Rhodobacter sphaeroides. The structure reveals a previously uncharacterized FAD-binding fold. Along with other lines of evidence, it suggests mechanistic aspects for the photocycle that is characterized by a red-shifted absorbance of the flavin. The isoalloxazine ring of FAD binds in a cleft between two helices, whereas the adenine ring points into the solvent. We propose that the adenine ring serves as a hook mediating the interaction with its effector͞output domain. The structure suggests a unique photochemical signaling switch in which the absorption of light induces a structural change in the rim surrounding the hook, thereby changing the protein interface between BLUF and the output domain.blue light sensing ͉ photochemistry ͉ protein function ͉ flavin ͉ reaction mechanism
Bacteriophytochromes are bacterial photoreceptors that sense red/far red light using the biliverdin chromophore. Most bacteriophytochromes work as photoactivated protein kinases. The Rhodobacter sphaeroides bacteriophytochrome BphG1 is unconventional in that it has GGDEF and EAL output domains, which are involved, respectively, in synthesis (diguanylate cyclase) and degradation (phosphodiesterase) of the bacterial second messenger c-di-GMP. The GGDEF-EAL proteins studied to date displayed either diguanylate cyclase or phosphodiesterase activity but not both. To elucidate the function of BphG1, the holoprotein was purified from an Escherichia coli overexpression system designed to produce biliverdin. The holoprotein contained covalently bound biliverdin and interconverted between the red (dark) and far red (light-activated) forms. BphG1 had c-di-GMP-specific phosphodiesterase activity. Unexpectedly for a photochromic protein, this activity was essentially light-independent. BphG1 expressed in E. coli was found to undergo partial cleavage into two species. The smaller species was identified as the EAL domain of BphG1. It possessed c-di-GMP phosphodiesterase activity. Surprisingly, the larger species lacking EAL possessed diguanylate cyclase activity, which was dependent on biliverdin and strongly activated by light. BphG1 therefore is the first phytochrome with a non-kinase photoactivated enzymatic activity. This shows that the photosensory modules of phytochromes can transmit light signals to various outputs. BphG1 is potentially the first "bifunctional" enzyme capable of both c-di-GMP synthesis and hydrolysis. A model for the regulation of the "opposite" activities of BphG1 is presented.The genome of the anoxygenic phototrophic bacterium Rhodobacter sphaeroides 2.4.1 contains two highly similar (97% identity) proteins, RSP4191 (located in plasmid 2.4.1d) and RSP4111 (located in plasmid 2.4.1c), with an unusual domain architecture (Fig. 1A). Each is composed of the PAS-GAF-PHY photosensory module, typically present in phytochromes, linked to the unconventional GGDEF-EAL output module (Fig. 1B).Phytochromes represent one of the six principal classes of photoreceptors identified thus far (1). In plants, phytochromes mediate light-dependent growth and development (reviewed in Ref.2). In bacteria, phytochromes regulate biosynthesis of photosynthetic and nonphotosynthetic pigments (3-6) and motility (7). Most phytochromes covalently bind a linear tetrapyrrole, bilin, and function as receptors of red/far red light (for a recent review, see Ref. 8). Their photoreception is based on the ability of the bilin chromophore to undergo reversible conversion between the red-absorbing (P r ) 2 and far red-absorbing (P fr ) forms (9). Phytochromes from bacteria, except for some phytochromes from cyanobacteria, bind biliverdin (BV) and are known as bacteriophytochromes (Bphs) (6).The N-terminal photoreception modules of Bphs incorporate all features required for chromophore binding and for photoconversion. A photoreception module ...
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Methylotrophic yeasts such as Ogataea polymorpha and Komagataella phaffii (sin. Hansenula polymorpha and Pichia pastoris, respectively) are commonly used in basic research and biotechnological applications, frequently those requiring genome modifications. However, the CRISPR-Cas9 genome editing approaches reported for these species so far are relatively complex and laborious. In this work we present an improved plasmid vector set for CRISPR-Cas9 genome editing in methylotrophic yeasts. This includes a plasmid encoding Cas9 with a nuclear localization signal and plasmids with a scaffold for the single guide RNA (sgRNA). Construction of a sgRNA gene for a particular target sequence requires only the insertion of a 24 bp oligonucleotide duplex into the scaffold. Prior to yeast transformation, each plasmid is cleaved at two sites, one of which is located within the selectable marker, so that the functional marker can be restored only via recombination of the Cas9-containing fragment with the sgRNA gene-containing fragment. This recombination leads to the formation of an autonomously replicating plasmid, which can be lost from yeast clones after acquisition of the required genome modification. The vector set allows the use of G418-resistance and LEU2 auxotrophic selectable markers. The functionality of this setup has been demonstrated in O. polymorpha, O. parapolymorpha, O. haglerorum and Komagataella phaffii.
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