The primary photochemistry is similar among the flavin‐bound sensory domains of light–oxygen–voltage (LOV) photoreceptors, where upon blue‐light illumination a covalent adduct is formed on the ...microseconds time scale between the flavin chromophore and a strictly conserved cysteine residue. In contrast, the adduct‐state decay kinetics vary from seconds to days or longer. The molecular basis for this variation among structurally conserved LOV domains is not fully understood. Here, we selected PpSB2‐LOV, a fast‐cycling (τrec 3.5 min, 20 °C) short LOV protein from Pseudomonas putida that shares 67% sequence identity with a slow‐cycling (τrec 2467 min, 20 °C) homologous protein PpSB1‐LOV. Based on the crystal structure of the PpSB2‐LOV in the dark state reported here, we used a comparative approach, in which we combined structure and sequence information with molecular dynamic (MD) simulations to address the mechanistic basis for the vastly different adduct‐state lifetimes in the two homologous proteins. MD simulations pointed toward dynamically distinct structural region, which were subsequently targeted by site‐directed mutagenesis of PpSB2‐LOV, where we introduced single‐ and multisite substitutions exchanging them with the corresponding residues from PpSB1‐LOV. Collectively, the data presented identify key amino acids on the Aβ‐Bβ, Eα‐Fα loops, and the Fα helix, such as E27 and I66, that play a decisive role in determining the adduct lifetime. Our results additionally suggest a correlation between the solvent accessibility of the chromophore pocket and adduct‐state lifetime. The presented results add to our understanding of LOV signaling and will have important implications in tuning the signaling behavior (on/off kinetics) of LOV‐based optogenetic tools.
The photocycle of light–oxygen–voltage (LOV) domains involves blue‐light‐triggered adduct formation between the bound flavin chromophore and a cysteine residue. LOV proteins show considerable variation in the lifetime of the adduct state. Here, we used a comparative approach selecting two homologous LOV proteins originating from Pseudomonas putida: a fast‐cycling PpSB2‐LOV (~ 3.5 min) and a slow‐cycling PpSB1‐LOV (~ 42 h) to investigate the mechanistic basis for the very different lifetimes of the adduct states.
Human guanylate‐binding protein 1 (hGBP1) belongs to the family of dynamin‐like proteins and is activated by addition of nucleotides, leading to protein oligomerization and stimulated GTPase ...activity. In vivo, hGBP1 is post‐translationally modified by attachment of a farnesyl group yielding farn‐hGBP1. In this study, hydrodynamic differences in farn‐hGBP1 and unmodified hGBP1 were investigated using dynamic light scattering (DLS), analytical ultracentrifugation (AUC) and analytical size‐exclusion chromatography (SEC). In addition, we performed small‐angle X‐ray scattering (SAXS) experiments coupled with a SEC setup (SEC‐SAXS) to investigate structural properties of nonmodified hGBP1 and farn‐hGBP1 in solution. SEC‐SAXS measurements revealed that farnesylation keeps hGBP1 in its inactive monomeric and crystal‐like conformation in nucleotide‐free solution, whereas unmodified hGBP1 forms a monomer–dimer equilibrium both in the inactive ground state in nucleotide‐free solution as well as in the activated state that is trapped by addition of the nonhydrolysable GTP analogue GppNHp. Nonmodified hGBP1 is structurally perturbed as compared to farn‐hGBP. In particular, GppNHp binding leads to large structural rearrangements and higher conformational flexibility of the monomer and the dimer. Structural changes observed in the nonmodified protein are prerequisites for further oligomer assemblies of farn‐hGBP1 that occur in the presence of nucleotides.
Database
All SEC‐SAXS data, corresponding fits to the data and structural models are deposited in the Small Angle Scattering Biological Data Bank SASBDB (Nucleic Acids Res, 43, 2015, D357) with project IDs: SASDEE8, SASDEF8, SASDEG8, SASDEH8, SASDEJ8, SASDEK8, SASDEL8 and SASDEM8.
Human guanylate‐binding protein 1 (hGBP1) is activated by the addition of nucleotides, which leads to protein oligomerization and stimulated GTPase activity. Earlier studies focused on the unmodified protein, although in vivo hGBP1 is farnesylated. We studied the effect of farnesylation using a combination of different biophysical methods, which revealed that farnesylation is needed to lock the protein in an inactive monomeric state, perhaps as a safety mechanism.
Abstract
Termination of the G-protein-coupled receptor signaling involves phosphorylation of its C-terminus and subsequent binding of the regulatory protein arrestin. In the visual system, arrestin-1 ...preferentially binds to photoactivated and phosphorylated rhodopsin and inactivates phototransduction.
Here, we have investigated binding of a synthetic phosphopeptide of bovine rhodopsin (residues 323–348) to the active variants of visual arrestin-1: splice variant p44, and the mutant R175E. Unlike the wild type arrestin-1, both these arrestins are monomeric in solution. Solution structure analysis using small angle X-ray scattering supported by size exclusion chromatography results reveal dimerization in both the arrestins in the presence of phosphopeptide. Our results are the first report, to our knowledge, on receptor-induced oligomerization in arrestin, suggesting possible roles for the cellular function of arrestin oligomers. Given high structural homology and the similarities in their activation mechanism, these results are expected to have implications for all arrestin isoforms.
Pseudomonas species have become promising cell factories for the production of natural products due to their inherent robustness. Although these bacteria have naturally evolved strategies to cope ...with different kinds of stress, many biotechnological applications benefit from engineering of optimised chassis strains with specially adapted tolerance traits. Here, we explored the formation of outer membrane vesicles (OMV) of Pseudomonas putida KT2440. We found OMV production to correlate with the recombinant production of a natural compound with versatile beneficial properties, the tripyrrole prodigiosin. Further, several P. putida genes were identified, whose up‐ or down‐regulated expression allowed controlling OMV formation. Finally, genetically triggering vesiculation in production strains of the different alkaloids prodigiosin, violacein, and phenazine‐1‐carboxylic acid, as well as the carotenoid zeaxanthin, resulted in up to three‐fold increased product yields. Consequently, our findings suggest that the construction of robust strains by genetic manipulation of OMV formation might be developed into a useful tool which may contribute to improving limited biotechnological applications.
The study explores the formation of outer membrane vesicles of Pseudomonas putida KT2440 as support mechanism for natural compound production. We first show that vesiculation and recombinant valuable compound production are correlated. We further genetically engineer P. putida for enhanced vesiculation which facilitated increased production levels of a range of natural products. Our findings suggest that this approach may provide a tool for improving hitherto limited biotechnological applications.
Cells steadily adapt their membrane glycerophospholipid (GPL) composition to changing environmental and developmental conditions. While the regulation of membrane homeostasis via GPL synthesis in ...bacteria has been studied in detail, the mechanisms underlying the controlled degradation of endogenous GPLs remain unknown. Thus far, the function of intracellular phospholipases A (PLAs) in GPL remodeling (Lands cycle) in bacteria is not clearly established. Here, we identified the first cytoplasmic membrane-bound phospholipase A
(PlaF) from
, which might be involved in the Lands cycle. PlaF is an important virulence factor, as the
Δ
mutant showed strongly attenuated virulence in
and macrophages. We present a 2.0-Å-resolution crystal structure of PlaF, the first structure that reveals homodimerization of a single-pass transmembrane (TM) full-length protein. PlaF dimerization, mediated solely through the intermolecular interactions of TM and juxtamembrane regions, inhibits its activity. The dimerization site and the catalytic sites are linked by an intricate ligand-mediated interaction network, which might explain the product (fatty acid) feedback inhibition observed with the purified PlaF protein. We used molecular dynamics simulations and configurational free energy computations to suggest a model of PlaF activation through a coupled monomerization and tilting of the monomer in the membrane, which constrains the active site cavity into contact with the GPL substrates. Thus, these data show the importance of the PlaF-mediated GPL remodeling pathway for virulence and could pave the way for the development of novel therapeutics targeting PlaF.
Sterile alpha motif (SAM) domains are protein interaction modules that are involved in a diverse range of biological functions such as transcriptional and translational regulation, cellular ...signalling, and regulation of developmental processes. SH3 domain-containing protein expressed in lymphocytes 1 (SLy1) is involved in immune regulation and contains a SAM domain of unknown function. In this report, the structure of the SLy1 SAM domain was solved and revealed that this SAM domain forms a symmetric homodimer through a novel interface. The interface consists primarily of the two long C-terminal helices, α5 and α5', of the domains packing against each other. The dimerization is characterized by a dissociation constant in the lower micromolar range. A SLy1 SAM domain construct with an extended N-terminus containing five additional amino acids of the SLy1 sequence further increases the stability of the homodimer, making the SLy1 SAM dimer two orders of magnitude more stable than previously studied SAM homodimers, suggesting that the SLy1 SAM dimerization is of functional significance. The SLy1 SAM homodimer contains an exposed mid-loop surface on each monomer, which may provide a scaffold for mediating interactions with other SAM domain-containing proteins via a typical mid-loop-end-helix interface.
Light, oxygen, voltage (LOV) photoreceptors consist of conserved photo-responsive domains in bacteria, archaea, plants and fungi, and detect blue-light via a flavin cofactor. We investigated the ...blue-light induced conformational transition of the dimeric photoreceptor PpSB1-LOV-R66I from Pseudomonas putida in solution by using small-angle X-ray scattering (SAXS). SAXS experiments of the fully populated light- and dark-states under steady-state conditions revealed significant structural differences between the two states that are in agreement with the known structures determined by crystallography. We followed the transition from the light- to the dark-state by using SAXS measurements in real-time. A two-state model based on the light- and dark-state conformations could describe the measured time-course SAXS data with a relaxation time τREC of ~ 34 to 35 min being larger than the recovery time found with UV/vis spectroscopy. Unlike the flavin chromophore-based UV/vis method that is sensitive to the local chromophore environment in flavoproteins, SAXS-based assay depends on protein conformational changes and provides with an alternative to measure the recovery kinetics.
TesA from Pseudomonas aeruginosa belongs to the GDSL hydrolase family of serine esterases and lipases that possess a broad substrate- and regiospecificity. It shows high sequence homology to TAP, a ...multifunctional enzyme from Escherichia coli exhibiting thioesterase, lysophospholipase A, protease and arylesterase activities. Recently, we demonstrated high arylesterase activity for TesA, but only minor thioesterase and no protease activity. Here, we present a comparative analysis of TesA and TAP at the structural, biochemical and physiological levels. The crystal structure of TesA was determined at 1.9 Å and structural differences were identified, providing a possible explanation for the differences in substrate specificities. The comparison of TesA with other GDSL-hydrolase structures revealed that the flexibility of active-site loops significantly affects their substrate specificity. This assumption was tested using a rational approach: we have engineered the putative coenzyme A thioester binding site of E. coli TAP into TesA of P. aeruginosa by introducing mutations D17S and L162R. This TesA variant showed increased thioesterase activity comparable to that of TAP. TesA is the first lysophospholipase A described for the opportunistic human pathogen P. aeruginosa. The enzyme is localized in the periplasm and may exert important functions in the homeostasis of phospholipids or detoxification of lysophospholipids.
Light–Oxygen–Voltage (LOV) domains represent the photo-responsive domains of various blue-light photoreceptor proteins and are widely distributed in plants, algae, fungi, and bacteria. Here, we ...report the dark-state crystal structure of PpSB1-LOV, a slow-reverting short LOV protein from Pseudomonas putida that is remarkably different from our previously published “fully light-adapted” structure 1. A direct comparison of the two structures provides insight into the light-activated signaling mechanism. Major structural differences involve a~11Å movement of the C terminus in helix Jα, ~4Å movement of Hβ–Iβ loop, disruption of hydrogen bonds in the dimer interface, and a~29° rotation of chain-B relative to chain-A as compared to the light-state dimer. Both crystal structures and solution NMR data are suggestive of the key roles of a conserved glutamine Q116 and the N-cap region consisting of A′α–Aβ loop and the A′α helix in controlling the light-activated conformational changes. The activation mechanism proposed here for the PpSB1-LOV supports a rotary switch mechanism and provides insights into the signal propagation mechanism in naturally existing and artificial LOV-based, two-component systems and regulators.
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•Comparison of crystal structures of PpSB1-LOV in dark and light states•Dimer interface and the C-terminal Jα-helix show major structural rearrangements.•A~29° rotation between the two protein chains gated by light•Extensive NMR solution studies reveal light-induced conformational changes.•We propose a rotary switch mechanism for the activation.
Light, oxygen, voltage (LOV) proteins, a ubiquitously distributed class of photoreceptors, regulate a wide variety of light-dependent physiological responses. Because of their modular architecture, ...LOV domains, i.e., the sensory domains of LOV photoreceptors, have been widely used for the construction of optogenetic tools. We recently described the structure and function of a short LOV protein (DsLOV) from the marine phototropic bacterium Dinoroseobacter shibae, for which, in contrast to other LOV photoreceptors, the dark state represents the physiologically relevant signaling state. Among bacterial LOV photoreceptors, DsLOV possesses an exceptionally fast dark recovery, corroborating its function as a “dark” sensor. To address the mechanistic basis of this unusual characteristic, we performed a comprehensive mutational, kinetic, thermodynamic, and structural characterization of DsLOV. The mechanistic basis of the fast dark recovery of the protein was revealed by mutation of the previously noted uncommon residue substitution at position 49 found in DsLOV. The substitution of M49 with different residues that are naturally conserved in LOV domains tuned the dark-recovery time of DsLOV over 3 orders of magnitude, without grossly affecting its overall structure or the light-dependent structural change observed for the wild-type protein. Our study thus provides a striking example of how nature can achieve LOV photocycle tuning by subtle structural alterations in the LOV domain active site, highlighting the easy evolutionary adaptability of the light sensory function. At the same time, our data provide guidance for the mutational photocycle tuning of LOV domains, with relevance for the growing field of optogenetics.