Silke von Horsten scite author profile

Organisms developed different photoreceptors to be able to adapt to changing environmental light conditions. Phytochromes are red/far-red (r/fr) photochromic photoreceptors that belong to the classical photoreceptors along with cryptochromes and phototropins. They convert absorbed light into a biological signal by switching between two states in a light-dependent manner therefore enabling the light control downstream signalling. Their Pfr conformation is the biological active form in plants, but until now only a structure of the ground state (Pr) was solved. Here, the authors provide information about structural changes occurring during photoconversion within phytochrome B and identify possible interaction sites for its N-terminal extension (NTE) utilising hydrogen/deuterium exchange rate analyses of its amide backbone. Especially, the newly identified light-dependency of two regions in the NTE are of particular interest for understanding the involvement of the phytochrome’s NTE in the regulation of its downstream signalling.

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Structural changes within the bifunctional cryptochrome/photolyase CraCRY upon blue light excitation

Franz-Badur

Penner

Straß

et al. 2019

Sci Rep

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Cryptochromes (CRYs) are an ubiquitously occurring class of photoreceptors, which are important for regulating the circadian rhythm of animals via a time-delayed transcription-translation feedback loop (TTFL). Due to their protein architecture and common FAD chromophore, they belong to the same superfamily as photolyases (PHLs), an enzyme class that repairs UV-induced DNA lesions upon blue light absorption. Apart from their different functions the only prominent structural difference between CRY and PHL is the highly variable C-terminal extension (CTE) of the former. The nature of the CTE is still unclear and highly speculated. In this study, we show by hydrogen/deuterium exchange and subsequent mass-spectrometric analysis that the CTE of the animal-like cryptochrome from the green algae Chlamydomonas reinhardtii ( Cr aCRY) binds to the surface of the photolyase homology region, which flanks the DNA binding site. We also compared the fully oxidized and fully reduced states of the flavoprotein and designed a tool, so called light chamber, for automated HDX-MS measurements of photoreceptors in defined photostates. We could observe some striking differences between the two photostates and propose a model for light-dependent switching of this bifunctional cryptochrome.

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Arabidopsis phytochrome A nuclear translocation is mediated by a far‐red elongated hypocotyl 1–importin complex

Helizon¹,

Rösler-Dalton

Gasch

et al. 2018

The Plant Journal

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Phytochrome A (phyA) is a red and far-red (FR) sensing photoreceptor regulating plant growth and development. Its biologically active FR-absorbing form Pfr translocates into the nucleus and subsequently regulates gene expression. Two transport facilitators, FR elongated hypocotyl 1 (FHY1) and FHY1-like (FHL), are crucial for its cytoplasmic-nuclear translocation. FHY1 interacts preferentially with activated phyA (Pfr) in assays with recombinant phyA and FHY1 and in vivo. Nuclear translocation of the phyA-FHY1 complex depends on a nuclear localization signal (NLS) of FHY1, which is recognized by IMPas independently of phyA. The complex is guided along the actin cytoskeleton. Additionally, FHY1 has the ability to exit the nucleus via the exportin route, thus is able to repeatedly transport phyA molecules to the nucleus, balancing the nucleocytoplasmic distribution. The direction of FHY1s transport appears to depend on its phosphorylation state in different compartments. Phosphorylated serins close to the NLS prevent FHY1 binding to IMPa. The work presented here elucidates key steps of the mechanism by which photoactivated phyA translocates to the nucleus.

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Inactive pseudoenzyme subunits in heterotetrameric BbsCD, a novel short‐chain alcohol dehydrogenase involved in anaerobic toluene degradation

et al. 2021

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Anaerobic toluene degradation proceeds by fumarate addition to produce (R)-benzylsuccinate as first intermediate, which is further degraded via β-oxidation by five enzymes encoded in the conserved bbs operon. This study characterizes two enzymes of this pathway, (E)-benzylidenesuccinyl-CoA hydratase (BbsH), and (S,R)-2-(α-hydroxybenzyl)succinyl-CoA dehydrogenase (BbsCD) from Thauera aromatica. BbsH, a member of the enoyl-CoA hydratase family, converts (E)-benzylidenesuccinyl-CoA to 2-(α-hydroxybenzyl)succinyl-CoA and was subsequently used in a coupled enzyme assay with BbsCD, which belongs to the short-chain dehydrogenases/reductase (SDR) family. The BbsCD crystal structure shows a C2-symmetric heterotetramer consisting of BbsC 2 and BbsD 2 dimers. BbsD subunits are catalytically active and capable of binding NAD + and substrate, whereas BbsC subunits represent built-in pseudoenzyme moieties lacking all motifs of the SDR family required for substrate binding or catalysis. Molecular modeling studies predict that the active site of BbsD is specific for conversion of the (S,R)-diastereomer of 2-(α-hydroxybenzyl)succinyl-CoA to (S)-2benzoylsuccinyl-CoA by hydride transfer to the re-face of nicotinamide adenine dinucleotide (NAD) + . Furthermore, BbsC subunits are not engaged in substrate binding and merely serve as scaffold for the BbsD dimer. BbsCD represents a novel clade of related enzymes within the SDR family, which adopt a heterotetrameric architecture and catalyze the β-oxidation of aromatic succinate adducts.

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Structural communication between the chromophore‐binding pocket and the N‐terminal extension in plant phytochrome phyB

et al. 2017

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The N-terminal extension (NTE) of plant phytochromes has been suggested to play a functional role in signaling photoinduced structural changes. Here, we use resonance Raman spectroscopy to study the effect of the NTE on the chromophore structure of B-type phytochromes from two evolutionarily distant plants. NTE deletion seems to have no effect on the chromophore in the inactive Pr state, but alters the torsion of the C-D ring methine bridge and the surrounding hydrogen bonding network in the physiologically active Pfr state. These changes are accompanied by a shift of the conformational equilibrium between two Pfr substates, which might affect the thermal isomerization rate of the C-D double bond and, thus, account for the effect of the NTE on the dark reversion kinetics.

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