Light–oxygen–voltage (LOV) receptors sense blue light through the photochemical generation of a covalent adduct between a flavin-nucleotide chromophore and a strictly conserved cysteine residue. Here we show that, after cysteine removal, the circadian-clock LOV-protein Vivid still undergoes light-induced dimerization and signalling because of flavin photoreduction to the neutral semiquinone (NSQ). Similarly, photoreduction of the engineered LOV histidine kinase YF1 to the NSQ modulates activity and downstream effects on gene expression. Signal transduction in both proteins hence hinges on flavin protonation, which is common to both the cysteinyl adduct and the NSQ. This general mechanism is also conserved by natural cysteine-less, LOV-like regulators that respond to chemical or photoreduction of their flavin cofactors. As LOV proteins can react to light even when devoid of the adduct-forming cysteine, modern LOV photoreceptors may have arisen from ancestral redox-active flavoproteins. The ability to tune LOV reactivity through photoreduction may have important implications for LOV mechanism and optogenetic applications.
Cryptochrome (CRY) is the principal light sensor of the insect circadian clock. Photoreduction of the Drosophila CRY (dCRY) flavin cofactor to the anionic semiquinone (ASQ) restructures a C-terminal tail helix (CTT) that otherwise inhibits interactions with targets that include the clock protein Timeless (TIM). All-atom molecular dynamics (MD) simulations indicate that flavin reduction destabilizes the CTT, which undergoes large-scale conformational changes (the CTT release) on short (25 ns) timescales. The CTT release correlates with the conformation and protonation state of conserved His378, which resides between the CTT and the flavin cofactor. Poisson-Boltzmann calculations indicate that flavin reduction substantially increases the His378 pK a . Consistent with coupling between ASQ formation and His378 protonation, dCRY displays reduced photoreduction rates with increasing pH; however, His378Asn/Arg variants show no such pH dependence. Replica-exchange MD simulations also support CTT release mediated by changes in His378 hydrogen bonding and verify other responsive regions of the protein previously identified by proteolytic sensitivity assays. His378 dCRY variants show varying abilities to light-activate TIM and undergo self-degradation in cellular assays. Surprisingly, His378Arg/Lys variants do not degrade in light despite maintaining reactivity toward TIM, thereby implicating different conformational responses in these two functions. Thus, the dCRY photosensory mechanism involves flavin photoreduction coupled to protonation of His378, whose perturbed hydrogen-bonding pattern alters the CTT and surrounding regions.light sensing | flavoprotein | photochemistry | redox | molecular dynamics C ryptochromes (CRYs) are flavin-binding proteins that perform a variety of sensory and catalytic functions in all kingdoms of life (1, 2). CRYs are closely related to the DNA photolyases (PLs), which catalyze light-driven redox reactions to break apart pyrimidine dimers in UV-damaged DNA (1, 2). CRYs and PLs share a conserved photolyase homology region that consists of an α-helical domain, which binds flavin adenine dinucleotide (FAD) and an α/β Rossman-fold domain, which sometimes binds a pteridine or deazaflavin antenna cofactor. CRYs also contain C-terminal extensions of variable sizes that contribute to their specific functions. The range of activities found for CRYs and PLs require that their flavin cofactors assume a broad range of redox, protonation, and excited states (1, 2).In the fruit fly Drosophila melanogaster, a type I cryptochrome (dCRY) is the primary light receptor of the circadian clock (1, 3). In response to blue light, dCRY coordinates interactions between Timeless (TIM) and the E3-ubiquitin ligase Jetlag (JET) (4). JETmediated proteolysis of TIM destabilizes its partner Period (PER). PER serves as the principal repressor of circadian gene expression and its degradation phase-shifts the clock (3). dCRY also catalyzes light-induced self-degradation that involves another E3-ligase: Brwd3 or RAMSHACKLE (5)...
The tryptophan 191 cation radical of cytochrome c peroxidase (CcP) compound I (Cpd I) mediates long-range electron transfer (ET) to cytochrome c (Cc). Here we test the effects of chemical substitution at the 191 position. CcP W191Y forms a stable tyrosyl radical on reaction with peroxide and produces spectral properties similar to that of Cpd I but has low reactivity toward reduced Cc. CcP W191G(or F) variants also have low activity, as do redox ligands that bind within the W191G cavity. Crystal structures of complexes between Cc and CcP W191X (X = Y, F, G), as well as W191G with four bound ligands, reveal similar 1:1 association modes and heme pocket conformations. The ligands display structural disorder in the pocket and do not hydrogen bond to Asp235, as does Trp191. Well-ordered Tyr191 directs its hydroxyl group toward the porphyrin ring, with no basic residue in range of interaction. CcP W191X (X = Y, F, G) variants substituted with zinc-porphyrin (ZnP) undergo photoinduced ET with Cc(III). Their slow charge recombination kinetics that results from loss of the radical center allow resolution of difference spectra for the charge-separated state (ZnP+, Cc(II)). The change from a phenyl moiety at position 191 in W191F to a water-filled cavity in W191G produces much smaller effects on ET rates than the change from Trp to Phe. Low net reactivity of W191Y toward Cc(II) either derives from the inability of ZnP+ or the Fe-CcP ferryl to oxidize Tyr or from a low potential of the resulting neutral Tyr radical.
Transient tyrosine and tryptophan radicals play key roles in the electron transfer (ET) reactions of photosystem (PS) II, ribonucleotide reductase (RNR), photolyase, and many other proteins. However, Tyr and Trp are not functionally interchangeable, and the factors controlling their reactivity are often unclear. Cytochrome c peroxidase (CcP) employs a Trp191 •+ radical to oxidize reduced cytochrome c (Cc). Although a Tyr191 replacement also forms a stable radical, it does not support rapid ET from Cc. Here we probe the redox properties of CcP Y191 by nonnatural amino acid substitution, altering the ET driving force and manipulating the protic environment of Y191. Higher potential fluorotyrosine residues increase ET rates marginally, but only addition of a hydrogen bond donor to Tyr191 • (via Leu232His or Glu) substantially alters activity by increasing the ET rate by nearly 30-fold. ESR and ESEEM spectroscopies, crystallography, and pH-dependent ET kinetics provide strong evidence for hydrogen bond formation to Y191 • by His232/Glu232. Rate measurements and rapid freeze quench ESR spectroscopy further reveal differences in radical propagation and Cc oxidation that support an increased Y191 • formal potential of ∼200 mV in the presence of E232. Hence, Y191 inactivity results from a potential drop owing to Y191 •+ deprotonation. Incorporation of a well-positioned base to accept and donate back a hydrogen bond upshifts the Tyr • potential into a range where it can effectively oxidize Cc. These findings have implications for the Y Z /Y D radicals of PS II, hole-hopping in RNR and cryptochrome, and engineering proteins for long-range ET reactions.
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