The signaling state of Arabidopsis cryptochrome 2 contains flavin semiquinone

Cryptochrome (Cry) photoreceptors share high sequence and structural similarity with DNA repair enzyme DNA-photolyase and carry the same flavin cofactor. Accordingly, DNA-photolyase was considered a model system for the light activation process of cryptochromes. In line with this view were recent spectroscopic studies on cryptochromes of the CryDASH subfamily that showed photoreduction of the flavin adenine dinucleotide (FAD) cofactor to its fully reduced form. However, CryDASH members were recently shown to have photolyase activity for cyclobutane pyrimidine dimers in single-stranded DNA, which is absent for other members of the cryptochrome/photolyase family. Thus, CryDASH may have functions different from cryptochromes. The photocycle of other members of the cryptochrome family, such as Arabidopsis Cry1 and Cry2, which lack DNA repair activity but control photomorphogenesis and flowering time, remained elusive. Here we have shown that Arabidopsis Cry2 undergoes a photocycle in which semireduced flavin (FADH(.)) accumulates upon blue light irradiation. Green light irradiation of Cry2 causes a change in the equilibrium of flavin oxidation states and attenuates Cry2-controlled responses such as flowering. These results demonstrate that the active form of Cry2 contains FADH(.) (whereas catalytically active photolyase requires fully reduced flavin (FADH(-))) and suggest that cryptochromes could represent photoreceptors using flavin redox states for signaling differently from DNA-photolyase for photorepair.     

Formation and function of flavin anion radical in cryptochrome 1 blue-light photoreceptor of monarch butterfly

The monarch butterfly (Danaus plexippus) cryptochrome 1 (DpCry1) belongs in the class of photosensitive insect cryptochromes. Here we purified DpCry1 expressed in a bacterial host and obtained the protein with a stoichiometric amount of the flavin cofactor in the two-electron oxidized, FAD(ox), form. Exposure of the purified protein to light converts the FAD(ox) to the FAD*(-) flavin anion radical by intraprotein electron transfer from a Trp residue in the apoenzyme. To test whether this novel photoreduction reaction is part of the DpCry1 physiological photocycle, we mutated the Trp residue that acts as the ultimate electron donor in flavin photoreduction. The mutation, W328F, blocked the photoreduction entirely but had no measurable effect on the light-induced degradation of DpCry1 in vivo. In light of this finding and the recently published action spectrum of this class of Crys, we conclude that DpCry1 and similar insect cryptochromes do not contain flavin in the FAD(ox) form in vivo and that, most likely, the [see text] photoreduction reaction is not part of the insect cryptochrome photoreaction that results in proteolytic degradation of the photopigment.     

Active site of DNA photolyase: tryptophan-306 is the intrinsic hydrogen atom donor essential for flavin radical photoreduction and DNA repair in vitro

DNA photolyases repair cyclobutadipyrimidines (Pyr()Pyr) in DNA by photoinduced electron transfer. The enzyme isolated from Escherichia coli contains methenyltetrahydrofolate (MTHF), which functions as photoantenna, and FADH2, which is the redox-active cofactor. During purification, FADH2 is oxidized to the blue neutral radical form, FADH., which has greatly diminished activity. Previous nanosecond flash photolysis studies [Heelis, P.F., Okamura, T., & Sancar, A. (1990) Biochemistry 29, 5694-5698] indicated that excitation of FADH. either directly by absorbing a photon or indirectly by electronic energy transfer from MTHF excited singlet state yielded an FADH. quartet which abstracted a hydrogen atom from a nearby tryptophan to generate the catalytically competent FADH2 from of the enzyme. Using site-directed mutagenesis, we replaced all 15 photolyase tryptophan residues by phenylalanine, individually, in order to identify the internal hydrogen atom donor responsible for photoreduction. We found that W306F mutation abolished photoreduction of FADH. without affecting the excited-state properties of FADH. or the substrate binding (KA approximately 10(9) M-1) of the enzyme. The specificity constant (kcat/km) was approximately 0 for the mutant enzyme in the absence of reducing agents in the reaction mixture, indicating that photoreduction of FADH. is an essential step for photorepair by photolyase in vitro. Chemical reduction of FADH. of the mutant enzyme restored the specificity constant to the wild-type level.     

Fourier-transform infrared study of the photoactivation process of Xenopus (6-4) photolyase

Photolyases (PHRs) are blue light-activated DNA repair enzymes that maintain genetic integrity by reverting UV-induced photoproducts into normal bases. The flavin adenine dinucleotide (FAD) chromophore of PHRs has four different redox states: oxidized (FAD(ox)), anion radical (FAD(?-)), neutral radical (FADH(?)), and fully reduced (FADH(-)). We combined difference Fourier-transform infrared (FTIR) spectroscopy with UV-visible spectroscopy to study the detailed photoactivation process of Xenopus (6-4) PHR. Two photons produce the enzymatically active, fully reduced PHR from oxidized FAD: FAD(ox) is converted to semiquinone via light-induced one-electron and one-proton transfers and then to FADH(-) by light-induced one-electron transfer. We successfully trapped FAD(?-) at 200 K, where electron transfer occurs but proton transfer does not. UV-visible spectroscopy following 450 nm illumination of FAD(ox) at 277 K defined the FADH(?)/FADH(-) mixture and allowed calculation of difference FTIR spectra among the four redox states. The absence of a characteristic C=O stretching vibration indicated that the proton donor is not a protonated carboxylic acid. Structural changes in Trp and Tyr are suggested by UV-visible and FTIR analysis of FAD(?-) at 200 K. Spectral analysis of amide I vibrations revealed structural perturbation of the protein's β-sheet during initial electron transfer (FAD(?-) formation), a transient increase in α-helicity during proton transfer (FADH(?) formation), and reversion to the initial amide I signal following subsequent electron transfer (FADH(-) formation). Consequently, in (6-4) PHR, unlike cryptochrome-DASH, formation of enzymatically active FADH(-) did not perturb α-helicity. Protein structural changes in the photoactivation of (6-4) PHR are discussed on the basis of these FTIR observations.     

On the role of aromatic side chains in the photoactivation of BLUF domains

BLUF (blue-light sensing using FAD) domain proteins are a novel group of blue-light sensing receptors found in many microorganisms. The role of the aromatic side chains Y21 and W104, which are in close vicinity to the FAD cofactor in the AppA BLUF domain from Rhodobacter sphaeroides, is investigated through the introduction of several amino acid substitutions at these positions. NMR spectroscopy indicated that in the W104F mutant, the local structure of the FAD binding pocket was not significantly perturbed as compared to that of the wild type. Time-resolved fluorescence and absorption spectroscopy was applied to explore the role of Y21 and W104 in AppA BLUF photochemistry. In the Y21 mutants, FADH*-W* radical pairs are transiently formed on a ps time scale and recombine to the ground state on a ns time scale. The W104F mutant shows a spectral evolution similar to that of wild type AppA but with an increased yield of signaling state formation. In the Y21F/W104F double mutant, all light-driven electron-transfer processes are abolished, and the FAD singlet excited-state evolves by intersystem crossing to the triplet state. Our results indicate that two competing light-driven electron-transfer pathways are available in BLUF domains: one productive pathway that involves electron transfer from the tyrosine, which leads to signaling state formation, and one nonproductive electron-transfer pathway from the tryptophan, which leads to deactivation and the effective lowering of the quantum yield of the signaling state formation. Our results are consistent with a photoactivation mechanism for BLUF domains where signaling state formation proceeds via light-driven electron and proton transfer from the conserved tyrosine to FAD, followed by a hydrogen-bond rearrangement and radical-pair recombination.     

Analysis of the role of intraprotein electron transfer in photoreactivation by DNA photolyase in vivo

Escherichia coli DNA photolyase contains FADH(-) as the catalytic cofactor. The cofactor becomes oxidized to the FADH(*) blue neutral radical during purification. The E-FADH(*) form of the enzyme is catalytically inert but can be converted to the active E-FADH(-) form by a photoreduction reaction that involves intraprotein electron transfer from Trp306. It is thought that the E-FADH(*) form is also transiently generated during pyrimidine dimer repair by photoinduced electron transfer, and it has been suggested that the FADH(*) that is generated after each round of catalysis must be photoreduced before the enzyme can engage in subsequent rounds of repair. In this study, we introduced the Trp306Phe mutation into the chromosomal gene and tested the non-photoreducible W306F mutant for photorepair in vivo. We find that both wild-type and W306F mutant photolyases carry out at least 25 rounds of photorepair at the same rate. We conclude that photoreduction by intraprotein electron transfer is not part of the photolyase photocycle under physiological conditions.     

Chromophore function and interaction in Escherichia coli DNA photolyase: reconstitution of the apoenzyme with pterin and/or flavin derivatives

Native DNA photolyase, as isolated from Escherichia coli, contains a neutral flavin radical (FADH.) plus a pterin chromophore (5,10-methenyltetrahydropteroylpolyglutamate) and can be converted to its physiologically significant form by reduction of FADH. to fully reduced flavin (FADH2) with dithionite or by photoreduction. Either FADH2 or the pterin chromophore in dithionite-reduced native enzyme can function as a sensitizer in catalysis. Various enzyme forms (EFADox, EFADH., EFADH2, EPteFADox, EPteFADH., EPteFADH2, EPte) containing stoichiometric amounts of FAD in either of its three oxidation states and/or 5,10-methenyltetrahydrofolate (Pte) have been prepared in reconstitution experiments. Studies with EFADox and EPte showed that these preparations retained the ability to bind the missing chromophore. The results suggest that there could be considerable flexibility in the biological assembly of holoenzyme since the order of binding of the enzyme's chromophores is apparently unimportant, the binding of FAD is unaffected by its redox state, and enzyme preparations containing only one chromophore are reasonably stable. The same catalytic properties are observed with dithionite-reduced native enzyme or EFADH2. These preparations do not exhibit a lag in catalytic assays whereas lags are observed with preparations containing FADox or FADH. in the presence or absence of pterin. Photochemical studies show that these lags can be attributed to enzyme activation under assay conditions in a reaction involving photoreduction of enzyme-bound FADox or FADH. to FADH2. EPte is catalytically inactive, but catalytic activity is restored upon reconstitution of EPte with FADox. The results show that pterin is not required for dimer repair when FADH2 acts as the sensitizer but that FADH2 is required when dimer repair is initiated by excitation of the pterin chromophore. The relative intensity of pterin fluorescence in EPte, EPteFADH., EPteFADox, or EPteFADH2 has been used to estimate the efficiency of pterin singlet quenching by FADH. (93%), FADox (90%), or FADH2 (58%). Energy transfer from the excited pterin to flavin is energetically feasible and may account for the observed quenching of pterin fluorescence and also explain why photoreduction of FADox or FADH. is accelerated by the pterin chromophore. An irreversible photobleaching of the pterin chromophore is accelerated by FADH2 in a reaction that is accompanied by a transient oxidation of FADH2 to FADH.. Both pterin bleaching and FADH2 oxidation are inhibited by substrate.     

Proton Transfer to Flavin Stabilizes the Signaling State of the Blue Light Receptor Plant Cryptochrome

Plant cryptochromes regulate the circadian rhythm, flowering time, and photomorphogenesis in higher plants as responses to blue light. In the dark, these photoreceptors bind oxidized FAD in the photolyase homology region (PHR). Upon blue light absorption, FAD is converted to the neutral radical state, the likely signaling state, by electron transfer via a conserved tryptophan triad and proton transfer from a nearby aspartic acid. Here we demonstrate, by infrared and time-resolved UV-visible spectroscopy on the PHR domain, that replacement of the aspartic acid Asp-396 with cysteine prevents proton transfer. The lifetime of the radical is decreased by 6 orders of magnitude. This short lifetime does not permit to drive conformational changes in the C-terminal extension that have been associated with signal transduction. Only in the presence of ATP do both the wild type and mutant form a long-lived radical state. However, in the mutant, an anion radical is formed instead of the neutral radical, as found previously in animal type I cryptochromes. Infrared spectroscopic experiments demonstrate that the light-induced conformational changes of the PHR domain are conserved in the mutant despite the lack of proton transfer. These changes are not detected in the photoreduction of the non-photosensory d-amino acid oxidase to the anion radical. In conclusion, formation of the anion radical is sufficient to generate a protein response in plant cryptochromes. Moreover, the intrinsic proton transfer is required for stabilization of the signaling state in the absence of ATP.     

Light-induced electron transfer in Arabidopsis cryptochrome-1 correlates with in vivo function

Cryptochromes are blue light-activated photoreceptors found in multiple organisms with significant similarity to photolyases, a class of light-dependent DNA repair enzymes. Unlike photolyases, cryptochromes do not repair DNA and instead mediate blue light-dependent developmental, growth, and/or circadian responses by an as yet unknown mechanism of action. It has recently been shown that Arabidopsis cryptochrome-1 retains photolyase-like photoreduction of its flavin cofactor FAD by intraprotein electron transfer from tryptophan and tyrosine residues. Here we demonstrate that substitution of two conserved tryptophans that are constituents of the flavin-reducing electron transfer chain in Escherichia coli photolyase impairs light-induced electron transfer in the Arabidopsis cryptochrome-1 photoreceptor in vitro. Furthermore, we show that these substitutions result in marked reduction of light-activated autophosphorylation of cryptochrome-1 in vitro and of its photoreceptor function in vivo, consistent with biological relevance of the electron transfer reaction. These data support the possibility that light-induced flavin reduction via the tryptophan chain is the primary step in the signaling pathway of plant cryptochrome.     

Exploring the possibilities for radical pair effects in cryptochrome

The ability of some animals to sense magnetic fields has long captured the human imagination. In our recent paper, we explored how radical pair effects in the protein cryptochrome may underlie the magnetic orientation sense of migratory birds. Here we explain our model and discuss its relationship to experimental results on plant cryptochromes, as well as discuss the next steps in refining our model, and explore alternate but related possibilities for modeling and understanding cryptochrome as a magnetic sensor.Key words: cryptochrome, radical pair machanism, avian orientation, magnetic field effect, Arabidopsis thaliana, avian magnetoreception, magnetic sensorThe ability of some animals to sense magnetic fields is a long-standing open problem in biology. Over the past 50 years, scientific studies have shown that a wide variety of living organisms have the ability to perceive magnetic fields and can use information from the earth''s magnetic field in orientation behavior. The best-studied example of animal magnetoreception is the case of migratory birds, who use the earth''s magnetic field, as well as a variety of other environmental cues, to find their way during migration.The two prevailing hypotheses for the mechanism of avian magnetoreception are an iron-mineral-based explanation, wherein birds use small deposits of magnetic iron minerals^1,2,12 in the base of their beaks for magnetic orientation, and a radical-pair-based explanation, in which a magnetically sensitive chemical reaction in the eye of the bird enables perception of the magnetic field via its effects on reaction products. The latter hypothesis is based on the idea that a radical pair reaction may take place in the protein cryptochrome in the retina of the bird.^3,4 Cryptochrome contains a blue-light-absorbing chromophore, flavin adenine dinucleotide (FAD); this FAD cofactor is reduced via a series of light-induced electron transfers from a chain of three tryptophans that bridge the space between FAD and the protein surface (see Fig. 1). The hypothesis explored in our paper⁴ is that a radical pair reaction takes place between FAD and the tryptophans in the photoreduction pathway which modulates the signaling activity of cryptochrome. The specifics of this idea are outlined in Figure 1.Open in a separate windowFigure 1Right: Cryptochrome internally binds the FAD cofactor and contains a three-tryptophan photoreduction pathway conserved from photolyase, consisting of Trp400, Trp377, and Trp324, with Trp400 nearest the FAD and Trp324 closest to the protein surface. After the FAD cofactor absorbs a photon, bringing it into an excited state, it is protonated from a nearby acidic residue, and then electron transfer proceeds from Trp400. At this stage, the semireduced FADH and Trp400⁺ comprise a radical pair—that is, each partner has an unpaired electron, and the spins of those electrons are in a correlated state. Cryptochrome is thought to be in its active, signaling state when the FAD cofactor is in this semireduced FADH form. An electron is then transferred from Trp377 to Trp400 and from Trp324 to Trp377, forming radical pairs FADH + Trp377⁺ and FADH + Trp324⁺ in the process. The Trp324 radical is then deprotonated. Before this final deprotonation, it is possible for the electron to back transfer from the tryptophan to FADH. If this occurs, FADH reverts to the oxidized FAD form, and cryptochrome is no longer in its active state. Left: This schematic of the electron transfer pathway in cryptochrome shows the estimated lifetimes of each of the radical pair states. The system spends most of its time in the FADH + Trp324 radical pair state. Also shown are the electron and nuclear spins on the FADH and Trp324 radicals. Each nuclear spin adds a small contribution to the local magnetic field. The unpaired electron spins are shown here in the singlet (antiparallel) state. They precess around the local magnetic field, which consists of contributions from the external field and from each of the nuclear spins, causing interconversion to the triplet (parallel) state and back again. This singlet-triplet interconversion is the basis of the radical pair effect in the following sense. Electron back-transfer from Trp324 to FADH proceeds only when the unpaired electrons on each radical are in the singlet state. Cryptochrome remains in its active state so long as this back-transfer is impeded. Therefore, singlet-triplet interconversion influences the time cryptochrome can spend in its active state, and so this magnetic-field-driven effect can alter the protein''s signaling behavior.That magnetic field effects do occur in cryptochrome is supported indirectly by experiments done by Margaret Ahmad and co-workers, as reported in their recent paper⁵ on the effects of magnetic fields on cryptochrome-dependent responses in Arabidopsis thaliana seedlings. In our paper, Magnetic Field Effects in Arabidopsis thaliana Cryptochrome-1 (4), we sought to evaluate this possibility computationally, to see whether a magnetic field effect in the FADH - tryptophan radical pair is reasonable. We found that it is possible to see a change in cryptochrome activation yield (the amount of time cryptochrome stays in its active state) of about 10%.Unfortunately, the magnetic field dependence of cryptochrome activation seen in our calculations cannot be taken as exact because of several limitations. Chief among these are that the models of the radical pair did not include all nuclei, and the hyperfine coupling constants were taken from DNA photolyase, which is a protein highly similar to cryptochrome in structure, but which does not necessarily have precisely the same hyperfine coupling for the FAD cofactor and the tryptophans in the photoreduction pathway as does cryptochrome. However, the suggested theory is general and with the knowledge of correct hyperfine coupling constants for the radical pair partners it can be used to calculate the activation yield precisely. Although it would be ideal to obtain hyperfine parameters from experiment, it is also possible to calculate the hyperfine coupling constants with advanced ab initio techniques using the Gaussian package.⁶ Our preliminary calculations of the hyperfine couplings in tryptophan radicals compare well with the values used in our paper.⁴ This sort of calculation creates the opportunity not only to refine our current picture of the radical pair mechanism in cryptochrome, but also to explore other possible radical pairs in the system.In light of work being done by Margaret Ahmad and co-workers (not yet published), it has been suggested recently that the radical pair reaction in cryptochrome may not occur between the FAD cofactor and tryptophan, but in some other radical pair within the protein. It is possible that rather than occurring in the FAD photoreduction process, the radical pair reaction actually takes place in the reoxidation reaction wherein the semireduced FADH is brought back to the oxidized FAD form. One possible radical pair in the back reaction is between FAD and an oxygen molecule which is thought to be involved in the reoxidization process. This radical pair is of particular interest because an oxygen radical would be devoid of hyperfine interactions. Such a radical pair, where one radical has no hyperfine coupling, would be consistent with studies on the effects of weak radio-frequency oscillating magnetic fields on migratory bird orientation. Thorsten Ritz and co-workers found that appropriate orientation behavior depended not only on the strength and angle of the oscillating field, but also that the minimum field strength necessary to disrupt orientation depended on the frequency of the oscillating field in a resonance-like behavior that would be predicted by just such a radical pair^7–9 (personal communication with T. Ritz).The scientific community is still a long way from a complete understanding of avian magnetoreception. The best that may be said of our understanding of it is that birds do demonstrably perceive and use magnetic field information, and that their responses to magnetic fields under different conditions—light intensity and color, magnetic field strength and presence and frequency of oscillating fields—belies a complex phenomenon which is probably the result of multiple receptors which interact in unknown ways.^10,11 However, disorientation responses to low-intensity oscillating magnetic fields are strongly suggestive of the involvement of a radical-pair mechanism, making the exploration of radical pair effects in cryptochrome a useful endeavor. Much remains to be done. Even if cryptochrome is confirmed as magnetoreceptor, it remains for biologists to determine how its signaling modulation enters into a bird''s sensory perception and ultimately its orientation behavior. Nevertheless, radical pair effects in cryptochrome seem promising as a possible source of magnetoreception in birds, and continued investigation may yet shed light on this complex behavior.     

Variable Electron Transfer Pathways in an Amphibian Cryptochrome: TRYPTOPHAN VERSUS TYROSINE-BASED RADICAL PAIRS*

Electron transfer reactions play vital roles in many biological processes. Very often the transfer of charge(s) proceeds stepwise over large distances involving several amino acid residues. By using time-resolved electron paramagnetic resonance and optical spectroscopy, we have studied the mechanism of light-induced reduction of the FAD cofactor of cryptochrome/photolyase family proteins. In this study, we demonstrate that electron abstraction from a nearby amino acid by the excited FAD triggers further electron transfer steps even if the conserved chain of three tryptophans, known to be an effective electron transfer pathway in these proteins, is blocked. Furthermore, we were able to characterize this secondary electron transfer pathway and identify the amino acid partner of the resulting flavin-amino acid radical pair as a tyrosine located at the protein surface. This alternative electron transfer pathway could explain why interrupting the conserved tryptophan triad does not necessarily alter photoreactions of cryptochromes in vivo. Taken together, our results demonstrate that light-induced electron transfer is a robust property of cryptochromes and more intricate than commonly anticipated.     

Cryptochrome 3 from Arabidopsis thaliana: structural and functional analysis of its complex with a folate light antenna

Cryptochromes are almost ubiquitous blue-light receptors and act in several species as central components of the circadian clock. Despite being evolutionary and structurally related with DNA photolyases, a class of light-driven DNA-repair enzymes, and having similar cofactor compositions, cryptochromes lack DNA-repair activity. Cryptochrome 3 from the plant Arabidopsis thaliana belongs to the DASH-type subfamily. Its crystal structure determined at 1.9 Angstroms resolution shows cryptochrome 3 in a dimeric state with the antenna cofactor 5,10-methenyltetrahydrofolate (MTHF) bound in a distance of 15.2 Angstroms to the U-shaped FAD chromophore. Spectroscopic studies on a mutant where a residue crucial for MTHF-binding, E149, was replaced by site-directed mutagenesis demonstrate that MTHF acts in cryptochrome 3 as a functional antenna for the photoreduction of FAD.     

Human and Drosophila cryptochromes are light activated by flavin photoreduction in living cells

Cryptochromes are a class of flavoprotein blue-light signaling receptors found in plants, animals, and humans that control plant development and the entrainment of circadian rhythms. In plant cryptochromes, light activation is proposed to result from photoreduction of a protein-bound flavin chromophore through intramolecular electron transfer. However, although similar in structure to plant cryptochromes, the light-response mechanism of animal cryptochromes remains entirely unknown. To complicate matters further, there is currently a debate on whether mammalian cryptochromes respond to light at all or are instead activated by non-light-dependent mechanisms. To resolve these questions, we have expressed both human and Drosophila cryptochrome proteins to high levels in living Sf21 insect cells using a baculovirus-derived expression system. Intact cells are irradiated with blue light, and the resulting cryptochrome photoconversion is monitored by fluorescence and electron paramagnetic resonance spectroscopic techniques. We demonstrate that light induces a change in the redox state of flavin bound to the receptor in both human and Drosophila cryptochromes. Photoreduction from oxidized flavin and subsequent accumulation of a semiquinone intermediate signaling state occurs by a conserved mechanism that has been previously identified for plant cryptochromes. These results provide the first evidence of how animal-type cryptochromes are activated by light in living cells. Furthermore, human cryptochrome is also shown to undergo this light response. Therefore, human cryptochromes in exposed peripheral and/or visual tissues may have novel light-sensing roles that remain to be elucidated.     

The Class III Cyclobutane Pyrimidine Dimer Photolyase Structure Reveals a New Antenna Chromophore Binding Site and Alternative Photoreduction Pathways

Photolyases are proteins with an FAD chromophore that repair UV-induced pyrimidine dimers on the DNA in a light-dependent manner. The cyclobutane pyrimidine dimer class III photolyases are structurally unknown but closely related to plant cryptochromes, which serve as blue-light photoreceptors. Here we present the crystal structure of a class III photolyase termed photolyase-related protein A (PhrA) of Agrobacterium tumefaciens at 1.67-Å resolution. PhrA contains 5,10-methenyltetrahydrofolate (MTHF) as an antenna chromophore with a unique binding site and mode. Two Trp residues play pivotal roles for stabilizing MTHF by a double π-stacking sandwich. Plant cryptochrome I forms a pocket at the same site that could accommodate MTHF or a similar molecule. The PhrA structure and mutant studies showed that electrons flow during FAD photoreduction proceeds via two Trp triads. The structural studies on PhrA give a clearer picture on the evolutionary transition from photolyase to photoreceptor.     

Active site of Escherichia coli DNA photolyase: Asn378 is crucial both for stabilizing the neutral flavin radical cofactor and for DNA repair

Escherichia coli DNA photolyase repairs cyclobutane pyrimidine dimer (CPD) in UV-damaged DNA through a photoinduced electron transfer mechanism. The catalytic activity of the enzyme requires fully reduced FAD (FADH (-)). After purification in vitro, the cofactor FADH (-) in photolyase is oxidized into the neutral radical form FADH (*) under aerobic conditions and the enzyme loses its repair function. We have constructed a mutant photolyase in which asparagine 378 (N378) is replaced with serine (S). In comparison with wild-type photolyase, we found N378S mutant photolyase containing oxidized FAD (FAD ox) but not FADH (*) after routine purification procedures, but evidence shows that the mutant protein contains FADH (-) in vivo as the wild type. Although N378S mutant photolyase is photoreducable and capable of binding CPD in DNA, the activity assays indicate the mutant protein is catalytically inert. We conclude that the Asn378 residue of E. coli photolyase is crucial both for stabilizing the neutral flavin radical cofactor and for catalysis.     

Observation of an intermediate tryptophanyl radical in W306F mutant DNA photolyase from Escherichia coli supports electron hopping along the triple tryptophan chain

DNA photolyases repair UV-induced cyclobutane pyrimidine dimers in DNA by photoinduced electron transfer. The redox-active cofactor is FAD in its doubly reduced state FADH-. Typically, during enzyme purification, the flavin is oxidized to its singly reduced semiquinone state FADH degrees . The catalytically potent state FADH- can be reestablished by so-called photoactivation. Upon photoexcitation, the FADH degrees is reduced by an intrinsic amino acid, the tryptophan W306 in Escherichia coli photolyase, which is 15 A distant. Initially, it has been believed that the electron passes directly from W306 to excited FADH degrees , in line with a report that replacement of W306 with redox-inactive phenylalanine (W306F mutant) suppressed the electron transfer to the flavin [Li, Y. F., et al. (1991) Biochemistry 30, 6322-6329]. Later it was realized that two more tryptophans (W382 and W359) are located between the flavin and W306; they may mediate the electron transfer from W306 to the flavin either by the superexchange mechanism (where they would enhance the electronic coupling between the flavin and W306 without being oxidized at any time) or as real redox intermediates in a three-step electron hopping process (FADH degrees * <-- W382 <-- W359 <-- W306). Here we reinvestigate the W306F mutant photolyase by transient absorption spectroscopy. We demonstrate that electron transfer does occur upon excitation of FADH degrees and leads to the formation of FADH- and a deprotonated tryptophanyl radical, most likely W359 degrees. These photoproducts are formed in less than 10 ns and recombine to the dark state in approximately 1 micros. These results support the electron hopping mechanism.     

Animal type 1 cryptochromes. Analysis of the redox state of the flavin cofactor by site-directed mutagenesis

It has recently been realized that animal cryptochromes (CRYs) fall into two broad groups. Type 1 CRYs, the prototype of which is the Drosophila CRY, that is known to be a circadian photoreceptor. Type 2 CRYs, the prototypes of which are human CRY 1 and CRY 2, are known to function as core clock proteins. The mechanism of photosignaling by the Type 1 CRYs is not well understood. We recently reported that the flavin cofactor of the Type 1 CRY of the monarch butterfly may be in the form of flavin anion radical, FAD(*-), in vivo. Here we describe the purification and characterization of wild-type and mutant forms of Type 1 CRYs from fruit fly, butterfly, mosquito, and silk moth. Cryptochromes from all four sources contain FAD(ox) when purified, and the flavin is readily reduced to FAD(*-) by light. Interestingly, mutations that block photoreduction in vitro do not affect the photoreceptor activities of these CRYs, but mutations that reduce the stability of FAD(*-) in vitro abolish the photoreceptor function of Type 1 CRYs in vivo. Collectively, our data provide strong evidence for functional similarities of Type 1 CRYs across insect species and further support the proposal that FAD(*-) represents the ground state and not the excited state of the flavin cofactor in Type 1 CRYs.     

A new electron spin resonance assay for membrane asymmetry and entrapped volume of unilamellar lipid vesicles based on photoreduced flavin adenine dinucleotide

A new ESR assay has been developed for the characterization of unilamellar lipid vesicles. It is based on the reduction by photogenerated FADH2 of amphiphilic spin-labels having the spin in the polar group. FADH2 is generated in situ under anaerobic conditions from its oxidized form (FAD) by photoreduction in the presence of excess EDTA as the reducing agent. Photoreduction is induced by exposing the FAD/EDTA mixture to white light of a commercial slide projector. FADH2 as an impermeable agent reduces spin-label molecules located on the outer layer of the bilayer that are readily accessible in a first fast reaction; spin-label located on the inner layer of the bilayer is reduced in a second slow reaction. The ESR assay is suitable for the routine characterization of unilamellar membrane vesicles: it allows the determination of the vesicle size, the entrapped volume, the bilayer asymmetry, the bilayer integrity, and the vesicle stability. The ESR assay developed is of general applicability: it can be used with charged and uncharged bilayers which may be labeled with either neutral or charged spin-labels. An assessment of the new ESR assay is given in comparison to the existing ascorbate method which uses sodium ascorbate as the reducing agent. Various other potential reducing agents for spin-labels have been tested and found unsuitable for the ESR assays discussed here.     

Mechanistic studies on the intramolecular one-electron transfer between the two flavins in the human endothelial NOS reductase domain

The object of this study was to clarify the mechanism of electron transfer in the human endothelial nitric oxide synthase (eNOS) reductase domain using recombinant eNOS reductase domains; the FAD/NADPH domain containing FAD- and NADPH-binding sites and the FAD/FMN domain containing FAD/NADPH-, FMN-, and a calmodulin-binding sites. In the presence of molecular oxygen or menadione, the reduced FAD/NADPH domain is oxidized via the neutral (blue) semiquinone (FADH(*)), which has a characteristic absorption peak at 520 nm. The FAD/NADPH and FAD/FMN domains have high activity for ferricyanide, but the FAD/FMN domain has low activity for cytochrome c. In the presence or absence of calcium/calmodulin (Ca(2+)/CaM), reduction of the oxidized flavins (FAD-FMN) and air-stable semiquinone (FAD-FMNH(*)) with NADPH occurred in at least two phases in the absorbance change at 457nm. In the presence of Ca(2+)/CaM, the reduction rate of both phases was significantly increased. In contrast, an absorbance change at 596nm gradually increased in two phases, but the rate of the fast phase was decreased by approximately 50% of that in the presence of Ca(2+)/CaM. The air-stable semiquinone form was rapidly reduced by NADPH, but a significant absorbance change at 520 nm was not observed. These findings indicate that the conversion of FADH(2)-FMNH(*) to FADH(*)-FMNH(2) is unfavorable. Reduction of the FAD moiety is activated by CaM, but the formation rate of the active intermediate, FADH(*)-FMNH(2) is extremely low. These events could cause a lowering of enzyme activity in the catalytic cycle.     

Steady-state and laser flash induced photoreduction of yeast glutathione reductase by 5-deazariboflavin and by a viologen analogue: stabilization of flavin adenine dinucleotide semiquinone species by complexation

Steady-state and laser flash photolysis techniques have been used to examine the photoreduction of yeast glutathione reductase by the one-electron reduction products of 5-deazariboflavin and the viologen analogue 1,1'-propylene-2,2'-bipyridyl. Steady-state photoreduction of the enzyme with the viologen generates the two-electron-reduced form, whereas photoreduction with deazaflavin generates the anion semiquinone. Flash photolysis indicates that the product of viologen radical reduction is also a semiquinone, suggesting that this species is rapidly further reduced by viologen in the steady-state experiment to form the EH2 enzyme. This reduction is apparently inhibited when deazaflavin is the photoreductant, perhaps due to complexation of the anion semiquinone with deazaflavin. Steady-state experiments demonstrate that complexation of the anion semiquinone with NADP+ also inhibits further reduction. Both one-electron reduction reactions of oxidized glutathione reductase proceed at close to diffusion-controlled rates (second-order rate constants = 10(8)-10(9) M-1 s-1), despite the relatively buried nature of the FAD cofactor. Addition of NADP+ and oxidized glutathione produced no effects on the kinetics of the initial entry of the electron into the enzyme. No kinetic evidence of intramolecular electron transfer involving the FAD and the protein disulfide was obtained during or subsequent to the initial one-electron reduction process. Thus, if this reaction occurs in the semiquinone, it must be quite rapid (k greater than 8000 s-1).