Primary events in the blue light sensor plant cryptochrome: intraprotein electron and proton transfer revealed by femtosecond spectroscopy.

Photoreceptors are chromoproteins that undergo fast conversion from dark to signaling states upon light absorption by the chromophore. The signaling state starts signal transduction in vivo and elicits a biological response. Therefore, photoreceptors are ideally suited for analysis of protein activation by time-resolved spectroscopy. We focus on plant cryptochromes which are blue light sensors regulating the development and daily rhythm of plants. The signaling state of these flavoproteins is the neutral radical of the flavin chromophore. It forms on the microsecond time scale after light absorption by the oxidized state. We apply here femtosecond broad-band transient absorption to early stages of signaling-state formation in a plant cryptochrome from the green alga Chlamydomonas reinhardtii. Transient spectra show (i) subpicosecond decay of flavin-stimulated emission and (ii) further decay of signal until 100 ps delay with nearly constant spectral shape. The first decay (i) monitors electron transfer from a nearby tryptophan to the flavin and occurs with a time constant of τ(ET) = 0.4 ps. The second decay (ii) is analyzed by spectral decomposition and occurs with a characteristic time constant τ(1) = 31 ps. We reason that hole transport through a tryptophan triad to the protein surface and partial deprotonation of tryptophan cation radical hide behind τ(1). These processes are probably governed by vibrational cooling. Spectral decomposition is used together with anisotropy to obtain the relative orientation of flavin and the final electron donor. This narrows the number of possible electron donors down to two tryptophans. Structural analysis suggests that a set of histidines surrounding the terminal tryptophan may act as proton acceptor and thereby stabilize the radical pair on a 100 ps time scale.

Photoreaction of plant and DASH cryptochromes probed by infrared spectroscopy: the neutral radical state of flavoproteins.

Flavoprotein radicals are important intermediates in many biochemical processes. In the blue light sensor plant cryptochrome, the radical state acts as a signaling state. An isolation and assignment of infrared bands of flavin radicals in the most relevant spectral region of carbonyl stretches is missing because of their overlap with absorption of water and the protein moiety. In this study, the neutral radical state of flavoproteins was investigated by Fourier transform infrared difference spectroscopy. The light-induced conversion of oxidized to neutral radical state was monitored in a plant cryptochrome and that of radical to fully reduced state in a DASH cryptochrome. A pure difference spectrum of flavin radical minus oxidized state was obtained from a point mutant of a phototropin LOV (light-, oxygen-, or voltage-sensitive) domain. The analysis of the spectra revealed a correlation between the frequencies of carbonyl vibrations of the flavin radical state and those of its visible absorption. Plant cryptochrome shows a very low frequency of the carbonyl stretch in the radical state. It is postulated that the downshift is caused by the charge of an adjacent aspartate, which donated its proton to flavin N(5). Contributions from the protein moiety to the spectra were isolated for DASH and plant cryptochromes. As a conclusion, the photosensitive domain of plant cryptochromes shows changes in secondary structure upon illumination, which might be related to signaling.

Microsecond light-induced proton transfer to flavin in the blue light sensor plant cryptochrome.

Plant cryptochromes are blue light photoreceptors that regulate key responses in growth and daily rhythm of plants and might be involved in magnetoreception. They show structural homology to the DNA repair enzyme photolyase and bind flavin adenine dinucleotide as chromophore. Blue light absorption initiates the photoreduction from the oxidized dark state of flavin to the flavin neutral radical, which is the signaling state of the sensor. Previous time-resolved studies of the photoreduction process have been limited to observation of the decay of the radical in the millisecond time domain. We monitored faster, light-induced changes in absorption of an algal cryptochrome covering a spectral range of 375-750 nm with a streak camera setup. Electron transfer from tryptophan to flavin is completed before 100 ns under formation of the flavin anion radical. Proton transfer takes place with a time constant of 1.7 micros leading to the flavin neutral radical. Finally, the flavin radical and a tryptophan neutral radical decay with a time constant >200 micros in the millisecond and second time domain. The microsecond proton transfer has not been observed in animal cryptochromes from insects or photolyases. Furthermore, the strict separation in time of electron and proton transfer is novel in the field of flavin-containing photoreceptors. The reaction rate implies that the proton donor is not in hydrogen bonding distance to the flavin N5. Potential candidates for the proton donor and the involvement of the tryptophan triad are discussed.

Blue light induces radical formation and autophosphorylation in the light-sensitive domain of Chlamydomonas cryptochrome.

Cryptochromes are sensory blue light receptors mediating various responses in plants and animals. Studies on the mechanism of plant cryptochromes have been focused on the flowering plant Arabidopsis. In the genome of the unicellular green alga Chlamydomonas reinhardtii, a single plant cryptochrome, Chlamydomonas photolyase homologue 1 (CPH1), has been identified. The N-terminal 500 amino acids comprise the light-sensitive domain of CPH1 linked to a C-terminal extension of similar size. We have expressed the light-sensitive domain heterologously in Escherichia coli in high yield and purity. The 59-kDa protein bears exclusively flavin adenine dinucleotide in its oxidized state. Illumination with blue light induces formation of a neutral flavin radical with absorption maxima at 540 and 580 nm. The reaction proceeds aerobically even in the absence of an exogenous electron donor, which suggests that it reflects a physiological response. The process is completely reversible in the dark and exhibits a decay time constant of 200 s in the presence of oxygen. Binding of ATP strongly stabilizes the radical state after illumination and impedes the dark recovery. Thus, ATP binding has functional significance for plant cryptochromes and does not merely result from structural homology to DNA photolyase. The light-sensitive domain responds to illumination by an increase in phosphorylation. The autophosphorylation takes place although the protein is lacking its native C-terminal extension. This finding indicates that the extension is dispensable for autophosphorylation, despite the role it has been assigned in mediating signal transduction in Arabidopsis.