ACTION SPECTRA OF PHYTOCHROME IN VIVO*

Abstract— A method is described to determine spectral properties of phytochrome in vivo. For photochrome in 7-day-old dark-grown Cucurbita pepo L. seedlings the mole fraction of the far-red-absorbing form (P_fr) present at photoequilibrium at 664 nm was found to be 0.76 ± 0.02 in vivo. Based on reflectance measurements, the photon fluence rate just below the surface of the cotyledons was calculated. Local rates of photoconversion for known local fluence rates were measured across cotyledons after non-saturating irradiations with wavelengths between 544 and 781 nm and in situ molar photoconversion coefficients were obtained. In contrast to purified oat phytochrome, the in situ molar photoconversion coefficients for P_fr show a strong shoulder between 660 and 700 nm. The maximum of P_fr absorption is at 726 nm. An isosbestic point of phytochrome is found at 686 nm. The mole fraction of P_fr present at photoequilibrium with 686 nm light is 0.58. The ratio of photoconversion quantum yields (that for P_r→ P_fr divided by that for P_fr→ P_r) is 1.38 ± 0.06.     

INTERMEDIATES IN THE PHOTOCONVERSION OF FUNCTIONAL PHYTOCHROME IN FERN SPORES OF Dryopteris-I DEMONSTRATION AND QUANTITATIVE CHARACTERIZATION OF THE PHOTOCHROMIC SYSTEM Pr⇔ Ii700USING NANOSECOND-LASER PULSES*,†

Abstract— Spores of Dryopteris paleacea and D. filix-mas are positively photoblastic with an optimum in the action spectrum around 665 nm. Light is perceived by phytochrome and the relationship between germination and mole fraction of the far-red-absorbing form of this pigment, P_fr, was investigated with saturating irradiations between 662 and 747 nm under low-fluence-rate conditions. These control irradiations establish a proportion of the total phytochrome, P,_tot, as P_fr with P_fr/P_tot–φ at equilibrium. These φ -values were calculated according to data for native oat phytochrome (Kelly and Lagarias, 1985, Biochemistry 24, 6003) and the spectral characteristics of the interference filters. With this method a linear relationship could be found between φ and germination from 2 to 70% for D. paleacea and from 2 to 90% for D. filix-mas, if probit germination was plotted vs probit φ This correlation formed the basis of investigating the phytochrome photoconversion by dye-laser pulses of 380 ± 30 ns under high-fluence-rate conditions, and thus to test quantitatively the impact of the photoreversibility of intermediate reactions of the photoconversion and the red-absorbing form of phytochrome, P_fr on the final P_fr-level. Spore germination was initiated by a single-laser pulse in the range from 592 to 700 nm. The most effective wavelengths were 649 and 660 nm in both species, and at saturation maximal germination (ca. 50%) was obtained from 592 to 665 nm for D. paleacea or ca. 60% germination from 592 to 670 nm for D. filix-mas. Both saturation levels correspond to a ø-value between 0.40 and 0.45. This significantly diminished photoconversion is a consequence of the high-fluence-rate conditions during the laser pulse which establishes the photochromic system between P_r and a set of very early intermediates, Iⁱ_700, (= P_r? Iⁱ₇₀₀). This system can be described by the extinction coefficients of P_r and the intermediates Iⁱ₇₀₀, and by the quantum yields, 4,φ for the forward and reverse reactions as φ If φ is calculated, assuming a quantum yield of 1:1 for both reactions and with the extinction coefficients of P_r and Iⁱ_7(l() (= lumi-R) given by Eilfeld and Riidiger (1985, Z. Naturforsch. 40c , 109), significantly higher values are calculated for / as compared to φ found in the control experiments. These results can be explained either: (i) with a quantum yield ratio φ_pr-φ1700: φ_1700φpr=1:1 and an assumed additional dark reaction leading from Iⁱ₇₀₀ or later intermediates back to P_r: or (ii) with a quantum yield ratio φ_{pr φ 1700}: φ_{1700 φpr}=1:2. In this case all Iⁱ₇₀₀ have to relax to P_fr. In this case all Iⁱ₇₀₀ have to relax to P_fr.     

PHOTOCONTROL OF PHYTOCHROME DESTRUCTION IN GRASS SEEDLINGS. THE INFLUENCE OF WAVELENGTH AND IRRADIANCE

Abstract— –The kinetics of phytochrome destruction in vivo of coleoptiles and mesocotyls of etiolated grass seedlings (Avena sativa L., Zea mays L.) in continuous light were investigated using wavelength and irradiance as experimental variables. In contrast to dicotyledonous seedlings, the destruction reaction of these monocotyledons is saturated at very low levels of the far-red absorbing form of phytochrome, P_fr (e.g. at 1% of total phytochrome, corresponding to the photostationary state established by 727 nm light, in 2.5-day-old dark-grown Avena). On the other hand, the first-order rate constant of monocotyledon destruction may be at least one order of magnitude larger than in dicots, as indicated by the zero-order rate measured in the presence of saturating amounts of P_fr (τ_l/2 1.5 min in Avena). At sub-saturation P_fr levels, the destruction rate was found to be determined by the rate constants of the photoreactions over a wide range of wavelengths and irradiances. These results can be interpreted in terms of a destruction enzyme with high catalytic efficiency but limited availability. Analysis of in vivo binding of phytochrome to a pelletable cell structure during destruction revealed that both the pelletable and the non-pelletable fraction lose photoreversiblility with similar rates and thus provide no useful information with respect to a causal relationship between the two processes. However, due to the short half-life of P_fr at sub-saturation levels (which make the photoreactions and intermediary processes rate-limiting for destruction even at relatively high irradiances) the existence of a similarly rapid dark-reaction between the photoreactions producing P_fr and the destruction reaction could be demonstrated. This dark reaction displays the properties of P_fr binding to a receptor site.     

THE BLUE ANOMALOUS EMISSION OF LARGE AND SMALL PHYTOCHROME*

–Small and immunoaffinity-purified large phytochrome (P_r and P_fr) show a so-called anomalous fluorescence with λ^em_max= 470 and 440 nm, respectively, when irradiated within the blue absorption band. Model studies indicate that this emission arises from a dipyrromethenone partial structure produced by a nucleophilic addition to the central carbon C-10 of the bilindione chromophore. The anomalous emitter of phytochrome is thus similar to one bilirubin conformer which has previously been found to contribute to the absorption and emission of the bile pigment.     

THE EFFECT OF DEUTERIUM OXIDE ON THE FLUORESCENCE AND PHOTOTRANSFORMATION OF 124 kDALTON PHYTOCHROME*

Abstract— To probe the nature of primary photoprocess and the mechanism of the phototransformation of undegraded 124 kDa oat phytochrome, solvent deuterium isotope effects on the fluorescence and phototransformation of phytochrome have been investigated. The fluorescence intensity and lifetime of phytochrome (P_r form) are greater in D₂0-buffer than in H₂O-buffer, suggesting a possible involvement of proton transfer in the primary photoprocess of phytochrome. Although the photostationary equilibrium (P_r to P_fr ratio) was not altered by deuterium oxide, in contrast to degraded phytochrome, the rate constants of both transformations, P_r→ P_fr and P_fr→ P_r were enhanced by up to 24%. The P_r to P_fr phototransformation of degraded phytochrome, however, was retarded by about the same percentage in D₂O. These opposite effects of D₂O with degraded and undegraded phytochromes underscore the fact that the P_r form from the former reverts to the P_r form in the dark, apparently catalyzed by deuterated general and/or conjugate acidic group(s). With the degraded phytochrome the deuterium oxide enhancement of the rate of dark reversion was approximately 2-fold (Sarkar and Song, 1981). Both the fluorescence intensity and the rates of phototransformation of phytochrome were enhanced in D₂O with successive photocyclings (P_r→ P_fr→ P_r→ P_fr→ P_r etc.) with alternating red and far-red irradiation. It has been proposed that successive photocycling of phytochrome in D₂O results in proton-deuteron exchange in the partially exposed P_tr chromophore and/or its surrounding amino acid residues.     

STUDIES ON PHYTOCHROME PHOTOCONVERSIONS IN VITRO WITH LASER-INDUCED OPTOACOUSTIC SPECTROSCOPY*

After excitation at room temperature with a 15 ns dye laser pulse, phytochrome (60 kDalton) from etiolated oat seedlings was studied by optoacoustic spectroscopy, which records the heat emission caused by non-radiative deactivation processes of the photoexcited molecule. The action spectrum for the heat emitted by P_r deviates from the absorption spectrum around 610 and 695 nm, indicating the build-up of photoproduct(s) within 15 ns after excitation. It is proposed that the 695 nm product is identical with I₇₀₀ and lumi-R known to be the first intermediate on the P_r× P_fr pathway, and that the photochemical back reaction of I₇₀₀ to P_r occurs on the same time scale. About 90% of the absorbed light energy was lost by radiationless deactivation. Values for the rate constants of excited state deactivation of P_r and for the internal energy content difference of the primary photoproducts are calculated.     

ON THE PRIMARY PHOTOPROCESS OF 124-kdalton PHYTOCHROME

The photoreaction between P_τ and the first detectable intermediate, lumi-R, of 124-kdalton oat phytochrome has been investigated at low temperatures. The temperature dependence of the quantum yields of the photoreactions, P_τ to lumi-R and lumi-R to P_τ, has been determined. From measurements over a temperature range from 119 to 155 K, an activation barrier of 3.6 ± 0.5 kJ mol ₁ is found for the photoreaction of P_τ with 661-nm actinic light. A higher value (5.7 ± 0.7 kJ mol ^-1) is found for the photoreaction of lumi-R to P^τ. with 698-nm actinic light. Increased quantum yields are found in deuterated buffer solutions at low temperatures. The activation energies for deuterated phytochrome (3.2 ± 0.7 kJ mol^–1 for P_τ with 661-nm irradiation and 6.2 ± 1.2 kJ mol^-1 for lumi-R at 698-nm irradiation) are identical within the limits of error with those of protonated phytochrome. The lack of a deuterium effect for the activation energies favors the Z,E-isomerization rather than proton transfer or tautomerization for the chromophore photochemistry during P_τ⇄lumi-R conversion.     

Results of studies of potential light spectrum effects on human performance

Abstract— Sensitization of the phytochrome-mediated germination at 20°C of lettuce seeds (Lactuca sativa L. cv. Grand Rapids) by pretreatment at 4°C, 28°C, or on 1% ethanol, was studied. The 660 nm fiuence-response characteristics were similarly biphasic for all sensitizing treatments and displayed responses at very low fluences (VLFR) as well as responses characteristic of non-sensitized seeds at 10000-fold higher, low fluences (LFR). Maximum VLFR increased with the duration of sensitizing treatments. However, the fluence ranges required for the two types of responses remained relatively constant. These and additonal responses of sensitized seeds to 730 nm fluences were compared to simulations of a mechanism involving a receptor, X, and based on the dimeric structure of phytochrome in which each monomer is independently phototransformed from the inactive (P_r) to the active (P_fr) form. The fluence requirements for phytochrome photoconversion in seeds were determined to be similar to those of purified Avena phytochrome in vitro, on which photochemical parameters for the simulations were based. The analyses suggest that P_r:P_fr-Xand P_fr:P_fr-X are responsible, respectively, for the VLFR and the LFR, and that sensitization involves membrane influences on the activity of P_r:P_r-X. They also suggest the concentration of X to be about 0.001 that of total phytochrome dimer in this system.     

THE KINETICS OF THE EARLY STAGES OF THE PHYTOCHROME PHOTOTRANSFORMATION Pr→ Pfr. A COMPARATIVE STUDY OF SMALL (60 kDalton) and NATIVE (124 kDalton) PHYTOCHROMES FROM OAT

A comparative study of the decay kinetics of photogenerated transients from small (60 kDalton) and native (124 kDalton) oat phytochrome in the red-absorbing form (P_r) in phosphate buffer containing 5 mM ethylenediamine tetraacetic acid, pH 7.8, (PB) and in PB containing 20% ethylene glycol, has been carried out in the temperature range 275–298 K. The analysis confirmed that at least two primary photoproducts, intermediates Iⁱ₇₀₀s and Iⁱ_7oo are formed from P_r. The kinetic parameters, as observed in PB at 695 nm and 275 K, are similar for the I₇₀₀ intermediates of both small and native phytochrome. Namely, the lifetimes are about 21 μs (component percentages 38%) for the I Iⁱ₇₀₀s and about 200 μ.s (62%) for the Iⁱ₇₀₀S- Arrhenius preexponential factors (A) of about 10¹⁶ and 10¹⁵ s-¹and activation energies of about 61 and 56 kJ/mol were measured for the absorbance decays of the I₇₀₀S of small and native phytochrome, respectively. The kinetic data favour parallel paths for the formation of the Iⁱ₇₀₀s from P_r, and the activation parameters indicate that the primary photoreactions of the transformation from P_r to the far-red-absorbing form are restricted to the chromophore within the protein. Moreover, the relatively modest temperature dependence of the lifetimes of the Iⁱ₇₀₀^S from small and native P_r supports the working hypothesis that the ground state reactions to the Iⁱ_bl, intermediates–although somewhat influenced by the polypeptide fragment that is removed upon degradation of native to small P_r–are localized to the chromophore, as is most probably the case also for the primary photoreactions. The effect of the addition of 20% ethylene glycol on the pre-exponential factors of the time-dependent decay functions is discussed in similar terms of the early stages of the phototransformation.     

KINETICS OF Pfr APPEARANCE IN Amaranthus caudatus‡

Abstract— The kinetics of the far-red absorbing form of phytochrome (P_fr) appearance from intermediates in the pathway from the red absorbing form of phytochrome (P_r) to P_fr that accumulate under high fluence rate white light have been investigated in 3-day old dark grown Amaranthus caudatus seedlings. The appearance of P_(r after a 5 s white light pulse was measured over the temperature range -8 to 25^°C in samples flushed with O₂ or N₂. Over the whole temperature range under anaerobic conditions the kinetics of the slowest component of P_fr appearance are faster than in the presence of O₂. Arrhenius plots are linear over this temperature range and indicate the activation energy for the slowest component of P_fr appearance is 44.05 ± 1.97 kJ mol^?1 for O₂ and 53.69 ± 4.86 kJ mol^?1 for N₂.     

CHARACTERIZATION OF A MICROSECOND INTERMEDIATE IN THE LASER FLASH PHOTOLYSIS OF SMALL PHYTOCHROME FROM OAT

Abstract— Irradiation of small phytochrome from oat in its P_r form with 15 ns laser pulses of different wavelengths(605–655 nm) gave rise to a difference absorption with maxima at 400 and 685 nm for the first detectable transient. Bleaching of a 660 nm band was observed, non-recuperable up to 1 ms. The transient absorption has a lifetime of 70±15 μs at 273 K. The transient is tentatively identified as lumi-R and the conformation of its chromophore is postulated to be more extended than that of P_r. A deviation from the exponential decay of the lumi-R absorption at 284 and 300 K and the lack of observable enhancement of the far-red absorption within 1 ms are interpreted in terms of the appearance of still other intermediates on this time scale between lumi-R and P_fr phytochrome.     

INTERMEDIATES IN THE PHOTOCONVERSION OF FUNCTIONAL PHYTOCHROME IN FERN SPORES OF Dryopteris–II. In vivo KINETICS OF THE DECAY OF Ii700 AND OF THE FORMATION OF Pfr STUDIED WITH A DOUBLE-LASER APPARATUS*

Abstract— Photoconversion of the red-light-absorbing form of phytochrome, P_r, to the far-red-light-absorbing form, P_fr, was investigated in vivo at 22°C with 600 or 800 ns laser pulses of high spectral purity and induction of spore germination in Dryopteris paleacea was used as indicator for the progress of photoconversion. This reaction is initiated by a saturating R-laser pulse of 648.5 nm, establishing an equilibrium of the photochromic system between P_r and the very early intermediates, Iⁱ₇₀₀ (P_rφ Iⁱ₇₀₀)- The decay of Iⁱ₇₀₀ as well as the formation of P_fr was recorded by the application of a second pulse varied between 698 and 717.5 nm, which inhibits the formation of P_lr being absorbed predominantly by Iⁱ₇₀₀or P_fr, respectively. The most effective inhibition for the second pulse is found up to 10 u.s after the first pulse and this is interpreted by photoreversion of Iⁱ₇₀₀ to P_r; thus reducing the formation of P_fr from Iⁱ₇₀₀. This early inhibition decreases between 10 μs to 100 ms after the R-laser pulse, as a result of the decay of Iⁱ_bl to a bleached species I,;. This decay can be described by three first order kinetics with the rate constants k₁₂= 16830 ± 2970 s^-1, k₁₂= 666 ± 218 s^-1,k₁₃= 9.8 ± 0.9 s^-1. A second inhibition, due to the formation of P_fr, is found for dark intervals <100 ms and can be described by two first order kinetics with the rate constants k₂₁= 2.9 ± 0.6 s^-1 and k₂₂= 0.17 s^-l.     

EVIDENCE FOR THE EXISTENCE OF MEMBRANE-ASSOCIATED PHYTOCHROME IN THE CELL

Abstract Comparative fluorescence and photochemical studies of phytochrome in etiolated seedlings of maize and in soluble and membrane-containing fractions isolated from them were camed out. The membrane fractions prepared in the absence of Mg²⁺ from etiolated coleoptiles contained 13% of total photoreversible phytochrome, which was readily solubilized by mild detergents. Its molecular size was indistinguishable from soluble phytochrome and equal to nondegraded maize phytochrome. Low-temperature fluorescence studies with intact tissue found that the position of the emission maximum at 85 K (λ_max) and the extent of the phototransformation of the red-absorbing form (Pr) into the first stable photoproduct, lumi-R, at 85 K (γ₁), varied in different parts of etiolated seedlings: λ_max and γ₁ reached their maximum values in the tips of coleoptiles and roots, 686 nm and 0.30–0.40, whereas the lowest values, 682 nm and ca 0.05, were observed in the root base. These parameters correlated well with those obtained for the pigment in the soluble and membrane-containing fractions: 684 and 680 nm, and 0.33 and 0.06, respectively. The extent of the Pr phototransformation into the far red-absorbing form (Pfr) (γ₂) did not differ much: values of 0.80–0.85 and 0.70–0.75 correlated with the high and low values of γ₁. These variations of the parameters were interpreted in agreement with our previous observations in terms of two phytochrome A species whose relative concentrations vary depending on the experimental conditions—the longer wavelength bulk light-labile species with high γ₁ (Pr″), and the shorter wavelength minor light-stable species with low γ₁ (Pr″). Close similarity between Pr’and the soluble phytochrome and between Pr″ and the membrane-bound phytochrome points to the possible origin of the native Pr’and PrPrime; species, thus providing evidence for the existence of membrane-bound pigment in the cell.     

ANALYSIS OF Pfr DESTRUCTION IN AMARANTHUS CAUDATUS L EVIDENCE FOR TWO POOLS OF PHYTOCHROME*

Abstract— Kinetics of the destruction of the far red absorbing form of phytochrome (P_fr), measured by in vivo spectroscopy, show two phases: after a saturating red light pulse, rapid first order decay results in the loss of most, but not all, of the detectable P_rr; decay of the rest is much slower. The concentration of the more stable P_fr is positively correlated to the concentration of the total P_fr established at time zero. The linear relationship between total and ‘stable’ P_fr exludes the existence of a threshold level of P_fr for fast destruction. Photoconversion of the P_r (red absorbing form of phytochrome) present during the slow decay, by exposure to a second light pulse, is followed by fast destruction of most of the newly formed P,_r, whereas some P_fr formed by the first pulse still remains. The experiment suggests that not all P_fr molecules are accessible to the same destruction mechanism, i.e. there are two populations of P_fI.     

EXCITED STATE BEHAVIOR OF PHYTOCHROME Pr

The primary excited state processes of phytochrome, the plant chromoprotein responsible for most photomorphogenetic responses, are investigated by picosecond intensity-dependent transmission measurements. At sufficient high excitation intensity (starting at photon flux densities of about 1′10²⁵ cm^?2 s^?l) a moderate bleaching of the absorption is observed. For the quantitative analysis of the experimental data a rate equation system approach for the energy levels responsible for the ultrafast transformation P_r→ lumi-R and the photon transport through the sample was utilized. The following was found for the excited state parameters of the phytochrome P_r: (1) an excited state absorption of the same order of magnitude as the ground state absorption (cross section: S?_exc= 4′10^?16 cm^?2 at 650 nm), (2) a fast relaxation of the higher excited singlet state on the femtosecond time scale.     

AN ATTEMPT TO LOCALIZE THE THRESHOLD REACTION IN PHYTOCHROME-MEDIATED CONTROL OF LIPOXYGENASE SYNTHESIS IN THE MUSTARD SEEDLING

Abstract —Synthesis* of the enzyme lipoxygenase (LOG)? in the cotyledons of the mustard seedling (Sinapis alba L.) is controlled by phytochrome (P_fr) through a threshold (all-or-none) mechanism. The data of the present paper confirm the previous assumption (Oelze-Karow and Mohr, 1973) that the primary reaction of P_fr (P_fr+ X → P_frX ? P_frX‘) is the site of the highly cooperative threshold reaction. Suppression of LOG synthesis depends on the presence of P_frX’. However, P_frX‘ is only stable above the threshold level of P_fr. If the level of P_fr is below the threshold, P_frX is stable, and no suppression of LOG synthesis occurs. As long as the level of P_fr remains below the threshold, no destruction of P_fr takes place. Destruction of P_fr occurs only as long as [P_fr]?is above the threshold level. Thus the simplest formulation of the actual threshold reaction in the LOG response is P_frX?_frX’ state at [P_fr] below threshold no P_fr destruction LOG synthesis suppressed state at [P_fr] above threshold P_fr destruction(¹k_d LOG synthesis unimpaired The reversible threshold reaction is thus an integral part of the “primary reaction” of P_fr occurring at the “matrix” specific for the LOG response. The data and conclusions on the LOG response are consistent with an “open phytochrome-receptor model” recently advanced by E. Schäfer (1975). The data are not consistent with the concept that a rapid dark reversion (P_fr→P_r) exists in dicotyledonous seedlings and that the degree of P_fr dark reversion strongly depends on the initial photostationary state, φ?, established by a saturating light pulse.     

Comparison of the protein conformations between different forms (Pr and Pfr) of native (124 kDa) and degraded (118/114 kDa) phytochromes from Avena sativa

Abstract— Circular dichroic properties of native, 124 kDa phytochrome from etiolated Avena sativa seedlings have been examined and compared with those of degraded phytochrome (118/114 kDa). The CD spectrum of the P_r form of 124 kDa phytochrome does not differ significantly in the visible region from that of 118/114 kDa P_r. In contrast, the CD spectrum of the P_fr form of 124 kDa phytochrome differs from that of the 118/114 kDa species in the far-red, red and blue regions of the spectrum. This result confirms that the NH₂-terminal polypeptide segment has a critical role in chromophore-protein interaction in the P_fr but not in the P_r form. In the UV region, 124 kDa phytochrome exhibits a photoreversible difference between the CD spectra of P_r and P_fr, whereas no such difference is observed for 118/114 kDa preparations. These data suggest a possible photoreversible change in secondary structure of the 124 kDa phytochrome polypeptide that requires the presence of the 6/10 kDa NH₂-terminal domain to occur.     

Stabilization of phytochrome intermediates by low temperature

Abstract— The photocon versions between the red-absorbing form (P_r) and the far-red absorbing form (P_fr) of phytochrome were examined at low temperatures. Partially purified preparations of the chromoprotein were examined in phosphate buffer and in 25 per cent buffer plus 75 per cent glycerol. Actinic irradiation of P, below – 150°C produces an intermediate with maximum absorbance near 695 nm, R₆₉₅. Actinic irradiation of R₆₉₅ converts it back to P. Above – 150°C R₆₉₅ decays to a low extinction form of phytochrome, R, which in turn decays to P_fr upon further warming. Light absorption by P_fr below – 150°C results in the formation of an intermediate form of phytochrome with maximum absorbance near 660 nm, FR₆₆₀. FR₆₆₀ decays upon warming to a lower extinction form, FR'. which in turn decays to P_r on continued warming. No evidence was obtained to suggest that any of the observed intermediate states are involved in more than one direction of phytochrome photocon version.     

The Complexity of the Pr to Pfr Phototransformation Kinetics Is an Intrinsic Property of Native Phytochrome*

Several possible origins of the complex phytochrome red to far-red light-absorbing phytochrome (P_r P_fr) phototransformation kinetics in the nanosecond-to-second time range have been examined. Heterogeneity based on protein sequence is ruled out as an origin of the multi-component kinetics because recombinant 124 kDa oat phytochrome A apoprotein reconstituted with phytochro-mobilin and the native protein are very similar in this regard throughout this time range. The P_r forms of native 124 kDa oat phytochrome A and of a homogeneous recombinant 65 kDa chromoprotein fragment exhibit thermochromic properties interpreted as arising in each case from the presence of two P_r species in thermal equilibrium. They exhibit identical photochemical properties. The complex kinetics therefore cannot result from P_r heterogeneity either. Thus, the presence of two P_r forms in equilibrium (P_r,₆₇₅ and P_r,₆₅₅) and the complex multiex-ponential P_rP_fr phototransformation kinetics observed in all time ranges are intrinsic properties of the homogeneous holoprotein of oat phytochrome A.     

Fluorescence and Photochemistry of Recombinant Phytochrome from the Cyanobacterium Synechocystis

Fluorescence and photochemical properties of phytochrome from the cyanobacterium Synechocystis were investigated in the temperature interval from 293 to 85 K. The apoprotein was obtained by overexpression in Escherichia coli and assembled to a holophytochrome with phycocyanobilin (PCB) and phytochromobilin (PφB), Syn(PCB)phy and Syn(PφB)phy, respectively. Its red-absorbing form, Pr, is characterized at 85 K by the emission and excitation maxima at 682 and 666 nm in Syn(PCB)phy and at 690 and 674 nm in Syn(PφB)phy. At room temperature, the spectra are blue shifted by 5–10 nm. The fluorescence intensity dropped down by ?15–20-fold upon warming from 85 to 293 K and activation energy of the fluorescence decay was estimated to be ca 5.4 and 4.9 kJ mol^?1 in Syn(PCB)phy and Syn(PφB)phy, respectively. Phototransformation of Pr upon red illumination was observed at temperatures above 160–170 K in Syn(PCB)phy and above 140–150 K in Syn(PφB)phy with a 2–3 nm shift of the emission spectrum to the blue and increase of the intensity of its shorter wavelength part. This was interpreted as a possible formation of the photoproduct of the meta-Ra type of the plant phytochrome. At ambient temperatures, the extent of the Pr phototransformation to the far-red-absorbing form, Pfr, was ca 0.7–0.75 and 0.85–0.9 for Syn(PCB)phy and Syn(PφB)phy, respectively. Fluorescence of Pfr and of the photoproduct similar to lumi-R was not observed. With respect to the photochemical parameters, Syn(PCB)phy and Syn(PφB)phy are similar to each other and also to a small fraction of phyA (phyA″) and to phyB. The latter were shown to have low photochemical activity at low temperatures in contrast to the major phyA pool (phyA″), which is distinguished by the high extent (ca 50%) of Pr photoransformation at 85 K. These photochemical features are interpreted in terms of different activation barriers for the photoreaction in the Pr excited state.