PHYTOCHROME MEDIATED CAROTENOID SYNTHESIS IN THE FUNGUS VERTICILLIUM AGARZCZNUM

Abstract— Ten minutes of red irradiation (R) increased carotenogenesis in Verticillium agoricinum and this effect was reversed by 10min of far-red (FR) irradiation indicating that phytochrome is involved. A far-red minus red difference spectrum of a crude extract shows a peak at 670 nm and a dip at 750 nm wavelength, values slightly larger than higher plant phytochrome. indicating the presence of phytochrome.     

THE ROLE OF HYDRATION IN THE PHOTOTRANSFORMATION OF PHYTOCHROME

Abstract— Changes in the visible absorption spectrum and in phototransformation of phytochrome have been found to be associated with dehydration and rehydration. These spectral properties explain the previously reported rapid appearance of phytochrome in imbibing seeds. No evidence was found for the orientation of the phytochrome chromophore in gelatin films or in preparations subjected to a shearing force.     

THE FUNCTION OF PHYTOCHROME IN THE NATURAL ENVIRONMENT—III. MEASUREMENT AND CALCULATION OF PHYTOCHROME PHOTOEQUILIBRIA

Abstract— Phytochrome photoequilibria have been measured in dark-grown Phaseolus uulgaris L . and Cucurbita pepo I . hypocotyl hooks which had been exposed to various natural and artificial radiation sources. Mean phytochrome photoequilibria ( φ ) varied from 0.20 within a wheat canopy to 0.54 above, although lower values were occasionally observed in densely shaded areas. Greater variation in phyto chrome photoequilibria and lower levels of P_fr were recorded within a sugar beet canopy. The range of photoequilibria was φ= 0.04 in dense shade to φ= 0.54 above the canopy. Photoequilibrium was achieved within 5 s in mid-day sunlight and approximately 30 s in dense canopy shade.
A close correlation was found between φ and the ratio of the quantum flux in the red and far-red wavelength bands (ζ) in broad spectrum (400–800 nm) radiation. This relationship allows direct prediction of φ from a knowledge of ζ. Phytochrome showed greatest sensitivity to spectral changes in the range ζ= zero to ζ= 1.0, which is the range found in the natural environment.
The observations provide support for the hypothesis that phytochrome is involved in the detection of shading by plants.     

LIGHT PROMOTION OF SEED GERMINATION IN Datura ferox IS MEDIATED BY A HIGHLY STABLE POOL OF PHYTOCHROME

Abstract— The duration of the far-red light-absorbing form of phytochrome (Pfr) of the photoreceptor pool involved in the control of seed germination was investigated for Datura ferox seeds. These seeds require both Pfr and alternating temperatures (20/30°C) to germinate. After 24 h imbibition (25°C), the seeds received pretreatment-light pulses providing different phytochrome photoequilibria (Pfr/P), followed by a 24 h dark incubation (25°C), and test-light pulses providing different Pfr/P immediately prior to transfer to alternating temperatures. Germination increased with increasing Pfr/P provided by the test-light pulses, but was unaffected by the pretreatment-light pulses. This suggests that phytochrome synthesis, phytochrome degradation and phytochrome-mediated changes in response to phytochrome were negligible. In other experiments, red light-pretreatment pulses were followed by dark incubations (25°C) of different duration before transfer to alternating temperatures. The proportion of Pfr remaining after the 25°C incubation period was estimated by comparing germination rates with those of seeds that received test-light pulses of known calculated Pfr/P immediately prior to the start of the cycles of alternating temperatures. More than 80% of the Pfr established by a Pfr/P= 0.87 light pulse was present and active even after 48 h dark incubation at 25°C. Surprisingly, when a pretreatmentlight pulse providing a Pfr/P= 0.70 was given, the reduction in [Pfr] was significantly faster.
Germination of Datura ferox seeds is under the control of a highly stable (type II like) phytochrome pool. Apparently, this pool follows Pfr dark reversion to the red light-absorbing form, the times to reach half the original Pfr pool being > 96 h or <14 h after light pulses providing Pfr/P= 0.87 or 0.70, respectively.     

LETTUCE SEED GERMINATION: EFFECTS OF HIGH TEMPERATURE AND OF REPEATED FAR-RED TREATMENT IN RELATION TO PHYTOCHROME

Abstract— At 37°C the active form of phytochrome in lettuce seed cannot function to promote subsequent germination. This effect of high temperature is distinct from thermal acceleration of dark reversion from the active form of phytochrome to the inactive form, and may be due to reversible denaturation of phytochrome.
Repeated brief irradiations with far-red light inhibit subsequent germination in the whole seed, whereas a similar irradiation regime results in a strong enhancement of the development of growth potential (ability to expand against an externally-imposed osmotic restraint) in the excised axial portion of the seed. A possible explanation for these two opposing results, in volving two different pigment systems with effective loci in different parts of the seed, is suggested.     

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.     

PICOSECOND DYNAMICS OF THE EXCITED STATE RELAXATIONS IN PHYTOCHROME

Abstract— A comparative study of the picosecond kinetics of rye ( Secale cereale L.) phytochrome, its 39 and 23 kDa chromopeptides and deuterated rye phytochrome has been carried out. Evidence is presented that the fluorescence decay of Pr contains a very short lifetime component (14 ps) which has escaped detection in the fluorescence studies reported so far. Thus, the overall decay is well described by four exponential components, two rapid (14 and 44 ps) and two slower ones (157 and 690 ps). The fluorescence decays of deuterated Pr and of a 39 and 23 kDa chromopeptide of Pr also require the analysis in terms of four exponentials for a good fit. Some of the lifetime and amplitude values obtained differ significantly from the values estimated for Pr. In the chromopeptides, the two longer components have distinctly slower decays. For the two faster components the lifetimes remain approximately the same, but their relative amplitudes vary greatly. In deuterated Pr, the lifetimes are affected only slightly by deuteration. In contrast, the decay amplitudes are strikingly altered. Moreover, from a rate equation simulation modelling the observed fluorescence kinetics, it turns out that the yields for the various deactivation steps in the chromopeptides and in deuterated Pr reveal differences from the corresponding values in Pr. The implications of the results presented with respect to the influence of the protein moiety of Pr on the picosecond relaxation process are discussed.     

CHANGES IN THE RATES OF PHOTOCONVERSION OF PHYTOCHROME DURING ETIOLATION IN MUSTARD SEEDLINGS

Abstract— The relative phytochrome photoconversion rates in cotyledons and hypocotylar hook of etiolating mustard ( Sinapis alba L.) seedlings were measured between 16 and 96 h after sowing. It was found that at constant fluence rates photoconversion rate in red light increases in both organs with time whereas the photoconversion rate in far-red (756 nm) light decreases with time of development. Since the isosbestic point remains constant, it was concluded that the observed changes cannot be attributed to changes of extinction coefficients. It was not possible, however, to decide whether the observed changes are due to changes of light attenuation or quantum yields.     

THE CONTROL BY PHYTOCHROME OF NITRATE REDUCTASE IN THE CURD OF LIGHT-GROWN CAULIFLOWER

Abstract— The activity of nitrate reductase from the curd of light-grown cauliflower ( Brassica oleracea (L) var botrytis (DC) 'St. Hilary') is modulated by nitrate and by light. Using broad-band sources of equal photosynthetically active radiation but with different proportions of red and far-red light, a linear relationship between nitrate reductase activity and ψ(Estimated phytochrome photoequilibrium) was obtained. This relationship, apparent after 8 h incubation, was maintained and little altered after 48 h incubation. The linearity was apparent between ψE 0.26 and ψE 0.69; ψE 0.26 being no more effective than a dark control. Far-red reversibility confirmed the involvement of phytochrome. Brief pulses of red light were also used to establish a range of phytochrome photoequilibria within the tissue. Again a linear relationship between ψ and nitrate reductase activity was obtained with a threshold for the response at ψ 0.3. With both monochromatic and broad-band sources it was seen that neither photon fluence rate nor duration of exposure affected the final activity of the enzyme and that phytochrome was acting solely through ψ (or [Pfr] since phytochrome is stable in this tissue) to bring about these responses.     

ON THE PHYSIOLOGICAL SIGNIFICANCE OF DARK REVERSION OF PHYTOCHROME IN THE MUSTARD SEEDLING

Abstract —We present physiological evidence using the threshold control of lipoxygenase synthesis† by P_fr in the mustard seedling (LOG response) that there is no dark reversion of phytochrome
which would be relevant for this response. Such Ptr which can be detected with the lipoxygenase response disappears exclusively through degradation with a half-life of 45 min at 25°C. De novo synthesis of P*_r in the hypocotylar hook takes place at a constant rate (zero order rate constant) irrespective of the level of P_r or P*_tot, i.e. there is no detectable feedback control of P_r synthesis during the period of experimentation. The data of the present paper are consistent with a quantitative phytochrome model (Scheme 1) which has been advanced and treated quantitatively in the companion paper (Oelze-Karow and Mohr, 1976).     

IN VIVO MEASUREMENTS OF THE PHYTOCHROME PHOTOSTATIONARY STATE IN FAR RED LIGHT

Abstract— The in vivo photostationary state, φ_fr= ([ P _fr]_fr/[ P ]), of phytochrome in far red light has been determined in mustard seedling cotyledons by three different methods. The φ_fr is a function of the length of time of etiolation ( t = 36 hr, φ_fr= 0·14; t = 72 – 120 hr, φ_fr= 0·075). The calculated φ_r= 0·8. The amount of P _tot is strongly dependent on the time of onset of far red light. These data imply that it would be almost impossible to maintain a constant level of P _fr in mustard cotyledons over a considerable period of time.     

BLUE LIGHT INDUCED PHOTOTRANSFORMATION OF PHYTOCHROME IN THE PRESENCE OF FLAVIN*

Abstract— Irradiation of the P_r form of phytochrome in the presence of flavin mononucleotide (FMN) which absorbs the actinic blue light yields P_fr at a rate greater than that in the absence of FMN. The actinic blue light absorbed by FMN enhances the phototransformation of P_r via the energy transfer from the former to the latter. On the other hand, the photoreversion of P_fr was inhibited by the presence of FMN when illuminated with blue light. The lack of photo-enhancement of the reversion of P_r, by blue light suggests that the P_fr chromophore (acceptor) transition dipole is virtually perpendicular to the FMN transition dipole, as the result of a chromophore reorientation in the P_r→P_fr phototransformation. The fact that blue light absorbed by flavin preferentially enhances the forward phototransformation of phytochrome while inhibiting the reversion may have an important implication in the high irradiance responses in plants in terms of a preferential accumulation of P_fr by blue light excitation.     

IN SlTU ESTIMATION OF SPATIAL DISTRIBUTION OF PHYTOCHROME ALONG THE AXIS OF THE ACTINIC BEAM

Non-stationary photoconversions of the two forms of the photochromic sensory plant pigment phytochrome are theoretically analyzed. It is shown that from actual in situ measurements of changes of absorbances caused by these photoconversions in a sequence of exposures to actinic light, one can calculate the spatial distribution of phytochrome along the path of the actinic beam. The necessary condition of such a calculation is the existence of a screen with a known spatial distribution, which must be obtained in an independent experiment. Thus, the possibility is proved to measure, instead of phytochrome spatial distribution, that of the screen which is a much larger chemical and optical body inside the object. Expressions to calculate the spatial distribution of phytochrome and to estimate the errors involved are presented in the present paper.     

APPARENT INCREASE IN PHOTODETECTABLE PHYTOCHROME IN THE PRESENCE OF CALCIUM CARBONATE*

Abstract— –Using squash seedling extracts ( Cucurbita pepo L.), we describe an apparent increase in photodetectable phytochrome content that is depended upon the use of either CaCO₃ or starch as a scattering agent and is also a function of preirradiation with red light of either intact tissue or crude extracts prior to sample preparation for spectrophotometric assay. This apparent increase in photodetectable phytochrome content requires about 1 h for full expression after addition of the scattering agent. If irradiations are given in vitro , the increase is partially reversed by far red light when using squash extracts, and is fully reversed with Aoena and Zea extracts. For squash extracts the magnitude of this increase. which is typically between 20 and 40%. is quantitatively correlated with both the amount of Pfr produced by a brief red irradiation and with the proportion of the total phytochrome pool that is pelletable upon centrifugation at 20,000 g . The correlation with pelletable phytochrome does not hold for Auena and Zea , at least when irradiations are gwen in uitro . The increase in photodetectable phytochrome may result from changed phytochrome extinction, changed phototransformation quantum yields, and/or specific trapping of phytochrome by the scattering agent as it settles. An important consequence of these data is that they indicate a need for caution when using a scattering agent during spectrophotometric assay of phytochrome.     

MODELS FOR THE CHROMOPHORE STRUCTURE OF THE PHOTOTRANSFORMATION INTERMEDIATES OF PEA PHYTOCHROME IN VITRO

Abstract— The changes in the chromophore structure of pea phytochrome during phototransformation in vitro from the red-light-absorbing form (P_r) to the far-red-light-absorbing form (P_fr), and from P_fr to P_r, were analysed in terms of wavelength and oscillator strength of absorption, using the zero-differential overlap approximation of the molecular orbital theory for electrons. The effect of a point-charge and a point-dipole on the optical absorption of phytochromobilin intermediates were examined using the stationary perturbation theory for degenerate states. The results indicate that the cis-trans photoisomerization of the pyrrole ring D, if any, occurred within 10 μs after a laser-flash excitation of the phytochrome, and that the conformations of phytochromobilin and the protein moiety of phytochrome were not significantly changed during the period of examination of phototransformation in either direction.     

INTERPRETATION OF THE 'DICHROIC ORIENTATION' OF PHYTOCHROME

The dichroic orientation of phytochrome observed both in the phytochrome-mediated phototropism in Adiantum protonemata and in the phytochrome-mediated chloroplast movement in Mougeotia were analyzed in terms of the orientation of the transition moment associated with the long-wavelength absorption band, assuming that phytochrome, associated with the plasma membrane, rotates around the normal to the membrane. The orientation of the long-wavelength transition moment of the phytochrome chromophore was calculated using the zero-differential overlap approximation of the molecular orbital theory for ir-electrons. The results indicate that the orientation of the long-wavelength transition moment mainly changes later than 2 ms after red light excitation of P_r, and that the different dichroic orientations of P_r and P_fr can be attributed to the change in the angle of the long-wavelength transition moment of phytochrome with the plasma membrane from 18^o to 72^o during phototransformation.     

PHYTOCHROME CONTROL OF THE DEVELOPMENT OF PHOTOPHOSPHORYLATION

In the cotyledons of the mustard (Sinapis ah L.) seedling the development of the capacity for photophosphorylation is strongly influenced by pretreatment of the seedling with red light pulses. The red light acts through phytochrome. After a red light pretreatment the capacity for photophosphorylation increases linearly with the chlorophyll content, at least up to 30 min after the onset of continuous white light. It is proposed that the reaction chain required for photophosphorylation is completed under the influence of phytochrome even in the absence of chlorophyll. As soon as chlorophyll becomes available photophosphorylation functions instantaneously. Without a red light pretreatment there is a lag of more than 15 min before photophosphorylation becomes detectable after the onset of continuous white light even though chlorophyll a is available. Although phytochrome strongly influences the rate of chlorophyll accumulation as well it is improbable that the control by phytochrome of development of photophosphorylation and of chlorophyll accumulation are causally connected.     

CIRCULAR DICHROISM OF THE PHYTOCHROME CHROMOPHORES IN NATIVE AND DENATURED STATE

Abstract— The circular dichroism spectra of oat phytochrome were recorded. Qualitatively, the same spectra were found for large (360 kilodaltons) and small (60 kilodaltons) phytochrome. Quantitative CD data were reported for small P_r and P_fr (photoequilibrium mixture with 20% P_r) in tris buffer (native state) and in acid urea (denatured state). Further, the CD spectra of a phytochromobilinpeptide in acid solution with and without urea were recorded. Differences between the data in native and denatured state are discussed.     

THE TEMPERATURE DEPENDENCE OF PHYTOCHROME TRANSFORMATIONS

Abstract— The kinetics of phytochrome transformation were examined over a 30°C temperature range (+5° to–25°C) in 75% glycerol. Two new intermediate reaction stages are described for the transformation of the red-absorbing form, P _r to the far-red absorbing form, P _fr The free energies, enthalpies and entropies of activation were obtained for five of the six reaction stages observed in the transformation of P _r to P _fr and for the two reaction stages observed in the reverse process. All exhibited positive entropies of activation with the maximum being 25 entropy units. The results suggest that the phototransformations between P _r and P _fr consist of relaxation processes beginning with the intermediate produced immediately upon absorption of a quantum of light and ending with either P _r or P _fr.