Aggregation of the 636 nm emitting monomeric protochlorophyllide form into flash-photoactive, oligomeric 644 and 655 nm emitting forms in vitro

Artificial formation of flash-photoactive oligomeric protochlorophyllide complexes was found in etiolated pea (Pisum sativum L. cv. Zsuzsi) epicotyl homogenates containing glycerol (40% v/v) and sucrose (40% m/v). The 77 K fluorescence emission spectra indicated that the ratio of the 644 and 655 nm emitting forms to the 636 nm form increased during 3 to 5-day incubation in the dark at −14 °C. Electron micrographs showed the presence of well-organized prolamellar bodies in the homogenates. The same phenomena were found when the homogenates were frozen into liquid nitrogen and thawed to room temperature in several cycles. Similar treatments of intact epicotyl pieces caused significant membrane destructions. In homogenates, the in vitro produced 644 and 655 nm emitting protochlorophyllide forms were flash-photoactive; the extent of phototransformation increased compared to that in native epicotyls. The newly appeared 692 nm chlorophyllide band showed a blue shift (similar to the Shibata shift in leaves), however this process took place only partially due to the effect of the isolation medium.These results prove that the in vitro accumulated 644 and 655 nm protochlorophyllide forms were produced from the flash-photoactive 636 nm emitting monomeric NADPH:protochlorophyllide oxidoreductase units via aggregation, in connection with structure stabilization properties of glycerol and sucrose.     

Fast phototransformation of the 636 nm-emitting protochlorophyllide form in epicotyls of dark-grown pea (Pisum sativum)

The phototransformation of protochlorophyllide forms was studied in epicotyls of dark-germinated pea (Pisum sativum L. cv. Zsuzsi) seedlings. Middle segments were illuminated with white or 632.8 nm laser flash or continuous light at room temperature and at −15°C. At low light intensities, photoreduction could be distinguished from bleaching. 77 K fluorescence emission spectra were measured, difference spectra of illuminated and non-illuminated samples were calculated and/or the spectra were deconvoluted into Gaussian components. The 629 nm-emitting protochlorophyllide form, P629 (Pxxx where xxx is the fluorescence emission maximum), was inactive. For short-period (2–100 ms) and/or low-intensity (0.75–1.5 µmol m⁻² s⁻¹) illumination, particularly with laser light, the transformation of P636 into the 678 nm-emitting chlorophyllide form, C678 (Cxxx where xxx is the fluorescence emission maximum), was characteristic. This process was also found when the samples were cooled to −15°C. The transformation of P644 into C684 usually proceeded in parallel with the process above as a result of the strong overlap of the excitation bands of P636 and P644. The Shibata shift of C684 into a short-wavelength form, C675–676, was observed. Long-period (20–600 s) and/or high-intensity (above 10 µmol m⁻² s⁻¹) illumination resulted in the parallel transformation of P655 into C692. These results demonstrate that three flash-photoactive protochlorophyllide forms function in pea epicotyls. As a part of P636 is flash photoactive, its protochlorophyllide molecule must be bound to the active site of a monomer protein unit [Böddi B, Kis-Petik K, Kaposi AD, Fidy J, Sundqvist C (1998) The two short wavelength protochlorophyllide forms in pea epicotyls are both monomeric. Biochim Biophys Acta 1365: 531–540] of the NADPH:protochlorophyllide oxidoreductase (EC 1.3.1.33). Dynamic interconversions of the protochlorophyllide forms into each other, and their regeneration, were also found, which are summarized in a scheme.     

Tissue specific protochlorophyll(ide) forms in dark-forced shoots of grapevine (<Emphasis Type="Italic">Vitis vinifera</Emphasis>L.)

Cuttings of grapevine (Vitis vinifera L. cv. Chardonnay) were dark-forced at least three weeks. Pigment contents, 77 K fluorescence emission, excitation spectra of the leaves, petioles, stems, transmission electron micrographs of the etioplasts from leaves, the chlorenchyma tissues of the stems were analysed. The dark-grown leaves, stems contained 8 to 10, 3 to 5 μg/g fresh weight protochlorophyllide, its esters, respectively. HPLC analysis showed that the molar ratio of the unesterified, esterified pigments was 7:3 in the shoot developed in darkness. The dark-forced leaves contained carotenoids identified as: neoxanthin, violaxanthin, antheraxanthin, lutein, β-carotene. Detailed analyses of the fluorescence spectra proved that all tissues of the dark-forced shoots had protochlorophyllide or protochlorophyll forms with emission maxima at 628, 636, 644, 655, 669 nm. The 628, 636 nm emitting forms were present in all parts of the dark-forced shoot, but dominated in the stems, which may indicate an organ specificity of the etioplast development. Variations in the distribution of the pigment forms were even found in the different tissues of the stem. The subepidermal layers were more abundant in the 655 nm form than the parenchyma cells of the inner part of the cortex, the pith. In the latter cells, the plastid differentiation stopped in intermediary stages between proplastids, etioplasts. The plastids in the subepidermal layers had developed prolamellar body structures, which were similar to those of etiolated leaves. The results highlight the importance of organ-, tissue specificity of plastid differentiation for chlorophyll biosynthesis, greening of different plant organs. This revised version was published online in June 2006 with corrections to the Cover Date.     

The influence of glycerol and chloroplast lipids on the spectral shifts of pigments associated with NADPH: protochlorophyllide oxidoreductase from Avena sativa L

Dark-grown angiosperm seedlings lack chlorophylls, but accumulate protochlorophyllide a complexed with the light-dependent enzyme NADPH:protochlorophyllide oxidoreductase. Previous investigators correlated spectral heterogeneity of in vivo protochlorophyllide forms and a shift of chlorophyllide forms from 680 to 672 nm (Shibata shift) occurring after irradiation, with intact membrane structures which are destroyed by solubilization. We demonstrate here that the various protochlorophyllide forms and the Shibata shift which disappear upon solubilization are restored if the reconstituted complex is treated with plastid lipids and 80% (w/v) glycerol. We hypothesize that the lipids can form a cubic phase and that this is the precondition in vitro and in vivo for the observed spectral properties before and after irradiation.     

The influence of glycerol and chloroplast lipids on the spectral shifts of pigments associated with NADPH:protochlorophyllide oxidoreductase from Avena sativa L.

Dark-grown angiosperm seedlings lack chlorophylls, but accumulate protochlorophyllide a complexed with the light-dependent enzyme NADPH:protochlorophyllide oxidoreductase. Previous investigators correlated spectral heterogeneity of in vivo protochlorophyllide forms and a shift of chlorophyllide forms from 680 to 672 nm (Shibata shift) occurring after irradiation, with intact membrane structures which are destroyed by solubilization. We demonstrate here that the various protochlorophyllide forms and the Shibata shift which disappear upon solubilization are restored if the reconstituted complex is treated with plastid lipids and 80% (w/v) glycerol. We hypothesize that the lipids can form a cubic phase and that this is the precondition in vitro and in vivo for the observed spectral properties before and after irradiation.     

Protochlorophyllide transformations and chlorophyll accumulation in epicotyls of pea (Pisum sativum)

Low-temperature fluorescence emission spectra of epicotyls of 6.5-day-old dark-grown seedlings of pea ( Pisum sativum L.) showed the dominance of short-wavelength protoch lorophyllide forms with emission maxima at 629 and 636 nm, respectively. The presence of long-wavelength protochlorophyllide with emission maxima around 650 nm was just detectable. Accordingly, irradiation with millisecond flashes gave a minute formation of chlorophyllide. The chlorophyll(ide) formation varied along the epicotyl. Irradiation with continuous light for 1.5 h resulted in an evident accumulation of chlorophyll(ide) in the upper part of the epicotyl. Only small amounts accumulated in the middle section. The conversion of protochlorophyllide to chlorophyllide was temperature dependent and almost arrested at 0°C. The chlorophyll(ide) formed had one dominating fluorescence peak at 681 nm. Irradiation for 24 h gave almost 100 times more chlorophyll in the upper part of the epicotyl than in the lower part. Electron micrographs from the upper part of the epicotyl irradiated for 6 h showed plastids with several developing thylakoids, while the plastids in the lower part of the epicotyl had only a few thylakoids. The dominance of short-wavelength protochlorophyllide forms indicated the presence of protochlorophyllide not bound to the active site of NADPH-protochlorophyllide oxidoreductase (EC 1.3.1.33). The inability of the short-wavelength form to transform into chlorophyllide with flash light denotes a dislocation from the active site. The time and temperature dependence of the chlorophyll(ide) formation in continuous light indicates that a relocation is required of the short-wavelength protochlorophyllide before chlorophyllide formation can occur.     

Abnormal etioplast development in barley seedlings infected with BSMV by seed transmission

The effect of barley stripe mosaic hordeivirus (BSMV) was studied on the ultrastructure of etioplasts, protochlorophyllide forms and the greening process of barley ( Hordeum vulgare cv. Pannónia) plants infected by seed transmission. The leaves of 7- to 11-day-old etiolated seedlings were examined by transmission electron microscopy, fluorescence and absorption spectroscopy. The etioplasts of infected seedlings contained smaller prolamellar bodies with less regular membrane structure, while prothylakoid content was higher than in the control. The protochlorophyllide content of virus-infected seedlings was reduced to 74% of the control. In the 77 K fluorescence spectra the relative amount of 655 nm emitting photoactive protochlorophyllide form decreased, and the amount of the 645 and 633 nm emitting forms increased in the infected leaves. A characteristic effect was observed in the process of the Shibata-shift: 40 min delay was observed in the infected leaves. The results of this work proved that BSMV infection delays or inhibits plastid development and the formation of photosynthetic apparatus.     

On the aggregational states of protochlorophyllide and its protein complexes in wheat etioplasts

The inner membranes from wheat ( Triticum aestivum L. cv. Walde) etioplasts were separated into membrane fractions representative of prolamellar bodies and prothylakoids by differential and gradient centrifugations. The isolated fractions were characterized by absorption-, low-temperature fluorescence-, and circular dichroism (CD) spectroscopy, by high performancy liquid chromatography and by sodium dodecyl sulphate polyacrylamide gel electrophoresis.
The prolamellar body fraction was enriched in NADPH-protochlorophyllide oxidoreductase (E.C. 1.6.99.1), and in protochlorophyllide showing an absorption maximum at 650 nm and a fluorescence emission maximum at 657 nm. Esterified protochlorophyllide was mainly found in the prothylakoid fraction. The carotenoid content was qualitatively the same in the two fractions. On a protein basis the carotenoid content was about three times higher in the prolamellar body fraction than in the prothylakoid fraction. The CD spectra of the membrane fractions showed a CD couplet with a positive band at 655 nm, a zero crossing at 643–644 nm and a negative band at 623–636 nm. These results differ from earlier CD measurements on protochlorophyllide holochrome preparations. The results support the interpretation that protochlorophyllide is present as large aggregates in combination with NADPH and NADPH-protochlorophyllide oxidoreductase in the prolamellar bodies.     

Plastid differentiation and chlorophyll biosynthesis in different leaf layers of white cabbage (Brassica oleracea cv. capitata)

The contents of protochlorophyllide, protochlorophyll and chlorophyll together with the native arrangements of the pigments and the plastid ultrastructure were studied in different leaf layers of white cabbage (Brassica oleracea cv. capitata) using absorption, 77 K fluorescence spectroscopy and transmission electron microscopy. The developmental stage of the leaves was determined using the differentiation of the stoma complexes as seen by scanning electron microscopy and light microscopy. The pigment content showed a gradual decrease from the outer leaf layer towards the central leaves. The innermost leaves were in a primordial stage in many aspects; they were large but had typical proplastids with few simple inner membranes, and contained protochlorophyllide and its esters in a 2 : 1 ratio and no chlorophyll. Short‐wavelength, not flash‐photoactive protochlorophyllide and/or protochlorophyll forms emitting at 629 and 636 nm were dominant in the innermost leaves. These leaves also had small amounts of the 644 and 654 nm emitting, flash‐photoactive protochlorophyllide forms. Rarely prolamellar bodies were observed in this layer. The outermost leaves had the usual characteristics of fully developed green leaves. The intermediary layers contained chlorophyll a and chlorophyll b besides the protochlorophyll(ide) pigments and had various intermediary developmental stages. Spectroscopically two types of intermediary leaves could be distinguished: one with only a 680 nm emitting chlorophyll a form and a second with bands at 685, 695 and 730 nm, corresponding to chlorophyll–protein complexes of green leaves. In these leaves, a large variety of chloroplasts were found. The data of this work show that etioplasts, etio‐chloroplasts or chloro‐etioplasts as well as etiolated leaves do exist in the nature and not only under laboratory conditions. The specificity of cabbage leaves compared with those of dark‐grown seedlings is the retained primordial or intermediary developmental stage of leaves in the inner layers for very long (even for a few month) period. This opens new developmental routes leading to formation of specially developed plastids in the various cabbage leaf layers. The study of these plastids provided new information for a better understanding of the plastid differentiation and the greening process .     

Etioplasts with protochlorophyll and protochlorophyllide forms in the under‐soil epicotyl segments of pea (Pisum sativum) seedlings grown under natural light conditions

To study if etiolation symptoms exist in plants grown under natural illumination conditions, under‐soil epicotyl segments of light‐grown pea (Pisum sativum) plants were examined and compared to those of hydroponically dark‐grown plants. Light‐, fluorescence‐ and electron microscopy, 77 K fluorescence spectroscopy, pigment extraction and pigment content determination methods were used. Etioplasts with prolamellar bodies and/or prothylakoids, protochlorophyll (Pchl) and protochlorophyllide (Pchlide) forms (including the flash‐photoactive 655 nm emitting form) were found in the (pro)chlorenchyma of epicotyl segments under 3 cm soil depth; their spectral properties were similar to those of hydroponically grown seedlings. However, differences were found in etioplast sizes and Pchlide:Pchl molar ratios, which indicate differences in the developmental rates of the under‐soil and of hydroponically developed cells. Tissue regions closer to the soil surface showed gradual accumulation of chlorophyll, and in parallel, decrease of Pchl and Pchlide. These results proved that etioplasts and Pchlide exist in soil‐covered parts of seedlings even if they have a 3–4‐cm long photosynthetically active shoot above the soil surface. This underlines that etiolation symptoms do develop under natural growing conditions, so they are not merely artificial, laboratory phenomena. Consequently, dark‐grown laboratory plants are good models to study the early stages of etioplast differentiation and the Pchlide–chlorophyllide phototransformation.     

Dominance of a 675?nm chlorophyll(ide) form upon selective 632.8 or 654?nm laser illumination after partial protochlorophyllide phototransformation

The phototransformation pathways of protochlorophyllide forms were studied in 8?C14-day-old leaves of dark-germinated wheat (Triticum aestivum L.) using white, 632.8?nm He?CNe laser and 654?nm laser diode light. The photon flux density (PFD) values (0.75?C360???mol photons?m^?2?s^?1), the illumination periods (20?ms?C10?s) and the temperature of the leaves (between ?60?°C and room temperature) were varied. The 77?K fluorescence spectra of partially phototransformed leaves showed gradual accumulation or even the dominance of the 675?nm emitting chlorophyllide or chlorophyll form at room temperature with 632.8?nm of PFD less than 200???mol photons?m^?2?s^?1 or with 654?nm of low PFD (7.5???mol photons?m^?2?s^?1) up to 1?s. Longer wavelength (685 or 690?nm) emitting chlorophyllide forms appeared at illuminations under ?25?°C with both laser lights or at room temperature when the PFD values were higher or the illumination period was longer than above. We concluded that the formation of the 675?nm emitting chlorophyllide form does not indicate the direct photoactivity of the 633?nm emitting protochlorophyllide form; it can derive from 644 and 657?nm forms via instantaneous disaggregation of the newly-produced chlorophyllide complexes. The disaggregation is strongly influenced by the molecular environment and the localization of the complex.     

Mercury Inhibits the Activity of the NADPH:Protochlorophyllide Oxidoreductase (POR)

The effect of Hg⁺⁺ was studied on the arrangement and photoactivity of NADPH:protochlorophyllide oxidoreductase (POR) in homogenates of dark-grown wheat (Triticum aestivum L.) leaves. 77 K fluorescence emission spectra of the homogenates were recorded before and after the irradiation of the homogenates and the spectra were deconvoluted into Gaussian components. The mercury treatment caused a precipitation of the membrane particles, which was followed by a remarkable decrease of the fluorescence yield. 10^-3 M Hg⁺⁺ decreased the ratio of the 655 nm-emitting protochlorophyllide (Pchlide) form to the 633 nm-emitting form. 10^-2 M Hg⁺⁺ shifted the short wavelength band to 629–630 nm and a 655 nm form was observed which was inactive on irradiation. This inhibition may be caused by serious alteration of the enzyme structure resulting in the trans-localisation of NADPH within the active site of POR.     

Activation volumes of processes linked to the phototransformation of protochlorophyllide determined by fluorescence spectroscopy at high pressure

The photochemical activity of NADPH:protochlorophyllide oxidoreductase (POR) was studied in etiolated wheat (Triticum aestivum, L., cult. MV17) leaf homogenates. The kinetics of the transformation of protochlorophyllide into chlorophyllide was detected by fluorescence intensity changes at 690 nm (formation of chlorophyllide) and 655 nm (decay of protochlorophyllide) at 20 degrees C, excited at 440 nm while the pressure was varied between 0.1 and 400 MPa. Both kinetics could be fitted by two exponentials and the reaction rates were pressure-dependent. A model was suggested based on the comparison of the two kinetics. Reaction rates of the processes occurring during the prototransformation were determined in function of pressure. The evaluation yielded the activation volume as 1.7 ml mol(-1), which corresponds with the formation of one H-bond/molecule.     

Etiolation symptoms in sunflower (Helianthus annuus) cotyledons partially covered by the pericarp of the achene

Background and Aims

Etiolation symptoms and the greening process are usually studied on dark-germinated seedlings and this raises the question – can these results be generalized for plants growing under field conditions? This work examines various aspects of the plastid differentiation under the covering of the achene wall, which often remains attached to the cotyledons of sunflower (Helianthus annuus) seedlings grown under light.

Methods

Cotyledons of 7- to 10-d-old sunflower seedlings grown in the dark and on light were examined. The partially covered cotyledons were sectioned into light-exposed, covered and transition zones. Pigment contents, 77 K fluorescence spectroscopy, electron microscopy and fluorescence imaging, along with fluorescence kinetic methods, were used.

Key Results

The light-exposed zone of the partially covered cotyledons was similar to cotyledons developed without achene covering. However, some of the plastids had prolamellar bodies among the granal thylakoid membranes; despite this no protochlorophyllide was detected. The fully covered, yellowish sections contained protochlorophyllide forms emitting at 633 and 655 nm and well-developed prolamellar bodies, similar to those of etiolated cotyledons. In addition, reduced amounts of chlorophyll a, chlorophyll b and stacked thylakoid membrane pairs were found in this region. The transitional sections showed a mixture of the characteristics of the covered and exposed sections. Various, but significantly different values of the photosynthetic activity parameters were found in each sector of the partially covered cotyledons.

Conclusions

The partial covering of the achene wall shades the cotyledon tissues effectively, enough to provoke the appearance of etiolation phenomena, i.e. the permanent presence of flash-photoactive protochlorophyllide complexes and prolamellar bodies (with or without protochlorophyllide), which proves that these phenomena may appear under natural illumination conditions.Key words: Cotyledon, etio-chloroplast, etioplast, etiolation, Helianthus annuus, photosynthetic activity, protochlorophyllide, prolamellar body, sunflower     

Preferential regeneration of the NADPH: protochlorophyllide oxidoreductase oligomer complexes in pea epicotyls after bleaching

The regeneration and stability of the NADPH:protochlorophyllide oxidoreductase (POR, EC 1.3.1.33) enzyme complexes were studied in bleached epicotyls of 9-day-old dark-germinated pea ( Pisum sativum L. cv. Zsuzsi) seedlings. Middle segments were illuminated with 1300 µmol m⁻² s⁻¹photon flux density (PFD) white light and subsequently incubated in total darkness for 4–24 h at 24°C. Almost the full amount of protochlorophyllide (Pchlide) was degraded after 60 min illumination. The preferential regeneration of the 655 nm emitting Pchlide form was observed after 4 h dark incubation; the accumulation of the short-wavelength Pchlide form—dominating in epicotyls of dark-grown seedling—required 18–24 h dark. The Pchlide content of bleached samples was around 2.5% of that of the etiolated samples; after 4 h of dark incubation this value increased to 4–7%. Polyacrylamide gel electrophoresis and western blot showed that the amount of the POR protein decreased to about 50% during bleaching; after 4 h regeneration it reached almost the same level as that of dark-grown samples. We concluded that much more POR protein compared with Pchlide pigment remained stable during bleaching and the non-destroyed POR units were able to form preferentially oligomers during the dark-regeneration which could collect de novo synthesized Pchlide into 655 nm emitting complexes. These data indicate the high stability of the POR protein in pea epicotyls and the importance of the molecular environment in stimulating the aggregation of POR units.     

The Pool Size of Protochlorophyllide during Different Stages of Greening of Dark Grown Wheat Leaves

The pool size of protochlorophyllide in wheat leaves irradiated for 5 minutes to 6 hours was studied. Protochlorophyllide then accumulated in the dark, but the pool size of regenerated protochlorophyllide was considerably smaller in leaves irradiated for six hours than in leaves irradiated for 5 minutes. The decrease in pool size of regenerated protochlorophyllide was found to take place at the time when the chlorophyll formation had accelerated and reached the linear phase. The protochlorophyllide accumulated is the form with absorption maximum at 650 nm, which is phototransformed to chlorophyllide with maximum absorption at 684 nm. This species goes through the Shibata shift when formed even after 6 hours of irradiation. If leaves, irradiated for 1 or 6 hours, were fed with δ-amino-levulinic acid the protochlorophyllide synthesis was only 1.2 times faster in the leaves irradiated for 6 hours than in those irradiated for 1 hour. In the case of leaves fed with δ-amino-levulinic acid the absorption maximum of protochlorophyllide is at 636 nm and the absorption maximum of the chlorophyllide formed is at 672 nm.     

Catalytic function of a novel protein protochlorophyllide oxidoreductase C of Arabidopsis thaliana

In Arabidopsis thaliana Por C has been identified only on sequence homology to that of por A and por B. To demonstrate its catalytic function Arabidopsis thaliana protochlorophyllide oxidoreductase C gene (por c) that codes for the mature part of POR C protein having 335 amino acids was expressed in Escherchia coli cells. The POR C enzyme in the presence of NADPH and protochlorophyllide when incubated in dark formed a ternary complex. When it was excited at 433 nm, it had a fluorescence emission peak at 636 nm. After illumination with actinic cool white fluorescent light, a peak at 673 nm due to chlorophyllide gradually increased with concomitant decrease of 636 nm emission, demonstrating the gradual phototransformation of protochlorophyllide to chlorophyllide. The significance of differential por gene expression in light and dark among different species is discussed.     

Breakdown of photosynthetic pigments and lipids in spinach leaves with ozone fumigation: Role of active oxygens

Dark-grown wheat leaves ( Triticum L. cv. Starke II Weibull) were illuminated repeatedly with light flashes giving partial phototransformation of protochlorophyllide to chlorophyllide. After short flashes (e.g. 15 ms red light, 250 W m⁻²), transforming only a minor part of the protochlorophyllide present, the first more stable chlorophyll(ide) measured ca 15 s after the phototransformation had its absorption maximum in the red around 672 nm. It stayed there during the following 30 min in darkness. After longer flashes (e.g. 125 ms), transforming a larger portion of the protochlorophyllide, the chlorophyll(ide) formed had its maximum absorption more towards 684 nm and shifted to 672 nm during a subsequent period in darkness. Thus, in this case a Shibata shift took place.
The conditions which produce the "stable" 672 nm form, without a Shibata shift, are discussed. The presence of large amounts of non-transformed protochlorophyllide remaining after the phototransformation seems to be important. Under such conditions it is possible that the Shibata shift is completed within a very short time.
Also the possible existence of two kinds of phototransformable protochlorophyllide is discussed. According to this idea one of the two protochlorophyllide forms produces a chlorophyllide absorbing at 672 nm shortly after phototransformation without having passed a Shibata shift. The other protochlorophyllide form photo-transforms to a chlorophyllide which proceeds through the Shibata shift.     

The photostability of different chlorophyll forms in dark grown leaves of wheat

Formulae were developed for calculation of the relative amount of different pigment forms of dark grown leaves of wheat, present before and after photoreduction of the protochlorophyllide. Three pigment forms were calculated from in vivo absorption spectra: the photoreducible protochlorophyllide with absorption maximum at 650 nm and the two chlorophyll(ide) forms with absorption maximum at 684 nm and 673 nm, respectively. The formulae were used to study the changes of the pigment forms at repeated photoreduction of the protochlorophyllide, and at a repeated treatment involving photoreduction of the protochlorophyllide followed by partial photo-decomposition of the chlorophyllide formed. Five consecutive photoreductions and reaccumulations of protochlorophyllide were carried out by high intensity irradiations of one second (red light, 700 W m^-2) given at intervals of 3 h. The results show that the pool size of reaccumulated protochlorophyllide decreased sharply with the number of photoreductions performed. The absorption spectrum of the chlorophyllide formed at each photoreduction proceeded through the Shibata shift (transformation of the 684-form to the 673-form) and the late red-shift (transformation of the 673-form to other pigment form(s) in the dark). High intensity irradiation for ten minutes (red light, 700 W m^-2) immediately after each phototransformation caused a photodecomposition of about three quarters of the newly formed chlorophyllide (which was in the 684-form) while the earlier formed chlorophyll(ide) (in the 673-form) appeared not to be decomposed. This partial photodecomposition of the chlorophyllide had no effect on further accumulation of protochlorophyllide in the dark, and the absorption spectrum of the remaining chlorophyllide proceeded through the Shibata shift. The partial photodecomposition caused an inhibition of the late red-shift, and the accumulated chlorophyll(ide) remained in the 673-form.