Compositional heterogeneity of protochlorophyllide ester in etiolated leaves of higher plants

The formation and degradation of protochlorophyllide esters, i.e., protochlorophylls, were studied in etiolated leaves of kidney bean in relation to their aging. By the sensitive analysis of the pigments using high-performance liquid chromatography, the presence of four protochlorophylls esterified with phytol, tetrahydrogeranylgeraniol (THGG), dihydrogeranylgeraniol (DHGG), and geranylgeraniol (GG) was detected in kidney bean grown in the dark. Similar components were also observed in the etiolated seedlings of cucumber, sunflower, and corn. The content of each protochlorophyll species changed with the plant species and age of plants. In the case of kidney bean, the content of protochlorophyll phytol reached a maximal level at 9 days, then decreased rapidly during the subsequent development, in spite of the total protochlorophyll content remaining unchanged. In contrast to the degradation of protochlorophyll phytol, the other three protochlorophylls esterified with THGG, DHGG, and GG accumulated. These results may indicate that (i) protochlorophyll phytol is formed from the first esterified protochlorophyll GG through the next three hydrogenation steps as in the case of chlorophyll a phytol formation; (ii) the esterification reaction stops at 9 days and then reaction proceeds in sequence in the reverse direction, leading to the dehydrogenation of the alcohol moiety of protochlorophyll phytol to protochlorophylls THGG, DHGG, and GG.     

Chloroplast Biogenesis: XXII. Contribution of Short Wavelength and Long Wavelength Protochlorophyll Species to the Greening of Higher Plants

The contribution of short and long wavelength membrane-bound fluorescing protochlorophyll species to the over-all process of chlorophyll formation was assessed during photoperiodic growth. Protochlorophyll forms were monitored spectrofluorometrically at 77 K during the first six light and dark cycles in homogenates of cucumber (Cucumis sativus L.) cotyledons grown under a 14-hour light/10-hour dark photoperiodic regime, and in cotyledons developing in complete darkness. In the etiolated tissue, short wavelength protochlorophyll having a broad emission maximum between 630 and 640 nm appeared within 24 hours after sowing. Subsequently, the long wavelength species fluorescing at 657 nm appeared, and accumulated rapidly. This resulted in the preponderance of the long wavelength species which characterizes the protochlorophyll profile of etiolated tissues. The forms of protochlorophyll present in etiolated cucumber cotyledons resembled those in etiolated bean leaves in their absorption, fluorescence, and phototransformability. A different pattern of protochlorophyll accumulation was observed during the dark cycles of photoperiodic greening. The short wavelength species appeared within 24 hours after sowing. Subsequently, the long wavelength form accumulated and disappeared. The long wavelength to short wavelength protochlorophyll emission intensity ratio reached a maximum (~3:1) during the second dark cycle, then declined during subsequent dark cycles. Short wavelength species were continuously present in the light and dark. Primary corn and bean leaves exhibited a similar pattern of protochlorophyll accumulation. In cucumber cotyledons, both the short and long wavelengths species appeared to be directly phototransformable at all stages of photoperiodic development. It thus appears that whereas the long wavelength protochlorophyll species is the major chlorophyll precursor during primary photoconversion in older etiolated tissues, both long wavelength and short wavelength species seem to contribute to chlorophyll formation during greening under natural photoperiodic conditions.     

Phosphorescence of protochlorophyll(ide) and chlorophyll(ide) in etiolated and greening bean leaves

The assignment is presented for the principal phosphorescence bands of protochlorophyll(ide), chlorophyllide and chlorophyll in etiolated and greening bean leaves measured at -196°C using a mechanical phosphoroscope. Protochlorophyll(ide) phosophorescence spectra in etiolated leaves consist of three bands with maxima at 870, 920 and 970 nm. Excitation spectra show that the 870 nm band belongs to the short wavelength protochlorophyll(ide), P627. The latter two bands correspond to the protochlorophyll(ide) forms, P637 and P650. The overall quantum yield for P650 phosphorescence in etiolated leaves is near to that in solutions of monomeric protochlorophyll, indicating a rather high efficiency of the protochlorophyll(ide) triplet state formation in frozen plant material. Short-term (2–20 min) illumination of etiolated leaves at the temperature range from -30 to 20°C leads to the appearance of new phosphorescence bands at about 990–1000 and 940 nm. Judging from excitation and emission spectra, the former band belongs to aggregated chlorophyllide, the latter one, to monomeric chlorophyll or chlorophyllide. This indicates that both monomeric and aggregated pigments are formed at this stage of leaf greening. After preillumination for 1 h at room temperature, chlorophyll phosphorescence predominates. The spectral maximum of this phosphorescence is at 955–960 nm, the lifetime is about 2 ms, and the maximum of the excitation spectrum lies at 668 nm. Further greening leads to a sharp drop of the chlorophyll phosphorescence intensity and to a shift of the phosphorescence maximum to 980 nm, while the phosphorescence lifetime and a maximum of the phosphorescence excitation spectrum remains unaltered. The data suggest that chlorophyll phosphorescence belongs to the short wavelength, newly synthesized chlorophyll, not bound to chloroplast carotenoids. Thus, the phosphorescence measurement can be efficiently used to study newly formed chlorophyll and its precursors in etiolated and greening leaves and to address various problems arising in the analysis of chlorophyll biosynthesis.Abbreviations Pchl protochlorophyll and protochlorophyllide - Chld chlorophyllide - Chl chlorophyll     

Estimation of protochlorophyll(ide) contents in plant extracts; re-evaluation of the molar absorption coefficient of protochlorophyll(ide)

In an attempt to solve the controversy about the evaluation of the molar absorption coefficient of PChl(ide), this coefficient is estimated in this work by using an original experimental approach. The calculated molar absorption coefficient of PChl(ide) is 30.4.10³ 1 mole^–1 cm^–1 at 626 nm in acetone 80%; it is close to that derived from the specific absorption coefficient of Koski and Smith when assuming that the pigment extracted by these authors was the esterified pigment: PChl. Sets of equations for the quantification of Chl(ide) a, Chl b and PChl(ide) in 80% acetone extracts are derived.Abbreviations PChl(ide) protochlorophyll(ide) - Chl(ide) chlorophyll(ide)     

Characterization of protochlorophyllide and protochlorophyllide esters in roots of dark-grown plants

The protochlorophyll pools of roots of dark-grown wheat ( Triticum aestivum L. cv. Walde), maize ( Zea mays L. cv. Goldcrest) and wrinkledseeded pea ( Pisum sativum L. ssp. sativurh cv. Kelvedon Wonder) were investigated by high performance liquid chromatography (HPLC) and low temperature fluorescence spectroscopy. All roots contained protochlorophyllide and esterified protochlorophyllides (protochlorophylls) but with considerably larger relative amounts of the latter compared with etiolated leaves. The alcohol moieties of the 4 detected protochlorophylls were geranylgeraniol (GG), dihydrogeranylgeraniol (DHGG), tetrahydrogeranylgeraniol (THGG) and phytol. The relative amounts of the different protochlorophylls varied between the species. Protochlorophyllide and the 4 protochlorophylls all contained monovinyl forms. The divinyl forms could not be detected by our instruments. Wrinkledseeded pea contained in addition chlorophyll a , some unidentified chlorophylls and negligible amounts of chlorophyllide. Small amounts of carotenoids were found in roots of all investigated species. The carotenoids were the same as those found in green or etiolated leaves, but present in different relative amounts.     

Relationship between chlorophyll concentration and the energy reaction between protochlorophyll and chlorophyll in mixed associations

In the paper results are presented of investigation of protochlorophyll (PChl) and chlorophyll (Chl) mixed associations and of interaction between them within the polymer molecular complex, which forms in mixture of water-dioxane (1 : 4). The initial PChl concentration in all solutions was constant (CPChl = 1 . 10(-5) m/l), and Chl concentration varied from 1.10(-8) m/l up to 2.10(-5) m/l. It is shown that with the rise of Chl proportion in the mixed aggregate the rearrangement of both donor (PChl) and acceptor (Chl) components of complex takes place. The luminescence quenching of PChl and the sensitization of Chl emission in mixed pigment associates were investigated of different Chl levels and the evaluation of efficiency of intracomplex electronic excitation energy transfer, determined from quenching and sensibilization, was performed. Similar dependence of energy transfer effectiveness on Chl concentration, determined by the two above-mentioned methods shows that the excitation migration in an associate takes place without losses. An analysis of results permits to conclude that a small trapping efficiency of PChl excitation by the acceptor part of the complex may be connected with the existence of the prerelaxation reverse energy transfer from Chl to PChl in mixed pigment associates. On the basis of the obtained data a mechanism of energy transfer from protochlorophyllide to chlorophyllide in etiolated leaves and homogenates is discussed.     

Control of chlorophyll synthesis by phytochrome

Summary The rate of chlorophyllide esterification in mustard cotyledons can be increased by a pretreatment with 5 min red light applied 24 h prior to the protochlorophyll(ide)chlorophyll(ide) photoconversion at 60 h after sowing. Simultaneously the red light pulse pretreatment leads to a decrease of the total amount of chlorophyll(ide) a in darkness. It has been proven that phytochrome (P_fr) is the photoeffector for both. Since the amounts of esterified chlorophyllide are determined by the ratio [chlorophyll a]/[chlorophyllide a+chlorophyll a] it is assumed that P_fr increases the rate of esterification indirectly via stimulating the decrease of chlorophyll(ide) a. The regulation of chlorophyll synthesis by P_fr does not seem to involve a control of esterification. The duration of the chlorophyllide esterification differs from the duration of the Shibata shift although both are greatly shortened by the red light pulse pretreatment. The effect of 5 min red light on the duration of the esterification is fully reversible by 5 min far-red light while the reversibility with respect to the Shibata shift is lost within 2 min [Jabben, M. and H. Mohr, Photochem. Photobiol. 22, 55–58 (1975)]. We conclude that the control of the chlorophyllide esterification and the control of the Shibata shift cannot be traced back to the same initial action of P_fr.Abbreviations Chl chlorophyll - Chlide chlorophyllide - Chl(ide) sum of Chl and Chlide - PChl protochlorophyll - PChlide protochlorophyllide - PChl(ide) sum of PChl and PChlide - P_fr far-red absorbing form of the phytochrome system     

Regulation of delta-aminolaevulinic acid synthesis and protochlorophyllide regeneration in the leaves of dark-grown barley (Hordeum vulgare) seedlings.

Laevulinic acid (Lev) was used to control the rate of protocholorophyllide (PChl) regeneration in the leaves of dark-grown seedlings of barley (Hordeum vulgare) after a brief light treatment. In the leaves given Lev, at concentrations that severely block the resynthesis of protochlorophyllide, there was a massive overproduction of delta-aminolaevulinic acid (AmLev) that was well in excess of that required for the regeneration of PChl observed in the control leaves. Lev, at low concentrations, slightly delayed regeneration and held up, rather than inhibited, the utilization of the AmLev, which accumulated in the tissues. The overproduction and uncontrolled formation of AmLev also occurred in dark-grown leaves treated with a high concentration of Lev and given a light treatment of just sufficient energy to photoreduce only small quantities of the endogenous PChl. Experiments in which a high level of free PChl was induced by incubating the leaves in AmLev indicated that the active species of PChl was that associated with, and bound to, the PChl reductase protein. The results strongly demonstrate a close relationship between the PChl-protein complex and the ability of the leaves to synthesize AmLev.     

Biosynthesis of chlorophyll from protochlorophyll(ide) in green plant leaves

Using spectral methods, the biosynthesis of protochlorophyll(ide) and chlorophyll(ide) in green plant leaves was studied. The main chlorophyll precursors in the green leaves (as in etiolated leaves) were photoactive photocholorophyll(ide) forms Pchl(ide)655/650(448) and Pchl(ide)653/648(440). The contributions into Chl biosynthesis of the shorter-wavelength precursor forms ,which were accumulated in darkened green leaves as well, were completely absent (of Pchl(ide) 633/628(440)) or insignificant (of Pchl(ide)642/635(444)).     

Soret absorption of intermediate(s) in protochlorophyllide to chlorophyllide photoreduction trapped at low temperature

Absorption spectra at ca 100 K from 400 to 750 nm and fluorescence emission spectra at 77 K from 600 to 750 nm were obtained from: 1) etiolated leaves of the H-ordeum vulgare L. (barley) mutant albozonata 2 and SAN 9789-treated Avena sativa L. (oat) with low levels of carotenoids, and 2) preparations of protochlorophyllide holo-chrome from Phaseolus vulgaris L. cv. Commodore (bean).
This allowed clear resolution for the first time of the Soret bands of the green pigments before and after light-induced accumulation of intermediate(s) in protochlorophyllide to chlorophyllide photoreduction and after conversion of the intermediate(s) to chlorophyllide by warming the samples to 233 K in darkness. Although the intermediate(s) differ(s) in absorption and fluorescence in the red wavelength region from both protochlorophyllide and chlorophyllide, the extinction in the Soret band is not distinguishable from that of chlorophyllide. These observations indicate that the C7-C8 double bond in ring IV of protochlorophyllide has been altered in intermediate(s) accumulated at low temperature in intense light, such that the transition state exhibits the character of a π complex.     

Protochlorophyll(ide) forms in hypocotyls of dark-grown bean (Phaseolus vulgaris)

The protochlorophyll(ide) forms and plastid ultrastructure were investigated in hypocotyls of dark-grown seedlings of kidney bean ( Phaseolus vulgaris L. cv. Brede zonder draad). By deconvolution of the fluorescence emission spectra into Gaussian components three protochlorophyll(ide) forms were found with maxima at 633, 642 and 657 nm, respectively. The ratio of protochlorophyll(ide) emitting at 657 nm to protochlorophyll(ide) emitting at 633 nm decreased downwards the hypocotyl. The gradient was established already after 4 days in dark-grown Phaseolus and was also seen in hypocotyls of 7-day-old dark-grown plants of 8 other species. Ultrastructural observations revealed a plastid developmental sequence along the hypocotyl. Plastids in the upper parts of the hypocotyl contained prolamellar bodies typical of etiolated leaves while those in the lower parts contained only stroma lamellae. Immunological detection of NADPH-protochlorophyllide oxidoreductase (EC 1.3.1.33) on nitrocellulose membranes after sodium dodecyl sulphate polyacrylamide gel electrophoresis (SDSPAGE) indicated the occurrence of the enzyme in upper, middle and lower sections of hypocotyls and in the root tips.     

Development and ageing of etioplast structures in dark grown leaves ofAvena sativa (L.)

Summary Etioplasts of dark grown plants contain a large paracrystalline prolamellar body (PLB) and, attached to this there are prothylakoid membranes (PTs).PLB-tubules inAvena are composed mainly of two saponins and include only a low percentage of other lipids, protochlorophyll(ide) and proteins.Following the development of etioplasts in darkness from the very beginning until plants loose turgescence one can observe marked changes in ultrastructure. In the early stage of development predominantly PTs are seen in small etioplasts. Wide-type PLBs are small. After eight days there is a well developed stage with the well-known big and highly crystalline PLBs, which are connected to many long PT-membranes. After 13 days the PLBs are not significantly changed, while number and length of PTs are strongly reduced.These morphological observations are quantified by measurements of PLB-area and PT-length per plastid section. Saponin content as a marker for PLB-tubules and protochlorophyll(ide)-content as a marker for PT-membranes were measured. Both methods of determination show in good agreement a peak of development for PTs around day 6–7, and for PLBs around 9–10. Beginning senescence affects PT-membranes and PChl(ide) strongly, while saponins resp. PLBs persist better. These results are presented in view of thylakoid formation during greening, starting from the different etioplast stages.Abbreviations Chl(ide) chlorophyll(ide) - EM electron-microscope - PChl(ide) protochlorophyll(ide) - PLB prolamellar body - PT prothylakoid - TLC Thin layer chromatography A preliminary report has been presented at the V. Intern. Congress on Photosynthesis at Chalkidiki, Greece 1980.     

Correlation between 5-aminolaevulinate accumulation and protochlorophyll photoconversion

A 1-min light pulse delivered to mustard seedlings (Sinapis alba L.) 60 h after sowing initiates the release of cotyledonary 5-aminolaevulinate (ALA) accumulation which continues for at least 2 h in the dark. Phytochrome (P _fr) increases the rate of ALA accumulation after a 24-h red light pretreatment but is not the trigger for this release. It is shown that the rate of ALA accumulation varies with the wave-length and fluence rate of the 1-min light pulse and can be predicted from the degree of protochlorophyll-(ide) photoconversion. There is a linear correlation between the rate of ALA accumulation and the degree of protochlorophyll(ide) (PChl)chlorophyll(ide) a (Chl a) photoconversion in etiolated seedlings. In seedlings pretreated with red light this correlation is non-linear and the rate increases more rapidly with increasing degrees of PChlChl a photoconversion. It is suggested that there may exist an interaction between P _fr and PChlChl a photoconversion in controlling ALA accumulation.Abbreviations ALA 5-aminolaevulinate - Chl chlorophyll(ide) - PChl protochlorophyll(ide) - cp cotyledon pair - LA laevulinate     

Chlorophyll and carotenoid degradation mediated by thylakoid-associated peroxidative activity in olives (Olea europaea) cv. hojiblanca

A peroxidative activity was found in solubilized thylakoid membranes of olives (Olea europaea) cv. hojiblanca that catalyses degradation of chloroplast pigments in the presence of H2O2 and 2,4-dichlorophenol (DCP). The intermediate products of this degradation were analyzed using HPLC with diode array detection and the results indicated that 13(2)-OH-chlorophyll a and 13(2)-OH-chlorophyll b were the primary catabolites. The peroxidative activity assosiated with the thylakoid membranes affected, not only chlorophyll a and chlorophyll b, but also other accessory pigments in the photosynthetic process, such as the carotenoids. Quantitatively, the progressive decrease of the ratios Chl a/b and total Chls a+b/carotenoids indicated a more rapid disappearance of Chl a than of Chl b and a faster degradation of Chls a+b than of carotenoids.     

Effects of caspase inhibitors (z-VAD-fmk, z-VDVAD-fmk) on Nile Red fluorescence pattern in 7-ketocholesterol-treated cells: investigation by flow cytometry and spectral imaging microscopy.

BACKGROUND: The 7-ketocholesterol (7KC)-induced cell death has some characteristics of apoptosis and is associated with polar lipid accumulation. So, we investigated the effects of the broad-spectrum caspase inhibitor z-VAD-fmk and of the caspase-2 inhibitor z-VDVAD-fmk on lipid profile evaluated by staining with Nile Red (NR). METHODS: The 7KC-treated human monocytic U937 cells were cultured in the absence or in the presence of the caspase inhibitors z-VAD-fmk or z-VDVAD-fmk. When staining with NR is performed, neutral and polar lipids have yellow and orange/red emission, respectively, and fluorescence was then analyzed by flow cytometry (FCM) and by confocal laser scanning microscopy (CLSM) combined with subsequent image processing. The 3D-image sequences were obtained by means of CLSM using spectral analysis, and were analyzed by the factor analysis of medical image sequences algorithm to differentiate spectra inside mixed fluorescence emission and get corresponding specific images. RESULTS: By FCM, comparatively to untreated cells, higher percentages of red fluorescent cells were identified in 7KC-treated cells. Factor curves and images reveal orange and red fluorescence emissions in 7KC-treated cells and show yellow, orange, and red fluorescence emissions in 7KC-treated cells cultured in the presence of z-VAD-fmk or z-VDVAD-fmk. CONCLUSIONS: Our data support that investigation by FCM and by spectral analysis in CLSM associated with subsequent image processing provides useful tools to determine the effect of caspase inhibitors on lipid content evaluated with NR. They also favor the hypothesis of relationships between caspase activity and polar lipid accumulation.     

Photoconvertible and non-photoconvertible forms of protochlorophyll(ide) in etiolated bean leaves

Precursors of chlorophylls in etiolated bean leaves were studiedby a sensitive technique of dual wavelength scanning of thinlayer chromatograms of pigments. The photoconvertible pigmentswith absorption maxima at 650 and 638 nm, respectively, wereidentified as protochlorophyllide. A minor non-photoconvertiblepigment with a maximum at 628 nm was found to be protochlorophyll. (Received July 3, 1974; )     

Protochlorophyll forms with different molecular arrangements

Spectral properties of protochlorophyll (PChl) forms were investigated in solid-film model systems by absorption. fluorescence and circular dichroism (CD) spectroscopy. The solid films were prepared from diethyl ether solution of PChl on a cover glass surface by evaporation of the solvent. After preparation the films usually showed an absorption maximum at 635 nm or in some cases at 640 nm. The PChl form with 635 nm absorption maximum had no CD signal, whilst the films with absorption maximum at 640 nm gave an intense negative CD band at about 640 nm and a positive one at 668 nm. The treatment of the films with ammonia or acetone vapour resulted in a red shift of the absorption maximum from 635 nm or 640 nm to 650 nm. The study of the CD spectra of the films with different PChl forms showed that, depending on the treatment, forms of PChl with similar absorption and fluorescence spectra, but with opposite CD signals, can exist. It is suggested that the differences of the CD spectra are mainly due to different arrangements of the aggregates.     

The primary reactions in the protochlorophyll(ide) photoreduction as investigated by optical and ESR spectroscopy

It has been found that at low temperatures (77K–153K) a long-lived (at these temperatures) singlet ESR signal induced by intensive light appears in etiolated leaves of plants and in model systems including both the monomeric and aggregated protochlorophyll.Comparison of the results of ESR, fluorescence and absorption spectra measurements made it possible to suggest that at the initial stages of the protochlorophyll(ide) photoreduction process at least two paramagnetic non-fluorescent intermediates are formed, one of which seems to be identical to the previously found intermediate with absorption maximum at 690 nm. On the strength of the obtained results a conclusion can be drawn that photoreduction of the semi-isolated double-c=c-bond of the chlorophyll precursor molecule in etiolated leaves and in model systems is actualized via at least two stages of free radicals formation. A scheme of the primary reactions of chlorophyllide biosynthesis has been proposed.     

THE EFFECTIVENESS OF THE SPECTRUM IN CHLOROPHYLL FORMATION

1. Although the carotenoid pigments are present in large concentration in the plastids of etiolated Avena seedlings as compared with protochlorophyll, the pigment precursor of chlorophyll, it is possible to show that the carotenoids do not act as filters of the light incident on the plant in the blue region of the spectrum where they absorb heavily. This suggests that the carotenoids are located behind the protochlorophyll molecules in the plastids. 2. Since the carotenoids do not screen and light is necessary for chlorophyll formation, an effectiveness spectrum of protochlorophyll can be obtained which is the reciprocal of the light energy necessary to produce a constant amount of chlorophyll with different wavelengths. The relative effectiveness of sixteen spectral regions in forming chlorophyll was determined. 3. From the effectiveness spectrum, one can conclude that protochlorophyll is a blue-green pigment with major peaks of absorption at 445 mµ, and 645 mµ, and with smaller peaks at 575 and 545 mµ. The blue peak is sharp, narrow, and high, the red peak being broader and shorter. This differs from previous findings where the use of rougher methods indicated that red light was more effective than blue and did not give the position of the peaks of absorption or their relative heights. 4. The protochlorophyll curve is similar to but not identical with chlorophyll. The ratio of the peaks of absorption in the blue as compared to the red is very similar to chlorophyll a, but the position of the peaks resembles chlorophyll b. 5. There is an excellent correspondence between the absorption properties of this "active" protochlorophyll and what is known of the absorption of a chemically known pigment studied in impure extracts of seed coats of the Cucurbitaceae. Conclusive proof of the identity of the two substances awaits chemical purification, but the evidence here favors the view that the pumpkin seed substance, which is chemically chlorophyll a minus two hydrogens, is identical with the precursor of chlorophyll formation found in etiolated plants.     

Developmental Physiology of Bean Leaf Plastids III. Tube Transformation and Protochlorophyll (ide) Photoconversion by a Flash Irradiation

A light flash of about 1 millisecond duration elicits tube transformation in paracrystalline prolamellar bodies as well as maximal protochlorophyll(ide) photoconversion in etiolated bean leaves (Phaseolus vulgaris L.). These findings support a more detailed hypothesis on the linkage between tube transformation and protochlorophyll(ide) photoconversion than has been offered previously.