Effect of Intermittent and Continuous Light on Chlorophyll Formation in Etiolated Plants

Short impulses of white light induce continuous synthesis of chlorophyll a and b in etiolated barley leaves. No lag phase is observed, and the rate of chlorophyll a accumulation is much higher than that of chlorophyll b, so that the a/b ratio is very high (12 to 20). The chlorophyll accumulation reaches a plateau at about 70 flashes after which the rate of their formation decreases appreciably. When the etiolated plants, after exposure to about 80 to 100 flashes, are transferred to continuous light, one can observe that the rate of formation of chlorophyll a and b increases during the first hour, and after that becomes still more rapid. At the same time the a/b ratio falls and it reaches a value of about 3 normally found in green leaves.     

Studies on Greening of Etiolated Seedlings

Evidence is given that a selective light-pretreatment of the embryonic axis exerts a deep influence on the greening in primary leaves of 8-day-old etiolated bean seedlings (Phaseolus vulgaris cv. Limburg). After a subsequent dark incubation of sufficient length and a final exposure of the entire plants to continuous illumination the lag phase of chlorophyll synthesis is completely removed. In particular the highly meristematic hook tissue seems to be responsible for this light effect. Lengthening of the dark period following pre-irradiation increased the capability of chlorophyll production in the main white light period, reaching its maximum after about 12 hours of darkness. The period of dark incubation for elimination of the lag phase is considerably longer in plants with shielded leaves than the length of the lag phase in etiolated seedlings of the same age, exposed entirely to continuous light. This difference may be explained by the synergistic effect between leaves and embryonic axis. Evidence for this interorgan cooperation is given by experiments with a selective light-pretreatment of leaves and embryonic axis. After a 5 min pre-exposure to white light of whole plants the leaves of some of the plants were shielded and these plants received a further pre-illumination of 2 hours on their embryonic axis. In all the pre-irradiated, etiolated plants the lag phase of chlorophyll synthesis was eliminated during the main white light period, following a dark incubation of 2 hours. Additional and preferential light activation of the embryonic axis during the pretreatment had no significant effect on chlorophyll production during the white light illumination after a 2 hours dark incubation, but resulted in a lower yield of chlorophylls after 18 hours dark incubation compared to the white light controls, receiving no selective light-pretreatment on the embryonic axis. From our results we can decisively conclude that a simultaneous light-pretreatment of both, leaves and embryonic axis, is more effective and beneficial for building up a capacity of chlorophyll synthesis in the leaves than either a selective light-pretreatment of the embryonic axis alone or a simultaneous pre-illumination of leaves and embryonic axis, immediately followed by an additional preirradiation of the embryonic axis. Therefore, we think that several photoactive sites are involved in de-etiolation processes of intact, etiolated seedings. Light activation of the embryonic axis stimulates the development of this organ and contributes to the greening processes in the leaf. At the same time, by irradiating the leaf, light activates the photo-sensitive site in the leaf itself, which also develops a capacity for chlorophyll synthesis. Both photo-acts are cooperative, explaining the enhanced chlorophyll production. Additional pre-irradiation of the embryonic axis after a short illumination of whole plants favours its own development and reduces the synthetic capacity of the leaf. A prolonged far-red pretreatment induces qualitatively the same response as white light. We assume that these effects on lag phase removal and chlorophyll production, induced in etiolated, primary bean leaves by selective irradiation of the embryonic axis, is a phytochrome-mediated process. Our results indicate a transmission of light-induced stimuli from one organ to another.     

Leaf Developmental Age Controls Expression of Genes Encoding Enzymes of Chlorophyll and Heme Biosynthesis in Pea (Pisum sativum L.)

The effects of leaf developmental age on the expression of three nuclear gene families in pea (Pisum sativum L.) coding for enzymes of chlorophyll and heme biosynthesis have been examined. The steady-state levels of mRNAs encoding aminolevulinic acid (ALA) dehydratase, porphobilinogen (PBG) deaminase, and NADPH:protochlorophyllide reductase were measured by RNA gel blot and quantitative slot-blot analyses in the foliar leaves of embryos that had imbibed for 12 to 18 h and leaves of developing seedlings grown either in total darkness or under continuous white light for up to 14 d after imbibition. Both ALA dehydratase and PBG deaminase mRNAs were detectable in embryonic leaves, whereas mRNA encoding the NADPH:protochlorophyllide reductase was not observed at this early developmental stage. All three gene products were found to increase to approximately the same extent in the primary leaves of pea seedlings during the first 6 to 8 d after imbibition (postgermination) regardless of whether the plants were grown in darkness or under continuous white-light illumination. In the leaves of dark-grown seedlings, the highest levels of message accumulation were observed at approximately 8 to 10 d postgermination, and, thereafter, a steady decline in mRNA levels was observed. In the leaves of light-grown seedlings, steady-state levels of mRNA encoding the three chlorophyll biosynthetic enzymes were inversely correlated with leaf age, with youngest, rapidly expanding leaves containing the highest message levels. A corresponding increase in the three enzyme protein levels was also found during the early stages of development in the light or darkness; however, maximal accumulation of protein was delayed relative to peak levels of mRNA accumulation. We also found that although protochlorophyllide was detectable in the leaves immediately after imbibition, the time course of accumulation of the phototransformable form of the molecule coincided with NADPH:protochlorophyllide reductase expression. In studies in which dark-grown seedlings of various ages were subsequently transferred to light for 24 and 48 h, the effect of light on changes in steady-state mRNA levels was found to be more pronounced at later developmental stages. These results suggest that the expression of these three genes and likely those genes encoding other chlorophyll biosynthetic pathway enzymes are under the control of a common regulatory mechanism. Furthermore, it appears that not light, but rather as yet unidentified endogenous factors, are the primary regulatory factors controlling gene expression early in leaf development.     

The Effect of Age on the Phytochrome-Mediated Chlorophyll Formation in Dark-grown Bean Leaves

The effect of red and far-red treatment on chlorophyll synthesis in dark-grown bean leaves was studied at various ages. Although the effect was pronounced in the old leaves, no effect was observed in the young ones (4 days old). In the 5-day old leaves a measurable effect of red light pretreatment can be observed, whereas the far-red reversal effect was not observed. — The length of the dark period between the red pretreatment and the continuous illumination is also age dependent. Leaves older than 6 days show a maximum at about six hours, while in the young leaves the red light effect increases with the time of dark incubation up to the 24 hours tested. — The reversal effect of far-red light on protochlorophyllide regeneration was also examined. The far-red light has no reversal effect on leaves younger than 6 days old, while on the old leaves it has such an effect.     

Distinct roles for light-dependent NADPH:protochlorophyllide oxidoreductases (POR) A and B during greening in higher plants

Light-dependent NADPH:protochlorophyllide oxidoreductase (POR), a nuclear-encoded plastid-localized enzyme, catalyzes the photoreduction of protochlorophyllide (Pchlide) to chlorophyllide in higher plants, algae and cyanobacteria. Angiosperms require light for chlorophyll (Chl) biosynthesis and have recently been shown to contain two POR-encoding genes, PorA and PorB , that are differentially regulated by light and developmental state. PorA expression rapidly becomes undetectable after illumination of etiolated seedlings, whereas PorB expression persists throughout greening and in adult plants. In order to study the in vivo functions of Arabidopsis POR A and POR B we have abolished the expression of PorA through the use of the phytochrome A-mediated far-red high irradiance response. Wild-type seedlings grown in continuous far-red light (cFR) display the morphology of white light (WL)-grown seedlings, but contain only traces of Chl and do not green upon transfer to WL. This cFR-induced greening defect correlates with the absence of PorA mRNA, the putative POR A protein, phototransformable Pchlide-F₆₅₅, and with strongly reduced POR enzymatic activity in plant extracts. In contrast, a cFR-grown phyA mutant expresses the PorA gene, accumulates Chl and visibly greens in WL. Furthermore, constitutive overexpression of POR A in cFR-grown transgenic Arabidopsis wild-type seedlings restores Chl accumulation and WL-induced greening. These data demonstrate that POR A is required for greening and that the availability of POR A limits Chl accumulation during growth in cFR. POR B apparently provides a means to sustain light-dependent Chl biosynthesis in fully greened, mature plants in the absence of phototransformable Pchlide-F₆₅₅.     

Regulation and activation of phytoene synthase, a key enzyme in carotenoid biosynthesis, during photomorphogenesis

 During photomorphogenesis in higher plants, a coordinated increase occurs in the chlorophyll and carotenoid contents. The carotenoid level is under phytochrome control, as reflected by the light regulation of the mRNA level of phytoene synthase (PSY), the first enzyme in the carotenoid biosynthetic pathway. We investigated PSY protein levels, enzymatic activity and topological localization during photomorphogenesis. The results revealed that PSY protein levels and enzymatic activity increase during de-etiolation and that the enzyme is localized at thylakoid membranes in mature chloroplasts. However, under certain light conditions (e.g., far-red light) the increases in PSY mRNA and protein levels are not accompanied by an increase in enzymatic activity. Under those conditions, PSY is localized in the prolamellar body fraction in a mostly enzymatically inactive form. Subsequent illumination of dark-grown and/or in far-red light grown seedlings with white light causes the decay of these structures and a topological relocalization of PSY to developing thylakoids which results in its enzymatic activation. This light-dependent mechanism of enzymatic activation of PSY in carotenoid biosynthesis shares common features with the regulation of the NADPH:protochlorophyllide oxidoreductase, the first light-regulated enzyme in chlorophyll biosynthesis. The mechanism of regulation described here may contribute to ensuring a spatially and temporally coordinated increase in both carotenoid and chlorophyll contents. Received: 14 February 2000 / Accepted: 15 March 2000     

Spectral Dependence of Chlorophyll Biosynthesis Pathways in Plant Leaves

This review covers studies on the dependence of chlorophyll photobiosynthesis reactions from protochlorophyllide on the spectral composition of actinic light. A general scheme of the reaction sequence for the photochemical stage in chlorophyll biosynthesis for etiolated plant leaves is presented. Comparative analysis of the data shows that the use of light with varied wavelengths for etiolated plant illumination reveals parallel transformation pathways of different protochloro-phyllide forms into chlorophyllide, including a pathway for early photosystem II reaction center P-680 pigment formation.     

The Circadian Oscillator Coordinates the Synthesis of Apoproteins and Their Pigments during Chloroplast Development

Greening has been studied at circadian times of maximal and minimal levels of mRNA for the light-harvesting chlorophyll a/b binding protein in photosystem II (Cab mRNA) after circadian synchronization of etiolated barley plantlets (Hordeum vulgare cv Apex) by heat-shock treatments. It was found that greening occurs faster and without a lag period when illumination was started at the time of maximal Cab mRNA accumulation. This holds true for the rate of accumulation of Cab and early light-inducible protein mRNAs, the levels of their correspondent proteins, and the levels of chlorophyll a and b. When illumination was started at the time of Cab mRNA minimum, a lag in the appearance of all components mentioned above was observed. Under these conditions, the lag in chlorophyll b accumulation was by far more pronounced than that found for chlorophyll a. The circadian oscillation in the capacity of chlorophyll synthesis appears to be controlled via [delta]-aminolevulinic acid ([delta]-ALA) synthesis. [delta]-ALA accumulation after levulinic acid treatment is itself under circadian control; the maxima in stationary concentrations coincide with those of Cab mRNA levels. The amounts of protochlorophyllide and photoconvertible protochlorophyllide showed only minor differences between circadian minima and maxima, the levels being slightly lower during the time of minimum.     

The flexible interrelation between AOX respiratory pathway and photosynthesis in rice leaves.

Alternative respiratory pathway was investigated in rice seedlings grown under total darkness, light/dark cycle, or continuous light. The capacity of the alternative pathway was relatively higher in leaves that had longer light exposure. An analysis of rice AOX1 multigene family revealed that AOX1c, but not AOX1a and AOX1b, had a light-independent expression. The alternative oxidase (AOX) inhibitor, salicylhydroxamic acid (SHAM, 1mM), inhibited nearly 68% of the capacity of the alternative pathway in leaves grown under different light conditions. The plants grown under different light periods were treated with SHAM and then were exposed to illumination for 4h. The transition from dark to 4h of light stimulated the capacity of alternative pathway in etiolated rice seedlings and in those grown under light/dark cycle, whereas the capacity of the alternative pathway was constant in seedlings grown under continuous light with additional 4h of illumination. Etiolated leaves did not show any CO(2) fixation after 4h of illumination, and the increase in chlorophyll content was delayed by the SHAM pretreatment. When seedlings grown under light/dark cycle were moved from dark and exposed to 4h of light, increases in chlorophyll content and CO(2) fixation rate were reduced by SHAM. Although these parameters were stable in plants grown under continuous light, SHAM decreased CO(2) fixation rate but not the chlorophyll content. These results indicate that the role and regulation of AOX in light are determined by the developmental stage of plant photosynthetic apparatus.     

Origin and evolution of the light-dependent protochlorophyllide oxidoreductase (LPOR) genes

Abstract: Light‐dependent NADPH‐protochlorophyllide oxidoreductase (LPOR) is a nuclear‐encoded chloroplast protein in green algae and higher plants which catalyzes the light‐dependent reduction of protochlorophyllide to chlorophyllide. Light‐dependent chlorophyll biosynthesis occurs in all oxygenic photosynthetic organisms. With the exception of angiosperms, this pathway coexists with a separate light‐independent chlorophyll biosynthetic pathway, which is catalyzed by light‐independent protochlorophyllide reductase (DPOR) in the dark. In contrast, the light‐dependent function of chlorophyll biosynthesis is absent from anoxygenic photosynthetic bacteria. Consequently, the question is whether cyanobacteria are the ancestors of all organisms that conduct light‐dependent chlorophyll biosynthesis. If so, how did photosynthetic eukaryotes acquire the homologous genes of LPOR in their nuclear genomes? The large number of complete genome sequences now available allow us to detect the evolutionary history of LPOR genes by conducting a genome‐wide sequence comparison and phylogenetic analysis. Here, we show the results of a detailed phylogenetic analysis of LPOR and other functionally related enzymes in the short chain dehydrogenase/reductase (SDR) family. We propose that the LPOR gene originated in the cyanobacterial genome before the divergence of eukaryotic photosynthetic organisms. We postulated that the photosynthetic eukaryotes obtained their LPOR homologues through endosymbiotic gene transfer.     

Formation of photosynthetic pigments and quinones and development of photosynthetic activity in barley etioplasts during greening in intermittent and continuous white light

The appearance and development of photosynthetic activity, and the accumulation of chlorophylls, carotenoids and quinones, was investigated in etiolated barley shoots (Hordeum vulgare L. cv. Villa) during greening in flash light, periodic light-dark cycles, and continuous white light. Greening and the development of photosynthetic activity was delayed in flash and periodic light compared to continuous white light. Photosystem II activity occurred after 6 light-dark cycles and increased continuously during greening. After 3 h greening in continuous white light, photosystem II activity appeared with a very high rate and decreased to that of a green leaf after 50 h greening. Parallel to the development of photosynthetic activity, light stimulated the biosynthesis of prenyllipids. Moreover, chlorophylls and those carotenoids and quinones that are contained in etioplasts in relatively small amounts, were particularly enhanced in their biosynthesis. Chlorophyll a was synthesized without a lag phase during greening in flash light, whereas a 2 h lag phase occurred in continuous white light. In all three modes of illumination the formation of chlorophyll a exceeded that of chlorophyll b. After 4 flashes and 2 light-dark cycles, chlorophyll b could be detected with a very high initial a/b ratio. Higher chlorophyll a/b ratios were reached after 200 flashes (a/b=10.9) and 50 light-dark cycles (a/b=6.6) than after 50 h continuous white light (a/b=3.3). The formation of carotenes, lutein, violaxanthin and neoxanthin was also enhanced by light. This was also confirmed for plast-ouinone-9. ?-tocopherol,α-tocoquinone and phylloquinone. A comparison of the carotenoid and quinone composition of the differentiating thylakoid membrane before and after onset of photosynthesis, reveals that the photosynthetic membrane is already equipped with photosynthetic pigments and quinones before the appearance of photosystem II activity. It is concluded that during development of the photo-synthetic apparatus the thylakoid membrane with its structural and functional constituents is formed first. In a second and slower process the water splitting enzyme system and enzymes of the Calvin cycle are activated.     

Effects of Light on Degradation of Chlorophyll and Proteins during Senescence of Detached Rice Leaves

Regulatory effects of light on senescence of rice leaves wereinvestigated by measuring degradation of chlorophyll and proteinsin leaf segments which had been kept in the dark or under illuminationwith light of different intensities and colors. When leaveshad been left in total darkness for three days at 30°C,there was an initial long lag that lasted for one whole dayand then chlorophyll was rapidly degraded in the second andthird days. Breakdown of chlorophyll was strongly retarded bycontinuous illumination with white light of intensity as lowas 0.5 µmol photons m^–2 s^–1 but the effectof light decreased at intensities above 10 µmol photonsm^–2 s^–2. The initial lag and subsequent degradationof chlorophyll in the dark were little affected by illuminationwith red or far red light at the beginning of dark treatment.However, a brief illumination with red light at the end of thefirst and/or second day significantly suppressed degradationof chlorophyll during subsequent dark periods and the effectof red light was nullified by a short irradiation with far redlight. Thus, degradation of chlorophyll is regulated by phytochrome.Thylakoid membrane proteins and soluble proteins were also largelydegraded during three days in the dark. Degradation of membraneproteins such as the apoproteins of light-harvesting chlorophylla/b proteins of photosystem II and chlorophyll a-binding proteinsof reaction center complexes showed a long lag and was stronglysuppressed by illumination with weak white light. Thus, theloss of chlorophyll can be correlated with degradation of chlorophyll-carryingmembrane proteins. By contrast, light had only a weak protectingeffect on soluble proteins and ribulose-1,5-bisphosphate carboxylase/oxygenaserapidly disappeared under illumination with weak white light.Thus, breakdown of thylakoid membrane and soluble proteins aredifferently regulated by light. Artifacts which would be introducedby detachment of leaves were also discussed. ¹ Present address: Department of Applied Biology, Faculty ofScience and Technology, Science University of Tokyo, Yamazaki,Noda-shi, Chiba, 278 Japan. ² Present address: Department of Life Science, Faculty of Science,Himeji Institute of Technology, Harima Science Park City, Hyogo,678-12 Japan.     

A two-fold action of benzyladenine on chlorophyll formation in etiolated cucumber cotyledons

Treatment of 3-day-old excised etiolated cotyledons of cucumber ( Cucumis sativus L. cv. Aonagajibai) with benzyladenine (BA) in the dark stimulates chlorophyll (Chl) formation during the lag phase (designated as 'lag elimination') and accelerates the steady-state rate of Chl formation under subsequent continuous illumination with white light. The separation of this two-fold effect is possible using two different methods of BA treatment in darkness: a brief BA treatment followed by various periods of water treatment in darkness, or various periods of continuous dark BA treatment. In either treatment, BA rapidly eliminates the lag phase (the fast-appearing effect) and after a longer time period accelerates the steady-state rate (the late-appearing effect). With a brief BA treatment, both effects decay rapidly. In contrast, with continuous BA treatment, none of the effects decay after reaching their maxima, particularly in cotyledons excised 2 days after sowing and aged for a long period before the onset of BA treatment. These facts indicate that BA acts as a trigger in stimulating Chl formation. The relationship between the actions of BA and light is discussed.     

A short overview of chlorophyll biosynthesis in algae

Chlorophylls are the most abundant classes of natural pigments and their biosynthesis is therefore a major metabolic activity in the ecosphere. Two pathways exist for chlorophyll biosynthesis, one taking place in darkness and the other requiring continuous light as a precondition. The key process for Chl synthesis is the reduction of protochlorophyllide (Pchlide). This enzymatic reaction is catalysed by two different enzymes — DPOR (dark-operative Pchlide oxidoreductase) or the structurally distinct LPOR (light-dependent Pchlide oxidoreductase). DPOR which consists of three subunits encoded by three plastid genes in eukaryotes was subject of our study. A short overview of our present knowledge of chlorophyll biosynthesis in Chlamydomonas reinhardtii in comparison with other plants is presented. Presented at the International Symposium Biology and Taxonomy of Green Algae V, Smolenice, June 26–29, 2007, Slovakia.     

Implications of a Developmental-Stage-Dependent Thylakoid-Bound Protease in the Stabilization of the Light-Harvesting Pigment-Protein Complex Serving Photosystem II during Thylakoid Biogenesis in Red Kidney Bean

Intact etioplasts of bean (Phaseolus vulgaris) plants exhibit proteolytic activity against the exogenously added apoprotein of the light-harvesting pigment-protein complex serving photosystem II (LHCII) that increases as etiolation is prolonged. The activity increases in the membrane fraction but not in the stroma, where it remains low and constant and is mainly directed against LHCII and protochlorophyllide oxidoreductase. The thylakoid proteolytic activity, which is low in etioplasts of 6-d-old etiolated plants, increases in plants pretreated with a pulse of light or exposed to intermittent-light (ImL) cycles, but decreases during prolonged exposure to continuous light, coincident with chlorophyll (Chl) accumulation. To distinguish between the control of Chl and/or development on proteolytic activity, we used plants exposed to ImL cycles of varying dark-phase durations. In ImL plants exposed to an equal number of ImL cycles with short or long dark intervals (i.e. equal Chl accumulation but different developmental stage) proteolytic activity increased with the duration of the dark phase. In plants exposed to ImL for equal durations to such light-dark cycles (i.e. different Chl accumulation but same developmental stage) the proteolytic activity was similar. These results suggest that the protease, which is free to act under limited Chl accumulation, is dependent on the developmental stage of the chloroplast, and give a clue as to why plants in ImL with short dark intervals contain LHCII, whereas those with long dark intervals possess only photosystem-unit cores and lack LHCII.     

Differential effects of benzyladenine and potassium on DNA, RNA, protein and chlorophyll contents and on expansion growth of detached cucumber cotyledons in the dark and light

Benzyladenine (BA) and KCl were applied to detached cucumber ( Cucumis sativus L. cv. Ohio) cotyledons in continuous light or in the dark with subsequent light. BA brought about an increase in fresh weight and in DNA, RNA and carotenoid contents in both treatments. KCl did not cause an increase in fresh weight and cellular constituents in the dark, but it did result in an increased fresh weight and DNA content after illumination or in continuous light. BA + KCl treatment resulted in increased carotenoid and DNA contents in the dark, and in increases in fresh weight and all cellular constituents upon subsequent exposure to light. The effects of BA and BA + KCl on growth and chlorophyll synthesis decreased with cotyledon age.
BA pretreatment in the dark eliminated the lag phase in chlorophyll synthesis and increased the rate of synthesis. Treatment in continuous light had little effect. KCl did not shorten the lag phase in chlorophyll synthesis, but it stimulated the rate of synthesis in the light. Dark pretreatment with BA + KCl markedly increased the effect of BA on chlorophyll synthesis. Chlorophyll content and fresh weight were higher in cotyledons treated with BA followed by KCl than in cotyledons treated in the reverse order. These results suggest that growth and greening in cucumber cotyledons are primarily controlled by BA and that KCl intensifies the BA effect after irradiation.     

Tissue-Specific Features of Pigment Biogenesis in Coleoptiles of Greening Etiolated Seedlings of Cereals

Biogenesis of the pigment apparatus was studied in coleoptiles of postetiolated barley seedlings (Hordeum vulgare L.) and triticale (Triticale), differing in chlorophyll content, during growing in a “ light-darkness” regime with a 16-h photoperiod. Photoactive protochlorophyllide with a fluorescence maximum at 655 nm (Pchlide655), which accumulates in coleoptiles of etiolated seedlings, was converted in the light into a chlorophyll pigment with a fluorescence maximum at 690 nm (excitation at 440 nm, temperature ?196°C). The spectral transition 690 nm → 675 nm forms was completed in darkness for 15 min illumination. There was almost no resynthesis of new portions of Pchlide655 in coleoptiles under darkness conditions, even after a 5–6-h darkness period after brief illumination of seedlings with flashes of white light. Chlorophyllide (Chlide) formed from Pchlide655 was not esterified and was destroyed both in the light (4 h, 1.0–1.5 klx) and darkness. In coleoptiles of greening etiolated seedlings, chlorophyll formation started only by 24 h of illumination. The instability of the chlorophyll pigment formed after etiolation indicates that plastids of coleoptiles do not contain the system of chlorophyll biosynthesis centers typical of leaves, which are bound to membranes and protect pigment from destruction.     

Chloroplast biogenesis. Demonstration of the monovinyl and divinyl monocarboxylic routes of chlorophyll biosynthesis in higher plants

It is shown that barley (Hordeum vulgare), a dark monovinyl/light divinyl plant species, and cucumber (Cucumis sativus L.) a dark divinyl/light divinyl plant species synthesize monovinyl and divinyl protochlorophyllide in darkness from monovinyl and divinyl protoporphyrin IX via two distinct monovinyl and divinyl monocarboxylic chlorophyll biosynthetic routes. Evidence for the operation of monovinyl monocarboxylic biosynthetic routes consisted (a) in demonstrating the conversion of delta-aminolevulinic acid to monovinyl protoporphyrin and to monovinyl Mg-protoporphyrins, and (b) in demonstrating the conversion of these tetrapyrroles to monovinyl protochlorophyllide by both isolated barley and cucumber etiochloroplasts. Likewise, evidence for the operation of divinyl monocarboxylic chlorophyll biosynthetic routes consisted (a) in demonstrating the biosynthesis of divinyl protoporphyrin and divinyl Mg-protoporphyrins from delta-aminolevulinic acid, and (b) in demonstrating the conversion of the latter tetrapyrroles to divinyl protochlorophyllide. Finally, it was shown that the divinyl tetrapyrrole substrates were metabolized differently by barley and cucumber. For example, divinyl protoporphyrin, divinyl Mg-protoporphyrin, and divinyl Mg-protoporphyrin monoester were converted predominantly to monovinyl protochlorophyllide and to smaller amounts of divinyl protochlorophyllide by barley etiochloroplasts. In contrast, cucumber etiochloroplasts converted the above substrates predominantly to divinyl protochlorophyllide, although smaller amounts of monovinyl protochlorophyllide were also formed. Furthermore, it was shown that monovinyl protochlorophyllide was not formed from divinyl protochlorophyllide either in barley or in cucumber etiochloroplasts. These metabolic differences are explained by the presence of strong biosynthetic interconnections between the divinyl and monovinyl monocarboxylic routes, prior to divinyl protochlorophyllide formation, in barley but not in cucumber.