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.     

Tentoxin does not cause chlorosis in greening mung bean leaves by inhibiting photophosphorylation

Effects of the fungal toxin, tentotoxin, on development and chlorophyll accumulation of plastids of primary leaves of mung bean [ Vigna radiata (L.) Wilczek cv. Berken] were studied using spectrophotometric, electrophoretic, and microscopic procedures. In etioplasts of control tissues both prolamellar bodies and prothylakoids occurred, whereas small vesicles were associated with structurally distinct prolamellar bodies in tentoxin-affected etioplasts. As determined by in vivo spectrophotometry, tentoxin-affected etioplasts had 25% less phototransformable protochlorophyll(ide) and 35% less non-phototransformable protochlorophyll(ide) than had control etioplasts after 5 days of dark seedling growth. Tentoxin had no effect on the rate of the Shibita shift. Protochlorophyll(ide) resynthesis in the dark immediately after protochlorophyll(ide) phototransformation was five to six times slower in tentoxintreated than in control tissues. Effects on chlorophyll(ide) content were observed within 30 min of the beginning of continuous white light exposure. In vivo measurement of cytochrome f redox activity revealed that this cytochrome was linked to light-driven electron flow in control tissues within 20 min of the beginning of continuous white light, whereas in the tentoxin-treated tissues there was no linkage (despite the presence of cytochrome f ) at any time. Coupling factor 1 was present and had potential ATPase activity in both control and tentoxin-affected plastids. There was about sixteen times more chlorophyll in control than in tentoxin-treated tissues in continuous as well as in intermittent (2 min light/118 min dark) light. These data are consistent with the view that tentoxin disrupts normal etioplast and chloroplast development through a mechanism unrelated to photophosphorylation.     

Die Wechselwirkung von Hellrot,Dunkelrot und Blaulicht bei der Photomorphogenese von Farngametophyten [Dryopteris filix-mas (L.) Schott]

Summary In Fig. 1 we have reproduced the action spectrum of photomorphogenesis in fern gametophytes (Dryopteris filix-mas (L.) Schott). The morphogenetic index L/W is shown as a function of wavelength (L=length, W=maximal width of the protonema). In experiments in which simultaneous irradiation with red and far-red was applied it has been shown (Fig. 2) that the effect of red light (lowering of the L/W-index) can be nullified by a simultaneous application of a suitable quantum flux density of far-red light. This fact means that the effects of red and far-red light on morphogenesis as measured by the L/W-index (Fig. 1) can be attributed exclusively to phytochrome.The strong morphogenetic effect of short wavelenth visible (=blue) light (strong lowering of the L/W-index) cannot be influenced by simultaneously applied far-red light (Fig. 4), whereas red light cancels the effect of blue light to a certain extent as measured by the L/W-index (Fig. 5). It has been concluded that the effect of blue light is due to a photoreceptor other than phytochrome, probably a flavoprotein. The antagonism between blue and red can be understood if we assume that the phytochrome-mediated growth at the tip of the apical cell of the protonema (e.g. Etzold, 1965) is fully promoted by P₇₃₀ only at a high relative concentration of P₇₃₀. The low relative concentration of P₇₃₀ under far-red light is too low to counteract significantly the blue light dependent response. Blue light initiates isodiametric growth of the apical cell instead of tip growth (Mohr, 1965). Under far-red light (a low level of P₇₃₀) growth of the apical cell seems to be restricted to the extreme tip of the apical cell. Slender protonemas with a high L/W-index are the result. Under red light (a high level of P₇₃₀) the growing zone of the apical cell is somewhat broader. As a consequence the protonemas are broader and the L/W-index is lowered.     

Phytochrome changes correlated to mesocotyl inhibition in etiolated Avena seedlings

The elongation of etiolated Avena mesocotyls is inhibited by red light (660 mμ). Immediately after exposing mesocotyl sections to varying doses of red light the ensuing concentrations of phytochrome in the far-red absorbing form (P₇₃₀) were measured. The extent of mesocotyl inhibition observed 5 days later is proportional to the logarithm of P₇₃₀ concentration in mesocotyl tissue at the time of red light exposure.

The inhibition of mesocotyl growth by red light can be reversed partially by subsequent exposure to far-red light (730 mμ). Increasing doses of far-red light result in decreasing concentrations of P₇₃₀ as compared with the original P₇₃₀ level due to the preceding red light exposure. The reduced mesocotyl inhibition of seedings which had been exposed to red and far-red light is proportional to the logarithm of P₇₃₀ concentration remaining in the tissue at the end of the two light exposures.

This indicates that the same correlation exists between P₇₃₀ concentration and growth response whether the seedlings had been exposed to red light only or to red followed by far-red light.

     

Oak seedlings grown in different light qualities

Oak seedlings (Quercus robur L.) were germinated in darkness for 3 weeks and then given continuous long wavelength far-red light (LFR; wavelengths longer than 700 nm). A control group of seedlings was kept in darkness. After 2 additional weeks the chlorophyll formation ability in red light was examined in the different seedlings. The stability of the protochlorophyll(ide) and chlorophyll(ide) forms to high intensity red irradiation was also measured. Oak seedlings grown in darkness accumulated protochlorophyll(ide) (6 μg per g fresh matter). Absorption spectra and fluorescence spectra indicated the presence of more protochlorophyll(ide)_628–632 than protochlorophyllide_650–657. The level of protochlorophyll(ide) was higher in leaves of plants cultivated in LFR light (13 μg per g fresh matter) than in leaves of dark grown plants. 12% of the protochlorophyll(ide) was esterified in both cases. The level of protochlorophyll(ide)_628–632 in LFR grown oaks varied with the age of the leaves, being higher in the older (basal) leaves, but also in the very youngest (top-most) leaves. The ability of the leaves to form photostable chlorophyll in red light showed a similar age dependence, being low in rather young and in older leaves. A low ability to form photostable chlorophyll thus appears to be correlated with a high content of protochlorophyll(ide)_628–632. Upon irradiation only the protochlorophyllide_650–657 was transformed to chlorophyllide. After this phototransformation the chlorophyllide peak at 684 nm shifted to 671 nm within about 30 min in darkness. This shift took place without any accompanying change in photostability of the chlorophyll(ide). Upon irradiation with strong red light a similar shift took place within one minute. This indicates that the chlorophyllide after phototransformation was rather loosely bound to the photoreducing enzyme. The development towards photostable chlorophyll forms consists of three phases and is discussed.     

Light-stimulated cell expansion in bean (Phaseolus vulgaris L.) leaves

The quantity and quality of light required for light-stimulated cell expansion in leaves of Phaseolus vulgaris L. have been determined. Seedlings were grown in dim red light (RL; 4 micromoles photons m-2 s-1) until cell division in the primary leaves was completed, then excised discs were incubated in 10 mM sucrose plus 10 mM KCl in a variety of light treatments. The growth response of discs exposed to continuous white light (WL) for 16 h was saturated at 100 micromoles m-2 s-1, and did not show reciprocity. Extensive, but not continuous, illumination was needed for maximal growth. The wavelength dependence of disc expansion was determined from fluence-response curves obtained from 380 to 730 nm provided by the Okazaki Large Spectrograph. Blue (BL; 460 nm) and red light (RL; 660 nm) were most effective in promoting leaf cell growth, both in photosynthetically active and inhibited leaf discs. Far-red light (FR; 730 nm) reduced the effectiveness of RL, but not BL, indicating that phytochrome and a separate blue-light receptor mediate expansion of leaf cells.     

Comparison of Light-dependent Oxygen Uptake, Protochlorophyll(ide)-650 Photoconversion, and Chlorophyll Disappearance in Wheat Etioplasts

Red light exposures given to dark-grown wheat seedlings (Triticum aestivum L.) prior to etioplast isolation reduced the ability of these organelles to consume O₂. The same preharvest red light exposures also decreased protochlorophyll(ide) content of etioplasts. In addition, regeneration of both O₂ uptake rates as well as protochlorophyll(ide) levels followed a parallel time course. These similarities suggested that photoconversion of protochlorophyll(ide)-650 to chlorophyll(ide) may mediate some process with O₂ as the electron acceptor. This process appears to involve photooxidation of nonphotoconvertible protochlorophyll(ide) as well as of newly formed chlorophyll(ide). This hypothesis is further supported by the observations that: (a) the in vitro light induced O₂ uptake phenomenon was observed in solubilized protochlorophyll(ide) holochrome preparations; and (b) photoinduced O₂ uptake was reduced to zero rate by light exposure time equivalent to that required for chlorophyll(ide) and nonphotoconvertible protochlorophyll(ide) destruction.     

Ricerche Sulla Morfogenesi Dei Plastidi Clorofilliani

Abstract

Studies on chloroplast morphogenesis. The effect of sucrose feeding and light intensity on the plastids of etiolated plants. — The changes in the fine structure of the plastids of etiolated Bean plants, dipped into water or in various sucrose concentrations, for 24, or more, hours, and exposed to conditions of darkness and weak light, were studied at the electron microscope, and protochlorophyll, chlorophyll a and chlorophyll b contents were determined. When the etiolated plants are dipped into water or sucrose solutions, in the dark, rows of tubules and lamellae, often stacked and resembling small grana, are formed in the plastids. These structural changes of plastids of the plants exposed to conditions of darkness, where no protochlorophyll was converted to chlorophyll a, are quite similar to those described by several Authors for plants exposed to light conditions and thought to coincide with the protochlorophyll-chlorophyll transformation. Thus, the preservation of the « Kristallgitterstruktur » of the vesicular centers, or, instead, their transformation into a lapse cluster of tubules, does not seem to be related with protochlorophyll accumulation in them; indeed, an increase of protochlorophyll contents was observed both with the preservation of the crystalline structure, and with its transformation, and low protochlorophyll contents did not always coincide with the transformation of the vesicular centers. In the plants exposed to weak light (1 ft-c) there is chlorophyll a and b accumulation, and a more pronounced tendency toward stacking of tubules and lamellae. In the plants exposed to weak light, dipped into water or sucrose solutions, at the lowest concentrations, and for the shortest periods, the vesicular centers are transformed into clusters of tubules; but with higher sucrose concentrations, or longer dipping periods, their crystalline structure is preserved, just as if their preservation would depend only by an adeguate nutrients supply.

The arrangement of normal lamellae and the formation of grana connected by intergrana lamellae occur, anyhow, only when the etiolated plants are exposed to « high » light (630 ft-c). But chlorophyll accumulation is possible under « weak » light (and a stacking of tubules and lamellae, resembling small grana, also occurs), when sucrose is supplied. The achievement of the « normal », complete structure of the chloroplast is, therefore, here interpreted in the sense that it represents only the functional aspect of its organization, determined by a light intensity favorable to its photosyntetic activity, which is not directly necessary for the synthesis of the contistuents of the lamellar system (chlorophylls, phospholipids).     

Role of Light in 5-Aminolevulinic Acid Formation in Wild Strain and Mutant C-2A' Cells of Scenedesmus obliquus

In dark-grown wild strain cells of Scenedesmus obliquus, 5-aminolevulinicacid (ALA) formation was induced by irradiation with a weakblue light, as in its mutant C-2A' cells. The induction wasinhibited by distamycin A, 6-methylpurine, cycloheximide andchloramphenicol. After the light induction, the ALA formationcould proceed in the dark as well as in the light, in such heterotrophicallygrown wild type cells, but not in the greening mutant C-2A'cells. In the latter, ALA formation was dependent on red light,as well as on blue light, in the presence of CMU. The amountsof protochlorophyll in the mutant cells increased upon cessationof illumination and decreased with subsequent irradiation withblue and red light. The possible role of protochlorophyll asa photoreceptor in regulation of ALA formation in the mutantcells is discussed. ¹Present address: Laboratory of Chemistry, Faculty of Medicine,Teikyo University, Otuka, Hachioji, Tokyo 192-03, Japan. (Received January 17, 1981; Accepted April 30, 1981)     

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 .     

Formation of short-wavelength chlorophyll(ide) after brief irradiation is correlated with the occurrence of protochlorophyll(ide)636–642 in dark-grown epi- and hypocotyls of bean (Phaseolus vulgaris)

Chlorophyll formation capacity along the seedling of bean ( Phaseolus vulgaris L. cv. Brede zonder draad) was investigated. After 7 days of irradiation a gradient was formed, where the primary leaf contained ca 300 times more chlorophyll per gram fresh weight than the lower hypocotyl section and ca 20 times more than the epicotyl. Similar chlorophyll gradients but at lower levels were seen when the seedlings were first placed in darkness for 7 days and then irradiated for 1, 2 or 7 days. Ultrastructural investigation of seedlings grown for 7 days in darkness and then irradiated for 24 h revealed a more developed inner membrane system with grana stacks in plastids of cells in the uppermost hypocotyl section compared to plastids of cells in lower hypocoty] sections. The higher up on the seedling the more the ratio increased of protochlorophyll(ide) emitting at 657 nm to short-wavelength protochlorophyll(ide). After flash irradiation of the different sections, fluorescence emission spectra with maxima at 680 and 690 nm, respectively, were observed, indicating the formation of short- and long wavelength chlorophyll(ide) forms. The lower the ratio of protochlorophyll(ide) emitting at 657 nm to the short-wavelength protochlorophyll(ide), the less long-wavelength chlorophyll(ide) was formed after irradiation. However, after continuous irradiation long-wavelength chlorophyll(ide) was formed. In dark grown roots, where only short-wavelength protochlorophyll forms were present, it was not possible to transform protochlorophyll to chlorophyll by flash irradiation. Possible explanations for this phenomenon are discussed.     

Protochlorophyll(ide) in a Blue-Green Alga

During growth under far-red (>650 nm) light, Anacystis nidulans accumulates protochlorophyllide to concentrations about one-tenth of the chlorophyll. From whole cell fluorescence spectra, protochlorophyll(ide) was identified also in another blue-green, and in a red, alga grown in far-red light.     

The Correlated Appearance of Prolamellar Bodies, Protochlorophyll(ide) Species, and the Shibata Shift during Development of Bean Etioplasts in the Dark

The structure and physiology of the etioplast was investigated in developing primary leaves of 3- to 9-day-old dark-grown bean (Phaseolus vulgaris L. var. Red Kidney) seedlings. Increase in total protochlorophyll(ide) content followed that of leaf fresh weight. In 3- to 4-day-old bean leaves more than 50% of the protochlorophyll(ide) is in the form of protochlorophyll(ide) 628, which is nontransformable by light. Most of the transformable pigment is protochlorophyll(ide) 635, with smaller amounts of protochlorophyll(ide) 650. During leaf development from the 3rd to the 7th day phototransformable protochlorophyll(ide) with an absorbance maximum at 650 nm accumulates faster than nontransformable protochlorophyll(ide) or protochlorophyll(ide) 635. This increase in protochlorophyll(ide) 650 is correlated with the formation and enlargement of prolamellar bodies.     

Structure of Protochlorophyll-containing Plastids in the Inner Seed Coat of Pumpkin Seeds (Cucurbita pepo)

The inner seed coat of seeds of Cucurbita pepo L. cv. Ohlsens Enke Köks was used to study the development of protochlorophyll-containing plastids with an abnormal ultrastructural composition. The pumpkins were harvested at different stages during fruit development and they thus contained seeds with different developmental stages. The dry weight of seeds of the developmental stages used varied from 0.04 g to 0.3 g. Such a series of seeds with decreasing water content indicating increasing maturity contained different amounts of protochlorophyll, from 0.20 μg/g fresh weight to 500 μg/g fresh weight. The ultrastructure of the protochlorophyll containing plastids changed greatly during development. In young seeds with a low content of protochlorophyll, regular prolamellar bodies were found and starch grains filled most of the plastids. During development the starch content decreased and the prolamellar bodies increased in size and lost their regularity. During maturation the plastids accumulated plastoglobuli, probably containing protochlorophyll, and finally the internal structure of the prolamellar body tubular complex was lost.     

Induction of delta-Aminolevulinic Acid Formation in Etiolated Maize Leaves Controlled by Two Light Systems

A short illumination of etiolated maize (Zea mays) leaves with red light causes a protochlorophyll(ide)-chlorophyll(ide) conversion and induces the synthesis of δ-aminolevulinic acid (ALA) during a subsequent dark period. In leaves treated with levulinic acid, more ALA is formed in the dark than in control leaves. Far red light does not cause a conversion of protochlorophyll(ide) into chlorophyll(ide) and does not induce accumulation of ALA in the dark. Both red and far red preilluminations cause a significant potentiation of ALA synthesis during a period of white light subsequent to the dark period. The results indicate a dual light control of ALA formation. The possible role of phytochrome and protochlorophyllide as photoreceptors in this control system is discussed.     

Events Surrounding the Early Development of Euglena Chloroplasts: VI. Action Spectra for the Formation of Chlorophyll, Lag Elimination in Chlorophyll Synthesis, and Appearance of TPN-dependent Triose Phosphate Dehydrogenase and Alkaline DNase Activities

Action spectra derived from dose-response curves measured for various processes associated with chloroplast development in Euglena gracilis var. bacillaris are presented. The action spectrum for chlorophyll synthesis during the first 36 hours of continuous illumination of dark-grown resting cells resembles the absorption spectrum of protochlorophyll(ide). The action spectrum for the preillumination phase of potentiation, during which preillumination followed by a dark period brings about lag elimination in chlorophyll synthesis when the cells are subsequently exposed to postilluminating light, shows a high peak in the blue region (at about 433 nm) with a small peak in the yellow-orange region (at about 597 nm); the postillumination phase yields an action spectrum very similar to that obtained for chlorophyll synthesis in continuous light in normal, unpotentiated cells, with peaks at 433 and 631 nm. Alkaline DNase and TPN-linked triose phosphate dehydrogenase, two plastid enzymes which are synthesized outside the chloroplast, yield action spectra which are consistent with protochlorophyll(ide) being the major light receptor. The action spectra which implicate pigments resembling protochlorophyll(ide) holochrome have blue to red peak ratios in the vicinity of 5:1 as does the absorption spectrum of the protochlorophyllide holochrome from beans; the action spectrum is not identical with the holochrome spectrum indicating that the Euglena holochrome may differ from the bean pigment in details of its absorption spectrum. The action spectrum for preillumination, shows a ratio of the blue peak to the red effectiveness of about 24:1. This suggests that preillumination is controlled by a photoreceptor different from the protochlorophyll(ide) holochrome.     

The Effect of Red Irradiation on Plastid Ribosomal RNA Synthesis in Dark-grown Pea Seedlings

Dark-grown pea seedlings (Pisum sativum L.) were irradiated for a short period each day with low intensity red light (662 nm), red light immediately followed by far red light (730 nm), or far red light alone. Other plants were transferred to a white light regime (14 hours light/10 hours dark). There was no change in the amount of RNA in the tissue on a fresh weight basis after the various treatments. However, compared with dark-grown seedlings, those plants irradiated with red light showed an increase in the net RNA content per stem apex. In addition there was a two- to three-fold increase in ribosomal RNA of the etioplasts relative to the total ribosomal RNA. These increases were comparable to those found in plants grown in the white light regime. The changes were much smaller if the dark-grown plants were irradiated either with red light followed by far red light, or with far red light alone. Thus continuous light is not essential for the production of ribosomal RNA in plastids, and the levels of ribosomal RNA found in chloroplasts can also be attained in etioplasts of pea leaves in the dark provided the leaf phytochrome is maintained in its active form.     

On the Delimitation of Chlorophyll Formation after an Irradiation with a Sharply Defined Light Area

Leaves of dark grown wheat seedlings have been irradiated for a few minutes with a strictly defined beam of red light. After a stay in darkness for six hours the whole leaves were irradiated for three hours. The pre-irradiated spot will then stand out greener than the rest of the leaf, due to accelerated formation of protochlorophyll, earlier described (22), and will consequently show a higher concentration of chlorophyll a. By scanning the leaf with a microphotometer it was shown that no spread whatsoever of the effect of the light impulse takes place, i.e. the phytochrome, which is one of the light absorbing systems, exerts its effect strictly locally. This is in contrast to many other red light effects on photomorphogenetic phenomena characterized by a rapid spread of the stimulus. The two kinds of phytochrome actions are discussed.     

Changes in Plastidic and Cytoplasmic Pyruvate Kinase Activity during Chloroplast Development of Pea in Blue and Red Light

Pyruvate kinase (PK) activity was demonstrated in the cytosolas well as in the plastids of pea leaves. Etioplasts and chloroplastscontained about 12% of the total activity. The presence of PKactivity in different cellular compartments and the pronounceddifferences in kinetic and regulatory properties indicate thatthese activities are due to isoenzymes. When etiolated pea leaves were illuminated with weak blue light,the plastidic PK activity increased immediately, reaching amaximum (about 21% of the total activity) after 24 h of illumination.Under red light, there was a lag period of about 4 h beforethe increase in isoenzyme activity. After 24 h of illumination,however, it reached the maximum found with blue light. In contrast,light quality had no appreciable effect on cytoplasmic PK andphosphoenolpyruvate carboxylase. Increases in NADP-dependent glyceraldehyde 3-phosphate dehydrogenaseactivity and in the soluble protein in the plastids were somewhathigher, whereas the increase in chlorophyll content was slightlylower under blue light than under red light. Blue light specificallyincreased the chlorophyll alb-ratio. These different responsesto the light quality during chloroplast development indicatethat more than one photoreceptor is involved in these processes. The results obtained for pea PK also are discussed in comparisonwith similar findings for the chlorophyll-free Chlorella mutantno. 20. (Received January 19, 1982; Accepted April 21, 1983)