Library

Notes: When grown in darkness the photomorphogenic lip1 mutant of pea (Pisum sativum L.) has a slender stem, expanded leaves, prolamellar body (PLB) lacking plastids with the size of chloroplasts and a low level of phytochrome A. The lack of PLBs in a dark-grown material (lip1) created a possibility to further study the regulation of their formation in relation to plant development. Inclusion of a cytokinin, 2-isopentenyladenine (2iP), in a medium supporting growth of the pea seedlings in darkness was found to reduce epicotyl length in the wild type. In lip1 the formation of a slender stem was inhibited and a short epicotyl developed. Furthermore, leaf expansion was inhibited, the plastid size reduced and the formation of PLBs induced. The PLB formation in lip1 was not accompanied by an increase in the amount of protochlorophyllide (Pchlide) or Pchilde oxidoreductase (POR). In the presence of 2iP the level of phytochrome A protein was increased in lip1 and the POR mRNA levels decreased in both lip1 and wild-type plants. The chloroplast characteristic trans-3-hexadecenoate acyl group of phosphatidylglycerol, present in the plastids of dark-grown lip1, was not influenced by 2iP. Thus, not all photomorphogenic processes reacted similarly in the lip1 mutant, but leaf expansion and plastid differentiation, including PLB formation, seemed to be regulated by the same signal transduction chain. Exogenously applied brassinolide could rescue neither dark- nor light-grown defects of the lip1 mutant. Thus, cytokinins but not brassinolides seem to be involved in the regulation of certain characteristic traits of skotomorphogenesis in pea, including plastid development and PLB formation.

Notes: 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.

Notes: During illumination of dark-grown plants protochlorophyllide (Pchlide) is continuously transformed to chlorophyllide (Chlide). Different dark-grown plants, maize (Zea mays cv. Sundance), wheat (Triticum aestivum cv. Kosack), pea (Pisum sativum cv. Kelwedon wonder), the lip1 mutant of pea, and the aurea mutant of tomato (Solanum lycopersicum), have various ratios of spectral Pchlide forms in darkness. When the plants were illuminated and then returned to darkness Pchlide re-accumulated. The proportions of different Pchlide forms within the pool of re-accumulated Pchlide were followed by low temperature fluorescence emission and excitation spectra in green and greening leaves. After 1 h of illumination the spectral characteristics of regenerated Pchlide forms mirrored those of Pchlide in dark-grown plants and were thus species dependent. After a prolonged illumination period (24 h) as well as in fully green leaves energy transfer to chlorophyll (Chl) masked the presence of long-wavelength Pchlide in the fluorescence emission spectra. However, excitation spectra showed Pchlide absorption around 650 nm and its flash-induced disappearance confirmed its nature of phototransformable Pchlide. In fact the excitation spectra showed that the proportions of different Pchlide forms in green leaves highly resembled the proportions of Pchlide forms in dark-grown leaves and were specific for the plant variety. Thus Chl formation in both dark-grown and light-grown leaves can occur in a similar way through the main photoactive long-wavelength form of Pchlide.

Notes: 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.

Notes: Potato tubers (Solanum tubersoum cvs Bintje and King Edward). never exposed to light, lack chlorophyllous pigments. Continuous irradiation results in chlorophyll (Chl) formation and induces the ability for protochlorophyll (Pchl) formation when the tubers are brought back to darkness. Pigment synthesis takes place in both blue and red light, but blue light is more effective than red in starting the greening process. The pigment formation is strongest in the layers just below the periderm with a steep gradient inwards. Small amounts of Chl formed after irradiation. slowly fade away during extended darkness. However, the Chl formed after long time of irradiation is remarkably stable. Irradiated potatoes, placed in darkness, form Pchl with a fluorescence emission peak at 633 nm. A maximal level is reached after ca 7 days. Resolution of the Pchl spectrum suggests the presence of small amounts of a pigment with an emission maximum at around 642 nm. No sign of the Pchl with emission maximum at 657 nm, which dominates in etiolated leaves, is found. A faint Chl fluorescence indicates that some Pchl, probably the 642 nm form, is phototransformed into Chl in weak light. The Chl formation in the potato tuber is discussed in relation to that of roots and leaves.

Notes: The effects of microtubule inhibitors on the spectral properties of leaves of wheat (Triticum aestivum L. cv. Walde) and on the presence of plastid microtubule–like structures (MTLS) during etioplast to chloroplast transformation were examined. Amiprophos-methyl (APM, 0.1 mM), fed to leaf sections of 7-day-old dark-grown wheat, reduced the ration of phototransformable to non-phototransformable proto-chlorophyllide (PChlide), decreased the rate of the Shibata shift, and inhibited chlorophyll accumulation and grana stacking. The spectral properties of isolated etioplasts were not affected by APM. Colchicine (10 mM), fed to leaf sections, inhibited greening but had no effect on the PChlide ratio or the Shibata shift. MTLS were still visible on electron micrographs after treatment with APM or colchicine at frequencies similar to controls. A third inhibitor, vinblastine, had no effect on the spectral properties of non-irradiated or irradiated etiolated leaves except at concentrations that produced visible tissue damage before the irradiation. The effects of APM and colchicine may reflect inhibitions of respiration and protein synthesis, respectively. It is concluded that MTLS are insensitive to microtubule inhibitors and thus are probably not composed of tubulin.

Notes: Membrane fractions containing intact etioplasts, etioplast inner membranes, prolamellar bodies or prothylakoids from wheat (Triticum aestivum L. cv. Walde) were assayed for chlorophyll synthetase activity. Calculated on a protein basis, the etioplast inner membrane fraction showed a higher activity than the intact etioplasts. The activity was higher in the prolamellar body fraction than in the prothylakoid fraction. However, when the fractions were incubated in isolation medium with 50% (w/w) sucrose and 0.3 mM NADPH, chlorophyll synthetase activity could not be detected in the prolamellar body fraction, while the prothylakoid fraction maintained a high activity. The spectral shift to a shorter wavelength of the newly formed endogenous chlorophyllide was very rapid in the prothylakoid fraction but slow in the prolamellar body fraction. The relation between the spectral shift of chlorophyllide and the esterification activity in the fractions is discussed. Even exogenous short-wavelength chlorophyllide could not be esterified in well preserved prolamellar bodies. This indicates that chlorophyll synthetase is present in an inactive state in the prolamellar body structure. A large-scale method for the synthesis of geranylgeranylpyrophosphate, one of the substrates of the chlorophyll synthetase reaction, is also presented.

Notes: The inner membranes from wheat (Triticum aestivum L. cv. Walde, Weibull) etioplasts were separated by density centrifugation. The etioplasts were broken by osmotic shock and the inner membranes were split by the sheering forces when pressed through a syringe needle. Membrane fractions representative of prolamellar bodies and prothylakoids, respectively, were achieved by separation on a 20–50% continuous sucrose density gradient followed by different purification procedures. The membrane contents of the isolated fractions were characterized by low temperature fluorescence spectra, sodium dodecyl sulphate polyacrylamide gel electrophoresis and electron micrographs. The prolamellar body and the prothylakoid fractions had a fluorescence emission ratio 657/633 nm of 18 and 0.9, respectively. The main part of the total amount of PChlide was found in the prolamellar body fraction. The electrophoretograms stained with Coomassie Blue showed the presence of mainly two polypeptides. The NADPH-protochlorophyllide oxidoreductase was the dominating polypeptide in the prolamellar body fraction, and the α and β subunits of the coupling factor 1 of chloroplast ATP synthase the dominating polypeptides in the prothylakoid fraction. Silver staining revealed at least 4 additional prominent bands with molecular weights of 86, 66, 34 and 28 kDa. The polypeptide composition of the prolamellar body is thus more complex than earlier judged after Coomassie Blue staining. The function of these polypeptides is unknown, but the knowledge of their presence is important in understanding the formation and function of the prolamellar body.

Notes: Isolated prolamellar bodies from the etioplasts of dark-grown wheat (Triticum aestivum L. cv. Walde, Weibull) contain the enzyme NADPH-protochlorophyllide oxidoreductase. The organisation of this enzyme in a pigment-protein complex results in fluorescence emission maxima at 633 and 657 nm. Isolated prolamellar bodies stored in darkness for 24 or 48 h at 4°C (pH 7.2) in the presence of NADPH showed a fluorescence emission ratio 657/633 nm around 4 at −196°C. With acidic conditions this fluorescence ratio increased, with an optimum at pH 5.5. Such an increase was even more pronounced in the presence of ATP and NADPH with ratios up to 8, but was completely blocked when the sulfhydryl inhibitor, dithiobis-nitrobenzoic acid, was added. As shown by sodium dodecyl sulfate polyacrylamide gel electrophoresis the amount of NADPH-protochlorophyllide oxidoreductase in the prolamellar bodies did not change during storage for 24 or 48 h.The total amount of protochlorophyllide measured in acetone extracts did not change significantly during storage for 48 h. The values were similar for storage at pH 7.2 and 5.5, but at lower pH (around 5) the pigment content decreased to a third.The most plausible explanation for the increase in fluorescence ratio is that low pH and ATP give rise to a change in conformation, which results in transformation of the short wavelength (633 nm) fluorescing protochlorophyllide to the long wavelength (657 nm) fluorescing form.

Notes: Brushite purified phytochrome from Avena sativa L. cv. Sol II was bound to phenyl Sepharose, octyl Sepharose, CNBr-activated Sepharose and to anti-phytochrome immunoglobulins immobilized on Sepharose. The spectral properties of phytochrome bound to anti-phytochrome immunoglobulins and to phenyl Sepharose were similar to phytochrome in solution. Phytochrome bound to CNBr-activated Sepharose or to octyl Sepharose showed reduced Pfr formation after red irradiation. The reversal to Pr with far-red light was only partial but a further increase at 667 nm took place slowly in the dark. A peak at 657 nm was seen in the difference spectrum between CNBr-activated Sepharose-bound phytochrome kept in darkness and the identical sample immediately after a far-red irradiation.The change in linear dichroism at 660 nm and 730 nm, induced by plane polarized red or far-red light, was measured. It was computed that the long-wavelength transition moment of phytochrome had an average rotation angle of 31.5° or 180°–31.5°. The substrate used for immobilization had a limited effect on the rotation angle. Phytochrome immobilized on CNBr-activated Sepharose gave an angle of 27.8° and phytochrome immobilized on phenyl Sepharose gave an angle of 32.6°.