Defective etioplasts observed in variegation mutants may reveal the light-independent regulation of white/yellow sectors of Arabidopsis leaves

Leaf variegation resulting from nuclear gene mutations has been used as a model system to elucidate the molecular mechanisms of chloroplast development. Since most variegation genes also function in photosynthesis, it remains unknown whether their roles in photosynthesis and chloroplast development are distinct. Here, using the variegation mutant thylakoid formation1 (thf1) we show that variegation formation is light independent. It was found that slow and uneven chloroplast development in thf1 can be attributed to defects in etioplast development in darkness. Ultrastructural analysis showed the coexistence of plastids with or without prolamellar bodies (PLB) in cells of thf1, but not of WT. Although THF1 mutation leads to significant decreases in the levels of Pchlide and Pchllide oxidoreductase (POR) expression, genetic and 5-aminolevulinic acid (ALA)-feeding analysis did not reveal Pchlide or POR to be critical factors for etioplast formation in thf1. Northern blot analysis showed that plastid gene expression is dramatically reduced in thf1 compared with that in WT, particularly in the dark. Our results also indicate that chlorophyll biosynthesis and expression of plastidic genes are coordinately suppressed in thf1. Based on these results, we propose a model to explain leaf variegation formation from the plastid development perspective.     

Etioplast differentiation in arabidopsis: both PORA and PORB restore the prolamellar body and photoactive protochlorophyllide-F655 to the cop1 photomorphogenic mutant.

The etioplast plastid type of dark-grown angiosperms is defined by the accumulation of the chlorophyll (Chl) precursor protochlorophyllide (Pchlide) and the presence of the paracrystalline prolamellar body (PLB) membrane. Both features correlate with the presence of NADPH:Pchlide oxidoreductase (POR), a light-dependent enzyme that reduces photoactive Pchlide-F655 to chlorophyllide and plays a key role in chloroplast differentiation during greening. Two differentially expressed and regulated POR enzymes, PORA and PORB, have recently been discovered in angiosperms. To investigate the hypothesis that etioplast differentiation requires PORA, we have constitutively overexpressed PORA and PORB in the Arabidopsis wild type and in the constitutive photomorphogenic cop1-18 (previously det340) mutant, which is deficient in the PLB and Pchlide-F655. In both genetic backgrounds, POR overexpression increased PLB size, the ratio of Pchlide-F655 to nonphotoactive Pchl[ide]-F632, and the amount of Pchlide-F655. Dramatically, restoration of either PORA or PORB to the cop1 mutant led to the formation of etioplasts containing an extensive PLB and large amounts of photoactive Pchlide-F655.     

Plastid development in germinating wheat (Triticum aestivum) is enhanced by gibberellic acid and delayed by gabaculine

Etioplast development and protochlorophyllide (Pchlide) accumulation was studied in wheat seedlings ( Triticum aestivum L. cv. Walde, Weibull) grown in darkness on gibberellic acid (GA₃), gabaculine (3-amino-2,3-dihydrobenzoic acid), or on a combination of the two. The results were compared with the features of seedlings grown on water only. GA₃ enhanced shoot growth and promoted etioplast development. A correlation was observed between the appearance of prolamellar bodies (PLBs) and of phototransformable Pchlide. Gabaculine, a known tetrapyrrole biosynthesis inhibitor, delayed growth, slowed down the rate of PLB formation and caused structural alterations of the etioplasts up to 48 h of germination. Gabaculine also delayed the formation of phototransformable Pchlide as well as overall Pchlide biosynthesis, as determined by low-temperature fluorescence emission in vivo. The spectral blue-shift of newly formed chlorophyllide (Chlide) was delayed in irradiated dark-grown gabaculine-grown seedlings, indicating an inhibited dissociation of Chlide and NADPH-Pchlide oxidoreductase (Pchlide reductase: EC 1.3.1.33). Thus there is a close correlation between accumulation of Pchlide and etioplast development, also under conditions when development is enhanced or delayed.     

Regulation of etioplast pigment-protein complexes, inner membrane architecture, and protochlorophyllide a chemical heterogeneity by light-dependent NADPH:protochlorophyllide oxidoreductases A and B

The etioplast of dark-grown angiosperms is characterized by the prolamellar body (PLB) inner membrane, the absence of chlorophyll, and the accumulation of divinyl and monovinyl derivatives of protochlorophyll(ide) a [Pchl(ide) a]. Either of two structurally related, but differentially expressed light-dependent NADPH:Pchlide oxidoreductases (PORs), PORA and PORB, can assemble the PLB and form dark-stable ternary complexes containing enzymatically photoactive Pchlide-F655. Here we have examined in detail whether these polypeptides play redundant roles in etioplast differentiation by manipulating the total POR content and the PORA-to-PORB ratio of etiolated Arabidopsis seedlings using antisense and overexpression approaches. POR content correlates closely with PLB formation, the amounts, spectroscopic properties, and photoreduction kinetics of photoactive Pchlide, the ratio of photoactive Pchlide-F655 to non-photoactive Pchl(ide)-F632, and the ratio of divinyl- to monovinyl-Pchl(ide). This last result defines POR as the first endogenous protein factor demonstrated to influence the chemical heterogeneity of Pchl(ide) in angiosperms. It is intriguing that excitation energy transfer between different spectroscopic forms of Pchl(ide) in etiolated cotyledons remains largely independent of POR content. We therefore propose that the PLB contains a minimal structural unit with defined pigment stoichiometries, within which a small amount of non-photoactive Pchl(ide) transfers excitation energy to a large excess of photoactive Pchlide-F655. In addition, our data suggests that POR may bind not only stoichiometric amounts of photoactive Pchlide, but also substoichiometric amounts of non-photoactive Pchl(ide). We conclude that the typical characteristics of etioplasts are closely related to total POR content, but not obviously to the specific presence of PORA or PORB.     

A coupling factor for photosynthetic phosphorylation from plastids of light- and dark-grown maize

1. Maize chloroplasts contain a trypsin-, dithiothreitol-, and Ca²⁺-activated ATPase. This enzyme, which can serve as a coupling factor for photosynthetic phosphorylation, differs slightly in a few properties but in general resembles a similar one in spinach plastids which was described earlier by others.

2. Maize etioplasts (immature plastids in dark-grown plants) also contain this ATPase, and it is shown that NaCl-EDTA extracts of etioplasts can restore photosynthetic phosphorylation activity to depleted green membranes of chloroplasts.

3. Electron microscopy of maize etioplast and chloroplast membranes demonstrates the presence of protruding knobs, approx. 90 Å in diameter. Removal and reassociation of knobs with membranes can be correlated with the ability to carry on photosynthetic phosphorylation.

4. Most or possibly all of the coupling factor (measured as ATPase) activity of a chloroplast may be present in the etioplast from which it develops. The photosynthetic membrane of the chloroplast can be formed in stages.

5. The significance of these observations is discussed with regard to membrane formation in general and plastid membrane development in particular.     

Ultrastructural Development of Chloroplasts in Sacred Lotus Embryo Bud under Invisible Light

The present paper reports that the development ultrastructural observations of chloroplasts from sacred lotus (Nelumbo nucifera) embryo buds under invisible light. Embryo bud of sacred lotus is enclosed by three layers of thick integument (pericap, seed coat and thick fleshy cotyledons). During the period of the formation of embryo bud, it remained in dark condition, but turned from pale yellow to bluish-green. It was noteworthy that chloroplasts of the embryo bud had well developed giant grana under invisible light. Their developmental pathway in sacred lotus, however, was different from those of other higher plants grown under sunlight, intermittent light, or even in dark conditions (Fig. 1). The chloroplast development of embryo buds in Sacred lotus seeds in invisible light underwent only in the following three stages: (1) In the first stage the development was similar to that from other higher plants, the inner envelope membranes of the proplastids were invaginating. (2) In the second stage, a proplastid centre composed of prolamellar bodies (PLB)with semicrystalline structure was formed, and was accompanied by one or two huge starch grains in almost each proplastid. In the meantime, prothylakoid membranes extended parallelly from the plastid centre in three forms: (a) One plastid centre extending parallelly prothylakoid membranes from itself in one direction; (b) The same to (a), but extending in two directions; (c) Two plastid centres extending parallelly prothylakoid membranes between the centres. (3) In the third stage, grana and stroma thylakoid membranes of chloroplasts were formed. It is to be noted that most of chloroplasts had only one or two giant grana which often extended across the entire chloroplast body, and the length of the grana thylakoid membranes of the chloroplasts from embryo bud in Sacred lotus is 3 to 5 times as many as that in other higher plants. However, their stromatic thylakoid membranes were rather rare and very short. The giant grana were squeezed to the margin of the chloroplast envelope by one or two huge starch grains.     

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.     

Intercalation of psoralen into DNA of plastid chromosomes decreases late during barley chloroplast development.

We have used a DNA crosslinking assay to measure intercalation of the psoralen derivative HMT (4'-hydroxymethyl-4,5',8-trimethylpsoralen) into barley (Hordeum vulgare) plastid chromosomal DNA during chloroplast and etioplast development. Intercalation into DNA in intact plastids in vivo and in plastid lysates in vitro shows that chromosomal DNA in the most mature chloroplasts intercalates HMT less efficiently than DNA in younger chloroplasts. In contrast, there is no change in HMT intercalation during etioplast differentiation in the dark. Our results also show that DNA in higher plant plastid chromosomes is under superhelical tension in vivo. The lower susceptibility to HMT intercalation of DNA in the most mature chloroplasts indicates that late during chloroplast development the superhelical tension or the binding of proteins to the DNA or both change.     

Effect of Periodic Heat Shock on the Inner Membrane System of Etioplasts

Etiolated barley (Hordeum vulgare L.) seedlings were treated with heat shock (HS). The heat treatment was conducted daily for 1 h at 40°C over 6 days and led to shortening of leaves and coleoptiles, an increase in the etioplast volume and prothylakoid length, and to a decrease in the size of paracrystalline prolamellar bodies (PLB). As a result of HS treatment, stimulation of carotenoid and protochlorophyllide (Pchlide) synthesis as well as an increase in the relative content of the Pchlide short-wavelength form (Pchlide₆₃₀) were observed in the leaf tissue of seven-day-old seedlings 12 h after the last HS treatment. HS had no effect on the overall amount of Pchlide-oxidoreductase (POR) in leaves and PLB membranes and did not suppress the Pchlide photoreduction in vivo. PLB membranes, isolated from the HS-treated seedlings, possessed a higher Pchlide and carotenoid content as calculated on total protein basis. These membranes showed more intense protein fluorescence than PLB from untreated plants, whereas hydrophobicity of the microenvironment of the fluorescent amino-acid residues remained unchanged. Studies using pyrene (lipophilic fluorescent probe emitted in Pchlide and carotenoid absorption bands) showed that HS increases the fluidity of membrane lipids in PLB membranes and that the pigments accumulated in these membranes are located in the region of lipid–protein contact site. The results are discussed in relation to the adaptive role of protein–protein and pigment–protein–lipid interactions in etioplast membranes under stress.     

Comparative study on the changes of proteins and oxidative enzymes occurring in protocorms and protocorm-like bodies systems of development in the orchid Dendrobium hookerianum

Proteins and activities of antioxidant enzymes, including polyphenol oxidase (PPO), peroxidase (POX) and catalase (CAT), were evaluated in Dendrobium hookerianum during different stages of development of both protocorms and protocorm-like bodies (PLB) derived from seeds and axillary buds, respectively. The changes in the protein contents and the enzyme activities along with their isozyme patterns were compared between these two culture systems. It was found that the protein contents and the enzyme activities increased steadily over time during different stages of development in both the systems. Protein contents (4.57 mg/g fresh wt.) and activities of POX (21.9 U/mg protein), CAT (9.86 U/mg protein) were observed to be higher in PLB system as compared to protocorm system at stage IV of development. However, although the PPO activity increased gradually till the third stage of development, a decline was observed at stage IV wherein the activity was recorded to be more or less same in both the systems. Also, few proteins (~61, 50, 46, 32, 25, 16, 6 kDa) and new isozymes (POX 7, 8; CAT 2) were expressed only in PLB system of development. In general, high protein content and enzyme activities were detected in PLB system as compared to protocorm system. The results of the present study indicate that few proteins and isozymes could be regarded as specific biochemical markers for different stages of development of this medicinally important orchid.     

Identification of the carotenoid isomerase provides insight into carotenoid biosynthesis, prolamellar body formation, and photomorphogenesis

Carotenoids are essential photoprotective and antioxidant pigments synthesized by all photosynthetic organisms. Most carotenoid biosynthetic enzymes were thought to have evolved independently in bacteria and plants. For example, in bacteria, a single enzyme (CrtI) catalyzes the four desaturations leading from the colorless compound phytoene to the red compound lycopene, whereas plants require two desaturases (phytoene and zeta-carotene desaturases) that are unrelated to the bacterial enzyme. We have demonstrated that carotenoid desaturation in plants requires a third distinct enzyme activity, the carotenoid isomerase (CRTISO), which, unlike phytoene and zeta-carotene desaturases, apparently arose from a progenitor bacterial desaturase. The Arabidopsis CRTISO locus was identified by the partial inhibition of lutein synthesis in light-grown tissue and the accumulation of poly-cis-carotene precursors in dark-grown tissue of crtISO mutants. After positional cloning, enzymatic analysis of CRTISO expressed in Escherichia coli confirmed that the enzyme catalyzes the isomerization of poly-cis-carotenoids to all-trans-carotenoids. Etioplasts of dark-grown crtISO mutants accumulate acyclic poly-cis-carotenoids in place of cyclic all-trans-xanthophylls and also lack prolamellar bodies (PLBs), the lattice of tubular membranes that defines an etioplast. This demonstrates a requirement for carotenoid biosynthesis to form the PLB. The absence of PLBs in crtISO mutants demonstrates a function for this unique structure and carotenoids in facilitating chloroplast development during the first critical days of seedling germination and photomorphogenesis.     

Proteome dynamics during plastid differentiation in rice

We have analyzed proteome dynamics during light-induced development of rice (Oryza sativa) chloroplasts from etioplasts using quantitative two-dimensional gel electrophoresis and tandem mass spectrometry protein identification. In the dark, the etioplast allocates the main proportion of total protein mass to carbohydrate and amino acid metabolism and a surprisingly high number of proteins to the regulation and expression of plastid genes. Chaperones, proteins for photosynthetic energy metabolism, and enzymes of the tetrapyrrole pathway were identified among the most abundant etioplast proteins. The detection of 13 N-terminal acetylated peptides allowed us to map the exact localization of the transit peptide cleavage site, demonstrating good agreement with the prediction for most proteins. Based on the quantitative etioplast proteome map, we examined early light-induced changes during chloroplast development. The transition from heterotrophic metabolism to photosynthesis-supported autotrophic metabolism was already detectable 2 h after illumination and affected most essential metabolic modules. Enzymes in carbohydrate metabolism, photosynthesis, and gene expression were up-regulated, whereas enzymes in amino acid and fatty acid metabolism were significantly decreased in relative abundance. Enzymes involved in nucleotide metabolism, tetrapyrrole biosynthesis, and redox regulation remained unchanged. Phosphoprotein-specific staining at different time points during chloroplast development revealed light-induced phosphorylation of a nuclear-encoded plastid RNA-binding protein, consistent with changes in plastid RNA metabolism. Quantitative information about all identified proteins and their regulation by light is available in plprot, the plastid proteome database (http://www.plprot.ethz.ch).     

Adenosine triphosphatase of bean plastids: its properties and site of formation

Extracts of bean (Phaseolus vulgaris L.) etioplasts and chloroplasts contain a dithiothreitol-activated Ca²⁺-dependent adenosine triphosphatase which is inhibited by Dio-9. The chloroplast and etioplast enzymes have identical R_F values upon disc gel electrophoresis. Optimum extraction of the enzyme from either plastid preparation is accomplished with 1 mm ethylenediamine tetraacetic acid. Photophosphorylation capacity can be partially restored to depleted chloroplast preparations by addition of either the chloroplast or etioplast extract. These results suggest that the adenosine triphosphatase from etioplasts and chloroplasts represents a modified coupling factor for photophosphorylation.     

Effects of salt wash on the structure of the prolamellar body iembrane and the membrane binding of NADPH–protochlorophyllide oxidoreductase

NADPn–protochlorophyllide oxidoreductase (EC 1.6.99.1; PCR) is the major protein component of the prolamellar body (PLB) membrane of the etioplast. The interaction between the pigment–protein complex of PCR and the membrane lipids is of importance for the induction and maintenance of the regularly branched PLB structure. The isoelectric point of the PLB surface and the impact of salt treatment on the PLB structure, the PCR absorbance properties and the association of PCR to the membrane, have been studied in isolated fractions of PLBs from dark–grown wheat ( Triticum aestivum L. cv. Starke 11). We conclude that the PLB membrane has its isoelectric point at pH 4.5. which is similar to that of other plastid membranes. The PLB membrane and the pigment–protein complex of PCR are both affected by salt treatment. Concentrations below 50 mM MgCl₂, or 250 m M KCI tend to stabilize the regularly branched strueture. while higher concentrations of both mono– and divalent cations lead to disintegration of the membrane and shifts towards shorter wave–lengths of the in vivo absorbance spectra of protoehlorophyllide. PCR. the dominant PLB protein, however, seems to be intimately associated with the membrane lipids and is not washed off the membrane by repeated salt treatment.     

Changes in Phosphorylation Status of Wheat Plastid Polypeptides as Influenced by Light, Calcium and Cyclic AMP

The polypeptides of etioplast and chloroplast fractions, purified on Percoll discontinuous gradient, were phosphorylated in vitro using (γ-³²P)ATP, resolved by SDS-PAGE and autoradiographed. In general, about 15-18 phosphopolypeptides in the range of 14-150 kD were distinctly visible in autoradiograms of both organelle fractions with varying degree of radiolabel incorporation. Although short-term irradiation with red or far-red light did not have any significant effect on phosphorylation status of etioplast polypeptides, in vivo irradiation with 1 h white light, followed by in vitro phosphorylation, decreased phosphorylation of a 116 kD polypeptide and increased the phosphorylation of polypeptides of 38 kD and a doublet around 20 kD. Strikingly, the phosphorylation status of 116 kD etioplast polypeptide was adversely affected by Ca²⁺ as well, and this phosphopolypeptlde was not distinctly visible in the autoradiogram of the chloroplast fraction proteins. However, in vitro phosphorylation of 98, 57 and 50 kD polypeptides of both etioplast and chloroplast fractions was found to be Ca²⁺ dependent. Unlike Ca²⁺, 3′,5′-cyclic AMP down-regulated the phosphorylation of several polypeptides of both etioplasts and chloroplasts, including 98 and 50 kD, and up-regulated the phosphorylation of 32 and 57 kD polypeptides. The significance of these observations on changes in phosphoprotein profile of etioplasts and chloroplasts, as influenced by light, Ca²⁺ and cyclic nucleotides, has been discussed.     

The cytokinin 2-isopentenyladenine causes partial reversion to skotomorphogenesis and induces formation of prolamellar bodies and protochlorophyllide657 in the lip1 mutant of pea

When grown in darkness the photomorphogenic lip 1 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 ( lip 1) 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 lip 1 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 lip 1 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 lip 1 and the POR mRNA levels decreased in both lip 1 and wild-type plants. The chloroplast characteristic trans -3-hexadecenoate acyl group of phosphatidylglycerol, present in the plastids of dark-grown lip 1, was not influenced by 2iP. Thus, not all photomorphogenic processes reacted similarly in the lip 1 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 lip 1 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.