A role for lipid trafficking in chloroplast biogenesis

Chloroplasts are the defining plant organelle carrying out photosynthesis. Photosynthetic complexes are embedded into the thylakoid membrane which forms an intricate system of membrane lamellae and cisternae. The chloroplast boundary consists of two envelope membranes controlling the exchange of metabolites between the plastid and the extraplastidic compartments of the cell. The plastid internal matrix (stroma) is the primary location for fatty acid biosynthesis in plants. Fatty acids can be assembled into glycerolipids at the envelope membranes of plastids or they can be exported and assembled into lipids at the endoplasmic reticulum (ER) to provide building blocks for extraplastidic membranes. Some of these glycerolipids, assembled at the ER, return to the plastid where they are remodeled into the plastid typical glycerolipids. As a result of this cooperation of different subcellular membrane systems, a rich complement of lipid trafficking phenomena contributes to the biogenesis of chloroplasts. Considerable progress has been made in recent years towards a better mechanistic understanding of lipid transport across plastid envelopes. Lipid transporters of bacteria and plants have been discovered and their study begins to provide detailed mechanistic insights into lipid trafficking phenomena relevant to chloroplast biogenesis.     

Chloroplast lipid synthesis and lipid trafficking through ER-plastid membrane contact sites

Plant chloroplasts contain an intricate photosynthetic membrane system, the thylakoids, and are surrounded by two envelope membranes at which thylakoid lipids are assembled. The glycoglycerolipids mono- and digalactosyldiacylglycerol, and sulfoquinovosyldiacylglycerol as well as phosphatidylglycerol, are present in thylakoid membranes, giving them a unique composition. Fatty acids are synthesized in the chloroplast and are either directly assembled into thylakoid lipids at the envelope membranes or exported to the ER (endoplasmic reticulum) for extraplastidic lipid assembly. A fraction of lipid precursors is reimported into the chloroplast for the synthesis of thylakoid lipids. Thus polar lipid assembly in plants requires tight co-ordination between the chloroplast and the ER and necessitates inter-organelle lipid trafficking. In the present paper, we discuss the current knowledge of the export of fatty acids from the chloroplast and the import of chloroplast lipid precursors assembled at the ER. Direct membrane contact sites between the ER and the chloroplast outer envelopes are discussed as possible conduits for lipid transfer.     

Lipid synthesis and metabolism in the plastid envelope

Plastid envelope membranes play a major role in the biosynthesis of glycerolipids. In addition, plastids are characterized by the occurrence of plastid-specific membrane glycolipids (galactolipids, a sulfolipid). Plant lipid metabolism therefore has unique features, when compared to that of other eukaryotic organisms, such as animals and yeast. However, the glycerolipid biosynthetic pathway in chloroplasts is almost identical to that found in cyanobacteria, and reflects the prokaryotic origin of the chloroplast. Fatty acids generated in the plastid stroma are substrates for a whole set of enzymes involved in the synthesis of polar lipids of plastid membranes such as galactolipids, the sulfolipid, the phosphatidylglycerol. In addition, fatty acids are exported outside the plastid where they are used for extraplastidial polar lipid synthesis (phosphatidylcholine, phosphatidylethanolamine, etc.). Various desaturation steps leading to the formation of polyunsaturated fatty acids occur in various cell compartments, especially in chloroplasts, using fatty acids esterified to polar lipids as substrates. Furthermore, plant glycerolipids can be metabolized by a series of very active envelope enzymes, such as the galactolipid:galactolipid galactosyltransferase and the acyl-galactolipid forming enzyme. The physiological significance of these enzymes is however largely unknown. One of the most active pathways involved in lipid metabolism and present in envelope membranes is the oxylipin pathway: polyunsaturated fatty acids that are released from polar lipids under various conditions (injury, pathogen attack) are converted to oxylipin. Thus, the plastid envelope membranes are also involved in the formation of signalling molecules.     

烟草种子成熟过程中膜脂的变化规律研究

该研究采用脂类组学方法,系统地研究了烟草种子成熟过程中膜脂含量及组成比例的变化规律。结果表明:(1)构成叶绿体和类囊体膜的重要脂类质体膜脂的含量及其在总膜脂中的组成比例,在种子成熟的整个过程中保持下降趋势;而构成细胞膜的重要脂类质外体膜脂含量在种子成熟前期则下降显著,在授粉21 d后基本保持不变。(2)总膜脂含量的变化规律与质体膜脂类似,但在授粉后第29天后含量却达到稳定状态。(3)因油脂在种子成熟过程中不断积累,且化学结构与膜脂相似,质体膜脂含量的降低可能与种子成熟过程中种子对油脂累积的持续需求以及对叶绿体及类囊体的需求降低有关。(4)质外体膜脂含量在授粉21 d后基本保持不变的原因,可能是由于脂质外体膜脂是细胞膜组成的主要膜脂,细胞膜在种子成熟以及成熟种子萌发过程中均发挥重要作用,因此质外体膜脂只在种子成熟的前期有部分转化为油脂。     

Lipid metabolism in ageing leaves of dark-grown barley seedlings

The rapid senescence of the etiolated leaves of dark-grown barley seedlings in the dark is accompanied by the loss of those lipids associated with the plastids. The linolenate content of the plastid glycerolipids rapidly decreased whereas it tended to increase in the extraplastidic phospholipids. Kinetin treatment slowed down the loss of the plastid lipids and their constituent fatty acids. The hormone treatment brought about increased linolenate, particularly in phosphatidylcholine and monogalactosyldiacylglycerol. The senescing leaf attempts to adapt to ageing by increased membrane synthesis and/or membrane repair. Kinetin appears to control the sequential desaturation of oleate to linolenate.     

With chlorophyll pigments from prolamellar bodies to light-harvesting complexes

The biosynthetic chain leading from 5-aminolevulinic acid to chlorophyll is localised to the plastid. Many of the enzymes are nuclear-encoded. NADPH-protochlorophyllide oxidoreductase (EC 1.3.1.33) is one such enzyme which is encoded by two different genes and can exist in an A and a B form. Its import into the plastid seems to be facilitated when protochlorophyllide is present in the chloroplast envelope. Within the plastid the reductase is assembled to thylakoids or prolamellar bodies. The specific properties of the reductase together with the specific properties of the lipids present in the etioplast inner membranes promote the formation of the three-dimensional regular network of the prolamellar bodies. The reductase forms a ternary complex with protochlorophyllide and NADPH that gives rise to different spectral forms of protochlorophyllide. Light transforms protochlorophyllide into chlorophyllide and this photoreaction induces a conformational change in the reductase protein which leads to a process of disaggregation of enzyme, pigment aggregates and membranes, which can be followed spectroscopically and with electron microscopy. The newly formed chlorophyllide is esterified by a membrane-bound nuclear-encoded chlorophyll synthase and the chlorophyll molecule is then associated with proteins into active pigment protein complexes in the photosynthetic machinery.     

Porphyrin Accumulation and Export by Isolated Barley (Hordeum vulgare) Plastids (Effect of Diphenyl Ether Herbicides)

We have investigated the formation of porphyrin intermediates by isolated barley (Hordeum vulgare) plastids incubated for 40 min with the porphyrin precursor 5-aminolevulinate and in the presence and absence of a diphenylether herbicide that blocks protoporphyrinogen oxidase, the enzyme in chlorophyll and heme synthesis that oxidizes protoporphyrinogen IX to protoporphyrin IX. In the absence of herbicide, about 50% of the protoporphyrin IX formed was found in the extraplastidic medium, which was separated from intact plastids by centrifugation at the end of the incubation period. In contrast, uroporphyrinogen, an earlier intermediate, and magnesium protoporphyrin IX, a later intermediate, were located mainly within the plastid. When the incubation was carried out in the presence of a herbicide that inhibits protoporphyrinogen oxidase, protoporphyrin IX formation by the plastids was completely abolished, but large amounts of protoporphyrinogen accumulated in the extraplastidic medium. To detect extraplastidic protoporphyrinogen, it was necessary to first oxidize it to protoporphyrin IX with the use of a herbicide-resistant protoporphyrinogen oxidase enzyme present in Escherichia coli membranes. Protoporphyrinogen is not detected by some commonly used methods for porphyrin analysis unless it is first oxidized to protoporphyrin IX. Protoporphyrin IX and protoporphyrinogen found outside the plastid did not arise from plastid lysis, because the percentage of plastid lysis, measured with a stromal marker enzyme, was far less than the percentage of these porphyrins in the extraplastidic fraction. These findings suggest that of the tetrapyrrolic intermediates synthesized by the plastids, protoporphyrinogen and protoporphyrin IX, are the most likely to be exported from the plastid to the cytoplasm. These results help explain the extraplastidic accumulation of protoporphyrin IX in plants treated with photobleaching herbicides. In addition, these findings suggest that plastids may export protoporphyrinogen or protoporphyrin IX for mitochondrial heme synthesis.     

Incorporation of newly synthesized fatty acids into cytosolic glycerolipids in pea leaves occurs via acyl editing

In expanding pea leaves, over 95% of fatty acids (FA) synthesized in the plastid are exported for assembly of eukaryotic glycerolipids. It is often assumed that the major products of plastid FA synthesis (18:1 and 16:0) are first incorporated into 16:0/18:1 and 18:1/18:1 molecular species of phosphatidic acid (PA), which are then converted to phosphatidylcholine (PC), the major eukaryotic phospholipid and site of acyl desaturation. However, by labeling lipids of pea leaves with [(14)C]acetate, [(14)C]glycerol, and [(14)C]carbon dioxide, we demonstrate that acyl editing is an integral component of eukaryotic glycerolipid synthesis. First, no precursor-product relationship between PA and PC [(14)C]acyl chains was observed at very early time points. Second, analysis of PC molecular species at these early time points showed that >90% of newly synthesized [(14)C]18:1 and [(14)C]16:0 acyl groups were incorporated into PC alongside a previously synthesized unlabeled acyl group (18:2, 18:3, or 16:0). And third, [(14)C]glycerol labeling produced PC molecular species highly enriched with 18:2, 18:3, and 16:0 FA, and not 18:1, the major product of plastid fatty acid synthesis. In conclusion, we propose that most newly synthesized acyl groups are not immediately utilized for PA synthesis, but instead are incorporated directly into PC through an acyl editing mechanism that operates at both sn-1 and sn-2 positions. Additionally, the acyl groups removed by acyl editing are largely used for the net synthesis of PC through glycerol 3-phosphate acylation.     

A small ATPase protein of Arabidopsis, TGD3, involved in chloroplast lipid import

Polar lipid trafficking is essential in eukaryotic cells as membranes of lipid assembly are often distinct from final destination membranes. A striking example is the biogenesis of the photosynthetic membranes (thylakoids) in plastids of plants. Lipid biosynthetic enzymes at the endoplasmic reticulum and the inner and outer plastid envelope membranes are involved. This compartmentalization requires extensive lipid trafficking. Mutants of Arabidopsis are available that are disrupted in the incorporation of endoplasmic reticulum-derived lipid precursors into thylakoid lipids. Two proteins affected in two of these mutants, trigalactosyldiacylglycerol 1 (TGD1) and TGD2, encode the permease and substrate binding component, respectively, of a proposed lipid translocator at the inner chloroplast envelope membrane. Here we describe a third protein of Arabidopsis, TGD3, a small ATPase proposed to be part of this translocator. As in the tgd1 and tgd2 mutants, triacylglycerols and trigalactolipids accumulate in a tgd3 mutant carrying a T-DNA insertion just 5' of the TGD3 coding region. The TGD3 protein shows basal ATPase activity and is localized inside the chloroplast beyond the inner chloroplast envelope membrane. Proteins orthologous to TGD1, -2, and -3 are predicted to be present in Gram- bacteria, and the respective genes are organized in operons suggesting a common biochemical role for the gene products. Based on the current analysis, it is hypothesized that TGD3 is the missing ATPase component of a lipid transporter involving TGD1 and TGD2 required for the biosynthesis of ER-derived thylakoid lipids in Arabidopsis.     

The role of lipids in plastid protein transport

The elaborate compartmentalization of plant cells requires multiple mechanisms of protein targeting and trafficking. In addition to the organelles found in all eukaryotes, the plant cell contains a semi-autonomous organelle, the plastid. The plastid is not only the most active site of protein transport in the cell, but with its three membranes and three aqueous compartments, it also represents the most topologically complex organelle in the cell. The chloroplast contains both a protein import system in the envelope and multiple protein export systems in the thylakoid. Although significant advances have identified several proteinaceous components of the protein import and export apparatuses, the lipids found within plastid membranes are also emerging as important players in the targeting, insertion, and assembly of proteins in plastid membranes. The apparent affinity of chloroplast transit peptides for chloroplast lipids and the tendency for unsaturated MGDG to adopt a hexagonal II phase organization are discussed as possible mechanisms for initiating the binding and/or translocation of precursors to plastid membranes. Other important roles for lipids in plastid biogenesis are addressed, including the spontaneous insertion of proteins into the outer envelope and thylakoid, the role of cubic lipid structures in targeting and assembly of proteins to the prolamellar body, and the repair process of D1 after photoinhibition. The current progress in the identification of the genes and their associated mutations in galactolipid biosynthesis is discussed. Finally, the potential role of plastid-derived tubules in facilitating macromolecular transport between plastids and other cellular organelles is discussed.     

Differential distribution of chlorophyll biosynthetic intermediates in stroma, envelope and thylakoid membranes in Beta vulgaris

Stroma, envelope and thylakoid membranes were prepared from chloroplasts isolated from leaves of Beta vulgaris. Out of total plastidic protochlorophyllide, envelope membranes contained 1.5%, thylakoids had the maximum 98.48% and stroma had a trace fraction of 0.02%. Distribution of the Mg-protoporphyrin IX and its monoester was 89.0% in thylakoids, 10.0% in stroma and 1.0% in envelope. A substantial fraction (33.77%) of plastidic protoporphyrin IX was partitioned into stroma. Envelope contained 0.66% and thylakoids had 65.57% of the total plastidic protoporphyrin IX pool. The proportion of monovinyl and divinyl forms of protochlorophyllide was almost similar in intact plastid, thylakoids, and outer and inner envelope membranes suggesting a tight regulation of vinyl reductase enzyme. The significance of differential distribution of chlorophyll biosynthetic intermediates among thylakoids, envelope and stroma is discussed. This work was supported by a grant from the Council of Scientific and Industrial Research (38/1079/03/EMRII) to BCT.     

Acyl-CoA dependent acylation of phospholipids in the chloroplast envelope

Acyl-CoAs are substrates for acyl lipid synthesis in the endoplasmic reticulum. In addition, they may also be substrates for lipid acylation in other membranes. In order to assess whether lipid acylation may have a role in plastid lipid metabolism, we have studied the incorporation of radiolabelled fatty acids from acyl-CoAs into lipids in isolated, intact pea chloroplasts. The labelled lipids were phosphatidylcholine (PC), phosphatidylglycerol (PG), phosphatidylinositol and free fatty acids. With oleoyl-CoA, the fatty acid was incorporated preferably into the sn-2 position of PC and the acylation activity mainly occurred in fractions enriched in inner chloroplast envelope. Added lysoPC stimulated the activity. With palmitoyl-CoA, the fatty acid was incorporated primarily into the sn-1 position of PG and the reaction occurred at the surface of the chloroplasts. As chloroplast-synthesized PG generally contains 16C fatty acids in the sn-2 position, we propose that the acylation of PG studied represents activities present in a domain of the endoplasmic reticulum or an endoplasmic reticulum-derived fraction that is associated with chloroplasts and maintains this association during isolation. This domain or fraction contains a discreet population of lipid metabolizing activities, different from that of bulk endoplasmic reticulum, as shown by that with isolated endoplasmic reticulum, acyl-CoAs strongly labelled phosphatidic acid and phosphatidylethanolamine, lipids that were never labelled in the isolated chloroplasts.     

Import of proteins into chloroplasts. Membrane integration of a thylakoid precursor protein reconstituted in chloroplast lysates

Many of the thylakoid membrane proteins of plant and algal chloroplasts are synthesized in the cytosol as soluble, higher molecular weight precursors. These precursors are post-translationally imported into chloroplasts, incorporated into the thylakoids, and proteolytically processed to mature size. In the present study, the process by which precursors are incorporated into thylakoids was reconstituted in chloroplast lysates using the precursor to the light-harvesting chlorophyll a/b protein (preLHCP) as a model. PreLHCP inserted into thylakoid membranes, but not envelope membranes, if ATP was present in the reaction mixture. Correct integration into the bilayer was verified by previously documented criteria. Integration could also be reconstituted with purified thylakoid membranes if reaction mixtures were supplemented with a soluble extract of chloroplasts. Several other thylakoid precursor proteins in addition to preLHCP, but no stromal precursor proteins, were incorporated into thylakoids under the described assay conditions. These results suggest that the observed in vitro activity represents in vivo events during the biogenesis of thylakoid proteins.     

Some unusual features of the ultrastructure of the chloroplasts of the green algal orderCaulerpales and their development

Summary The ultrastructure of developing and mature chloroplasts of members of the green algal orderCaulerpales is described. The mature chloroplasts develop from small starch containing plastids. These small starch containing plastids may also develop into the large amyloplasts characteristic of this order. The thylakoid organizing body (TOB), a system of concentric lamellae found at one end of the plastid, appears to be involved in initial thylakoid membrane synthesis. During early plastid development the first formed thylakoids, the plastid DNA and lipid are closely associated with this body. Many developing plastids also have a number of microfilaments near the chloroplast envelope. These microfilaments extend from the TOB towards the opposite end of the plastid.The size and structure of the mature caulerpalean chloroplast varies greatly between species, as does the size and structure of the TOB. The simplest type of TOB occurs inAvrainvillea erecta and the most complex inCaulerpa cactoides. The membranes of the TOB are connected by crossbridges and they are also connected with the inner chloroplast envelope membrane. The structure of the TOB, its relation to the chloroplast envelope, its association with the thylakoids and its possible functions are described.     

Sulfolipid is a potential candidate for annexin binding to the outer surface of chloroplast

Using a subcellular-specific proteomic approach, we have identified by protein microsequencing, a putative 35-kDa annexin from among the chloroplast envelope polypeptides. To confirm this identification, we demonstrate that (a) a 35-kDa protein, identified as annexin by antibody cross-reactivity, co-purifies with Percoll-purified chloroplasts and their envelope membranes when extracted in the presence of Ca(2+) and (b) the native spinach annexin protein binds to chloroplast-specific lipids in a Ca(2+)-dependent manner. The binding of the spinach annexin to these glycerolipids occurs at similar Ca(2+) concentrations as those, which promote the interaction of annexins to phospholipids in other membranes. Among chloroplast glycerolipids known to be accessible on the cytosolic face (outer leaflet) of the outer envelope membrane, sulfolipid, and probably phosphatidylinositol, would be the sole candidates for a putative Ca(2+)-dependent interaction of annexin with the chloroplast surface.     

Envelope Membranes from Spinach Chloroplasts Are a Site of Metabolism of Fatty Acid Hydroperoxides

Enzymes in envelope membranes from spinach (Spinacia oleracea L.) chloroplasts were found to catalyze the rapid breakdown of fatty acid hydroperoxides. In contrast, no such activities were detected in the stroma or in thylakoids. In preparations of envelope membranes, 9S-hydroperoxy-10(E),12(Z)-octadecadienoic acid, 13S-hydroperoxy-9(Z),11(E)-octadecadienoic acid, or 13S-hydroperoxy-9(Z),11(E),15(Z)-octadecatrienoic acid were transformed at almost the same rates (1-2 [mu]mol min-1 mg-1 protein). The products formed were separated by reversed-phase high-pressure liquid chromatography and further characterized by gas chromatography-mass spectrometry. Fatty acid hydroperoxides were cleaved (a) into aldehydes and oxoacid fragments, corresponding to the functioning of a hydroperoxide lyase, (b) into ketols that were spontaneously formed from allene oxide synthesized by a hydroperoxide dehydratase, (c) into hydroxy compounds synthesized enzymatically by a system that has not yet been characterized, and (d) into oxoenes resulting from the hydroperoxidase activity of a lipoxygenase. Chloroplast envelope membranes therefore contain a whole set of enzymes that catalyze the synthesis of a variety of fatty acid derivatives, some of which may act as regulatory molecules. The results presented demonstrate a new role for the plastid envelope within the plant cell.     

Preparation and characterization of envelope membranes from nongreen plastids

We have developed a reliable procedure for the purification of envelope membranes from cauliflower (Brassica oleracea L.) bud plastids and sycamore (Acer pseudoplatanus L.) cell amyloplasts. After disruption of purified intact plastids, separation of envelope membranes was achieved by centrifugation on a linear sucrose gradient. A membrane fraction, having a density of 1.122 grams per cubic centimeter and containing carotenoids, was identified as the plastid envelope by the presence of monogalactosyldiacylglycerol synthase. Using antibodies raised against spinach chloroplast envelope polypeptides E24 and E30, we have demonstrated that both the outer and the inner envelope membranes were present in this envelope fraction. The major polypeptide in the envelope fractions from sycamore and cauliflower plastids was identified immunologically as the phosphate translocator. In the envelope membranes from cauliflower and sycamore plastids, the major glycerolipids were monogalactosyldiacylglycerol, digalactosyldiacylglycerol, and phosphatidylcholine. Purified envelope membranes from cauliflower bud plastids and sycamore amyloplasts also contained a galactolipid:galactolipid galactosyltransferase, enzymes for phosphatidic acid and diacylglycerol biosynthesis, acyl-coenzyme A thioesterase, and acyl-coenzyme A synthetase. These results demonstrate that envelope membranes from nongreen plastids present a high level of homology with chloroplasts envelope membranes.     

Chloroplast proteins of cytoplasmic origin. Effect of chloramphenicol on their synthesis, transport and intraplastidial localization. Ultrastructural autoradiographic studies

Ultrastructural autoradiographic studies after application of 3H-lysine indicate that during the transformation of the etioplasts into chlorplasts in the bean (Phaseolus vulgaris) the protein synthesis in plastids occurs mainly near the thylakoid membranes and the prolamellar bodies: most of the autoradiographic grains are placed over the structures. After 24 h postincubation in nonradioactive medium the ratio of the number of silver grains associated with thylakoids to those over stroma increases more than 2.5 times in control plants, whereas in cells treated with chloramphenicol only 1.5 times. Simultaneously in chloramphenicol-treated plants an increase in plastid envelope labelling is observed. It has been assumed that chloramphenicol, having no inhibitory effect on the synthesis and transport of proteins imported from the cytoplasm to the plastid, lowers their penetration inside the plastid as well as their incorporation into the thylakoid membrane.     

Ultrastructural characterization of the reversible differentiation of chloroplasts in cucumber fruit

The changes in plastid ultrastructure in the pericarp of cucumber (Cucumis sativus L) fruit were studied during fruit yellowing (which accompanied maturation) and regreening. In the course of fruit maturation, the thylakoid system was progressively reduced, and only a small number of membranes remained in the plastids of mature fruit. At the same time, the plastoglobules increased in size, often remaining in close proximity to the degrading thylakoids. In pericarp tissue which turned green again, the thylakoid network in the plastids was gradually reconstituted. Morphological similarities between the plastids in mature and regreening fruit indicated that the chloroplasts in regreened tissue were redifferentiated from the plastids of mature fruit. Reconstitution of the thylakoid system appeared to start from two morphologically distinct types of membranes: from double membranes which resembled thylakoids and from membrane-bound bodies (MBBs). The latter appeared to form thylakoids by two mechanisms: by detachment of extensions from their surfaces and by fragmentation. The plastoglobules remained in the plastids during thylakoid system reconstitution and were often observed in close proximity to developing thylakoids. In the course of chloroplast redifferentiation, several types of membraneous structures were found to be associated with the plastid envelope: (i) vesicles which appeared to separate from the envelope and to fuse subsequently with the developing thylakoids, (ii) tubules, and (iii) double-membrane sheets which appeared asde novo forming thylakoids.