The SCO2 protein disulphide isomerase is required for thylakoid biogenesis and interacts with LHCB1 chlorophyll a/b binding proteins which affects chlorophyll biosynthesis in Arabidopsis seedlings

The process of chloroplast biogenesis requires a multitude of pathways and processes to establish chloroplast function. In cotyledons of seedlings, chloroplasts develop either directly from proplastids (also named eoplasts) or, if germinated in the dark, via etioplasts, whereas in leaves chloroplasts derive from proplastids in the apical meristem and are then multiplied by division. The snowy cotyledon 2, sco2, mutations specifically disrupt chloroplast biogenesis in cotyledons. SCO2 encodes a chloroplast-localized protein disulphide isomerase, hypothesized to be involved in protein folding. Analysis of co-expressed genes with SCO2 revealed that genes with similar expression patterns encode chloroplast proteins involved in protein translation and in chlorophyll biosynthesis. Indeed, sco2-1 accumulates increased levels of the chlorophyll precursor, protochlorophyllide, in both dark grown cotyledons and leaves. Yeast two-hybrid analyses demonstrated that SCO2 directly interacts with the chlorophyll-binding LHCB1 proteins, being confirmed in planta using bimolecular fluorescence complementation (BIFC). Furthermore, ultrastructural analysis of sco2-1 chloroplasts revealed that formation and movement of transport vesicles from the inner envelope to the thylakoids is perturbed. SCO2 does not interact with the signal recognition particle proteins SRP54 and FtsY, which were shown to be involved in targeting of LHCB1 to the thylakoids. We hypothesize that SCO2 provides an alternative targeting pathway for light-harvesting chlorophyll binding (LHCB) proteins to the thylakoids via transport vesicles predominantly in cotyledons, with the signal recognition particle (SRP) pathway predominant in rosette leaves. Therefore, we propose that SCO2 is involved in the integration of LHCB1 proteins into the thylakoids that feeds back on the regulation of the tetrapyrrole biosynthetic pathway and nuclear gene expression.     

Characterization of the Snowy Cotyledon 1 Mutant of Arabidopsis Thaliana: The Impact of Chloroplast Elongation Factor G on Chloroplast Development and Plant Vitality

During seedling development chloroplast formation marks the transition from heterotrophic to autotrophic growth. The development and activity of chloroplasts may differ in cotyledons that initially serve as a storage organ and true leaves whose primary function is photosynthesis. A genetic screen was used for the identification of genes that affect selectively chloroplast function in cotyledons of Arabidopsis thaliana. Several mutants exhibiting pale cotyledons and green true leaves were isolated and dubbed snowy cotyledon (sco).One of the mutants, sco1, was characterized in more detail. The mutated gene was identified using map-based cloning. The mutant contains a point mutation in a gene encoding the chloroplast elongation factor G, leading to an amino acid exchange within the predicted 70S ribosome-binding domain. The mutation results in a delay in the onset of germination. At this early developmental stage embryos still contain undifferentiated proplastids, whose proper function seems necessary for seed germination. In light-grown sco1 seedlings the greening of cotyledons is severely impaired, whereas the following true leaves develop normally as in wild-type plants. Despite this apparent similarity of chloroplast development in true leaves of mutant and wild-type plants various aspects of mature plant development are also affected by the sco1 mutation such as the onset of flowering, the growth rate, and seed production. The onset of senescence in the mutant and the wild-type plants occurs, however, at the same time, suggesting that in the mutant this particular developmental step does not seem to suffer from reduced protein translation efficiency in chloroplasts.     

Chloroplast biogenesis by Arabidopsis seedlings is impaired in the presence of exogenous glucose

Seedlings of Arabidopsis thaliana (L.) Heynh. fail to become green when germinated and grown on media containing high concentrations of glucose (Glc). Although previous studies have shown that sugar concentration affects chlorophyll levels and photosynthetic gene expression, the possibility that sugar concentration might affect actual chloroplast biogenesis has received little attention. Therefore, experiments were conducted to determine whether germination and growth on Glc impairs development of mature chloroplasts from the proplastids found in plant embryos. To monitor chloroplast biogenesis, the levels of a chloroplast-specific fatty acid, hexadecatrienoic (16:3) fatty acid, were measured in Arabidopsis seedlings grown on media containing different concentrations of Glc. These experiments indicate that moderate concentrations of Glc delay accumulation of 16:3. The effects of Glc on 16:3 levels are not solely due to osmotic stress, as equi-molar and even twice equi-molar concentrations of sorbitol do not exert comparable effects. Seedlings grown on concentrations of Glc high enough to prevent greening accumulate almost no 16:3, even after 22 days of growth under continuous light conditions. The lack of 16:3, a major structural component of chloroplast membranes, suggests that seedlings do not develop mature chloroplasts when grown in the presence of high concentrations of exogenous Glc. Further support for this hypothesis is provided by electron microscopy studies revealing that seedlings grown on high concentrations of Glc lack identifiable chloroplasts. Although Glc has been reported to inhibit chloroplast development in unicellular organisms, similar studies on intact higher plants have been lacking.     

Early seedling growth and morphogenesis in the <Emphasis Type="Italic">xantha1</Emphasis> mutant of sunflower with alteration of chloroplast biogenesis

In the xantha1 (xan1) mutant of sunflower (Helianthus annuus L.), the effects on organ anatomy and seedling growth did correlate to the alteration of chloroplast biogenesis. The xan1 seedlings grown under 165 μmol(photon) m⁻² s⁻¹ revealed a severely altered chloroplast ultrastructure in cotyledons and leaves. Cross-sections or clarified tissues of the xan1 cotyledons did not show evident alterations with respect to normal cotyledons suggesting that the impairment of chloroplast biogenesis has negligible consequences on embryonic leaves. By contrast, the analysis of xan1 leaves showed that the defects in chloroplast biogenesis were correlated to a drastic reduction of organ size and to a clear enhancement of the trichome growth. The differentiation of palisade and spongy parenchyma in cotyledons and leaves of the xan1 mutant was normal but both organs displayed a drastic reduction in the plastid number with respect to wild type. In addition, xan1 hypocotyls showed a reduced development of the main vascular bundles in comparison with normal seedlings and an undersized central cylinder of the primary root. The exogenous supply of sucrose was not sufficient to revert in vitro the deficit of xan1 growth and the constraints in morphogenetic processes.     

A mutation in the Arabidopsis DET3 gene uncouples photoregulated leaf development from gene expression and chloroplast biogenesis

The genetic and phenotypic characterization of a new Arabidopsis mutant, de-etiolated -3, ( det 3), involved in light-regulated seedling development is described. A recessive mutation in the DET 3 gene uncouples light signals from a subset of light-dependent processes. The det 3 mutation causes dark-grown Arabidopsis thaliana seedlings to have short hypocotyls, expanded cotyledons, and differentiated leaves, traits characteristic of light-grown seedlings. Despite these morphological changes, however, the det 3 mutant does not develop chloroplasts or show elevated expression of nuclear- and chloroplast-encoded light-regulated mRNAs. The det 3 mutation thus uncovers a downstream branch of the light transduction pathways that separates leaf development from chloroplast differentiation and light-regulated gene expression. In addition, light-grown det 3 plants have reduced stature and apical dominance, suggesting that DET3 functions during growth in normal light conditions as well. The genetic interactions between mutations in det 1, det 2, and det 3 are described. The phenotypes of doubly mutant strains suggest that there are at least two parallel pathways controlling light-mediated development in Arabidopsis .     

Peroxisome biogenesis occurs in an unsynchronized manner in close association with the endoplasmic reticulum in temperature-sensitive Yarrowia lipolytica Pex3p mutants

Pex3p is a peroxisomal integral membrane protein required early in peroxisome biogenesis, and Pex3p-deficient cells lack identifiable peroxisomes. Two temperature-sensitive pex3 mutant strains of the yeast Yarrowia lipolytica were made to investigate the role of Pex3p in the early stages of peroxisome biogenesis. In glucose medium at 16 degrees C, these mutants underwent de novo peroxisome biogenesis and exhibited early matrix protein sequestration into peroxisome-like structures found at the endoplasmic reticulum-rich periphery of cells or sometimes associated with nuclei. The de novo peroxisome biogenesis seemed unsynchronized, with peroxisomes occurring at different stages of development both within cells and between cells. Cells with peripheral nascent peroxisomes and cells with structures morphologically distinct from peroxisomes, such as semi/circular tubular structures that immunostained with antibodies to peroxisomal matrix proteins and to the endoplasmic reticulum-resident protein Kar2p, and that surrounded lipid droplets, were observed during up-regulation of peroxisome biogenesis in cells incubated in oleic acid medium at 16 degrees C. These structures were not detected in wild-type or Pex3p-deficient cells. Their role in peroxisome biogenesis remains unclear. Targeting of peroxisomal matrix proteins to these structures suggests that Pex3p directly or indirectly sequesters components of the peroxisome biogenesis machinery. Such a role is consistent with Pex3p overexpression producing cells with fewer, larger, and clustered peroxisomes.     

EMB1211 is required for normal embryo development and influences chloroplast biogenesis in Arabidopsis

Chloroplast biogenesis is tightly linked with embryogenesis and seedling development. A growing body of work has been done on the molecular mechanisms underlying chloroplast development; however, the molecular components involved in chloroplast biogenesis during embryogenesis remain largely uncharacterized. In this paper, we show that an Arabidopsis mutant carrying a T‐DNA insertion in a gene encoding a multiple membrane occupation and recognition nexus (MORN)‐containing protein exhibits severe defects during embryogenesis, producing abnormal embryos and thereby leading to a lethality of young seedlings. Genetic and microscopic studies reveal that the mutation is allelic to a previously designated Arabidopsis embryo‐defective 1211 mutant (emb1211). The emb1211 +/? mutant plants produce approximately 25% of white‐colored ovules with abnormal embryos since late globular stage when primary chloroplast biogenesis takes place, while the wild‐type plants produce all green ovules. Transmission electron microscopic analysis reveals the absence of normal chloroplast development, both in the mutant embryos and in the mutant seedlings, that contributes to the albinism. The EMB1211 gene is preferentially expressed in developing embryos as revealed in the EMB1211::GUS transgenic plants. Taken together, the data indicate that EMB1211 has an important role during embryogenesis and chloroplast biogenesis in Arabidopsis.     

shygrl1 is a mutant affected in multiple aspects of photomorphogenesis

We have used a counter-selection strategy based on aberrant phytochrome regulation of an Lhcb gene to isolate an Arabidopsis mutant designated shygrl1 (shg1). shg1 seedlings have reduced phytochrome-mediated induction of the Lhcb gene family, but normal phytochrome-mediated induction of several other genes, including the rbcS1a gene. Additional phenotypes observed in shg1 plants include reduced chlorophyll in leaves and additional photomorphogenic abnormalities when the seedlings are grown on medium containing sucrose. Mutations in the TATA-proximal region of the Lhcb1*3 promoter that are known to be important for phytochrome regulation affected reporter gene expression in a manner similar to the shg1 mutation. Our results are consistent with the possibility that the mutation either leads to defective chloroplast development or to aberrant phytochrome regulation. They also add to the evidence of complex interactions between light- and sucrose-regulated pathways.     

Quantitative proteomics of a chloroplast SRP54 sorting mutant and its genetic interactions with CLPC1 in Arabidopsis

cpSRP54 (for chloroplast SIGNAL RECOGNITION PARTICLE54) is involved in cotranslational and posttranslational sorting of thylakoid proteins. The Arabidopsis (Arabidopsis thaliana) cpSRP54 null mutant, ffc1-2, is pale green with delayed development. Western-blot analysis of individual leaves showed that the SRP sorting pathway, but not the SecY/E translocon, was strongly down-regulated with progressive leaf development in both wild-type and ffc1-2 plants. To further understand the impact of cpSRP54 deletion, a quantitative comparison of ffc2-1 was carried out for total leaf proteomes of young seedlings and for chloroplast proteomes of fully developed leaves using stable isotope labeling (isobaric stable isotope labeling and isotope-coded affinity tags) and two-dimensional gels. This showed that cpSRP54 deletion led to a change in light-harvesting complex composition, an increase of PsbS, and a decreased photosystem I/II ratio. Moreover, the cpSRP54 deletion led in young leaves to up-regulation of thylakoid proteases and stromal chaperones, including ClpC. In contrast, the stromal protein homeostasis machinery returned to wild-type levels in mature leaves, consistent with the developmental down-regulation of the SRP pathway. A differential response between young and mature leaves was also found in carbon metabolism, with an up-regulation of the Calvin cycle and the photorespiratory pathway in peroxisomes and mitochondria in young leaves but not in old leaves. The Calvin cycle was down-regulated in mature leaves to adjust to the reduced capacity of the light reaction, while reactive oxygen species defense proteins were up-regulated. The significance of ClpC up-regulation was confirmed through the generation of an ffc2-1 clpc1 double mutant. This mutant was seedling lethal under autotrophic conditions but could be partially rescued under heterotrophic conditions.     

Prediction of a low dose herbicide effect from studies on binding of metribuzin to the chloroplasts of Chenopodium album L.

Chenopodium album L. seedlings at the 4- and 8-leaf stage were exposed to low concentrations metribuzin [4-amino-6-(l, l-dimethyl)-3-(methylthio)-l,2,4-triazin (4 H )-one] in nutrient solution to study herbicide uptake and the effects of low-dose rates. Chlorophyll fluorescence was measured to relate the inhibition of photosynthesis to herbicide dose. The minimum rate at which metribuzin fully inhibited photosynthesis was less than 1 μM for seedlings at the 4-leaf stage of development, and between 1 and 5 μM for the 8-leaf stage seedlings. With isolated chloroplasts, experiments were conducted to establish the relationship between the amount of herbicide molecules bound to each chloroplast and the inhibition of photosynthesis. From the dose-response curves obtained it was calculated that photosynthesis was fully inhibited when 7.5 10⁵ molecules metribuzin were bound to each chloroplast. This amount of binding was used to estimate minimum-lethal dose rates of metribuzin required for seedlings differing in fresh weight of leaves and amounts of chloroplasts present. It is suggested that prediction of a low dose herbicide effect from studies on binding of photosystem-II inhibitors in combination with chlorophyll fluorescence measurements may lead to the development of a new weed management strategy.     

增强UV-B辐射和He-Ne激光对小麦原生质体微管骨架的影响

以小麦叶片原生质体为材料,采用间接免疫荧光定位法标记其微管系统,并利用激光共聚焦扫描显微系统进行观察。研究了低剂量He-Ne激光(5mW.mm-2)、增强UV-B辐射(10.08kJ.m-2.d-1)及二者的复合处理对小麦幼苗叶肉细胞中微管骨架的影响。结果表明,增强UV-B辐射后,小麦叶片细胞中微管骨架发生解聚,呈短棒状或点状分布,微管束弥散且荧光强度减弱;而增强UV-B辐射后再施以He-Ne激光处理,小麦叶肉细胞微管骨架有部分断裂,但较单独UV-B处理组的损伤程度轻,说明低剂量的He-Ne激光可以部分修复增强UV-B辐射对微管骨架的损伤,且对微管的聚合有促进作用。     

Incorporation of [14C]carbon dioxide and [2-14C]mevalonic acid into terpenoids of higher plants during chloroplast development

1. The incorporation of (14)CO(2) and dl-[2-(14)C]mevalonic acid into various terpenoids in developing chloroplasts in a number of seedlings has been studied. 2. beta-Carotene and phytol (from chlorophyll) tend to be heavily labelled from (14)CO(2), whereas sterols and beta-amyrin are only slightly labelled; with dl-[2-(14)C]mevalonic acid the situation is reversed. 3. The incorporation of (14)CO(2) into terpenoids is dependent on the stage of chloroplast development, whereas that of mevalonic acid is independent of chloroplast development. 4. The uptake of (14)CO(2) into beta-carotene and phytol in mature chloroplasts is very low in monocotyledons but somewhat greater in dicotyledons. 5. The results are discussed in relation to the view that terpenoid biosynthesis in developing chloroplasts is regulated by a combination of enzyme segregation and specific membrane permeability.