More plastids in human parasites?

Trypanosomatid parasites are disease agents with an extraordinarily broad host range including humans, livestock and plants. Recent work has revealed that trypanosomatids harbour numerous genes sharing apparent common ancestry with plants and/or bacteria. Although there is no evidence of a plastid (chloroplast-like organelle) in trypanosomatids, the presence of such genes suggests lateral gene transfer from some photosynthetic organism(s) during trypanosomatid evolution. Remarkably, many products of these horizontally acquired genes now function in the glycosome, a highly modified peroxisome unique to trypanosomatids and their near relatives.     

Glycoprotein import: A common feature of complex plastids?

Complex plastids evolved by secondary endosymbiosis and are, in contrast to primary plastids, surrounded by 3 or 4 envelope membranes. Recently, we provided evidence that in diatoms proteins exist that get N-glycosylated during transport across the outermost membrane of the complex plastid. This gives rise to unique questions on the transport mechanisms of these bulky proteins, which get transported across up to 3 further membranes into the plastid stroma. Here we discuss our results in an evolutionary context and speculate about the existence of plastidal glycoproteins in other organisms with complex plastids.     

Vipp1: a very important protein in plastids?!

As a key feature in oxygenic photosynthesis, thylakoid membranes play an essential role in the physiology of plants, algae, and cyanobacteria. Despite their importance in the process of oxygenic photosynthesis, their biogenesis has remained a mystery to the present day. A decade ago, vesicle-inducing protein in plastids 1 (Vipp1) was described to be involved in thylakoid membrane formation in chloroplasts and cyanobacteria. Most follow-up studies clearly linked Vipp1 to membranes and Vipp1 interactions as well as the defects observed after Vipp1 depletion in chloroplasts and cyanobacteria indicate that Vipp1 directly binds to membranes, locally stabilizes bilayer structures, and thereby retains membrane integrity. Here current knowledge about the structure and function of Vipp1 is summarized with a special focus on its relationship to the bacterial phage shock protein A (PspA), as both proteins share a common origin and appear to have retained many similarities in structure and function.     

Conjoined mitochondria and plastids in the barley mutant ‘albostrians’

The intercalary meristem and surrounding tissues of the gene induced plastome mutant albostrians of Hordeum vulgare L. were examined in the electron microscope for ultrastructural evidence of membrane continuities between plastids and mitochondria. In well developed tissues the ribosome-deficient plastids were usually in close proximity or appressed to mitochondria of normal appearance. In some sections through the meristemmatic region however the relationship between the two organelles was observed to be of a fused nature. These conjoinings are thought to be similar to those reported in normal living cells using cinephotomicrography but never before observed by transmission electron microscopy.     

Did an ancient chlamydial endosymbiosis facilitate the establishment of primary plastids?

Background  

Ancient endosymbioses are responsible for the origins of mitochondria and plastids, and they contribute to the divergence of several major eukaryotic groups. Although chlamydiae, a group of obligate intracellular bacteria, are not found in plants, an unexpected number of chlamydial genes are most similar to plant homologs, which, interestingly, often contain a plastid-targeting signal. This observation has prompted several hypotheses, including gene transfer between chlamydiae and plant-related groups and an ancestral relationship between chlamydiae and cyanobacteria.     

Did some red alga‐derived plastids evolve via kleptoplastidy? A hypothesis

The evolution of plastids has a complex and still unresolved history. These organelles originated from a cyanobacterium via primary endosymbiosis, resulting in three eukaryotic lineages: glaucophytes, red algae, and green plants. The red and green algal plastids then spread via eukaryote–eukaryote endosymbioses, known as secondary and tertiary symbioses, to numerous heterotrophic protist lineages. The number of these horizontal plastid transfers, especially in the case of red alga‐derived plastids, remains controversial. Some authors argue that the number of plastid origins should be minimal due to perceived difficulties in the transformation of a eukaryotic algal endosymbiont into a multimembrane plastid, but increasingly the available data contradict this argument. I suggest that obstacles in solving this dilemma result from the acceptance of a single evolutionary scenario for the endosymbiont‐to‐plastid transformation formulated by Cavalier‐Smith & Lee (1985). Herein I discuss data that challenge this evolutionary scenario. Moreover, I propose a new model for the origin of multimembrane plastids belonging to the red lineage and apply it to the dinoflagellate peridinin plastid. The new model has several general and practical implications, such as the requirement for a new definition of cell organelles and in the construction of chimeric organisms.     

Division and DNA distribution in ribosome-deficient plastids of the barley mutant “albostrians”

The ribsome-deficient plastids of the albino leaves of the barley mutant albostrians divide at about the same rate as normal plastids and contain similar levels of plastids DNA to the normal plastids. Double-ring structures were observed around the neck of constricting dumbbell-shaped, ribosome-deficient plastids in the basal intercalary meristem of albino leaves. In the distal region of albino leaves the ribosome-deficient plastids contain a rudimentary thylakoid system often closely associated with DNA nucleoids. It is suggested that nuclear coded proteins synthesized within the cytoplasm are responsible for the formation of the double-ring structures and the rudimentary thylakoids of albino plastids.     

Developmental regulation of the maize Zm-p60.1 gene encoding a β-glucosidase located to plastids

A β-glucosidase that cleaves the biologically inactive hormone conjugates cytokinin-O- and kinetin-N3-glucosides is encoded by the maize Zm-p60.1 gene. The expression of the Zm-p60.1 gene was analyzed by Northern blot analysis and in-situ hybridization. It was found that the expression levels of the Zm-p60.1-specific mRNA changed after pollination of carpellate inflorescences. The Zm-p60.1 cDNA was expressed in E. coli and antibodies were raised against this protein. An antibody was used to determine the tissue-specific localization of this protein. By in situ immunolocalization experiments, this protein was found to be located in cell layers below the epidermis and around the vascular bundles of the coleoptile. In the primary leaf, the Zm-p60.1 protein was detected in cells of the outermost cell layer and around the vascular tissue. In floral tissue, Zm-p60.1 was present in the glumes, the carpels and in the outer cell layer of the style. In coleoptiles, as determined by immuno-electronmicroscopy, the Zm-p60.1 protein was located exclusively in the plastids. Received: 11 August 1998 / Accepted: 30 December 1998     

Dynamic morphologies of pollen plastids visualised by vegetative-specific FtsZ1–GFP in Arabidopsis thaliana

The behaviour and multiplication of pollen plastids have remained elusive despite their crucial involvement in cytoplasmic inheritance. Here, we present live images of plastids in pollen grains and growing tubes from transgenic Arabidopsis thaliana lines expressing stroma-localised FtsZ1–green-fluorescent protein fusion in a vegetative cell-specific manner. Vegetative cells in mature pollen contained a morphologically heterogeneous population of round to ellipsoidal plastids, whilst those in late-developing (maturing) pollen included plastids that could have one or two constriction sites. Furthermore, plastids in pollen tubes exhibited remarkable tubulation, stromule (stroma-filled tubule) extension, and back-and-forth movement along the direction of tube growth. Plastid division, which involves the FtsZ1 ring, was rarely observed in mature pollen grains.     

Do plastids in Dendrobium cv. Lucky Duan petals function similar to autophagosomes and autolysosomes?

In animal cells a double-membrane-bound structure, the autophagosome, encloses a portion of the cytoplasm. The encapsulated material becomes digested after fusion of the autophagosome with a vesicle containing lytic enzymes. The autophagosome is then termed autolysosome. In intact plants, structures similar to animal autophagosomes/autolysosomes have been found only in a few types of cells. Additionally, some early papers indicated that plastids can function similar to autophagosomes/autolysosomes. Here, we report that plastids in Dendrobium cv. Lucky Duan petals produced an endocytosis-like invagination of the two outer membranes. The opening between the invagination space and the cytoplasm was almost isodiametric, less than 0.2 μm in diameter. The volume of the space formed by the invagination had a maximum of about half of the total plastid volume. Staining of the invagination lumen for acid phosphatase, a marker of organelles showing autophagic activity, was positive. Membranes and numerous ribosomes were observed inside the lumen of the invagination. The structure of the material inside the lumen varied from that of the cytoplasm to uniform electron-translucent, indicating that the enclosed cytoplasmic material became completely digested. No support was found for the idea that the material engulfed by the plastid or the whole plastid became transferred to a vacuole. Taken together, the data suggested the hypothesis that plastids in Dendrobium petal mesophyll cells can function in a way similar to both autophagosomes and autolysosomes in animal cells.     

The first α-helical domain of the vesicle-inducing protein in plastids 1 promotes oligomerization and lipid binding

The vesicle-inducing protein in plastids 1 (Vipp1) is an essential component for thylakoid biogenesis in cyanobacteria and chloroplasts. Vipp1 proteins share significant structural similarity with their evolutionary ancestor PspA (bacterial phage shock protein A), namely a predominantly α-helical structure, the formation of oligomeric high molecular weight complexes (HMW-Cs) and a tight association with membranes. Here, we elucidated domains of Vipp1 from Arabidopsis thaliana involved in homo-oligomerization as well as association with chloroplast inner envelope membranes. We could show that the 21 N-terminal amino acids of Vipp1, which form the first α-helix of the protein, are essential for assembly of the 2 MDa HMW-C but are not needed for formation of smaller subcomplexes. Interestingly, removal of this domain also interferes with association of the Vipp1 protein to the inner envelope. Fourier transform infrared spectroscopy of recombinant Vipp1 further indicates that Escherichia coli lipids bind tightly enough that they can be co-purified with the protein. This feature also depends on the presence of the first helix, which strongly supports an interaction of lipids with the Vipp1 HMW-C but not with smaller subcomplexes. Therefore, Vipp1 oligomerization appears to be a prerequisite for its membrane association. Our results further highlight structural differences between Vipp1 and PspA, which might be important in regard to their different function in thylakoid biogenesis and bacterial stress response, respectively.     

The stromacentre inAvena plastids: an aggregation ofβ-glucosidase responsible for the activation of oat-leaf saponins

The stromacentre, a particular structure in the plastids of mostAvena species, was isolated from etioplasts ofAvena sativa and then characterized to determine its biological function. When comparing differentAvena species with or without stromacentre, it was shown that the stromacentre, a 63-kDa protein, and saponins (characteristic compounds ofAvena sativa) either occur together or not at all. This linkage was confirmed by demonstrating a transformation of saponins by the isolated stromacentre protein: avenacosides were hydrolyzed to 26-desgluco-avenacosides. Therefore, the stromacentre protein had to be regarded as a-glucosidase. Enzyme assays usingp-nitrophenyl--d-glucopyranoside as substrate showed that this-glucosidase has a pH optimum at pH 6.0. The calculatedK _m value for this substrate was 2.2·10^-3 M. Antibodies against the stromacentre protein inhibited-glucosidase activity. The determination of the molecular weight of the-glucosidase by sodium dodecyl sulfate-gel electrophoresis showed that it consists of subunits of 63 kDa. After gel electrophoresis under non-denaturing conditions, enzymatically active molecules were shown to consist of at least two of these subunits. Molecules aggregated up to about 10⁶ Da also had enzyme activity. Enzyme assays using avenacosides as substrate showed a pH optimum at pH 6.0. The calculatedK _m value for this substrate was 1.2·10^-5 M. The high affinity to the avenacosides and the high specificity for the C-26 bound glucose indicate that avenacosides are the natural substrates for this-glucosidase. Assuming that the avenacosides in oat leaves play a role as preformed chemical inhibitory substances against phytopathogenic microorganisms, a model is presented showing the stromacentre with a central role in activating the fungitoxicity of avenacosides.     

Transient expression of β-glucuronidase in plastids of various plant cells and tissues delivered by a pneumatic particle gun

Chloroplast expression plasmids pTRBCL-GUS (tobaccorbcL promoter-gusA-tobaccorbcL terminator) and pHHU3004 (spinach ‘x gene’ promoter-gusA-spinachrbcL terminator) and a control nuclear expression plasmid pBI221 (CaMV 35S promoter-gusA-NOS terminator) were introduced separately into cultured cells and tissues of tobacco andArabidopsis thaliana, as well as into cultured cells of the lower land plants liverwort and hornwort by a pneumatic particle gun. The pTRBCL-GUS and pHHU3004 plasmids produced many blue spots in the BY-2 cells and the roots ofArabidopsis thaliana, but not in any of the green cells or tissues. The results suggest that the pTRBCL-GUS and pHHU3004 plasmids are expressed more in proplastids and amyloplasts than in chloroplasts. GUS activities of the BY-2 cells bombarded with pTRBCL-GUS and pHHU3004 were insensitive to α-amanitin treatment (10 and 50 μg/ml), while that of the cells with pBI221 greatly decreased by the same treatment. Hence, it is likely that the pTRBCL-GUS and pHHU3004 plasmids were substantially expressed in the proplastids.     

Morphological and chemical studies on the crystalloid-forming ‘succulent protein’ from normal and ribosome-deficient Aeonium domesticum plastids

Aeonium domesticum cv. variegatum is a mesochimera of the constitution green/white/green with normal proplastids and chloroplasts in the unaffected tissues and ribosome-deficient colourless mutant plastids in the white leaf tissues. All the different plastid types contain succulent protein crystalloids (SPC). For more detailed characterization, the SPC elements were freed from the plastids and purified by gel filtration. Electron microscopy of different fractions revealed five levels of structural organization. Beginning with the most complex state, the levels are designated as succulent protein (SP) organizational state V (hexagonally arranged and closely packed tubules in the stroma of intact plastids) to I (globular protomers of 5 nm diameter as the basic structure of SPCs). Highly purified SP-fractions were shown by means of sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) to consist of two or three proteins of M_r 56 kdalton, 58 kdalton and 60 kdalton, depending on the buffer medium used for SP isolation and the duration of storage of leaves in the frozen state. In the urea/SDS-PAGE system, these proteins show similar mobilities to - and -tubulin, but no immunoreaction against antitubulin. The proteolytic cleavage pattern of tubulin subunits and SP proteins are different. Their locations on two-dimensional isoelectric focusing-SDS gels show some overlappings because of microheterogeneities in both proteins in the pH gradient from pH 4.5 to 6.5. Malatedehydrogenase activity could not be detected in the purified SP fractions.Abbreviations CAM Crassulacean acid metabolism - SDS-PAGE sodium dodecyl sulfate-polyacrylamide gel electrophoresis - SP succulent protein - SPC succulent protein crystalloid - SPOS succulent protein organizational state     

The general occurrence of “plastid initials” and their development into plastids in cortical cells of woody plants in winter

Summary Electron microscopic studies revealed that plastid initials, presumed precursors of plastids, occur in cortical cells of the following plants studied in February and March: Betula ermanii Cham.; Prunus sargentii Rhed.; Pyrus communis L.; Ribes sinanense F. Maekawa; Salix matsudana Koidz. forma tortuosa Rhed.; and Sambucus sieboldiana var. miquelii Hara. Since plastid initials were found previously in Malus pumila Mill., Morus bombycis Koidz. and Populus euramericana cv. gelrica (Sagisaka 1991), plastid initials have been found in all woody plants examined to date. In P. euramericana cv. gelrica, at later stages of the development of the initials in March, the conglomerates of plastid initials became heterogeneous in terms of size, extent of thylakoid formation and ability to form starch granules. The formation of prolamellar structures was frequently observed in cells of Magnolia kobus var. borealis Sarg., which was sampled on April 19. These observations suggest the course of events in the development of the plastid initial and the continuity of the life of amyloplasts over a year in the life of woody plants.