Tic22 is targeted to the intermembrane space of chloroplasts by a novel pathway.
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Tic22 previously was identified as a component of the general import machinery that functions in the import of nuclear-encoded proteins into the chloroplast. Tic22 is peripherally associated with the outer face of the inner chloroplast envelope membrane, making it the first known resident of the intermembrane space of the envelope. We have investigated the import of Tic22 into isolated chloroplasts to define the requirements for targeting of proteins to the intermembrane space. Tic22 is nuclear-endoded and synthesized as a preprotein with a 50-amino acid N-terminal presequence. The analysis of deletion mutants and chimerical proteins indicates that the precursor of Tic22 (preTic22) presequence is necessary and sufficient for targeting to the intermembrane space. Import of preTic22 was stimulated by ATP and required the presence of protease-sensitive components on the chloroplast surface. PreTic22 import was not competed by an excess of an authentic stromal preprotein, indicating that targeting to the intermembrane space does not involve the general import pathway utilized by stromal preproteins. On the basis of these observations, we conclude that preTic22 is targeted to the intermembrane space of chloroplasts by a novel import pathway that is distinct from known pathways that target proteins to other chloroplast subcompartments. (+info)
The envelope anion channel involved in chloroplast protein import is associated with Tic110.
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An anion channel of the chloroplast envelope was previously shown to be involved in protein import. Some gating characteristics of the channel are presented. The pore size of the channel is estimated to be around 6.5 A. Antibodies raised to Tic110 completely inactivate the protein import-related channel. These observations suggest that the channel is associated with the Tic machinery and can function as the protein conducting channel of the inner envelope membrane. (+info)
Protein prenylation in spinach chloroplasts.
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Protein prenylation in plants was studied by in vivo metabolic (3)H-mevalonate labeling in combination with a range of protein synthesis inhibitors. In spinach cotyledons, this posttranslational protein modification was found to be divided into two categories, one representing the conventional prenylation involving farnesyl and geranylgeranyl groups bound to cysteine residues via thioether linkages. This category revealed a similar pattern of prenylated proteins to that observed in mammalian cells and depends on nuclear gene expression. The other category was shown to represent a type of prenylation confined to chloroplasts. It depends on plastid gene expression and does not involve a thioether bond. The modifying isoprenoid could be released from the chloroplastic polypeptides by alkaline treatment and was identified as phytol upon GC-MS analysis. The phytol could readily be derived from all-trans-[(3)H]farnesol, which, like all-trans-[(3)H]geranylgeraniol, was taken up by the cotyledons, resulting in incorporation of radiolabel into proteins. (+info)
The complete chloroplast DNA sequence of the green alga Nephroselmis olivacea: insights into the architecture of ancestral chloroplast genomes.
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Green plants seem to form two sister lineages: Chlorophyta, comprising the green algal classes Prasinophyceae, Ulvophyceae, Trebouxiophyceae, and Chlorophyceae, and Streptophyta, comprising the Charophyceae and land plants. We have determined the complete chloroplast DNA (cpDNA) sequence (200,799 bp) of Nephroselmis olivacea, a member of the class (Prasinophyceae) thought to include descendants of the earliest-diverging green algae. The 127 genes identified in this genome represent the largest gene repertoire among the green algal and land plant cpDNAs completely sequenced to date. Of the Nephroselmis genes, 2 (ycf81 and ftsI, a gene involved in peptidoglycan synthesis) have not been identified in any previously investigated cpDNA; 5 genes [ftsW, rnE, ycf62, rnpB, and trnS(cga)] have been found only in cpDNAs of nongreen algae; and 10 others (ndh genes) have been described only in land plant cpDNAs. Nephroselmis and land plant cpDNAs share the same quadripartite structure-which is characterized by the presence of a large rRNA-encoding inverted repeat and two unequal single-copy regions-and very similar sets of genes in corresponding genomic regions. Given that our phylogenetic analyses place Nephroselmis within the Chlorophyta, these structural characteristics were most likely present in the cpDNA of the common ancestor of chlorophytes and streptophytes. Comparative analyses of chloroplast genomes indicate that the typical quadripartite architecture and gene-partitioning pattern of land plant cpDNAs are ancient features that may have been derived from the genome of the cyanobacterial progenitor of chloroplasts. Our phylogenetic data also offer insight into the chlorophyte ancestor of euglenophyte chloroplasts. (+info)
Comparison of DeltapH- and Delta***φ***-driven ATP synthesis catalyzed by the H(+)-ATPases from Escherichia coli or chloroplasts reconstituted into liposomes.
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The H(+)-ATPases from Escherichia coli, EF(0)F(1), and from chloroplasts, CF(0)F(1), were reconstituted in liposomes from phosphatidylcholine/phosphatidic acid. The proteoliposomes were energized by an acid-base transition and a K(+)/valinomycin diffusion potential and the initial rate of ATP synthesis was measured as a function of the transmembrane pH difference, DeltapH, and the electric potential difference, Deltaφ. With EF(0)F(1), a rate of 80 s(-1) is observed at DeltapH=4.1 and Deltaφ approximately 140 mV. The rate decreases sigmoidally with Deltaφ and at Deltaφ approximately 0 mV, the rate is about 1 s(-1) although DeltapH is still 4.1. Under the same conditions with CF(0)F(1), a rate of 280 s(-1) is observed which decreases to 190 s(-1) when Deltaφ is abolished, i.e. ATP synthesis catalyzed by EF(0)F(1) and CF(0)F(1) depends in a different way on DeltapH and Deltaφ. EF(0)F(1)-catalyzed ATP synthesis was measured as a function of DeltapH at a constant Deltaφ. The rate depends sigmoidally on DeltapH reaching a maximal rate which cannot be further increased by increasing DeltapH. However, this maximal rate depends on Deltaφ, i.e. DeltapH and Deltaφ are not kinetically equivalent in driving ATP synthesis. We assume that EF(0)F(1) must be converted into a metastable, active state before it catalyzes proton transport-coupled ATP synthesis. For EF(0)F(1), this activation step depends only on Deltaφ, whereas for CF(0)F(1), the activation depends on DeltapH and Deltaφ. (+info)
C172S substitution in the chloroplast-encoded large subunit affects stability and stress-induced turnover of ribulose-1,5-bisphosphate carboxylase/oxygenase.
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Previous work has indicated that the turnover of chloroplast ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco; EC 4.1.1. 39) may be controlled by the redox state of certain cysteine residues. To test this hypothesis, directed mutagenesis and chloroplast transformation were employed to create a C172S substitution in the Rubisco large subunit of the green alga Chlamydomonas reinhardtii. The C172S mutant strain was not substantially different from the wild type with respect to growth rate, and the purified mutant enzyme had a normal circular dichroism spectrum. However, the mutant enzyme was inactivated faster than the wild-type enzyme at 40 and 50 degrees C. In contrast, C172S mutant Rubisco was more resistant to sodium arsenite, which reacts with vicinal dithiols. The effect of arsenite may be directed to the cysteine 172/192 pair that is present in the wild-type enzyme, but absent in the mutant enzyme. The mutant enzyme was also more resistant to proteinase K in vitro at low redox potential. Furthermore, oxidative (hydrogen peroxide) or osmotic (mannitol) stress-induced degradation of Rubisco in vivo was delayed in C172S mutant cells relative to wild-type cells. Thus, cysteine residues could play a role in regulating the degradation of Rubisco under in vivo stress conditions. (+info)
Comparative analysis of splicing of the complete set of chloroplast group II introns in three higher plant mutants.
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The barley mutant albostrians and the maize mutants crs1 and crs2 are defective in the splicing of various plastid group II introns. By analysing tRNA precursors and several mRNAs not previously examined, the investigation of in vivo splicing defects in these mutants has been completed. The albostrians mutation causes the loss of plastid ribosomes resulting secondarily in a disruption of splicing of all subgroup IIA introns in the chloroplast. Thus MatK, the only putative chloroplast intron-specific maturase of higher plants, might have evolved to function in splicing of multiple introns. We show that in the case of tRNA-Ala(UGC)the first step of splicing is affected, as suggested by the absence of lariat molecules. Thus the plastid-encoded splicing factor lacking in albostrians must participate in the formation of the catalytically active structure. In contrast, a mutation in the nuclear gene crs1 prevents splicing of only one intron but causes specific additional effects as precursor transcripts for tRNA-Ile(GAU), tRNA-Ala(UGC), tRNA-Lys(UUU)and tRNA-Val(UAC), but not tRNA-Gly(UCC), have significantly enhanced steady-state levels in this mutant. Our data provide evidence for a variety of splicing factors and pathways in the chloroplast, some encoded by nuclear and some by chloroplast genes, and possibly for a dual function of some of these factors. (+info)
Mechanically induced avoidance response of chloroplasts in fern protonemal cells.
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Cell response to mechanical stimulation was investigated at a subcellular level in protonemal cells of the fern Adiantum capillus-veneris L. by pressing a small part of the cell with a microcapillary. In cells receiving local stimulation, the chloroplasts moved away from the site of stimulation, whereas the nuclei failed to show such avoidance movement. Mechanical stimulation for a period as short as 0.3 min was enough to induce the avoidance response to a maximal level. The avoidance movement of chloroplasts started within 30 min and the plateau level of avoidance was attained around 2 h after stimulation. By tracing the movement of chloroplasts during the response, it was shown that the mobility of chloroplasts near the stimulation site increased transiently within 1 h after the stimulation. After 2 to 3 h, it slowed down to the control level without stimulation. The avoidance response was inhibited by 0.1 mM cytochalasin B and 25 mM 2, 3-butanedione monoxime but not by 3.3 microM amiprophosmethyl or 5 mM colchicine. These findings indicate that the protonemal cells were very sensitive to mechanical stimulation and that chloroplasts moved away from the mechanically stimulated site through the actomyosin motile system. (+info)