Protein synthesis during chloroplast development in Spirodela oligorhiza. Coordinated synthesis of chloroplast-encoded and nuclear-encoded subunits of ATPase and ribulose-1,5-bisphosphate carboxylase

A proteomic analysis of maize chloroplast biogenesis

Proteomics studies to explore global patterns of protein expression in plant and green algal systems have proliferated within the past few years. Although most of these studies have involved mapping of the proteomes of various organs, tissues, cells, or organelles, comparative proteomics experiments have also led to the identification of proteins that change in abundance in various developmental or physiological contexts. Despite the growing use of proteomics in plant studies, questions of reproducibility have not generally been addressed, nor have quantitative methods been widely used, for example, to identify protein expression classes. In this report, we use the de-etiolation ("greening") of maize (Zea mays) chloroplasts as a model system to explore these questions, and we outline a reproducible protocol to identify changes in the plastid proteome that occur during the greening process using techniques of two-dimensional gel electrophoresis and mass spectrometry. We also evaluate hierarchical and nonhierarchical statistical methods to analyze the patterns of expression of 526 "high-quality," unique spots on the two-dimensional gels. We conclude that Adaptive Resonance Theory 2-a nonhierarchical, neural clustering technique that has not been previously applied to gene expression data-is a powerful technique for discriminating protein expression classes during greening. Our experiments provide a foundation for the use of proteomics in the design of experiments to address fundamental questions in plant physiology and molecular biology.

Functional analysis of a divergent system II protein, Ccs1, involved in c-type cytochrome biogenesis

The Ccs1 gene, encoding a highly divergent novel component of a system II type c-type cytochrome biogenesis pathway, is encoded by the previously defined CCS1 locus in Chlamydomonas reinhardtii. phoA and lacZalpha bacterial topological reporters were used to deduce a topological model of the Synechocystis sp. 6803 Ccs1 homologue, CcsB. CcsB, and therefore by analogy Ccs1, possesses a large soluble lumenal domain at its C terminus that is tethered in the thylakoid membrane by three closely spaced transmembrane domains in the N-terminal portion of the protein. Molecular analysis of ccs1 alleles reveals that the entire C-terminal soluble domain is essential for Ccs1 function and that a stromal loop appears to be important in vivo, at least for maintenance of Ccs1. Site-directed mutational analysis reveals that a single histidine (His(274)) within the last transmembrane domain, preceding the large lumenal domain, is required for c-type cytochrome assembly, whereas an invariant cysteine residue (Cys(199)) is shown to be non-essential. Ccs1 is proposed to interact with other Ccs components based on its reduced accumulation in ccs2, ccs3, ccs4, and ccsA strains.

Two types of ferrochelatase in photosynthetic and nonphotosynthetic tissues of cucumber: their difference in phylogeny, gene expression, and localization

Ferrochelatase catalyzes the insertion of Fe(2+) into protoporphyrin IX to generate protoheme. In higher plants, there is evidence for two isoforms of this enzyme that fulfill different roles. Here, we describe the isolation of a second ferrochelatase cDNA from cucumber (CsFeC2) that was less similar to a previously isolated isoform (CsFeC1) than it was to some ferrochelatases from other higher plants. In in vitro import experiments, the two cucumber isoforms showed characteristics similar to their respective ferrochelatase counterparts of Arabidopsis thaliana. The C-terminal region of CsFeC2 but not CsFeC1 contained a conserved motif found in light-harvesting chlorophyll proteins, and CsFeC2 belonged to a phylogenetic group of plant ferrochelatases containing this conserved motif. We demonstrate that CsFeC2 was localized predominantly in thylakoid membranes as an intrinsic protein, and forming complexes probably with the C-terminal conserved motif, but a minor portion was also detected in envelope membranes. CsFeC2 mRNA was detected in all tissues and was light-responsive in cotyledons, whereas CsFeC1 mRNA was detected in nonphotosynthetic tissues and was not light-responsive. Interestingly, tissue-, light-, and cycloheximide-dependent expressions of the two isoforms of ferrochelatase were similar to those of two glutamyl-tRNA reductase isoforms involved in the early step of tetrapyrrole biosynthesis, suggesting the existence of distinctly controlled tetrapyrrole biosynthetic pathways in photosynthetic and nonphotosynthetic tissues.

Cell cycle-dependent transcriptional and post-transcriptional regulation of chloroplast gene expression in Chlamydomonas reinhardtii

The regulated expression of five chloroplast genes in Chlamydomonas reinhardtii during a 24 hour cell cycle (12 hours light, 12 hours dark) was analyzed. Transcription rates of the genes encoding the two reaction center proteins of Photosystem I (psaA, psaB), the subunits alpha and beta (atpA, atpB) of chloroplast ATP synthase and for chloroplast elongation factor tu (EF-tu) were measured during the cell cycle. All genes are maximally transcribed at the beginning of the light period. Transcription was induced before the onset of illumination by a light-independent mechanism. Transcript abundance of the same genes during the cell cycle was determined by quantification of Northern blots hybridized with gene-specific probes. The atpA, atpB and psaB mRNAs were most abundant in the first 6 hours of the light period and decreased to about 15% of maximum in the dark. The abundance of psaA mRNA showed less variation and was maximal around the middle of the cell cycle. The EF-tu mRNA showed a maximum early in the light period, but decreased to almost undetectable levels in the second half of the light period. Because of the similar transcriptional patterns observed, the differential steady state levels of these chloroplast transcripts appeared to be regulated at the post-transcriptional level.

Multiple coordinate controls contribute to a balanced expression of ribulose-1,5-bisphosphate carboxylase/oxygenase subunits in rye leaves

In the leaves of rye (Secale cereale L.), control mechanisms acting at multiple molecular levels contribute to a coordinate expression of the subunit polypeptides of ribulose-1,5-bisphosphate carboxylase. The relevance and hierarchy of the different control steps were evaluated by comparing the time courses of changes in levels of translatable mRNA, rates of in vivo amino acid incorporation, and the turnover of subunit polypeptides after selective interference with translation at either cytoplasmic 80S ribosomes, or at the 70S ribosomes of the chloroplast, by compartment-specific inhibitors, or by the use of 70S-ribosome-deficient leaves. The latter were generated by growing the plants at a non-permissive elevated temperature of 32 degrees C. The rates of synthesis of the two ribulose-1,5-bisphosphate carboxylase subunits were most rapidly adapted to each other by translational controls. Within 0.5-2.5 h after selective inhibition of the synthesis of either subunit, that of the other subunit made in the unaffected compartment also declined by more than 90% without any marked change in its mRNA. After prolonged inhibition (24 h) of either cytoplasmic or chloroplast protein synthesis, the levels of mRNAs for both subunits were greatly diminished. In rye, the mRNA levels for both subunits changed under all experimental conditions tested in a closely parallel manner and appeared to be always maintained in a balanced, fairly constant ratio by strong coordinate controls. Even 70S-ribosome-deficient leaves contained mRNAs for both the small and the large subunits, although only in small amounts. The mRNAs for both subunits were also markedly further decreased in 70S-ribosome-deficient leaves after application of an inhibitor of cytoplasmic translation. MDMP [2-(4-methyl-2,6-dinitroanilino)-N-methylpropionamide], suggesting that the suppression of the large subunit mRNA in the plastids was not mediated through feedback effects of accumulating unassembled large subunits. Coordinate controls at both the mRNA and the translational level require a bidirectional exchange of regulatory signals between chloroplast and cytoplasm. However, these controls were not absolutely restrictive and allowed low rates of uncoupled synthesis of either large or small subunits. Large subunits made in the presence of MDMP were stable over 24 h. However, unassembled small subunits synthesized in 70S-ribosome-deficient leaves were degraded with a half-time of 10.5 h, in contrast to their behavior after integration into the holoprotein in normal leaves, where no turnover was detected. The proteolytic removal of surplus free small subunits is regarded as a final post-translational fine-tuning step to establish a balanced subunit stoichiometry in leaves.

The chloroplast genes encoding subunits of the H(+)-ATP synthase

Three CF1 and three CF0 subunits of the chloroplast H(+)-ATP synthase are encoded on the chloroplast genome. The chloroplast atp genes are organized as two operons in plants but not in the green alga, Chlamydomonas reinhardtii. The atpBE or β operon shows a relatively simple organisation and transcription pattern, while the atpIHFA or α operon is transcribed into a large variety of mRNAs. The atp genes are related to those of cyanobacteria and, more distantly, to those of non-photosynthetic bacteria such as E. coli, suggesting a common origin of most F1F0 ATP synthase subunits. Both the chloroplast and cyanobacterial ATP synthases have four F0 subunits, not three as in the E. coli complex. The proton pore of the CF0 is proposed to be formed by the interaction of subunits III and IV.

Effects of specific inhibitors on the coordination of the concentrations of ribulose-bisphosphate-carboxylase subunits and their corresponding mRNAs in the alga Chlorogonium

Investigations were carried out on the effects of inhibitors of transcription and translation on the concentrations of the subunits of the plastid enzyme ribulose-1,5-bisphosphate carboxylase/oxygenase (RuBPCase) and their corresponding mRNAs in the unicellular green alga Chlorogonium elongatum Dangeard. The light-induced increase of nuclear-coded small-subunit mRNA was strongly inhibited by α-amanitin while the increase of plastid-coded large-subunit mRNA was only weakly affected: Consequently, the mRNAs of the two subunits were present in very different proportions. Nevertheless, the light-induced increase of both subunits was strongly reduced by α-amanitin to the same degree, and hence the ratio of their concentrations was not affected compared with the untreated control cells. The effect of cycloheximide on the subunit mRNAs was similar to but weaker than that of α-amanitin. Again the increases in the subunit levels were strongly inhibited to the same degree. By contrast, rifampicin and chloramphenicol inhibited the light-induced increase of large-subunit mRNA more strongly than that of small-subunit mRNA, but the differences were less distinct than those caused by α-amanitin and cycloheximide. Again, the increase in both subunits was inhibited almost to the same extent. These results - especially those of the α-amanitin experiments - clearly show that the fine coordination of the RuBPCase subunits occurs posttranscriptionally at the level of translation and-or degradation. This conclusion was confirmed by pulse-chase experiments. Inhibition of the synthesis of the large subunits by chloramphenicol resulted - as also found by other authors-in a degradation of excess small subunits in the plastid. On the other hand, inhibition of the concentration of small subunits caused a proportionate reduction in the synthesis of large subunits, but no rapid degradation of large subunits could be detected. Therefore, the fine coordination of both subunits of RuBPCase is achieved by the degradation of an excess of small subunits, while the level of large subunits is adapted to the small subunit concentration, probably by adjustment of translation of the large-subunit mRNA. Furthermore, our experiments with α-amanitin and cycloheximide allow us to conclude that in the blue-light induction of large-subunit mRNA in the plastid the nucleocytoplasmic compartment is not directly involved.

Part of respiratory nitrate reductase of Klebsiella aerogenes is intimately associated with the peptidoglycan

Lysozyme digestion and sonication of sodium dodecyl sulfate (SDS)-purified Klebsiella aerogenes murein sacculi resulted in the quantitative release of both subunits of nitrate reductase, as well as a number of other cytoplasmic membrane polypeptides (5.2%, by weight, of the total membrane proteins). Similar results were obtained after lysozyme digestion of SDS-prepared peptidoglycan fragments, which excluded the phenomenon of simple trapping of the polypeptides by the surrounding peptidoglycan matrix. About 28% of membrane-bound nitrate reductase appears to be tightly associated with the peptidoglycan. Additional evidence for this association was demonstrated by positive immunogold labeling of SDS-murein sacculi and thin sections of plasmolyzed bacteria. Qualitative amino acid analysis of trypsin-treated sacculi, a tryptic product of holo-nitrate reductase, and amino- and carboxypeptidase digests of both nitrate reductase subunits indicated the possible existence of a terminal anchoring peptide containing the following amino acids: (Gly)n, Trp, Ser, Pro, Ile, Leu, Phe, Cys, Tyr, Asp, and Lys.

Translational regulation of light-induced ribulose 1,5-bisphosphate carboxylase gene expression in amaranth

The regulation of the genes encoding the large and small subunits of ribulose 1,5-bisphosphate carboxylase was examined in amaranth cotyledons in response to changes in illumination. When dark-grown cotyledons were transferred into light, synthesis of the large- and small-subunit polypeptides was initiated very rapidly, before any increase in the levels of their corresponding mRNAs. Similarly, when light-grown cotyledons were transferred to total darkness, synthesis of the large- and small-subunit proteins was rapidly depressed without changes in mRNA levels for either subunit. In vitro translation or in vivo pulse-chase experiments indicated that these apparent changes in protein synthesis were not due to alterations in the functionality of the mRNAs or to protein turnover, respectively. These results, in combination with our previous studies, suggest that the expression of ribulose 1,5-bisphosphate carboxylase genes can be adjusted rapidly at the translational level and over a longer period through changes in mRNA accumulation.

The genes encoding chloroplast ribosomal proteins S7 and S12 are located in the inverted repeat of Spirodela oligorhiza chloroplast DNA

We have used a variety of methods to localize the genes for ribosomal proteins S7 and S12 on Spirodela chloroplast DNA. Heterologous hybridization with a rps12 gene specific probe from Euglena has revealed the presence of rps12 homologous sequences within the inverted repeat of Spirodela chloroplast DNA on the fragment BamHI-V. In the partial nucleotide sequence of this fragment, two regions of amino acid sequence homology to Euglena S12 can be identified, separated from each other by a 542 bp intron with conserved boundary sequences. As was found for Nicotiana S12, the Spirodela S12 coding regions are for 85 amino acids homologous (79%) to E. coli S12 (starting from residue 38 to the C-terminus). Likewise, we are unable to identify the 37 5' terminal codons of rps12 in Spirodela. The functionality of the Spirodela rps12 sequence is discussed. The rps7 gene is located adjacent to rps12. Chloroplast ribosomal protein C-S11 (homologous to S7) has been detected by immunoprecipitation with both a polyspecific anti 30S serum and an anti C-S11 serum, among the in vitro translation products of mRNAs selected by Spirodela chloroplast DNA fragments BamHI-V and BamHI-P. Since in a DNA dependent E. coli cell free system, only BamHI-V appears to be capable of synthesis of C-S11, it is concluded that rps7 is located entirely within BamHI-V and is transcribed into a mRNA which extends into BamHI-P. As determined by Northern hybridization experiments, rps7 is cotranscribed with rps12; a stable transcript of approx. 1100 b is detected in total cellular Spirodela RNA with either rps12 and rps7 gene specific probes. The rps12 probe additionally detects an approx. 600 b transcript, which presumably corresponds to the excised rps12 intron RNA. Finally we have examined the expression of both rps7 and rps12 during light induced chloroplast development by Northern blotting and by immunoblotting. It is shown, that the steady-state levels of neither chloroplast ribosomal protein transcripts, nor those of the chloroplast ribosomal proteins itself, change significantly during the greening process.

Translational regulation of light-induced ribulose 1,5-bisphosphate carboxylase gene expression in amaranth

The regulation of the genes encoding the large and small subunits of ribulose 1,5-bisphosphate carboxylase was examined in amaranth cotyledons in response to changes in illumination. When dark-grown cotyledons were transferred into light, synthesis of the large- and small-subunit polypeptides was initiated very rapidly, before any increase in the levels of their corresponding mRNAs. Similarly, when light-grown cotyledons were transferred to total darkness, synthesis of the large- and small-subunit proteins was rapidly depressed without changes in mRNA levels for either subunit. In vitro translation or in vivo pulse-chase experiments indicated that these apparent changes in protein synthesis were not due to alterations in the functionality of the mRNAs or to protein turnover, respectively. These results, in combination with our previous studies, suggest that the expression of ribulose 1,5-bisphosphate carboxylase genes can be adjusted rapidly at the translational level and over a longer period through changes in mRNA accumulation.

Synthesis and degradation of unassembled polypeptides of the coupling factor of photophosphorylation CF1 in 70S ribosome-deficient rye leaves

The formation of polypeptides of the coupling factor CF1 was investigated in 70S ribosome-deficient rye leaves generated by growing the plants at a non-permissive elevated temperature of 32 degrees C, in order to analyse mechanisms coordinating subunit accumulation. Antibodies were raised in rabbits against total CF1 as well as against its five individual subunits purified from chloroplast thylakoids from rye leaves. Several immunological techniques applying these antibodies (immunoprecipitation, immunoblotting, antibody affinity chromatography) were unable to detect the presence of any of the CF1 subunits in heat-treated 70S ribosome-deficient leaves. After in vivo labeling with L-[35S]methionine and subsequent immunoprecipitation, however, radioactivity was found to be incorporated into the subunits gamma and delta, but not into alpha, beta and epsilon, in 70S ribosome-deficient leaves, demonstrating the cytoplasmic synthesis of CF1-gamma and CF1-delta. Chase experiments after in vivo labeling with L-[35S]methionine indicated that the unassembled subunits gamma and delta were rapidly and preferentially degraded, while they were stabilized when integrated into the complete CF1 complex in normal green leaves from permissive growth conditions. The apparent half-times of the unassembled subunits were 2 h for CF1-gamma and 4 h for CF1-delta in 32 degrees C-grown leaves. Several other, stromal, plastid proteins of cytoplasmic origin were stable in 32 degrees C-grown leaves during the period of chase. In etiolated leaves total CF1, including all subunits, appeared to be less stable than in green leaves grown under permissive temperature conditions in light. Rapid degradation of the excess of unassembled subunits is regarded as an important mechanism ensuring a constant stoichiometry and apparently synchronous development of CF1 subunits.

Nucleotide sequences of the genes for the alpha, beta and epsilon subunits of wheat chloroplast ATP synthase

The nucleotide sequences of the chloroplast genes for the alpha, beta and epsilon subunits of wheat chloroplast ATP synthase have been determined. Open reading frames of 1512 bp, 1494 bp and 411 bp are deduced to code for polypeptides of molecular weights 55201, 53796 and 15200, identified as the alpha, beta and epsilon subunits respectively by homology with the subunits from other sources and by amino acid sequencing of the epsilon subunit. The genes for the beta and epsilon subunits overlap by 4 bp. The gene for methionine tRNA is located 118 bp downstream from the epsilon subunit gene. Comparisons of the deduced amino acid sequences of the alpha and beta subunits with those from other species suggest regions of the proteins involved in adenine nucleotide binding.

Plastid and nuclear DNA synthesis are not coupled in suspension cells ofNicotiana tabacum

The relationship between nuclear and plastid DNA synthesis in cultured tobacco cells was measured by following(3)H-thymidine incorporation into total cellular DNA in the absence or presence of specific inhibitors. Plastid DNA synthesis was determined by hybridization of total radiolabeled cellular DNA to cloned chloroplast DNA.Cycloheximide, an inhibitor of nuclear encoded cytoplasmic protein synthesis, caused a rapid and severe inhibition of nuclear DNA synthesis and a delayed inhibition of plastid DNA synthesis. By contrast, chloramphenicol which only inhibits plastid and mitochondrial protein production, shows little inhibition of either nuclear or plastid DNA synthesis even after 24 h of exposure to the cells.The inhibition of nuclear DNA synthesis by aphidicolin, which specifically blocks the nuclear DNA polymeraseα, has no significant effect on plastid DNA formation. Conversely, the restraint of plastid DNA synthesis exerted by low levels of ethidium bromide has no effect on nuclear DNA synthesis.These results show that the synthesis of plastid and nuclear DNA are not coupled to one another. However, both genomes require the formation of cytoplasmic proteins for their replication, though our data suggest that different proteins regulate the biosynthesis of nuclear and plastid DNA.