Sequence of the intercistronic region between the ribulose-1, 5-bisphosphate carboxylase/oxygenase large subunit and coupling factor beta subunit gene

Engineered PPR proteins as inducible switches to activate the expression of chloroplast transgenes

The engineering of plant genomes presents exciting opportunities to modify agronomic traits and to produce high-value products in plants. Expression of foreign proteins from transgenes in the chloroplast genome offers advantages that include the capacity for prodigious protein output, the lack of transgene silencing and the ability to express multicomponent pathways from polycistronic mRNA. However, there remains a need for robust methods to regulate plastid transgene expression. We designed orthogonal activators that boost the expression of chloroplast transgenes harbouring cognate cis-elements. Our system exploits the programmable RNA sequence specificity of pentatricopeptide repeat proteins and their native functions as activators of chloroplast gene expression. When expressed from nuclear transgenes, the engineered proteins stimulate the expression of plastid transgenes by up to ~40-fold, with maximal protein abundance approaching that of Rubisco. This strategy provides a means to regulate and optimize the expression of foreign genes in chloroplasts and to avoid deleterious effects of their products on plant growth.

Engineered RNA-binding protein for transgene activation in non-green plastids

Non-green plastids are desirable for the expression of recombinant proteins in edible plant parts to enhance the nutritional value of tubers or fruits, or to deliver pharmaceuticals. However, plastid transgenes are expressed at extremely low levels in the amyloplasts of storage organs such as tubers^1-3. Here, we report a regulatory system comprising a variant of the maize RNA-binding protein PPR10 and a cognate binding site upstream of a plastid transgene that encodes green fluorescent protein (GFP). The binding site is not recognized by the resident potato PPR10 protein, restricting GFP protein accumulation to low levels in leaves. When the PPR10 variant is expressed from the tuber-specific patatin promoter, GFP accumulates up to 1.3% of the total soluble protein, a 60-fold increase compared with previous studies² (0.02%). This regulatory system enables an increase in transgene expression in non-photosynthetic plastids without interfering with chloroplast gene expression in leaves.

The downstream atpE cistron is efficiently translated via its own cis-element in partially overlapping atpB-atpE dicistronic mRNAs in chloroplasts

The chloroplast atpB and atpE genes encode subunits β and ε of the ATP synthase, respectively. They are co-transcribed as dicistronic mRNAs in flowering plants. An unusual feature is an overlap (AUGA) of the atpB stop codon (UGA) with the atpE start codon (AUG). Hence, atpE translation has been believed to depend on atpB translation (i.e. translational coupling). Using an in vitro translation system from tobacco chloroplasts, we showed that both atpB and atpE cistrons are translated from the tobacco dicistronic mRNA, and that the efficiency of atpB translation is higher than that of atpE translation. When the atpB 5'-UTR was replaced with lower efficiency 5'-UTRs, atpE translation was higher than atpB translation. Removal of the entire atpB 5'-UTR arrested atpB translation but atpE translation still proceeded. Introduction of a premature stop codon in the atpB cistron did not abolish atpE translation. These results indicate that atpE translation is independent of atpB translation. Mutation analysis showed that the atpE cistron possesses its own cis-element(s) for translation, located ~25 nt upstream from the start codon.

Chloroplast tRNA gene contains a long intron in the D stem: Nucleotide sequences of tobacco chloroplast genes for tRNA (UCC) and tRNA (UCU)

The nucleotide sequences of tobacco chloroplast genes for tRNA(Gly) (UCC) and tRNA(Arg) (UCU) have been determined. The tRNA(Gly) gene has a 691-base-pair intron located in the D stem while the tRNA(Arg) gene does not have any intron. The tRNA(Gly) and tRNA(Arg) genes are encoded on the same strand and separated by a 169-base-pair spacer. The tRNA(Gly) gene is transcribed as a 900-base precursor RNA molecule. The tRNA(Gly) and tRNA(Arg) deduced from the DNA sequences show 84% and 55% sequence homologies with Escherichia coli tRNA(Gly) (UCC) and phage T4 tRNA(Arg) (UCU), respectively.

The evolution of the atpbeta-rbcL intergenic spacer in the epacrids (Ericales) and its systematic and evolutionary implications

Sequence data from the noncoding region separating the plastid genes atpbeta and rbcL were gathered for 27 epacrid taxa, representing all previously recognized infrafamilial groups, and four outgroup taxa (Ericaceae), to address several persistent phylogenetic questions in the group. Parsimony analyses were conducted on these data, as well as on a complementary rbcL sequence dataset assembled from the literature and the combined dataset. The atpbeta-rbcL spacer was notable for the high frequency of insertion-deletion mutations (indels); their distributions were coded as binary characters and included as a adjunct matrix in some of the analyses. The phylogenetic patterns derived from the spacer and rbcL data and the combined analyses, both including and excluding the indel data, concur in resolving seven major lineages corresponding to the tribes of Crayn et al. (1998, Aust. J. Bot. 46, 187-200), viz. Prionoteae, Archerieae, Oligarrheneae, Cosmelieae, Richeeae, Epacrideae, and Styphelieae. The relationships of the tribes and within Styphelieae, however, are not convincingly resolved. Minor conflicts in the positions of some taxa between the spacer and the rbcL trees are poorly supported. Among epacrids, the spacer region provided more cladistically informative characters than rbcL and resulted in trees with lower homoplasy. Further, the spacer data, when analyzed alone and when combined with rbcL, resolved several clades that could not be retrieved on rbcL data alone and provided increased support for many other relationships. The evolution of a putative three-base inversion associated with a hairpin secondary structure in the spacer region is discussed in the light of the inferred phylogeny.

Oxidative stress causes ferredoxin-NADP+ reductase solubilization from the thylakoid membranes in methyl viologen-treated plants

The flavoenzyme ferredoxin-NADP+ reductase (FNR) is a member of the cellular defense barrier against oxidative damage in Escherichia coli. We evaluated the responses of chloroplast FNR to methyl viologen, a superoxide radical propagator, in wheat (Triticum aestivum L.) plants and chloroplasts. Treatments with the herbicide showed little effect on the levels of FNR protein or transcripts, indicating that expression of this reductase is not upregulated by oxidants in plants. Viologens and peroxides caused solubilization of active FNR from the thylakoids into the stroma, converting the enzyme from a membrane-bound NADPH producer to a soluble NADPH consumer. This response appeared specific for FNR, since other thylakoid proteins were unaffected by the treatments. The reductase-binding protein was released together with FNR, suggesting that it might be the target of oxidative modification. Stromal accumulation of a functional NADPH reductase in response to oxidative stress is formally analogous to the induction of FNR synthesis observed in E. coli under similar conditions. FNR solubilization may be playing a crucial role in maintaining the NADPH/NADP+ homeostasis of the stressed plastid. The unchecked accumulation of NADPH might otherwise increase the risks of oxidative damage through a rise in the Mehler reaction rates and/or the production of hydroxyl radicals.

Alternate paths of evolution for the photosynthetic gene rbcL in four nonphotosynthetic species of Orobanche

We have determined the nucleotide sequence for the Rubisco large subunit from four holoparasitic species of Orobanche. Intact open reading frames are present in two species (O. corymbosa and O. fasciculata), whereas the remaining species (O. cernua and O. ramosa) have rbcL pseudogenes. Sequences for rbcL 5'-UTRs from species of Orobanche have few changes in the promoter and ribosome binding sites compared to photosynthetic higher plants. Comparison of rbcL 3'-UTR sequences for Nicotiana, Ipomoea, Cuscuta, and Orobanche reveal that nucleotide sequences from parasitic plants have regions capable of forming stem-loop structures, but 56-69 nt are deleted upstream of the stem-loop in the parasitic plants compared to their photosynthetic relatives. Although rbcL pseudogenes of O. cernua and O. ramosa have many large and small deletions, few indels are shared in common, implying that their common ancestor probably had an intact rbcL reading frame. Intact rbcL reading frames in O. corymbosa and O. fasciculata retain a bias of synonymous over nonsynonymous substitutions and deduced protein sequences are consistent with potentially functional Rubisco large subunit proteins. A conservative model of random substitution processes in pseudogene sequences estimates that the probability is low (P < 0.028) that these sequences would retain an open reading frame by chance. Species of Orobanche have either had recent photosynthetic ancestors, implying multiple independent losses of photosynthesis in this genus, or the rbcL gene may serve an unknown function in some nonphotosynthetic plants.

An atpE-specific promoter within the coding region of the atpB gene in tobacco chloroplast DNA

The atpB and atpE genes encode beta and epsilon subunits, respectively, of chloroplast ATP synthase and are co-transcribed in the plant species so far studied. In tobacco, an atpB gene-specific probe hybridizes to 2.7- and 2.3-kb transcripts. In addition to these, a probe from the atpE coding region hybridizes also to a 1.0-kb transcript. The 5' end of the atpE-specific transcript has been mapped 430/431 nt upstream of the atpE translation initiation site, within the coding region of the atpB gene. In-vitro capping revealed that this transcript results from a primary transcriptional event and is also characterized by -10 and -35 canonical sequences in the 5' region. It has been found to share a common 3' end with the bi-cistronic transcripts that has been mapped within the coding region of the divergently transcribed trnM gene, approximately 236 nt downstream from the atpE termination codon. Interestingly, this transcript accumulates only in leaves and not in proplastid-containing cultured (BY-2) cells, indicating that, unless it is preferentially degraded in BY-2 cells, its expression might be transcriptionally controlled.

The atpB and rbcL promoters in plastid DNAs of a wide dicot range

The plastid atpB-rbcL intergene has been analyzed within a wide range of plants covering the major dicot lineages. New sequences from 13 plant species were determined and aligned with three already-known sequences. The promoters of the rbcL and the atpB genes were localized and analyzed according to published observations in spinach and tobacco. The evolutionary conservation of two atpB promoters, separated by 113-262 nucleotides, is strong support that both are functionally active, and it also allows a discrimination between the previously reported atpB transcripts. Moreover, the radically distinct sequences of the two atpB promoters suggest that they interact with two distinct initiation complexes. The alignment also confirms the much higher conservation of the leader sequence in the rbcL mRNA than in the atpB mRNA among dicots, presuming a function at the posttranscriptional level.

Chloroplast DNA evolution in potato (Solanum tuberosum L.)

A deletion specific to chloroplast (ct) DNA of potato (Solanum tuberosum ssp. tuberosum) was determined by comparative sequence analysis. The deletion was 241 bp in size, and was not flanked by direct repeats. Five small, open reading frames were found in the corresponding regions of ctDNAs from wild potato (S. tuberosum ssp. andigena) and tomato (Lycopersicon esculentum). Comparison of the sequences of 1.35-kbp HaeIII ctDNA fragments from potato, tomato, and tobacco (Nicotiana tabacum) revealed the following: the locations of the 5' ends of both rubisco large subunit (rbcL) and ATPase beta subunit (atpβ) mRNAs were probably the same as those of spinach (Spinacia oleracea); the promoter regions of the two genes were highly conserved among the four species; and the 5' untranslated regions diverged at high rates. A phylogenetic tree for the three potato cultivars, one tomato cultivar, and one tobacco cultivar has been constructed by the maximum parsimony method from DNA sequence data, demonstrating that the rate of nucleotide substitution in potato ctDNA is much slower than that in tomato ctDNA. This fact might be due to the differences in the method of propagation between the two crops.

The divergently transcribed rbcL and atpB genes of tobacco plastid DNA are separated by nineteen base pairs

The in vivo transcripts of the tobacco chloroplast gene for the beta subunit of the ATPase (atpB) were examined. In tobacco, like spinach, the atpB gene encodes multiple transcripts. Six tobacco atpB transcripts are present in vivo, with 5' ends at positions "-90", "-255", "-290", "-490", "-500" and "-610" relative to the translation initiation site. The 5' end of the atpB gene ("-610" position) is 20 base pairs from the 5' end of the rbcL gene, coded for on the complementary strand. The "-255", "-490" and "-610" regions are recognized as promoters in vitro by spinach chloroplast and E. coli RNA polymerases.

Nicotiana chloroplast genes for components of the photosynthetic apparatus

In order to understand more fully chloroplast genetic systems, we have determined the complete nucleotide sequence (155, 844 bp) of tobacco (Nicotiana tabacum var. Bright Yellow 4) chloroplast DNA. It contains two copies of an identical 25,339 bp inverted repeat, which are separated by 86, 684 bp and 18,482 bp single-copy regions. The genes for 4 different rRNAs, 30 different tRNAs, 44 different proteins and 9 other predicted protein-coding genes have been located. Fifteen different genes contain introns.Twenty-two genes for components of the photosynthetic apparatus have so far been identified. Most of the genes (except the gene for the large subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase) code for thylakoid membrane proteins. Twenty of them are located in the large single-copy region and one gene for a 9-kd polypeptide of photosystem I is located in the small single-copy region. The gene for the 32-kd protein of photosystem II as well as the gene for the large subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase have strong promoters and are transcribed monocistronically while the other genes are transcribed polycistronically. We have found that the predicted amino acid sequences of six DNA sequences resemble those of components of the respiratory-chain NADH dehydrogenase from human mitochondria. As these six sequences are highly transcribed in tobacco chloroplasts, they are probably genes for components of a chloroplast NADH dehydrogenase. These observations suggest the existence of a respiratory-chain in the chloroplast of higher plants.

Sequence and over-expression of subunits of adenosine triphosphate synthase in thermophilic bacterium PS3

The primary structures of all the subunits of thermophilic ATP synthase were determined, and its alpha, beta and gamma subunits could be over-expressed in Escherichia coli, because these subunits were stable and reconstitutable. DNA of 7500 base pairs in length was found to contain a cluster of nine genes for subunits of ATP synthase. The order of their reading frames (size in base pairs) was: I(381): a(630): c(216): b(489): delta(537): alpha(1507): gamma(858): beta(1419): epsilon(396), I being a gene for a small hydrophobic, basic protein expressed in vitro. All the termini of TF0F1 subunits were confirmed by peptide sequencing. Large quantities of the overexpressed thermophilic alpha, beta and gamma subunits were prepared from the extract of E. coli, by a few purification steps.

Synthesis and assembly of H+-ATPase complex by isolated "rough" thylakoids

The synthesis and assembly of chloroplast H+-ATPase complex were studied by analyzing the incorporation of [35S]methionine into the constituent subunits with isolated intact chloroplasts and with thylakoid membranes that had been prepared from the chloroplasts so that they would retain ribosomes. The complex was isolated from thylakoids after labeling and identified by immunoprecipitation with an antiserum specific to CF1. The mechanism for the assembly of the complex was demonstrated to be active in the isolated chloroplasts by the following observations: the plastid genome-regulated subunits (alpha, beta, epsilon, I, and III) were labeled by in organello translation and recovered with the complex, and three other subunits (gamma, delta, and II) were labeled when intact chloroplasts were incubated with translation products from polyadenylated RNA. The two largest subunits, alpha and beta, were translated on thylakoid-bound ribosomes when the thylakoid membranes were incubated with soluble factors from Escherichia coli. They were recovered with the H+-ATPase complex, suggesting that they are translated on the bound ribosomes in the chloroplast, and that the isolated membranes retain the ability to assemble a complete complex. Provided that these observations are the result of de novo assembly of the complex, the imported and processed nuclear-coded subunits are presumed to be pooled not in stroma but on the membrane.

Using bacteria to analyze sequences involved in chloroplast gene expression

The expression of higher plant chloroplast genes in prokaryotic cells has been used to examine organelle sequences involved in promoter recognition by RNA polymerase, and protein translocation through membranes. The similarity in sequence structure between Escherichia coli promoters and the maize chloroplast atpB promoter has been investigated using deletion and single base pair substitution mutants. The atpB mutants were mainly isolated by a selection system in E. coli, and then used as templates for the analysis of transcription using chloroplast RNA polymerase. It was found that both the bacterial and chloroplast RNA polymerases behaved in a similar fashion with the wild-type and mutant promoters, indicating that the sequences involved in promoter recognition share a considerable degree of homology. Signal peptide recognition of pea cytochrome f has also been examined in E. coli. This signal peptide, which is probably responsible for insertion of the protein into the thylakoid membrane, is efficiently recognized in E. coli leading to the inner membrane insertion of petA::lacZ fusion proteins. This process requires the bacterial SecA protein and points to a general similarity in the mechanisms of protein translocation within chloroplasts and bacteria.

Six chloroplast genes (ndhA-F) homologous to human mitochondrial genes encoding components of the respiratory chain NADH dehydrogenase are actively expressed: determination of the splice sites in ndhA and ndhB pre-mRNAs

Sequences (ndhA-F) homologous to human mitochondrial genes for components of the respiratory chain NADH dehydrogenase have been found in the chloroplast DNA of tobacco. The ndhA, D, E and F sequences corresponding to the mitochondrial URF1, 4, 4L and 5 are located in the small single copy region, the ndhB sequence corresponding to URF2 in the inverted repeat and the ndhC sequence corresponding to URF3 in the large single copy region of the chloroplast DNA. Northern blot hybridization revealed that all six ndh sequences are actively expressed in the chloroplasts. The ndhA and ndhB sequences contain single introns and the splice sites of their pre-mRNAs were determined by reverse transcription analysis. These findings suggest that potential components of an NADH dehydrogenase are synthesized in the chloroplasts.

Transcriptional and post-transcriptional regulation of chloroplast gene expression in Petunia hybrida

To study the control of differential gene expression during plastid biogenesis in Petunia hybrida, we have investigated the in vivo translation and transcription of the rbc L gene, coding for the large subunit of ribulose bisphosphate carboxylase (LSU), and the psa A gene, coding for P700 chlorophyll-a apoprotein (AP700). Differential expression of these plastid-encoded genes was studied in two developmentally different plastid systems, proplastid-like organelles from the green cell suspension AK2401 and mature chloroplasts from green leaves. In vivo translation of rbc L and psa A transcripts was analysed using specific antibodies. Specific transcript levels were analysed using internal fragments of the rbc L and psa A genes. A standardization procedure was used so that a direct correlation could be made between the amount of products and gene copy number. In Petunia hybrida the amount of LSU polypeptides present in both plastid types does not correspond to the amount of specific mRNA for the gene. Although the rbc L transcripts are present in both plastid types, the LSU protein is only present in green leaf plastids and not in cell culture plastids. In vitro translation of isolated rbc L transcripts give similar results, thereby suggesting that differences in the primary structure of the transcripts are responsible for the observed discrepancy. In contrast to this, the amount of AP700 polypeptides does correspond to the amount of the psa A transcripts. Therefore, our results indicate that the expression of chloroplast genes during plastid biogenesis takes place on at least two different levels: expression of the rbc L gene is regulated post-transcriptionally while expression of the psa A gene is regulated at the transcriptional level.

In vitro synthesis and processing of a maize chloroplast transcript encoded by the ribulose 1,5-bisphosphate carboxylase large subunit gene

The large subunit gene (rbcL) of ribulose 1,5-bisphosphate carboxylase was transcribed in vitro by using maize and pea chloroplast extracts and a cloned plastid DNA template containing 172 base pairs (bp) of the maize rbcL protein-coding region and 791 bp of upstream sequences. Three major in vitro RNA species were synthesized which correspond to in vivo maize rbcL RNAs with 5' termini positioned 300, 100 to 105, and 63 nucleotides upstream of the protein-coding region. A deletion of 109 bp, including the "-300" 5' end (the 5' end at position -300), depressed all rbcL transcription in vitro. A plasmid DNA containing this 109-bp fragment was sufficient to direct correct transcription initiation in vitro. A cloned template, containing 191 bp of plastid DNA which includes the -105 and -63 rbcL termini, did not support transcription in vitro. Exogenously added -300 RNA could be converted to the -63 transcript by maize chloroplast extract. These results established that the -300 RNA is the primary maize rbcL transcript, the -63 RNA is a processed form of the -300 transcript, and synthesis of the -105 RNA is dependent on the -300 region. The promoter for the maize rbcL gene is located within the 109 bp flanking the -300 site. Mutagenesis of the 109-bp chloroplast sequence 11 bp upstream of the -300 transcription initiation site reduced rbcL promoter activity in vitro.

The complete nucleotide sequence of the tobacco chloroplast genome: its gene organization and expression

The complete nucleotide sequence (155 844 bp) of tobacco (Nicotiana tabacum var. Bright Yellow 4) chloroplast DNA has been determined. It contains two copies of an identical 25 339 bp inverted repeat, which are separated by a 86 684 bp and a 18 482 bp single-copy region. The genes for 4 different rRNAs, 30 different tRNAs, 39 different proteins and 11 other predicted protein coding genes have been located. Among them, 15 genes contain introns. Blot hybridization revealed that all rRNA and tRNA genes and 27 protein genes so far analysed are transcribed in the chloroplast and that primary transcripts of the split genes hitherto examined are spliced. Five sequences coding for proteins homologous to components of the respiratory-chain NADH dehydrogenase from human mitochondria have been found. The 30 tRNAs predicted from their genes are sufficient to read all codons if the ;two out of three' and ;U:N wobble' mechanisms operate in the chloroplast. Two sequences which autonomously replicate in yeast have also been mapped. The sequence and expression analyses indicate both prokaryotic and eukaryotic features of the chloroplast genes.

Structural features of the murine dihydrofolate reductase transcription termination region: identification of a conserved DNA sequence element

Structural features of the transcription termination region for the mouse dihydrofolate reductase gene have been determined and compared with those of several other known termination regions for protein coding genes. A common feature identified among these termination regions was the presence of a 20 bp consensus DNA sequence element (ATCAGAATATAGGAAAGTAGCAAT). The results imply that the 20 bp consensus DNA sequence element is important for signaling RNA polymerase II transcription termination at least in the several vertebrate species investigated. Furthermore, the results suggest that for the dhfr gene and possibly for other genes in mice as well, the potential termination consensus sequence can exist as part of a long interspersed repetitive DNA element.

Complete nucleotide sequence and mRNA-mapping of the large subunit gene of ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) from Chlamydomonas moewusii

Nucleotide (nt) sequence of the large subunit (LS) gene of ribulose-1,5-bisphosphate carboxylase/oxygenase from the green alga, Chlamydomonas moewusii, and mapping of transcription ends was achieved by two new strategies. The deduced LS sequence of 475 amino acid residues was compared with similar genes from six other species; cyanobacteria, land plants and a related alga (C. reinhardtii). The most conserved regions are the three ribulose bisphosphate binding sites and the CO2 activator site. The nt sequence conservation outside the coding region is limited to only three segments within the 5'-flanking region: a region of tandem repeats, TATAA box and ribosome-binding site. Termination point of transcription is an 'A' residue 3' to the first of two 18-nt inverted repeats, which has the potential to form a stem-loop hairpin structure. The possible role of these potential regulatory features for transcription and translation, and similar structures in other LS genes is presented.

The sequence of the chloroplast atpB gene and its flanking regions in Chlamydomonas reinhardtii

The chloroplast (cp)-encoded CF1 ATPase beta-subunit gene (atpB) of Chlamydomonas reinhardtii and its flanking regions have been sequenced. The derived amino acid (aa) sequence is highly homologous to that of the beta-subunit gene in Escherichia coli, bovine heart mitochondria, and higher plant cp. In contrast to all other cp genomes, the CF1 epsilon subunit gene (atpE) does not lie at the 3' end of the atpB gene but maps to a position 92 kb away in the other single-copy region. Northern blots confirm that the beta subunit is not encoded as part of a dicistronic message as it is in higher plants. The region just upstream from the atpB gene in C. reinhardtii contains two small open reading frames (ORFs) and not the gene for the large subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase as is found in cp genomes of higher plants. No transcripts for either ORF were detected, but the codon usage in these ORFs as well as in the atpB gene follows the unique pattern of codon usage previously seen in other cp genes in C. reinhardtii.

In vitro synthesis and processing of a maize chloroplast transcript encoded by the ribulose 1,5-bisphosphate carboxylase large subunit gene

The large subunit gene (rbcL) of ribulose 1,5-bisphosphate carboxylase was transcribed in vitro by using maize and pea chloroplast extracts and a cloned plastid DNA template containing 172 base pairs (bp) of the maize rbcL protein-coding region and 791 bp of upstream sequences. Three major in vitro RNA species were synthesized which correspond to in vivo maize rbcL RNAs with 5' termini positioned 300, 100 to 105, and 63 nucleotides upstream of the protein-coding region. A deletion of 109 bp, including the "-300" 5' end (the 5' end at position -300), depressed all rbcL transcription in vitro. A plasmid DNA containing this 109-bp fragment was sufficient to direct correct transcription initiation in vitro. A cloned template, containing 191 bp of plastid DNA which includes the -105 and -63 rbcL termini, did not support transcription in vitro. Exogenously added -300 RNA could be converted to the -63 transcript by maize chloroplast extract. These results established that the -300 RNA is the primary maize rbcL transcript, the -63 RNA is a processed form of the -300 transcript, and synthesis of the -105 RNA is dependent on the -300 region. The promoter for the maize rbcL gene is located within the 109 bp flanking the -300 site. Mutagenesis of the 109-bp chloroplast sequence 11 bp upstream of the -300 transcription initiation site reduced rbcL promoter activity in vitro.

Identification and mutational analysis of the promoter for a spinach chloroplast transfer RNA gene

A transcription extract from purified spinach chloroplast was used to test chloroplast DNA sequences for their function as promoter elements. Chloroplast tRNA genes are correctly transcribed in the extract by a soluble RNA polymerase, and precursor molecules are processed into mature tRNAs. Transcription of the spinach chloroplast tRNA2Met gene (trnM2) in vitro requires 5' upstream DNA sequences. Deletion of 5' DNA sequences with exonuclease Bal31 was used to establish the 5' boundary of the promoter region. This boundary is part of a DNA sequence with partial homology to the prokaryotic -35 region. Seventeen base pairs downstream from this sequence a DNA sequence occurs which is homologous to the prokaryotic -10 region. We used synthetic oligonucleotides fused to trnM2 5' deletion mutants to create insertions, deletions and base substitutions in these regions. Internal deletion mutants demonstrated that the -10 promoter element is also required for transcription in vitro. The arrangement of DNA sequences recognised by the chloroplast RNA polymerase resembles the prokaryotic promoter organization.

Photosynthetic ATPases: purification, properties, subunit isolation and function

Photosynthetic coupling factor ATPases (F1-ATPases) generally censist of five subunits named α, β, γ, δ and ε in order of decreasing apparent molecular weight. The isolated enzyme has a molecular weight of between 390,000 to 400,000, with the five subunits probably occurring in a 3:3:1:1:1 ratio. Some photosynthetic F1 ATPases are inactive as isolated and require treatment with protease, heat or detergent in order to elicit ATPase activity. This activity is sensitive to inhibition by free divalent cations and appears to be more specific for Ca(2+) vs. Mg(2+) as the metal ion substrate chelate. This preference for Ca(2+) can be explained by the higher inhibition constant for inhibition of ATPase activity by free Ca(2+). Methods for the assay of a Mg-dependent ATPase activity have recently been described. These depend on the presence of organic solvents or detergents in the reaction mixture for assay. The molecular mechanism behind the expression of either the Ca- or Mg-ATPase activities is unknown. F1-ATPases function to couple proton efflux from thylakoid membranes or chromatophores to ATP synthesis. The isolated enzyme may thus also be assayed for the reconstitution of 'coupling activity' to membranes depleted of coupling factor 1.The functions of the five subunits in the complex have been deduced from the results of chemical modification and reconstitution studies. The δ subunit is required for the functional binding of the F1 to the F0. The active site is probably contained in the β (and α) subunit(s). The proposed functions for the γ and ε subunits are, however, still matters of controversy. Coupling factors from a wide variety of species including bacteria, algae, C3 and C4 plants, appear to be immunologically related. The β subunits are the most strongly related, although the α and γ subunits also show significant immunological cross-reactivity. DNA sequence analyses of the genes for the β subunit of CF1 have indicated that the primary sequence of this polypeptide is highly conserved. The genes for the polypeptides of CF1 appear to be located in two cellular compartments. The α, β and ε subunits are coded for on chloroplast DNA, whereas the γ and δ subunits are probably nuclear encoded. Experiments involving protein synthesis by isolated chloroplasts or protein synthesis in the presence of inhibitors specific for one or the other set of ribosomes in the cell suggest the existence of pools of unassembled CF1 subunits. These pools, if they do exist in vivo, probably make up no greater than 1% of the total CF1 content of the cell.

Characterization of the mRNA transcripts of the maize, ribulose-1,5-bisphosphate carboxylase, large subunit gene

The analysis of RNA isolated from maize leaves indicates that there are two mRNA transcripts which are homologous to the chloroplast encoded gene for the large subunit of ribulose-1,5-bisphosphate carboxylase (rbcL). The 5' end of the smaller transcript, 1.62 Kb in length, begins at a position which is 60 nucleotides upstream from the coding sequence of the gene, corresponding to the position mapped by earlier workers. The larger transcript, 1.86 Kb in length, has not been previously described and originates from a site on the gene which is 302 nucleotides upstream from the coding sequence. The increased size of the largerbcL mRNA transcript from maize, as compared to the transcripts from spinach and tobacco, results from the presence of a 130 nucleotide insert between the two maizerbcL gene mRNA start sites. The DNA sequence adjacent to the start site for the large mRNA transcript is shown to have greater than 90% homology to the DNA sequences adjacent to the mRNA start sites for the spinach and tobaccorbcL gene. Discounting the presence of the insert in the maizerbcL gene, the nucleotides upstream from the coding sequence in the maize, spinach and tobaccorbcL genes, all share approximately the same amount of homology to each other. This homology, along with other evidence, suggests that the large mRNA species are the primary transcripts and that the smaller RNA species are the result of post-transcriptional processing. The finding that spinach also contains two different mRNA transcripts for therbcL gene is consistent with this model.

Multiple transcripts for higher plantrbcL andatpB genes and localization of the transcription initiation site of therbcL gene

We have compared therbcL andatpB transcription units from spinach, maize, and pea. In most cases multiple transcripts were found for a given chloroplast gene. The 5' termini of these transcripts were determined by S1 nuclease protection and primer extension analyses. TherbcL transcripts have 5' termini 178-179 and 64 nucleotides (spinach), 300 and 59-63 nucleotides (maize), and 178 and 65 nucleotides (pea) upstream from their respective protein coding regions. TheatpB transcripts have 5' termini (453-454, 272-273, 179, and 99 nucleotides (spinach), 298-302 nucleotides (maize), and 351-355 nucleotides (pea) upstream from their respective protein coding regions. The intergenic distance between therbcL andatpB genes is relatively constant (152 to 157 base pairs) among the three chloroplast genomes. In spinach, maize, and pea, the 80 base pairs surrounding the 5' end of therbcL gene (±40 base pairs) have 85% sequence homology. Similarly, the 60 base pairs preceding theatpB gene have 48% sequence homology. Both genes have '-10' and '-35' regions that resemble the prokaryotic consensus promoter sequence. The larger, but not smaller,rbcL transcripts from spinach and pea can be labeled with alpha-(32)P-GTP by guanylyltransferase. These data suggest that DNA sequences 178-179 (spinach), 300 (maize), and 178 (pea) base pairs before therbcL protein coding regions represent sites of transcription initiation. The sequences 59-65 base pairs before therbcL protein coding regions may correspond to sites of RNA cleavage.

Single gene for the large subunit of ribulosebisphosphate carboxylase in maize yields two differentially regulated mRNAs

A second mRNA coding for the large subunit of ribulose-1,5-bisphosphate carboxylase [3-phospho-D-glycerate carboxylase (dimerizing), EC 4.1.1.39] has been found in the plastids of maize leaves. The 5' terminus of this mRNA was shown by S1 nuclease analysis to be 238 nucleotides upstream of the previously described large subunit mRNA [McIntosh, L., Poulsen, C. & Bogorad, L. (1980) Nature (London) 288, 556-560]. The same two mRNAs were produced in a homologous in vitro transcription system using cloned plastid DNA as a template. The ratio of the two mRNAs changes during light-induced plastid development and can be altered in the in vitro system by manipulation of transcription conditions.

Nicotiana chloroplast genome : 8. Localization of genes for subunits of ATP synthase, the cytochrome b-f complex and the 32 kD protein

Using the existing restriction map and probes from wheat and pea ct-DNA, seven protein genes have been localized in the chloroplast genome of N. tabacum. On the clock-like map, the location of each gene is indicated by its time zone: the 15.2 kD polypeptide of the cytochrome b/f complex at 3∶15, cytochrome f at 4∶30, LS of RuBPCase at 4∶50, both β and ɛ subunits of ATP synthase at or near 5∶00, proton-translocating subunit of ATP synthase at 8∶20, α subunit of ATP synthase at 8∶40 and the 32 kD protein at 9∶30. The genome organization of Nicotiana chloroplast DNA is similar to spinach.

Molecular and genetic analysis of the chloroplast ATPase of chlamydomonas

We have carried out a molecular and genetic analysis of the chloroplast ATPase in Chlamydomonas reinhardtii. Recombination and complementation studies on 16 independently isolated chloroplast mutations affecting this complex demonstrated that they represent alleles in five distinct chloroplast genes. One of these five, the ac-u-c locus, has been positioned on the physical map of the chloroplast DNA by deletion mutations. The use of cloned spinach chloroplast ATPase genes in heterologous hybridizations to Chlamydomonas chloroplast DNA has allowed us to localize three or possibly four of the ATPase genes on the physical map. The beta and probably the epsilon subunit genes of Chlamydomonas CF1 lie within the same region of chloroplast DNA as the ac-u-c locus, while the alpha and proteolipid subunit genes appear to map adjacent to one another approximately 20 kbp away. Unlike the arrangement in higher plants, these two pairs of genes are separated from each other by an inverted repeat.

Nucleotide sequence of the gene for the P680 chlorophyll alpha apoprotein of the photosystem II reaction center from spinach

The DNA sequence of 2210 nucleotides including the gene for the "51 kd" chlorophyll alpha-conjugated thylakoid membrane protein associated with the photosystem II reaction center of spinach has been determined. This protein is functionally identical with the P680 chlorophyll alpha apoprotein that catalyses the primary light-induced photochemical processes of photosystem II (Camm, E.L. and Green, B.R. (1983) Biochim. Biophys. Acta 724 291-293). The only large open reading frame in the sequence consists of 508 triplets encoding a protein of molecular mass of 56,246 kd. The deduced amino acid sequence shows clustering of hydrophobic residues into seven core regions which probably traverse the membrane, and a large hydrophilic domain of about 200 amino acids interspersed between span VI and VII. Potential transcription promotor and terminator signals flanking the structural gene show prokaryotic-like features. Seven discrete RNA species ranging in size from 2.0 to over 5.0 kilobases display complementarity to apoprotein coding sequences implying that the region can be polycistronically transcribed. The primary transcript includes information for at least two further genes coding for subunits of the cytochrome b/f complex.

Clone bank of Nicotiana tabacum chloroplast DNA: mapping of the alpha, beta and epsilon subunits of the ATPase coupling factor, the large subunit of ribulosebisphosphate carboxylase, and the 32-kDal membrane protein

All of the PstI restriction fragments of the chloroplast DNA of Nicotiana tabacum have been cloned in the plasmid vector pBR322. The cloned fragment sizes range from 0.8 to 26 kb, are stable, and can be amplified by chloramphenicol with varying efficiencies. Using these clones we have detailed a PstI physical map of the tobacco chloroplast genome. Selected clones of SalI, BamHI and PstI fragments were used to localize the map positions of the alpha, beta, and epsilon subunits of the chloroplast ATPase coupling factor, the large subunit of ribulosediphosphate carboxylase and the 32-kDal membrane protein. The gene products of these clones were characterized by RNA transcript sizing, immunoprecipitation of maxicell-directed protein synthesis, and hybrid-arrested translation.

Overlap and cotranscription of the genes for the beta and epsilon subunits of tobacco chloroplast ATPase

The nucleotide sequences of the genes for the beta and epsilon subunits of tobacco chloroplast ATPase have been determined. The coding regions for the beta and epsilon subunits contain 1494 bp (498 codons) and 399 bp (133 codons), respectively. The 3' end of the beta-coding region overlaps by one nucleotide with the 5' end of the epsilon-coding region. The overlapping termination and initiation codons are ATGA. The beta and epsilon genes are cotranscribed as a 2.7-kb polycistronic mRNA. The amount of the beta and epsilon mRNA in the chloroplast is about one-twentieth that of the LS mRNA.

Synthesis of the large subunit of ribulose-1,5-bisphosphate carboxylase in anin vitro partially definedE. coli system

Thein vitro DNA- or RNA-directed synthesis of the large subunit (LS) of spinach chloroplast ribulose-1,5-biphosphate carboxylase (RuP2C) has been examined in a highly definedE. coli transcription-translation system. Spinach chloroplast DNA, RNA and recombinant plasmids containing the spinach chloroplast LS gene (rbcL) have been used as templates in thein vitro system and a quantitative assay has been developed to measure LS formation. Thein vitro formed product contains formylmethionine at the N-terminal position and sediments primarily as a monomer. There is no detectable enzymatic activity associated with thein vitro product. To determine where theE. coli RNA polymerase used in these systems initiates, we have examined the transcripts produced by this enzymein vitro. Measurements of run-off transcripts indicate thatE. coli RNA polymerase initiates at the same position on the gene as is seenin vivo. In addition, the complete nucleotide sequence of therbcL gene including previously unsequenced 3' and 5' flanking regions has been determined. The sequence agrees, except at two nucleotide positions, with previously published sequencing data for this gene (Zurawski, G, Perrot, B, Bottomley, W, Whitfeld, PR, 1981. Nucleic Acids Res. 9:3251-3270).

Nucleotide sequence of tobacco chloroplast gene for the alpha subunit of proton-translocating ATPase

The tobacco chloroplast gene for the alpha subunit of proton-translocating ATPase has been cloned and sequenced. The coding region contains 1521 bp (507 codons). The nucleotide sequence and the deduced amino acid sequence show 55% and 54% homologies with those of the E. coli alpha subunit, respectively. The deduced amino acid composition is quite similar to that estimated for the spinach alpha subunit.