Genes and transcripts for the ATP synthase CF0 subunits I and II from spinach thylakoid membranes

Unprecedented variation pattern of plastid genomes and the potential role in adaptive evolution in Poales

BACKGROUND

The plastid is the photosynthetic organelle in plant cell, and the plastid genomes (plastomes) are generally conserved in evolution. As one of the most economically and ecologically important order of angiosperms, Poales was previously documented to exhibit great plastomic variation as an order of photoautotrophic plants.

RESULTS

We acquired 93 plastomes, representing all the 16 families and 5 major clades of Poales to reveal the extent of their variation and evolutionary pattern. Extensive variation including the largest one in monocots with 225,293 bp in size, heterogeneous GC content, and a wide variety of gene duplication and loss were revealed. Moreover, rare occurrences of three inverted repeat (IR) copies in angiosperms and one IR loss were observed, accompanied by short IR (sIR) and small direct repeat (DR). Widespread structural heteroplasmy, diversified inversions, and unusual genomic rearrangements all appeared in Poales, occasionally within a single species. Extensive repeats in the plastomes were found to be positively correlated with the observed inversions and rearrangements. The variation all showed a "small-large-moderate" trend along the evolution of Poales, as well as for the sequence substitution rate. Finally, we found some positively selected genes, mainly in C4 lineages, while the closely related lineages of those experiencing gene loss tended to have undergone more relaxed purifying selection.

CONCLUSIONS

The variation of plastomes in Poales may be related to its successful diversification into diverse habitats and multiple photosynthetic pathway transitions. Our order-scale analyses revealed unusual evolutionary scenarios for plastomes in the photoautotrophic order of Poales and provided new insights into the plastome evolution in angiosperms as a whole.

Chloroplast genome analysis of three Acanthus species reveal the adaptation of mangrove to intertidal habitats

Acanthus is a distinctive genus that covers three species with different ecological niches including Acanthus mollis (arid terrestrial), Acanthus leucostachyus (damp forest) and Acanthus ilicifolius (coastal intertidal). It is an intriguing question how these species evolved from terrestrial to coastal intertidal. In the present study, we assembled chloroplast genomes of A. ilicifolius, A. leucostachyus and A. mollis, which exhibited typical quadripartite structures. The sizes were 150,758, 154,686 and 150,339 bp that comprised a large single copy (LSC, 82,963, 86,461 and 82,612 bp), a small single copy (SSC, 17,191, 17,511 and 17,019 bp), and a pair of inverted repeats (IRs, 25,302, 25,357 and 25,354 bp), respectively. Gene annotation revealed that A. ilicifolius, A. leucostachyus and A. mollis contained 113, 112 and 108 unique genes, each of which contained 79, 79 and 74 protein-coding genes, 30, 29 and 30 tRNAs, and 4 rRNA genes, respectively. Differential gene analysis revealed plenty of ndhs gene deletions in the terrestrial plant A. mollis. Nucleotide diversity analysis showed that the psbK, ycf1, ndhG, and rpl22 have the highest nucleotide variability. Compared to A. leucostachyus and A. mollis, seven genes in A. ilicifolius underwent positive selection. Among them, the atpF gene showed a strong positive selection throughout terrestrial to marine evolution and was important for adaptation to coastal intertidal habitats. Phylogenetic analysis indicated that A. ilicifolius has a closer genetic relationship with A. leucostachyus than A. mollis which further confirmed the evolutionary direction of Acanthus going from terrestrial to coastal intertidal zones.

Chloroplast genomic comparison provides insights into the evolution of seagrasses

BACKGROUND

Seagrasses are a polyphyletic group of monocotyledonous angiosperms that have evolved to live entirely submerged in marine waters. Thus, these species are ideal for studying plant adaptation to marine environments. Herein, we sequenced the chloroplast (cp) genomes of two seagrass species (Zostera muelleri and Halophila ovalis) and performed a comparative analysis of them with 10 previously published seagrasses, resulting in various novel findings.

RESULTS

The cp genomes of the seagrasses ranged in size from 143,877 bp (Zostera marina) to 178,261 bp (Thalassia hemprichii), and also varied in size among different families in the following order: Hydrocharitaceae > Cymodoceaceae > Ruppiaceae > Zosteraceae. The length differences between families were mainly related to the expansion and contraction of the IR region. In addition, we screened out 2,751 simple sequence repeats and 1,757 long repeat sequence types in the cp genome sequences of the 12 seagrass species, ultimately finding seven hot spots in coding regions. Interestingly, we found nine genes with positive selection sites, including two ATP subunit genes (atpA and atpF), three ribosome subunit genes (rps4, rps7, and rpl20), one photosystem subunit gene (psbH), and the ycf2, accD, and rbcL genes. These gene regions may have played critical roles in the adaptation of seagrasses to diverse environments. In addition, phylogenetic analysis strongly supported the division of the 12 seagrass species into four previously recognized major clades. Finally, the divergence time of the seagrasses inferred from the cp genome sequences was generally consistent with previous studies.

CONCLUSIONS

In this study, we compared chloroplast genomes from 12 seagrass species, covering the main phylogenetic clades. Our findings will provide valuable genetic data for research into the taxonomy, phylogeny, and species evolution of seagrasses.

Comparative Chloroplast Genomes of Zosteraceae Species Provide Adaptive Evolution Insights Into Seagrass

Seagrasses are marine flowering plants found in tropical and sub-tropical areas that live in coastal regions between the sea and land. All seagrass species evolved from terrestrial monocotyledons, providing the opportunity to study plant adaptation to sea environments. Here, we sequenced the chloroplast genomes (cpGenomes) of three Zostera species, then analyzed and compared their cpGenome structures and sequence variations. We also performed a phylogenetic analysis using published seagrass chloroplasts and calculated the selection pressure of 17 species within seagrasses and nine terrestrial monocotyledons, as well as estimated the number of shared genes of eight seagrasses. The cpGenomes of Zosteraceae species ranged in size from 143,877 bp (Zostera marina) to 152,726 bp (Phyllospadix iwatensis), which were conserved and displayed similar structures and gene orders. Additionally, we found 17 variable hotspot regions as candidate DNA barcodes for Zosteraceae species, which will be helpful for studying the phylogenetic relationships and interspecies differences between seagrass species. Interestingly, nine genes had positive selection sites, including two ATP subunit genes (atpA and atpF), two ribosome subunit genes (rps4 and rpl20), two DNA-dependent RNA polymerase genes (rpoC1 and rpoC2), as well as accD, clpP, and ycf2. These gene regions may have played key roles in the seagrass adaptation to diverse environments. The Branch model analysis showed that seagrasses had a higher rate of evolution than terrestrial monocotyledons, suggesting that seagrasses experienced greater environmental pressure. Moreover, a branch-site model identified positively selected sites (PSSs) in ccsA, suggesting their involvement in the adaptation to sea environments. These findings are valuable for further investigations on Zosteraceae cpGenomes and will serve as an excellent resource for future studies on seagrass adaptation to sea environments.

Phylogenetic relationships and molecular evolution of woody forest tree family Aceraceae based on plastid phylogenomics and nuclear gene variations

The forest tree family Aceraceae is widespread in the northern hemisphere and it has ecological and economic importance. However, the phylogenetic relationships and classifications within the family are still controversial due to transitional intraspecific morphological characteristics and introgression hybridization among species. In this study, we determined the evolutionary relationships and molecular evolution of Aceraceae based on plastid phylogenomics and two nuclear gene variations. Phylogenetic analysis based on the plastid genomes suggested that Aceraceae species can be divided into two larger sub-clades corresponding to the two genera Acer and Dipteronia. Conjoint analysis of the plastid and nuclear gene sequences supported the classification with two genera in the family. Molecular dating showed that the two genera diverged 60.2 million years ago, which is generally consistently with previously reported results. Divergence hotspots and positively selected genes identified in the plastid genomes could be useful genetic resources in Aceraceae.

Comparative Chloroplast Genomics of Dipsacales Species: Insights Into Sequence Variation, Adaptive Evolution, and Phylogenetic Relationships

In general, the chloroplast genomes of angiosperms are considered to be highly conserved and affected little by adaptive evolution. In this study, we tested this hypothesis based on sequence differentiation and adaptive variation in the plastid genomes in the order Dipsacales. We sequenced the plastid genomes of one Adoxaceae species and six Caprifoliaceae species, and together with seven previously released Dipsacales chloroplasts, we determined the sequence variations, evolutionary divergence of the plastid genomes, and phylogeny of Dipsacales species. The chloroplast genomes of Adoxaceae species ranged in size from 157,074 bp (Sinadoxa corydalifolia) to 158,305 bp (Sambucus williamsii), and the plastid genomes of Caprifoliaceae varied from 154,732 bp (Lonicera fragrantissima var. lancifolia) to 156,874 bp (Weigela florida). The differences in the number of genes in Caprifoliaceae and Adoxaceae species were largely due to the expansion and contraction of inverted repeat regions. In addition, we found that the number of dispersed repeats (Adoxaceae = 37; Caprifoliaceae = 384) was much higher than that of tandem repeats (Adoxaceae = 34; Caprifoliaceae = 291) in Dipsacales species. Interestingly, we determined 19 genes with positive selection sites, including three genes encoding ATP protein subunits (atpA, atpB, and atpI), four genes for ribosome protein small subunits (rps3, rps7, rps14, and rps15), four genes for photosystem protein subunits (psaA, psaJ, psbC, and pabK), two genes for ribosome protein large subunits (rpl22 and rpl32), and the clpP, infA, matK, rbcL, ycf1, and ycf2 genes. These gene regions may have played key roles in the adaptation of Dipsacales to diverse environments. In addition, phylogenetic analysis based on the plastid genomes strongly supported the division of 14 Dipsacales species into two previously recognized sections. The diversification of Adoxaceae and Caprifoliaceae was dated to the late Cretaceous and Tertiary periods. The availability of these chloroplast genomes provides useful genetic information for studying taxonomy, phylogeny, and species evolution in Dipsacales.

Purification, characterization and crystallization of the F-ATPase from Paracoccus denitrificans

The structures of F-ATPases have been determined predominantly with mitochondrial enzymes, but hitherto no F-ATPase has been crystallized intact. A high-resolution model of the bovine enzyme built up from separate sub-structures determined by X-ray crystallography contains about 85% of the entire complex, but it lacks a crucial region that provides a transmembrane proton pathway involved in the generation of the rotary mechanism that drives the synthesis of ATP. Here the isolation, characterization and crystallization of an integral F-ATPase complex from the α-proteobacterium Paracoccus denitrificans are described. Unlike many eubacterial F-ATPases, which can both synthesize and hydrolyse ATP, the P. denitrificans enzyme can only carry out the synthetic reaction. The mechanism of inhibition of its ATP hydrolytic activity involves a ζ inhibitor protein, which binds to the catalytic F₁-domain of the enzyme. The complex that has been crystallized, and the crystals themselves, contain the nine core proteins of the complete F-ATPase complex plus the ζ inhibitor protein. The formation of crystals depends upon the presence of bound bacterial cardiolipin and phospholipid molecules; when they were removed, the complex failed to crystallize. The experiments open the way to an atomic structure of an F-ATPase complex.

Assembly of F1F0-ATP synthases

F1F0-ATP synthases are multimeric protein complexes and common prerequisites for their correct assembly are (i) provision of subunits in appropriate relative amounts, (ii) coordination of membrane insertion and (iii) avoidance of assembly intermediates that uncouple the proton gradient or wastefully hydrolyse ATP. Accessory factors facilitate these goals and assembly occurs in a modular fashion. Subcomplexes common to bacteria and mitochondria, but in part still elusive in chloroplasts, include a soluble F1 intermediate, a membrane-intrinsic, oligomeric c-ring, and a membrane-embedded subcomplex composed of stator subunits and subunit a. The final assembly step is thought to involve association of the preformed F1-c10-14 with the ab2 module (or the ab8-stator module in mitochondria)--mediated by binding of subunit δ in bacteria or OSCP in mitochondria, respectively. Despite the common evolutionary origin of F1F0-ATP synthases, the set of auxiliary factors required for their assembly in bacteria, mitochondria and chloroplasts shows clear signs of evolutionary divergence. This article is part of a Special Issue entitled: Chloroplast Biogenesis.

Comparative cross-linking and mass spectrometry of an intact F-type ATPase suggest a role for phosphorylation

F-type ATPases are highly conserved enzymes used primarily for the synthesis of ATP. Here we apply mass spectrometry to the F1FO-ATPase, isolated from spinach chloroplasts, and uncover multiple modifications in soluble and membrane subunits. Mass spectra of the intact ATPase define a stable lipid 'plug' in the FO complex and reveal the stoichiometry of nucleotide binding in the F1 head. Comparing complexes formed in solution from an untreated ATPase with one incubated with a phosphatase reveals that the dephosphorylated enzyme has reduced nucleotide occupancy and decreased stability. By contrasting chemical cross-linking of untreated and dephosphorylated forms we show that cross-links are retained between the head and base, but are significantly reduced in the head, stators and stalk. Conformational changes at the catalytic interface, evidenced by changes in cross-linking, provide a rationale for reduced nucleotide occupancy and highlight a role for phosphorylation in regulating nucleotide binding and stability of the chloroplast ATPase.

Effects of selective inactivation of individual genes for low-molecular-mass subunits on the assembly of photosystem II, as revealed by chloroplast transformation: the psbEFLJoperon in Nicotiana tabacum

Photosystem (PSII) is a supramolecular polypeptide complex found in oxygenic photosynthetic membranes, which is capable of extracting electrons from water for the reduction of plastoquinone. An intriguing feature of this assembly is the fact that it includes more than a dozen low-mass polypeptides of generally unknown function. Using a transplastomic approach, we have individually disrupted the genes of the psbEFLJoperon in Nicotiana tabacum, which encode four such polypeptides, without impairing expression of downstream loci of the operon. All four mutants exhibited distinct phenotypes; none of them was capable of photoautotrophic growth. All mutants bleached rapidly in the light. Disruption of psbEand psbF, which code for the alpha and beta apoproteins of cytochrome b(559), abolished PSII activity, as expected; Delta psbL and Delta psbJ plants displayed residual PSII activity in young leaves. Controlled partial solubilisation of thylakoid membranes uncovered surprisingly severe impairment of PSII structure, with subunit and assembly patterns varying depending on the mutant considered. In the Delta psbL mutant PSII was assembled primarily in a monomeric form, the homodimeric form was preponderant in Delta psbJ, and, unlike the case in Delta psbZ, the thylakoids of both mutants released some PSII supercomplexes. On the other hand, Photosystem I (PSI), the cytochrome b(6)f complex, ATP synthase, LHCII, and CP24/CP26/CP29 antennae were present in near wild-type levels. The data are discussed in terms of their implications for structural, biogenetic and functional aspects of PSII.

Identification of four genes of the Brucella melitensis ATP synthase operon F0 sector: relationship with the Rhodospirillaceae family

We have determined the nucleotide sequence of a cloned DNA fragment from the human and animal pathogen Brucella melitensis. Four genes were identified from a 4069 bp fragment, corresponding to the B. melitensis a, c, b', and b subunits of the ATP synthase F0 sector operon. A duplicated and divergent copy of the b-subunit gene was observed. This feature has been found only in photosynthetic bacteria and chloroplasts. In addition, the gene cluster was separated from the F1 sector, a characteristic described only for the Rhodospirillaceae family.

Specific heterodimer formation by the cytoplasmic domains of the b and b' subunits of cyanobacterial ATP synthase

The soluble domains of the b and b' subunits of the ATP synthase of the cyanobacterium Synechocystis PCC 6803 were expressed with His tags attached to their N-termini. Following purification, the polypeptides were characterized by chemical cross-linking, analytical ultracentrifugation, and circular dichroism spectroscopy. Treatment of a mixture of the soluble b and b' domains with a chemical cross-linking agent led to substantial formation of cross-linked dimers, whereas similar treatment of either domain by itself resulted in only trace formation of cross-linked species. The molecular weights of the domains of b and b' in solution at 20 degrees C, measured by sedimentation equilibrium, were 17 800+/-700 and 16 300+/-400, respectively, compared to calculated polypeptide molecular weights of 16 635 and 15 422, whereas a mixture of b and b' gave a molecular weight of 29 800+/-800. The sedimentation coefficient of an equimolar mixture was 1.73+/-0.03. The circular dichroism spectra of the individual polypeptides indicated helical contents in the range of 40-50%; the spectrum of the mixture revealed changes indicative of coiled-coil formation and a helical content of 60%. The results indicate that the cytosolic domains of the b and b' subunits exist individually as monomers but form a highly extended heterodimer when they are mixed together.

Phylogenetic transfer of organelle genes to the nucleus can lead to new mechanisms of protein integration into membranes

Subunits CFo-I and CFo-II of ATP synthase in chloroplast thylakoid membranes are two structurally and functionally closely related proteins of bitopic membrane topology which evolved from a common ancestral gene. In higher plants, CFo-I still originates in plastid chromosomes (gene: atpF), while the gene for CFo-II (atpG) was phylogenetically transferred to the nucleus. This gene transfer was accompanied by the reorganization of the topogenic signals and the mechanism of membrane insertion. CFo-I is capable of integrating correctly as the mature protein into the thylakoid membrane, whereas membrane insertion of CFo-II strictly depends on a hydrophobic targeting signal in the transit peptide. This requirement is caused by three negatively charged residues at the N-terminus of mature CFo-II which are lacking from CFo-I and which have apparently been added to the protein only after gene transfer has occurred. Accordingly, the CFo-II transit peptide is structurally and functionally equivalent to typical bipartite transit peptides, capable of also translocating hydrophilic lumenal proteins across the thylakoid membrane. In this case, transport takes place by the Sec-dependent pathway, despite the fact that membrane integration of CFo-II is a Sec-independent, and presumably spontaneous, process.

Molecular studies of CtpA, the carboxyl-terminal processing protease for the D1 protein of the photosystem II reaction center in higher plants

The D1 reaction center protein of the Photosystem II complex in green plants is synthesized with a short carboxyl-terminal extension. Proteolytic cleavage and removal of this extension peptide in the thylakoid lumen are necessary for the assembly of a manganese cluster that is essential for the oxygen evolution activity of Photosystem II. We have isolated cDNAs encoding CtpA, the carboxyl-terminal processing protease for the D1 protein, from two higher plants, spinach and barley. In each of these organisms, CtpA is encoded by a single copy nuclear gene, and its steady-state mRNA levels are light-regulated. The CtpA protein is detectable in etiolated material, and its level increases approximately 5-fold upon illumination. Moreover, the CtpA gene is expressed in shoot tissues and not in roots. In its precursor form, the CtpA protein harbors a bipartite transit sequence characteristic for thylakoid lumenal proteins. Cell fractionation studies demonstrated that CtpA is associated with thylakoid membranes and is resistant to treatments with thermolysin, consistent with its localization in the lumen of thylakoids. Comparisons of the sequence of the higher plant CtpA enzyme with those of other related carboxyl-terminal processing proteases suggest that these proteins constitute a new family of proteases.

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.

Tissue-specific expression of the large ATP synthase gene cluster in spinach plastids

Plastids present in different tissues may vary morphologically and functionally, despite the fact that all plastids within the same plant contain identical genomes. This is achieved by regulation of expression of the plastid genome by tissue-specific factors, the mechanisms of which are not fully understood. The proton translocating ATP synthase/ATPase is a multisubunit complex composed of nine subunits, six encoded in the plastid and three in the nucleus. We have investigated the tissue-specific expression of the large ATP synthase gene cluster in spinach (Spinacia oleracea). This gene cluster encodes four of the six plastid-encoded ATP synthase genes. Transcript abundance, transcriptional activity, and transcript stability were investigated relative to gene dosage in root plastids and in stem, leaf, and flower chloroplasts. All three of these factors display significant tissue-specific variation. It was intriguing to discover that, although transcript abundance normalized to gene dosage varies in each tissue, transcript abundance as a proportion of the entire plastid RNA population in each tissue is not significantly different. Thus it appears that in these tissues the variation in transcription and stability of transcripts derived from the large ATP synthase gene cluster balances to yield an equivalent proportion of these transcripts in the plastid RNA population. Expression of this gene cluster in photosynthetic as well as non-photosynthetic tissues may facilitate the plasticity of structure and function which is characteristic of plastids.

Mutagenesis of the b'-subunit of Synechocystis sp. PCC 6803 ATP-synthase

We investigated the F0F1 ATP synthase of the cyanobacterium, Synechocystis sp. PCC 6803. The gene for the F0-subunit b', a peptide probably located at the interface between F0 and F1, has been partially or completely evicted from the bacterial genome. We found that the complete deletion of the subunit was lethal to the cells. However, the subunit could be truncated down to its hydrophobic N-terminal stretch without much harm. Since the gene for b' probably shares a common ancestor with the gene for subunit b and emerged by gene duplication, we propose that b' gathered a new role during evolution, perhaps in the regulation of photophosphorylation.

Organization of plastid-encoded ATPase genes and flanking regions including homologues of infB and tsf in the thermophilic red alga Galdieria sulphuraria

We have cloned and sequenced the plastid ATPase operons (atp1 and atp2) and flanking regions from the unicellular red alga Galdieria sulphuraria (Cyanidium caldarium). Six genes (5 atpI, H, G, F, D and A 3) are linked in atp1 encoding ATPase subunits a, c, b, b, delta and alpha, respectively. The atpF gene does not contain an intron and overlaps atpD by 1 bp. As in the genome of chloroplasts from land plants, the cluster is located downstream of rps2, but between this gene and atp1 we found the gene for the prokaryotic translation elongation factor TS. Downstream of atpA, we detected two open reading frames, one encoding a putative transport protein. The genes atpB and atpE, encoding ATPase subunits beta and epsilon, respectively, are linked in atp2, separated by a 2 bp spacer. Upstream of atpB, an uninterrupted orf167 was detected which is homologous to an intron-containing open reading frame in land plant chloroplasts. This orf167 is preceded on the opposite DNA strand by a homologue to initiation factor 2 in prokaryotes. The arrangement of atp1 and atp2 is the same as observed in the multicellular red alga Antithamnion sp., indicating a conserved genome arrangement in the red algal plastid genome. Differences compared to green chloroplast genomes suggest a large phylogenetic distance between red algae and green plants, while similarities in arrangement and sequence to chromophytic ATPase operons support a red algal origin of chlorophyll a/c-containing plastids or alternatively point to a common prokaryotic endosymbiont.

The nuclear-encoded polypeptide Cfo-II from spinach is a real, ninth subunit of chloroplast ATP synthase

Proton-translocating F-ATP synthases from chloroplasts contain a nuclear-coded subunit, CFo-II, that lacks an equivalent in the corresponding E. coli complex. Three recombinant phages that code for the entire precursor of this subunit have been isolated from lambda gt11 cDNA expression libraries made from polyadenylated spinach RNA using a two-step strategy. The reading frame of 222 amino acid residues includes 147 residues for the mature protein (M(r) 16.5 kDa) and a transit sequence of 75 residues (M(r) 8.0 kDa). Secondary structure predictions indicate a bitopic protein, anchored by a single N-terminal transmembrane segment and a C-terminal hydrophilic region that probably reaches into CF1. CFo-II precursor made in vitro can be imported into isolated, intact chloroplasts and assembled into ATP synthase. This protein is a real subunit of the plastid enzyme and a distinctive characteristic of ATP synthases involved in photosynthetic processes. Unique features are (i) that the gene for CFo-II (atpG) appears to be a duplication of atpF encoding CFo-I, the homologues of the genes for subunits b' and b in photosynthetic bacteria, (ii) that it represents the first instance that one copy of the various duplicated loci found in plastid chromosomes has been phylogenetically translocated to the nucleus, and (iii) that it operates with a bipartite (import/thylakoid-targeting) transit peptide but without an intermediate cleavage site for the stroma protease, suggestive of a way of membrane integration different from that of its plastome-encoded counterpart CFo-I. With these data, the first complete sequence for a chloroplast ATP synthase of a higher plant (spinach) is available.

Structure of the nuclear encoded gamma subunit of CF0CF1 of the diatom Odontella sinensis including its presequence

Using a PCR-product as homologous probe for screening of a cDNA library of the diatom Odontella sinensis overlapping cDNA clones were obtained which showed homologies to atpC-genes of F0F1-ATPases from different sources. Comparison of the deduced amino acid sequence with the N-terminal sequence of the Odontella gamma subunit obtained by protein sequencing, indicated that the complete 370 amino acid protein is processed to a mature protein of 315 amino acids. The 55 amino acids comprising the presequence consists of two segments, one resembling a signal sequence for cotranslational transport through ER membranes and one showing characteristics of a transit sequence for transport of proteins into chloroplasts of higher plants. This result is discussed with respect to the particular envelope structure of chromophytic plastids consisting of four membranes. The outer membrane contains ribosomes on its cytosolic surface. As in cyanobacterial gamma subunits the regulatory sequence region, which is involved in thiol modulation of chloroplast ATPase of green algae and higher plants, is absent in the Odontella gamma subunit.

Large ATP synthase operon of the red alga Antithamnion sp. resembles the corresponding operon in cyanobacteria

The large plastid ATP synthase operon of the multicellular red alga Antithamnion sp. was cloned and the sequence of six ATPase genes determined. The operon resembles more the one from cyanobacteria than the ATP synthase operon of the chloroplast genome. The gene order is atpI, H, G, F, D and A, coding for the ATPase subunits a, c, b', b, delta and alpha, respectively. In green plants, the genes atpG and atpD are located in the nucleus. Unlike the situation in three published cyanobacterial ATP synthase operons, atpC, coding for the gamma subunit, is not a part of the rhodoplast operon. A single 4.5 kb transcript was detected with atpG, F, D and A gene probes that could span the whole operon, but no transcript could be detected with atpI and atpH probes. The end of an open reading frame preceding the atp genes shows remarkable homology to elongation factor TS from Escherichia coli. Behind the ATPase cluster, two open reading frames were detected that are not homologous to any known chloroplast gene. One of them may code for a transport protein of unknown specificity. Gene arrangement and sequence comparisons support the hypothesis of a polyphyletic origin of rhodoplasts and chloroplasts.

Nucleotide sequence and phylogenetic implication of the ATPase subunits beta and epsilon encoded in the chloroplast genome of the brown alga Dictyota dichotoma

We have cloned and sequenced the genes atpB and atpE, coding for CF1 subunits beta and epsilon, respectively, of the chloroplast genome of the brown alga Dictyota dichotoma. Although the coding site of atpE cannot be demonstrated by heterologous Southern hybridizations, a 417 bp reading frame 3' to atpB was identified as the gene atpE by sequence similarities with atpE genes from other sources. A maximum sequence identity of 30% is found between the predicted amino acid sequence of the Dictyota subunit epsilon and the corresponding cyanobacterial subunits. Including conserved amino acid replacements, the Dictyota epsilon subunit exhibits about 70% sequence similarity with the cyanobacterial and land plant subunits. As in cyanobacteria, the atpE gene does not overlap the preceding gene atpB. The deduced amino acid sequence of atpB is 74-79% identical to the corresponding cyanobacterial and chloroplast subunits. Entirely conserved are regions referred to as the catalytic and/or regulatory sites of ATP formation, including interacting regions between subunits alpha and beta. A phylogram predicted from F1/CF1-beta subunits of eleven different organisms suggests a common evolutionary origin of plastids from chlorophytes and brown algae.

Chloroplast ATPase genes in the diatom Odontella sinensis reflect cyanobacterial characters in structure and arrangement

We have cloned and sequenced a 5200 base restriction fragment and an overlapping 3100 base fragment of the large single copy region of the chloroplast genome of the diatom Odontella sinensis, which hybridized to several ATPase gene probes. These fragments contain six closely linked reading frames that were identified as atpI, atpH, atpG, atpF, atpD, and atpA, coding for subunits IV, III, II, I, delta, and alpha, respectively. Remarkably, the genes atpG and atpD, which are nucleus-encoded in chlorophyll a + b plants, are present in the Odontella chloroplast gene cluster. They map at the same positions as in cyanobacteria. The genes atpD and atpF overlap by four base-pairs as in certain photosynthetic and heterotrophic eubacteria. Upstream from the atpA gene cluster an open reading frame coding for 251 amino acid residues was found, which shows sequence similarity to ATP-binding subunits of periplasmic prokaryotic and eukaryotic transport systems. No similar reading frame is present in the land plant chloroplast genomes analysed so far. Sequences and arrangement of the genes are discussed with respect to the peculiar evolution of the chlorophyll a + c-containing chromophytic plastids.

Expression of the wheat chloroplast gene for CF0 subunit IV of ATP synthase

The nucleotide sequence of the wheat chloroplast atp I gene encoding CF0 subunit IV of ATP synthase has been determined. The gene encodes a polypeptide of 247 amino acid residues with high sequence similarity to subunit IV from other plant chloroplasts and from cyanobacteria. The polypeptide shows sequence homology to the C-terminus of the F0 alpha subunit of Escherichia coli ATP synthase and subunit 6 of mitochondrial ATP synthase. The atp I gene is co-transcribed with the atp H, atp F and atp A genes for other subunits of ATP synthase in wheat. A gene-fusion of most of the atp I coding region with cro'-lacI'-lacZ' has been constructed in pEX2 and the fusion-protein has been used to raise antibodies in rabbits. The antibodies react with a polypeptide of 17 kDa in wheat thylakoid membranes indicating that the wheat atp I gene is expressed at the protein level. A model for the organisation of the polypeptide in the thylakoid membrane with four membrane-spanning segments is proposed.

Nucleotide sequence and transcripts of the pea chloroplast gene encoding CFo subunit III of ATP synthase

The structure and expression of the pea chloroplast atpH gene, encoding ATP synthase CFo subunit III, have been investigated. The atpH gene is situated between the atpI and atpF genes for CFo subunits IV and I, and encodes a hydrophobic polypeptide of 81 amino acid residues which is very similar to subunit III from other species. Analysis of transcripts from the region of chloroplast DNA encoding ATP synthase subunits IV-III-I-alpha shows a complex pattern of transcription, with large transcripts potentially coding for several subunits and also smaller gene-specific transcripts. Two abundant transcripts of 660 nucleotides (nt) and 980 nt specific for atpH were identified. Primer extension and S1 nuclease protection mapping suggested that the 660-nt transcripts were produced by endonucleolytic processing at the sequence, 5'-UGGAAU.

Application of an efficient strategy with a phage lambda vector for constructing a physical map of the amyloplast genome of sycamore (Acer pseudoplatanus)

Amyloplasts were isolated from a heterotrophic culture cell line of a woody plant, sycamore (Acer pseudoplatanus), and their DNA was purified. Conventional procedures for making a physical map were not easily applicable to the amyloplast DNA, since the yield of DNA was too low and the presence of repeated sequences interfered with the analysis. Therefore, the pieces of amyloplast DNA starting with a few micrograms of DNA were cloned in the lambda Fix vector, which is a derivative of lambda EMBL vectors improved for efficient cloning and gene walking. Cloned DNA fragments were randomly picked, mapped for restriction endonuclease sites by a refined procedure, and combined by overlapping their physical maps. The DNA library was also subjected to screening by gene walking using promoters recognized by T3 and T7 RNA polymerases in the vector to fill the gaps between sequences determined by overlapping the physical maps. In this way, we constructed the entire DNA library and the complete physical map of the amyloplast DNA. The sycamore amyloplast genome was composed of 141.7-kbp nucleotides with the same gene arrangement as that of tobacco chloroplasts.

Differential expression of nuclear- and organelle-encoded genes during tomato fruit development

Steady-state mRNA levels of nuclear-and organelle-encoded genes were determined during fruit development and ripening. Transcripts specific for subunits of the mitochondrial and chloroplast ATPase complexes appear simultaneously and reach high levels two to three weeks after anthesis, but follow a different expression pattern during the ripening period. While the chloroplast-specific mRNA levels continuously decrease to low levels in ripe tomato fruits, the transcripts specific for two mitochondrial ATPase subunits continue to be present at relative high levels in red fruits. Transcript levels for the fructose-1,6-bisphosphate aldolase increase significantly during ripening. Structural proteins such as the alpha-subunit of tubulin and the hydroxyproline-rich glycoprotein extensin are expressed during maximal fruit growth. In addition, comparisons of mRNA levels of different genes in several plant organs (leaf, fruit, stem, and root) show characteristic differences. The results presented in this paper demonstrate that changes at the transcriptional or post-transcriptional level during fruit development can be correlated with morphological and physiological alterations.

The chloroplast genome of the green alga Chlamydomonas moewusii: localization of protein-coding genes and transcriptionally active regions

We have recently reported the map positions of the ribosomal RNA genes and 6 protein-coding genes on the 292 kbp Chlamydomonas moewusii chloroplast genome. In the present study we localized 12 additional protein-coding genes on this green algal genome as well as 5 of these genes on the 196 kbp C. reinhardtii chloroplast genome. The gene mapping data agree with previous reports indicating that these two algal genomes differ tremendously in their global sequence organization and bear little similarity to their land plant counterparts. Among the 18 protein-coding genes examined, atpA and atpF of C. moewusii constitute the unique set of closely linked genes which is shared with land plant chloroplast genomes. The important gene order differences between the C. moewusii and C. reinhardtii chloroplast DNAs led us to speculate that gene grouping into transcription units is less prevalent in green algal chloroplast genomes than in their land plant homologs. To gain an insight into the transcriptional organization of the C. moewusii chloroplast genome, we probed Northern blots of total cellular RNA with clones covering 85% of this genome. Most chloroplast DNA regions were found to produce simple transcript patterns with RNAs less than 3.5 kb in size. This may be interpreted as indicating that Chlamydomonas chloroplast genes are transcribed mainly as monocistronic RNAs or that the RNAs observed are processed forms of unstable polycistronic transcripts.

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.

Structure, organization and expression of cyanobacterial ATP synthase genes

The genes encoding the nine polypeptides of the ATP synthase from Synechococcus sp. PCC 6301, a unicellular cyanobacterium, and Anabaena sp. PCC 7120, a filamentous cyanobacterium, have recently been isolated and their sequences determined. These represent the first such sequences available from procaryotic organisms that perform oxygenic photosynthesis. Similar to the organization in chloroplasts, the ATP synthase genes of both cyanobacteria are arranged in two gene clusters which are not closely linked in the chromosome. Three of the genes located in one cluster in cyanobacteria, however, are localized in the nuclear rather than the chloroplast genomes of plants. The cyanobacterial ATP synthase genes are ordered in the same manner as those in the single gene cluster of Escherichia coli. Cyanobacteria contain an additional gene denoted atpG which appears to be a duplicated and diverged from of the atpF gene. The larger cyanobacterial cluster, atp 1, is comprised of eight ATP synthase subunit genes arranged in the order atpI-atpH-atpG-atpF-atpD-atpA-atpC. An overlap between the atpF and atpD gene coding regions observed in Anabaena sp. PCC 7120 is absent in both Synechococcus sp. PCC 6301 and E. coli. The second cluster of genes, atp 2, contains the remaining two ATP synthase genes in the order atpB-atpE. Unlike the situation in many chloroplast genomes, this gene pair does not overlap in either cyanobacterial species. In Anabaena sp. PCC 7120, atp 1 and atp 2 each comprise an operon and the transcription initiation sites for each gene cluster have been identified. The cyanobacterial ATP synthase subunits are much more closely related in sequence to the equivalent polypeptides from chloroplasts than they are to those of E. coli. The similarity in chloroplast and cyanobacterial ATP synthase subunit sequences and gene oreganization argue strongly for an endosymbiotic origin for plant chloroplasts.

Genes encoding the alpha, gamma, delta, and four F0 subunits of ATP synthase constitute an operon in the cyanobacterium Anabaena sp. strain PCC 7120

A cluster of genes encoding subunits of ATP synthase of Anabaena sp. strain PCC 7120 was cloned, and the nucleotide sequences of the genes were determined. This cluster, denoted atp1, consists of four F0 genes and three F1 genes encoding the subunits a (atpI), c (atpH), b' (atpG), b (atpF), delta (atpD), alpha (aptA), and gamma (atpC) in that order. Closely linked upstream of the ATP synthase subunit genes is an open reading frame denoted gene 1, which is equivalent to the uncI gene of Escherichia coli. The atp1 gene cluster is at least 10 kilobase pairs distant in the genome from apt2, a cluster of genes encoding the beta (atpB) and epsilon (atpE) subunits of the ATP synthase. This two-clustered ATP synthase gene arrangement is intermediate between those found in chloroplasts and E. coli. A unique feature of the Anabaena atp1 cluster is overlap between the coding regions for atpF and atpD. The atp1 cluster is transcribed as a single 7-kilobase polycistronic mRNA that initiates 140 base pairs upstream of gene 1. The deduced translation products for the Anabaena sp. strain PCC 7120 subunit genes are more similar to chloroplast ATP synthase subunits than to those of E. coli.

Nucleotide sequence of cDNA clones encoding the complete precursor for subunit delta of thylakoid-located ATP synthase from spinach

The nucleotide sequence of the entire nuclear-encoded precursor for subunit delta of the ATP synthase from spinach thylakoid membranes was determined by cDNA sequencing. Appropriate recombinant DNAs were selected from pBR322 and lambda gt11 libraries made from polyadenylated RNA of greening spinach seedlings. The mature protein consists of 187 amino acid residues corresponding to a molecular weight of 20468. The precursor protein (257 amino acid residues; M r=27676) is probably processed between a Met-Val bond. The predicted secondary structure of the transit sequence (70 residues; 7.2 kDa) resembles that of the Rieske Fe/S polypeptide, but shows little similarity with those of stromal or luminal proteins. The comparison of the chloroplast delta amino acid sequence with the published delta sequences from respiratory ATP synthases of bacterial and mitochondrial sources and from the thylakoid ATP synthase of the cyanobacterium Synechococcus suggests substantial divergence at the genic level although structural elements appear to be remarkably conserved.

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.

Rapid splicing and stepwise processing of a transcript from the psbB operon in tobacco chloroplasts: determination of the intron sites in petB and petD

Expression of the psbB gene cluster in tobacco chloroplasts has been studied. This cluster contains the genes for the 51 kDa chlorophyll a apoprotein (psbB) and the 10 kDa phosphoprotein (psbH) of the photosystem II, and cytochrome b6 (petB) and subunit IV (petD) of the cytochrome b/f complex in this order. Northern blot hybridization and reverse transcription analyses have revealed that petB and petD contain single introns and the psbB gene cluster is transcribed as a single polycistronic unit. The primary transcript seems to be spliced very rapidly and then processed into several small RNA species. The exact splice sites have been located by cDNA sequencing. The transcriptional initiation site of the psbB operon has been determined by S1 mapping with in vitro capped chloroplast RNA. The stepwise processing of chloroplast RNA precursors is discussed.

ATP synthase from bovine mitochondria. The characterization and sequence analysis of two membrane-associated sub-units and of the corresponding cDNAs

ATP synthase from bovine mitochondria is a complex of 13 different polypeptides, whereas the Escherichia coli enzyme is simpler and contains eight subunits only. Two of the bovine subunits, b and d, which had not been characterized, have been isolated from the purified enzyme. Subunits with sizes corresponding to bovine subunits b and d are evident in preparations of the enzyme from mitochondria of other species. Partial protein sequences have been determined by direct methods. On the basis of some of this information, two oligonucleotide mixtures, 17 and 18 bases in length, have been synthesized and used as hybridization probes in the isolation of clones of the cognate cDNAs. The sequences of the two proteins have been deduced from their DNA sequences. Subunit b is 214 amino acid residues in length and has a free N terminus. Subunit d is 160 amino acid residues long. Its N-terminal alanine is blocked by an N-acetyl group, as demonstrated by fast atom bombardment mass spectrometry of N-terminal peptides. The sequence near the N terminus of the b subunit is made predominantly of hydrophobic residues, whereas the remainder of the protein is mainly hydrophilic. This N-terminal hydrophobic region may be folded into an alpha-helical structure spanning the lipid bilayer. In its distribution of hydrophobic residues, this protein resembles the b subunits of ATP synthase complexes in bacteria and chloroplasts. The b subunit in E. coli forms an important structural link between the extramembrane sector of the enzyme F1, and the intrinsic membrane domain, FO. It is proposed that the bovine mitochondrial subunit b serves a similar function. If this is so, the mitochondrial enzyme, as the chloroplast ATP synthase, contains equivalent subunits to all eight of those that constitute the E. coli enzyme. Subunit d has no extensive hydrophobic sequences, and is not apparently related to any subunit described in the simpler ATP synthases in bacteria and chloroplasts.

A gene cluster in the spinach and pea chloroplast genomes encoding one CF1 and three CF0 subunits of the H+-ATP synthase complex and the ribosomal protein S2

The regions of the spinach and pea chloroplast genomes containing the ATP synthase genes atpA, atpF and atpH have been sequenced. The encoded proteins, CF1 alpha, CF0I and CF0III, are well conserved between spinach and pea, and analogous to the alpha, b and c subunits of the Escherichia coli ATP synthase complex. The atpF gene is split by a single intron, and the exon/intron boundaries have been defined by isolating and sequencing a partial cDNA clone. Two other genes, designated atpI and rps2, located upstream from atpH, have also been sequenced. They encode a 27,000 Mr hydrophobic protein analogous to the F0a subunit of E. coli ATP synthase and a basic protein analogous to the S2 protein of the E. coli 30 S ribosomal subunit. Transcriptional analysis by electron microscopy of RNA-DNA hybrids, Northern blotting and primer extension experiments shows that these genes are transcribed and processed into a complex set of transcripts, with 5' ends mapping upstream from the rps2, atpI and atpH genes.

The organization and sequence of the genes for ATP synthase subunits in the cyanobacterium Synechococcus 6301. Support for an endosymbiotic origin of chloroplasts

The nucleotide sequence has been determined of two regions of DNA cloned from the cyanobacterium Synechococcus 6301. The larger, 8890 base-pairs in length, contains a cluster of seven genes for subunits of ATP synthase. The order of the genes is a:c:b':b:delta:alpha:gamma, b' being a duplicated and diverged form of b. As in the Escherichia coli unc operon, the a gene is preceded by a gene for a small hydrophobic and basic protein. The hydrophobic profile of the potential gene product suggests that its secondary structure is similar to the uncI protein. The smaller DNA fragment, 4737 base-pairs in length, is separated from the larger by at least 15 X 10(3) base-pairs of DNA. It contains a cluster of two genes encoding ATP synthase subunits beta and epsilon. Both clusters of ATP synthase genes are preceded by sequences resembling the -10 (Pribnow) box of E. coli promoters and are followed by sequences able to form stable stem-loop structures that might serve to terminate transcription. These features and the small intergenic non-coding sequences suggest that the clusters are operons, for which the names atp1 and atp2 are proposed. The order of genes within the two clusters is very similar to the gene order in the E. coli unc operon. However, it is most closely related to the arrangement of genes for ATP synthetase subunits a:c:b:alpha and beta:epsilon in two clusters in pea chloroplast DNA. This close relationship between chloroplasts and the cyanobacterium is also evident from comparisons of the sequences of ATP synthase subunits; the Synechococcus proteins are much more closely related to chloroplast homologues than to those in other bacteria or in mitochondria. It is further supported by the cyanobacterial b and b' proteins which, in common with their chloroplast counterpart, subunit I, have extra amino-terminal extensions relative to the E. coli b protein. This extension is known to be removed by post-translational processing in the chloroplast, but its function is obscure. It also seems likely that the cyanobacterial and chloroplast ATP synthases have important similarities in subunit composition. For example, the presence of two related genes, b and b', in the cyanobacterium suggests that its ATP synthase is a complex of nine polypeptides, and that it may have single copies of related b and b' proteins rather than two copies of identical b subunits as found in the E. coli enzyme.4+off