The genes for the alpha and proton-translocating subunits of wheat chloroplast ATP synthase are close together on the same strand of chloroplast DNA

An internal part of the chloroplast atpA gene sequence is present in the mitochondrial genome of Triticum aestivum: molecular organisation and evolutionary aspects

An internal part of the chloroplast atpA gene has been identified in the mitochondrial DNA of Triticum aestivum. It is located near the 18S-5S ribosomal genes and partially contained within a repeated sequence. Comparison of the transferred sequence with the original ct sequence reveals several nucleotide changes and shows that neither 5' nor 3' ends are present in the mt genome. No transcript of this region could be detected by Northern analysis. This sequence is present in mitochondrial genomes of other tetraploid and diploid species of Triticum, also in the vicinity of the 18S-5S ribosomal genes, suggesting a unique transfer event. The date of this event is discussed.

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.

Common features of three inversions in wheat chloroplast DNA

We have determined the DNA sequences of regions involved in two of the three inversions known to have occurred during the evolution of wheat chloroplast DNA. This establishes the extent of the second largest of the three inversions. Examination of these sequences suggests that although short repeated sequences are present, the endpoints of the second and third inversions are not associated with repeated sequences as long as those associated with the first inversion. However the endpoints of all three inversions are all adjacent to at least one tRNA gene, and there is evidence that three of the tRNA genes have been subjected to partial duplication, possibly at the time of inversion. This suggests that tRNA genes might be involved with rearrangements of chloroplast DNA, as has also been postulated for mitochondrial DNA.

A model for the evolution of the Vicia faba chloroplast genome

The Vicia faba chloroplast genome lacks inverted repeat sequences and contains only one set of ribosomal RNA genes. The genetic organization has been altered by inversions, relative to the typical arrangement of most higher plant chloroplast genomes. The Vicia faba plastid genome thus represents one of the more interesting results of chloroplast genomic evolution. The present study employs small DNA probes and Southern blot hybridizations to investigate the steps involved in the evolution of the Vicia faba chloroplast genome. The data from heterologous hybridizations between chloroplast DNA of Brassica napus (a conserved genome) and of Vicia faba led to three observations: 1) The inverted repeat segment closest to the psbA gene was deleted prior to the rearrangements. 2) A quarter of the ancestral small single copy region was lost during the deletion. 3) The genetic organization observed in Vicia faba resulted from three inversions after the deletion event. Our findings, combined with previous observations, helped devise a stepwise model for the evolution of the Vicia faba chloroplast genome. The area of the small single copy region absent from the Vicia faba chloroplast chromosome lacks in vivo transcription activity in Brassica napus.

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.

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

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

Localization and nucleotide sequences of the tRNA GCC (Gly) , tRNA GUC (Asp) and tRNA GCA (Cys) genes from wheat chloroplast

The location on the wheat chloroplast DNA map and the nucleotide sequences of the genes coding for tRNA GCC (Gly) (trnG-GCC), tRNA GUC (Asp) (trnD-GUC) and tRNA GCA (Cys) (trnC-GCA) have been determined. These three genes are located in the large single copy region of the chloroplast genome, about half-way between one of the inverted repeats and the gene for the α subunit of ATP synthase. They are located on two Bam H1 fragments, called B6 and B18 by Bowmanet al. (1), which are separated by about 450 bp and which were cloned in our laboratory to allow sequencing. ThetrnD-GUC andtrnC-GCA sequences show 98.6 and 89% homology, respectively, with the corresponding spinach chloroplast tRNA genes sequences (2), which are the only other higher plant chloroplasttrnD-GUC andtrnC-GCA sequenced so far, while no othertrnG-GCC sequence has been published. ThetrnG-GCC sequence shows only 58% homology with the corresponding gene sequence inEuglena chloroplasts (3).

Organization and sequence of five tRNA genes and of an unidentified reading frame in the wheat chloroplast genome: evidence for gene rearrangements during the evolution of chloroplast genomes

The genes for the initiator tRNA(Met)CAU, tRNA(Gly)UCC, tRNA(Thr)GGU, tRNA(Glu)UUC and tRNA(Tyr)GUA and an open reading frame of 62 codons have been identified by sequencing a 2,358 bp BamHI and a 1,378 bp BamHI-Sst2 DNA fragments from wheat chloroplasts. A comparison of the organization of these five tRNA genes and of the open reading frame on the wheat, tobacco and spinach chloroplast genomes suggests that at least three genomic inversions must have occurred during the evolution of the wheat chloroplast genome from a spinach-like ancestor genome. Furthermore, it seems that in wheat the 91 bp intergenic region between the genes for the initiator tRNA(Met) and the gene for tRNA(Gly)UCC is one end-point of the 20 kbp genomic inversion proposed by Palmer and Thompson in the case of maize (Palmer and Thompson 1982). A 119 bp duplication is located at this junction: the first copy comprises the 91 bp of the intergenic region and the first 28 bp of the tRNA(Met) gene, the second copy is found downstream of the tRNA(Met) gene.

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.

Positioning of protein-coding genes on the soybean chloroplast genome

Seven major plastid protein encoding genes were positioned on the soybean chloroplast DNA by heterologous hybridization. These include the genes for the alpha, beta and epsilon subunits of the CF1 component of ATP synthase (atpA, atpB and atpE respectively), for subunit III of the CF0 component of ATP synthase (atpH), for the cytochrome f (cytF), for the '32 Kd' thylakoid protein (psbA), and for the large subunit of ribulose-1,5-bisphosphate carboxylase-oxygenase (rbcL), all of which map in the large single copy region. The atpB, atpE and rbcL genes are located in the region adjacent to one of the segments of the inverted repeat. The genetic organization of the soybean chloroplast DNA is compared to that of other plastid genomes.

The endpoints of an inversion in wheat chloroplast DNA are associated with short repeated sequences containing homology to att-lambda

The endpoints of an inversion in wheat chloroplast DNA are shown to be associated with copies of a short repeated sequence. Recombination across the repeats in an inverted configuration may have been responsible for the inversion, although they are currently in a direct orientation owing to a second inversion. The repeated sequence contains an element homologous to the core of the bacteriophage lambda att-site, which can function as such in vivo.

Chloroplast DNA deletions associated with wheat plants regenerated from pollen: possible basis for maternal inheritance of chloroplasts

Albinism in plants regenerated from pollen by anther culture may result from the same mechanisms as postulated to be responsible for maternal inheritance of chloroplasts. Consistent with this view, Southern blotting was used to show that large regions of the chloroplast genome (over 80% in one case) were deleted in the major ctDNA molecules present in eight albino wheat plants regenerated from separate pollen calluses. A wide variety of deleted ctDNA molecules was present in these plants. Most albino plants appeared to contain a heterogeneous population of ctDNA molecules. Albino plant 6 contained one major type of deleted ctDNA molecule that had a circular 39 kb restriction map. The retention of only two Pst l (unaltered in size) fragments in albino plant 7 may delimit a region of ctDNA that contains a replication origin.

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.

Maize mitochondrial DNA contains a sequence homologous to the ribulose-1,5-bisphosphate carboxylase large subunit gene of chloroplast DNA

The mitochondrial genome of maize contains a DNA sequence homologous to the chloroplast gene coding for the large subunit of ribulose-1,5-bisphosphate carboxylase (LS gene). The presence in mitochondrial DNA of both coding and flanking sequences of this gene has been demonstrated first, by cross hybridization between the purified organelle DNAs and between cloned mitochondrial and chloroplast DNA sequences and second, by in vitro transcription-translation of cloned mitochondrial DNA in an E. coli cell free system where a 21,000 dalton polypeptide is synthesized that can be precipitated with antibodies to wheat ribulose-1,5-bisphosphate carboxylase. In contrast to the 12 kb chloroplast homologous sequence found in the mitochondrial genome (Stern and Lonsdale, 1982), the sequence homologous to the LS gene is unaltered in mitochondrial DNA isolated from the male sterile cytoplasms of maize. The LS gene homologous sequence in the mitochondrial genome is located some 65 kb from the 18S mitochondrial rRNA gene and approximately 20 kb from the mitochondrial DNA sequence having homology to the chloroplast 16S rRNA gene.

Chloroplast DNA variation between species of Triticum and Aegilops. Location of the variation on the chloroplast genome and its relevance to the inheritance and classification of the cytoplasm

Restriction endonuclease analysis revealed interspecific and intraspecific variation between the chloroplast DNAs and therefore between the cytoplasms of 14 selected species of Triticum and Aegilops. Eleven distinct chloroplast DNA types were detected, the differences between them residing in the varied combination of a relatively few DNA alterations.The variation was simple enough for chloroplast DNA analysis to be used as a basis for the identification and classification of the Triticum and Aegilops cytoplasms. There was good agreement with the classification based on analysis of the phenotypic effects of the cytoplasm when combined with the T. aestivum nucleus in nuclear-cytoplasmic hybrids (Tsunewaki et al. 1976). There was however no correlation between specific chloroplast DNA alterations and any of the phenotypic effects known to be associated with specific cytoplasms.Although the diploid species examined included all those which have been suggested as possible donors of the cytoplasm and the B genome to T. aestivum, none of the chosen accessions belonged to the same cytoplasmic class as T. aestivum itself, except that of the tetraploid T. dicoccoides. Therefore, none of the diploid accessions analysed was the B genome donor. The analyses did however support several other suggestions which have been made concerning wheat ancestry. Scoring the different chloroplast DNA types according to the rarity of their banding patterns indicated that four of the eleven cytoplasms are of relatively recent origin.The DNA alterations most easily detectable by the limited comparison of the eleven Triticum/Aegilops chloroplast DNA types using only 4 endonucleases were insertions and deletions. These ranged between approximately 50 bp and 1,200 bp in size and most of them were clustered in 2 segments of the large single-copy region of the genome. Only two examples of the loss of restriction endonuclease sites through possible point mutations were observed. No variation was detected in the inverted repeat regions. Several of the deletions and insertions map close to known chloroplast protein genes, and there is also an indication that the more variable regions of the chloroplast genome may contain sequences which have allowed DNA recombination and rearrangement to occur.