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.     

The δ subunit of the chloroplast ATPase is plastid-encoded in the diatom Odontella sinensis

A 5.2 kb PstI restriction fragment containing the atpA gene cluster of the plastic genome of the centric diatom Odontella sinensis was cloned. Sequencing revealed a reading frame of 561 bp separating the genes atpF and atpA, which is preceded by a putative ribosome binding site. The third nucleotide of the codon for the last amino acid of atpF is the first nucleotide of the initiation codon of the 561 bp reading frame. The amino acid sequence deduced from the nucleotide sequence of this gene (ntpD) is colinear with δ subunits of different F₀F₁-ATPases and shows an overall sequence homology of up to 35% when compared with the sequences of cyanobacteria and Cyanophora paradoxa. The results are discussed in context with the evolution of chloroplasts of the chlorophyll-a + b and -a + c lineages, respectively.     

Independent and coupled translational initiation of atp genes in Escherichia coli: experiments using chromosomal and plasmid-borne lacZ fusions

The translational initiation rates directed by the translational initiation regions (TIRs) of the atpB, atpH, atpA and atpG genes of Escherichia coli were investigated using lacZ fusions present on plasmids as well as integrated into the chromosome. This was the first investigation of the translational efficiency of the atpB gene, whose unfused product (subunit a) can be toxic to the cell. The specific mRNA levels, rates of in vivo protein synthesis and beta-galactosidase activities encoded by the atp::lacZ fusions were compared in order to obtain valid estimates of relative translation rates. The results indicate that in the E. coli atp operon, translation directed by the atpB, atpH and atpG TIRs is less efficient than that directed by the atpA TIR, and are thus consistent with earlier measurements of direct atp gene expression. Initiation is, however, to differing extents, controlled by coupling to the translation of upstream neighbours. There is particularly tight coupling between atpH and atpA. Increasing the distance between these two genes whilst maintaining the original atpA TIR structure decreased the degree of coupling. The influence of manipulations of the atpG TIR structure upon translational efficiency was quantitatively more pronounced when the atpG fusions were present as a single copy per chromosome. This is likely to be related to the mRNA binding characteristics of 30S ribosomal subunits and/or to the influence of other (trans-acting) factors. The control of independent and coupled initiation at the atp TIRs is discussed in relation to mRNA structure and possible cis and trans regulatory phenomena.     

Translational coupling varying in efficiency between different pairs of genes in the central region of the atp operon of Escherichia coli

A series of atp::lacZ fusions has been constructed for use in a study of translational coupling in the central region of the Escherichia coli atp operon. Five genes, atpE, atpF, atpH, atpA and atpG, were shown to be translationally coupled to various degrees of tightness. A new lac promoter vector, compatible with the atp::lacZ fusion vectors, was used to express individual atp genes in the same hosts as the fusion genes. The H(+)-ATPase subunits thus synthesized exercised no significant trans-regulation on the expression of the atp::lacZ fusions, indicating that the coupling is primarily cis. The mechanism of this coupling was investigated using in vitro mutagenesis. At least in the case of the pair atpHA, coupling seems to involve facilitated binding of fresh ribosomes to the atpA translational initiation regions.     

The Na(+)-F(1)F(0)-ATPase operon from Acetobacterium woodii. Operon structure and presence of multiple copies of atpE which encode proteolipids of 8- and 18-kda

Eight genes (atpI, atpB, atpE(1), atpE(2), atpE(3), atpF, atpH, and atpA) upstream of and contiguous with the previously described genes atpG, atpD, and atpC were cloned from chromosomal DNA of Acetobacterium woodii. Northern blot analysis revealed that the eleven atp genes are transcribed as a polycistronic message. The atp operon encodes the Na(+)-F(1)F(0)-ATPase of A. woodii, as evident from a comparison of the biochemically derived N termini of the subunits with the amino acid sequences deduced from the DNA sequences. The molecular analysis revealed that all of the F(1)F(0)-encoding genes from Escherichia coli have homologs in the Na(+)-F(1)F(0)-ATPase operon from A. woodii, despite the fact that only six subunits were found in previous preparations of the enzyme from A. woodii. These results unequivocally prove that the Na(+)-ATPase from A. woodii is an enzyme of the F(1)F(0) class. Most interestingly, the gene encoding the proteolipid underwent quadruplication. Two gene copies (atpE(2) and atpE(3)) encode identical 8-kDa proteolipids. Two additional gene copies were fused to form the atpE(1) gene. Heterologous expression experiments as well as immunolabeling studies with native membranes revealed that atpE(1) encodes a duplicated 18-kDa proteolipid. This is the first demonstration of multiplication and fusion of proteolipid-encoding genes in F(1)F(0)-ATPase operons. Furthermore, AtpE(1) is the first duplicated proteolipid ever found to be encoded by an F(1)F(0)-ATPase operon.     

Structure and organization of Marchantia polymorpha chloroplast genome. II. Gene organization of the large single copy region from rps'12 to atpB

The nucleotide sequence (56,410 base-pairs) of the large single-copy region of chloroplast DNA from the liverwort Marchantia polymorpha has been determined. The sequence starts from one end (JLA) of the large single-copy region and encompasses genes for 21 tRNAs, six ATPase subunits (atpA, atpB, atpE, atpF, atpH and atpI), two photosystem I polypeptides (psaA and psaB), four photosystem II polypeptides (psbA, psbC, psbD and psbG), five ribosomal proteins (rps2, rps4, rps7, rps'12 and rps14), and three RNA polymerase subunits (rpoB, rpoC1 and rpoC2). In addition, we detected 18 open reading frames ranging from 29 to 2136 amino acid residues long, four of which share significant amino acid sequence homology to those of an Escherichia coli malK protein (designated mbpX), human mitochondrial ND2 (ndh2) and ND3 (ndh3) of a respiratory chain NADH dehydrogenase, or a bacterial antenna protein of a light-harvesting complex (lhcA). Sequence analysis suggests that four tRNA genes and six protein genes might be split by introns; they are trnG(UCC), trnK(UUU), trnL(UAA), trnV(UAC), atpF, ndh2, rpoC1, rps'12, ORF135 and ORF167. In the large single-copy region described here, the gene organization deduced is highly conserved with respect to that of higher plants, but an inversion of some 30,000 base-pairs flanked by trnL(CAA) and trnD(GUC) was seen between the liverwort and tobacco chloroplast genomes.     

Rice chloroplast DNA molecules are heterogeneous as revealed by DNA sequences of a cluster of genes.

We describe the isolation of two rice chloroplast HindIII fragments (9.5 kb and 5.3 kb) each containing a gene cluster coding for the large subunit of ribulose-1,5-bisphosphate carboxylase (rbcL), beta and epsilon subunits of ATPase (atpB and atpE), tRNAmet (trnM) and tRNAval (trnV). All five genes contained in the 9.5 kb fragment are potentially functional, whereas in the 5.3 kb fragment, rbcL is truncated and atpB is frame-shift mutated. The copy number of the 9.5 kb fragment is 10 times that of the 5.3 kb fragment, indicating that the two fragments are probably located on different chloroplast genomes and represent two different (major and minor) genomic populations. Thus, the rice chloroplast genome appears to be heterogeneous, contrary to general belief. We also describe the isolation of a rice mitochondrial HindIII fragment (6.9 kb) which contains an almost complete transferred copy of this chloroplast gene cluster. In this transferred copy, the coding sequences of rbcL, atpE and trnM contain perfectly normal reading frames, whereas atpB has become grossly defective and trnV is truncated.     

利用酵母双杂交筛选豌豆叶绿体镁离子螯合酶D亚基相互作用蛋白

植物叶绿体镁离子螯合酶是四吡咯化合物生物合成途径中合成叶绿素分支(镁分支)的第一个酶,它催化镁离子螯合到原卟啉IX中,形成镁原卟啉IX. 镁离子螯合酶是1个由3个亚基H、D和I组成的多亚基酶,3个亚基均由细胞核编码,进入叶绿体发挥功能.该酶不仅控制着叶绿素的合成,其各个亚基还具有很多其它的功能：H亚基既是ABA受体,又参与叶绿体到细胞核的反向信号传导;D亚基也与叶绿体到细胞核的反向信号传导有关. 本文利用酵母双杂交技术,将编码豌豆镁离子螯合酶D亚基的cDNA片段构建到诱饵载体pGBKT7中,分别用共转化的方法筛选豌豆叶片细胞核编码的均一化cDNA文库和用Mating的方法筛选豌豆叶片叶绿体编码的均一化cDNA文库,共得到121个候选克隆,其中有60个克隆共编码21个叶绿体蛋白质,19个来自于核基因编码,2个来自于叶绿体基因编码. 这些候选蛋白参与叶绿素合成、卡尔文循环、叶绿体蛋白质翻译和叶绿体基因转录等多个代谢过程. 酵母点对点和GST-pull down对其中的4个蛋白做了进一步的验证.这些结果将为D亚基的功能研究提供进一步的线索.     

Characterization of semi-uncoupled hybrid Escherichia coli-Bacillus megaterium F1F0 proton-translocating ATPases.

Cloned atp genes for the proton-translocating ATPase of the obligate aerobe Bacillus megaterium have been demonstrated to be capable of complementing Escherichia coli ATPase (unc) mutants (Hawthorne, C. A., and Brusilow, W. S. A. (1986) J. Biol. Chem. 261, 5245-5248). To determine the minimum subunit requirements for cross-species complementation, we constructed all combinations of B. megaterium atpA, G, D, and C genes (coding for the alpha, gamma, beta, and epsilon subunits, respectively) and tested their abilities to complement two uncA (alpha subunit) and two uncD (beta subunit) mutants of E. coli. The results indicated that complementation of either uncD mutant required atpD (beta) only. Complementation of one of the uncA (alpha) mutants required atpA, G, and D (alpha, gamma, and beta) and possibly atpE (epsilon) as well. The other uncA mutant was not complemented by any combination of B. megaterium ATPase genes. Complementation of a beta mutant by atpD (beta) or atpD and C (beta epsilon) produced cells which could grow aerobically on a nonfermentable carbon source (succinate) but not anaerobically on rich medium containing glucose. These E. coli therefore had become obligate aerobes. The ability to grow anaerobically could be restored to the mutant complemented by atpD alone by growth at pH 7.5 or pH 8 in the presence of 0.1 M potassium.