Regulation of Anabaena sp. strain PCC 7120 glutamine synthetase activity in a Synechocystis sp. strain PCC 6803 derivative strain bearing the Anabaena glnA gene and a mutated host glnA gene.

The glnA gene from Synechocystis sp. strain PCC 6803 was cloned by hybridization with the glnA gene from Anabaena sp. strain PCC 7120, and a deletion-insertion mutation of the Synechocystis gene was generated in vitro. A strain derived from Synechocystis sp. strain PCC 6803 which contained integrated into the chromosome, in addition to its own glnA gene, the Anabaena glnA gene was constructed. From that strain, a Synechocystis sp. glnA mutant could be obtained by transformation with the inactivated Synechocystis glnA gene; this mutant grew by using Anabaena glutamine synthetase and was not a glutamine auxotroph. A Synechocystis sp. glnA mutant could not be obtained, however, from the wild-type Synechocystis sp. The Anabaena glutamine synthetase enzyme was subject to ammonium-promoted inactivation when expressed in the Synechocystis strain but not in the Anabaena strain itself.     

Structure and expression of a cyanobacterial ilvC gene encoding acetohydroxyacid isomeroreductase.

Acetohydroxyacid isomeroreductase (AHAIR) is the shared second enzyme in the biosynthetic pathways leading to isoleucine and valine. AHAIR is encoded by the ilvC gene in bacteria. A 1,544-bp fragment of genomic DNA containing the ilvC gene was cloned from the cyanobacterium Synechocystis sp. strain PCC 6803, and the complete nucleotide sequence was determined. The identity of the gene was established by comparison of the nucleotide and derived peptide sequences with those of other ilvC genes. The highest degree of sequence similarity was found with the ilvC gene from Rhizobium meliloti. The isolated Synechocystis ilvC gene complemented an Escherichia coli ilvC mutant lacking AHAIR activity. The expressed Synechocystis gene encodes a protein that has a molecular mass of 35.7 kDa and that has AHAIR activity in an in vitro assay. Polyclonal antibodies raised against purified Synechocystis AHAIR produced a single band on a Western blot (immunoblot) of a Synechocystis cell extract and detected the protein in an extract of an E. coli ilvC mutant strain that was transformed with a plasmid containing the Synechocystis ilvC gene. The antibody did not react with an extract of an E. coli ilvC mutant strain that was transformed with a control plasmid lacking the Synechocystis ilvC gene or with an extract of an E. coli IlvC+ control strain.     

“Self-Feeding” Strain of Salmonella typhimurium with a Mutation in the trpB Gene and Nutritional Requirements of trpA Gene Mutants

An indole-requiring (Ind(-)) mutant of Salmonella typhimurium, isolated from a culture of a leaky trpA mutant, was genetically analyzed by P22-mediated transduction. The mutation site giving the Ind(-) phenotype was shown to be in trpB, the second gene of the trp operon. A second mutation at this site resulted in change of nutritional requirement from indole to anthranilic acid (Anth(-)). This phenotype is normally associated with mutations in the first trp gene, trpA. However, the Anth(-) mutant also excreted anthranilic acid and showed "self-feeding" on unsupplemented media. Of two possible explanations for this aberrant phenotype, the first, that the trpB mutations may be in the "unusual" region, was dismissed on genetic evidence and on the biochemical evidence that an active anthranilate synthetase (AS) is produced. The alternative explanation, that the affected enzymatic activity, phosphoribosyl transferase, is unstable in vivo, but its AS component 2 activity is stable, is considered more probable.     

Nucleotide sequences and genomic constitution of five tryptophan genes of Lactobacillus casei

Five trp genes, trpD, trpC, trpF, trpB, and trpA, of Lactobacillus casei were cloned by transformation of tryptophan auxotrophic mutants of the respective trp genes in Escherichia coli. These trp genes appear to constitute an operon and are located in the above order in a segment of DNA of 6,468 base pairs. The entire nucleotide sequence of this DNA segment was determined. Five contiguous open reading frames in this segment can encode proteins consisting of 341, 260, 199, 406, and 266 amino acids, respectively, in the same direction. The amino acid sequences of these proteins exhibit 25.5-50.2% homology with the amino acid sequences of the corresponding trp enzymes of E. coli. Two trp genes, trpC and trpF, from L. casei can complement mutant alleles of the corresponding genes of E. coli. However, neither the trpA gene nor the trpB gene of L. casei can complement mutations in the E. coli trpA gene and the trpB gene, respectively, suggesting that the protein products of the L. casei and E. coli trpA and trpB genes, respectively, cannot form heterodimers of tryptophan synthetase with activity. Other features of the coding and flanking regions of the trp genes are also described.     

Restoration of Phosphoribosyl Transferase Activity by Partially Deleting the trpB Gene in the Tryptophan Operon of Salmonella typhimurium

The amber mutant trpA28, which contains a mutation mapping within the so-called "unusual" region of the tryptophan (trp) operon of Salmonella typhimurium (between the genes trpA and trpB), lacks both components of the anthranilate synthetase (AS)-phosphoribosyl transferase (PRT) enzyme complex, the products of the genes trpA and trpB, respectively. Twenty-six revertants of this mutant selected on minimal medium supplemented with anthranilic acid, a substrate of PRT, contain deletions of various segments of the "unusual" region and make a species of PRT different in every respect from the wild-type, dissociated form of this enzyme. The results indicate that the unusual region corresponds to the operator proximal end of the trpB gene. Mutants in the unusual region, however, show unexpectedly low levels of AS activity and in two cases (trpA515 and trpA28) no detectable activity of this enzyme component.     

The rpaC gene product regulates phycobilisome-photosystem II interaction in cyanobacteria

State transitions in cyanobacteria are a physiological adaptation mechanism that changes the interaction of the phycobilisomes with the Photosystem I and Photosystem II core complexes. A random mutagenesis study in the cyanobacterium Synechocystis sp. PCC6803 identified a gene named rpaC which appeared to be specifically required for state transitions. rpaC is a conserved cyanobacterial gene which was tentatively suggested to code for a novel signal transduction factor. The predicted gene product is a 9-kDa integral membrane protein. We have further examined the role of rpaC by overexpressing the gene in Synechocystis 6803 and by inactivating the ortholog in a second cyanobacterium, Synechococcus sp. PCC7942. Unlike the Synechocystis 6803 null mutant, the Synechococcus 7942 null mutant is unable to segregate, indicating that the gene is essential for cell viability in this cyanobacterium. The Synechocystis 6803 overexpressor is also unable to segregate, indicating that the cells can only tolerate a limited gene copy number. The non-segregated Synechococcus 7942 mutant can perform state transitions but shows a perturbed phycobilisome-Photosystem II interaction. Based on these results, we propose that the rpaC gene product controls the stability of the phycobilisome-Photosystem II supercomplex, and is probably a structural component of the complex.     

Cloning of the psbK gene from Synechocystis sp. PCC 6803 and characterization of photosystem II in mutants lacking PSII-K

We cloned and sequenced the psbK gene, coding for a small photosystem II component (PSII-K), from the transformable cyanobacterium, Synechocystis sp. PCC 6803, and determined the N-terminal sequence of mature PSII-K. The psbK gene product is processed by cleaving off eight amino acid residues from the N terminus. A mutant lacking psbK was constructed; this mutant grew photoautotrophically, but its growth rate was reduced. The number of photosystem II reaction centers on a chlorophyll basis was decreased by less than a factor of 2 in the psbK-deletion mutant. In Synechocystis sp. PCC 6803, the psbK gene is transcribed as a single gene and is not part of an operon. Single-site mutations were introduced into psbK leading to early termination or deletion of the presequence. The phenotype of these mutants strongly resembles that of the psbK deletion mutant, indicating that indeed the change in phenotype in the deletion mutant is directly correlated with PSII-K. PSII-K is not essential for photosystem II assembly or activity but is needed for optimal photosystem II function.     

人肝金属硫蛋白突变体β基因通过同源重组在蓝藻中的克隆与表达

将人肝金属硫蛋白（ＭＴ）突变体β基因插入到中间载体ｐＲＬ－４３９上的强启动子ＰｐｓｂＡ 下游,利用载体ｐＲＬ－β上的ＰｐｓｂＡ 和β基因与ｐｈａｓｍ ｉｄ ｐＴＺ１８－８上整合平台ＰｓｂＢ,构建整合表达载体ｐＴＺ－β．整合平台ＰｓｂＢ与集胞藻（Ｓｙｎｅｃｈｏｃｙｓｔｉｓｓｐ．ＰＣＣ６８０３）染色体ＤＮＡ 上ｐｓｂＢ基因下游片段为同源序列．为了发生单交换同源重组,将外源基因β插入到整合平台ＰｓｂＢ下游的克隆位点．利用自然转化方法将表达载体ｐＴＺ－β整合到Ｓｙｎｅｃｈｏｃｙｓｔｉｔｓｐ．ＰＣＣ６８０３的染色体上．经氨苄青霉素筛选得到遗传性状稳定的转基因蓝藻．Ｓｏｕｔｈｅｒｎ ｂｌｏｔｔｉｎｇ 证明β基因已整合到Ｓｙｎｅｃｈｏｃｙｓｔｉｓ ｓｐ．ＰＣＣ６８０３的染色体上;Ｗｅｓｔｅｒｎ ｂｌｏｔｔｉｎｇ 表明β基因已在蓝藻中表达．ＥＬＩＳＡ 测定在Ｚｎ２＋ 浓度为１５０ μｍ ｌ／Ｌ时表达量最高,为５９０ μｇ／ｇ 鲜藻;原子吸收表明转β基因的藻对Ｚｎ２＋ 的富集能力约为野生型的２倍．     

集胞藻PCC6803膜脂循环关键基因酶学性质和生理功能

集胞藻PCC6803野生型和其脂酰ACP合酶敲除突变株的自由脂肪酸含量和组成表明膜脂的重构和降解是细胞内自由脂肪酸的来源之一。在这一过程中脂肪酶起到关键性作用。通过基因组数据库检索,发现集胞藻PCC6803基因组中只有一个脂肪酶编码基因sll1969,但是还没有其功能相关的生化证据。为了确定该基因的功能及其在脂肪酸代谢途径中的作用,加深对集胞藻PCC6803脂肪酸代谢途径的了解,文中将sll1969基因在大肠杆菌中过表达和体外纯化,得到重组蛋白Sll1969,并对其酶学性质进行初步分析。在30℃条件下,测得Sll1969以对硝基苯丁酸酯作为底物时的Km和kcat值分别为(1.16±0.01)mmol/L和(332.8±10.0)/min;该脂肪酶的最适反应温度为55℃。通过比较分析sll1969突变株中脂肪酸含量和组成变化,发现sll1969的表达量与细胞自由脂肪酸的产量呈正相关,但Sll1969不是细胞中唯一的脂肪酶。     

DNA photolyase homologs are the major UV resistance factors in the cyanobacterium Synechocystis sp. PCC 6803

In this study, the unicellular photosynthetic cyanobacterium Synechocystis sp. PCC 6803 was used as a model phototroph to study the contribution of enzymatic photoreactivation to the overall protection against UV irradiation. We have isolated genes encoding two DNA photolyase homologs, phrA and phrB, from Synechocystis 6803. phrA encodes an 8-hydroxy-5-deazariboflavin (HDF) type, Class I DNA photolyase. By complementing a photolyase-deficient mutant strain of Escherichia coli, we demonstrated that PhrA is a DNA photolyase. Analysis of a phrA knockout mutant strain suggested that this gene is responsible for the majority of the observed UV resistance in Synechocystis 6803. Similar studies on phrB demonstrated that it also contributes to photoreactivation, but to a much lesser degree. Based on these findings, we conclude that enzymatic photoreactivation is the primary process used for repairing UV-induced damage in Synechocystis 6803.     

Molecular cloning and targeted mutagenesis of the gene psaF encoding subunit III of photosystem I from the cyanobacterium Synechocystis sp. PCC 6803

Photosystem I is one of the two multisubunit pigment-protein complexes in the thylakoid membranes of cyanobacteria. Subunit III of photosystem I complex was isolated from a mutant of the cyanonbacterium Synechocystis sp PCC 6803, which lacks subunit II. The sequence of its NH2-terminal residues was determined and corresponding oligonucleotide probes were used to isolate the gene encoding this subunit. The gene, designated as psaF, codes for a mature protein of 15705 Da that is synthesized with a 23-amino acid extension. The deduced amino acid sequence is homologous to subunit III from spinach and Chlamydomonas reinhardtii. The presequence of subunit III shows characteristics typical of bacterial presequences and exhibits remarkable amino acid identity around the proteolytic processing site when compared to corresponding regions from the precursors of eukaryotic subunit III. There are two conserved hydrophobic regions in the mature subunit III which may cross or interact with thylakoid membrane. The gene psaF exists as a single copy in the genome and is expressed as a monocistronic RNA. A stable mutant strain in which the gene psaF was replaced by a gene conferring resistance to kanamycin was generated by targeted mutagenesis. Photoautotrophic growth of the mutant strain was comparable with that of the wild type suggesting that function of subunit III is dispensable for photosynthesis in Synechocystis sp. PCC 6803. Addition of more MgSO4 to BG11 medium enhanced growth of the mutant strain but not of the wild type cells.     

Sucrose accumulation in salt-stressed cells of agp gene deletion-mutant in cyanobacterium Synechocystis sp PCC 6803

The agp gene encoding the ADP-glucose pyrophosphorylase is involved in cyanobacterial glycogen synthesis and glucosylglycerol formation. By in vitro DNA recombination technology, a mutant with partial deletion of agp gene in the cyanobacterium Synechocystis sp. PCC 6803 was constructed. This mutant could not synthesize glycogen or the osmoprotective substance glucosylglycerol. In the mutant cells grown in the medium containing 0.9 M NaCl for 96 h, no glucosylglycerol was detected and the total amount of sucrose was 29 times of that of in wild-type cells. Furthermore, the agp deletion mutant could tolerate up to 0.9 M salt concentration. Our results suggest that sucrose might act as a similar potent osmoprotectant as glucosylglycerol in cyanobacterium Synechocystis sp. PCC 6803.     

Site-directed mutagenesis of the CPa-1 protein of photosystem II: alteration of the basic residue pair 384,385R to 384,385G leads to a defect associated with the oxygen-evolving complex.

The psbB gene encodes the intrinsic chlorophyll-a binding protein CPa-1 (CP-47), a component of photosystem II in higher plants, algae, and cyanobacteria. Oligonucleotide-directed mutagenesis was used to introduce mutations into a segment of the psbB gene encoding the large extrinsic loop region of CPa-1 in the cyanobacterium Synechocystis sp. PCC 6803. Altered psbB genes were introduced into a mutant recipient strain (DEL-1) of Synechocystis in which the genomic psbB gene had been partially deleted. Initial target sites for mutagenesis were absolutely conserved basic residue pairs occurring within the large extrinsic loop. One mutation, RR384385GG, produced a strain with impaired photosystem II activity. This strain exhibited growth characteristics comparable to controls. However, at saturating light intensities this mutant strain evolved oxygen at only 50% of the rate of the control strains. Quantum yield measurements at low light intensities indicated that the mutant had 30% fewer fully functional photosystem II centers than do control strains of Synechocystis. Immunological analysis of a number of photosystem II protein components indicated that the mutant accumulates normal quantities of photosystem II proteins and that the ratio of photosystem II to photosystem I proteins is comparable to that found in control strains. Upon exposure to high light intensities the mutant cells exhibited a markedly increased susceptibility to photoinactivation. However, Tris-treated thylakoid membranes from both the mutant and wild-type exhibited comparable rates of photoinactivation. Thylakoid membranes isolated from RR384385GG exhibited only 15% of the H2O to 2,6-dichlorophenolindophenol electron transport rate observed in wild-type strains.(ABSTRACT TRUNCATED AT 250 WORDS)     

Ordering tryptophan synthase genes of Pseudomonas aeruginosa by cloning in Escherichia coli.

The Pseudomonas aeruginosa tryptophan synthase genes, trpA and trpB, which are induced by their substrate indoleglycerol phosphate, were cloned along with their controlling region into the BamHI site of pBR322 to produce the 10.7-megadalton plasmid pZAZ5. SalI partial digestion and ligation yielded a smaller plasmid, pZAZ167, with the chromosomal insert reduced in size from 8.1 to 3.4 megadaltons. Both pZAZ5 and pZAZ167 display Pseudomonas-like regulation of the trpA and trpB genes. Deletion of an EcoRI fragment or a BglII fragment from pZAZ167 yielded plasmids pZAZ168 and pZAZ169; the former expresses trpB but not trpA, and the latter has lost both activities. A deleted form of pZAZ5 designated pZAZ101 was obtained by excising a BglII-BamHI segment and religating the trip gene segment in the opposite orientation. This plasmid expresses trpA and trpB constitutively. The physical maps of these plasmids establish the gene order: promoter-trpB-trpA.