Inactivation of the open reading frame slr0399 in Synechocystis sp. PCC 6803 functionally complements mutations near the Q(A) niche of photosystem II. A possible role of Slr0399 as a chaperone for quinone binding.

The Synechocystis sp. PCC 6803 triple mutant D2R8 with V247M/A249T/M329I mutations in the D2 subunit of the photosystem II is impaired in Q(A) function, has an apparently mobile Q(A), and is unable to grow photoautotrophically. Several photoautotrophic pseudorevertants of this mutant have been isolated, each of which retained the original psbDI mutations of D2R8. Using a newly developed mapping technique, the site of the secondary mutations has been located in the open reading frame slr0399. Two different nucleotide substitutions and a deletion of about 60% of slr0399 were each shown to restore photoautotrophy in different pseudorevertants of the mutant D2R8, suggesting that inactivation of Slr0399 leads to photoautotrophic growth in D2R8. Indeed, a targeted deletion of slr0399 restores photoautotrophy in D2R8 and in other psbDI mutants impaired in Q(A) function. Slr0399 is similar to the hypothetical protein Ycf39, which is encoded in the cyanelle genome of Cyanophora paradoxa; in the chloroplast genomes of diatoms, dinoflagellates, and red algae; and in the nuclear genome of Arabidopsis thaliana. Slr0399 and Ycf39 have a NAD(P)H binding motif near their N terminus and have some similarity to isoflavone reductase-like proteins and to a subunit of the eukaryotic NADH dehydrogenase complex I. Deletion of slr0399 in wild type Synechocystis sp. PCC 6803 has no significant phenotypic effects other than a decrease in thermotolerance under both photoautotrophic and photomixotrophic conditions. We suggest that Slr0399 is a chaperone-like protein that aids in, but is not essential for, quinone insertion and protein folding around Q(A) in photosystem II. Moreover, as the effects of Slr0399 are not limited to photosystem II, this protein may also be involved in assembly of quinones in other photosynthetic and respiratory complexes.     

Slr2013 is a novel protein regulating functional assembly of photosystem II in Synechocystis sp. strain PCC 6803

The Synechocystis sp. strain PCC 6803, which has a T192H mutation in the D2 protein of photosystem II, is an obligate photoheterotroph due to the lack of assembled photosystem II complexes. A secondary mutant, Rg2, has been selected that retains the T192H mutation but is able to grow photoautotrophically. Restoration of photoautotrophic growth in this mutant was caused by early termination at position 294 in the Slr2013 protein. The T192H mutant with truncated Slr2013 forms fully functional photosystem II reaction centers that differ from wild-type reaction centers only by a 30% higher rate of charge recombination between the primary electron acceptor, QA-, and the donor side and by a reduced stability of the oxidized form of the redox-active Tyr residue, YD, in the D2 protein. This suggests that the T192H mutation itself did not directly affect electron transfer components, but rather affected protein folding and/or stable assembly of photosystem II, and that Slr2013 is involved in the folding of the D2 protein and the assembly of photosystem II. Besides participation in photosystem II assembly, Slr2013 plays a critical role in the cell, because the corresponding gene cannot be deleted completely under conditions in which photosystem II is dispensable. Truncation of Slr2013 by itself does not affect photosynthetic activity of Synechocystis sp. strain PCC 6803. Slr2013 is annotated in CyanoBase as a hypothetical protein and shares a DUF58 family signature with other hypothetical proteins of unknown function. Genes for close homologues of Slr2013 are found in other cyanobacteria (Nostoc punctiforme, Anabaena sp. strain PCC 7120, and Thermosynechococcus elongatus BP-1), and apparent orthologs of this protein are found in Eubacteria and Archaea, but not in eukaryotes. We suggest that Slr2013 regulates functional assembly of photosystem II and has at least one other important function in the cell.     

Glu-69 of the D2 protein in photosystem II is a potential ligand to Mn involved in photosynthetic oxygen evolution

To probe the involvement of amino acid residues of the D2 protein in the water-splitting process in photosystem II, site-directed mutagenesis was applied to identify D2 residues that might contribute to binding the Mn cluster involved in oxygen evolution. Mutation of Glu-69 to Gln or Val in D2 of the cyanobacterium Synechocystis sp. PCC 6803 was found to lead to a loss of photoautotrophic growth. However, in cells of the Gln mutant (E69Q) a significant Hill reaction rate could be observed upon the start of illumination, but the oxygen evolution rate declined with a half-time of approximately 1 min. Addition of 1 mM Mn2+ stabilized oxygen evolution in E69Q thylakoids. Other divalent cations were ineffective in specific stabilization. When the water-splitting system was bypassed, the rate of electron transport remained stable during illumination, indicating that the inactivation of oxygen evolution is localized in the water-splitting complex. We interpret these observations to indicate that Glu-69 is a Mn ligand and that the loss of oxygen evolution in the E69Q mutant upon turnover of PS II is initiated by changes in the Mn cluster, possibly leading to Mn release from the water-splitting complex. The addition of exogenous Mn to E69Q thylakoids may help to keep the Mn cluster active for a longer time, perhaps by providing Mn to rebind in the cluster after release of one Mn and before the Mn cluster had disintegrated.(ABSTRACT TRUNCATED AT 250 WORDS)     

Deletion of PsbM in tobacco alters the QB site properties and the electron flow within photosystem II

Photosystem II, the oxygen-evolving complex of photosynthetic organisms, includes an intriguingly large number of low molecular weight polypeptides, including PsbM. Here we describe the first knock-out of psbM using a transplastomic, reverse genetics approach in a higher plant. Homoplastomic Delta psbM plants exhibit photoautotrophic growth. Biochemical, biophysical, and immunological analyses demonstrate that PsbM is not required for biogenesis of higher order photosystem II complexes. However, photosystem II is highly light-sensitive, and its activity is significantly decreased in Delta psbM, whereas kinetics of plastid protein synthesis, reassembly of photosystem II, and recovery of its activity are comparable with the wild type. Unlike wild type, phosphorylation of the reaction center proteins D1 and D2 is severely reduced, whereas the redox-controlled phosphorylation of photosystem II light-harvesting complex is reversely regulated in Delta psbM plants because of accumulation of reduced plastoquinone in the dark and a limited photosystem II-mediated electron transport in the light. Charge recombination in Delta psbM measured by thermoluminescence oscillations significantly differs from the 2/6 patterns in the wild type. A simulation program of thermoluminescence oscillations indicates a higher Q(B)/Q(-)(B) ratio in dark-adapted mutant thylakoids relative to the wild type. The interaction of the Q(A)/Q(B) sites estimated by shifts in the maximal thermoluminescence emission temperature of the Q band, induced by binding of different herbicides to the Q(B) site, is changed indicating alteration of the activation energy for back electron flow. We conclude that PsbM is primarily involved in the interaction of the redox components important for the electron flow within, outward, and backward to photosystem II.     

Molecular characterization of a novel gene from Synechocystis sp. PCC 6803

A novel gene slr2049 was identified in Synechococcus sp. PCC7002 by homologous alignment. The features and possible functions of slr2049 gene were predicted by bioinformatics analysis. The function of slr2049 was analyzed in vitro with a heterologous Escherichia coli system with plasmids conferring biosynthesis of phycocyanobilin (PCB) and of the acceptor proteins, β-phycocyanin (CpcB). The resulting products were evaluated with SDS-PAGE and absorption spectra. The function of slr2049 was further analyzed via site-directed mutations. Two mutants, slr2049 (W14L) and slr2049 (Y132S) were generated. The results showed that Slr2049 could catalyze the chromophorylation of CpcB. Compared to wild type, mutant Slr2049 (W14L) had red-shifted absorbance maxima and was not highly fluorescent as the wild-type. However, mutant Slr2049 (Y132S) was almost the same as the wild-type. In conclusion, our study suggests that we have cloned a novel gene and this gene may play an important role in attachment of the chromophores to the apo-proteins.     

Site-directed mutagenesis of glutamate residues in the large extrinsic loop of the photosystem II protein CP 43 affects oxygen-evolving activity and PS II assembly

The psbC gene encodes the intrinsic chlorophyll protein CP 43, a component of photosystem II in higher plants, green algae, and cyanobacteria. Oligonucleotide-directed mutagenesis was used to introduce mutations into the portion of psbC that encodes the large extrinsic loop E of CP 43 in the cyanobacterium Synechocystis 6803. Three mutations, E293Q, E339Q, and E352Q, each produced a strain with impaired photosystem II activity. The E293Q mutant strain grew photoautotrophically at rates comparable to the control strain. Immunological analyses of several PS II components indicated that this mutant accumulated normal quantities of PS II proteins. However, this mutant evolved oxygen to only 56% of control rates at saturating light intensities. Measurements of total variable fluorescence yield indicated that this mutant assembled approximately 60% of the fully functional PS II centers found in the control strain. The E339Q mutant grew photoautotrophically at a severely reduced rate. Both immunological analysis and variable fluorescence yield experiments indicated that E339Q assembled a normal complement of PS II centers. However, this mutant was capable of evolving oxygen to only 20% of control rates. Variable fluorescence yield experiments demonstrated that this mutant was inefficient at using water as an electron donor. Both E293Q and E339Q strains exhibited an increased (approximately 2-fold) sensitivity to photoinactivation. The E352Q mutant was the most severely affected. This mutant failed to grow photoautotrophically and exhibited essentially no capacity for oxygen evolution. Measurements of total variable fluorescence yield indicated that this mutant assembled no functional PS II centers. Immunological analysis of isolated thylakoid membranes from E352Q revealed a complete absence of CP 43 and reduced levels of both the D1 and manganese-stabilizing proteins. These results suggest that the mutations E293Q and E339Q each produce a defect associated with the oxygen-evolving complex of photosystem II. The E352Q mutation appears to affect the stability of the PS II complex. This is the first report showing that alteration of negatively charged residues in the CP 43 large extrinsic loop results in mutations affecting PS II assembly/function.     

Effects of inactivating psbM and psbT on photodamage and assembly of photosystem II in Synechocystis sp. PCC 6803

PsbM and PsbT have been assigned to electron densities on both photosystem II (PSII) monomers at the PSII dimer interface in X-ray crystallographic structures from Thermosynechoccocus elongatus and T. vulcanus. Our results show that removal of either or both proteins from Synechocystis sp. PCC 6803 resulted in photoautotrophic strains but the DeltaPsbM:DeltaPsbT mutant did not form stable dimers. A CP43-less PSII monomer accumulated in both single mutants, although absence of PsbT destabilized PSII to a greater extent than removing PsbM. Additionally, DeltaPsbT cells exhibited slowed electron transfer between the plastoquinone electron acceptors, Q(A) and Q(B); however, S-state cycling in both mutants was similar to wild type. Oxygen evolution in these mutants rapidly inactivated following exposure to high light where recovery required protein synthesis and could proceed in the dark in DeltaPsbM cells but required light in DeltaPsbT cells. Interestingly, the extent of recovery of oxygen-evolving activity was greatest in the DeltaPsbM:DeltaPsbT strain. We also found recovery required Psb27 in DeltaPsbT cells although, under our conditions, the DeltaPsb27 strain remained similar to wild type. In contrast, the DeltaPsbM:DeltaPsb27 mutant could not assemble PSII beyond a CP43-minus intermediate. Our results suggest essential roles for Psb27 in biogenesis in the DeltaPsbM strain and for repair from photodamage in cells lacking PsbT.     

Site-directed mutagenesis of the CP 47 protein of photosystem II: alteration of conserved charged residues which lie within lethal deletions of the large extrinsic loop E

The intrinsic chlorophyll-protein CP 47 is a component of photosystem II which functions in both light-harvesting and oxygen evolution. The large extrinsic loop E of this protein has been shown to interact with the oxygen-evolving site. Previously, Vermaas and coworkers have produced a number of deletions within loop E which yielded mutants which were unable to grow photoautotrophically and which could not evolve oxygen at normal rates. During the course of our site-directed mutagenesis program in Synechocystis 6803, we have altered all of the conserved charged residues which were present within six of these deletions. All ten of these mutants were photoautotrophic and evolved oxygen at normal rates. We speculate that the severe phenotypes of the deletion mutants observed by Vermaas and coworkers in due to large structural perturbations in the extrinsic loop E of CP 47.     

Arginine residues in the D2 polypeptide may stabilize bicarbonate binding in photosystem II of Synechocystis sp. PCC

Bicarbonate (HCO3-) causes a significant and reversible stimulation of anion-inhibited electron flow in photosystem II of higher plants and cyanobacteria. To test if selected arginine (Arg) residues are involved in the binding of HCO3-, we utilized oligonucleotide-directed mutagenesis to construct Synechocystis sp. PCC 6803 mutants carrying mutations in Arg residues in the D2 protein. Measurements of oxygen evolution showed that the D2 mutants R233Q (arginine-233----glutamine) and R251S (arginine-251----serine) were 10-fold more sensitive to formate than the wild type. The formate concentration giving half-maximal inhibition of the steady-state oxygen evolution rate was 48 mM, 4.5 mM and 4 mM for the wild type, R233Q and R251S, respectively. Measurements of oxygen evolution in single-turnover flashes confirm that the mutants are more sensitive to formate than the wild type. Measurements of chlorophyll a fluorescence decay kinetics after the second saturating actinic flash indicated that, after formate treatment, the halftime of QA- oxidation was decreased by approximately a factor of 2, 4 and 6 in the wild type, R251S and R233Q, respectively. The recombination rate between QA- and S2 was approx. 2-fold slower in R251S and R233Q than in the wild type. In the presence of 100 mM sodium formate, reactivation of the Hill reaction by bicarbonate showed that the wild type had an apparent Km for bicarbonate of 0.5 mM, while the Km values for R233Q and R251S were 1.4 and 1.5 mM, respectively. We suggest that Arg-233 and Arg-251 in the D2 polypeptide contribute to stabilization of HCO3- binding in Photosystem II.     

Changes in structural and functional properties of oxygen-evolving complex induced by replacement of D1-glutamate 189 with glutamine in photosystem II: ligation of glutamate 189 carboxylate to the manganese cluster

A carboxylate group of D1-Glu-189 in photosystem II has been proposed to serve as a direct ligand for the manganese cluster. Here we constructed a mutant that eliminates the carboxylate by replacing D1-Glu-189 with Gln in the cyanobacterium Synechocystis sp. PCC 6803, and we examined the resulting effects on the structural and functional properties of the oxygen-evolving complex (OEC) in photosystem II. The E189Q mutant grew photoautotrophically, and isolated photosystem II core particles evolved oxygen at approximately 70% of the rate of control wild-type particles. The E189Q OEC showed typical S(2) state electron spin resonance signals, and the spin center distance between the S(2) state manganese cluster and the Y(D) (D2-Tyr-160), detected by electron-electron double resonance spectroscopy, was not affected by this mutation. However, the redox potential of the E189Q OEC was considerably lower than that of the control OEC, as revealed by the elevated peak temperature of the S(2) state thermoluminescence bands. The mutation resulted in specific changes to bands ascribed to the putative carboxylate ligands for the manganese cluster and to a few carbonyl bands in mid-frequency (1800 to 1100 cm(-1)) S(2)/S(1) Fourier transform infrared difference spectrum. Notably, the low frequency (650 to 350 cm(-1)) S(2)/S(1) Fourier transform infrared difference spectrum was also uniquely changed by this mutation in the frequencies for the manganese cluster core vibrations. These results suggested that the carboxylate group of D1-Glu-189 ligates the manganese ion, which is influenced by the redox change of the oxidizable manganese ion upon the S(1) to S(2) transition.     

Slr1122影响Hik12磷酸化并参与调节Synechocystis sp.PCC 6803的色素合成

Synechocystis sp.PCC 6803是一种良好的研究光合作用的模式生物,其中slr1122编码一个250个氨基酸的未知蛋白。据报道Slr1122可能与杂合传感激酶（hybrid sensory kinase）Sll1672（Hik12）相互作用,本研究通过复合物实验证实了Slr1122与Sll1672确实存在相互作用。利用32P标记证明,在加入Slr1122后Hik12的磷酸化受到了明显的影响,推测其可能参与该双组分系统的调控。通过同源双交换,用卡那霉素抗性基因替换slr1122,将slr1122从Synechocystis sp.PCC 6803中敲除,构建了slr1122的缺失体Δslr1122。研究发现在Δslr1122中,编码PSⅡ中核心蛋白D1亚基的slr1181（psbAI）的转录水平明显降低,使PSⅡ光合作用受到影响,导致Δslr1122的生长速率低于野生型（WT）。同时slr1122的缺失使得蓝细菌对光的敏感性增强,在弱光条件下,Δslr1122对光能的利用效率高于WT,其生长速率也较WT高,但与此相反,Δslr1122对强光的耐受力及生长速率则不及WT。Δslr1122体内的藻胆蛋白含量与色素含量均降低,尤其是类胡萝卜素,RT-PCR的结果也显示合成类胡萝卜素过程中的5个关键酶转录水平均下降。这可能是Δslr1122对氧化胁迫变得敏感的原因之一。总之,Slr1122影响杂合传感激酶Hik12磷酸化并参与调节Synechocystis sp.PCC 6803的光合色素合成。     

Influence of histidine-198 of the D1 subunit on the properties of the primary electron donor, P680, of photosystem II in Thermosynechococcus elongatus

The influence of the histidine axial ligand to the PD1 chlorophyll of photosystem II on the redox potential and spectroscopic properties of the primary electron donor, P680, was investigated in mutant oxygen-evolving photosystem II (PSII) complexes purified from the thermophilic cyanobacterium Thermosynechococcus elongatus. To achieve this aim, a mutagenesis system was developed in which the psbA1 and psbA2 genes encoding D1 were deleted from a His-tagged CP43 strain (to generate strain WT*) and mutations D1-H198A and D1-H198Q were introduced into the remaining psbA3 gene. The O2-evolving activity of His-tagged PSII isolated from WT* was found to be significantly higher than that measured from His-tagged PSII isolated from WT in which psbA1 is expected to be the dominantly expressed form. PSII purified from both the D1-H198A and D1-H198Q mutants exhibited oxygen-evolving activity as high as that from WT*. Surprisingly, a variety of kinetic and spectroscopic measurements revealed that the D1-H198A and D1-H198Q mutations had little effect on the redox and spectroscopic properties of P680, in contrast to the earlier results from the analysis of the equivalent mutants constructed in Synechocystis sp. PCC 6803 [B.A. Diner, E. Schlodder, P.J. Nixon, W.J. Coleman, F. Rappaport, J. Lavergne, W.F. Vermaas, D.A. Chisholm, Site-directed mutations at D1-His198 and D2-His197 of photosystem II in Synechocystis PCC 6803: sites of primary charge separation and cation and triplet stabilization, Biochemistry 40 (2001) 9265-9281]. We conclude that the nature of the axial ligand to PD1 is not an important determinant of the redox and spectroscopic properties of P680 in T. elongatus.     

Targeted random mutagenesis to identify functionally important residues in the D2 protein of photosystem II in Synechocystis sp. strain PCC 6803

To identify important residues in the D2 protein of photosystem II (PSII) in the cyanobacterium Synechocystis sp. strain PCC 6803, we randomly mutagenized a region of psbDI (coding for a 96-residue-long C-terminal part of D2) with sodium bisulfite. Mutagenized plasmids were introduced into a Synechocystis sp. strain PCC 6803 mutant that lacks both psbD genes, and mutants with impaired PSII function were selected. Nine D2 residues were identified that are important for PSII stability and/or function, as their mutation led to impairment of photoautotrophic growth. Five of these residues are likely to be involved in the formation of the Q(A)-binding niche; these are Ala249, Ser254, Gly258, Ala260, and His268. Three others (Gly278, Ser283, and Gly288) are in transmembrane alpha-helix E, and their alteration leads to destabilization of PSII but not to major functional alterations of the remaining centers, indicating that they are unlikely to interact directly with cofactors. In the C-terminal lumenal tail of D2, only one residue (Arg294) was identified as functionally important for PSII. However, from the number of mutants generated it is likely that most or all of the 70 residues that are susceptible to bisulfite mutagenesis have been altered at least once. The fact that mutations in most of these residues have not been picked up by our screening method suggests that these mutations led to a normal photoautotrophic phenotype. A novel method of intragenic complementation in Synechocystis sp. strain PCC 6803 was developed to facilitate genetic analysis of psbDI mutants containing several amino acid changes in the targeted domain. Recombination between genome copies in the same cell appears to be much more prevalent in Synechocystis sp. strain PCC 6803 than was generally assumed.     

Leucine 245 is a critical residue for folding and function of the manganese stabilizing protein of photosystem II

In solution, Manganese Stabilizing Protein, the polypeptide which is responsible for the structural and functional integrity of the manganese cluster in photosystem II, is a natively unfolded protein with a prolate ellipsoid shape [Lydakis-Simantiris et al. (1999) Biochemistry 38, 404-414; Zubrzycki et al. (1998) Biochemistry 37, 13553-13558]. The C-terminal tripeptide of Manganese Stabilizing Protein was shown to be critical for binding to photosystem II and restoration of O(2) evolution activity [Betts et al. (1998) Biochemistry 37, 14230-14236]. Here, we report new biochemical, hydrodynamic, and spectroscopic data on mutants E246K, E246STOP, L245E, L245STOP, and Q244STOP. Truncation of the final dipeptide (E246STOP) or substitution of Glu246 with Lys resulted in no significant changes in secondary and tertiary structures of Manganese Stabilizing Protein as monitored by CD spectroscopy. The apparent molecular mass of the protein remained unchanged, both mutants were able to rebind to photosystem II, and both proteins reactivate O(2) evolution. Manganese Stabilizing Protein lacking the final tripeptide (L245STOP), or substitution of Glu for Leu245 dramatically modified the protein's solution structure. The apparent molecular masses of these mutants increased significantly, which might indicate unfolding of the protein in solution. This was verified by CD spectroscopy. Both mutant proteins rebound to photosystem II with lower affinities, and activation of O(2) evolution was decreased dramatically. Enhancement of these defects was observed upon removal of the final tetrapeptide (Q244STOP). These results indicate that Leu245 is essential to maintaining Manganese Stabilizing Protein's solution structure in a conformation that promotes efficient binding to photosystem II and/or for the subsequent steps that lead to enzyme activation. Based on an analysis of the properties of C-terminal mutations, a hypothesis for structural requirements for functional binding of Manganese Stabilizing Protein to photosystem II is presented. Effects of C-terminal mutations on the UV spectrum of Manganese Stabilizing Protein were also examined. Mutations that alter solution structure also affect a 293 nm absorption shoulder which is assigned to the only tryptophan residue, Trp241, in the protein, and this absorbance feature is shown to be a useful indicator of alterations to the Trp241 environment.     

PsbQ (Sll1638) in Synechocystis sp. PCC 6803 is required for photosystem II activity in specific mutants and in nutrient-limiting conditions

A PsbQ homologue has been found associated with photosystem II complexes in Synechocystis sp. PCC 6803 where it is involved in optimal photoautotrophic growth and water splitting under CaCl(2)-depleted conditions [Thornton, L. E., Ohkawa, H., Roose, J. L., Kashino, Y., Keren, N., and Pakrasi, H. B. (2004) Plant Cell 16, 2164-2175]. By inactivating psbQ in strains carrying photosystem II-specific mutations, we have identified stringent requirements for PsbQ in vivo. Whereas under nutrient-replete conditions the DeltaPsbQ mutant was similar to wild type, a strain lacking PsbQ and PsbV was not photoautotrophic, exhibiting decreased oxygen evolution and decreased photosystem II assembly compared to the DeltaPsbV mutant. Combining the removal of PsbU and PsbQ introduced an altered requirement for Ca(2+) and Cl(-), and photoautotrophic growth of the DeltaPsbQ strain was prevented in nutrient-limiting media depleted in Ca(2+), Cl(-), and iron. Unlike other photosystem II extrinsic proteins PsbQ did not participate in the acquisition of thermotolerance; however, photoautotrophic growth at elevated temperatures was impaired in this mutant. Growth of the DeltaPsbV:DeltaPsbQ mutant was restored at pH 10.0: in contrast, an additional deletion between Arg-384 and Val-392 in the CP47 protein of photosystem II prevented recovery at alkaline pH. When conditions prevented photoautotrophy in strains lacking PsbQ, photoheterotrophic growth was indistinguishable to wild type, indicating that photosystem II had been inactivated. These data substantiate a role for PsbQ in optimizing photosystem II activity in Synechocystis sp. PCC 6803 and establish an absolute requirement for the subunit under specific biochemical and physiological conditions.     

Random chemical mutagenesis of a specific psbDI region coding for a lumenal loop of the D2 protein of photosystem II in Synechocystis sp. PCC 6803

To identify amino acid residues of the D2 protein that are critical for functional photosystem II (PS II), sodium bisulfite was utilized for in vitro random mutagenesis of the psbDI gene from Synechocystis sp. PCC 6803. Sodium bisulfite reacts specifically with cytosine in single-stranded regions of DNA and does not attack double-stranded DNA. Using a hybrid plasmid that was single-stranded in the region to be mutagenized and that was double-stranded elsewhere, mutations were targeted to a specific psbDI region coding for the lumenal A-B loop of the D2 protein. Several mutants were isolated with a total of 15 different amino acid changes in the loop. The majority of these mutations did not result in a loss of photoautotrophic growth or in significantly altered PS II function. However, mutation of Glu-69 to Lys, Ser-79 to Phe, and Ser-88 to Phe were found to influence photosystem II activity; the importance of the latter two residues for proper PS II function was unexpected. Cells carrying the double mutation S79F/S88F in D2 did not grow photoautotrophically and had no functionally active PS II centers. The single mutant S79F was also incapable of photoautrophic growth, but displayed reasonably stable oxygen evolution, while PS II function in the single mutant S88F appeared to be close to normal. Because of the more pronounced phenotype of the S79F/S88F strain as compared to the single mutants, both Ser residues appear to affect stable assembly and function of the PS II complex. The mechanism by which the S79F mutant loses photoautotrophic growth remains to be established. However, these results show the potential of targeted random mutagenesis to identify functionally important residues in selected regions of proteins.     

Insertional inactivation of the gene encoding subunit II of photosystem I from the cyanobacterium Synechocystis sp. PCC 6803

The cyanobacterium Synechocystis sp. PCC 6803 carries out oxygenic photosynthesis analogous to higher plants. Its photosystem I contains seven different polypeptide subunits. The cartridge mutagenesis technique was used to inactivate the psaD gene which encodes subunit II of photosystem I. A mutant strain lacking subunit II was generated by transforming wild type cells with cloned DNA in which psaD gene was interrupted by a gene conferring kanamycin resistance. The photoautotrophic growth of mutant strain is much slower than that of wild type cells. The membranes prepared from mutant cells lack subunit II of photosystem I. Studies on the purified photosystem I reaction center revealed that the complex lacking subunit II is assembled and is functional in P700 photooxidation but at much reduced rate. Therefore, subunit II of photosystem I is required for efficient function of photosystem I.     

Identification of a cyanobacterial CRR6 protein,Slr1097, required for efficient assembly of NDH‐1 complexes in Synechocystis sp. PCC 6803

Despite significant progress in clarifying the subunit compositions and functions of the multiple NADPH dehydrogenase (NDH‐1) complexes in cyanobacteria, the subunit maturation and assembly of their NDH‐1 complexes are poorly understood. By transformation of wild‐type cells with a transposon‐tagged library, we isolated three mutants of Synechocystis sp. PCC 6803 defective in NDH‐1‐mediated cyclic electron transfer and unable to grow under high light conditions. All the mutants were tagged in the same slr1097 gene, encoding an unknown protein that shares significant homology with the Arabidopsis protein chlororespiratory reduction 6 (CRR6). The slr1097 product was localized in the cytoplasm and was required for efficient assembly of NDH‐1 complexes. Analysis of the interaction of Slr1097 with 18 subunits of NDH‐1 complexes using a yeast two‐hybrid system indicated a strong interaction with NdhI but not with other Ndh subunits. Absence of Slr1097 resulted in a significant decrease of NdhI in the cytoplasm, but not of other Ndh subunits including NdhH, NdhK and NdhM; the decrease was more evident in the cytoplasm than in the thylakoid membranes. In the ?slr1097 mutant, NdhH, NdhI, NdhK and NdhM were hardly detectable in the NDH‐1M complex, whereas almost half the wild‐type levels of these subunits were present in NDH‐1L complex; similar results were observed in the NdhI‐less mutant. These results suggest that Slr1097 is involved in the maturation of NdhI, and that assembly of the NDH‐1M complex is strongly dependent on this factor. Maturation of NdhI appears not to be crucial to assembly of the NDH‐1L complex.     

蓝细菌PCC6803染色体上的毒素蛋白Slr0664与抗毒素蛋白Ssr1114的相互作用

【目的】证明蓝细菌PCC6803染色体上的毒素-抗毒素系统(TA,toxin-antitoxin system)ssr1114/slr0664中毒素蛋白Slr0664与抗毒素蛋白Ssr1114之的相互作用。【方法】构建在大肠杆菌(Escherichia coli)BL21(DE3)中诱导表达H6-Ssr1114或共表达H6-Ssr1114和Slr0664的重组质粒,诱导表达后借助亲和捕捉技术在不同的条件下纯化H6-Ssr1114或共纯化重组蛋白H6-Ssr1114和Slr0664,并通过肽谱分析共纯化的重组蛋白,证明H6-Ssr1114与Slr0664之间存在相互作用。【结果】诱导Slr0664表达对细胞产生毒性作用导致生长抑制或细胞死亡,诱导H6-Ssr1114和Slr0664共表达时细胞能能正常生长,在非变性条件下可纯化共表达的重组蛋白H6-Ssr1114和Slr0664,在变性条件下仅H6-Ssr1114被纯化,肽谱分析结果表明共纯化的的重组蛋白为H6-Ssr1114和Slr0664。【结论】ssr1114/slr0664TA系统中抗毒素蛋白Ssr1114与毒素蛋白Slr0664之间存在相互作用。