Targeted Random Mutagenesis To Identify Functionally Important Residues in the D2 Protein of Photosystem II in Synechocystis sp. Strain PCC 6803

doi:10.1128/JB.183.1.145-154.2001

This Article

	Abstract
	Full Text (PDF)
	Alert me when this article is cited
	Alert me if a correction is posted

Services

	Similar articles in this journal
	Similar articles in PubMed
	Alert me to new issues of the journal
	Download to citation manager
	Reprints and Permissions
	Copyright Information
	Books from ASM Press
	MicrobeWorld

Citing Articles

	Citing Articles via HighWire
	Citing Articles via Google Scholar

Google Scholar

	Articles by Ermakova-Gerdes, S.
	Articles by Vermaas, W.
	Search for Related Content

PubMed

	PubMed Citation
	Articles by Ermakova-Gerdes, S.
	Articles by Vermaas, W.

Journal of Bacteriology, January 2001, p. 145-154, Vol. 183, No. 1
0021-9193/01/$04.00+0 DOI: 10.1128/JB.183.1.145-154.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.

Targeted Random Mutagenesis To Identify Functionally Important Residues in the D2 Protein of Photosystem II in Synechocystis sp. Strain PCC 6803

Svetlana Ermakova-Gerdes, Zhenbao Yu, and Wim Vermaas^*

Department of Plant Biology and Center for the Study of Early Events in Photosynthesis, Arizona State University, Tempe, Arizona 85287-1601

Received 30 May 2000/Accepted 3 October 2000

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

To identify important residues in the D2 protein of photosystem II (PSII) in the cyanobacterium Synechocystis sp. strain PCC6803, we randomly mutagenized a region of psbDI (coding for a96-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 mutantswith impaired PSII function were selected. Nine D2 residues wereidentified 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 formationof 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 PSIIbut 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, fromthe number of mutants generated it is likely that most or allof the 70 residues that are susceptible to bisulfite mutagenesishave been altered at least once. The fact that mutations in mostof these residues have not been picked up by our screening methodsuggests that these mutations led to a normal photoautotrophicphenotype. A novel method of intragenic complementation in Synechocystissp. strain PCC 6803 was developed to facilitate genetic analysisof psbDI mutants containing several amino acid changes in thetargeted domain. Recombination between genome copies in the samecell appears to be much more prevalent in Synechocystis sp. strainPCC 6803 than was generallyassumed.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

Remarkable progress has been made toward the understanding of the molecular mechanism of electron transfer in the photosystemII (PSII) complex, which catalyzes the light-induced reductionof plastoquinone by water in organisms capable of oxygenic photosynthesis(for reviews, see references 6, 24 and 38). To a largeextent, this has been due to the elucidation by X-ray crystallographyof the three-dimensional structure of the reaction center complexfrom the photosynthetic purple bacteria Rhodopseudomonas viridis(5) and Rhodobacter sphaeroides R-26 (1, 3). The availabilityof this high-resolution three-dimensional structure and the factthat the PSII complex was realized to be structurally and functionallyhomologous to the bacterial reaction center (reviewed in reference20) allowed a structural interpretation of photochemical processescatalyzed by PSII. From this, testable hypotheses could be formulatedregarding the nature of redox-active PSII cofactors and the aminoacid residues in their vicinity, and these predictions generallyproved to be correct on the basis of analysis of site-directedmutants in cyanobacteria and Chlamydomonas reinhardtii (6,26, 43). Moreover, several molecular models of PSII have beenconstructed on the basis of homology with the bacterial reactioncenter (31, 34, 46, 47), and these models also providea starting point forexperimentation.

This experimentation generally is carried out through mutant analysis. However, generation of a collection of site-directedmutants is time consuming. Instead, we have developed an approachby which to efficiently generate a collection of mutants withrandom changes in part of a protein, followed by screening forfunctionally altered phenotypes. We have previously reported onprobing of the AB loop of the D2 protein by targeted random mutagenesis(9). In this study, the C-terminal 30% of core PSII subunitD2 was targeted for random mutagenesis in Synechocystis sp. strainPCC 6803, and mutants that were impaired in photoautotrophic growth(and thus stable PSII function) were selected. By this approach,amino acid residues were found that previously were not realizedto be important for PSII function. Genetic and functional analysisof selected mutations in this region is presented in thispaper.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

Synechocystis sp. strain PCC 6803 transformation, isolation of chromosomal DNA from this organism, and monitoring of growthkinetics were performed as previously described (11).

Sodium bisulfite mutagenesis to introduce random mutations in a psbDI domain. The procedure for sodium bisulfite-induced targeted random mutagenesis of the D2 protein was similar to that previously described(9). This procedure is based on the fact that sodium bisulfitepreferentially reacts with single-stranded DNA regions, causingC-to-T transitions (13, 32). Therefore, heteroduplex DNA wasgenerated where the region to be mutagenized is single strandedand other regions are double stranded. To generate such heteroduplexDNA, two plasmids were used: (i) pDICK, containing the clonedSynechocystis sp. strain PCC 6803 psbDIC operon with its flankingregions (39), and (ii) the pDICK.del plasmid. The latter wasconstructed from pDICK by deleting the 287-bp NcoI/Bsu36I fragmentof psbDI, coding for amino acid residues Val247 to Pro342 of D2.The pDICK and pDICK.del plasmids were linearized with XhoI andEcoRV, respectively (the enzymes have a unique site in differentdomains of the plasmid), and the two plasmids were mixed in a1:1 molar ratio, heat denatured, and annealed. Homoduplex DNAmolecules formed in this process are linear, while heteroduplexesare nicked double-stranded circles because of the use of distantrestriction enzyme cleavage sites in the two types of molecules(14, 27). In heteroduplex DNA, the region corresponding tothe deletion forms a single-stranded loop. Two types of heteroduplexesare formed, as the coding and noncoding strands of psbDI may forma single-stranded loop. After annealing, the DNA mixture was treatedwith sodium bisulfite as previously described (29). Eight setsof conditions were used: exposure times of 20, 35, 50, and 65min with 3 M sodium bisulfite and exposure times of 1, 2, 3, and4 h with 1 M sodium bisulfite. DNA concentrations in the samplesvaried from 2.5 to 7 ng/µl.

After mutagenesis, the DNA mixtures were used to transform the ung mutant strain of Escherichia coli. Only heteroduplex moleculeswill yield transformants, as homoduplexes are linear. Either thefull-length plasmid (pDICK) or the deletion variant (pDICK.del)is found in E. coli cells, as the plasmids belong to the samecompatibility group. Colonies carrying either of the two plasmidsoccurred in a 1:1 ratio and were easily distinguished by size:colonies that contained full-length pDICK were significantly smaller,as expression of the intact psbDIC operon appears to be toxicto E. coli.

Individual pDICK-containing colonies were cultured, and plasmid DNA was prepared. Plasmids were used to transform the Synechocystissp. strain PCC 6803 mutant lacking psbDIC and psbDII (39), selectingfor kanamycin resistance conferred by pDICK. The transformantsexpressed sodium bisulfite-exposed psbDI in the absence of thetwo wild-type copies of psbD. Mutants that were obligate photoheterotrophsor that showed impaired photoautotrophy were selected, and theDNA sequence of part of psbDI (the region corresponding to codons247 to 342 and flanking regions) was determined. As expected,any plasmid showed either C-to-T transitions or G-to-A transitions(in the latter case, C-to-T transitions had been introduced intothe noncoding strand of psbDI). At the protein level, sodium bisulfitemutagenesis leads to potential substitution of the majority ofamino acid residues with one, two, three, or four others. Exceptionsare (i) Asn, Ile, Lys, Phe, and Tyr residues that cannot be mutatedand (ii) Gln and Trp residues that can be converted only to stopcodons.

Site-directed mutagenesis. An A260G mutation was introduced into the D2 protein using a single-stranded M13mp18 template containing cloned psbDI (39)and the mutagenic primer GTTGGAGAAACCAATACCGAAAATC. The mutagenesisprocedure used was previously described (35).

PSII quantitation and functional assays. The steady-state rate of oxygen evolution was determined as described earlier (11). PSII quantitation in whole cells ona chlorophyll basis using atrazine-replaceable [¹⁴C]diuron binding was performed as previously described (40).Chlorophyll a fluorescence induction and decay of the variablefluorescence were measured in intact cells on a commercial PAMfluorometer (Walz, Effeltrich, Germany) as previously described(16).

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

Isolation of Synechocystis sp. strain PCC 6803 psbDI mutants. Random mutations were introduced in the 287-bp NcoI/Bsu36I region of psbDI, which codes for amino acid residues Val247 toPro342 of the D2 subunit of PSII. This was done by sodium bisulfitemutagenesis of heteroduplex DNA as described in Materials andMethods. The Val247-to-Pro342 domain that was targeted for randommutagenesis starts in the DE loop and ends 10 residues beforethe C terminus of the protein. We chose not to alter the veryend of the psbDI coding region, since it overlaps the Shine-Dalgarnoribosome-binding site and the five N-terminal codons of psbC encodingthe CP43protein.

A total of 227 psbDI psbC-carrying pDICK plasmids that had been isolated independently after mutagenesis were used to transformthe recipient Synechocystis sp. strain PCC 6803 mutant lackingpsbDIC and psbDII (39). Kanamycin-resistant Synechocystis sp.strain PCC 6803 colonies were selected on BG-11 plates containingglucose as a source of fixed carbon, and these colonies were subsequentlyscreened for the inability or reduced ability to grow photoautotrophically.Twenty-six (11%) of these plasmids gave rise to transformantsimpaired in photoautotrophic growth. To determine whether thisphenotype was due to mutations within the targeted psbDI region,each mutant was subjected to a complementation test with a setof cloned wild-type psbDI fragments corresponding to small overlappingregions of the gene as previously described (9). Transformantswith mutations exclusively in the targeted region should regainthe ability to grow photoautotrophically at the wild-type rate.The majority of the mutants (19 [76%] out of 26) could be transformedto normal photoautotrophy by a plasmid containing a 338-bp NcoI/TaqIpsbDI fragment covering the mutagenized region of psbDI and werenot transformed by other fragments corresponding to neighboringregions. This test indicates that mutations leading to impairedphotoautotrophic growth in these 19 mutants were localized solelywithin the targeted DNA region that was exposed to sodium bisulfite.These 19 Synechocystis sp. strain PCC 6803 strains with randommutations introduced exclusively within the desired region ofpsbDI were used for furtherstudy.

Sequence analysis of the mutant collection. The psbDI gene was PCR amplified using chromosomal DNA from each of the 19 selected mutants as the template. The PCR productswere sequenced in the 287-bp NcoI/Bsu36I region that was targetedfor random mutagenesis. The sequences of the 200- to 300-bp-longflanking regions upstream and downstream of this region were determinedas well. Each of the mutants contained between one and nine G-to-Aor C-to-T nucleotide changes, leading at the protein level toone to six amino acid substitutions in D2 per plasmid (Fig. 1).Within the collection of 19 mutants, a total of 67 mutations wereintroduced into the 96-residue-long C-terminal part of the D2protein (Fig. 1). In only one case was a mutation (L346F) foundto have occurred outside of the targeted region. In this case,the mutation, which occurred 12 bp away from the targeted region,probably was due to transient denaturation-renaturation of theDNA double helix at the ends of the single-stranded loop. Thistransient denaturation and renaturation may have caused regionsadjacent to the loop to be briefly single stranded, renderingthem susceptible to sodium bisulfite mutagenesis (see Materialsand Methods).

View larger version (28K):
[in this window]
[in a new window]

FIG. 1. Representation of the wild-type sequence of the region of D2 that had been exposed to targeted random mutagenesis (top) and of the sequences in the various mutants (below). An asterisk above the wild-type sequence indicates a residue that has been mutated in one of the mutants indicated here. Minus signs above residues of the wild-type sequence indicate that these residues could not be changed by the method employed, and arrows delineate the region corresponding to the part of psbDI that was single stranded during the targeted random-mutagenesis experiment. Two residues that closely interact with Q_A or nonheme iron are underlined. These are Trp253 (presumed to be located between pheophytin and Q_A) and His268 (a putative ligand to nonheme iron). Residues the mutation of which appears to give rise to impaired PSII activity are in boldface. An asterisk in one of the mutant sequences indicates a stop codon. The four deletion (del.) plasmids that were used for functional complementation (see text) are indicated at the bottom.

As expected, 24 (about one-third) of the changes occurred at the third "wobble" nucleotide of codons, resulting in silentmutations. These mutations are not likely to influence expressionof psbDI. Analysis of DNA sequences in the GenBank database withrespect to codon usage in Synechocystis sp. strain PCC 6803 showedthat all of the codons are utilized in this cyanobacterium (datanot shown). The 43 nonsynonymous mutations affected a total of27 amino acid residues (Fig. 1) out of 70 that could be mutagenizedby sodium bisulfite in the targeted region of D2. Note that onlythose mutagenized plasmids that led to impaired PSII functionupon introduction into the Synechocystis sp. strain PCC 6803 genomehave been included in the sequence analysis. These plasmids constituteonly 8% of the total collection of 227 sodium bisulfite-treatedpDICK constructs. Since 8% of the collection contained substitutionsat more than a third of the possible sites, within the entirecollection essentially all of the 70 susceptible amino acid residuesare likely to have been altered at least once. This implies thatmutation of the majority of residues in this part of the proteindo not greatly affect photosynthetic function under laboratoryconditions.

Identification of D2 residues important for PSII function. Six mutants in the collection contained single amino acid substitutions (S254F, G258D, G278D, S283F, G288D, and R294W) (Fig.1), making analysis of the specific impact of these residues onPSII structure and function straightforward. However, the majorityof the mutants each carried between two and six changes in theD2 protein (Fig. 1). To identify which residues were primarilyresponsible for the impairment of photoautotrophic growth in strainswith multiple mutations, we utilized a genetic functional complementationtest. Four deletion variants of the complementing plasmid thatcarried the 338-bp NcoI/TaqI psbDI fragment were constructed usingBal 31 digestion of this plasmid. These deletion variants containedsubfragments of the wild-type psbDI gene corresponding to differentparts of the mutagenized region (Fig. 1). The deletion variantswere used to transform mutants with multiple amino acid changesbut without nonsense (stop codon) mutations. The subfragment(s)capable of restoring photoautotrophic growth to a specific mutantmust contain the mutation(s) primarily responsible for the PSII-impairedphenotype.

The results of the complementation test are presented in Table 1. Analysis of these data identified A249T, A260V, A260T,and H268Y as mutations that have a major effect on the abilityto grow photoautotrophically. Also, a number of mutations, mostlyin the C-terminal part of the D2 protein, were shown to have nosignificant impact on the photoautotrophic growth capacity ofSynechocystis sp. strain PCC 6803 (Table 1). Note that in Table1 the S282N mutation has been left off of the list of residuespossibly having a significant effect on photoautotrophic growthin D2R13 because of the results obtained with the D2R6 mutant,and the G285S mutation has been left off of the listing of possiblyimportant residues in D2R12 because of the results obtained withD2R4.

View this table:
[in this window]
[in a new window]

TABLE 1. Complementation analysis of selected psbDI mutants^a

Altogether, genetic analysis of the collection of sodium bisulfite-induced psbDI mutants resulted in the identification ofnine amino acid residues in the D2 protein that can be alteredto yield significant effects on PSII function (Fig. 1). The majorityof them are located in the DE loop and in transmembrane $alpha$ -helixE near the lumenal side of the membrane. In the C-terminal hydrophilicloop of the protein, only Arg294 was found to be very importantfor PSII stability and/orfunction.

Intragenic complementation in Synechocystis sp. strain PCC 6803. To facilitate the analysis of the effects of individual mutations on PSII function, the availability of corresponding singlemutants of Synechocystis sp. strain PCC 6803 would be advantageous.To obtain such mutants from our current collection, we probedfor the efficiency of intragenic recombination in this cyanobacterium.Single mutants may be generated by in vivo recombination betweenpsbDI genes with different sequences, and if such single mutantsare photoautotrophs, then they may be selected for by screeningfor photoautotrophic growth. A Synechocystis sp. strain PCC 6803cell contains several copies of its chromosome, and interchromosomalrecombination in Synechocystis sp. strain PCC 6803 appears tooccur (12). Therefore, if one combines in one cell two differentgenome copies that have differences in psbDI, recombination betweenthe two psbDI alleles is possible. Therefore, in principle, onecan create single psbDI mutants from photoheterotrophic mutantsthat each have multiple amino acid substitutions in psbDI butthat have one mutation in common. An example of a pair of mutantsthat have one mutation (G285S) in common are mutants D2R4 andD2R12 (Fig. 1). Using chromosomal DNA of each mutant to transformthe other mutant of the pair, one can select for transformantswith restored photoautotrophic growth capability, assuming thatthe shared mutation is not the reason for the photoheterotrophicphenotype. If the shared mutation is the reason for this phenotype,then no transformants will be obtained by this selectionprocedure.

Indeed, DNA sequencing of rapidly growing photoautotrophic transformants of photoheterotrophic strains with DNA from otherappropriate photoheterotrophic psbDI mutants indicates that thisapproach works well. We used this method of intragenic phenotypiccomplementation to generate the single mutants G285S (by transformingD2R4 with DNA from D2R12) and G288S (by transforming D2R16 withDNA from D2R18) and the double mutant S282N/V284I (by transformingD2R13 with DNA from D2R6; Fig. 1). In the latter case, the failureto find variants with a single mutation is likely to be due tothe relatively low number (four) of transformants that werescreened.

The scheme of interchromosomal recombination events that are likely to have led to the generation of the single mutant G285Sis presented in Fig. 2. It was necessary to assume a minimum oftwo double-crossover events to explain the genotype of the resultingtransformants. The transformation frequencies with which G285S,G288S, and S282N/V284I appeared were 10⁶ to 10⁷. When the corresponding photoheterotrophic mutants (D2R4, D2R16,and D2R13) were transformed with wild-type DNA, the frequencyof transformation leading to photoautotrophy was 10⁵. The increased frequency is consistent with the much larger regionwhere crossovers can occur and with the fact that one double-crossoverevent can restore photoautotrophic growth in this case. It isnoteworthy that even almost adjacent mutation sites (D308N andE310K and G285S and G288D) can be separated by crossover events(Fig. 2), indicating that crossover between these closely spacedresidues can occur at a reasonable frequency.

View larger version (10K):
[in this window]
[in a new window]

FIG. 2. Schematic representation of recombination events that are likely to have taken place to generate the G285S mutant as a result of transformation of the D2R4 strain with DNA from D2R12. The sequence at residues 288 and 310 is the wild-type sequence in strain D2R4, but the mutations present at residues 295, 302, and 308 in strain D2R4 were not retained. The solid horizontal line indicates the strain from which a particular region seems to originate in the G285S mutant, and crosses indicate the approximate locations where crossovers appear to have taken place. Note that a fourth crossover occurred at a position before codon 260.

Mutations in the Q_A-binding niche of the D2 protein. On the basis of similarity between the D2 protein and the M polypeptide of the bacterial reaction center (20), the N-terminalpart of the mutagenized D2 region (residues Val247 to His268)is thought to create most of the binding pocket of Q_A. This regionincludes the D2 DE helix and the N-terminal part of transmembrane $alpha$ -helix E that is located close to the acceptor side of the thylakoidmembrane. The approach indicated above identified Ala249, Ser254,Gly258, Ala260, and His268 as important for the photoautotrophiccompetence of PSII. Properties of D2 mutants with changes at positionsAla249 and His268 have been presented in detail earlier (10,42) and were not included in the present study. Some characteristicsof the other mutants are summarizedbelow.

As indicated in Table 2, mutants S254F and G258D showed a large decrease in the amount of functional PSII centers and rapidinhibition of oxygen evolution by light. The rates of electrontransport between Q_A and Q_B and of charge recombination betweenQ_A and the PSII donor side in the S254F mutant both were somewhatlower than in the wild type, as measured by fluorescence decayafter flash illumination in the absence and presence of 3-(3,4-dichlorophenyl)-1,1-dimethylurea(DCMU), respectively (Fig. 3). The yield of chlorophyll a fluorescencein the G258D strain was too low to be analyzed in detail. An interestingfeature of strains S254F and G258D is the fact that their oxygenevolution can be inhibited by micromolar concentrations of artificialquinones (Fig. 4). This effect is particularly pronounced withtetramethyl-p-benzoquinone (duroquinone, DQ). The addition of6 and 8 µM DQ to G258D and S254F, respectively, causes 50% inhibitionof oxygen evolution, while in the control strain a maximum inhibitionof 45% is achieved only at DQ concentrations of about 200 µM.Addition of increasing concentrations of 2,5-dichloro-p-benzoquinone (DCBQ) or 2,5-dimethyl-p-benzoquinone(DMBQ) to these mutants led to rapid inhibition of oxygen evolutionas well, whereas in the control strain no inhibition was observedat similar quinone concentrations (Fig. 4). Instead, stimulationwas observed, which is due to the quinones serving as PSII electronacceptors.

View this table:
[in this window]
[in a new window]

TABLE 2. Rates of photoautotrophic growth and electron transport, PSII content on a per-chlorophyll basis, and DCMU affinity in the control strain and psbDI mutants with amino acid substitutions in the DE loop, transmembrane $alpha$ -helix E, and the C terminus of the D2 protein^a

View larger version (21K):
[in this window]
[in a new window]

FIG. 3. Variable fluorescence yield recorded as a function of time after illumination in the absence (A) and presence (B) of 10 µM DCMU in intact cells of the S254F mutant (crosses) and the control (squares). The difference in signal-to-noise ratio between the two graphs is due to the fact that the measurements in the absence of DCMU were done with PSI-less strains and the measurements in the presence of DCMU were done with PSI-containing strains. The choice of background strain did not impact the decay kinetics of variable fluorescence.

View larger version (14K):
[in this window]
[in a new window]

FIG. 4. Inhibition of oxygen evolution in intact cells upon addition of artificial quinones. (A) Effects of DCBQ (closed symbols) and DMBQ (open symbols) on oxygen evolution in intact wild-type (triangles), S254F (squares), and G258D (circles) cells. (B) Inhibition of oxygen evolution in wild-type (triangles), S254F (squares), and G258D (circles) cells by different concentrations of DQ. No exogenous electron acceptors were added, except for 0.5 mM K₃Fe(CN)₆, which does not penetrate the cells and which was present to keep the quinones oxidized.

Two different substitutions were found at the Ala260 position (A260T and A260V). The fact that replacement of Ala260 withThr and especially with Val caused complete loss of PSII centers(Table 2) was unexpected, since these residues are relativelyclose in size and biochemical properties. Val differs from Alaby only two additional methyl groups in its side chain. Thus,stereochemical constraints seem the most likely explanation forthe fact that Val could not be functionally incorporated at position260 of D2. To check this hypothesis, an A260G mutation was introducedinto the D2 protein by site-directed mutagenesis. In the A260Gmutant, the amount of the PSII centers, the DCMU dissociationconstant, and the rate of oxygen evolution at saturating lightintensity were indistinguishable from those of the wild type (Table2). The kinetics of electron transfer around Q_A also were verysimilar to those of the wild type (data not shown). These datasuggest that only small residues (Ala and Gly) can be accommodatedat position 260 without loss ofPSII.

Mutations in transmembrane $alpha$ -helix E of the D2 protein. While the part of transmembrane $alpha$ -helix E that is located near the cytoplasmic side of the membrane may be involved in formationof the nonheme iron- and Q_A-binding niche, the opposite end ofthe helix positioned near the lumenal side of the membrane isthought to be in the vicinity of the reaction center chlorophylls(31, 34, 36, 47). Several mutations located in the regionof $alpha$ -helix E that is closest to the lumen were isolated and analyzedin the present study. A brief characterization of the PSII propertiesin mutants G278D, S282N/V284I, S283F, G285S, G288S, and G288Dis presentedbelow.

Introduction of a negatively charged Asp residue at position 278 of D2, thought to be near the middle of the membrane, causeda sevenfold reduction in the photoautotrophic growth rate (Table2). However, the PSII content, on a per-chlorophyll basis, andthe oxygen evolution rate in this mutant were only about twofoldlower than the corresponding values of the control strain. Furthermore,the kinetics of the charge separation and recombination in theG278D mutant, as monitored by chlorophyll fluorescence, were normal(data not shown). This suggests the presence of some inactivePSII centers in this mutant during normal growth. A possible reasonfor the inactive centers could be increased photoinactivationof PSII centers by light or decreased repair efficiency in theG278D mutant. The latter explanation seems more likely, as evenat a high light intensity (2,000 µmol photons m² s¹, which is 40 times higher than the light intensity under whichcells were propagated), inhibition of oxygen evolution in themutant was found to be only slightly faster than in the controlstrain.

Residues 282 to 288 are near the lumenal side of the membrane. Ser282 was presumed to possibly interact with P680 (23).However, replacement of the conserved Ser282 residue with Asndid not result in measurable alteration of PSII function or stability:the PSII content per cell, the rate of oxygen evolution at saturatinglight intensity, the photoautotrophic growth rate (Table 2),and the fluorescence properties (not shown) of the double mutantS282N/V284I were normal. On the other hand, the S283F mutationcaused a nearly twofold reduction in the photoautotrophic growthrate although the number of PSII centers per cell (Table 2) andPSII fluorescence properties (not shown) were almost normal. Replacementof Gly residues with Ser at positions 285 and 288 led to onlya small reduction in the PSII content per cell and in oxygen evolution(Table 2). Introduction of a negatively charged Asp at position288 had a more pronounced effect (Table 2), although not as drasticas the introduction of an Asp residue in place of Gly278. Thekinetics of Q_A reduction and recombination with the PSII donorside in the G285S, G288S, and G288D mutants were normal (datanot shown), suggesting that these mutations do not affect themidpoint redox potential ofP680.

Mutation R294W. Arg294 is thought to be on the lumenal side of D2. The R294W mutation caused a large decrease in PSII content and led to obligatephotoheterotrophy (Table 2). At saturating light intensity, themutant was capable of oxygen evolution but this process was rapidlyinhibited, indicating rapid photoinactivation. The initial rateof oxygen evolution amounted to about one-quarter of that of thewild type. The kinetics of charge separation and recombinationin R294W were similar to those in the control (data not shown),excluding a direct effect of the mutation on the midpoint potentialsof P680 or the water-splittingapparatus.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

Mutagenesis approach. Targeted random mutagenesis is an excellent way to identify functionally important residues in a larger part of a protein.A single treatment with sodium bisulfite can create a collectionof mutants in which collectively most of the residues within thetargeted region have been changed into up to four different residues.Mutations are targeted to a specific part of the gene while usinga DNA construct that contains the entire gene (14, 27, 29).In combination with a convenient and fast screening technique(in this case, impaired photoautotrophic function), a large numberof different mutants can be generated and identified easily bytargeted randommutagenesis.

Related techniques of random mutagenesis have been applied earlier to study structure-function relationships in various PSIIsubunits. Using an E. coli mutator strain, Wu and coworkers haveintroduced mutations at 14 sites in large extrinsic loop E andadjacent transmembrane helix VI of the CP47 protein (45). ResultingSynechocystis sp. strain PCC 6803 mutants exhibited variable phenotypes,ranging from moderate to severe impairment of PSII function. Randommutagenesis of the psbA2 region coding for 178 amino acids ofthe C-terminal portion of D1 was utilized to study mechanismsunderlying light sensitivity of D1 (22). In that work, Synechocystissp. strain PCC 6803 was transformed with psbA2 gene constructsthat were mutagenized in vitro using hydroxylamine or PCR underlow-fidelity conditions. Phototolerant transformants that didnot bleach in high-intensity light were selected and analyzed(21, 22).

In the present study, we chose to screen for mutants with slow or no photoautotrophic growth. The simplicity of the test allowedus to analyze more than 200 Synechocystis sp. strain PCC 6803colonies, identifying several new residues that are of functionalsignificance for PSII. About 10% of the Synechocystis sp. strainPCC 6803 colonies that originated from transformation of the acceptorstrain (39) with 227 mutagenized psbDI-containing plasmids wereimpaired in photoautotrophic growth. The fact that transformationwith about 90% of the mutagenized pDICK constructs did not leadto any measurable effects on PSII function suggests that in thisarea of D2, the majority of amino acid residues that can be alteredto other residues by sodium bisulfite mutagenesis (all exceptAsn, Gln, Ile, Lys, Phe, Trp, and Tyr) are not crucial for PSIIstructure or function. In an earlier study, all D2 Asn, Gln, Asp,Glu, and His residues presumed to be located on the donor sideof the thylakoid were probed by site-directed mutagenesis (reviewedin reference 25). Indeed, most mutations did not affect photoautotrophicgrowth; only at one position (Glu69) was a negative amino acidfound to be crucial for PSII function (40).

The psbDI region mutagenized in the present study included part of the DE loop, transmembrane helix E, and the C terminusof the D2 protein, except for the 10 distal C-terminal residues.A total of nine amino acid residues have been identified in thisarea of D2 to be important for PSII stability or function. Thedistribution of these residues, however, was nonuniform. Morethan half of them (Ala249, Ser254, Gly258, Ala260, and His268)were found to be located in the region forming the putative Q_A-bindingpocket. Three of the functionally important residues that wereidentified (Gly278, Ser283, and Gly288) are thought to be locatedin $alpha$ -helix E, even though Gly288 may be at the very end of thishelix. A mutation in only one residue (Arg294 changed to Trp)in the more than 50-residue-long C-terminal lumenal part of D2that had been mutagenized was found to greatly impair PSII stabilityor function. Thus, the C-terminal domain of D2 appears to be ableto accommodate many changes although the length of this regionwas shown to affect photoautotrophy in Synechocystis sp. strainPCC 6803 (7) and termination of translation at codon 334 ledto an obligate photoheterotrophic phenotype (Fig. 1).

Targeted sodium bisulfite mutagenesis appears to introduce mutations fairly evenly throughout the targeted region. Most ofthe 27 amino acid residues where mutations were found in thisstudy have been altered only once or twice in the mutant collection.However, some residues were altered in many different mutants:we mutated Gly288 in six independent mutants, Ala327 in four mutants,and Gly258 and Ala260 in three mutants. These mutations may notbe overrepresented in the collection simply because they leadto impaired photoautotrophic growth and thus have been preferentiallyselected: Ala327 does not seem to be important for PSII function.Moreover, all of the other mutations leading to complete lossof photoautotrophic growth occur only once in the collection.Most likely, residues Gly258, Ala260, Gly288, and Ala327 werelocated in hot spots of sodium bisulfite mutagenesis, possiblydue to the secondary structure of the single-stranded DNA loop.This explanation is supported by the observation that within themutant collection as a whole, the ratio of mutated versus unchangedamino acid residues around Gly288 and Ala327 is higher than inmost other areas of the mutagenized region (Fig. 1).

The majority of the Synechocystis sp. strain PCC 6803 mutants produced in the present work contained several amino acid substitutions,which complicated the analysis of the impact of each of thesemutations on PSII performance. To identify a single residue primarilyresponsible for impairment of PSII stability and/or function ina mutant carrying multiple mutations in psbDI, we used intragenicphenotypic complementation. The fact that closely clustered mutatednucleotides could be separated by recombination even if the distancebetween them was as short as 5 nucleotides is suggestive of frequentrearrangements between genome copies in Synechocystis sp. strainPCC 6803. Upon transformation of this cyanobacterium, exogenousDNA is incorporated into the genome via double-reciprocal recombination(44). This same mechanism may also drive interchromosomalrecombination.

Mutations in the Q_A-binding niche of the D2 protein. Mutations S254F and G258D both cause a 5- to 10-fold decrease in the number of PSII centers per cell. Furthermore, oxygenevolution in the remaining centers is inhibitable by light orby addition of artificial quinones (DQ, DCBQ, and DMBQ) at concentrationsbelow 0.3 mM. Particularly, DQ was found to have a very prominentinhibitory effect at micromolar concentrations. This is similarto the situation observed upon mutation of Ala249 of D2, in whichcase Q_A apparently could be displaced by artificial quinones (10).The introduction of a bulky (Phe) or polar (Ser or Asp) residueinto the Q_A-binding site presumably makes plastoquinone accessibleto exogenous quinones and may make it exchangeable. Ser254 andGly258 are 4 amino acid residues apart, which puts them on thesame side of the putative DE $alpha$ -helix. Ser254 is located next toTrp253, a residue that is probably involved in facilitating electrontransport through Q_A and/or in the binding of Q_A (20, 41).

Unexpectedly, mutations A260V and A260T led to complete loss of PSII while the function of PSII in the A260G mutant was normal(Table 1). Ala260 may be homologous to Ala258 of the M polypeptideof the R. viridis reaction center. The backbone nitrogen of thisresidue appears to form a hydrogen bond with an oxygen of Q_A (8,17, 19). Ala260 of D2 may play a similar role in PSII (37).According to an electron spin echo envelope modulation study ofthe PSII Q_A-binding pocket that used an elegant combination ofisotopic labeling of individual amino acids and site-directedmutagenesis in Synechocystis sp. strain PCC 6803, the peptidenitrogen of Ala260 of D2 indeed appears to form a weak hydrogenbond with Q_A (28). This puts Ala260 in the immediate vicinityof Q_A and implies strict stereochemical constraints in this partof the Q_A-binding pocket. This can explain our finding that onlythe two smallest amino acid residues (Ala and Gly) can be incorporatedat this position in D2 without complete loss of the PSII centersfrom thylakoid membrane. Our data are in line with work on thereaction center of R. sphaeroides in which M-subunit residuesAla248 and Ala260 (homologous to D2 residues Ala249 and Ala260,respectively) were replaced with Trp residues (30). Differentlines of evidence, including preliminary analysis of X-ray diffractiondata, demonstrated that the resulting mutants apparently lackedQ_A and that the Trp side chain partially occupied the volume thatis occupied by the ubiquinone group in the wild-type reactioncenter (30).

The R251H mutation in D2 has been shown before to be important for stabilization of bicarbonate binding in PSII (2). ResidueArg251 was modeled to be a part of the channel that allows waterand bicarbonate molecules to pass from the outside solvent towardthe nonheme iron (46). In the present study, the effect of R251Hon PSII stability or function was not addressed in detail, sincethis change occurred in the mutant collection together with mutationG258D, which by itself caused a drastic reduction in PSII content.However, the fact that the G258D single mutant retained some 10%of the PSII electron transfer while the R251H/G258H double mutantcontained no PSII centers indicates that the R251H mutation furtherdestabilizesPSII.

Even though many important residues in the Q_A-binding niche of PSII are conserved in the purple bacterial M subunit, Ser254has no obvious counterpart in the close vicinity of Q_A in thebacterial reaction center. However, we believe that Ser254 inPSII indeed is part of the Q_A-binding niche since the S254F mutantshows altered electron transfer characteristics around Q_A, particularlyin terms of its sensitivity to artificial quinones (Fig. 3). Anidentical Ser-to-Phe mutation introduced at position 262 of D2had no measurable effect on photoautotrophic function (Table 2).The data presented in this study support PSII models in whichresidues Ala249, Ser254, and Ala260 are implicated in the formationof the Q_A-binding site (31, 36, 46, 47).

Mutations in transmembrane $alpha$ -helix E and the C-terminal part of the D2 protein. Transmembrane $alpha$ -helix E is thought to be involved in the formation of the protein environment around Q_A (the stromal end ofthe helix), as well as around chlorophylls associated with thePSII reaction center (the lumenal end of the helix) (31, 34,36, 47). Furthermore, together with $alpha$ -helix D, $alpha$ -helix E isbelieved to create a significant part of the interface betweenD1 and D2 (37, 46). By probing $alpha$ -helix E of D2 by means oftargeted random mutagenesis, we strived to identify specific aminoacid residues that are important for these or other roles of $alpha$ -helixE in the PSII reactioncenter.

Seven mutations located in the lumenal half of D2 $alpha$ -helix E were isolated and analyzed in the present study (G278D, S282N/V284I,S283F, G285S, G288S, and G288D). In two of them (G278D and G288D),a negatively charged residue was introduced into the otherwisehydrophobic environment of a transmembrane $alpha$ -helix. In mutantsS282N, G285S, and G288S, a polar but uncharged residue was introduced,and in S283F, a small residue was changed to a more bulky one.Surprisingly, all of these mutants were still capable of photoautotrophicgrowth, although some at reduced rates. Another rather surprisingfinding was that none of these mutants were altered in the kineticsof PSII electron transfer and charge recombination, as determinedfrom the chlorophyll a fluorescence yield decay kinetics aftera flash in the presence and absence of DCMU (data not shown).Therefore, the midpoint potential of P680 remained unaffectedin the mutants. Residues Gly278, Ser282, and Gly285 are homologousto R. viridis M-subunit residues Val274, Ala278, and Gly281, respectively(20). The shortest distances between these residues and thebacteriochlorophylls of the special pair are 3.2 to 4.5 Å (8).In various models of P680 (23, 34), conserved D2 residue Ser282was predicted to form a hydrogen bond with the carbomethoxy groupof one of the P680 chlorophylls. The fact that the functionaland fluorescence properties of the double mutant S282N/V284I arenormal argues against this prediction, as changing of ligandsusually leads to a change in midpoint potential and back-reactionrates (18). These data indicate that P680 chlorophylls in PSIIare positioned and coordinated differently than bacteriochlorophyllsof the special pair in bacterial reaction centers, which may notbe surprising in view of the much less dimeric nature of P680in comparison to the special pair in purplebacteria.

It is noteworthy that the S283F mutation has a more pronounced effect on PSII properties than S282N. Residue Ser283 is notconserved between the D2 proteins from different species (33).This makes Ser283 an unlikely candidate for the formation of ahydrogen bond with one of the chlorophylls of the special pairin place of Ser282. However, this position in various D2 proteinstends to be occupied by a small residue (Ala or Ser) and appearsto be unable to accommodate Phe without impeding PSIIfunction.

Mutants G278D, S283F, and G288D have growth rates that are significantly lower than expected on the basis of their PSII contentand oxygen evolution capacity, compared to most other D2 mutants(see references 4, 7, and 15). The rate of photoinactivationof oxygen evolution by light in these mutants is only slightlyhigher than that of the wild type and therefore does not explainthis discrepancy. Instead, assembly and repair may have been sloweddown in these mutants, thus causing a rather normal phenotypeafter cell harvesting and incubation in darkness but leading tosignificant functional impairment in a continuous-lightsituation.

Only one residue in the C-terminal hydrophilic tail of D2 (Arg294) was identified as functionally important for PSII, eventhough from the number of mutants generated it is likely thatmost of the residues susceptible to bisulfite mutagenesis havebeen altered at least once. This supports the results of previoussite-directed mutagenesis experiments by our group (reviewed inreference 25): mutations of Asp, Asn, Glu, Gln, and His residuesin the C-terminal tail of the D2 protein had surprisingly littleeffect. In the photoheterotrophic mutant R294W, the residual rateof oxygen evolution was light sensitive. Because of the normalcharge recombination kinetics of the remaining centers in thismutant, changes in the thermodynamics of important donor sidecomponents (such as P680 and the oxygen-evolving complex) canbe virtually excluded. Instead, a structural role of Arg294 inthe stabilization of a functional PSII complex seemslikely.

Overall, targeted random mutagenesis has proven to be an efficient approach by which to identify functionally important residuesin PSII. The method described in this paper seems particularlyattractive in that modifications can be targeted to a specificregion without modification of the flankingregions.

	ACKNOWLEDGMENT

This research was supported by the National Science Foundation (MCB-9728400 to W.V.).

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Plant Biology and Center for the Study of Early Events in Photosynthesis,Arizona State University, P.O. Box 871601, Tempe, AZ 85287-1601.Phone: (480) 965-3698. Fax: (480) 965-6899. E-mail: wim{at}asu.edu.

Present address: Integrated Genomics, Inc., Chicago, IL60612.

Present address: Pharmaceutical Sector, Biotechnology Research Institute, National Research Council of Canada, Montreal, QuebecH4P 2R2,Canada.

REFERENCES

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

1. Allen, J. P., G. Feher, T. O. Yeates, D. C. Rees, J. Deisenhofer, H. Michel, and R. Huber. 1986. Structural homology of reaction centers from Rhodopseudomonas sphaeroides and Rhodopseudomonas viridis as determined by X-ray diffraction. Proc. Natl. Acad. Sci. USA 83:8589-8593[Abstract/Free Full Text].

2. Cao, J., W. F. J. Vermaas, and Govindjee. 1991. Arginine residues in the D2 polypeptide may stabilize bicarbonate binding in photosystem II of Synechocystis sp. PCC 6803. Biochim. Biophys. Acta 1059:171-180[Medline].

3. Chang, C.-H., D. Tiede, J. Tang, U. Smith, and J. Norris. 1986. Structure of Rhodopseudomonas sphaeroides R-26 reaction center. FEBS Lett. 205:82-86[CrossRef][Medline].

4. Chu, H.-A., A. P. Nguyen, and R. J. Debus. 1994. Amino acid residues that influence the binding of manganese or calcium to photosystem II. 2. The carboxy-terminal domain of the D1 polypeptide. Biochemistry 34:5859-5882.

5. Deisenhofer, J., O. Epp, K. Miki, R. Huber, and H. Michel. 1985. Structure of the protein subunits in the photosynthetic reaction center of Rhodopseudomonas viridis at 3 Å resolution. Nature 318:618-624[CrossRef].

6. Diner, B. A., and G. T. Babcock. 1996. Structure, dynamics, and energy conversion efficiency in photosystem II, p. 213-247. In D. R. Ort, and C. F. Yocum (ed.), Oxygenic photosynthesis: the light reactions. Kluwer Academic Publishers, Dordrecht, The Netherlands.

7. Eggers, B., and W. Vermaas. 1993. Truncation of the D2 protein in Synechocystis sp. PCC 6803: a role of the C-terminal domain of D2 in photosystem II function and stability. Biochemistry 32:11419-11427[CrossRef][Medline].

8. El-Kabbani, O., C.-H. Chang, D. Tiede, J. Norris, and M. Schiffer. 1991. Comparison of reaction centers from Rhodobacter sphaeroides and Rhodopseudomonas viridis: overall architecture and protein-pigment interactions. Biochemistry 30:5361-5369[CrossRef][Medline].

9. Ermakova-Gerdes, S., and W. Vermaas. 1996. 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. Plant Mol. Biol. 30:243-254[CrossRef][Medline].

10. Ermakova-Gerdes, S., and W. Vermaas. 1998. Mobility of the primary electron-accepting plastoquinone Q_A of photosystem II in a Synechocystis sp. PCC 6803 strain carrying mutations in the D2 protein. Biochemistry 37:11569-11578[CrossRef][Medline].

11. Ermakova-Gerdes, S., and W. Vermaas. 1999. 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. J. Biol. Chem. 274:30540-30549[Abstract/Free Full Text].

12. Gurevitz, M., H. D. Osiewacz, and Y. Keren. 1991. Molecular evidence for interchromosomal recombination in the cyanobacterium Synechocystis sp. PCC 6803. Plant Sci. 78:217-224[CrossRef].

13. Hayatsu, H. 1976. Bisulfite modification of nucleic acids and their constituents. Prog. Nucleic Acid Res. Mol. Biol. 16:75-124[Medline].

14. Kalderon, D., B. A. Oostra, B. K. Ely, and A. E. Smith. 1982. Deletion loop mutagenesis: a novel method for the construction of point mutations using deletion mutants. Nucleic Acids Res. 10:5161-5171[Abstract/Free Full Text].

15. Kless, H., M. Oren-Shamir, I. Ohad, M. Edelman, and W. Vermaas. 1993. Protein modifications in the D2 protein of photosystem II affect properties of the Q_B/herbicide-binding environment. Z. Naturforsch. 48c:185-190.

16. Kless, H., and W. Vermaas. 1995. Many combinations of amino acid sequences in a conserved region of the D1 protein satisfy photosystem II function. J. Mol. Biol. 246:120-131[CrossRef][Medline].

17. Komiya, H., T. O. Yeates, D. C. Rees, J. P. Allen, and G. Feher. 1988. Structure of the reaction center from Rhodobacter sphaeroides R-26 and 2.4.1: symmetry relations and sequence comparisons between different species. Proc. Natl. Acad. Sci. USA 85:9012-9016[Abstract/Free Full Text].

18. Lin, X., H. A. Murchison, V. Nagarajan, W. W. Parson, J. P. Allen, and J. C. Williams. 1994. Specific alteration of the oxidation potential of the electron donor in reaction centers from Rhodobacter sphaeroides. Proc. Natl. Acad. Sci. USA 91:10265-10269[Abstract/Free Full Text].

19. Michel, H., O. Epp, and J. Deisenhofer. 1986. Pigment-protein interactions in the photosynthetic reaction centre from Rhodopseudomonas viridis. EMBO J. 5:2445-2451[Medline].

20. Michel, H., and J. Deisenhofer. 1988. Relevance of the photosynthetic reaction center from purple bacteria to the structure of photosystem II. Biochemistry 27:1-7.

21. Minagawa, J., Y. Narusaka, Y. Inoue, and K. Satoh. 1999. Electron transfer between Q_A and Q_B in photosystem II is thermodynamically perturbed in phototolerant mutants of Synechocystis sp. PCC 6803. Biochemistry 38:770-775[CrossRef][Medline].

22. Narusaka, Y., M. Narusaka, K. Satoh, and H. Kobayashi. 1999. In vitro random mutagenesis of the D1 protein of the photosystem II reaction center confers phototolerance on the cyanobacterium Synechocystis sp. PCC 6803. J. Biol. Chem. 274:23270-23275[Abstract/Free Full Text].

23. Noguchi, T., Y. Inoue, and K. Satoh. 1993. FT-IR studies on the triplet state of P₆₈₀ in the photosystem II reaction center: triplet equilibrium within a chlorophyll dimer. Biochemistry 32:7186-7195[CrossRef][Medline].

24. Nugent, J. H. A. 1996. Oxygenic photosynthesis $---$ electron transfer in photosystem I and photosystem II. Eur. J. Biochem. 237:519-531[Medline].

25. Pakrasi, H. B., and W. F. J. Vermaas. 1992. Protein engineering of photosystem II, p. 231-257. In J. Barber (ed.), The photosystems: structure, function and molecular biology. Elsevier Science Publishers, Amsterdam, The Netherlands.

26. Pakrasi, H. B. 1995. Genetic analysis of the form and function of photosystem I and photosystem II. Annu. Rev. Genet. 29:755-776[CrossRef][Medline].

27. Peden, K. W., and D. Nathans. 1982. Local mutagenesis within deletion loops of DNA heteroduplexes. Proc. Natl. Acad. Sci. USA 79:7214-7217[Abstract/Free Full Text].

28. Peloquin, J. M., X.-S. Tang, B. A. Diner, and R. D. Britt. 1999. An electron spin-echo envelope modulation (ESEEM) study of the Q_A binding pocket of PS II reaction centers from spinach and Synechocystis. Biochemistry 38:2057-2067[CrossRef][Medline].

29. Pine, R., and P. C. Huang. 1987. An improved method to obtain a large number of mutants in a defined region of DNA. Methods Enzymol. 154:415-430[Medline].

30. Ridge, J. P., M. E. van Brederode, M. G. Goodwin, R. van Grondelle, and M. R. Jones. 1999. Mutations that modify or exclude binding of the Q_A ubiquinone and carotenoid in the reaction center from Rhodobacter sphaeroides. Photosynth. Res. 59:9-26.

31. Ruffle, S. V., D. Donnelly, T. L. Blundell, and J. H. A. Nugent. 1992. A three-dimensional model of the photosystem II reaction centre of Pisum sativum. Photosynth. Res. 34:287-300[CrossRef].

32. Shapiro, R., B. Braverman, J. B. Louis, and R. E. Servis. 1973. Nucleic acid reactivity and conformation. II. Reaction of cytosine and uracil with sodium bisulfite. J. Biol. Chem. 248:4060-4064[Abstract/Free Full Text].

33. Svensson, B., I. Vass, and S. Styring. 1991. Sequence analysis of the D1 and D2 reaction center proteins of photosystem II. Z. Naturforsch. 46c:765-776.

34. Svensson, B., C. Etchebest, P. Tuffery, P. van Kan, J. Smith, and S. Styring. 1996. A model for the photosystem II reaction center core including the structure of the primary donor P680. Biochemistry 35:14486-14502[CrossRef][Medline].

35. Tichy, M., and W. Vermaas. 1997. Functional analysis of combinatorial mutants altered in a conserved region in loop E of the CP47 protein in Synechocystis sp. PCC 6803. Biochemistry 37:1523-1531.

36. Trebst, A. 1986. The topology of the plastoquinone and herbicide binding peptides of photosystem II $---$ a model. Z. Naturforsch. 41c:240-245.

37. Trebst, A. 1991. A contact site between the two reaction center polypeptides of photosystem II is involved in photoinhibition. Z. Naturforsch. 46c:557-562.

38. Tsiotis, G., G. McDermott, and D. Ghanotakis. 1996. Progress towards structural elucidation of photosystem II. Photosynth. Res. 50:93-101.

39. Vermaas, W., J. Charité, and B. Eggers. 1990. System for site-directed mutagenesis in the psbDI/C operon of Synechocystis sp. PCC 6803, p. 231-238. In M. Baltscheffsky (ed.), Current research in photosynthesis, vol. I. Kluwer Academic Publishers, Dordrecht, The Netherlands.

40. Vermaas, W., J. Charité, and G. Shen. 1990. Glu-69 of the D2 protein in photosystem II is a potential ligand to Mn involved in photosynthetic oxygen evolution. Biochemistry 29:5325-5332[CrossRef][Medline].

41. Vermaas, W., J. Charité, and G. Shen. 1990. Q_A binding to D2 contributes to the functional and structural integrity of photosystem II. Z. Naturforsch. 45c:359-365.

42. Vermaas, W., I. Vass, B. Eggers, and S. Styring. 1994. Mutation of a putative ligand to the non-heme iron in photosystem II: implications for Q_A reactivity, electron transfer, and herbicide binding. Biochim. Biophys. Acta 1184:263-272[CrossRef].

43. Webber, A. N., S. E. Bingham, and H. Lee. 1995. Genetic engineering of thylakoid protein complexes by chloroplast transformation in Chlamydomonas reinhardtii. Photosynth. Res. 44:191-205[CrossRef].

44. Williams, J. G. K. 1988. Construction of specific mutations in photosystem II photosynthetic reaction center by genetic engineering methods in Synechocystis 6803. Methods Enzymol. 167:766-778.

45. Wu, J., N. Marsi, W. Lee, L. K. Frankel, and T. M. Bricker. 1999. Random mutagenesis in the large extrinsic loop E and transmembrane $alpha$ -helix VI of the CP 47 protein of photosystem II. Plant Mol. Biol. 39:381-386[CrossRef][Medline].

46. Xiong, J., S. Subramaniam, and Govindjee. 1996. Modeling of the D1/D2 proteins and cofactors of the photosystem II reaction center: implications for herbicide and bicarbonate binding. Protein Sci. 5:2054-2073[Abstract].

47. Xiong, J., S. Subramaniam, and Govindjee. 1998. A knowledge-based three dimensional model of the photosystem II reaction center of Chlamydomonas reinhardtii. Photosynth. Res. 56:229-254[CrossRef].

This article has been cited by other articles:

Rexroth, S., Wong, C. C. L., Park, J. H., Yates, J. R. III, Barry, B. A. (2007). An Activated Glutamate Residue Identified in Photosystem II at the Interface between the Manganese-stabilizing Subunit and the D2 Polypeptide. J. Biol. Chem. 282: 27802-27809 [Abstract] [Full Text]
Ishikita, H., Knapp, E.-W. (2006). Function of Redox-Active Tyrosine in Photosystem II. Biophys. J 90: 3886-3896 [Abstract] [Full Text]
Buchan, A., Ornston, L. N. (2005). When Coupled to Natural Transformation in Acinetobacter sp. Strain ADP1, PCR Mutagenesis Is Made Less Random by Mismatch Repair. Appl. Environ. Microbiol. 71: 7610-7612 [Abstract] [Full Text]
Yamasato, A., Kamada, T., Satoh, K. (2002). Random Mutagenesis Targeted to the psbAII Gene of Synechocystis sp. PCC 6803 to Identify Functionally Important Residues in the D1 Protein of the Photosystem II Reaction Center. Plant Cell Physiol 43: 540-548 [Abstract] [Full Text]

This Article

	Abstract
	Full Text (PDF)
	Alert me when this article is cited
	Alert me if a correction is posted

Services

	Similar articles in this journal
	Similar articles in PubMed
	Alert me to new issues of the journal
	Download to citation manager
	Reprints and Permissions
	Copyright Information
	Books from ASM Press
	MicrobeWorld

Citing Articles

	Citing Articles via HighWire
	Citing Articles via Google Scholar

Google Scholar

	Articles by Ermakova-Gerdes, S.
	Articles by Vermaas, W.
	Search for Related Content

PubMed

	PubMed Citation
	Articles by Ermakova-Gerdes, S.
	Articles by Vermaas, W.

Appl. Environ. Microbiol.	Infect. Immun.	Eukaryot. Cell
Mol. Cell. Biol.	J. Virol.	Microbiol. Mol. Biol. Rev.
	ALL ASM JOURNALS

1.	Allen, J. P., G. Feher, T. O. Yeates, D. C. Rees, J. Deisenhofer, H. Michel, and R. Huber. 1986. Structural homology of reaction centers from Rhodopseudomonas sphaeroides and Rhodopseudomonas viridis as determined by X-ray diffraction. Proc. Natl. Acad. Sci. USA 83:8589-8593[Abstract/Free Full Text].
2.	Cao, J., W. F. J. Vermaas, and Govindjee. 1991. Arginine residues in the D2 polypeptide may stabilize bicarbonate binding in photosystem II of Synechocystis sp. PCC 6803. Biochim. Biophys. Acta 1059:171-180[Medline].
3.	Chang, C.-H., D. Tiede, J. Tang, U. Smith, and J. Norris. 1986. Structure of Rhodopseudomonas sphaeroides R-26 reaction center. FEBS Lett. 205:82-86[CrossRef][Medline].
4.	Chu, H.-A., A. P. Nguyen, and R. J. Debus. 1994. Amino acid residues that influence the binding of manganese or calcium to photosystem II. 2. The carboxy-terminal domain of the D1 polypeptide. Biochemistry 34:5859-5882.
5.	Deisenhofer, J., O. Epp, K. Miki, R. Huber, and H. Michel. 1985. Structure of the protein subunits in the photosynthetic reaction center of Rhodopseudomonas viridis at 3 Å resolution. Nature 318:618-624[CrossRef].
6.	Diner, B. A., and G. T. Babcock. 1996. Structure, dynamics, and energy conversion efficiency in photosystem II, p. 213-247. In D. R. Ort, and C. F. Yocum (ed.), Oxygenic photosynthesis: the light reactions. Kluwer Academic Publishers, Dordrecht, The Netherlands.
7.	Eggers, B., and W. Vermaas. 1993. Truncation of the D2 protein in Synechocystis sp. PCC 6803: a role of the C-terminal domain of D2 in photosystem II function and stability. Biochemistry 32:11419-11427[CrossRef][Medline].
8.	El-Kabbani, O., C.-H. Chang, D. Tiede, J. Norris, and M. Schiffer. 1991. Comparison of reaction centers from Rhodobacter sphaeroides and Rhodopseudomonas viridis: overall architecture and protein-pigment interactions. Biochemistry 30:5361-5369[CrossRef][Medline].
9.	Ermakova-Gerdes, S., and W. Vermaas. 1996. 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. Plant Mol. Biol. 30:243-254[CrossRef][Medline].
10.	Ermakova-Gerdes, S., and W. Vermaas. 1998. Mobility of the primary electron-accepting plastoquinone Q_A of photosystem II in a Synechocystis sp. PCC 6803 strain carrying mutations in the D2 protein. Biochemistry 37:11569-11578[CrossRef][Medline].
11.	Ermakova-Gerdes, S., and W. Vermaas. 1999. 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. J. Biol. Chem. 274:30540-30549[Abstract/Free Full Text].
12.	Gurevitz, M., H. D. Osiewacz, and Y. Keren. 1991. Molecular evidence for interchromosomal recombination in the cyanobacterium Synechocystis sp. PCC 6803. Plant Sci. 78:217-224[CrossRef].
13.	Hayatsu, H. 1976. Bisulfite modification of nucleic acids and their constituents. Prog. Nucleic Acid Res. Mol. Biol. 16:75-124[Medline].
14.	Kalderon, D., B. A. Oostra, B. K. Ely, and A. E. Smith. 1982. Deletion loop mutagenesis: a novel method for the construction of point mutations using deletion mutants. Nucleic Acids Res. 10:5161-5171[Abstract/Free Full Text].
15.	Kless, H., M. Oren-Shamir, I. Ohad, M. Edelman, and W. Vermaas. 1993. Protein modifications in the D2 protein of photosystem II affect properties of the Q_B/herbicide-binding environment. Z. Naturforsch. 48c:185-190.
16.	Kless, H., and W. Vermaas. 1995. Many combinations of amino acid sequences in a conserved region of the D1 protein satisfy photosystem II function. J. Mol. Biol. 246:120-131[CrossRef][Medline].
17.	Komiya, H., T. O. Yeates, D. C. Rees, J. P. Allen, and G. Feher. 1988. Structure of the reaction center from Rhodobacter sphaeroides R-26 and 2.4.1: symmetry relations and sequence comparisons between different species. Proc. Natl. Acad. Sci. USA 85:9012-9016[Abstract/Free Full Text].
18.	Lin, X., H. A. Murchison, V. Nagarajan, W. W. Parson, J. P. Allen, and J. C. Williams. 1994. Specific alteration of the oxidation potential of the electron donor in reaction centers from Rhodobacter sphaeroides. Proc. Natl. Acad. Sci. USA 91:10265-10269[Abstract/Free Full Text].
19.	Michel, H., O. Epp, and J. Deisenhofer. 1986. Pigment-protein interactions in the photosynthetic reaction centre from Rhodopseudomonas viridis. EMBO J. 5:2445-2451[Medline].
20.	Michel, H., and J. Deisenhofer. 1988. Relevance of the photosynthetic reaction center from purple bacteria to the structure of photosystem II. Biochemistry 27:1-7.
21.	Minagawa, J., Y. Narusaka, Y. Inoue, and K. Satoh. 1999. Electron transfer between Q_A and Q_B in photosystem II is thermodynamically perturbed in phototolerant mutants of Synechocystis sp. PCC 6803. Biochemistry 38:770-775[CrossRef][Medline].
22.	Narusaka, Y., M. Narusaka, K. Satoh, and H. Kobayashi. 1999. In vitro random mutagenesis of the D1 protein of the photosystem II reaction center confers phototolerance on the cyanobacterium Synechocystis sp. PCC 6803. J. Biol. Chem. 274:23270-23275[Abstract/Free Full Text].
23.	Noguchi, T., Y. Inoue, and K. Satoh. 1993. FT-IR studies on the triplet state of P₆₈₀ in the photosystem II reaction center: triplet equilibrium within a chlorophyll dimer. Biochemistry 32:7186-7195[CrossRef][Medline].
24.	Nugent, J. H. A. 1996. Oxygenic photosynthesis $---$ electron transfer in photosystem I and photosystem II. Eur. J. Biochem. 237:519-531[Medline].
25.	Pakrasi, H. B., and W. F. J. Vermaas. 1992. Protein engineering of photosystem II, p. 231-257. In J. Barber (ed.), The photosystems: structure, function and molecular biology. Elsevier Science Publishers, Amsterdam, The Netherlands.
26.	Pakrasi, H. B. 1995. Genetic analysis of the form and function of photosystem I and photosystem II. Annu. Rev. Genet. 29:755-776[CrossRef][Medline].
27.	Peden, K. W., and D. Nathans. 1982. Local mutagenesis within deletion loops of DNA heteroduplexes. Proc. Natl. Acad. Sci. USA 79:7214-7217[Abstract/Free Full Text].
28.	Peloquin, J. M., X.-S. Tang, B. A. Diner, and R. D. Britt. 1999. An electron spin-echo envelope modulation (ESEEM) study of the Q_A binding pocket of PS II reaction centers from spinach and Synechocystis. Biochemistry 38:2057-2067[CrossRef][Medline].
29.	Pine, R., and P. C. Huang. 1987. An improved method to obtain a large number of mutants in a defined region of DNA. Methods Enzymol. 154:415-430[Medline].
30.	Ridge, J. P., M. E. van Brederode, M. G. Goodwin, R. van Grondelle, and M. R. Jones. 1999. Mutations that modify or exclude binding of the Q_A ubiquinone and carotenoid in the reaction center from Rhodobacter sphaeroides. Photosynth. Res. 59:9-26.
31.	Ruffle, S. V., D. Donnelly, T. L. Blundell, and J. H. A. Nugent. 1992. A three-dimensional model of the photosystem II reaction centre of Pisum sativum. Photosynth. Res. 34:287-300[CrossRef].
32.	Shapiro, R., B. Braverman, J. B. Louis, and R. E. Servis. 1973. Nucleic acid reactivity and conformation. II. Reaction of cytosine and uracil with sodium bisulfite. J. Biol. Chem. 248:4060-4064[Abstract/Free Full Text].
33.	Svensson, B., I. Vass, and S. Styring. 1991. Sequence analysis of the D1 and D2 reaction center proteins of photosystem II. Z. Naturforsch. 46c:765-776.
34.	Svensson, B., C. Etchebest, P. Tuffery, P. van Kan, J. Smith, and S. Styring. 1996. A model for the photosystem II reaction center core including the structure of the primary donor P680. Biochemistry 35:14486-14502[CrossRef][Medline].
35.	Tichy, M., and W. Vermaas. 1997. Functional analysis of combinatorial mutants altered in a conserved region in loop E of the CP47 protein in Synechocystis sp. PCC 6803. Biochemistry 37:1523-1531.
36.	Trebst, A. 1986. The topology of the plastoquinone and herbicide binding peptides of photosystem II $---$ a model. Z. Naturforsch. 41c:240-245.
37.	Trebst, A. 1991. A contact site between the two reaction center polypeptides of photosystem II is involved in photoinhibition. Z. Naturforsch. 46c:557-562.
38.	Tsiotis, G., G. McDermott, and D. Ghanotakis. 1996. Progress towards structural elucidation of photosystem II. Photosynth. Res. 50:93-101.
39.	Vermaas, W., J. Charité, and B. Eggers. 1990. System for site-directed mutagenesis in the psbDI/C operon of Synechocystis sp. PCC 6803, p. 231-238. In M. Baltscheffsky (ed.), Current research in photosynthesis, vol. I. Kluwer Academic Publishers, Dordrecht, The Netherlands.
40.	Vermaas, W., J. Charité, and G. Shen. 1990. Glu-69 of the D2 protein in photosystem II is a potential ligand to Mn involved in photosynthetic oxygen evolution. Biochemistry 29:5325-5332[CrossRef][Medline].
41.	Vermaas, W., J. Charité, and G. Shen. 1990. Q_A binding to D2 contributes to the functional and structural integrity of photosystem II. Z. Naturforsch. 45c:359-365.
42.	Vermaas, W., I. Vass, B. Eggers, and S. Styring. 1994. Mutation of a putative ligand to the non-heme iron in photosystem II: implications for Q_A reactivity, electron transfer, and herbicide binding. Biochim. Biophys. Acta 1184:263-272[CrossRef].
43.	Webber, A. N., S. E. Bingham, and H. Lee. 1995. Genetic engineering of thylakoid protein complexes by chloroplast transformation in Chlamydomonas reinhardtii. Photosynth. Res. 44:191-205[CrossRef].
44.	Williams, J. G. K. 1988. Construction of specific mutations in photosystem II photosynthetic reaction center by genetic engineering methods in Synechocystis 6803. Methods Enzymol. 167:766-778.
45.	Wu, J., N. Marsi, W. Lee, L. K. Frankel, and T. M. Bricker. 1999. Random mutagenesis in the large extrinsic loop E and transmembrane $alpha$ -helix VI of the CP 47 protein of photosystem II. Plant Mol. Biol. 39:381-386[CrossRef][Medline].
46.	Xiong, J., S. Subramaniam, and Govindjee. 1996. Modeling of the D1/D2 proteins and cofactors of the photosystem II reaction center: implications for herbicide and bicarbonate binding. Protein Sci. 5:2054-2073[Abstract].
47.	Xiong, J., S. Subramaniam, and Govindjee. 1998. A knowledge-based three dimensional model of the photosystem II reaction center of Chlamydomonas reinhardtii. Photosynth. Res. 56:229-254[CrossRef].