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.
The requirement of cytochrome c-550 (PSII-V) in photosystem II (PSII) has been assessed in Synechocystis sp. PCC 6803 containing mutations between Gly-351 and Thr-436 of the loop E domain of the chlorophyll a-binding protein CP47. Six photoautotrophic strains were utilized to compare the effect of removal of either the manganese-stabilizing protein (PSII-O) or PSII-V on PSII activity in vivo. These were a wild-type control; two strains with amino acid deletions, Delta(R384-V392) and Delta(G429-T436); and three carrying specific amino acid substitutions, G351L/T365Q, G351L/E364Q/T365Q, and G351L/E353Q/E355Q/T365Q. The removal of PSII-O prevented the assembly of PSII in Delta(G429-T436) but not in Delta(R384-V392). Neither Delta(G429-T436) nor Delta(R384-V392) could support photoautotrophic growth in the absence of PSII-V. In chloride-limiting conditions, the photoautotrophic growth of Delta(R384-V392) was severely impaired and that of Delta(G429-T436) totally inhibited, and no strains lacking PSII-V could grow in chloride-limiting or calcium-limiting media. Substitutions at Gly-351, Glu-353, Glu-355, and Thr-365 produced phenotypes that were similar to those of the control in the presence or absence of PSII-O and PSII-V, but removal of PSII-O from G351L/E364Q/T365Q produced a significant reduction of assembled PSII centers and an enhanced sensitivity to photoinactivation while removal of PSII-V prevented photoautotrophic growth. The additional mutants E364Q:DeltaPSII-V and E364G:DeltaPSII-V demonstrated that this inhibition was a consequence of the mutation at Glu-364. These results also show that the removal of PSII-V, in vivo, produces phenotypes in the CP47 mutants examined that are either similar or more severe than those resulting from the removal of PSII-O.
The removal of either the PsbU or PsbV protein has been investigated in a cyanobacterial v vPsbO strain and in mutants carrying deletions or substitutions in lumen-exposed domains of CP47. These experiments have demonstrated a functional interaction between the PsbU protein and photosystem II (PSII) in the absence of the PsbO subunit. The control:v vPsbO:v vPsbU strain assembled PSII centers at pH 7.5 but did not evolve oxygen; however, photoautotrophic growth was restored at pH 10.0. In addition, several CP47 mutants, lacking extrinsic proteins, were obligate photoheterotrophs at pH 7.5 but photoautotrophic at pH 10.0, whereas other strains remained photoheterotrophs at alkaline pH. ß
The Photosystem II (PSII) core antenna chlorophyll a-binding protein, CP47, contains six membrane-spanning alpha-helices separated by five hydrophilic loops: A-E. To identify important hydrophilic cytosolic regions, oligonucleotide-directed mutagenesis was employed to introduce short segment deletions into loops B and D, and the C-terminal domain. Four strains carrying deletions of between three and five residues were created in loop B. Two strains, with deletions adjacent to helices II and III, did not assemble PSII; however, the mutants delta(F123-D125) and delta(R127-S131) remained photoautotrophic with near wild-type levels of assembled reaction centers. In contrast, all deletions introduced into loop D, connecting helices IV and V, failed to assemble significant levels of PSII and were obligate photoheterotrophic mutants. However, deletions in the C-terminal domain did not prevent the assembly of PSII reaction centers although the mutant delta(S471 -T473), with a deletion adjacent to helix V1, exhibited retarded Q(A)- oxidation kinetics and the PSII-specific herbicide, atrazine, bound less tightly in the delta(S471-T473) and delta(F475-D477) strains. Deletions in the C-terminal domain also created mutants with large protein aggregates that were recognized by an antibody raised against the PSII reaction center D1 protein. Low-temperature fluorescence emission spectra of photoautotrophic strains carrying deletions in either the C-terminal domain or loop B did not provide evidence for impaired energy transfer from the phycobilisomes to the PSII reaction center. The data therefore suggest an important structural role for loop D in the assembly of PSII and a potential interaction between the C-terminal domain of CP47 and the PSII reaction center that, when perturbed, results in photoinduced protein aggregates involving the D1 protein.
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