Ghada Ajlani

Flavodiiron proteins Flv1 and Flv3 enable cyanobacterial growth and photosynthesis under fluctuating light

Cyanobacterial flavodiiron proteins (FDPs; A-type flavoprotein, Flv) comprise, besides the β-lactamase–like and flavodoxin domains typical for all FDPs, an extra NAD(P)H:flavin oxidoreductase module and thus differ from FDPs in other Bacteria and Archaea. Synechocystis sp. PCC 6803 has four genes encoding the FDPs. Flv1 and Flv3 function as an NAD(P)H:oxygen oxidoreductase, donating electrons directly to O2 without production of reactive oxygen species. Here we show that the Flv1 and Flv3 proteins are crucial for cyanobacteria under fluctuating light, a typical light condition in aquatic environments. Under constant-light conditions, regardless of light intensity, the Flv1 and Flv3 proteins are dispensable. In contrast, under fluctuating light conditions, the growth and photosynthesis of the Δflv1(A) and/or Δflv3(A) mutants of Synechocystis sp. PCC 6803 and Anabaena sp. PCC 7120 become arrested, resulting in cell death in the most severe cases. This reaction is mainly caused by malfunction of photosystem I and oxidative damage induced by reactive oxygen species generated during abrupt short-term increases in light intensity. Unlike higher plants that lack the FDPs and use the Proton Gradient Regulation 5 to safeguard photosystem I, the cyanobacterial homolog of Proton Gradient Regulation 5 is shown not to be crucial for growth under fluctuating light. Instead, the unique Flv1/Flv3 heterodimer maintains the redox balance of the electron transfer chain in cyanobacteria and provides protection for photosystem I under fluctuating growth light. Evolution of unique cyanobacterial FDPs is discussed as a prerequisite for the development of oxygenic photosynthesis.

Structural organisation of phycobilisomes from Synechocystis sp strain PCC6803 and their interaction with the membrane

In cyanobacteria, the harvesting of light energy for photosynthesis is mainly carried out by the phycobilisome - a giant, multi-subunit pigment-protein complex. This complex is composed of heterodimeric phycobiliproteins that are assembled with the aid of linker polypeptides such that light absorption and energy transfer to photosystem II are optimised. In this work we have studied, using single particle electron microscopy, the phycobilisome structure in mutants lacking either two or all three of the phycocyanin hexamers. The images presented give much greater detail than those previously published, and in the best two-dimensional projection maps a resolution of 13 A was achieved. As well as giving a better overall picture of the assembly of phycobilisomes, these results reveal new details of the association of allophycocyanin trimers within the core. Insights are gained into the attachment of this core to the membrane surface, essential for efficient energy transfer to photosystem II. Comparison of projection maps of phycobilisomes with and without reconstituted ferredoxin:NADP oxidoreductase suggests a location for this enzyme within the complex at the rod-core interface.

Construction and characterization of a phycobiliprotein-less mutant of Synechocystis sp. PCC 6803

A mutant strain of the cyanobacterium Synechocystis PCC 6803, called PAL, (PC-, ΔapcAB, ΔapcE), lacking phycocyanin, allophycocyanin and the core-membrane linker (Lcm), was constructed. The strain was characterized by absorption and fluorescence spectroscopy. The mutant compensates for the absence of the major PS II antenna by increasing its PS II / PS I ratio. It is stable and grows well albeit more slowly than wild type.

PHYCOBILISOME CORE MUTANTS OF SYNECHOCYSTIS PCC 6803

Abstract Mutant strains of the cyanobacterium Synechocystis 6803 were constructed in which either the apcABC operon, encoding core subunits allophycocyanin α and β and a small linker L C 8 , or th0e apcE gene encoding the phycobilisome core-membrane linker was deleted. Phycobilisome assembly and energy transfer were studied in these mutants using both SDS gel analysis of phycobiliprotein complexes and low temperature fluorescence spectroscopy. Both mutants assembled phycocyanin rods but neither assembled a core complex. Although the mutants have no functional phycobilisomes, they grow photoautotrophically. No energy transfer between the remaining soluble phycobiliproteins and the photosystems was observed.

A second isoform of the ferredoxin:NADP oxidoreductase generated by an in-frame initiation of translation

Ferredoxin:NADP oxidoreductases (FNRs) constitute a family of flavoenzymes that catalyze the exchange of reducing equivalents between one-electron carriers and the two-electron-carrying NADP(H). The main role of FNRs in cyanobacteria and leaf plastids is to provide the NADPH for photoautotrophic metabolism. In root plastids, a distinct FNR isoform is found that has been postulated to function in the opposite direction, providing electrons for nitrogen assimilation at the expense of NADPH generated by heterotrophic metabolism. A multiple gene family encodes FNR isoenzymes in plants, whereas there is only one FNR gene (petH) in cyanobacteria. Nevertheless, we detected two FNR isoforms in the cyanobacterium Synechocystis sp. strain PCC6803. One of them (FNRS ≈34 kDa) is similar in size to the plastid FNR and specifically accumulates under heterotrophic conditions, whereas the other one (FNRL ≈46 kDa) contains an extra N-terminal domain that allows its association with the phycobilisome. Site-directed mutants allowed us to conclude that the smaller isoform, FNRS, is produced from an internal ribosome entry site within the petH ORF. Thus we have uncovered a mechanism by which two isoforms are produced from a single gene, which is, to our knowledge, novel in photosynthetic bacteria. Our results strongly suggest that FNRL is an NADP+ reductase, whereas FNRS is an NADPH oxidase.

Ultrastructure and light adaptation of phycobilisome mutants of Synechocystis PCC 6803

Abstract We have performed functional and ultrastructural characterization of Synechocystis PCC 6803 wild type and of two mutants, the first one (PMB11) lacking phycocyanin and still possessing the core of the phycobilisome and the second one (PΔE) lacking phycocyanin and Lcm (the core-membrane linker) and totally devoid of assembled phycobilisome structure. In the three strains, the state 1-state 2 transition occurred and was accompanied by ultrastructural changes. In state 1, an increased percentage of PS II-associated EF particles were aligned in rows compared to state 2 where more EF particles were randomly distributed in the membrane. A spill-over model is suggested by our ultrastructural and spectrophotometric results.© 1997 Elsevier Science B.V. All rights reserved.

Comparative studies on electron transfer in Photosystem II of herbicide-resistant mutants from different organisms

Abstract We have studied the electron transfer properties of Photosystem II using several techniques (fluorescence, oxygen emission and thermoluminescence measurements) in a series of herbicide-resistant mutants from widely different organisms. Five mutants of Synechocystis 6714, of which we have determined the D1 sequence, one mutant of Synechococcus 7942, one mutant of Chlamydomonas reinhardtii , a triazine-resistant biotype of Chenopodium album and their herbicide-susceptible controls were analyzed. Two mutants have an almost unimpaired Photosystem II electron transfer. For five mutants of the different organisms, the initial phase of the electron transfer Q − A to Q B is unaltered but the electron transfer equilibrium between these two acceptors is displaced. In the Chlamydomonas -resistant mutant, the electron transfer from Q − A to Q B is slowed down.

Molecular analysis of psb A mutations responsible for various herbicide resistance phenotypes in Synechocystis 6714

Mutations conferring herbicide resistance in 3 mutant strains of the cyanobacterium Synechocystis 6714 have been characterized by gene cloning and sequencing. The mutants display very different phenotypes: DCMU-IIA is DCMU-resistant and atrazine-resistant, DCMU-IIB is DCMU-resistant and atrazine-sensitive, and Az-V is DCMU-sensitive, atrazine-resistant and presents particular photoinhibition properties. These mutants were originally obtained either by one-step selection (DCMU-IIA) or by two-step selection (DCMU-IIB and Az-V). psbA copies carrying herbicide resistance have been identified by transformation experiments as psbAI in all cases. Sequences of the psbAI copy of each mutant have been compared to the wild-type sequence. In the single mutant DCMU-IIA, a point mutation at codon 264 (Ser→Ala) results in resistance to both DCMU and atrazine. In the double mutants DCMU-IIB and Az-V, two point mutations were found. DCMU-IIB was derived from DCMU-IIA and had acquired a second mutation at codon 255 (Phe→Leu) resulting in a slight increase in DCMU resistance and complete abolition of atrazine resistance. Az-V contains two changes at codons 211 (Phe→Ser) and 251 (Ala→Val) resulting in high atrazine resistance but only slight DCMU resistance.

Ferredoxin:NADP+ Oxidoreductase Association with Phycocyanin Modulates Its Properties

In photosynthetic organisms, ferredoxin:NADP+ oxidoreductase (FNR) is known to provide NADPH for CO2 assimilation, but it also utilizes NADPH to provide reduced ferredoxin. The cyanobacterium Synechocystis sp. strain PCC6803 produces two FNR isoforms, a small one (FNRS) similar to the one found in plant plastids and a large one (FNRL) that is associated with the phycobilisome, a light-harvesting complex. Here we show that a mutant lacking FNRL exhibits a higher NADP+/NADPH ratio. We also purified to homogeneity a phycobilisome subcomplex comprising FNRL, named FNRL-PC. The enzymatic activities of FNRL-PC were compared with those of FNRS. During NADPH oxidation, FNRL-PC exhibits a 30% decrease in the Michaelis constant Km(NADPH), and a 70% increase in Km(ferredoxin), which is in agreement with its predicted lower activity of ferredoxin reduction. During NADP+ reduction, the FNRL-PC shows a 29/43% decrease in the rate of single electron transfer from reduced ferredoxin in the presence/absence of NADP+. The increase in Km(ferredoxin) and the rate decrease of single reduction are attributed to steric hindrance by the phycocyanin moiety of FNRL-PC. Both isoforms are capable of catalyzing the NADP+ reduction under multiple turnover conditions. Furthermore, we obtained evidence that, under high ionic strength conditions, electron transfer from reduced ferredoxin is rate limiting during this process. The differences that we observe might not fully explain the in vivo properties of the Synechocystis mutants expressing only one of the isoforms. Therefore, we advocate that FNR localization and/or substrates availability are essential in vivo.

Mutations responsible for high light sensitivity in an atrazine-resistant mutant of Synechcystis 6714

The primary target of photoinhibition is the photosystem II reaction center. The process involves a reversible damage, followed by an irreversible inhibition of photosystem II activity. During cell exposition to high light intensity, the D1 protein is specially degraded. An atrazine-resistant mutant of Synechocystis 6714, AzV, reaches the irreversible step of photoinhibition faster than wild-type cells. Two point mutations present in the psbA gene of AzV (coding for D1) lead to the modification of Phe 211 to Ser and Ala 251 to Val in D1. Transformation of wild-type cells with the AzV psbA gene shows that these two mutations are sufficient to induce a faster photodamage of PSII. Other DCMU-and/or atrazine-resistant mutants do not differ from the wild type when photoinhibited. We conclude that the QB pocket is involved in PSII photodamage and we propose that the mutation of Ala 251 might be related to a lower rate of proteolysis of the D1 protein than in the wild type.