Guy T. Hanke

Variable photosynthetic roles of two leaf-type ferredoxins in arabidopsis, as revealed by RNA interference.

Ferredoxin (Fd) is the soluble protein that accepts electrons from photosystem I (PSI) and makes them available to stromal enzymes in higher plant chloroplasts. In linear electron flow, Fd mainly donates electrons to Fd:NADPH reductase (FNR) which generates NADPH for use in the Calvin cycle, but Fd may also return electrons to the thylakoid plastoquinone pool, forming a cyclic electron flow. Many higher plants contain two different photosynthetic Fd proteins, but there are no conserved sequence differences that allow their division into evolutionary groups. In the model C3 photosynthesizing dicot, Arabidopsis thaliana, there are two such photosynthetic Fds, and we have exploited RNA interference (RNAi) techniques to specifically decrease transcript abundance of different Fds in this plant. Surprisingly, the perturbation of photosynthesis, as measured by cholorophyll fluorescence, in RNAi lines of the two different photosynthetic Fds shows opposite trends. Linear electron flow is retarded in lines with lower Fd2 (the most abundant Fd species) levels and under certain circumstances enhanced in lines with lower Fd1 (the minor isoprotein) levels. These data are evidences for at least partially differentiated roles of Fd1 and Fd2 in photosynthetic electron transfer, possibly in the partition of electrons into linear and cyclic electron flow.

Altered photosynthetic electron channelling into cyclic electron flow and nitrite assimilation in a mutant of ferredoxin:NADP(H) reductase

The mechanism by which plants regulate channelling of photosynthetically derived electrons into different areas of chloroplast metabolism remains obscure. Possible fates of such electrons include use in carbon assimilation, nitrogen assimilation and redox signalling pathways, or return to the plastoquinone pool through cyclic electron flow. In higher plants, these electrons are made accessible to stromal enzymes, or for cyclic electron flow, as reduced ferredoxin (Fd), or NADPH. We investigated how knockout of an Arabidopsis (Arabidopsis thaliana) ferredoxin:NADPH reductase (FNR) isoprotein and the loss of strong thylakoid binding by the remaining FNR in this mutant affected the channelling of photosynthetic electrons into NADPH- and Fd-dependent metabolism. Chlorophyll fluorescence data show that these mutants have complex variation in cyclic electron flow, dependent on light conditions. Measurements of electron transport in isolated thylakoid and chloroplast systems demonstrated perturbed channelling to NADPH-dependent carbon and Fd-dependent nitrogen assimilating metabolism, with greater competition in the mutant. Moreover, mutants accumulate greater biomass than the wild type under low nitrate growth conditions, indicating that such altered chloroplast electron channelling has profound physiological effects. Taken together, our results demonstrate the integral role played by FNR isoform and location in the partitioning of photosynthetic reducing power.

Fd : FNR Electron Transfer Complexes: Evolutionary Refinement of Structural Interactions

During the evolution of higher-plant root and leaf-type-specific Fd : FNR complexes from an original cyanobacterial type progenitor, rearrangement of molecular interaction has altered the relative orientation of prosthetic groups and there have been changes in complex induced conformational change. Selection has presumably worked on mutation of residues responsible for interaction between the two proteins, favoring optimized electron flow in a specific direction, and efficient dissociation following specific oxidation of leaf Fd and reduction of root Fd. Major changes appear to be: loss in both leaf and root complexes of a cyanobacterial mechanism that ensures Fd dissociation from the complex following change in Fd redox state, development of a structural rearrangement of Fd on binding to leaf FNR that results in a negative shift in Fd redox potential favorable to photosynthetic electron flow, creation of a vacant space in the root Fd:FNR complex that may allow access to the redox centers of other enzymes to ensure efficient channeling of heterotrophic reductant into bioassimilation. Further structural analysis is essential to establish how root type FNR distinguishes between Fd isoforms, and discover how residues not directly involved in intermolecular interactions may affect complex formation.

A screen for potential ferredoxin electron transfer partners uncovers new, redox dependent interactions

Ferredoxin (Fd) is the primary soluble acceptor at the end of the photosynthetic electron transport chain, and is known to directly transfer electrons to a wide range of proteins for use in metabolism and regulatory processes. We have conducted a screen to identify new putative Fd interaction partners in the cyanobacteria Synechocystis sp. PCC 6803 using Fd-chromatography in combination with MALDI-TOF mass spectrometry. Many novel interactions were detected, including several redox enzymes, which are now candidates for further experiments to investigate electron transfer with Fd. In addition, some proteins with regulatory activity related to photosynthesis were identified. We cloned and expressed one such protein, known as RpaA, which is a specific regulator of energy transfer between phycobilisomes and PSI. Using the recombinant protein we confirmed direct interaction with Fd, and discovered that this was dependent on redox state. The screen for putative Fd-binding proteins was repeated, comparing oxidizing and reducing conditions, identifying many proteins whose interaction with Fd is redox dependent. These include several additional signaling molecules, among them the LexA repressor, Ycf53 and NII, which are all involved in interpreting the redox state of the cell.

N-Terminal Structure of Maize Ferredoxin:NADP + Reductase Determines Recruitment into Different Thylakoid Membrane Complexes

Maize chloroplasts conducting either cyclic or linear electron flow vary in their ferredoxin:NADP+ reductase (FNR) composition. By comparing FNR crystal structures and introducing modified FNRs back into plants, we show that N-terminal structure determines recruitment to different thylakoid complexes. Furthermore, electron flow is analyzed in plants enriched in FNR at alternative locations. To adapt to different light intensities, photosynthetic organisms manipulate the flow of electrons through several alternative pathways at the thylakoid membrane. The enzyme ferredoxin:NADP+ reductase (FNR) has the potential to regulate this electron partitioning because it is integral to most of these electron cascades and can associate with several different membrane complexes. However, the factors controlling relative localization of FNR to different membrane complexes have not yet been established. Maize (Zea mays) contains three chloroplast FNR proteins with totally different membrane association, and we found that these proteins have variable distribution between cells conducting predominantly cyclic electron transport (bundle sheath) and linear electron transport (mesophyll). Here, the crystal structures of all three enzymes were solved, revealing major structural differences at the N-terminal domain and dimer interface. Expression in Arabidopsis thaliana of maize FNRs as chimeras and truncated proteins showed the N-terminal determines recruitment of FNR to different membrane complexes. In addition, the different maize FNR proteins localized to different thylakoid membrane complexes on expression in Arabidopsis, and analysis of chlorophyll fluorescence and photosystem I absorbance demonstrates the impact of FNR location on photosynthetic electron flow.

Identification of N-terminal regions of wheat leaf ferredoxin NADP+ oxidoreductase important for interactions with ferredoxin.

Wheat leaves contain two isoproteins of the photosynthetic ferredoxin:NADP(+) reductase (pFNRI and pFNRII). Truncated forms of both enzymes have been detected in vivo, but only pFNRII displays N-terminal length-dependent changes in activity. To investigate the impact of N-terminal truncation on interaction with ferredoxin (Fd), recombinant pFNRII proteins, differing by deletions of up to 25 amino acids, were generated. During purification of the isoproteins found in vivo, the longer forms of pFNRII bound more strongly to a Fd affinity column than did the shorter forms, pFNRII(ISKK) and pFNRII[N-2](KKQD). Further truncation of the N-termini resulted in a pFNRII protein which failed to bind to a Fd column. Similar k(cat) values (104-140 s(-1)) for cytochrome c reduction were measured for all but the most truncated pFNRII[N-5](DEGV), which had a k(cat) of 38 s(-1). Stopped-flow kinetic studies, examining the impact of truncation on electron flow between mutant pFNRII proteins and Fd, showed there was a variation in k(obs) from 76 to 265 s(-1) dependent on the pFNRII partner. To analyze the sites which contribute to Fd binding at the pFNRII N-terminal, three mutants were generated, in which a single or double lysine residue was changed to glutamine within the in vivo N-terminal truncation region. The mutations affected binding of pFNRII to the Fd column. Based on activity measurements, the double lysine residue change resulted in a pFNRII enzyme with decreased Fd affinity. The results highlight the importance of this flexible N-terminal region of the pFNRII protein in binding the Fd partner.