Francesca Zito

Involvement of state transitions in the switch between linear and cyclic electron flow in Chlamydomonas reinhardtii

The energetic metabolism of photosynthetic organisms is profoundly influenced by state transitions and cyclic electron flow around photosystem I. The former involve a reversible redistribution of the light‐harvesting antenna between photosystem I and photosystem II and optimize light energy utilization in photosynthesis whereas the latter process modulates the photosynthetic yield. We have used the wild‐type and three mutant strains of the green alga Chlamydomonas reinhardtii—locked in state I (stt7), lacking the photosystem II outer antennae (bf4) or accumulating low amounts of cytochrome b6f complex (A‐AUU)—and measured electron flow though the cytochrome b6f complex, oxygen evolution rates and fluorescence emission during state transitions. The results demonstrate that the transition from state 1 to state 2 induces a switch from linear to cyclic electron flow in this alga and reveal a strict cause–effect relationship between the redistribution of antenna complexes during state transitions and the onset of cyclic electron flow.

Isolation and characterization of photoautotrophic mutants of Chlamydomonas reinhardtii deficient in state transition.

In photosynthetic cells of higher plants and algae, the distribution of light energy between photosystem I and photosystem II is controlled by light quality through a process called state transition. It involves a reorganization of the light-harvesting complex of photosystem II (LHCII) within the thylakoid membrane whereby light energy captured preferentially by photosystem II is redirected toward photosystem I or vice versa. State transition is correlated with the reversible phosphorylation of several LHCII proteins and requires the presence of functional cytochromeb 6 f complex. Most factors controlling state transition are still not identified. Here we describe the isolation of photoautotrophic mutants of the unicellular algaChlamydomonas reinhardtii, which are deficient in state transition. Mutant stt7 is unable to undergo state transition and remains blocked in state I as assayed by fluorescence and photoacoustic measurements. Immunocytochemical studies indicate that the distribution of LHCII and of the cytochromeb 6 f complex between appressed and nonappressed thylakoid membranes does not change significantly during state transition in stt7, in contrast to the wild type. This mutant displays the same deficiency in LHCII phosphorylation as observed for mutants deficient in cytochromeb 6 f complex that are known to be unable to undergo state transition. The stt7 mutant grows photoautotrophically, although at a slower rate than wild type, and does not appear to be more sensitive to photoinactivation than the wild-type strain. Mutant stt3-4b is partially deficient in state transition but is still able to phosphorylate LHCII. Potential factors affected in these mutant strains and the function of state transition in C. reinhardtii are discussed.

Cytochrome f translation in Chlamydomonas chloroplast is autoregulated by its carboxyl-terminal domain.

The rate of synthesis of cytochrome f is decreased ∼10-fold when it does not assemble with the other subunits of the cytochrome b6f complex in Chlamydomonas reinhardtii chloroplasts. This assembly-mediated regulation of cytochrome f synthesis corresponds to a regulation of petA mRNA initiation of translation. Here, we demonstrate that cytochrome f translation is autoregulated by its C-terminal domain. Five cytochrome f residues conserved throughout all chloroplast genomes—residue Gln-297 in the transmembrane helix and a cluster of four amino acids, Lys-Gln-Phe-Glu, at positions 305 to 308, in the stromal extension—participate in the formation of a translation repressor motif. By contrast, positively charged residues in the stromal extension have little influence on the autoregulation process. These results do not favor a direct interaction between the repressor motif and the petA 5′ untranslated region but suggest the participation of a membrane-bound ternary effector.

Nonionic Homopolymeric Amphipols: Application to Membrane Protein Folding, Cell-Free Synthesis, and Solution Nuclear Magnetic Resonance

Nonionic amphipols (NAPols) synthesized by homotelomerization of an amphiphatic monomer are able to keep membrane proteins (MPs) stable and functional in the absence of detergent. Some of their biochemical and biophysical properties and applications have been examined, with particular attention being paid to their complementarity with the classical polyacrylate-based amphipol A8-35. Bacteriorhodopsin (BR) from Halobacterium salinarum and the cytochrome b(6)f complex from Chlamydomonas reinhardtii were found to be in their native state and highly stable following complexation with NAPols. NAPol-trapped BR was shown to undergo its complete photocycle. Because of the pH insensitivity of NAPols, solution nuclear magnetic resonance (NMR) two-dimensional (1)H-(15)N heteronuclear single-quantum coherence spectra of NAPol-trapped outer MP X from Escherichia coli (OmpX) could be recorded at pH 6.8. They present a resolution similar to that of the spectra of OmpX/A8-35 complexes recorded at pH 8.0 and give access to signals from solvent-exposed rapidy exchanging amide protons. Like A8-35, NAPols can be used to fold MPs to their native state as demonstrated here with BR and with the ghrelin G protein-coupled receptor GHS-R1a, thus extending the range of accessible folding conditions. Following NAPol-assisted folding, GHS-R1a bound four of its specific ligands, recruited arrestin-2, and activated binding of GTPγS by the G(αq) protein. Finally, cell-free synthesis of MPs, which is inhibited by A8-35 and sulfonated amphipols, was found to be very efficient in the presence of NAPols. These results open broad new perspectives on the use of amphipols for MP studies.

Is the redox state of the ci heme of the cytochrome b6f complex dependent on the occupation and structure of the Qi site and vice versa

Oxidoreductases of the cytochrome bc1/b6f family transfer electrons from a liposoluble quinol to a soluble acceptor protein and contribute to the formation of a transmembrane electrochemical potential. The crystal structure of cyt b6f has revealed the presence in the Qi site of an atypical c-type heme, heme ci. Surprisingly, the protein does not provide any axial ligand to the iron of this heme, and its surrounding structure suggests it can be accessed by exogenous ligand. In this work we describe a mutagenesis approach aimed at characterizing the ci heme and its interaction with the Qi site environment. We engineered a mutant of Chlamydomonas reinhardtii in which Phe40 from subunit IV was substituted by a tyrosine. This results in a dramatic slowing down of the reoxidation of the b hemes under single flash excitation, suggesting hindered accessibility of the heme to its quinone substrate. This modified accessibility likely originates from the ligation of the heme iron by the phenol(ate) side chain introduced by the mutation. Indeed, it also results in a marked downshift of the ci heme midpoint potential (from +100 mV to −200 mV at pH 7). Yet the overall turnover rate of the mutant cytochrome b6f complex under continuous illumination was found similar to the wild type one, both in vitro and in vivo. We propose that, in the mutant, a change in the ligation state of the heme upon its reduction could act as a redox switch that would control the accessibility of the substrate to the heme and trigger the catalysis.

B6f-Associated Chlorophyll : Structural and Dynamic Contribution to the Different Cytochrome Functions

Cytochromes bc1/b6f complexes catalyze electron transfer from lipid- to water-soluble carriers in both the respiratory and photosynthetic processes. They contain several common redox cofactors, while a chlorophyll a molecule, the function of which is still enigmatic, is only present in b b6f-type complexes. In this work, we describe a mutagenesis approach aimed at characterizing the role of this pigment. Mutants of the binding pocket were constructed to obtain cytochrome (cyt) b6f f complexes altered in chlorophyll position and/or stability. On the basis of a combined biochemical and functional analysis, we conclude that the chlorophyll plays a major structural role in the complex. Moreover, the chlorophyll and its binding pocket may also be implicated in the regulation of photosynthetic state transitions, a function that is specific to cyt b6f complexes.