The precursor of pea ferredoxin-NADP+ reductase synthesized in Escherichia coli contains bound FAD and is transported into chloroplasts

Introduction of a terminal electron sink in chloroplasts decreases leaf cell expansion associated with higher proteasome activity and lower endoreduplication

Foliar development involves successive phases of cell proliferation and expansion that determine the final leaf size, and is characterized by an early burst of reactive oxygen species generated in the photosynthetic electron transport chain (PETC). Introduction of the alternative PETC acceptor flavodoxin in tobacco chloroplasts led to a reduction in leaf size associated to lower cell expansion, without affecting cell number per leaf. Proteomic analysis showed that the biogenesis of the PETC proceeded stepwise in wild-type leaves, with accumulation of light-harvesting proteins preceding that of electron transport components, which might explain the increased energy and electron transfer to oxygen and reactive oxygen species build-up at this stage. Flavodoxin expression did not affect biogenesis of the PETC but prevented hydroperoxide formation through its function as electron sink. Mature leaves from flavodoxin-expressing plants were shown to contain higher levels of transcripts encoding components of the proteasome, a key negative modulator of organ size. Proteome profiling revealed that this differential accumulation was initiated during expansion and led to increased proteasomal activity, whereas a proteasome inhibitor reverted the flavodoxin-dependent size phenotype. Cells expressing plastid-targeted flavodoxin displayed lower endoreduplication, also associated to decreased organ size. These results provide novel insights into the regulation of leaf growth by chloroplast-generated redox signals, and highlight the potential of alternative electron shuttles to investigate the link(s) between photosynthesis and plant development.

Ectopic expression of a cyanobacterial flavodoxin in creeping bentgrass impacts plant development and confers broad abiotic stress tolerance

Flavodoxin (Fld) plays a pivotal role in photosynthetic microorganisms as an alternative electron carrier flavoprotein under adverse environmental conditions. Cyanobacterial Fld has been demonstrated to be able to substitute ferredoxin of higher plants in most electron transfer processes under stressful conditions. We have explored the potential of Fld for use in improving plant stress response in creeping bentgrass (Agrostis stolonifera L.). Overexpression of Fld altered plant growth and development. Most significantly, transgenic plants exhibited drastically enhanced performance under oxidative, drought and heat stress as well as nitrogen (N) starvation, which was associated with higher water retention and cell membrane integrity than wild-type controls, modified expression of heat-shock protein genes, production of more reduced thioredoxin, elevated N accumulation and total chlorophyll content as well as up-regulated expression of nitrite reductase and N transporter genes. Further analysis revealed that the expression of other stress-related genes was also impacted in Fld-expressing transgenics. Our data establish a key role of Fld in modulating plant growth and development and plant response to multiple sources of adverse environmental conditions in crop species. This demonstrates the feasibility of manipulating Fld in crop species for genetic engineering of plant stress tolerance.

Chloroplastic Hsp100 chaperones ClpC2 and ClpD interact in vitro with a transit peptide only when it is located at the N-terminus of a protein

BACKGROUND

Clp/Hsp100 chaperones are involved in protein quality control. They act as independent units or in conjunction with a proteolytic core to degrade irreversibly damaged proteins. Clp chaperones from plant chloroplasts have been also implicated in the process of precursor import, along with Hsp70 chaperones. They are thought to pull the precursors in as the transit peptides enter the organelle. How Clp chaperones identify their substrates and engage in their processing is not known. This information may lie in the position, sequence or structure of the Clp recognition motifs.

RESULTS

We tested the influence of the position of the transit peptide on the interaction with two chloroplastic Clp chaperones, ClpC2 and ClpD from Arabidopsis thaliana (AtClpC2 and AtClpD). The transit peptide of ferredoxin-NADP+ reductase was fused to either the N- or C-terminal end of glutathione S-transferase. Another fusion with the transit peptide interleaved between two folded proteins was used to probe if AtClpC2 and AtClpD could recognize tags located in the interior of a polypeptide. We also used a mutated transit peptide that is not targeted by Hsp70 chaperones (TP1234), yet it is imported at a normal rate. The fusions were immobilized on resins and the purified recombinant chaperones were added. After a washing protocol, the amount of bound chaperone was assessed. Both AtClpC2 and AtClpD interacted with the transit peptides when they were located at the N-terminal position of a protein, but not when they were allocated to the C-terminal end or at the interior of a polypeptide.

CONCLUSIONS

AtClpC2 and AtClpD have a positional preference for interacting with a transit peptide. In particular, the localization of the signal sequence at the N-terminal end of a protein seems mandatory for interaction to take place. Our results have implications for the understanding of protein quality control and precursor import in chloroplasts.

Functional replacement of ferredoxin by a cyanobacterial flavodoxin in tobacco confers broad-range stress tolerance

Chloroplast ferredoxin (Fd) plays a pivotal role in plant cell metabolism by delivering reducing equivalents to various essential oxidoreductive pathways. Fd levels decrease under adverse environmental conditions in many microorganisms, including cyanobacteria, which share a common ancestor with chloroplasts. Conversely, stress situations induce the synthesis of flavodoxin (Fld), an electron carrier flavoprotein not found in plants, which can efficiently replace Fd in most electron transfer processes. We report here that chloroplast Fd also declined in plants exposed to oxidants or stress conditions. A purified cyanobacterial Fld was able to mediate plant Fd-dependent reactions in vitro, including NADP+ and thioredoxin reduction. Tobacco (Nicotiana tabacum) plants expressing Fld in chloroplasts displayed increased tolerance to multiple sources of stress, including redox-cycling herbicides, extreme temperatures, high irradiation, water deficit, and UV radiation. Oxidant buildup and oxidative inactivation of thioredoxin-dependent plastidic enzymes were decreased in stressed plants expressing plastid-targeted Fld, suggesting that development of the tolerant phenotype relied on productive interaction of this flavoprotein with Fd-dependent oxidoreductive pathways of the host, most remarkably, thioredoxin reduction. The use of Fld provides new tools to investigate the requirements of photosynthesis in planta and to increase plant stress tolerance based on the introduction of a cyanobacterial product that is free from endogenous regulation in higher plants.

FAD assembly and thylakoid membrane binding of ferredoxin:NADP+ oxidoreductase in chloroplasts

We investigated the process of flavin adenine dinucleotide (FAD) incorporation into the ferredoxin (Fd):NADP(+) oxidoreductase (FNR) polypeptide during FNR biosynthesis, using pull-down assay with resin-immobilized Fd which bound strongly to FAD-assembled holo-FNR, but hardly to FAD-deficient apo-FNR. After FNR precursor was imported into isolated chloroplasts and processed to the mature size, the molecular form pulled down by Fd-resin increasingly appeared. The mature-sized FNR (mFNR) accumulated transiently in the stroma as the apo-form, and subsequently bound on the thylakoid membranes as the holo-form. Thus, FAD is incorporated into the mFNR inside chloroplasts, and this assembly process is followed by the thylakoid membrane localization of FNR.

Precursors with altered affinity for Hsp70 in their transit peptides are efficiently imported into chloroplasts

Protein import into chloroplasts is postulated to occur with the involvement of molecular chaperones. We have determined that the transit peptide of ferredoxin-NADP(H) reductase precursor binds preferentially to an Hsp70 from chloroplast stroma. To investigate the role of Hsp70 molecular chaperones in chloroplast protein import, we analyzed the import into pea chloroplasts of preproteins with decreased Hsp70 binding affinity in their transit peptides. Our results indicate that the precursor with the lowest affinity for Hsp70 molecular chaperones in its transit peptide was imported to chloroplasts with similar apparent Km as the wild type precursor and a 2-fold increase in Vmax. Thus, a strong interaction between chloroplast stromal Hsp70 and the transit peptide seems not to be essential for protein import. These results indicate that in chloroplasts the main unfolding force during protein import may be applied by molecular chaperones other than Hsp70s. Although stromal Hsp70s undoubtedly participate in chloroplast biogenesis, the role of these molecular chaperones in chloroplast protein translocation differs from the one proposed in the mechanisms postulated up to date.

The M domain of atToc159 plays an essential role in the import of proteins into chloroplasts and chloroplast biogenesis

Toc159, a protein located in the outer envelope membrane and the cytosol, is an important component of the receptor complex for nuclear-encoded chloroplast proteins. We investigated the molecular mechanism of protein import into chloroplasts by atToc159 using the ppi2 mutant, which has a T-DNA insertion at atToc159, shows an albino phenotype, and does not survive beyond the seedling stage due to a defect in protein import into chloroplasts. First we established that transiently expressing atToc159 in protoplasts obtained from the white leaf tissues of ppi2 plants complements the protein import defect into chloroplasts. Using this transient expression approach and a series of deletion mutants, we demonstrated that the C-terminal membrane-anchored (M) domain is targeted to the chloroplast envelope membrane in ppi2 protoplasts, and is sufficient to complement the defect in protein import. The middle GTPase (G) domain plays an additional critical role in protein import: the atToc159[S/N] and atToc159[D/L] mutants, which have a mutation at the first and second GTP-binding motifs, respectively, do not support protein import into chloroplasts. Leaf cells of transgenic plants expressing the M domain in a ppi2 background contained nearly fully developed chloroplasts with respect to size and density of thylakoid membranes, and displayed about half as much chlorophyll as wild-type cells. In transgenic plants, the isolated M domain localized to the envelope membrane of chloroplasts but not the cytosol. Based on these results, we propose that the M domain is the minimal structure required to support protein import into chloroplasts, while the G domain plays a regulatory role.

The import of ferredoxin-NADP+ reductase precursor into chloroplasts is modulated by the region between the transit peptide and the mature core of the protein

Protein transport across organelles' membranes requires that precursor proteins adopt an unfolded structure in order to be translocated by the import machinery. Ferredoxin-NADP+ reductase precursor, as well as many others, acquires a tightly folded structure that needs to be unfolded before or during its import. Several steps of chloroplast protein import are not fully understood. In particular, the role of different regions of the precursor protein has not been completely elucidated. In this work, we have studied the import into chloroplasts of precursor proteins with inclusions of amino acid spacers between the transit peptide and the mature protein, and with deletions in the N-terminal region of the mature enzyme. We measured the import rate constants for these precursors and the results indicate that the distance between the transit peptide and the core of the mature protein determines the import kinetics. The longer precursors were imported into the organelle faster than the wild type form. Precursors with deletions in the N-terminal region of the mature protein also showed increased import rates compared to the wild type. Homology studies amongst all family members reveal that only chloroplastic proteins possess this region. We suggest that even if the first amino acids of the mature protein do not contribute to its overall structural stability, they condition the kinetic parameters of the import reaction. Besides, the distance between the transit peptide and the mature protein core may be modulating the import rate at which the chloroplast incorporates this protein from the cytosol.

Interaction of the targeting sequence of chloroplast precursors with Hsp70 molecular chaperones

We have analyzed the interaction of DnaK and plant Hsp70 proteins with the wild-type ferredoxin-NADP+ reductase precursor (preFNR) and mutants containing amino-acid replacements in the targeting sequence. Using an algorithm already developed [Rüdiger, S., Germeroth, L., Schneider-Mergener, J. & Bukau, B. (1997) EMBO J. 16, 1501-1507] we observed that 75% of the 727 plastid precursor proteins analyzed contained at least one site with high likelihood of DnaK binding in their transit peptides. Statistical analysis showed a decrease of DnaK binding site frequency within the first 15 amino-acid residues of the transit peptides. Using fusion proteins we detected the interaction of DnaK with the transit peptide of the folded preFNR but not with the mature region of the protein. Discharge of DnaK from the presequence was favored by addition of MgATP. When a putative DnaK binding site was artificially added at the N-terminus of the mature protein, we observed formation of complexes with bacterial and plant Hsp70 molecular chaperones. Reducing the likelihood of DnaK binding by directed mutagenesis of the presequence increased the release of bound DnaK. The Hsp70 proteins from plastids and plant cell cytosol also interacted with the preFNR transit peptide. Overall results are discussed in the context of the proposed models to explain the organelle protein import.

Characterization of recombinant adrenodoxin reductase homologue (Arh1p) from yeast. Implication in in vitro cytochrome p45011beta monooxygenase system

The mammalian electron transfer chain of mitochondrial cytochrome P450 forms involved in steroidogenesis includes very specific proteins, namely adrenodoxin reductase and adrenodoxin. Adrenodoxin reductase transfers electrons from NADPH to adrenodoxin, which subsequently donates them to the cytochrome P450 forms. The Saccharomyces cerevisiae ARH1 gene product (Arh1p) presents homology to mammalian adrenodoxin reductase. We demonstrate the capacity of recombinant Arh1p, made in Escherichia coli, to substitute for its mammalian homologue in ferricyanide, cytochrome c reduction, and, more importantly, in vitro 11beta-hydroxylase assays. Electrons could be transferred from NADPH and NADH as measured in the cytochrome c reduction assay. Apparent Km values were determined to be 0.5, 0.6, and 0.1 microM for NADPH, NADH, and bovine adrenodoxin, respectively. These values differ slightly from those of mammalian adrenodoxin reductase, except for NADH, which is a very poor electron donor to the mammalian protein. Subcellular fractionation studies have localized Arh1p to the inner membrane of yeast mitochondria. The biological function of Arh1p remains unknown, and to date, no mitochondrial cytochrome P450 has been identified. ARH1 is, however, essential for yeast viability because an ARH1 gene disruption is lethal not only in aerobic growth conditions but also, surprisingly enough, during fermentation.

Biogenesis of the covalently flavinylated mitochondrial enzyme dimethylglycine dehydrogenase

Rat dimethylglycine dehydrogenase (Me2GlyDH) was used as model protein to study the biogenesis of a covalently flavinylated mitochondrial enzyme. Here we show that: 1) enzymatically active holoenzyme correlated with trypsin resistance of the protein; 2) folding of the reticulocyte lysate-translated protein into the trypsin-resistant, holoenzyme form was a slow process that was stimulated by the presence of the flavin cofactor and was more efficient at 15 degrees C than at 30 degrees C; 3) the mitochondrial presequence reduced the extent but did not prevent holoenzyme formation; 4) covalent attachment of FAD to the Me2GlyDH apoenzyme proceeded spontaneously and did not require a mitochondrial protein factor; 5) in vitro only the precursor, but not the mature form, of the protein was imported into isolated rat liver mitochondria; in vivo, in stably transfected HepG2 cells, both the precursor and the mature form were imported into the organelle; 6) holoenzyme formation in the cytoplasm did not prevent the translocation of the proteins into the mitochondria in vivo; and 7) lack of vitamin B2 in the tissue culture medium resulted in a reduced recovery of the precursor and the mature form of Me2GlyDH from cell mitochondria, suggesting a decreased efficiency of mitochondrial protein import.