The chloroplastic GrpE homolog of Chlamydomonas: two isoforms generated by differential splicing.

In eubacteria and mitochondria, Hsp70 chaperone activity is controlled by the nucleotide exchange factor GrpE. We have identified the chloroplastic GrpE homolog of Chlamydomonas, CGE1, as an approximately 26-kD protein coimmunoprecipitating with the stromal HSP70B protein. When expressed in Escherichia coli, CGE1 can functionally replace GrpE and interacts physically with DnaK. CGE1 is encoded by a single-copy gene that is induced strongly by heat shock and slightly by light. Alternative splicing generates two isoforms that differ only by two residues in the N-terminal part. The larger form is synthesized preferentially during heat shock, whereas the smaller one dominates at lower temperatures. Fractions of both HSP70B and CGE1 associate with chloroplast membranes in an ATP-sensitive manner. By colorless native PAGE and pulse labeling, CGE1 monomers were found to assemble rapidly into dimers and tetramers. In addition, CGE1 was found to form ATP-sensitive complexes with HSP70B of approximately 230 and approximately 120 kD, the latter increasing dramatically after heat shock.

Time-resolved fluorescence analysis of the photosystem II antenna proteins in detergent micelles and liposomes.

We have studied the time-resolved fluorescence properties of the light-harvesting complexes (Lhc) of photosystem II (Lhcb) in order to obtain information on the mechanism of energy dissipation (non-photochemical quenching) which is correlated to the conversion of violaxanthin to zeaxanthin in excess light conditions. The chlorophyll fluorescence decay of Lhcb proteins LHCII, CP29, CP26, and CP24 in detergent solution is mostly determined by two lifetime components of 1.2-1.5 and 3.6-4 ns while the contribution of the faster component is higher in CP29, CP26, and CP24 with respect to LHCII. The xanthophyll composition of Lhc proteins affects the ratio of the lifetime components: when zeaxanthin is bound into the site L2 of LHCII, the relative amplitude of the faster component is increased and, consequently, the chlorophyll fluorescence quenching is enhanced. Analysis of quenching in mutants of Arabidopsis thaliana, which incorporate either violaxanthin or zeaxanthin in their Lhc proteins, shows that the extent of quenching is enhanced in the presence of zeaxanthin. The origin of the two fluorescence lifetimes was analyzed by their temperature dependence: since lifetime heterogeneity was not affected by cooling to 77 K, it is concluded that each lifetime component corresponds to a distinct conformation of the Lhc proteins. Upon incorporation of Lhc proteins into liposomes, a quenching of chlorophyll fluorescence was observed due to shortening of all their lifetime components: this indicates that the equilibrium between the two conformations of Lhcb proteins is displaced toward the quenched conformation in lipid membranes or thylakoids with respect to detergent solution. By increasing the protein density in the liposomes, and therefore the probability of protein-protein interactions, a further decrease of fluorescence lifetimes takes place down to values typical of quenched leaves. We conclude that at least two major factors determine the quenching of chlorophyll fluorescence in Lhcb proteins, i.e., intrasubunit conformational change and intersubunit interactions within the lipid membranes, and that these processes are both important in the photoprotection mechanism of nonphotochemical quenching in vivo.

Possible role for molecular chaperones in assembly and repair of photosystem II.

Genes of the HSP70 chaperone family are induced by light. In Chlamydomonas reinhardtii, the induction of HSP70 (70 kDa heat shock protein) chaperones by light results in a partial protection of photosystem II against damage by photoinhibitory conditions. Underexpression of a chloroplast-localized HSP70 protein caused an increased sensitivity of photosystem II to light. Overexpression of this protein had a protective effect. Fluorescence measurements and studies of the turnover of photosystem II core components suggest that this HSP70 might function in both the protection and the regeneration of photosystem II. This concept is supported by fractionation studies in which the plastid HSP70 was found associated with chloroplast membranes. Because the light-induced elevation of HSP70 levels provides protection for photosystem II, we examined whether the chloroplast is involved in this regulation and found that mutants defective in plastid-localized chlorophyll synthesis, i.e. the insertion of Mg(2+) into protoporphyrin IX are impaired in the induction of HSP70 by light. Exogenous addition of Mg-protoporphyrin in the dark induced the genes. The combined results support a model in which chlorophyll precursors are essential in the signalling from chloroplast to nucleus that regulates the chaperone genes.

The light sensitivity of ATP synthase mutants of Chlamydomonas reinhardtii.

Chlamydomonas reinhardtii mutants defective in the chloroplast ATP synthase are highly sensitive to light. The ac46 mutant is affected in the MDH1 gene, required for production or stability of the monocistronic atpH mRNA encoding CF(O)-III. In this and other ATP synthase mutants, we show that short-term exposure to moderate light intensities-a few minutes-induces an inhibition of electron transfer after the primary quinone acceptor of photosystem II (PSII), whereas longer exposure-several hours-leads to a progressive loss of PSII cores. An extensive swelling of thylakoids accompanies the initial inhibition of electron flow. Thylakoids deflate as PSII cores are lost. The slow process of PSII degradation involves the participation of ClpP, a chloroplast-encoded peptidase that is part of a major stromal protease Clp. In the light of the above findings, we discuss the photosensitivity of ATP synthase mutants with respect to the regular photoinhibition process that affects photosynthetic competent strains at much higher light intensities.

Chloroplast and mitochondrial proteases in Arabidopsis. A proposed nomenclature.

The identity and scope of chloroplast and mitochondrial proteases in higher plants has only started to become apparent in recent years. Biochemical and molecular studies suggested the existence of Clp, FtsH, and DegP proteases in chloroplasts, and a Lon protease in mitochondria, although currently the full extent of their role in organellar biogenesis and function remains poorly understood. Rapidly accumulating DNA sequence data, especially from Arabidopsis, has revealed that these proteolytic enzymes are found in plant cells in multiple isomeric forms. As a consequence, a systematic approach was taken to catalog all these isomers, to predict their intracellular location and putative processing sites, and to propose a standard nomenclature to avoid confusion and facilitate scientific communication. For the Clp protease most of the ClpP isomers are found in chloroplasts, whereas one is mitochondrial. Of the ATPase subunits, the one ClpD and two ClpC isomers are located in chloroplasts, whereas both ClpX isomers are present in mitochondria. Isomers of the Lon protease are predicted in both compartments, as are the different forms of FtsH protease. DegP, the least characterized protease in plant cells, has the most number of isomers and they are predicted to localize in several cell compartments. These predictions, along with the proposed nomenclature, will serve as a framework for future studies of all four families of proteases and their individual isomers.

Synthesis, assembly and degradation of thylakoid membrane proteins.

The thylakoid membrane of chloroplasts contains four major protein complexes, involved in the photosynthetic electron transfer chain and in ATP synthesis. These complexes are built from a large number of polypeptide subunits encoded either in the nuclear or in the plastid genome. In this review, we are considering the mechanism that couples assembly (association of the polypeptides with each other and with their cofactors) with the upstream and downstream steps of the biogenetic pathway, translation and proteolytic degradation. We present the contrasting images of assembly that have emerged from a variety of approaches (studies of photosynthesis mutants, developmental studies and direct biochemical analysis of the kinetics of assembly). We develop the concept of control by epistasy of synthesis, through which the translation of certain subunits is controlled by the state of assembly of the complex and address the question of its mechanisms. We describe additional factors that assist in the integration and assembly of thylakoid membrane proteins.

New sequence motifs in flavoproteins: evidence for common ancestry and tools to predict structure.

We describe two new sequence motifs, present in several families of flavoproteins. The "GG motif" (RxGGRxxS/T) is found shortly after the betaalphabetadinucleotide-binding motif (DBM) in L-amino acid oxidases, achacin and aplysianin-A, monoamine oxidases, corticosteroid-binding proteins, and tryptophan 2-monooxygenases. Other disperse sequence similarities between these families suggest a common origin. A GG motif is also found in protoporphyrinogen oxidase and carotenoid desaturases and, reduced to the central GG doublet, in the THI4 protein, dTDP-4-dehydrorhamnose reductase, soluble fumarate reductase, steroid dehydrogenases, Rab GDP-dissociation inhibitor, and in most flavoproteins with two dinucleotide-binding domains (glutathione reductase, glutamate synthase, flavin-containing monooxygenase, trimethylamine dehydrogenase...). In the latter families, an "ATG motif" (oxhhhATG) is found in both the FAD- and NAD(P)H-binding domains, forming the fourth beta-strand of the Rossman fold and the connecting loop. On the basis of these and previously described motifs, we present a classification of dinucleotide-binding proteins that could also serve as an evolutionary scheme. Like the DBM, the ATG motif appears to predate the divergence of NAD(P)H- and FAD-binding proteins. We propose that flavoproteins have evolved from a well-differentiated NAD(P)H-binding protein. The bulk of the substrate-binding domain was formed by an insertion after the fourth beta-strand, either of a closely related NAD(P)H-binding domain or of a domain of completely different origin.

Evidence for a role of ClpP in the degradation of the chloroplast cytochrome b(6)f complex.

In the green alga Chlamydomonas reinhardtii, the ClpP protease is encoded by an essential chloroplast gene. Mutating its AUG translation initiation codon to AUU reduced ClpP accumulation to 25 to 45% of that of the wild type. Both the mature protein and the putative precursor containing its insertion sequence were present in reduced amounts. Attenuation of ClpP did not affect growth rates under normal conditions but restricted the ability of the cells to adapt to elevated CO(2) levels. It also affected the rate of degradation of the cytochrome b(6)f complex of the thylakoid membrane in two experimental situations: (1) during nitrogen starvation, and (2) in mutants deficient in the Rieske iron-sulfur protein. The ClpP level also controls the steady state accumulation of a mutated version of the Rieske protein. In contrast, attenuation of ClpP did not rescue the fully unassembled subunits in other cytochrome b(6)f mutants. We conclude that proteolytic disposal of fully or partially assembled cytochrome b(6)f is controlled by the Clp protease.

Mutants of Chlamydomonas: tools to study thylakoid membrane structure, function and biogenesis.

The unicellular green alga Chlamydomonas reinhardtii is a model system for the study of photosynthesis and chloroplast biogenesis. C. reinhardtii has a photosynthesis apparatus similar to that of higher plants and it grows at rapid rate (generation time about 8 h). It is a facultative phototroph, which allows the isolation of mutants unable to perform photosynthesis and its sexual cycle allows a variety of genetic studies. Transformation of the nucleus and chloroplast genomes is easily performed. Gene transformation occurs mainly by homologous recombination in the chloroplast and heterologous recombination in the nucleus. Mutants are precious tools for studies of thylakoid membrane structure, photosynthetic function and assembly. Photosynthesis mutants affected in the biogenesis of a subunit of a protein complex usually lack the entire complex; this pleiotropic effect has been used in the identification of the other subunits, in the attribution of spectroscopic signals and also as a 'genetic cleaning' process which facilitates both protein complex purification, absorption spectroscopy studies or freeze-fracture analysis. The cytochrome b6f complex is not required for the growth of C. reinhardtii, unlike the case of photosynthetic prokaryotes in which the cytochrome complex is also part of the respiratory chain, and can be uniquely studied in Chlamydomonas by genetic approaches. We describe in greater detail the use of Chlamydomonas mutants in the study of this complex.

A chloroplast-targeted heat shock protein 70 (HSP70) contributes to the photoprotection and repair of photosystem II during and after photoinhibition.

Dark-grown Chlamydomonas reinhardtii cultures that were illuminated at low fluence rates before exposure to high-light conditions exhibited a faster rate of recovery from photoinhibition than did dark-grown cells that were directly exposed to photoinhibitory conditions. This pretreatment has been shown to induce the expression of several nuclear heat shock protein 70 (HSP70) genes, including HSP70B, encoding a chloroplast-localized chaperone. To investigate a possible role of plastidic HSP70B in photoprotection and repair of photosystem II, which is the major target of photoinhibition, we have constructed strains overexpressing or underexpressing HSP70B. The effect of light stress on photosystem II in nuclear transformants harboring HSP70B in the sense or antisense orientation was monitored by measuring variable fluorescence, flash-induced charge separation, and relative amounts of various photosystem II polypeptides. Underexpression of HSP70B caused an increased light sensitivity of photosystem II, whereas overexpression of HSP70B had a protective effect. Furthermore, the reactivation of photosystem II after photoinhibition was enhanced in the HSP70B-overexpressing strain when compared with the wild type, both in the presence or absence of synthesis of chloroplast-encoded proteins. Therefore, HSP70B may participate in vivo both in the molecular protection of the photosystem II reaction centers during photoinhibition and in the process of photosystem II repair.

Mutations Affecting O-Glycosylation in Chlamydomonas reinhardtii Cause Delayed Cell Wall Degradation and Sex-Limited Sterility.

We describe a mutation, gag-1, that affects in a temperature-dependent manner a specific type of O-glycosylation in the green alga Chlamydomonas reinhardtii. In the mutant, all the major glycoproteins, in particular cell wall proteins, show a decreased apparent molecular weight in polyacrylamide gels, and their antigenicity is affected. The mutant forms multicellular aggregates (palmelloid colonies) at the restrictive temperature due to the delayed release of the daughter cells from the mother cell wall after mitosis. In addition, the mutation causes sterility by preventing sexual agglutination. In contrast to the other phenotypes, the sterility phenotype is temperature independent, and it is expressed only by cells of the plus mating type. We show that imp-8, a previously described nonagglutinating sex-limited mutation, causes the same glycosylation defect and is allelic to gag-1. Thus, expression of mt+ agglutinability appears to require the specific type of O-glycosylation that is defective in these mutants. More generally, these observations show that a sex-limited phenotype can be caused by a mutation in a gene that is not itself sex limited in its expression.

Extensive accumulation of an extracellular L-amino-acid oxidase during gametogenesis of Chlamydomonas reinhardtii.

In a previous study [Bulté, L. & Wollman, F.-A. (1992) Eur. J. Biochem. 204, 327-336], we identified a novel gamete-specific polypeptide of Chlamydomonas reinhardtii, M alpha. This 66-kDa polypeptide reacts with antibodies to cytochrome f and accumulates in gametes only in conditions that promote destabilisation of the cytochrome b6/f complex. Here, we show that M alpha is not a modification product of cytochrome f, but is part of protein M, a high-molecular-mass L-amino-acid oxidase located in the periplasm. It catalyzes oxidation of all L-amino acids tested, except cysteine. Using phenylalanine as a substrate, saturation of the enzymatic rate is reached at 2 microM. These characteristics suggest that protein M may operate in vivo as an efficient scavanger of ammonium from extracellular amino acids. The enzyme contains non-covalently bound FAD. It exists in two forms with essentially similar enzymatic properties, of 1.2-1.3 MDa and 0.9-1.0 MDa, respectively. The lighter form is an oligomer of M alpha, while the heavier form contains, in addition to M alpha, a second polypeptide of 135 kDa, M beta, in a molar ratio of 3-4 M alpha/M beta. Both polypeptides are glycosylated.

Topological study of PSI-A and PSI-B, the large subunits of the photosystem-I reaction center.

The core of the photosystem-I reaction center is formed by polypeptides PSI-A and PSI-B, the products of the homologous psaA and psaB genes. Based on hydropathy analyses, models have been proposed for the folding of these polypeptide chains in the membrane [Fish, L. E., Kück, U. & Bogorad, L. (1985), in Molecular biology of the photosynthetic apparatus, pp. 111-120, Cold Spring Harbor Laboratory, Cold Spring Harbor, NY]. To test these models, we have tried to identify regions of PSI-A that are exposed to the surrounding medium, on the stromal or lumenal surface of the membrane. Immunogold labeling of thylakoid vesicles, with antibodies to synthetic peptides, shows that residues 413-421 of PSI-A are exposed on the stromal surface of the membrane, and that the accessibility of this region is enhanced by NaSCN treatment, which removes extrinsic polypeptides. This treatment also enhances a trypsin-cleavage site which may lie just after residues 413-421. Immunogold labeling also indicates that residues 371-379 and 497-505 are exposed on the lumenal surface. These results establish the conformation of the central portion of the polypeptide. Assuming that the transmembrane regions are correctly predicted by the 11-helix model, the N-terminal domain, as well as the conserved region proposed to bind the iron-sulfur center FX, would be expected to be on the stromal surface.

Purification and membrane topology of PSI-D and PSI-E, two subunits of the photosystem I reaction center.

Structural studies have been conducted on polypeptides PSI-D and PSI-E, which are extrinsic but firmly bound to the photosystem I reaction center. These subunits are predicted to be involved in the correct interaction with soluble electron acceptor(s), like ferredoxin. We designed an original method to extract both polypeptides directly from thylakoid membranes and to purify them: a stepwise extraction with NaSCN followed by size fractionation and reverse-phase HPLC. Investigation of the in situ topology of PSI-D and PSI-E was undertaken using monoclonal antibody binding, controlled proteolysis, peptide sequencing and electron microscopy. The precise identification of numerous proteolytic sites indicates that the entire N-terminal regions of PSI-E (up to Glu15) and PSI-D (up to Lys15) are exposed to the medium. Partial mapping of the exposed epitopes was possible using purified fragments of each polypeptide. In the case of PSI-E, this mapping confirmed the accessibility of the N-terminal part, and suggested the need for another exposed sequence, probably located after Met39 in the second half of the protein. For PSI-D, this mapping revealed that the sequence between Met74 and Met140, including the most basic amino acid clusters, is also partly accessible. These experiments provide the first detailed informations, although still partial, on the topology of these polypeptides. They give a preliminary basis for hypotheses concerning the sites of interaction with the soluble counterparts.

Lateral redistribution of cytochrome b6/f complexes along thylakoid membranes upon state transitions.

The cytochrome b6/f complex operates in photosynthetic electron transfer either in linear electron flow from photosystem II to photosystem I or in cyclic flow around photosystem I. Using membrane fractionation and immunocytochemistry, we show a change in lateral distribution of cytochrome b6/f complexes along the thylakoid membranes during state transitions. This change is seen in maize as well as in the green algae Chlamydomonas reinhardtii. When either of the two organisms were adapted to state II in vivo, the proportion of cytochrome b6/f complexes found in the photosystem I-enriched stroma lamellae regions was significantly larger than after adaptation to state I. A similar observation was made upon state I to state II transitions done in vitro by illuminating, in the presence of ATP, broken maize chloroplasts prepared from dark-adapted leaves. This reorganization of the electron-transfer chain is concurrent with the change in light-energy distribution between the two photosystems, which requires lateral displacement of light-harvesting complex II. That the changes in lateral distribution of both cytochrome b6/f and light-harvesting II complexes seen upon state transition in vitro similarly required addition of exogenous ATP, suggests that the change in cytochrome b6/f organization also depends on kinase activity. The increased concentration of cytochrome b6/f complexes in the vicinity of photosystem I in state II is discussed in terms of an increase in cyclic electron flow, thus favoring ATP production. Because transition to state II can be triggered in vivo by ATP depletion, we conclude that state transitions should be regarded not only as a light-adaptation mechanism but also as a rerouting of photosynthetic electron flow, enabling photosynthetic organisms to adapt to changes in the cell demand for ATP.

Structural organization of the thylakoid membrane: freeze-fracture and immunocytochemical analysis.

This article summarizes our ultrastructural studies on the organization of the thylakoid membrane of green algae and higher plants. We have used freeze-fracture and immunogold labeling to investigate the lateral distribution of the components in the membrane, their interactions, and the folding of their polypeptide chains in the membrane.

Visualization of antibody binding to the photosynthetic membrane: the transmembrane orientation of cytochrome b-559.

We have used immuno-gold labeling and electron microscopy to study the topography of thylakoid membrane polypeptides. Thylakoid vesicles formed by passage through a French press were adsorbed onto a plastic film supported by an electron microscope grid and processed for single or double immuno-gold labeling. After shadowing with platinum, the inside-out and right-side-out vesicles were identified by their distinctive morphologies. Right-side-out vesicles were labeled by a monoclonal antibody recognizing an epitope located in the trypsin-cleaved, N-terminal portion of the LHC II apoprotein, and by an antibody to CF1. A monoclonal antibody to the alpha-subunit of cytochrome b-559 reacted with a synthetic tridecapeptide corresponding to the C-terminal portion of the polypeptide. Both this antibody and a polyclonal antibody to the synthetic peptide labeled inside-out vesicles exclusively, indicating that the polypeptide C-terminus was exposed on the lumenal (exoplasmic) surface of the membrane.

Thylakoid membrane protein topography: transmembrane orientation of the chloroplast cytochrome b-559 psbE gene product.

Protease accessibility and antibody to a COOH-terminal peptide were used as probes for the in situ topography of the Mr 10,000 psbE gene product (alpha subunit) of the chloroplast cytochrome b-559. Exposure of thylakoid membranes to trypsin or Staphylococcus aureus V8 protease cleaved the alpha subunit to a slightly smaller polypeptide (delta Mr approximately -1000) as detected on Western blots, without loss of reactivity to COOH-terminal antibody. The disappearance of the parent Mr 10,000 polypeptide from thylakoids in the presence of trypsin correlated with the appearance of the smaller polypeptide with delta Mr = -750, the conversion having a half-time of approximately 15 min. Exposure of inside-out vesicles to trypsin resulted in almost complete loss of reactivity to the antibody, showing that the COOH terminus is exposed on the lumenal side of the membrane. Removal of the extrinsic polypeptides of the oxygen-evolving complex resulted in an increase of the accessibility of the alpha subunit to trypsin. These data establish that the alpha subunit of cytochrome b-559 crosses the membrane once, as predicted from its single, 26-residue, hydrophobic domain. The NH2 terminus of the alpha polypeptide is on the stromal side of the membrane, where it is accessible, most likely at Arg-7 or Glu-6/Asp-11, to trypsin or V8 protease, respectively. As a consequence of this orientation, the single histidine residue in the alpha subunit is located on the stromal side of the hydrophobic domain.(ABSTRACT TRUNCATED AT 250 WORDS)

MP26 in the bovine lens: a post-embedding immunocytochemical study.

Gold immunolabeling of bovine lens tissue embedded in Lowicryl K4M, using a polyclonal antibody specific for a major component of lens fiber plasma membrane of 26 K molecular weight, shows that this constituent is absent from the epithelial cell plasma membrane and associated only with the junctional and non-junctional domains of the lens fiber plasma membrane.

[Post-therapeutic development of small cell epitheliomas to malpighian epitheliomas, or initially composite forms? Apropos of 3 cases, review of the literature]. / Evolution post-thérapeutique d'épithéliomas à petites cellules en épithéliomas malpighiens, ou formes composites d'emblée? A propos de 3 cas, revue de la littérature.

Three cases of transformation of small cell carcinomas into squamous cell cancer after chemotherapy are reported. A review of the literature shows that about 7% of small cell carcinomas are associated to different histological types of cancer before treatment. Such an association is found in about 25% of the cases after chemotherapy. Recent biochemical and ultrastructural approaches have led to new concepts concerning the histogenesis of lung cancer. The unicyst theory suggested by some authors could explain the therapy-induced maturation of undifferentiated small cell carcinoma.