A new geminialphasatellite associated with wheat dwarf virus identified in winter barley in France.

Using a high-throughput sequencing (HTS) approach, we report the discovery of a new alphasatellite identified in a winter barley plant collected in France in 2022 that was also infected by wheat dwarf virus (WDV). The presence of the satellite and of WDV was confirmed by several independent PCR assays, and the complete genome sequence was determined. The circular satellite genome is 1424 nt long and shows typical hallmarks of members of the subfamily Geminialphasatellitinae, including a replication-associated hairpin with a CAGTATTAC sequence and a Rep-encoding open reading frame (ORF). It also possesses a second ORF, embedded in a different frame within the Rep ORF, which is also observed in clecrusatellites and a few other members of the family Alphasatellitidae. Pairwise sequence comparisons and phylogenetic analysis showed that this satellite represents a novel species. Its closest relatives are in the genus Colecusatellite, but it likely represents a new genus given its divergence from other genera of the subfamily Geminialphasatellitinae. Given that WDV was the only virus observed in coinfection with the satellite, the name "wheat dwarf virus-associated alphasatellite" is proposed for this novel agent.

A new subunit of cytochrome b6f complex undergoes reversible phosphorylation upon state transition.

A 15.2-kDa polypeptide, encoded by the nuclear gene PETO, was identified as a novel cytochrome b(6)f subunit in Chlamydomonas reinhardtii. The PETO gene product is a bona fide subunit, subunit V, of the cytochrome b(6)f complex, because (i) it copurifies with the other cytochrome b(6)f subunits in the early stages of the purification procedure, (ii) it is deficient in cytochrome b(6)f mutants accumulating little of the complex, and (iii) it colocalizes with cytochrome f, which migrates between stacked and unstacked membrane regions upon state transition. Sequence analysis and biochemical characterization of subunit V shows that it has a one transmembrane alpha-helix topology with two large hydrophilic domains extending on the stromal and lumenal side of the thylakoid membranes, with a lumenal location of the N terminus. Subunit V is reversibly phosphorylated upon state transition, a unique feature that, together with its topological organization, points to the possible role of subunit V in signal transduction during redox-controlled short term and long term adaptation of the photosynthetic apparatus in eukaryotes.

Analysis of the nucleus-encoded and chloroplast-targeted rieske protein by classic and site-directed mutagenesis of Chlamydomonas.

Three mutants of the alga Chlamydomonas reinhardtii affected in the nuclear PETC gene encoding the Rieske iron-sulfur protein 2Fe-2S subunit of the chloroplast cytochrome b(6)f complex have been characterized. One has a stable deletion that eliminates the protein; two others carry substitutions Y87D and W163R that result in low accumulation of the protein. Attenuated expression of the stromal protease ClpP increases accumulation and assembly into b(6)f complexes of the Y87D and W163R mutant Rieske proteins in quantities sufficient for analysis. Electron-transfer kinetics of these complexes were 10- to 20-fold slower than those for the wild type. The deletion mutant was used as a recipient for site-directed mutant petC alleles. Six glycine residues were replaced by alanine residues (6G6A) in the flexible hinge that is critical for domain movement; substitutions were created near the 2Fe-2S cluster (S128 and W163); and seven C-terminal residues were deleted (G171och). Although the 6G6A and G171och mutations affect highly conserved segments in the chloroplast Rieske protein, photosynthesis in the mutants was similar to that of the wild type. These results establish the basis for mutational analysis of the nuclear-encoded and chloroplast-targeted Rieske protein of photosynthesis.

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.

Function-directed mutagenesis of the cytochrome b6f complex in Chlamydomonas reinhardtii: involvement of the cd loop of cytochrome b6 in quinol binding to the Q(o) site.

The FUD2 mutant from the green alga Chlamydomonas reinhardtii expresses a cytochrome b6 variant of higher apparent molecular mass [Lemaire et al. (1986) Biochim. Biophys. Acta 851, 239-248]. Here, we show that the mutation corresponds to a 36 base pair duplication in the chloroplast petB gene, which corresponds to a 12 amino acid duplication in the cd loop of cytochrome b6. The resulting protein still binds its heme cofactors and assembles into cytochrome b6f complexes, which accumulate in wild type amounts in exponentially growing cells of FUD2. However, these cytochrome b6f complexes show loosened binding of the Rieske protein and are more prone to degradation in aging cells. Electron transfer through the cytochrome b6f complexes is about 8 times slower in FUD2 than in wild type cells. This is due to a slower oxidation of plastoquinol at the Q(o) site, the folding of which is most likely altered by the duplication. By varying the redox state of the plastoquinone pool in vivo, we show that there is a dramatic decrease in the affinity of the Q(o) site for plastoquinols, which is about 100 times lower in FUD2 than in wild type cells. Our results show that the value of the binding constant of plastoquinol to the Q(o) site (2 x 10(4) M(-1)) derived in [Kramer et al. (1994) Biochim. Biophys. Acta 1184, 251-262] may be extrapolated to in vivo conditions.

Molecular genetic identification of a pathway for heme binding to cytochrome b6.

Heme binding to cytochrome b6 is resistant, in part, to denaturing conditions that typically destroy the noncovalent interactions between the b hemes and their apoproteins, suggesting that one of two b hemes of holocytochrome b6 is tightly bound to the polypeptide. We exploited this property to define a pathway for the conversion of apo- to holocytochrome b6, and to identify mutants that are blocked at one step of this pathway. Chlamydomonas reinhardtii strains carrying substitutions in either one of the four histidines that coordinate the bh or bl hemes to the apoprotein were created. These mutations resulted in the appearance of distinct immunoreactive species of cytochrome b6, which allowed us to specifically identify cytochrome b6 with altered bh or bl ligation. In gabaculine-treated (i.e. heme-depleted) wild type and site-directed mutant strains, we established that (i) the single immunoreactive band, observed in strains carrying the bl site-directed mutations, corresponds to apocytochrome b6 and (ii) the additional band present in strains carrying bh site-directed mutations corresponds to a bl-heme-dependent intermediate in the formation of holocytochrome b6. Five nuclear mutants (ccb strains) that are defective in holocytochrome b6 formation display a phenotype that is indistinguishable from that of strains carrying site-directed bh ligand mutants. The defect is specific for cytochrome b6 assembly, because the ccb strains can synthesize other b cytochromes and all c-type cytochromes. The ccb strains, which define four nuclear loci (CCB1, CCB2, CCB3, and CCB4), provide the first evidence that a b-type cytochrome requires trans-acting factors for its heme association.

The 4-kDa nuclear-encoded PetM polypeptide of the chloroplast cytochrome b6f complex. Nucleic acid and protein sequences, targeting signals, transmembrane topology.

The 4-kDa subunit of cytochrome b6f complex encoded by the nuclear PetM gene in Chlamydomonas reinhardtii has been characterized. 38 of the 39 residues of the mature protein have been established by Edman degradation, a cDNA clone encoding the complete precursor has been isolated and sequenced, and a 0.6-kb transcript detected. The deduced amino acid sequence of the precursor includes an N-terminal transit peptide of 60 amino acids with stromal targeting features. Examination of the sequence suggests that PetM spans the membrane as a single transmembrane alpha-helix, which is supported by its non-extractability following dissociating treatments. When PetM and PetG, another small subunit of the b6f complex, are folded into alpha-helices, an array of identical residues becomes apparent. Proteolysis data, charge distribution, and homology with PetG are consistent with a lumenal localization of the N terminus of PetM.

Membrane association of cytochrome b6f subunits. The Rieske iron-sulfur protein from Chlamydomonas reinhardtii is an extrinsic protein.

The mode of membrane attachment of five subunits from Chlamydomonas reinhardtii cytochrome b6f complex has been studied using biochemical approaches. Antisera specific for cytochrome f, cytochrome b6, the Rieske iron-sulfur protein, subunit IV, and a 4-kDa subunit (product of the petG gene) were used to quantify the degree of extraction of each of these polypeptides following various treatments. In contrast to the other four subunits, the Rieske protein was extracted to extents varying between 50 and 100% following two cycles of freezing and thawing in the presence of chaotropic agents (KSCN, urea, or NaI). The Rieske protein was not extracted by 2 M NaCl and was rather resistant to alkaline treatments, being extracted by 20 mM 3-(cyclohexylamino)propanesulfonic acid buffer only at pH > 11.5. The hydrodynamic behavior of the isolated Rieske protein was examined in the absence and presence of detergent by ultracentrifugation and by molecular sieving. The extracted protein bound neither to laurylmaltoside nor to C12E8 micelles. Its sedimentation coefficient (D20,w = 9.6 x 10(-11) m2 x s-1), diffusion coefficient (s20,w = 2S), an deduced molecular mass (20.0 +/- 1.7 kDa) are those expected for the monomeric protein. We conclude that the Rieske protein is extrinsic and therefore does not cross the membrane, although its association with the rest of the complex involves primarily hydrophobic interactions, and that the other four subunits analyzed are intrinsic.

Characterization of the gene of the chloroplast Rieske iron-sulfur protein in Chlamydomonas reinhardtii. Indications for an uncleaved lumen targeting sequence.

The sequence of the nuclear gene encoding the Rieske iron-sulfur protein of the cytochrome b6f complex of Chlamydomonas reinhardtii has been established. Comparison of genomic clones and amplified cDNA indicates that the petC gene is interrupted by four introns within the coding sequence of the mature protein. The nucleotide sequence predicts a precursor protein of 206 amino acid residues with a transit peptide of 29 amino acids. The transit peptide is shorter than that of higher plants and has a basic region typical for the transfer through the chloroplast envelope, but no hydrophobic segment at the C-terminal end as is found in proteins transferred through the thylakoid membrane. The mature protein shows a high degree of homology with that of higher plants and has an N-terminal hydrophobic segment as in other Rieske proteins. Biochemical data (Breyton, C., de Vitry, C., and Popot, J.-L. (1994) J. Biol. Chem. 269, 7597-7602) indicate that the chloroplast Rieske protein of C. reinhardtii is an extrinsic membrane protein. Therefore, this N-terminal hydrophobic segment is not a transmembrane segment but may act as an uncleaved N-terminal thylakoid membrane transfer signal sequence. There are other examples of uncleaved hydrophobic membrane transfer signal in secreted proteins, although these are rare.

Identification of mitochondrial proteins in membrane preparations from Chlamydomonas reinhardtii.

Preparations enriched in Chlamydomonas reinhardtii thylakoids have proven useful in the study of photosynthesis. Many of their polypeptides however remain unidentified. We report here on three of those, h1 (34 kDa), h2 (11 kDa), and P3 (63 kDa). h1, h2, and P3 are present in all tested mutants of C. reinhardtii lacking either one or several of the photosynthetic chain complexes or depleted in thylakoid membranes. h2 is an ascorbate-reducible, soluble c550-type cytochrome encoded in the nucleus. It cross-reacts immunologically with mitochondrial cytochromes c from various sources and contains a hexapeptide encoded in C. reinhardtii cytochrome c cDNA. P3, a nuclear-encoded peripheral protein, cross-reacts with various ATP synthase beta subunits. Its N-terminal sequence is encoded in C. reinhardtii mitochondrial beta subunit cDNA. h1 behaves as an integral hemoprotein; it is absent in a mitochondrial mutant that carries a deletion in apocytochrome b gene. We conclude that C. reinhardtii mitochondrial membranes copurify with thylakoid membranes. h1 is part of the cytochrome bc1 complex, h2 is cytochrome c, and P3 is the beta subunit of mitochondrial ATP synthase.

Photosystem II particles from Chlamydomonas reinhardtii. Purification, molecular weight, small subunit composition, and protein phosphorylation.

PSII particles from Chlamydomonas reinhardtii were purified according to the protocol of Diner and Wollman (Diner, B.A., and Wollman, F.-A. (1980) Eur. J. Biochem. 110, 521-526) followed by ion-exchange chromatography. They contained the psbA, psbB, psbC, and psbD gene products in a 1/1/1/1 stoichiometry, cytochrome b559, and several small polypeptides, and exhibited electron transfer from donor Z to acceptor QA (40-50 chlorophylls/reducible QA). Upon ultracentrifugation and molecular sieving in the presence of either lauryl maltoside or octaethylene glycol dodecyl ether (C12E8), they behaved as monomers of 440-510 kDa, including the detergent. C12E8 preparations also contained a small proportion of a partially interconvertible dimeric form. Four small subunits were identified by N-terminal sequencing, namely a 6.1-kDa nuclear-encoded subunit and three chloroplast-encoded subunits homologous to psbE, psbK, and psbM gene products. Cytochrome b559 subunit alpha (psbE) of C. reinhardtii, but not subunit beta (psbF), was recognized by an antiserum raised against higher plant cytochrome b559. The products of the psbF, psbI, and psbN genes remained undetected, presumably because of blocked N termini. At least four polypeptides presented both phosphorylated and unphosphorylated forms (psbC, psbD, and psbH gene products, as well as an unidentified 5-kDa subunit).

The "microassembly" of integral membrane proteins: applications & implications.

We summarize some evidence in favor of the view that the transmembrane region of many, perhaps most integral membrane proteins is made up of an aggregate of hydrophobic alpha-helices, each of which behaves as an autonomous folding domain. Folding of these proteins is seen as a two-stage process during which individual transmembrane helices first form in response to local interactions between the polypeptide and the aqueous and lipid phases, and then pack without extensive rearrangement to yield the three-dimensional structure. This two-stage model is supported by examination of those few structures that are known to a sufficient resolution, by experiments in which functional integral membrane proteins are "microassembled" from separately folded fragments, and by the existence in the inner membranes of organelles of a large number of very small integral subunits, often barely longer than a single transmembrane alpha-helix. We describe application of microassembly to establishing the path of the polypeptide in the tertiary structure of bacteriorhodopsin by neutron diffraction and we briefly discuss its possible role in the biosynthesis of organelle inner membrane complexes and its implications for model building from sequence data.

Posttranslational events leading to the assembly of photosystem II protein complex: a study using photosynthesis mutants from Chlamydomonas reinhardtii.

We studied the assembly of photosystem II (PSII) in several mutants from Chlamydomonas reinhardtii which were unable to synthesize either one PSII core subunit (P6 [43 kD], D1, or D2) or one oxygen-evolving enhancer (OEE1 or OEE2) subunit. Synthesis of the PSII subunits was analyzed on electrophoretograms of cells pulse labeled with [14C]acetate. Their accumulation in thylakoid membranes was studied on immunoblots, their chlorophyll-binding ability on nondenaturating gels, their assembly by detergent fractionation, their stability by pulse-chase experiments and determination of in vitro protease sensitivity, and their localization by immunocytochemistry. In Chlamydomonas, the PSII core subunits P5 (47 kD), D1, and D2 are synthesized in a concerted manner while P6 synthesis is independent. P5 and P6 accumulate independently of each other in the stacked membranes. They bind chlorophyll soon after, or concomitantly with, their synthesis and independently of the presence of the other PSII subunits. Resistance to degradation increases step by step: beginning with assembly of P5, D1, and D2, then with binding of P6, and, finally, with binding of the OEE subunits on two independent high affinity sites (one for OEE1 and another for OEE2 to which OEE3 binds). In the absence of PSII cores, the OEE subunits accumulate independently in the thylakoid lumen and bind loosely to the membranes; OEE1 was found on stacked membranes, but OEE2 was found on either stacked or unstacked membranes depending on whether or not P6 was synthesized.