©1996 by The American Society for Biochemistry and Molecular Biology, Inc.
The 4-kDa Nuclear-encoded PetM Polypeptide of the Chloroplast Cytochrome bf Complex
NUCLEIC ACID AND PROTEIN SEQUENCES, TARGETING SIGNALS, TRANSMEMBRANE TOPOLOGY (*)

(Received for publication, November 3, 1995; and in revised form, February 16, 1996)

Catherine de Vitry (§) Cécile Breyton Yves Pierre Jean-Luc Popot

From the Service de Photosynthèse, CNRS/URA 1187, Institut de Biologie Physico-Chimique, 13 rue Pierre et Marie Curie, F-75005 Paris, France

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
FOOTNOTES
ACKNOWLEDGEMENTS
REFERENCES

ABSTRACT

The 4-kDa subunit of cytochrome b(6)f 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 b(6)f 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.


INTRODUCTION

The cytochrome b(6)f complex catalyzes electron transfer from plastoquinol to an acceptor protein (plastocyanin or a soluble cytochrome) in the photosynthetic membrane of plants, algae, and some bacteria. A homologous complex, cytochrome bc(1), plays a comparable role in mitochondria and in several prokaryotes. The cytochrome b(6)f complex of Chlamydomonas reinhardtii(1, 2, 3) is similar to that of higher plants(4) . It is comprised of four high molecular mass subunits: cytochrome f (petA gene product), cytochrome b(6) (petB gene product), subunit IV (petD gene product) (homologous to the C-terminal region of mitochondrial cytochrome b), all three of them chloroplast-encoded, and the Rieske iron-sulfur protein (PetC gene product), which is nuclear-encoded. Three hydrophobic and very small (4 kDa) proteins are also present: two of them, PetG (petG gene product) and PetL (petL gene product), are chloroplast-encoded and one, PetM (PetM gene product), is nuclear-encoded. PetG has been characterized as a b(6)f subunit in maize (5) and identified in C. reinhardtii b(6)f complex(6, 7) . PetL has been characterized by deletion of the chloroplast petL gene and immunoblot analysis of purified b(6)f complex in C. reinhardtii(8) . Gene petL is also present in higher plant chloroplast genomes.

Concerning PetM, we have previously identified by protein sequencing and immunodetection a 4-kDa polypeptide that is present in purified b(6)f complexes and absent in b(6)f-deficient mutants from C. reinhardtii(7) ; we provisionally designated this novel b(6)f subunit PetX, product of the nuclear petX gene(7, 9) . To conform to the alphabetical order recommended for gene nomenclature, we shall from now on refer to this protein as PetM (b(6)f complex subunit 7). PetM has been independently identified in C. reinhardtii and in spinach b(6)f by Schmidt and Malkin(6) . PetM is translated as a precursor in the cytoplasm and imported into the chloroplast. In the present work, we have determined 38 of the 39 residues of the mature protein by Edman degradation, isolated, and sequenced a cDNA clone encoding the complete precursor of PetM, whose transit peptide has features of a stromal-targeting peptide, and studied PetM transmembrane topology by dissociating treatments and trypsinization.


EXPERIMENTAL PROCEDURES

Protein Sequencing

b(6)f complex was purified by solubilization of thylakoid membranes with 6-O-(N-heptylcarbamoyl)-methyl-alpha-D-glycopyranoside, centrifugation on sucrose density gradient, and hydroxylapatite chromatography(3) . After urea/SDS-PAGE, purified b(6)f complex was electrotransferred onto Prot Blott(TM) membranes (Applied Biosystems) in a semidry blotting system at 0.8 mA/cm^2 for 30 min(10) . Sequencing of the 4 kDa band by Edman degradation was performed by J. d'Alayer (Laboratoire de Microséquençage des Protéines, Institut Pasteur, Paris). This band contains PetG, PetL, and PetM, but under our experimental conditions the only unblocked N terminus is that of PetM(7, 8, 9, 11) .

Screening of cDNA Library, DNA Sequencing, and RNA Analysis

A C. reinhardtii cDNA library cloned into -GT10(12) , kindly provided by M. Goldschmidt-Clermont (University of Geneva), was replicated in Escherichia coli C600. Screening by plaque hybridization and isolation of positive clones were performed using oligonucleotide primers based on the amino acid sequence of the N terminus of PetM (Fig. 2) and [P]ATP-phosphorylated by T4 polynucleotide kinase. The EcoRI insert was isolated from one of the phage isolates, subcloned into Bluescript KS, and sequenced by the dideoxy chain termination method. Total RNA was analyzed as described in (13) using as a probe the EcoRI insert encoding PetM.


Figure 2: Oligonucleotides used for cloning and corresponding amino acid sequences.



Preparation of Antipeptide Antisera

An antiserum was raised against a synthetic peptide corresponding to the C terminus of PetM (Fig. 1), coupled to ovalbumin by an additional tyrosine at its N terminus, as described in (14) . We have described elsewhere the antisera against PSII subunit OEE3(15) , the N terminus of PetM(7) , and subunit IV(3) .


Figure 1: N-terminal sequence of PetM obtained by protein sequencing. Bold italics indicate the sequences of the synthetic peptides used to raise antibodies. Sequences used to design oligonucleotide probes are underlined.



Protein Electrophoresis, Transfer, and Immunoblotting

Urea/SDS-PAGE and electrotransfer were performed as described previously(10) . Immunodetection was carried out by labeling either with I-protein A using anti-PetM antisera at a dilution of 1/50 or with the enhanced chemiluminescence method (Amersham Corp.) using anti-OEE3 and anti-subunit IV antisera at dilutions of 1/20,000 and 1/10,000, respectively. Procedures were as described in (14) .

Polypeptide Extraction from Thylakoid Membranes

Polypeptide extraction from thylakoid membranes was performed as described in (14) . Thylakoid membranes were incubated with a dissociating agent (6.8 M urea, 2 M KSCN, or 1.5 M NaI in Tricine (^1)buffer, pH 8.0, or 20 M CAPS, pH 12.0) for 10 min at room temperature, frozen/thawed, and centrifuged. In order to improve the immunodetection of PetM, the pigments and lipids of the pellets were extracted by incubating 15 µl of the resuspended pellet in 100 µl of ice-cold methanol for 10 min, followed by addition of 900 µl of ice-cold ether, 10-min incubation on ice, and centrifugation for 10 min at 12,500 times g. The resulting pellet was resuspended in 15 µl of 100 mM dithiothreitol, 100 mM Na(2)CO(3), 2.5% SDS solution, and analyzed by urea/SDS-PAGE along with the supernatant of the first extraction.

Trypsinization of Thylakoid Membranes

Thylakoid membranes (16) were washed twice with 10 mM Tris, pH 7.8, without protease inhibitors. Various concentrations (from 0 to 25 µg/ml) of trypsin (L-1-tosylamido-2-phenylethyl chloromethyl ketone-treated, type XIII from bovine pancreas, Sigma) were added to thylakoid membranes at a final chlorophyll concentration of 1 mg/ml. Half of each sample was sonicated for 20 s on ice. Trypsin treatments were performed at room temperature for 1 h and the reaction arrested by methanol/ether extraction. The resulting pellet was resuspended in 100 mM dithiothreitol, 100 mM Na(2)CO(3), 2.5% SDS, and proteases inhibitors (200 µM phenylmethylsulfonyl fluoride, 1 mM benzamidine, 5 mM -aminocaproic acid) and analyzed by urea/SDS-PAGE and immunoblotting. The efficiency of proteolysis blockade is demonstrated by the differential cleavage of lumenal proteins depending on whether thylakoid membrane vesicles are disrupted by sonication or not.

Hydrophobicity Analysis

The presence of putative transmembrane hydrophobic alpha-helices was assessed using the GES scale (17) and a 17-residue window(18) . Sequences are from Refs. 9, 19, and 20.^1


RESULTS AND DISCUSSION

N-terminal Amino Acid Sequence of PetM

Sequencing of PetM by Edman degradation yielded 38 residues, which corresponds almost to the entire mature protein (Fig. 1). Our previous data were limited to 28 residues(7) . The additional information allowed us to design better oligonucleotide probes and to raise an antipeptide antiserum recognizing PetM C terminus.

Nucleic Acid Sequence and Messenger RNA

Based on this amino acid sequence, two oligonucleotide primers (Fig. 2) were synthesized and used to screen a C. reinhardtii cDNA library cloned into -gt10(12) . The EcoRI insert isolated from one of the phage isolates was subcloned into Bluescript KS and sequenced. The insert was 556 bp long with a putative polyadenylation signal located 13 nucleotides upstream from the poly(A) tail (Fig. 3). The transcript of the PetM gene is 0.6 kb long (Fig. 4), which corresponds to the size of the insert.


Figure 3: Nucleotide and amino acid sequence of PetM (EMBL accession number X92488). The deduced amino acid sequence is in bold type, the amino acid sequence determined by Edman degradation is in italics. The arrow indicates the processing site. The hydrophobic region likely to correspond to a transmembrane alpha-helix is underlined.




Figure 4: Northern blot of total RNA from C. reinhardtii wild-type cells probed with PetM cDNA. Ribosomal RNA was used for molecular weight determination.



The Transit Peptide: Similarity to a Stromal-targeting Peptide

There are two in-frame ATG codons at the beginning of the PetM coding sequence. The deduced amino acid sequence begins with MetAlaMet as in the C. reinhardtii Rieske protein(21) . C. reinhardtii initiation regions have a consensus sequence with AUG generally preceded by an A-rich tetranucleotide similar to that of higher plants AACAAUGGC (see (21) and references therein). Therefore, the first methionine codon (CAAAATGGC) seems more likely to be the initiation codon than the second (GGCCATGTC). Starting at the first ATG, the precursor protein is 99 residue long with a molecular mass of 10.0 kDa. The site of processing is indicated by the N-terminal sequence of the mature protein(6, 7, 9) . Starting at the first ATG, the transit peptide is 60 residues long with a molecular mass of 6.0 kDa, which is larger than the mature protein. It comprises (i) a short uncharged N-terminal region, (ii) a central region rich in residues with basic (Arg, Lys) or small (Ala, Ser) side chains, (iii) an alanine residue preceding the processing site (Fig. 3). These features are typical of transit peptides directing transfer through the chloroplast envelope(22, 23) . However, at variance with the transit peptides of most of the proteins transferred through the thylakoid membrane(22, 24) , that of PetM contains no hydrophobic segment in its C-terminal region (Fig. 5) and has only features of a stromal-targeting sequence.


Figure 5: Hydrophobicity profile of PetM precursor. The free energy of transfer from lipids to water calculated using the GES scale has been averaged over a 17-residue window. , processing site. In integral membrane proteins most sequence segments with average hydrophobicity > 1.3 kcal/residue (dotted line) correspond to transmembrane helices (18) .



The Mature Protein: a 4-kDa Hydrophobic Protein

The mature protein is 39 residues long with a molecular mass of 4.0 kDa, matching its apparent molecular mass in urea/SDS-PAGE of 4 kDa (7) or 3.8 kDa (6) . The sequence of the mature protein established by Edman degradation is identical to that deduced from the cDNA sequence, except that it lacks the last residue (Fig. 3), which probably originates from the low yield often observed for the last amino acid in protein sequencing. The mature protein features a 24-residue hydrophobic segment likely to form a transmembrane alpha-helix (Fig. 5). The average hydrophobicity of the most hydrophobic 17-amino acid residue stretch of PetM (2.3 kcal/residue on the GES scale) is among the highest among putative transmembrane alpha-helices of b(6)f subunits (b(6), 1.9 (average of four alpha-helices); IV, 2.2 (average of three alpha-helices); and f, 2.3; PetG, 2.2; PetL, 2.2 (1 alpha-helix)). A systematic examination of hydrophobic segments in the sequences of integral membrane proteins has revealed no segments with such a high hydrophobicity that would not be transmembrane(18) . The lateral amphipathy of the putative alpha-helix is low.

Transmembrane Topology: a Single alpha-Helix with Short Extramembrane Segments

The mode of association of PetM with the thylakoid membrane was probed using various dissociating treatments. Cytochrome f, cytochrome b(6), subunit IV, PetG, and PetL cannot be extracted by these treatments(14) ,^1 indicating that they are intrinsic membrane proteins, whereas the Rieske protein is extrinsic(8, 14) . Thylakoid membranes were incubated for 10 min in the dissociating solutions, subjected to two freeze/thaw cycles, centrifuged, and the pellet and supernatant analyzed by urea/SDS-PAGE and immunoblotting. As shown in Fig. 6, PetM is not extracted by dissociating treatments (6.8 M urea; 2 M KSCN; 1.5 M NaI; 20 mM CAPS, pH 12.0), as is the case for transmembrane polypeptides (e.g. subunit IV (IV) in Fig. 6) and in contrast to peripheral polypeptides (e.g. polypeptide OEE3 (OEE3) in Fig. 6).


Figure 6: Extraction of thylakoid proteins by various dissociating treatments. Thylakoid membranes were treated either with 20 mM Tricine, pH 8.0, or with 6.8 M urea, 2 M KSCN or 1.5 M NaI in Tricine, pH 8.0, or with 20 mM CAPS, pH 12.0. S, supernatant, P, pellet. The immunoblot was labeled with antisera directed against the extrinsic protein OEE3 (OEE3), the intrinsic subunit IV (IV), or the N terminus of PetM (PetM).



Purified preparations of b(6)f complex contain one molecule of chlorophyll a per cytochrome f(3, 4, 11, 25) . A spectral shift associated with functioning of the b(6)f suggests that it is located in the vicinity of the Q(0) site (26) . Our attempts to detect chlorophyll a binding to PetM using low temperature SDS-PAGE (27) have been unsuccessful. Subunits with a single transmembrane alpha-helix and short extramembrane segments are numerous in the thylakoid membrane and inner mitochondrial membrane complexes(18, 28) . Most of them have no known cofactors. Deletion of their coding gene usually destabilizes the complex to which they belong, as is the case for PetG (29) and, to a lesser extent, for PetL (8) . Directed deletion of nuclear genes is difficult to achieve in C. reinhardtii because of the low efficiency of homologous recombination. It is not yet known whether PetM is also present in prokaryotic photosynthetic organisms, in which directed mutagenesis is more efficient.

N Terminus: Indications for a Localization on the Lumenal Side of the Membrane

The ``positive-inside'' rule applies to thylakoid membrane proteins, regions enriched in basic residues on average facing the stroma(30) . The presence of basic residues in the C terminus of PetM suggests its stromal localization. In order to test this prediction, thylakoid membranes were trypsinized for 1 h at room temperature, with and without sonication. Trypsin has two potential cleavage sites in the C terminus of PetM (Arg and Lys). Blots were probed with antisera raised against peptides corresponding to the N terminus and C terminus of PetM (Fig. 7A). While the specificity of the antisera is not complete (particularly as regards the C terminus antiserum, which is very weak), immunostaining of the blots in the 4-kDa region is specific for PetM, since it is not observed when membranes from the b(6)f-less C. reinhardtii mutant FUD4 are used ( (7) and data not shown). In contrast to lumenal proteins, whose trypsinization increases when thylakoid vesicles are disrupted by sonication (e.g. OEE1, OEE2, and OEE3 in Fig. 7B), PetM was cleaved by trypsin to a similar extent in both intact and sonicated vesicles (Fig. 7C). As revealed by antisera against PetM N and C termini, intact and proteolyzed PetM are not resolved by urea/SDS-PAGE (Fig. 7C) (PetM, PetG, and PetL also comigrate in this gel system; (7, 8, 9) and 11). Decreased immunolabeling with the antiserum directed against PetM C terminus was expected from proteolysis from the stromal side; it did decrease to a similar extent in sonicated and intact vesicles with increasing trypsin concentrations from 0 to 5 µg/ml (Fig. 7C). Labeling with the anti-N terminus was still strong after exposure to trypsin at 25 µg/ml, as expected from the absence of a trypsin cleavage site in PetM N terminus. However, the labeling with anti-PetM-N terminus decreases with increasing trypsin concentrations. This may reflect a change of electrophoretic migration following cleavage of PetM. Altogether, these data suggest that the C terminus of PetM is exposed to the stroma.


Figure 7: Proteolysis of thylakoid membrane proteins by trypsin. Analysis by urea/SDS-PAGE. A, PetM immunodetection on methanol/ether extracted membranes using antisera raised against the N terminus (N-term) and the C terminus (C-term); mb, membranes. B, polypeptide pattern after incubation with increasing trypsin concentrations (0, 3, 6, 12, and 24 µg/ml); s, vesicles were sonicated in the presence of trypsin; gel was stained with Coomassie Brilliant Blue; note the effect of sonication on the degradation of the lumenal protein OEE3. C, PetM immunodetection after incubation with trypsin. b(6)f, purified b(6)f complex; the polypeptide band noted () in the purified b(6)f indicates PetM; the two cross-reacting bands noted by the asterisks are a thylakoid membrane polypeptide detected in the absence of trypsin and a degradation product detected in its presence.



PetG has been shown to also feature a single transmembrane alpha-helix whose N terminus is lumenal(5) . Residue identities between PetM and PetG are limited (29% in the putative transmembrane region). However, a zone of identity becomes apparent when PetM and PetG are modeled to form alpha-helices (Fig. 8). This similarity (which is not observed with PetL) suggests either a common ancestry or convergent evolution. If not coincidental, it may indicate that PetG and PetM share similar functions and, presumably, span the membrane with the same orientation, i.e. a lumenal N terminus, in keeping with the distribution of basic residues in their sequences as well as with proteolysis data (Fig. 8). Determination of PetM sequences from other organisms will be necessary in order to test the generality of this observation. Gene duplication has been proposed previously to account for similarities between the nuclear-encoded subunit II and the chloroplast-encoded subunit I from C. reinhardtii CF(0), both of which are homologous to F(0) subunit b from E. coli(31) .


Figure 8: Putative transmembrane arrangement of PetM and PetG. PetG sequence from (29) . Identical residues are boxed.



PetG is chloroplast-encoded and has no transit peptide(5) . We show here that PetM has a transit peptide with only the features of a stromal-targeting peptide. Nonetheless, a lumenal localization of the N termini of both proteins implies that these can be translocated across the thylakoid membrane. In bacteria, translocation of N termini across the inner membrane is most efficient when they are short and contain few positively charged residues; translocation in these cases is Sec-independent and depends on the membrane potential(32) . The N termini of PetG and PetM are both very short and very poor in positive charges. Analogy with bacteria would suggest that their translocation is Sec-independent and dependent on the membrane potential. Studies of this process should lead to further insights into the mechanisms of protein translocation across thylakoid membranes.

Conclusion

Three b(6)f subunits belonging to the class of proteins forming a single transmembrane alpha-helix with short extramembrane segments have now been characterized. Two are chloroplast-encoded, PetG (5) and PetL(8) . One is nuclear-encoded, PetM(6, 7, 9) ; the present work establishes the cDNA sequence of PetM, as well as the amino acid sequence, the targeting signals and the transmembrane topology of its product.


FOOTNOTES

*
This work was supported by the CNRS, the Collège de France, the Commissariat à l'Energie Atomique, and by grants from the European Economic Community (BIO2CT930076 and HC&) and from the Ministère de la Recherche et de la Technologie (87C0385). The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore by hereby marked ``advertisement'' in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

The nucleotide sequence(s) reported in this paper has been submitted to the GenBank(TM)/EMBL Data Bank with accession number(s) U36401[GenBank].

§
To whom correspondence should be addressed. Tel.: 33-1-43-25-26-09; Fax: 33-1-40-46-83-31; devitry{at}ibpc.fr.

(^1)
The abbreviations used are: Tricine, N-[2-hydroxy-1,1-bis(hydroxymethyl)ethyl]glycine; CAPS, 3-(cyclohexylamino)-1-propanesulfonic acid; OEE, oxygen evolution enhancer; PAGE, polyacrylamide gel electrophoresis.


ACKNOWLEDGEMENTS

We thank M. Goldschmidt-Clermont for the cDNA library, J. d'Alayer for amino acid sequencing, Y. Choquet and D. Drapier for advice during the course of this work, and H. Couratier for the photographic work.


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