(Received for publication, May 22, 1997, and in revised form, June 22, 1997)
From the Department of Biochemistry and Biophysics, Iowa State University, Ames, Iowa 50011
PsaA and PsaB are homologous integral membrane proteins that form the heterodimeric core of photosystem I. Domain-specific antibodies were generated to examine the topography of PsaA and PsaB. The purified photosystem I complexes from the wild type strain of Synechocystis sp. PCC 6803 were treated with eight proteases to study the accessibility of cleavage sites in PsaA and PsaB. Proteolytic fragments were identified using the information from N-terminal amino acid sequencing, reactivity to antibodies, apparent mass, and specificity of proteases. The extramembrane loops of PsaA and PsaB differed in their accessibility to proteases, which indicated the folded structure of the loops or their shielding by the small subunits of photosystem I. NaI-treated and mutant photosystem I complexes were used to identify the extramembrane loops that were exposed in the absence of specific small subunits. The absence of PsaD exposed additional proteolytic sites in PsaB, whereas the absence of PsaE exposed sites in PsaA. These studies distinguish PsaA and PsaB in the structural model for photosystem I that has been proposed on the basis of x-ray diffraction studies (Krauß, N., Schubert, W.-D., Klukas, O., Fromme, P., Witt, H. T., and Saenger, W. (1996) Nat. Struct. Biol. 3, 965-973). Using osmotically shocked cells for protease treatments, the N terminus of PsaA was determined to be on the n side of the photosynthetic membranes. Based on these data and available published information, we propose a topological model for PsaA and PsaB.
Photosystem I (PS I)1
from cyanobacteria and chloroplasts is a multisubunit membrane-protein
complex that catalyzes electron transfer from reduced plastocyanin (or
cytochrome c6) to oxidized ferredoxin (or
flavodoxin) (1-4). The PsaA and PsaB subunits of PS I form the
heterodimeric core of the complex which harbors approximately 100 antenna chlorophyll a molecules, 10-12 -carotenes, the
primary electron donor P700, and a chain of electron acceptors (A0, A1, and FX). PsaA and PsaB also
interact directly with plastocyanin or cytochrome
c6 (5-7). In addition to the core proteins, the cyanobacterial PS I complex contains 9 small subunits (1-3). PsaC
binds the terminal electron acceptors FA and
FB, which are two [4Fe-4S] center (8). PsaD provides an
essential ferredoxin-docking site on the reducing side of PS I (9-11)
and is required for the stable assembly of PsaC and PsaE into the PS I
complex (12, 13). PsaE is involved in ferredoxin docking (10, 14-16)
and in cyclic electron flow around PS I (17, 18). PsaF provides a
component of the docking site for plastocyanin in the plant PS I (7,
19, 20) but not in the cyanobacterial PS I (6, 21). PsaL is essential
for the formation of PS I trimers in cyanobacteria (22). PsaI and PsaJ
are required for the correct organization of PsaL and PsaF,
respectively (23, 24). The absence of PsaM in cyanobacterial mutants
causes deficiency in growth at high light intensity and affects stable
assembly of PsaD.2,3
The role of PsaK has not been identified.
During the past few years, major advances in x-ray crystallography (25,
26), electron microscopy (27), molecular genetics (10, 22), and
biochemical studies (28, 29) have provided a framework for
understanding the overall architecture of PS I. The PS I complex has an
elongated shape with a local pseudo-2-fold symmetry. PsaC, PsaD, and
PsaE are peripheral subunits, located on the n side (stromal
side in chloroplasts and cytoplasmic side in cyanobacteria) of
photosynthetic membranes, with PsaC positioned in the center of each
monomeric PS I on the axis of symmetry (26, 27). The recent crystal
analysis of PS I has indicated the location of [4Fe-4S] clusters
FX, FA, and FB, 71 chlorophyll
a molecules, 31 transmembrane -helices, and 9 surface and
3 stromal
-helices (26). A monomer of PS I consists of a
"catalytic domain" and a smaller "connecting domain" that links
monomers to form a trimer. The connecting domain contains three
transmembrane helices which may belong to PsaL and PsaI (22, 23). The
remaining helices belong to the PS I core and other subunits in the
catalytic domain. Twenty-two transmembrane and eight peripheral helices
in the catalytic domain are arranged in an approximate symmetry (25,
26). Therefore, in agreement with the hydropathy analysis, the PsaA and
PsaB cores are proposed to contain 11 transmembrane helices each
(30).
Although the x-ray crystallography studies provided information of the PS I core, PsaA and PsaB could not be distinguished at the present resolution (26). Similarly, the interaction between PS I core and small subunits, the surface domains, and residues of the PS I core and positioning of extramembrane loops with respect to the photosynthetic membranes have not been elucidated clearly. Topographical studies provide a valuable tool to understand these unresolved structural features of PS I. In this paper, we describe biochemical studies that used subunit-deficient mutants, limited proteolysis, and domain-specific antibodies. We studied the accessibility of PsaA and PsaB to different proteases, the shielding of PsaA and PsaB by smaller PS I subunits, and the position of the N terminus of PsaA with respect to the membrane plane.
Strains of
Synechocystis sp. PCC 6803 that were used in this study are
listed in Table I. Cultures of wild type
and mutant strains were grown in BG-11 with or without 5 mM
glucose and antibiotics (30 µg/ml chloramphenicol or 40 µg/ml
kanamycin) under a light intensity of 21 µmol·m1·s
1. Cells were harvested at
the late exponential growth phase and resuspended in 0.4 M
sucrose, 10 mM NaCl, 1 mM PMSF, 2 mM benzamidine, and 10 mM MOPS, pH 7.0, for
isolation of thylakoids.
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Photosynthetic membranes were isolated after cell breakage with a bead beater (Biospec Products) (28). To isolate PS I, the membranes were solubilized with Triton X-100 and subjected to DEAE-cellulose chromatography and sucrose gradient centrifugation (31). Chlorophyll concentrations in the thylakoid membranes and PS I complexes were determined in 80% (v/v) acetone (32).
Preparation of Osmotically Shocked Cells of Synechocystis sp. PCC 6803Cells were harvested at the late exponential growth phase by
centrifugation (7000 × g, 10 min). The pellet was
resuspended in 0.4 M sucrose, 5 mM EDTA, and 10 mM HEPES, pH 7.0, pelleted again, and resuspended in the
same buffer with 0.2% (w/v) lysozyme to 1 g of cells per 10 ml.
Cell wall was digested by incubation at 27 °C for 12 h under
illumination (21 µmol·m1·s
1) with
constant shaking. Cells were harvested by centrifugation (7000 × g, 10 min), resuspended in osmotic shock solution (50 mM potassium phosphate, pH 6.8, 30 mM sodium
citrate, 0.2 mM CaCl2, 1 mM PMSF,
and 2 mM benzamidine), incubated on ice for 30 min, and
harvested by centrifugation (7000 × g, 10 min) again.
This osmotic shock treatment was repeated two additional times. The cells were pelleted and resuspended twice with 10 mM NaCl,
10 mM HEPES, pH 7.0, and finally resuspended in 0.4 M sucrose, 10 mM NaCl, 10 mM HEPES,
pH 7.0, for protease treatment (33).
To study the accessibility of PS I subunits to proteases, purified wild type and mutant PS I complexes, wild type thylakoid membranes, and osmotically shocked cells were incubated with protease at a final chlorophyll concentration of 200 µg/ml. The protease reaction conditions are listed in Table II. To remove peripheral subunits from the PS I core, purified wild type PS I complex was incubated with 3 M NaI for 30 min on ice (34). The samples were diluted with an excess amount of 10 mM MOPS-HCl, pH 7.0, 0.05% Triton X-100, and desalted by ultrafiltration through a Centricon-100 (Amicon).
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Purified PS I complexes that had
been treated with proteases were used for oxygen uptake measurements.
In a total volume of 1 ml, PS I containing 10 µg of chlorophyll was
used for the reaction. PS II inhibitor, electron donors, and electron
acceptor were added to a final concentration of 50 µM
3-(3,4-dichlorophenyl)-1,1-dimethyl urea, 1 mM ascorbate, 1 mM 3,6-diaminodurene, and 2 mM methyl viologen.
Oxygen uptake was measured on the Oxygen Monitoring System (Hansatech,
UK) under the light density of 2430 µmol m2
s
1.
Domain-specific antibodies were
generated using overexpressed fusion proteins as antigens. DNA
fragments coding the appropriate peptides in PsaA and PsaB of
Synechocystis sp. PCC 6803, PsaA2 for residues
A2-TISPPEREAKAKVSVDNNPVPTSFEKWGKPGHFDRTL of PsaA, and PsaB450 for
residues B450-QILIEPVFAQWIQATSGKALYGFDVLLSNPDSIASTTGAAWLPGWLDAINSGINSLF of PsaB were amplified by polymerase chain reaction and inserted into expression vector pGEX-KG between EcoRI and
XhoI sites. The expression of fusion proteins was induced by
isopropyl -D-thiogalactopyranoside. Cells were harvested
by centrifugation and lysed by a probe sonicator. The fusion proteins
in inclusion bodies were isolated from membranes by centrifugation
through 10% sucrose and applied directly for electrophoresis. The gel
was stained by Coomassie Blue. The fusion proteins were excised from
the gel and used for raising antibodies at Cocalico Biological.
Antibody anti-PsaB718 was raised against the C terminus of PsaB (35).
Antisera were evaluated by Western blotting against both thylakoid
membranes and purified PS I complex. All three domain-specific
antibodies anti-PsaA2, anti-PsaB450, and anti-PsaB718 recognized only
the 66-kDa diffuse band corresponded to the comigrating PsaA and PsaB
proteins.
Isolated PS I complexes and photosynthetic membranes were solubilized at 37 °C for 2 h with 1% SDS and 0.1% 2-mercaptoethanol. Proteins were resolved by a modified Tricine/urea SDS-PAGE for better resolution of the PS I subunits (10). After electrophoresis, gels were electrotransferred to Immobilon-P polyvinylidene difluoride membranes (Millipore). Immunodetection was performed using the enhanced chemiluminescence reagents (Amersham Corp.). For sequencing of N termini of proteolytic cleavage fragments, peptides were separated by electrophoresis, transferred to Immobilon-P membranes, stained with Coomassie Blue containing 1% acetic acid for several minutes, destained with 50% methanol, and rinsed with deionized water. The N-terminal sequences were determined on an Applied Biosystems 477A Sequencer.
In this study, we used limited proteolysis to map surface domains in the PsaA-B core of PS I. To examine activity of the protease-treated complexes, we determined PS I-mediated oxygen consumption rates by Mehler reaction (36, 37). Purified wild type PS I complexes were treated by eight proteases and employed in oxygen uptake measurements (Table III). The PS I activity of untreated sample was 377.5 µmol of O2/mg of chlorophyll/h. The PS I activities in all eight protease treatments ranged from 99 to 133% control activity. An active reaction center and functional electron transfer chain are required for the PS I activity that is measured by the oxygen uptake. Thus the protease treatments did not damage the electron transfer chain within the PS I complex. This may imply that the limited proteolysis could only access extramembrane loops. In most protease-treated samples, the PS I activity was higher than that in the untreated control. Proteases might have degraded the extramembrane loops and small subunits, thereby facilitating access of electron donor or acceptor to the electron transfer centers in the PS I complexes.
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Purified PS I
complexes from the wild type strain were treated with proteases to
study the accessibility of cleavage sites in PsaA and PsaB. The PS I
complexes were treated with different concentrations of proteases and
the resulting fragments were stained by Coomassie Blue or
immunodetected by the three domain-specific antibodies (Fig.
1). The apparent masses of protein
fragments were determined from the migration of prestained protein
molecular weight standards (Life Technologies, Inc.) upon
electrophoresis. The protein fragments that were visible in Coomassie
Blue staining were subjected to N-terminal amino acid sequencing. Three
criteria, the N-terminal sequences, the apparent mass, and the
immunoreactivities of proteolytic fragments, were used to identify the
proteolytic fragments (Table IV).
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The ThII, GlIII, and PaIII fragments were deduced accurately from their N-terminal sequence and from their immunodetection by anti-PsaB718 showing that they contain the C terminus of PsaB. The ThI, ThIII, ThIV, and ChI fragments were recognized by the anti-PsaB450 antibody indicating that they contain the PsaB450 peptide. The ThI fragment also contained the N terminus of PsaB and showed a similar accumulation pattern as the ThII fragment. The immunodetection pattern and apparent mass imply that these fragments resulted from a single cleavage at Ile-498 of PsaB. The ThIII and ThIV fragments were predicted with the same C terminus of the ThI fragment and matched the immunodetection and apparent mass. They may have resulted from the further cleavage of the ThI fragment as their accumulation followed that of ThI. The N terminus of the ChI fragment resulted from the cleavage at Phe-8 of PsaB protein. The immunodetection and apparent mass of the ChI fragment is similar to the ThI fragment, thus the C terminus of the ChI fragment should result from a cleavage close to Ile-498. The only reasonable site to generate C terminus of the ChI fragment is Phe-506. When the PS I complexes were treated with trypsin, the signals corresponding to the intact PsaA were decreased significantly when detected by anti-PsaA2. Also, a diffused band that migrated slightly faster than the PsaA-B band was visible in Coomassie Blue staining. This can be explained as a cleavage in the N-terminal sequence of PsaA. The N-terminal sequence of the TrI fragment revealed the cleavage site in the N-terminal extramembranal domain of PsaA. Thus these fragments, grouped as type I fragments, could be identified with accuracy. Similar to many membrane proteins, the electrophoretic behavior of the PS I core proteins was anomalous compared with the migration of soluble proteins. The comigrating PsaA and PsaB formed the 66-kDa diffuse band in PAGE, whereas the deduced mass is more than 80 kDa. The predicted mass was higher than the apparent mass. This was also true for the type I fragments and was considered during the prediction of the other fragments.
Table V lists the results of Western blotting, the apparent mass, and the predicted proteolysis regions for the protein fragments that could be immunodetected with domain-specific antibodies. The identity of these fragments could be predicted by several ways. The prediction of type 1 fragments was described in the previous paragraph. Type 2 and type 3 fragments contained epitope for the N terminus of PsaA or epitope at the C terminus of PsaB, as shown by the immunodetection results. Based on their apparent mass, there was only one reasonable cleavage site for the fragments of type 2. For example, the GlV fragment, a 44.5-kDa polypeptide recognized by anti-PsaA2, could result from the proteolysis at Glu-512 in PsaA with a predicted mass of 47.5 kDa. The adjacent Glu-C cleavage sites were Glu-342 or Glu-695 in PsaA which made the predicted mass of 37.9 or 76.9 kDa unreasonable for GlV. In type 3 fragments, there were several possible cleavage sites located within one extramembrane loop or in a region containing two extramembrane loops. For example, the GlII fragment, a 33.7-kDa peptide immunodetected with anti-PsaA2, could result from four reasonable cleavages between Glu-323 and Glu-342 in PsaA with the predicted mass from 35.8 to 37.9 kDa. These four possible cleavage sites were located in the E loop. The LyI fragment is the only type 4 fragment. It accumulated similarly as the TrI fragment, so it was predicted to have the similar cleavage at the N-terminal loop of PsaA. The type 5 fragments contained the peptide PsaB450 but there was not enough data to identify them accurately. Overall, the limited proteolysis of the wild type PS I provided extensive information about the residues that are exposed on the surface of the PS I complex.
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As the
components of the multiprotein PS I complex, the PsaA and PsaB core
proteins interact with the small subunits. To study these interactions,
subunit-deficient mutant PS I complexes (Table I) and NaI-treated PS I
complexes were used for limited proteolytic treatments. Different PS I
complexes were incubated with proteases, and resulting fragments were
detected by Western blotting (Fig. 2).
When specific small subunits were absent, the proteolytic sites in the
core proteins that are shielded by the small subunits were expected to
be exposed to proteases. Indeed, additional peptide fragments that
reacted with the three domain-specific antibodies were obtained in
mutant PS I complexes compared with the protease-treated wild type PS I
complexes. The apparent mass and the immunoreactivity were used in
prediction of the additional fragments
(Table VI).
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In general the ADC4, AEK2, and NaI-treated PS I complexes yielded more additional proteolytic fragments than the AFK6 and AIC9 complexes, indicating that the peripheral PS I subunits shield more extramembrane proteolytic sites in the core proteins than the integral membrane proteins. When the ADC4 and NaI-treated PS I complexes were incubated with proteases, PsaA and PsaB were digested much more rapidly than the core proteins in the wild type PS I complexes. The AEK2, AFK6, and AIC9 complexes were more resistant to proteolysis than ADC4 and NaI-treated PS I complexes. The untreated ADC4 and NaI-treated PS I complexes contained 42-kDa fragments detected by anti-PsaA2 and anti-PsaB450. The natural degradation of PsaA is predicted in the H loop. The degradation fragment of PsaB was similar to the ThI fragment that resulted from the cleavage at Ile-498 in the H loop. Therefore, these results suggest that the natural degradation may occur in the H loops of both core proteins.
Information about the protection of PsaA by small subunits can be obtained from the immunodetection data with the anti-PsaA2 antibody. Additional fragments were not observed in the protease treatments of the AIC9 complexes. Therefore, PsaL and PsaI may not shield protease-recognition sites in PsaA from proteolysis. When the PS I complexes from the AFK6 strain were treated with trypsin, the additional 40-kDa TrA fragment was obtained. The TrA fragment could result from a cleavage in the H loop of PsaA. When the PS I complexes of the ADC4 strain were treated with proteases, the major fragments detected by anti-PsaA2 were the 42-kDa degradation fragments. However, when the PS I complexes of the AEK2 strain were treated with proteases, small additional proteolytic fragments (ThC-F, ChC-F, and ClC) resulted from the cleavages in the N-terminal domain of PsaA. Also, a 44-kDa fragment (ClA) resulted from accessible sites in the C-terminal domain of PsaA. The cleavages in the N-terminal domain of PsaA could be detected only upon protease treatment of the PsaE-less AEK2 complexes, implying that the N-terminal domain of PsaA may interact with PsaE. The NaI treatment of PS I complexes removed PsaD, PsaE, and PsaC from the core proteins. When the NaI-treated PS I complexes were treated with proteases, the anti-PsaA2 antibody immunoreacted with the 42-kDa degradation product that was similar to the one in the protease-treated ADC4 complex and also with the large proteolytic fragments similar to the ones in the protease-treated AEK2 complex.
When detected with the anti-PsaB450 antibody, the protease-treated PS I complexes of the AEK2, AFK6, and AIC9 strains contained the similar pattern as the protease-treated wild type PS I proteins. For the protease treatments of the ADC4 and NaI-treated PS I complexes, the 28.2-kDa LyC fragment was detected in addition to the 42-kDa degradation fragment. Some diffused fragments between the 42-kDa fragment and the intact PsaA-B protein were also observed, especially in the NaI-treated PS I complexes. When compared with the detection by the anti-PsaB718 antibody, these fragments did not contain the C-terminal epitope. These fragments could result from the cleavages in the I, J, or K loops which are close to the C terminus of PsaB.
Additional fragments were detected by the anti-PsaB718 antibody in all mutant PS I complexes. The 28.2-kDa LyC fragment that was recognized by the anti-PsaB450 antibody was also immunodetected by the anti-PsaB718 antibody when the ADC4 and NaI-treated PS I complexes were treated with the Lys-C protease. From its apparent mass and the presence of the C-terminal epitope, this fragment was predicted to have N terminus from one of five possible cleavage sites in the G and H loops to the C terminus of PsaB. Proteolysis at these sites should result in fragments with a predicted mass of 31.0-36.8 kDa. When the PS I complexes of AFK6 were treated with trypsin, the 22.7-kDa TrB fragment was detected by the anti-PsaB718 antibody. This fragment could have resulted from a cleavage at Lys-449 or Lys-467 in the H loop of PsaB. In the ADC4 and NaI-treated PS I complexes, an additional 40.0-45.0-kDa fragment shown as LF in Fig. 2 was detected in most protease treatments. This fragment was absent in the untreated PS I complex. The possible cleavage sites may be located in the C, D, and E loops of PsaB with a predicted mass of 45.0-63.4 kDa. However, no such fragment was observed in the AEK2, AFK6, and AIC9 PS I complexes. Therefore, the N-terminal domain of PsaB is protected by PsaD but may not interact with the other subunits.
Previous work has indicated that a 16-kDa proteolytic fragment detected by anti-PsaB718 in thermolysin-treated ADC4 PS I complex resulted from a cleavage at Leu-531 in the I loop of PsaB (28). Similar proteolytic fragments, such as ChB, ClB, LyA, LyB, ThA in different mutant PS I complexes, were detected. These proteolytic fragments could result from cleavages in the I loop of PsaB indicating that the I loop in the C-terminal domain of PsaB may interact with several subunits. In the Lys-C treatments, two close fragments from the cleavages in the I loop of PsaB were obtained in the AFK6, AIC9, and NaI-treated PS I complexes with apparent mass about 15.5 and 16.8 kDa. Only one such fragment was detected in ADC4 and AEK2 each, with a slight difference in their apparent mass. One of the four lysyl residues in the I loop may be involved in the cleavage by the Lys-C endoprotease. The cleavage at Lys-533 may yield a C-terminal fragment with a predicted mass of 22.7 kDa, and the cleavage at Lys-542, Lys-547, or Lys-548 would result in the fragment containing C-terminal epitope with a predicted mass of 21.1-21.8 kDa. According to these results, LyB was predicted as the cleavage at Lys-533 in the AEK2, AFK6, AIC9, and NaI-treated PS I complexes, and LyA might have resulted from the cleavage at one of the other three lysyl residues in the ADC4, AFK6, AIC9, and NaI-treated PS I complexes.
Apparently, numerous proteolytic fragments resulted from the cleavages in the C-terminal domain of PsaB in the mutant PS I complexes indicating the shielding and protection of this domain by the missing small subunits. These results imply that the C-terminal domain of PsaB may play an important role in the assembly of the PS I complex.
Orientation of the N Terminus of the PsaA ProteinThe
osmotically shocked Synechocystis sp. PCC 6803 cells were
treated with trypsin and Lys-C and examined by Western blotting. The
thylakoid membranes that had been isolated by usual procedure (38) were
used as a control. Two antibodies, anti-PsaD and anti-PsbO, were used
to test the intactness of thylakoid membranes after osmotic treatment
and during protease digestions. The domain-specific antibody anti-PsaA2
was used to determine the orientation of PsaA (Fig.
3). PsaD, which is located on the
n side of photosynthetic membrane, was expected to be
exposed to proteases during the treatment. Small fragments in Lys-C and
trypsin treatments were recognized by anti-PsaD indicating the
digestion of PsaD in membranes from both control and osmotically
shocked cells. Digestion of PsaD in the osmotically shocked cells was
not as extensive as in isolated membranes. Due to a large amount of
cytoplasmic proteins, protease to protein ratio in the cell treatments
was expected to be lower than in the thylakoid treatments. If the
thylakoid membranes were intact during the protease treatments, PsbO
which is located on the p side of photosynthetic membrane
was expected to remain intact. In membranes, PsbO was not detected
after protease treatment. In contrast, most PsbO remained intact in the
osmotically shocked cells. These results showed that the osmotically
shocked thylakoid membranes remain largely intact during the protease
treatments. In Lys-C and trypsin treatments, significant degradation of
PsaA was observed when anti-PsaA2 was used for detection. As described previously, the degradation of PsaA in Lys-C and trypsin treatments resulted from the cleavage in the N-terminal loop of PsaA. Therefore, the N terminus of PsaA was exposed to proteases in the osmotically shocked cells showing that it is on the n side of
photosynthetic membranes.
PS I is a multisubunit protein complex that contains at least 11 polypeptides in cyanobacteria (1). In this study, we used domain-specific antibodies, limited proteolysis, and subunit-deficient PS I complexes to understand the topography of the PsaA and PsaB proteins that form the catalytic hydrophobic core of PS I. Domain-specific antibodies were generated against specific peptides in PsaA and PsaB. Western blotting with thylakoid membranes and purified PS I complexes showed that the antibodies are specific to PsaA or PsaB. N-terminal amino acid sequences of the fragments recognized by antibodies (Table IV) demonstrated the domain specificity of the antibodies to PsaA and PsaB proteins. The GlIII fragment with the N terminus at Lys-449 of PsaB was recognized by the anti-PsaB450 antibodies, whereas the ThII fragment with the N terminus at Ile-498 of PsaB was not recognized by anti-PsaB450. These results indicated that the specific binding domain of anti-PsaB450 should be located between Lys-449 and Ile-498 of PsaB protein, the corresponding peptide of anti-PsaB450. N terminus of the TrI fragment which was not recognized by anti-PsaA2 started at Trp-28 of PsaA. Therefore anti-PsaA2 specifically recognizes the N terminus of PsaA. Limited proteolysis has been successfully used to probe transmembrane topology of membrane proteins. In these analyses, it is necessary to establish conditions that allow cleavage of the extramembrane loops but not of the transmembrane regions. We ensured integrity of the hydrophobic core of PS I after proteolysis from measuring PS I activity using artificial electron donor and acceptor (Table III).
The structure of cyanobacterial PS I complex at 4-Å resolution has
indicated that PsaA and PsaB have 11 transmembrane helices each. These
helices span the lipid bilayer completely (26). Based on the available
information and the results in this paper, we proposed a model for
transmembrane folding of the PsaA and PsaB core proteins (Fig.
4). The homology between PsaA and PsaB proteins implied that they would fold similarly. Therefore, the model
in Fig. 4 should be applicable to both PsaA and PsaB proteins. In this
model, 11 transmembrane helices span the thylakoid membrane completely
with the N termini on the n side of thylakoid membrane. Consequently, the C termini are on the p side of thylakoid
membrane (Fig. 4). Such orientation is supported by the following
observations. The 4-Å crystal structure indicated clearly the complete
spanning of the 11 transmembrane helices (26). The Lys-C and trypsin treatments of the osmotically shocked cells in this paper suggested that the N terminus of PsaA is located on the n side of the
thylakoid membrane. Xu and Chitnis (28) showed that the K loop
interacts with PsaD which is located on the n side of the
thylakoid membrane. Vallon and Bogorad (29) located the G loop on the
n side and the F and H loops on the p side by
using immunogold labeling. The I loop with the FX binding
domain should be located on the n side of the thylakoid
membrane. Also, the six n side extramembrane loops contain
the majority of the positive residues, which agrees with the
"positive inside" rule (39, 40). Therefore, now there is sufficient
evidence from different sources that collectively demonstrate the
transmembrane orientation of the PsaA and PsaB proteins (Fig. 4).
Because of the folded structure of the substrate proteins, proteases cannot cleave at every recognition site in the primary sequence. The accessibility of extramembrane loops in PsaA and PsaB to proteases is determined by folding of the loops. Some loops may form loose conformation that will be exposed readily to proteases. In contrast, some loops may have compact conformation, like the helices that are parallel to the membrane plane. Many protease recognition sites in the compact loops may not be accessible to proteases. Also, the protection from other proteins will reduce the surface exposure of the loops. For these reasons, the accessibility of extramembrane loops in PsaA and PsaB differed for each loop (Fig. 4). The protease recognition sites in the C, F, and K loops of PsaA and PsaB could not be cleaved, whereas the H and E loops of PsaB were readily accessible to proteases. The H loop is on the p side of the thylakoid membrane in the model. It is only one transmembrane helix from the I loop which contains the FX-binding motif and interacts with PsaC on the n side (41, 42). From the arrangement of helices in the 4-Å model of PS I, both I and H loops should be located in the center of the PS I core. The extensive accessibility of the H loop to proteases and its p side location imply that the H loop of PsaB could be accessible to interaction with plastocyanin or cytochrome c6, the electron carriers that transfer electrons from cytochrome b6f complex to the P700 reaction center of PS I complex in the p side of the thylakoid membrane. PsaF is involved in docking of plastocyanin in the plant PS I (7, 19, 20) but not in the cyanobacterial PS I (6, 21). This difference is ascribed to a lysine-rich sequence that is present in the N-terminal region of the plant PsaF but not in the cyanobacterial PsaF (43). Besides PsaF, the H and J loops are the only two domains exposed to p side and located in the center the PS I complex. When the H and J loop sequences of PsaA and PsaB from high plants and cyanobacteria are aligned, there is a major difference in a 12-residue sequence in the H loop of PsaB but not in others (4). This information suggests that the H loop of PsaB in cyanobacterial PS I complex may help the docking of plastocyanin or cytochrome c6 from the p side of the thylakoid membrane and even contribute to the electron transfer from these two electron donors to the P700 reaction center.
In the 4-Å crystal structure of PS I, the C-terminal domains from both
PsaA and PsaB core proteins form a cage where the electron transfer
chain is located. This important cage is the catalytic center of the PS
I complex and is protected by PsaD, PsaC, and PsaE subunits from the
n side and by the surface helices l and l in the J loop of
PsaA and PsaB from the p side of the thylakoid membrane
(26). The protection of the C-terminal domains in PsaA and PsaB is also
observed in the protease treatments of the wild type PS I complex. The
only cleavages that may occur in the I, J, K, and L loops were the PaVI
and PaVII fragments from the papain treatment accompanying the complete
degradation of the small subunits PsaD and PsaF. With intact small
subunits, the C-terminal loops I, J, K, and L are well protected from
the limited proteolysis. Protection by the small subunits is also shown
by the numerous proteolytic fragments from the cleavages in the I loop
of PsaB in the mutant PS I complexes (Table VI).
The additional fragments in protease treatments of the subunit-deficient PS I complexes provide information about the interactions between the small subunits and the loops of PsaA and PsaB. PsaE is the only missing subunit in the PS I complex from the AEK2 strain. The additional fragments from the protease treatments of AEK2 complexes indicated that the absence of PsaE resulted in possible cleavages in the B-I loops of PsaA and the I loop of PsaB (Table VI). As an n side subunit, PsaE may interact with the C, E, F, and I loops in the n side of the thylakoid membrane. The cleavages in the p side loops may result from further digestion of the degradation products. Therefore, PsaE may interact with the n side loops in the N-terminal domain of PsaA and the I loops of both PsaA and PsaB (Fig. 4). In the protease treatments of the ADC4 PS I complexes, additional cleavages were located in the C-E and G-I loops of PsaB (Table VI). Thus, PsaD may interact with the n side loops in the N-terminal domain of PsaB and the I loop of PsaB (Fig. 4). Additionally, Xu and Chitnis (28) identified that PsaD may shield the I and K loops of PsaB. When the PS I complexes from the AFK6 and AIC9 strains were treated by proteases, no additional fragments from the N-terminal domains of PsaA and PsaB were observed. The AFK6 and AIC9 mutant PS I complexes do not contain PsaF-PsaJ and PsaI-PsaL, respectively. Therefore, the extramembrane loops in the N-terminal domains of PsaA and PsaB may not interact with these subunits. The trypsin treatment of the AFK6 PS I complex yielded the TrA and TrB fragments. These two fragments resulted from the cleavages in the H loops of PsaA and PsaB (Table VI). Between the two subunits absent in the AFK6 complex, PsaJ is mainly a transmembrane helix, whereas PsaF has been proposed to contain a peripheral domain on the p side of membrane (44). Therefore, the p side domain of PsaF may interact with the H loops of PsaA and PsaB on the p side of the thylakoid membrane (Fig. 4). In the Lys-C treatments of the AFK6 and AIC9 PS I complexes, additional cleavages were observed in the I loop of PsaB. The missing subunits in these mutant PS I complexes may not directly interact with the I loop of PsaB because the predicted positions of these subunits in the 4-Å crystal structure were not close enough to the I loop of PsaB (26). However, chemical cross-linking studies have yielded the following cross-linked products: PsaC-PsaD, PsaC-PsaE, PsaD-PsaL, and PsaE-PsaF (44, 45). The interactions between the cross-linked subunits may cause some conformational changes of PsaD, PsaE, or even PsaC in the mutant PS I complexes. Therefore, the I loop of PsaB that was protected by PsaD and PsaE subunits could be exposed to protease in the AFK6 and AIC9 PS I complexes. Correspondingly, the absence of PsaE may cause the conformational change in PsaF and result in the exposure of the H loops of PsaA and PsaB that are shielded by PsaF. In the thermolysin treatment of the AEK2 PS I complex, the ThB fragment resulted from the cleavage in the H loop of PsaB (Table VI). As described above, PsaF may interact with the H loops of PsaA and PsaB, whereas PsaI, PsaL, and PsaJ may not shield the extramembrane loops of the core proteins (Fig. 4).
In the 4-Å crystal structure of PS I, core proteins PsaA and PsaB
contribute their C-terminal domain to form the central cage of PS I
core, and the N-terminal domain of PsaA and PsaB may form the
peripheral helices. PsaA and PsaB may crossover in the central cage so
both the C-terminal domains of PsaA and PsaB may be protected by a
single subunit. For this reason, PsaF can interact with both H loops of
the core proteins, and PsaE can shield both I loops of PsaA and PsaB
(Fig. 4). However, the peripheral helices in one of the two symmetry
regions should be donated from one of the core proteins. The absence of
PsaE results in further cleavages in the N-terminal domain of PsaA, and
the absence of PsaD results in further cleavages in the N-terminal
domain of PsaB in the protease treatments of the mutant PS I complexes
(Fig. 4). This asymmetrical interaction indicated the arrangement of
the N termini of the PsaA and PsaB core proteins related to the PsaD
and PsaE subunits. However, the electron microscopy study has revealed
that PsaD and PsaE are located in different sides of the central axis,
and they do shield different parts of the core proteins (46). Combining this information, we propose a model to distinguish PsaA and PsaB in
the 4-Å crystal structure of PS I (Fig.
5). In this model, the region partly
covered by PsaD and not by PsaE belongs to PsaB, and the region only
covered by PsaE belongs to PsaA. Therefore, our data indicate that the
primed helices in the 4-Å map belong to PsaA, and the unprimed helices
are assigned to PsaB if the primed and unprimed helices are contributed
from each of the core proteins (Fig. 5).
To conclude, the topographical analyses of the PsaA and PsaB proteins have allowed us to examine the accessibility of their extramembrane loops to proteases, the shielding and protection of these loops by small subunits, the location of the N terminus of PsaA, and the assignment of the two core proteins relative to small subunits in the 4-Å map. The biochemical techniques are indeed valuable for deciphering the structure of membrane proteins and to complement the biophysical techniques that cannot be applied readily to the structural analysis of membrane proteins.
We thank Dr. James A. Guikema for the anti-PsaB718 antibody. We thank Drs. Petra Fromme, Wolf-Dieter Schubert, Norbert Krauß, and Prof. Wolfram Saenger for insightful discussions.