(Received for publication, December 31, 1996, and in revised form, February 14, 1997)
From the Institute of Molecular Biology, Academia Sinica, Nankang, Taipei 11529, Taiwan, Republic of China
Several components in the machinery mediating the import of nuclear-encoded chloroplastic precursor proteins have been identified. One of the components, OEP34, is an outer membrane protein and is synthesized at its mature size in the cytosol without a distinguishable chloroplast-targeting signal. To address the question of how components in the transport machinery are imported to chloroplasts themselves, we first identified the chloroplastic outer membrane-targeting signal of OEP34. Using an Arabidopsis homologue of the originally isolated pea OEP34, we show that the outer membrane-targeting signal of OEP34 is located within a 10-amino acid hydrophobic core of the C-terminal membrane anchor. Interestingly, this signal can target a passenger protein to the chloroplastic outer membrane no matter whether it is placed at the N or C terminus of a passenger protein. Proper insertion of fusion proteins into the outer membrane requires in addition the C-terminal hydrophilic region following the hydrophobic core. Furthermore, passenger proteins fused to the C terminus of the targeting/insertion signal were most likely imported into the intermembrane space of the envelope.
Most proteins in chloroplasts are nuclear-encoded and post-translationally imported into chloroplasts. With the exception of most outer membrane proteins, nuclear-encoded chloroplastic proteins are synthesized as higher molecular weight precursors with N-terminal extensions called transit peptides. Protein import into chloroplasts involves specific interactions between the transit peptides and a set of transport machinery in the envelope (1) and requires the hydrolysis of ATP and GTP. No consensus sequence has been found for the transit peptides, but they generally have a net positive charge, are devoid of negative charges, and are rich in serine and threonine (2, 3).
Outer envelope membrane proteins represent a unique branch of nuclear-encoded chloroplastic proteins. Most outer membrane proteins are synthesized at their mature size in the cytosol without cleavable transit peptides (4-9). Their insertion into the outer membrane does not require ATP (4-9). Most of them also do not require thermolysin-sensitive components on the chloroplastic surface for their targeting to chloroplasts (4-8). Targeting signals from two of these outer membrane proteins have been identified. The first 48 amino acids of a hydrophilic peripheral membrane protein SCE/Com70 (10), and the first 30 amino acids of an integral membrane protein OEP14 (11), have been shown to be necessary and sufficient for chloroplastic outer membrane targeting. The first 30 amino acids of OEP14 is the membrane anchor of the protein (11). There is no similarity between the targeting signals of SCE/Com70 and OEP14 except that both are located at the N terminus of the respective protein.
Several components in the machinery responsible for the import of transit peptide-bearing precursor proteins have been identified (1, 12). cDNAs for some of the identified components have also been isolated and three of them encode outer membrane proteins (4, 9, 13-15). According to their molecular weight, they are named OEP/IAP1 (uter nvelope membrane rotein or mport intermediate-ssociated rotein) 86, 75, and 34. OEP86 and OEP34 are GTP-binding proteins (4, 9, 13) and may function as receptor and regulator of the transport machinery, respectively. OEP75 may function as a transport channel across the outer membrane (14, 15). In contrast to all other outer membrane proteins identified, OEP86 and OEP75 are synthesized as higher molecular weight precursors with cleavable targeting sequences at their N termini. OEP75 has a bipartite targeting sequence (16). The first part functions as a regular transit peptide (16) and OEP75 competes with the import of a stroma-targeting precursor protein (15), indicating that OEP75 uses the same, or at least part of the same, import pathway used by most precursor proteins. OEP86, on the other hand, does not compete with the import of a stroma-targeting precursor protein (13). Its cleavable targeting sequence is unusually long and highly negatively charged (13). This signal is also not sufficient for chloroplast targeting. Proper targeting and insertion of OEP86 to the outer membrane requires, in addition, a C-terminal portion of the mature protein (17).
OEP34 is synthesized at its mature size in the cytosol like the majority of outer membrane proteins (4, 9). However, although it is an integral membrane protein like OEP14, OEP34 does not have a membrane-anchoring domain at its N terminus. Therefore it is not clear what kind of signal directs the targeting of OEP34 to chloroplasts. Furthermore, while one report describes insertion of OEP34 into the outer membrane as being independent of ATP and thermolysin-sensitive components (4), another report has shown that insertion of OEP34 into the outer membrane is stimulated by ATP and is greatly impaired by thermolysin pretreatment of chloroplasts (9). Therefore, it is possible that OEP34 does not use an import pathway shared by other outer membrane proteins without cleavable transit peptides, but instead uses a novel pathway that is yet to be described.
Because most chloroplastic proteins are imported from the cytosol, the synthesis and assembly of the protein transport machinery are some of the most important parts of chloroplast biogenesis. To address the interesting question of how components in the transport machinery are targeted to chloroplast themselves, we have started to investigate the import pathway used by one of the components, OEP34. Here we report the localization of its chloroplastic outer membrane-targeting signal and describe the unique features of this signal. These findings provide insight into the import mechanism of OEP34.
The
AtOEP34 cDNA from the Arabidopsis Biological Resource Center at the
Ohio State University (stock number 167B21T7, named by us as
pLOX-AtOEP34) was excised with SalI and XbaI and
subcloned into the SalI/XbaI site of the pSP64
(Promega, Madison, WI) vector, creating the plasmid pSP64-AtOEP34.
N43 was constructed by excising the coding region with
SacI, which cut at amino acid 37 of AtOEP34, and
BamHI. The insert was subcloned into the
SacI/BamHI site of pSP65 (Promega).
N116 was
constructed by cutting pSP64-AtOEP34 with PstI, which cut
once in front of the AtOEP34 coding region in the pSP64 vector and once
between amino acids 65 and 66 of AtOEP34. The plasmid was then
blunt-ended with T4 DNA polymerase and self-religated, creating the
plasmid pAtOEP34
N116.
N206 was constructed by amplifying the
corresponding coding region from pLOX-AtOEP34 by polymerase chain
reaction (PCR) with an N-terminal primer, which changes amino acid 207 from isoleucine to methionine and creating an SphI site in
the process, and the SP6 primer as the C-terminal primer. The amplified
fragment was then digested with SphI and XbaI and
cloned into the SphI/XbaI site of plasmid pSP72
(Promega).
N272 was constructed by cutting pSP64-AtOEP34 with
HincII, which cut once in the vector in front of the AtOEP34 coding region and once at amino acid 253 of AtOEP34 and then
self-religated. The C-terminal deletion mutants At(1-271) and
At(1-282) were constructed by amplifying the corresponding coding
regions by PCR from pSP64-AtOEP34 using the SP6 sequence on the vector
as the N-terminal primer and two C-terminal primers spanning the amino
acids 271 or 282 regions with a stop codon and a HindIII
restriction site at the 5
ends of the primers. The PCR-amplified
fragments were digested with XbaI and HindIII and
cloned into the XbaI/HindIII site of pSP64.
The fusion proteins with glutathione S-transferase (GST)
were constructed as follows. The GST coding region, which also contain a factor Xa processing site and a multiple cloning site at the C
terminus, was excised from the plasmid pGEX-5X-1 (Pharmacia Biotech
Inc., Uppsala, Sweden) with HincII and EcoRI and
subcloned into the EcoRV/EcoRI site of
pBluescript SK+ (Stratagene, La Jolla, CA), creating the plasmid
pBluescript-GST. The coding region of amino acid 253-313 of AtOEP34
was excised from pAtOEP34N116 with HincII and
XbaI and cloned into the SmaI/XbaI
site plasmid pBluescript-GST. The plasmid encoding the fusion protein
GST×(272-282) was constructed by inserting into the
EcoRI/PstI site of pBluescript-GST a linker sequence encoding an EcoRI site, the coding sequence for
amino acid 272-282, and a PstI site.
The fusion proteins with dihydrofolate reductase (DHFR) and the small
subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase (SS) were
constructed as follows. The coding regions for amino acids 250-313 and
273-313 were amplified by PCR with primers specific for the desired
regions plus the sequence for the EcoRI restriction site
(and an ATG initiation codon for the 250-313 construct) at the 5 end
of the N-terminal primers and the sequences for XbaI restriction site at the 5
end of the C-terminal primer. PCR products were digested with EcoRI and XbaI and subcloned
into the EcoRI/XbaI site of pSP65-XDHFR,
which contains a multiple cloning site followed by the coding
sequence for factor Xa recognition site and the DHFR protein (11). The
resulting plasmids were called pAtOEP34(250-313)×DHFR and
pAtOEP34(273-313)×DHFR. The plasmid encoding (273-313)×SS was
constructed by excising the coding sequence for the factor Xa
recognition site followed by SS from the plasmid pOEP14(1-30)×SS (11)
with XbaI and EcoRV and cloning it into the
XbaI/HindIII site of pAtOEP34(273-313)×DHFR in
which the HindIII site has been blunt-ended by the Klenow
fragment of DNA polymerase I. The plasmid encoding (273-282)×SS was
constructed by inserting a linker that contains the restriction site
for XhoI, the coding sequence for amino acids 273-282 of
AtOEP34 followed by the restriction site of XbaI, into the
XhoI/XbaI site of pOEP14(1-30)×SS.
[35S]Methionine-labeled proteins were synthesized through in vitro transcription (18) and in vitro translation with wheat germ extracts (Promega) or rabbit reticulocyte lysate (Promega) according to the manufacturer's specifications. Isolation of chloroplasts from 9- to 11-day-old pea (Pisum sativum cv dark-skinned perfection) seedlings, and import of proteins into chloroplasts were performed as described (18).
Thermolysin and factor Xa (Boehringer Mannheim) treatments and fractionation of chloroplasts after import were performed as described (7, 11). Factor Xa treatment of isolated outer membrane vesicles was performed by digesting outer membrane vesicles with 400 µg/ml factor Xa in import buffer (300 mM sorbitol and 50 mM Hepes/KOH, pH 8.0) plus 150 mM NaCl and 1 mM CaCl2 at room temperature for 2 h. The samples that went through a cycle of freeze-thaw were frozen in liquid nitrogen after adding factor Xa, then slowly thawed in a metal block in a ice-water bucket (19). When the sample was completely thawed, the sample was then moved to room temperature and further incubated for another 2 h. Digestion was terminated by adding phenylmethylsulfonyl fluoride to 1 mM. Membrane vesicles, except those in which 1% Triton X-100 had been added, was reisolated by centrifugation at 125,000 × g for 45 min in a Beckman TLA 45 rotor.
Samples were analyzed by SDS-PAGE on 10-20% gradient Tricine gels or 10% NuPAGE gels with MES running buffer purchased from Novex (San Diego, CA). Quantitation of samples were performed using the PhosphorImagor SP (Molecular Dynamics, Sunnyvale, CA) with dried gels.
Through sequence
comparison with the Arabidopsis EST data base (20), we
identified a putative Arabidopsis homologue of the pea OEP34
(21). The Arabidopsis cDNA encodes a protein of 313 amino acids, which has about 65% identity and 78% similarity to the
pea OEP34 (Fig. 1). Several regions in the sequence,
e.g. the G1 to G3 potential GTP-binding motifs (22), are
almost totally conserved between the two proteins. Results of charge
distribution and and
secondary structure-forming tendency
analyses of the Arabidopsis protein were also very similar
to those of pea OEP34 (data not shown). Hydropathy analysis indicated
that, like pea OEP34, the Arabidopsis protein also has only
one potential membrane-spanning domain close to the C terminus of the
protein (amino acids 269-283, Fig. 1, underlined). These
data indicate that the two proteins are likely to have very similar, if
not identical, structures and the Arabidopsis protein most
likely performs the same function as pea OEP34. We thus named the
protein encoded by the Arabidopsis cDNA "AtOEP34"
for Arabidopsis thaliana OEP34.
In view of the potential use of Arabidopsis to study the in vivo function of proteins identified in the transport machinery, we decided to further characterize AtOEP34. Another feature of AtOEP34 that proved useful to us was the distribution of methionine residues along the sequence of AtOEP34. Pea OEP34 has been predicted to insert into the outer membrane using the C-terminal hydrophobic domain, because thermolysin digestion of in vitro imported pea OEP34 results in a 6-kDa thermolysin-resistant fragment (9). One line of evidence supporting this fragment being the C-terminal portion is that pea OEP34 lacks methionine residues at its C-terminal half, and the 6-kDa fragment can only be seen when the protein is labeled with [3H]leucine (9). AtOEP34, on the other hand, has two methionine residues in the predicted C-terminal membrane-anchoring domain (amino acids 273 and 282, Fig. 1). Therefore if the predicted membrane topology of pea OEP34 is correct and AtOEP34 has the same topology as pea OEP34, we should be able to detect the thermolysin-protected fragment of AtOEP34 even when the protein is labeled with [35S]methionine (see below).
The Hydrophobic Core of the Membrane-anchoring Domain Is Necessary for Targeting and Insertion of AtOEP34 to the Chloroplastic Outer MembraneWe first investigated whether AtOEP34 could be imported
into chloroplasts. Using an in vitro import system with
isolated pea chloroplasts (18), AtOEP34 was imported to chloroplasts
(Fig. 2, lanes 1-4), and the imported
proteins were resistant to alkaline extraction, indicating they were
integral membrane proteins (data not shown). As with pea OEP34, there
was no molecular weight shift after import, indicating the absence of a
cleavable transit peptide. When the imported molecules were treated
with thermolysin, they were digested to a major protected fragment of 6 kDa (lane 4, arrow) and a minor fragment of 25 kDa,
identical to the digestion pattern of imported pea OEP34 (9). This
shows that AtOEP34 had inserted into the outer membrane the same way as
pea OEP34. Results from thermolysin concentration and digestion time
course experiments suggest that the 25-kDa product is most likely a
digestion intermediate (Ref. 9 and data not shown). In addition, the 6-kDa thermolysin-protected fragment of AtOEP34 was seen when the
protein was labeled with [35S]methionine. As discussed in
the previous section, this suggests that the 6-kDa fragment is the
C-terminal region of AtOEP34.
To locate the chloroplastic outer membrane-targeting signal within
AtOEP34, we made N- and C-terminal deletions of AtOEP34. Mutant
proteins with the N-terminal 43, 116, 206, or 272 amino acids or the
C-terminal 31 or 42 amino acids deleted were constructed (Figs. 1 and
3A). They were named N43,
N116,
N206,
N272, At(1-282), and At(1-271), respectively. As shown in
Fig. 2, amino acids preceding number 272 could be entirely deleted
without affecting the chloroplastic import of AtOEP34. However, the
import efficiency varied with individual mutants (Fig.
4). While
N43 and
N116 retained less than 20% of
the import efficiency of full-length AtOEP34, the import efficiency of
N206 was around 60% of that of AtOEP34. Interestingly, the mutant
that has the largest deletion,
N272, had an import efficiency
comparable with that of AtOEP34.
Thermolysin treatment of imported N43,
N116, and
N206 all
produced the same 6-kDa fragment as that of AtOEP34 (Fig. 2, lanes 4, 8, 12, and 16).
N272 has a length
indistinguishable from the 6-kDa fragment in our gel system (Fig. 2,
lane 17, arrow) and
N272 was basically
thermolysin-resistant after import (Fig. 2, lane 20). These
data further support that the 6-kDa fragment is the C-terminal portion
of AtOEP34, most likely the portion from amino acids 273-313. These
data also indicate that the N-terminal deletion mutants had inserted
into the outer membrane in the same orientation as the full-length
AtOEP34.
The mutant protein with the C-terminal 31 amino acids deleted, At(1-282), was still targeted to chloroplasts (Fig. 2, lane 23). Thermolysin treatment of imported At(1-282) resulted in a fragment (lane 24, arrow) smaller than the 6-kDa fragment of AtOEP34. This fragment further supports that the 6-kDa fragment of AtOEP34 resulted from thermolysin cleavage at around amino acid 273, so a C-terminal deletion mutant like At(1-282) would still have the cleavage site but resulted in a smaller sized fragment. This result also indicates that At(1-282) had inserted into the outer membrane the same way as AtOEP34 did. However the import efficiency of At(1-282) was much lower than that of AtOEP34 (Fig. 4). This suggests that amino acids following number 282 are not necessary for targeting but are important for import efficiency. Alkaline extraction of all the imported N-terminal deletion mutants and At(1-282) indicated that most of the imported proteins were integral membrane proteins (data not shown).
The deletion in the mutant protein At(1-271) extends into the
hydrophobic core of the AtOEP34 membrane-anchoring domain (Fig. 3A). This mutant could no longer associate with chloroplasts
(Fig. 2, lanes 25-28). Compared with At(1-282) (Fig.
3A), this result indicates that amino acids 272-282 (or
273-282 compared with N272) are necessary for targeting and
insertion of AtOEP34 to the chloroplastic outer membrane.
To investigate if the
hydrophobic core of amino acids 272-282 is also sufficient for
chloroplastic outer membrane targeting, we made two fusion proteins in
which the C-terminal portion of AtOEP34 was fused to the C terminus of
Schistosoma japonicum GST. GST was chosen as the passenger
protein, because many fusion proteins with foreign polypeptides fused
at the C terminus of GST remain soluble and actively bind glutathione
(23), indicating the GST portion has folded into its active
conformation and the foreign polypeptide at the C terminus is not
likely to be buried by GST. The first fusion protein contained only the
hydrophobic core of AtOEP34 and was named GST×(272-282) (Fig. 3). To
ensure better import efficiency and for cloning convenience, we also
fused amino acids 253-313 of AtOEP34 to the C terminus of GST and
created the fusion protein GST×(253-313) (Fig. 3). The results of
their import to chloroplasts are shown in Fig. 5. GST by
itself could not associate with chloroplasts (lanes 1-4).
When amino acids 272-282 of AtOEP34 were fused at its C terminus, the
fusion protein could associate with chloroplasts. However, the import
efficiency was very low (Fig. 4), and few imported molecules had
inserted into the outer membrane, since almost all the imported
molecules remained thermolysin-sensitive (Fig. 5, lane 8).
On the other hand, when GST was fused to amino acids 253-313 of
AtOEP34, not only was the import efficiency higher (Fig. 4),
thermolysin digestion of the imported molecules produced the same 6-kDa
fragment as that of full-length AtOEP34 (Fig. 5, lane 12, arrow). This indicates that fusion protein GST×(253-313) had
inserted into the outer membrane in the same orientation as AtOEP34.
These data also show that although amino acids 273-282 of AtOEP34 can
lead to association with chloroplasts, proper insertion of a fusion
protein into the outer membrane requires the entire C-terminal portion
of AtOEP34, starting at least from amino acid 253.
The C-terminal Membrane-anchoring Domain Can Also Function as a Targeting Signal when Located at the N Terminus of a Passenger Protein
An inspection of the deletion mutant N272 revealed
that the necessary targeting signal, amino acids 273-282, was located at the extreme N terminus of the protein (Fig. 3A). This
prompted us to ask the question whether the targeting signal could
still function if it was placed at the N terminus of a passenger
protein as opposed to its normal C-terminal location. To answer this
question, we made four fusion proteins in which various lengths of
AtOEP34 C-terminal portion were fused to the passenger protein DHFR or the mature protein region of the SS (Fig. 3). These two proteins, when
fused at the C termini of other polypeptides, have been used successfully to assay polypeptides with a potential function as targeting signals (11, 16, 24, 25), indicating polypeptides fused at
their N termini are properly exposed. We first fused amino acids
273-282 and 273-313 to SS and created the fusion proteins (273-282)×SS and (273-313)×SS (Fig. 3). To make sure any effect we
see with these fusion proteins is not due to the passenger protein we
chose, we made another two fusion proteins in which the C-terminal
portion of AtOEP34 from amino acid 250 or 273 was fused to another
passenger protein, DHFR. These two fusion proteins were named
(250-313)×DHFR and (273-313)×DHFR (Fig. 3). When synthesized in an
in vitro translation system, the plasmid encoding
(250-313)×DHFR yielded three major products (Fig. 6,
lane 1). The two lower molecular weight products (lane
1, arrows) probably resulted from internal initiations from the
methionine residue of amino acid 273 of AtOEP34 and the initiation
methionine of DHFR. This is supported by the fact that the plasmid
encoding (273-313)×DHFR yielded two bands identical to these two
lower molecular weight bands of (250-313)×DHFR (Fig. 6, lane
5). The construct (273-313)×SS yielded two products in an
in vitro translation system (Fig. 6, lane 13).
The lower molecular weight product (lane 13, arrow) has the
same molecular weight as SS and is most likely an internal initiation
from the first residue of SS, which happens to be a methionine (Fig.
3B).
Import competency of these fusion proteins was tested with isolated chloroplasts, and all of them could associate with chloroplasts (Fig. 6, lanes 3, 7, 11, and 15). All of the imported (273-282)×SS molecules remained thermolysin-sensitive (Fig. 6, lane 12), indicating no insertion had occurred. These data show that the necessary signal, amino acids 273-282, could lead to association with chloroplasts even when placed at the N terminus of a passenger protein. However, as with the GST fusions, amino acids following number 282 are critical for import efficiency and insertion (see below).
Passenger Proteins at the C Terminus of the AtOEP34-targeting Signal Were Translocated into the Intermembrane SpaceMost (273-313)×SS fusion protein molecules were thermolysin-resistant after import (Fig. 6, lane 16), indicating that (273-313)×SS had been translocated into or across the outer membrane. In addition, import of (250-313)×DHFR and (273-313)×DHFR resulted in a distinct population of lower molecular weight proteins (Fig. 6, brackets by lanes 4 and 8). These lower molecular weight proteins were almost totally thermolysin-resistant after import, indicating they were internal to the outer membrane. It is possible that the DHFR portion of the fusion proteins was translocated into the intermembrane space and was degraded by some unknown protease located there.
To confirm the location of thermolysin-resistant population of the
imported fusion proteins, chloroplasts after import of (250-313)×DHFR
and (273-313)×SS were treated with thermolysin, then fractionated
into the outer and inner envelope membrane, the stroma, and the
thylakoid fractions (Fig. 7). OEP34, SS, and chlorophyll
a/b-binding protein were used as markers for the outer envelope membrane, the stroma, and the thylakoid, respectively. Chloroplasts containing imported N272 were also fractionated to
confirm its outer membrane location. As shown in Fig. 7, most of the
thermolysin-resistant (250-313)×DHFR and (272-313)×SS fusion proteins were still located at the outer membrane. The portion in the
inner membrane most likely arose from contamination by the outer
membrane (Ref. 26, see also the OEP34 control). Interestingly, some of
the lower molecular weight proteins generated after import of
(250-313)×DHFR were predominantly located in the "stroma"
fraction. Our fractionation method cannot separate the content of the
intermembrane space from that of the stroma. It is possible that these
lower molecular weight products were in the intermembrane space. This would agree with our hypothesis that these lower molecular weight products were generated from degradation and release of imported (250-313)×DHFR by some protease in the intermembrane space. However, we could not exclude the possibility that these lower molecular weight
products were in the stroma.
To further confirm that the passenger proteins at the C terminus of the AtOEP34-targeting signal have been translocated across or into the outer membrane, we employed another more specific protease, factor Xa. The cleavage site for factor Xa has been engineered into the junctions of all fusion proteins between AtOEP34 and the various passenger proteins (Fig. 3). If the prediction about the membrane topology of AtOEP34 in the outer membrane is correct, then a fusion protein with the passenger protein located at the N terminus of the AtOEP34-targeting signal, e.g. GST×(253-313), should have the factor Xa cleavage site exposed in the cytosol, and imported GST×(253-313) should be sensitive to exogenous factor Xa. On the other hand, for a fusion protein with the passenger protein located at the C terminus of the AtOEP34-targeting signal, e.g. (273-313)×SS, the factor Xa cleavage site should be buried in the outer membrane or translocated into the intermembrane space, and imported (273-313)×SS should be factor Xa-resistant.
As shown in Fig. 8A, in vitro
translated GST×(253-313) was cleaved by factor Xa into two major
bands, the GST portion and the AtOEP34 membrane-anchoring portion (Fig.
8A, lane 2, arrows). When imported GST×(253-313) was
treated with factor Xa, all of the imported proteins were factor
Xa-sensitive (lane 4). The GST portion was released into the
supernatant (lane 5) and the membrane-anchoring region of
AtOEP34 remained associated with the chloroplasts (lane 4).
In contrast, although in vitro translated (273-313)×SS was also cleaved by factor Xa into two major bands, the SS region and the
membrane-anchoring region of AtOEP34 (lane 7, arrows), most
imported (273-313)×SS molecules were factor Xa-resistant (lane
9), indicating the factor Xa cleavage site had been translocated into a location that was inaccessible to factor Xa. The supernatant still contained some digested fragments, but both the SS and the AtOEP34 membrane-anchoring fragments were there (lane 10).
These fragments probably arose from those (273-313)×SS molecules that were only bound to, but had not inserted into, the outer membrane. The
small amount of SS remained associated with chloroplasts after digestion could be due to the tendency of SS to stick to the envelope membranes of chloroplasts (27).
In an effort to find out if the factor Xa site in (272-313)×SS was buried in the outer membrane or exposed in the intermembrane space, outer membrane vesicles were isolated after import of GST×(253-313) and (273-313)×SS and subjected to various treatments. When these outer membrane vesicles were treated with factor Xa directly, most of the imported GST×(253-313) was sensitive (Fig. 8B, lane 3), and most of the imported (273-313)×SS was resistant (lane 7), confirming the right-side-out orientation of these vesicles (7, 28). Imported (272-313)×SS could be fully digested if the membranes were permeabilized by 1% Triton X-100 (Fig. 8B, lane 8), indicating the factor Xa resistance of imported (273-313)×SS was not due to the possibility that (273-313)×SS had folded into a conformation that rendered the factor Xa site inaccessible. It has been reported that when membrane vesicles are subjected to a cycle of freezing and thawing, contents from the surrounding solution, e.g. exogenous proteases, can be enclosed into the vesicles during thawing (19). We tried this treatment on the isolated chloroplastic outer membrane vesicles to enclose factor Xa into the vesicles. While this treatment had no additional effect on the digestion of imported GST×(253-313) (Fig. 8B, lane 2), the treatment increased the amount of (273-313)×SS digested by factor Xa (lane 6). Although the amount of increase was low, it supports that the factor Xa cleavage site in (273-313)×SS was exposed in the intermembrane space.
AtOEP34 is the first protein reported to have a C-terminally located chloroplast-targeting signal. Uniquely, this signal can function at both termini of passenger proteins. Although the signal is a signal-anchor sequence as in the case of OEP14, the two signals not only are located at opposite ends of their respective polypeptide, but also insert into the outer membrane in opposite orientations. The signal of OEP14 has its C-terminal end facing the cytosol (11), while the signal of OEP34 has its N-terminal end facing the cytosol. These data suggest that AtOEP34 may use a different import pathway from the one used by OEP14 or other outer membranes proteins without cleavable transit peptides.
Fusion protein studies also suggest that AtOEP34 uses an unusual mechanism for its insertion into the outer membrane. Passenger proteins fused to the C terminus of the AtOEP34-targeting signal are translocated into the intermembrane space of the envelope. This means the mechanism AtOEP34 uses for integration can translocate a polypeptide of at lease 26 kDa (the molecular mass of DHFR) across the outer membrane. This supports the existence of a facilitated transport system, e.g. a proteinaceous channel, rather than a spontaneous insertion. Indeed, one report has shown that the insertion of pea OEP34 into the outer membrane requires some thermolysin-sensitive components and is stimulated by ATP. Our data also indicate that association of AtOEP34 and (273-313)×SS with chloroplasts is sensitive to thermolysin pretreatment of chloroplasts. Insertion of both AtOEP34 and (273-313)×SS is stimulated by ATP.2 These data suggest that AtOEP34 uses an import pathway that has a proteinaceous receptor that recognizes a C-terminal signal-anchor sequence, different from all chloroplast protein import pathways described so far.
It therefore seems the three components in the transport machinery of the chloroplastic outer membrane, OEP86, OEP75, and OEP34, may use three different pathways for their targeting to chloroplasts. OEP75 uses the general transit peptide-dependent targeting pathway at least for the beginning of its import (15). OEP86 does not use the general transit peptide-dependent pathway, but possesses a negatively charged cleavable targeting sequence at its N terminus (13). OEP34 is targeted to chloroplasts by a C-terminal signal-anchor sequence. Unfortunately, plant mutants defective in individual components of the transport machinery are not available. Therefore, it is not clear whether the three components really use three different pathways or each uses other components in the complex to facilitate its own import and therefore bypass part of the pathway, similar to the situation of the yeast mitochondrial protein import machinery (29-31).
Deletion of 58 amino acids from the C terminus of pea OEP34 also abolishes the association of pea OEP34 with chloroplasts (9). It is likely that the chloroplastic outer membrane-targeting signal of pea OEP34 is also located at the C-terminal hydrophobic-core region (Fig. 1, underlined). At least two other clones that show a high degree of similarity to OEP34 have been found in the Arabidopsis EST data base (20). If they are also homologues of OEP34, sequence comparison with these two additional clones and site-directed mutagenesis will help to identify the critical residues or structure(s) of the OEP34-targeting signal.
We thank the Arabidopsis Biological Resource Center at the Ohio State University for the AtOEP34 cDNA clone. We also thank Jenny Dorl and Drs. Kathy Archer, C.-T. Chien, Ulrich Hartl, Ken Keegstra, and Chung Wang for critical reading of the manuscript.