Analysis of the Interactions of Preproteins with the Import Machinery over the Course of Protein Import into Chloroplasts

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J. Cell Biol.
© The Rockefeller University Press
0021-9525/97/12/1677/09 $2.00
Volume 139, Number 7, December 29, 1997 1677-1685

Analysis of the Interactions of Preproteins with the Import Machinery over the Course of Protein Import into Chloroplasts

Andrei Kouranov, and Danny J. Schnell

Department of Biological Sciences, Rutgers University, Newark, New Jersey 07102

Abstract

Materials and Methods

Results

Discussion

Footnotes

Acknowledgements

Abbreviations used in this paper

References

Abstract

We have investigated the interactions of two nuclear-encoded preproteins with the chloroplast protein import machinery atthree stages in import using a label-transfer crosslinking approach.During energy-independent binding at the outer envelope membrane,preproteins interact with three known components of the outermembrane translocon complex, Toc34, Toc75, and Toc86. AlthoughToc75 and Toc86 are known to associate with preproteins duringimport, a role for Toc34 in preprotein binding previously hadnot been observed. The interaction of Toc34 with preproteins isregulated by the binding, but not hydrolysis of GTP. These dataprovide the first evidence for a direct role for Toc34 in import,and provide insights into the function of GTP as a regulator ofpreprotein recognition. Toc75 and Toc86 are the major targetsof cross-linking upon insertion of preproteins across the outerenvelope membrane, supporting the proposal that both proteinsfunction in translocation at the outer membrane as well as preproteinrecognition. The inner membrane proteins, Tic(21) and Tic22, anda previously unidentified protein of 14 kD are the major targetsof crosslinking during the late stages in import. These data provideadditional support for the roles of these components during proteintranslocation across the inner membrane. Our results suggest adefined sequence of molecular interactions that result in thetransport of nuclear-encoded preproteins from the cytoplasm intothe stroma of chloroplasts.

AS a consequence of its dual genetic origin, the chloroplast must import the vast majority of its polypeptide components fromtheir site of synthesis in the cytoplasm. The import of nuclear-encodedproteins into the chloroplast is mediated by interactions betweenthe intrinsic NH₂-terminal targeting signal (transit sequence)of the preprotein and a common recognition and translocation machineryat the chloroplast envelope (for review see Cline and Henry, 1996;Fuks and Schnell, 1997; Lübeck et al., 1997). The general importmachinery is composed of independent translocon complexes in theinner and outer envelope membranes (Schnell et al., 1997). Thetranslocon at the outer envelope membrane of chloroplasts (Toc)¹ complex mediates the initial binding of cytoplasmic preproteinsat the chloroplast surface and their subsequent ATP/GTP-dependenttranslocation across the outer membrane. Translocation acrossthe inner membrane is mediated by the translocon at the innerenvelope membrane of chloroplasts (Tic) complex and is drivenby ATP hydrolysis in the stroma. The Toc and Tic complexes associateat contact sites between the outer and inner envelope membranesto facilitate direct translocation of preproteins from the cytoplasmto the stroma (Schnell and Blobel, 1993; Nielsen et al., 1997).A fraction of Toc and Tic complexes can be coimmunoprecipitated(Nielsen et al., 1997), suggesting that a portion of the outerand inner membrane import machineries may be stably linked understeady state conditions.

Initial binding of the preprotein to the Toc complex is mediated by a trimeric complex composed of Toc34, Toc75, and Toc86(Waegemann and Soll, 1991; Hirsch et al., 1994; Kessler et al.,1994; Schnell et al., 1994; Seedorf et al., 1995; Tranel et al.,1995). Antibody inhibition (Hirsch et al., 1994) and covalentcrosslinking studies (Perry and Keegstra, 1994; Ma et al., 1996)indicate a role for Toc86 in preprotein binding. Toc75 appearsto form at least part of the translocation channel at the outermembrane translocon because it is efficiently crosslinked to preproteinsin the presence of low concentrations of ATP and GTP (0.1 mM)that promote insertion of the preprotein across the outer membrane(Perry and Keegstra, 1994; Ma et al., 1996). Experimental evidencefor the function of Toc34 in import is lacking, but it has beenproposed that it acts in concert with Toc86 to regulate preproteinrecognition. This proposal is consistent with the observationsthat both Toc34 and Toc86 are GTP-binding proteins (Hirsch etal., 1994; Kessler et al., 1994; Seedorf et al., 1995) and thatGTP is required at the early stages of import (Olsen and Keegstra,1992; Kessler et al., 1994).

Several components of the inner membrane translocon have been identified. An integral inner membrane component, Tic110 (Schnellet al., 1994; Wu et al., 1994; Lübeck et al., 1996), has beendetected in complexes containing proteins at late stages in import.Tic110 coimmunoprecipitates with two stromal chaperones, the hsp60homologue, cpn60 (Kessler and Blobel, 1996), and the chloroplastClpC homologue (Nielsen et al., 1997). These observations suggestthat Tic110 may function as a docking site for molecular chaperonesthat participate in driving transport across the inner membraneor in folding of newly imported proteins in the stroma. Two additionalcomponents of the chloroplast envelope, IAP21 and IAP25, havebeen covalently crosslinked to modified versions of the precursorto the small subunit of ribulose-1,5-bisphosphate carboxylase(pS) at an intermediate stage in import (Ma et al., 1996). Onthe basis of the localization at the inner membrane (Kouranov,A., and D.J. Schnell, unpublished observation) and in accordancewith the newly adopted uniform nomenclature for chloroplast importcomponents (Schnell et al., 1997), we now refer to IAP21 and IAP25as Tic(21) and Tic22, respectively. The ability to directly crosslinkTic(21) and Tic22 to preproteins suggests that they form partof the recognition or translocation channel at the inner membrane.

Although several components of the Toc and Tic complexes have been identified based on their association with preproteins,the sequence of molecular interactions that result in the importof preproteins from the cytoplasm to the stroma has not been mapped.In this report, we have investigated the interactions of two preproteinswith the Toc and Tic complexes using site-specific crosslinkingto intermediates at three known stages in import: preprotein recognition,outer membrane translocation, and inner membrane translocation.Our results indicate that Toc34, Toc75, and Toc86 directly interactwith preproteins during recognition at the outer membrane. Theinteraction of preproteins with Toc34 is regulated by GTP binding.Toc86 and Toc75 are associated with preproteins during outer membranetranslocation, suggesting that both proteins may participate inprotein conductance at this membrane. Tic(21), Tic22, and a previouslyunidentified protein, designated Tic(14), are the major crosslinkingtargets during inner membrane translocation.

Materials and Methods

Preparation of Crosslinking Substrates

Plasmid pET21b-pS-protA encoding the pS-protA preprotein was constructed as previously described (Schnell and Blobel, 1993).Plasmid pET21b-pFd-protA-1 encoding pFd-protA-1 was generatedby PCR-directed mutagenesis of pET-pFd-protA (Ma et al., 1996)with primers that introduced the following changes in the pFdcoding region: a methionine to cysteine conversion at position $-$ 1 and a glutamate-phenylalanine insertion at position +4. Theremainder of the pFd-protA-1 sequence was identical to pFd-protA(Ma et al., 1996). Plasmid pET21b-pS-protA-1 encoding pS-protA-1was generated by PCR-directed mutagenesis of pET21b-pS-protA tochange the cysteine at position $-$ 1 to serine. The remainder ofthe pS-protA-1 sequence was identical to pS-protA. Plasmid pET21b-pS-protA-2encoding pS-protA-2 was generated by PCR-directed mutagenesisof pET21b-pS-protA-1 with primers that introduced the followingchanges: a valine to glutamate conversion at position +39 andthe elimination of the cysteine at position +41. The remainderof the pS-protA-2 sequence was identical to pS-protA-1.

The pS-protA, pS-protA-1, pS-protA-2, and pFd-protA-1 polypeptides were expressed in Escherichia coli BL21 (DE3) containingCOOH-terminal extensions of six histidine residues. The preproteinswere purified from extracts by affinity chromatography on a nickel-chelatematrix according to the supplier's recommendations (Novagen, Inc.,Madison, WI).

The iodination of the heterobifunctional crosslinking reagent, N-[4[(p-azidosalicylamido)butyl]-3 $'$ (2-pyridyldithio)propionamide(APDP; Pierce, Inc., Rockford, IL) and the coupling of [¹²⁵I]APDP to preproteins were performed as previously described (Maet al., 1996). The molar ratio of [¹²⁵I]APDP to cysteine residues for each preprotein was 1.5:1 in allcoupling reactions. The crosslinking substrates were stored at $-$ 80°C in 0.1 M NaHCO₃, pH 9.0, containing 8 M urea.

Chloroplast Isolation and Subfractionation

Intact chloroplasts were isolated from 10- to 14-d-old pea seedlings (Pisum sativum variant Green Arrow) by homogenizationand Percoll silica gel gradient centrifugation as previously described(Pain and Blobel, 1987). Isolated chloroplasts were resuspendedin 50 mM Hepes-KOH, pH 7.7, 0.33 M sorbitol (HS buffer) to a concentrationequivalent to 2 to 3 mg chlorophyll/ml.

To prepare chloroplast envelope membranes, intact chloroplasts were lysed under hypertonic conditions and separated into solubleand membrane fractions by differential centrifugation as describedby Keegstra and Yousif (1986). The total membrane fraction wasseparated into envelope and thylakoid membrane fractions by flotationinto linear sucrose gradients as previously described (Schnellet al., 1994).

Precursor Binding and Crosslinking Reactions

Isolated intact chloroplasts were incubated in HS buffer containing 50 mM KOAc, 4 mM MgOAc (import buffer) in the presenceof 400 nM nigericin for 15 min at 26°C in the dark to depletethem of endogenous ATP. All binding reactions were performed inthe dark using chloroplasts equivalent to 2 mg chlorophyll ina reaction volume of 1 ml. For the binding of precursor in theabsence of ATP (energy-independent binding), 20 U of apyrase (SigmaChemical Co., St. Louis, MO) was added to the chloroplast suspensionduring the ATP depletion reaction. For the binding of precursorin the presence of ATP (early import intermediate), ATP-depletedchloroplasts were incubated in the presence of 0.1 mM MgATP and0.1 mM MgGTP for 5 min at 26°C. For the import reactions, ATP-depletedchloroplasts were incubated in the presence of 2 mM MgATP for5 min at 26°C. After the pretreatments, urea-denatured preproteinwas added to a final concentration of 200 nM, and the incubationwas continued for 10 min (energy-independent binding and earlyimport intermediate) or 20 min (late import stage) at 26°C. Thechloroplasts were transferred to the bottom half of a glass petridish on ice and irradiated from above with a chromato-vu transilluminator(UVP, Inc., Upland, CA) at 312 nm at a distance of 5 cm for 20min with constant shaking. Thermolysin treatment of intact chloroplastswas performed as described previously (Cline et al., 1984) using0.1 mg thermolysin/ml for 30 min on ice. The chloroplasts werecollected by centrifugation for 30 s at 6,000 g in a microcentrifuge,subfractionated as described above, and the envelope fractionswere analyzed by SDS-PAGE.

Sample Analysis and Quantitation

All crosslinked samples were resolved by SDS-PAGE on 12% polyacrylamide gels. The radioactive signals in dried gels were capturedand quantitated using a Phosphorimager SI (Molecular Dynamics,Inc., Sunnyvale, CA) with the IPLab gel scientific image processingversion 1.5c program (Signal Analytics, Vienna, VA). All imagesof radioactive gels were captured using the IP Labgel software.Image labels were added using Canvas version 2.1 software (DenebaSystems, Inc., Miami, FL), and images were printed on an XLS 8600PS printer (Kodak, Rochester, NY).

Results

Similar Envelope Import Components Are Crosslinked to Two Chimeric Preproteins

We performed label transfer crosslinking experiments with preproteins at each of the known stages in import to map the specificmolecular interactions between preproteins and components of theouter and inner membrane translocons. Two chimeric preproteins,pS-protA and pFd-protA-1, were used as crosslinking substratesfor these studies (Fig. 1). The pS-protA and pFd-protA-1 preproteinsconsisted of pS or preferredoxin (pFd) fused at their COOH terminito the IgG binding domains of staphylococcal protein A, respectively.Both pS-protA and pFd-protA-1 were modified with the photoactivatible,cleavable crosslinking reagent, [¹²⁵I]APDP, at cysteine residues by a disulfide exchange reactionto yield the crosslinking substrates (Fig. 1). The modificationsof pS-protA and pFd-protA-1 with [¹²⁵I]APDP had a negligible effect on the binding and import characteristicsof the preproteins in in vitro assays using intact chloroplasts(data not shown). The pS-protA and pFd-protA-1 proteins providedcrosslinking substrates derived from two preproteins of similarsize with crosslinking groups at comparable positions within theirtransit sequences and at additional sites within their maturesequences.

Fig. 1. Schematic diagram of the crosslinking substrates used in this study. The names of the preproteins used as crosslinking substratesare indicated to the left of each figure. The positions of thetransit sequences, mature sequences, and IgG-binding domain ofprotein A are indicated by boxed regions. The positions of [¹²⁵I]APDP-reactive cysteines are indicated above each figure. Thescale in amino acid residues is indicated at the bottom of eachfigure. The +1 residue refers to the amino-terminal residue ofthe mature polypeptides.
[View Larger Version of this Image (21K GIF file)]

To investigate the interactions of preproteins with translocon components, pS-protA and pFd-protA-1 were crosslinked to isolatedchloroplasts at three known stages in import. These stages aredefined as energy-independent binding observed in the presenceof the NTP hydrolyzing enzyme, apyrase (Ma et al., 1996); an earlyimport intermediate observed in the presence of 0.1 mM ATP andGTP (Cline et al., 1985; Schnell et al., 1993); or a late stagein import observed in the presence of 2 mM ATP and 0.1 mM GTP(Schnell et al., 1993). The late stage of import contains bothproteolytically processed and unprocessed import substrates. Theprocessed substrate previously was shown to represent a late importintermediate that is simultaneously inserted across the outerand inner membranes. The presence of the late import intermediateat this stage provided the potential to identify components ofthe inner membrane translocon.

Isolated chloroplasts were depleted of endogenous ATP by incubation in the dark at 26°C in the presence of the proton ionophore,nigericin. Energy-depleted chloroplasts were incubated with apyraseor NTP and either pS-protA or pFd-protA-1 and irradiated to inducephotocrosslinking. After crosslinking, the chloroplasts were reisolatedand fractionated to yield a total envelope membrane fraction.The envelope proteins were treated under reducing conditions tocleave the crosslinker and resolved by SDS-PAGE. Cleavage of thecrosslinker with reducing agents releases the ¹²⁵I-ADP moiety from the preprotein, but it remains covalently attachedto the target protein, allowing the crosslinked products to bevisualized directly by fluorography.

The results of crosslinking are shown in Fig. 2. The pS-protA and pFd-protA-1 substrates migrate at 52 and 55 kD, respectively,and are detected in all lanes of Fig. 2. Both preproteins retaina significant amount of radiolabel even after treatment with reducingagents, indicating that irradiation induces significant intra-or intermolecular crosslinking of the substrates themselves. Theoverall pattern of crosslinking to envelope components with pS-protAand pFd-protA-1 is remarkably similar at all stages of import(Fig. 2). This observation is consistent with previous proposalsthat preproteins use a common import machinery at the envelope.

Fig. 2. Crosslinking of pS-protA and pFd-protA-1 to envelope polypeptides at three stages in import. Energy-depleted chloroplasts(2 mg chlorophyll) were incubated with 200 nM urea denatured pS-protAand pFd-protA-1 in a standard import assay-containing apyrase(+ Apyrase), or the indicated concentrations of ATP (ATP) andGTP (GTP) at 26°C in the dark. The chloroplasts were irradiatedat 312 nM for 20 min on ice with a transilluminator at a distanceof 5 cm. Reisolated chloroplasts were fractionated to yield atotal envelope membrane fraction. Envelope membranes (50 µg ofprotein) were analyzed by SDS-PAGE under reducing conditions andfluorography. The molecular masses of standard proteins are indicatedat the center of the figures. The positions of pS-protA, S-protA,pFd-protA-1, Fd-protA-1, Toc86, Toc75, Toc34, Tic22, and Tic(21)are shown to the left and right of the figures. Asterisks indicatethe position of the 45-kD crosslinked protein, and arrowheadsindicate the position of the 14-kD crosslinked protein.
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As previously observed (Ma et al., 1996), Toc86 and Toc75 are crosslinked at the energy-independent binding of both pS-protA(Fig. 2, lane 1) and pFd-protA-1 (Fig. 2, lane 4). In addition,a 34-kD crosslinked protein coincident with Toc34 is present atthe binding stage (Fig. 2, lanes 1 and 4). Fig. 3 shows that anti-Toc34serum immunoprecipitates the 34-kD crosslinked product from pS-protAcrosslinking reactions, confirming that this polypeptide is Toc34.Similar results were obtained with pFd-protA-1 crosslinked membranes(data not shown). The results in Fig. 2 are consistent with thehypothesis that Toc34 participates in preprotein recognition atthe outer membrane.

Fig. 3. Immunoprecipitation of the crosslinked 34-kD protein with anti-Toc34. Envelope membranes (50 µg protein) from a pS-protA crosslinkingreaction (lane 1, Env) were reduced with 100 mM DTT, dissolvedunder denaturing conditions, and immunoprecipitated with anti-Toc34serum (anti-34) or anti-Toc34 preimmune serum (PI). The immunoprecipitateof anti-Toc34 reactions (B) and the unbound supernatant (U) wereanalyzed by SDS-PAGE and fluorography.
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Crosslinking of preproteins to Toc34 was not detected in previous studies using similar methods (Perry and Keegstra, 1994;Ma et al., 1996). As is demonstrated below (see Fig. 8), Toc34crosslinking is very sensitive to the presence of NTPs. Therefore,we believe that the short apyrase pretreatment used in the previousstudies was insufficient to completely deplete chloroplasts ofexogenous NTPs (Ma et al., 1996). In the present study, we foundit necessary to extend the apyrase preincubation to obtain consistentToc34 crosslinking.

Fig. 8. Energy requirements for pS-protA-1 crosslinking to Toc34. Energy-depleted chloroplasts (2 mg chlorophyll) were incubated with200 nM urea-denatured pS-protA-1 in the presence of apyrase (+Apyrase), or 0.1 mM ATP (+ATP), GTP (+GTP), GDP (+GDP), or GMP(+GMP) for 10 min at 26°C in the dark and crosslinked by UV irradiation.The envelope fraction (50 µg protein) from crosslinked chloroplastswas analyzed by SDS-PAGE and fluorography. The positions of pS-protA-1,Toc86, and Toc34 are shown to the left of the figure.
[View Larger Version of this Image (65K GIF file)]

A minor crosslinked band of 45 kD (Fig. 2, asterisk) is apparent with both substrates (Fig. 2, lanes 1 and 4) at energy-independentbinding. The identity of this protein is unknown. Additional faintcrosslinked bands are observed at 70 and 60 kD with pFd-protA-1(Fig. 2, lane 4). The identity of these two proteins was not investigatedbecause crosslinking was only observed with pFd-protA-1. We focusedour studies on proteins found in crosslinking reactions with bothproteins because they are likely to represent components of thegeneral import apparatus.

Toc86 and Toc75 are crosslinked to the early import intermediates of both pS-protA and pFd-protA-1 (Fig. 2, lanes 2 and 5),with the levels of Toc75 crosslinking significantly increasingover those observed at the binding stage of import. Crosslinkingto Toc34 decreases to undetectable levels in the presence of exogenousATP and GTP (Fig. 2, lanes 2 and 5). In addition to the outermembrane components, two components of the inner membrane translocon,Tic(21) and Tic22, are crosslinked to the early import intermediates(Fig. 2, lanes 2 and 5).

Toc75 and Toc86 are major crosslinked products in the outer membrane under import conditions (i.e., 2 mM ATP, 0.1 mM GTP)with pS-protA (Fig. 2, lane 3) and pFd-protA-1 (Fig. 2, lane 6).These results are consistent with the observation that both processedand precursor forms of the substrates are present at this stage(Fig. 2, lanes 3 and 6) and that late import intermediates spanboth the outer and inner membrane translocons (Schnell et al.,1994). The inner membrane import components, Tic(21) and Tic22,also are major crosslinked products at the late stage in import(Fig. 2, lanes 3 and 6). In addition to these known components,a previously unidentified crosslinked product is apparent at ~14kD (Fig. 2, lanes 3 and 6, arrowhead). The identity of this proteinhas not been determined, although immunoblot analysis indicatesthat it is not the mature small subunit of rubisco (data not shown).This polypeptide is a new candidate for a component of the innermembrane translocon.

The crosslinking data in Fig. 2 suggest a sequence of events in which the preprotein successively inserts more deeply intothe outer and inner membrane translocons en route to the stroma.The label transfer crosslinking technique provides a method toassess the degree of preprotein insertion into the transloconcomplexes by performing crosslinking with preproteins that havebeen engineered with crosslinking sites at various positions withintheir primary structures. To take advantage of this method, twoderivatives of pS-protA were generated by site-directed mutagenesisto eliminate the cysteine at position $-$ 1 in the transit sequence(pS-protA-1) or the cysteines at both position $-$ 1 and +41 (pS-protA-2;Fig. 1). These crosslinking substrates allowed us to examine theextent of envelope translocation of pS-protA at each stage inimport by determining the extent of crosslinking to outer andinner membrane translocon components.

The results of crosslinking to the pS-protA derivatives is shown in Fig. 4. The patterns of crosslinked proteins with pS-protA,pS-protA-1, and pS-protA-2 are very similar in the absence ofenergy (Fig. 4, compare lanes 1, 4, and 7). As previously observed,Toc34 and Toc86 are the major crosslinked products with pS-protAat this stage. Toc86 and Toc34 also are efficiently labeled withpS-protA-1 and pS-protA-2 (Fig. 4, lanes 4 and 7). These resultsindicate that residues as far as 112 amino acids from the transitsequence of the preprotein are associated with these two outermembrane components during initial binding of the preprotein.

Fig. 4. Crosslinking of pS-protA, pS-protA-1, or pS-protA-2 to envelope polypeptides at three stages in import. Energy- depleted chloroplasts(2 mg chlorophyll) were incubated with 200 nM urea-denatured pS-protA(pS-protA), pS-protA-1 (pS-protA-1), or pS-protA-2 (pS-protA-2)in the presence of apyrase (+ Apyrase), or the indicated concentrationsof ATP (ATP) and GTP (GTP) at 26°C in the dark. The chloroplastswere irradiated at 312 nM for 20 min on ice with a transilluminatorat a distance of 5 cm. Reisolated chloroplasts were fractionatedto yield a total envelope membrane fraction. Envelope membranes(50 µg of protein) were analyzed by SDS-PAGE under reducing conditionsand fluorography. The molecular masses of standard proteins areindicated at the center of the figures. The positions of pS-protA,S-protA, Toc86, Toc75, Toc34, Tic22, and Tic(21) are shown tothe left and right of the figures.
[View Larger Version of this Image (87K GIF file)]

In the presence of 0.1 mM ATP and GTP, Toc86 is a major crosslinking target in the outer membrane with all three substrates(Fig. 4, lanes 2, 5, and 8). Crosslinking of all three substratesto Toc34 is dramatically reduced, indicating that the interactionof Toc34 with the preprotein is sensitive to the presence of NTPs(Fig. 4, lanes 2, 5, and 8). In contrast, crosslinking to Toc75and the inner membrane components, Tic(21) and Tic22, is observedonly with pS-protA (Fig. 4, lanes 2, 5, and 8). These data suggestthat only the NH₂-terminal residues of pS-protA have insertedinto or across the outer membrane translocon at this early importintermediate stage.

In the presence of concentrations of ATP that promote insertion of the preproteins across the inner membrane, Toc86 is stillcrosslinked to all three substrates (Fig. 4, lanes 3, 6, and 9).Toc75 and Tic22 crosslink to both pS-protA and pS-protA-1 (Fig.4, lanes 3, and 6). Therefore, the transit sequence and at least41 amino acids of the preprotein have translocated across theouter membrane and are exposed to the outer face of the innermembrane at the late stage of import. The integral inner membraneprotein, Tic(21), and the 14-kD protein of unknown identity arecrosslinked only to pS-protA (Fig. 4, lane 3), suggesting thatonly the NH₂-terminal regions of the preprotein have engaged thesecomponents. The pS-protA-2 substrate does not label Toc75 or innermembrane components at this stage (Fig. 4, lane 8) indicatingthat the COOH-terminal region of the pS domain and the entireprotein A domain of the preprotein remain exposed to the cytoplasmicside of the outer membrane.

Toc86 Functions in Preprotein Recognition and Translocation at the Outer Membrane Translocon

Toc86 is consistently and efficiently crosslinked to all substrates at each stage in import (Fig. 4), indicating a key rolefor this protein in the outer membrane translocon. However, therelationship of crosslinking to the function of Toc86 is unclear.Toc86 has been proposed to represent a receptor for preproteinsat the outer envelope and has previously been shown to crosslinkto the transit sequence of pS in the absence of energy or in thepresence of 0.1 mM ATP and 0.1 mM GTP (Perry and Keegstra, 1994;Ma et al., 1996). Therefore, one possibility to explain crosslinkingto Toc86 at each stage in import is that preproteins accumulateat the Toc86 receptor site en route to the translocation channeleven in the presence of ATP concentrations that promote import.An alternative explanation is that Toc86 serves additional functionsin import, such as participating in membrane translocation, andthat the association of preproteins with Toc86 may undergo significantchanges upon energy-dependent insertion across the outer membrane.To further investigate the differences in preprotein binding atthe two early stages of import, we mapped the sites of preproteincrosslinking to Toc86 using the outer membrane impermeable protease,thermolysin (Cline et al., 1984). Thermolysin digests the 34-kDcytoplasmic GTP-binding domain of Toc86 leaving a 52-kD membrane-protected domain (Fig. 5 B; Hirsch et al., 1994; Schnell et al.,1994). As a result, thermolysin treatment of crosslinked Toc86allowed us to determine whether crosslinking of the preproteinoccurred via the cytoplasmic domain or the membrane-protecteddomain of the protein. Crosslinking to the membrane-protecteddomain of Toc86 would be consistent with a role for this proteinin translocation.

Fig. 5. Crosslinking of pS-protA substrates to the membrane-protected domain of Toc86. Energy-depleted chloroplasts (2 mg chlorophyll)were crosslinked to pS-1 (pS-1), pS-protA (pS-protA), pS-protA-1(pS-protA-1), or pS-protA-2 (pS-protA-2) in the presence of apyrase( $-$ NTP) or 0.1 mM ATP and GTP (+NTP) for 10 min at 26°C in thedark as described in Fig. 4. After crosslinking, chloroplastswere treated in the absence ( $-$ T-lysin) or presence (+T-lysin)of 0.2 mg/ml thermolysin on ice for 30 min. The envelope membranefractions from these chloroplasts were resolved by SDS-PAGE andanalyzed by (A) fluorography or (B) immunoblotting with anti-Toc86sera. The positions of Toc75, Toc86, the 52-kD proteolytic fragmentof Toc86 (Toc86 (52 kD)), pS-protA, pS-protA-1, and pS-protA-2are indicated at the left of the figures. (C) Quantitation ofthe percent of radiolabeled crosslinker that is retained in the52-kD membrane-protected fragment of Toc86 after thermolysin digestionfrom A.
[View Larger Version of this Image (41K GIF file)]

After crosslinking reactions with pS-protA, pS-protA-1, and pS-protA-2, intact chloroplasts were treated with thermolysinunder conditions that previously have been shown to selectivelydigest cytoplasmically exposed proteins (Cline et al., 1984).The experiment was also performed with a fourth crosslinking substrate,pS-1. This derivative of pS contains a single crosslinking siteat position $-$ 1 of the transit sequence (Fig. 1) and has previouslybeen shown to crosslink to Toc86 in the absence of energy andin the presence of 0.1 mM ATP and 0.1 mM GTP (Ma et al., 1996).The pS-1 substrate allowed us to selectively investigate the environmentof the transit sequence at the two early stages of import. Interestingly,the radiolabeled crosslinker is quantitatively retained in the52-kD thermolysin fragment of Toc86 after crosslinking to pS-1in either the absence or presence of added energy (Fig. 5 A, comparelanes 1 and 2, and lanes 3 and 4, and C). These data suggest thatthe transit sequence is in the vicinity of the membrane-protecteddomain of Toc86 and may be partially inserted into the outer membraneeven in the absence of energy.

Crosslinking of pS-protA occurs to the cytoplasmic and membrane-protected domains of Toc86 in the absence of energy (Fig.5, lanes 9 and 10, and C) , consistent with the distribution ofcrosslinker in both the transit sequence and mature sequence ofthe preprotein. Crosslinking to the membrane-protected domainof Toc86 is dramatically decreased in pS-protA-1 at this stage(Fig. 5 A, lanes 17 and 18, and C), reflecting the absence ofa crosslinker within the transit sequence of this preprotein.In the presence of 0.1 mM ATP and 0.1 mM GTP, the relative amountof crosslink label retained in the 52-kD domain increases 1.5-foldfor pS-protA (Fig. 5 A, lanes 11 and 12, and C), and 2.5-foldfor pS-protA-1 (Fig. 5 A, lanes 19 and 20, and C). Very low levelsof crosslinking between pS-protA-2 and the 52-kD fragment aredetected in the absence or presence of energy (Fig. 5 A, lanes25-28, and C), indicating that the distant crosslinking site onthis preprotein has not inserted into the outer membrane at eitherstage in import. We interpret these data to indicate that thetransition from energy-independent binding to the early importintermediate results in the insertion of a significant portionof the mature sequence of the preproteins into the outer membraneand that this insertion is, at least, partially mediated by themembrane-protected domain of Toc86. On the basis of these results,we suggest that Toc86 participates both in preprotein recognitionand translocation at the outer membrane.

Association of Toc34 with Preproteins Is Regulated by GTP Binding

A direct interaction of Toc34 with preproteins has not previously been observed. The crosslinking of Toc34 to preproteinsduring energy-independent binding supports the proposal that Toc34participates with Toc86 in the initial interaction of preproteinswith the outer envelope translocon. We wished to investigate thenature of the interaction of preproteins with Toc34 to gain insightinto its roles at the outer membrane. As a first step, we investigatedthe specificity of preprotein binding to Toc34. Both Toc34 andToc86 are major proteins of the outer membrane and both possesssignificant cytoplasmic domains. Therefore, it is possible thatthe crosslinking observed with Toc34 and Toc86 in the presenceof apyrase represents a nonspecific association of the urea-denaturedpreprotein with these two components. To eliminate this possibility,we tested the ability of authentic pS or the mature small subunitof ribulose-1,5-bisphosphate carboxylase (S) to compete for thelabeling of Toc34 and Toc86 with pS-protA-1 in the crosslinkingassay. The pS-protA-1 substrate was used for these experimentsbecause it consistently gave the highest levels of Toc34 labelingin our assays and therefore provided the highest sensitivity forquantitative analysis of crosslinking. Fig. 6 A shows that authenticpS (Fig. 6 A, compare lanes 1 and 3) but not mature small subunitlacking a transit sequence (Fig. 6 A, compare lanes 1 and 2),is able to competitively inhibit the crosslinking of both Toc86and Toc34 to pS-protA-1. Crosslinking to Toc86 and Toc34 decreaseto 15% of the control levels in the presence of a 10-fold excessof authentic pS. As a second test of the selectivity of the Toc34-preproteinassociation, we tested whether the interaction was saturable.Chloroplasts were crosslinked to increasing concentrations ofpS-protA-1 in the absence of energy. Fig. 6 B shows that crosslinkingof pS-protA-1 to Toc34 is saturated at ~400 nM pS-protA-1. Crosslinkingto Toc86 was saturated at the same concentration of pS-protA-1(data not shown). Therefore, the interaction of the preproteinwith Toc34 and Toc86 in the absence of energy is dependent uponthe presence of a functional targeting sequence and representsa selective interaction with preprotein.

Fig. 6. Selectivity of pS-protA-1 crosslinking to Toc34 and Toc86. (A) Isolated chloroplasts equivalent to 2 mg of chlorophyll werecrosslinked to 50 nM pS-protA-1 in the presence of apyrase and500 nM of unlabeled pS (+pS) or mature S (+S) as described inFig. 4. Fractions corresponding to envelope membranes (50 µg protein)were analyzed by SDS/PAGE and fluorography. (B) Isolated chloroplastsequivalent to 2 mg of chlorophyll were crosslinked in the presenceof apyrase and the indicated concentrations of urea-denaturedpS-protA-1 as described in Fig. 4. The envelope membrane fractionsfrom these chloroplasts were resolved by SDS-PAGE and analyzedby fluorography. The inset shows the fluorograph of crosslinkingto Toc34. The graph shows quantitative analysis of the crosslinkingto Toc34 shown in the inset.
[View Larger Version of this Image (23K GIF file)]

We previously showed that the interaction of Toc86 with preproteins in the absence of NTPs occurred primarily in Toc complexesthat were not associated with Tic components at contact sites(Ma et al., 1996). To determine whether Toc34 crosslinking wasdependent upon the formation of contact sites, we separated envelopemembranes from crosslinking reactions into fractions enrichedin outer membrane vesicles and mixed outer-inner membrane vesiclesthat contain contact sites. Fig. 7 shows that crosslinked Toc34is enriched in outer membrane vesicles (compare lanes 1 and 2).Therefore, the interaction is not dependent on the formation ofcontact sites but can occur in "free" Toc complexes.

Fig. 7. Location of crosslinked Toc34 in outer and inner envelope membranes. Envelope membranes from chloroplasts crosslinked to pS-protA-1in the presence of apyrase were fractionated into outer membraneand inner membrane vesicles by flotation in linear sucrose gradients(see Materials and Methods). The proteins (50 µg) from outer membrane(OM) and inner membrane vesicles (IM) were resolved by SDS-PAGEand analyzed by fluorography. The molecular masses of standardproteins are indicated at the left of the figure. The positionsof pS-protA-1, Toc86, and Toc34 are shown to the right of thefigure.
[View Larger Version of this Image (44K GIF file)]

Crosslinking of Toc34 to preproteins was observed only in the absence of added ATP or GTP. This observation suggests thatthe Toc34-preprotein interaction may be regulated by the intrinsicGTP-binding activity of Toc34 or Toc86. To explore this possibility,we tested the effects of various nucleotides on the crosslinkingof pS-protA-1 to Toc34. Energy-depleted chloroplasts were crosslinkedto pS-protA-1 in the presence or absence of apyrase, 0.1 mM ATP,0.1 mM GTP, 0.1 mM GDP, or 0.1 mM GMP. Crosslinking to Toc34 wasstimulated only in samples containing apyrase (Fig. 8, lane 1).Even samples without added nucleotide exhibited little crosslinkingto Toc34 (Fig. 8, lane 2). These results suggest that sufficientNTP is present in the binding reaction to promote the disruptionof the Toc34-preprotein interaction. We attempted to reinvestigatethe energy requirements for Toc34 crosslinking by using chloroplaststhat had been pretreated with apyrase and reisolated before theaddition of nucleotide. However, the pattern of crosslinking wasnearly identical to that presented in Fig. 8 (data not shown).Apparently, the physical manipulations of chloroplast reisolationreleases sufficient nucleotide to promote dissociation of theToc34-preprotein interaction.

As an alternative, we tested whether AMPPNP, GMPPNP, GDP $beta$ S, or GMP could affect Toc34 crosslinking in the presence of apyrase.AMPPNP and GMPPNP are nonhydrolyzable analogues of ATP and GTP,respectively, that should be unaffected by apyrase. GDP $beta$ S, ananalogue of GDP, presumably can be hydrolyzed but at a very lowrate, and GMP is unaffected by apyrase. The results shown in Fig.9 demonstrate that 10 µM or greater concentrations of GMPPNP areable to disrupt the Toc34-preprotein interaction (lanes 4 and5), whereas comparable concentrations of AMPPNP (lanes 2 and 3),GDP $beta$ S (lane 7), or GMP (lane 8) did not affect crosslinking. AlthoughGTP is known to be required for protein import into chloroplasts,the specific function(s) of GTP has not been defined. The resultspresented in Fig. 9 suggest that the binding of GTP regulatesthe interaction of preproteins with the components of the Toccomplex at the early stages of preprotein recognition.

Fig. 9. Effect of nonhydrolizable GTP analogues on the crosslinking of pS-protA-1 to Toc34. Energy-depleted chloroplasts (2 mg chlorophyll)were incubated with 200 nM urea-denatured pS-protA-1 in the presenceof apyrase (+ Apyrase), and the indicated concentrations of AMPPNP(AMPPNP), GMPPNP (+GMPPNP), GDP $beta$ S (+GDP $beta$ S), or GMP (GMP) for 10min at 26°C in the dark and crosslinked by UV irradiation. Theenvelope fraction (50 µg protein) from crosslinked chloroplastswas analyzed by SDS-PAGE and fluorography. The positions of pS-protA-1,Toc86, and Toc34 are shown to the left of the figure.
[View Larger Version of this Image (85K GIF file)]

Discussion

Our results suggest a sequence of events during the import of cytoplasmic preproteins across the chloroplast envelope. Inthis model, cytoplasmic preproteins initially bind to the Toccomplex at the outer envelope membrane in a readily reversiblereaction that does not require NTP hydrolysis. We refer to thisstage as energy-independent binding. This stage in import wasnot previously recognized as a productive step because of thelow levels of preprotein binding detected in standard in vitrobinding assays with isolated chloroplasts (Cline et al., 1985;Olsen et al., 1989; Olsen et al., 1992). The binding of preproteinto Toc complexes in the absence of NTPs may be of relatively lowaffinity, and preprotein could dissociate during the reisolationof chloroplasts. However, covalent crosslinking allowed us tocapture a steady state picture of the binding reaction. Our dataindicate that the energy-independent binding requires the transitsequence of the preprotein and is saturable (Fig. 6). Both observationsare consistent with a specific binding reaction. The concentrationof pS-protA that saturates energy-independent binding (400 nM)is nearly identical to the concentrations of pS-protA that wepreviously showed are necessary to saturate the sites for bindingof the early import intermediate (Schnell and Blobel, 1993). Thissuggests that the number of energy- independent preprotein-bindingsites limit the number of preproteins that associate with theToc complex.

We previously showed that Toc86 and Toc75 are crosslinked to the transit sequence of pS during energy- independent binding(Ma et al., 1996). Based on these results we proposed that thetransit sequence receptor site may be composed of domains fromboth Toc components. In Fig. 5 we show that the transit sequencecrosslinks to the membrane-protected domains of Toc75 and Toc86,suggesting that the transit sequence may be partially insertedin the outer membrane translocon at this early recognition stepin import.

In this report, we also demonstrate that the preprotein interacts with Toc34 during energy-independent binding (Fig. 2). AlthoughToc34 forms a stable complex with Toc75 and Toc86, a role forthis component in import previously had not been observed. Wepropose that Toc 34 may regulate the transition from energy-independentbinding of the preprotein to a later stage in import through acycle of GTP binding. This hypothesis is supported by our observationthat GMPPNP binding results in the dissociation of the contactbetween Toc34 and the preprotein (Fig. 9).

There are several possibilities to explain the observed effect of GMPPNP on the Toc34-preprotein interaction. One possibilityis that GTP binding may regulate the association/dissociationof Toc34 with other Toc components. Toc34 is detected in associationwith Toc complexes in the absence of bound preprotein and at allstages in import examined (Schnell et al., 1994; Ma et al., 1996;Nielsen et al., 1997), but the dynamics of this interaction havenot been examined. An alternative explanation is that GTP bindinginduces a conformational change in the Toc complex that is necessaryfor subsequent insertion of the preprotein across the outer membranethrough the protein-conducting channel. In this scenario, GTPbinding may serve as a switch that is necessary to commit thepreprotein to translocation. Future studies should clarify whetherToc34 crosslinking represents a true binding of preprotein tothis component or is a consequence of a conformation of boundpreprotein in the Toc complex that brings the crosslinker in closevicinity to Toc34. Furthermore, reconstitution of these interactionsshould allow us to define whether the observed change in preproteinbinding is a consequence of GTP binding at Toc34, Toc86, or bothproteins.

Although we have shown GMPPNP regulates the Toc34-preprotein interaction, it is unlikely that this represents the only rolefor GTP in preprotein binding. Previous data have shown that GMPPNPor slowly hydrolyzable analogues of GTP inhibit the formationof early import intermediates (Olsen et al., 1992; Schnell 1994).Likewise, pS does not crosslink to the inner membrane import components,Tic(21) or Tic22, in the presence of GMPPNP (Fig. 9). These dataindicate that GTP hydrolysis is necessary for steps subsequentto energy-independent binding in the import reaction, such asstable insertion across the outer membrane. Therefore, the GMPPNP-drivendissociation of Toc34 and preprotein may represent only the firstin a set of GTP-dependent reactions that regulates the targetingreaction.

The second stage of import corresponds to the early import intermediate that has inserted across the outer membrane and isin contact with components of the inner membrane. This step inimport requires the hydrolysis of ATP and GTP (Cline et al., 1985;Olsen et al., 1989; Olsen et al., 1992; Schnell et al., 1994).Toc75 is the major target of crosslinking to the transit sequenceof pS at this stage in import (Ma et al., 1996). Furthermore,anti-Toc75 antibodies block protein import (Tranel et al., 1995).These observations led to the proposal that Toc75 is a componentof the protein-conducting channel in the outer membrane. Here,we show that Toc86 also is in contact with the preproteins thatare inserted across the outer membrane. The protease-sensitivitystudies in Fig. 5 indicate that this contact occurs through theregions of Toc86 that are embedded in the outer membrane or locatedwithin the intermembrane space of the envelope. The regions ofcontact between the preprotein and Toc86 are significantly differentat the energy-independent binding stage and the early import intermediate.Although Toc86 contacts the transit sequence of preproteins duringrecognition, it remains in contact with mature sequences of thepreprotein during outer membrane translocation. On the basis ofthese results, we propose that Toc86 participates in preproteintranslocation at the Toc complex in addition to its role in preproteinrecognition. It is possible that the membrane domains of Toc86and Toc75 interact to form the transport channel in the outermembrane translocon, or that the preprotein associates with adomain of Toc86 in the intermembrane space after insertion acrossthe outer membrane.

The final step of import is the insertion of the preprotein across the inner membrane. Our previous results showed that twoinner membrane associated proteins, Tic(21) and Tic22, crosslinkto a derivative of pS at an early intermediate stage in import(Ma et al., 1996). We have shown here that both proteins crosslinkto a pS-protA and pFd-protA at early and late stages in importproviding further support for these proteins as components ofthe general import machinery of the inner membrane. Site specificcross-linking suggests that Tic22 and Tic(21) interact with preproteinssequentially (Fig. 4). We propose that Tic22 may contain the bindingsite for the precursor at the inner membrane as it emerges fromthe Toc complex into the intermembrane space. Tic(21) is likelyto form part of the membrane translocation machinery. Detectablecrosslinking to an additional inner membrane import component,Tic110, is not observed with either pS-protA or pFd-protA at anystage in import although considerable evidence supports a rolefor Tic110 in the import process (Schnell et al., 1994; Wu, etal., 1994; Kessler and Blobel, 1996; Lübeck, et al., 1996). Basedon its association with the chloroplast hsp60 homolog, cpn60,Kessler and Blobel (1996) have proposed that Tic110 acts as adocking site for the molecular chaperone at the inner membrane.This function would serve to localize the chaperone at the sitesof translocation to assist in folding of newly imported preproteins.Such a function for Tic110 would not require direct contact withpreproteins.

The pS-protA and pFd-protA substrates crosslinked to two previously unidentified proteins in the envelope. One of these crosslinkedproducts is a 45 kDa polypeptide that is crosslinked to pS-protAand pFd-protA at the energy-independent binding stage of import.The second is 14-kD polypeptide that crosslinks to pS-protA andpFd-protA only at the late stages of import. These proteins representnew candidates for import components that participate in the earlyand late stages of envelope translocation, respectively.

Footnotes

Received for publication 29 August 1997 and in revised form 14 October 1997.

Address all correspondence to Danny J. Schnell, Department of Biological Sciences, Rutgers University, 101 Warren Street,Newark, NJ 07102. Tel.: (973) 353-1082. Fax: (973) 353-1007. E-mail:schnell{at}andromeda.rutgers.edu

The authors would like to thank Samuel LaSala and Yongkang Ma for their technical assistance and helpful discussions duringthe preparation of this manuscript.

This work was supported by National Science Foundation grants MCB-9404611 and MCB-9722914 to D.J. Schnell.

Abbreviations used in this paper

APDP, N-[4-(p-azidosalicylamido)butyl]-3 $'$ (2-pyridyldithio)propionamide; Tic, translocon at the inner envelope membrane of chloroplasts; Toc, translocon at the outer envelope membrane of chloroplasts.

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J. Cell Biol. © The Rockefeller University Press0021-9525/97/12/1677/09 $2.00 Volume 139, Number 7, December 29, 1997 1677-1685

Analysis of the Interactions of Preproteins with the Import Machinery over the Course of Protein Import into Chloroplasts

Abstract

Materials and Methods

Results

Discussion

Footnotes

Abbreviations used in this paper

References

Copyright © 1997 by The Rockefeller University Press.

J. Cell Biol.
© The Rockefeller University Press
0021-9525/97/12/1677/09 $2.00
Volume 139, Number 7, December 29, 1997 1677-1685