The Thylakoid {Delta}pH/{Delta}{Psi} Are Not Required for the Initial Stages of Tat-dependent Protein Transport in Tobacco Protoplasts

doi:10.1074/jbc.M509215200

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The Thylakoid ${Delta}$ pH/ ${Delta}$ ${Psi}$ Are Not Required for the Initial Stages of Tat-dependent Protein Transport in Tobacco Protoplasts^*

Alessandra Di Cola 1, Shaun Bailey 1, and Colin Robinson2

From the Department of Biological Sciences, University of Warwick, Coventry CV4 7AL, United Kingdom

Received for publication, August 22, 2005

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES

The twin-arginine translocation (Tat) system transports foldedproteins across the chloroplast thylakoid membrane and bacterialplasma membrane. In vitro import assays have pointed to a keyrole for the thylakoid ${Delta}$ pH in the initial assembly of the fulltranslocon from two subcomplexes; more generally, the ${Delta}$ pH isbelieved to provide the overall driving force for translocation.Here, we have studied the role of the ${Delta}$ pH in vivo by analyzingthe translocation of Tat substrates in transfected tobacco protoplasts.We show that the complete maturation of the precursor of the23-kDa lumenal protein (pre-23K) and of a fusion of the 23Kpresequence linked to green fluorescent protein (pre-GFP) areunaffected by dissipation of the ${Delta}$ pH. High level expression ofTat substrates in protoplasts has recently been shown to resultin "translocation reversal" in that a large proportion of agiven substrate is partially translocated across the thylakoidmembrane, processed to the mature size, and returned to thestroma. However, the efficiency of translocation of pre-23Kis undiminished in the absence of the ${Delta}$ pH and/or ${Delta}$ ${Psi}$ , and the rateand extent of maturation of both pre-23K and pre-GFP by thelumen-facing processing peptidase is similarly unaffected. Thesedata demonstrate that the proton motive force is not requiredfor the functional assembly of the Tat translocon and the initialstages of translocation in higher plant chloroplasts in vivo.We conclude that unknown factors play an influential role inboth the mechanism and energetics of this system under in vivoconditions.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES

The twin-arginine translocation (Tat)³ system transports proteinsacross the chloroplast thylakoid membrane and the plasma membranesof a wide variety of prokaryotes (reviewed in Ref. 1). The keyrole of this system appears to lie in the transport of globularproteins in a folded state in both chloroplasts (2, 3) and bacteria(4-8). While there are some differences between the signal peptidesrecognized by plant and bacterial Tat systems, almost all Tatsignal peptides contain an essential and invariant twin-argininemotif (9, 10). These targeting signals are recognized by a membrane-boundtranslocase that is encoded by three key genes in plants andGram-negative bacteria: the tatABC genes in bacteria and thehomologous tha4, hcf106, and cptatC genes in higher plants (11-13).

The mechanism of the Tat system is poorly understood but proteinpurification and cross-linking studies have recently providedinsights into the organization and operation of the system.Two primary Tat complexes have been characterized in membranesisolated from Escherichia coli cells, namely a TatABC core complexof $~$ 370 kDa as estimated by blue native gels (14, 15) and a seriesof separate homo-oligomeric TatA complexes (15, 16) that arehighly heterogeneous when analyzed by blue native gels (15).The situation appears to be similar, though possibily not identicalin chloroplasts; a complex containing Hcf106 and cpTatC wasidentified using blue native gels of solubilized thylakoids,with all of the Tha4 present in separate complexes (17). Cross-linkingstudies have shown that substrates initially bind to a corecomplex (TatC-Hcf106 in chloroplasts or TatABC in E. coli (17,18)). The subsequent events are poorly understood, but Tha4was only found to cross-link to the core complex subunits inthe presence of the thylakoid ${Delta}$ pH and substrate (19), givingrise to a model in which the Tha4 complex (or TatA in bacteria)is recruited under these conditions to form the full translocationcomplex. A range of earlier in vitro import studies (20, 21)also showed that the full translocation of Tat substrates acrossthe thylakoid membrane is completely ${Delta}$ pH-dependent in both intactchloroplasts or isolated thylakoids.

More recently, the role of the ${Delta}$ pH has been evaluated in vivofor the first time. Pulse labeling studies in the unicellulargreen alga Chlamydomonas reinhardtii (22) showed that severalTat substrates were converted to the mature size in the completeabsence of a ${Delta}$ pH, strongly suggesting that Tat-dependent translocationis not dependent on the thylakoid proton motive force. Anotherrecent study using transfected tobacco protoplasts demonstratedanother unexpected characteristic that has not been observedusing in vitro assays; Tat substrates were found to be partiallytranslocated across the thylakoid membrane but then returnedto the stroma in a high percentage of instances (23). Giventhe emerging indications of major differences between the invivo and in vitro characteristics of the Tat system, we haveset out to study the role of the ${Delta}$ pH in the translocation ofsubstrates by the Tat pathway in tobacco protoplasts. We showthat the ${Delta}$ pH is not required for the partial translocation ofa GFP construct across the thylakoid membrane by the Tat pathwayor for the full translocation of an authentic lumenal Tat substrate.

EXPERIMENTAL PROCEDURES

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES

Constructs—A chimera comprising the presequence of thepea 23-kDa lumenal photosystem II protein (23K) linked to aversion of GFP termed sGFP (24) was expressed as described byDi Cola and Robinson (23). The structure of a non-processableform is described in the same report; in brief, the terminalAla of the signal peptide was deleted, removing the consensusAla-Xaa-Ala motif recognized by the thylakoid processing peptidase.Full-length pea pre-23K was also expressed using the same vectorsystem, but the protein was modified by the addition of twomethionines at the extreme C terminus to facilitate radiolabeling.

Transient Transformation of Leaf Protoplasts—Protoplastswere prepared from axenic leaves (4-7 cm long) of Nicotianatabacum cv. Petit Havana SR1 (24). In brief, leaves were cutand incubated overnight in the presence of an enzymatic mixcontaining 0.2% macerozyme and 0.4% cellulase prepared in K3medium (Gamborg's B5 basal medium with minimal organics (Sigma),supplemented with 750 mg/liter CaCl₂, 250 mg/liter NH₄NO₃, 136.2g/liter sucrose, 250 mg/liter xylose, 1 mg/liter 6-benzylaminopurine,and 1 mg/liter naphthaleneacetic acid, pH 5.5). Protoplastswere subjected to polyethylene glycol-mediated transfectionas described (25) and were incubated overnight at 25 °Cin the dark before pulse labeling.

In Vivo Labeling of Protoplasts, Analysis of Expressed Polypeptides,and Import Assays—Pulse-chase labeling of protoplastsusing Pro-Mix (a mixture of [³⁵S]Met and [³⁵S]Cys; AmershamBiosciences, Buckinghamshire, UK) was performed exactly as describedin Ref. 26. In some experiments (see "Results") protoplastswere treated with 2 µM nigericin (Sigma), 2 µM valinomycin,or a combination of the two at the beginning of the pulse labelingperiod. KCl was added to 10 mM in each case. At the desiredtime points, 3 volumes of W5 medium (26) were added, and protoplastswere pelleted by centrifugation at 100 x g for 5 min. Cellswere frozen in liquid nitrogen and stored at -80 °C. Homogenizationof protoplasts and incubation media was performed by addingto the frozen samples 2 volumes of ice-cold homogenization buffer(150 mM Tris-Cl, 150 mM NaCl, 1.5 mM EDTA, and 1.5% (w/v) TritonX-100, pH 7.5) supplemented with complete protease inhibitormixture (Roche Applied Science). Immunoprecipitation of expressedpolypeptides was performed as described (26), using rabbit polyclonalantisera raised against pea 23K or GFP (Molecular Probes, Eugene,OR). Immunoselected proteins were analyzed by 15% (w/v) reducingSDS-PAGE and fluorography.

Chloroplast Isolation and Fractionation—Protoplast pellets(from 3,000,000 cells) obtained at the desired time points duringpulse-chase were resuspended in 150 ml HS buffer (50 µMHepes-KOH, 330 mM sorbitol, pH 8) and homogenized by repeatedpassage through a 23-gauge syringe needle. The obtained lysatewas diluted to 4 ml with HS buffer and loaded on top of a 35%(v/v) Percoll pad in 5x HS and centrifuged at 1,400 x g for9 min at 4 °C. Pellets (chloroplasts) were washed once inHS buffer, pelleted at 3,300 x g for 2 min, and resuspendedin 120 µl of HS. An aliquot (30 µl) was saved andused for immunoprecipitation (chloroplast (C)), and the restwas incubated for 1 h on ice with thermolysin (Sigma 2 µg/µl)at the final concentration of 0.2 µg/µl. EDTA wasadded at the 10 µM final concentration to inhibit thermolysin,and 30 µl were kept for immunoprecipitation (protease-treatedchloroplast (C+)). Chloroplasts were lysed in HM buffer (10mM Hepes-KOH, pH 8.0, 5 mM MgCl) supplemented with 10 µMEDTA, for 10 min on ice, after which the lysate was centrifugedfor 10 min at 20,000 x g. Supernatants (stroma (S)) were savedand used for immunoprecipitation (S), while pellets (thylakoids)were first washed in HM buffer and then resuspended in 60 µlof HM buffer containing 3 µM CaCl₂. 30 µl were usedfor immunoprecipitation (thylakoid membrane (T)) and the restincubated for 20 min on ice with thermolysin 0.2 µg/ml.EDTA was added (10 µM), and the last aliquot (30 µl)was kept for immunoprecipitation (thermolysin-treated thylakoid(T+)).

For in vitro import assays, pre-GFP was generated by transcription-translationin the presence of [³⁵S]methionine followed by import into intactpea chloroplasts in the absence or presence of nigericin asdescribed (20).

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FIGURE 1.
Tat-dependent translocation of a pre-GFP construct is ${Delta}$ pH-dependent in isolated chloroplasts. A construct comprising the 23K presequence linked to GFP was synthesized by transcription-translation (lane Tr) and imported into intact pea chloroplasts for 40 min in the absence or presence of 2 µM nigericin as indicated. After import, chloroplasts were analyzed directly after centrifugation (lane C), after treatment with thermolysin (lane C+), or after fractionation of thermolysin-treated chloroplasts into stroma (lane S) and thylakoid (lane T) samples. T+, thermolysin-treated thylakoids. iGFP denotes the intermediate size form generated by stromal processing peptidase.

Chlorophyll Fluorescence Quenching Analysis—Chlorophylla fluorescence measurements were carried out using a HansatechFMS-2 fluorometer (Hansatech Instruments Ltd., Norfolk, UK).Tobacco protoplasts were suspended at a chlorophyll concentrationof 0.2 mg ml^-1 and maintained at 20 °C. Following dark adaptationfor several hours protoplasts were given a saturating pulseof white light (all saturating pulses at 3,000 µmol m^-2s^-1) to record the maximum fluorescence yield, F_m. An actiniclight at 400 µmol m^-2 s^-1 was then provided for a 30-minduration to induce non-photochemical quenching (NPQ) of chlorophylla fluorescence. A second saturating pulse was then applied withthe actinic light on to record F_m'. The actinic light was thenswitched off, and F_m' values were recorded with regular saturatingpulses in the dark. Dark relaxation kinetics of NPQ were thenresolved into fast relaxing (NPQf) and slowly relaxing components(NPQs) according to Walters and Horton (27), using the equationF_m/F_m'-1 as a measure of NPQ. When used nigericin was addedat a concentration of 2 µM.

RESULTS AND DISCUSSION

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES

Maturation of Pre-GFP Is ${Delta}$ pH-dependent in Chloroplast ImportAssays—One of the constructs used in this study (pre-GFP)comprises the presequence of the lumenal 23-kDa photosystemII protein (from pea) linked to green fluorescent protein. GFPconstructs have been successfully used as Tat-dependent passengerproteins in bacteria (28) and transgenic Arabidopsis thaliana(29), and we have recently shown that this construct behavesas a typical Tat substrate in standard chloroplast import assays.However, expression in transfected protoplasts gave an unexpectedresult: the protein was imported into chloroplasts, extensivelytranslocated across the thylakoid membrane by the Tat pathway,and processed to the mature size, but then the majority wasreturned to the stroma. A similar observation was made usinga natural Tat substrate (the 23-kDa protein), with about 50%of this protein also appearing as the processed, mature sizeform in the stroma (23). Interestingly, it was found that mutationof the terminal thylakoid-processing peptidase (TPP) cleavagesite caused the intermediate form to associate strongly withthe thylakoid membrane, possibly due to prolonged interactionwith the Tat translocon. This non-processable mutant, whichlacks the terminal Ala in the Tat signal peptide, is termedpre-GFP ${Delta}$ TPP in the studies described below.

The protoplast transfection system offers the opportunity tocarry out pulse-chase assays on the time scales usually usedfor in vitro translocation assays, and in this study we havetested the importance of the thylakoid ${Delta}$ pH for the targetingof pre-GFP. First, we tested whether this substrate exhibitsthe typical ${Delta}$ pH dependence observed for Tat substrates in invitro import assays, as shown in Fig. 1. The control panel showsthe import and localization of the protein using the standardpea chloroplast import protocol, and the data show that pre-GFPis imported and converted to smaller products (lane C) thatare protected from proteolysis of the organelles (lane C+).Fractionation of the chloroplasts shows the presence of maturesize GFP in the thylakoid fraction (lane T), and this is resistantto thermolysin treatment of the membranes (lane T+) confirminga lumenal location. A small amount of intermediate size protein(iGFP) is apparent in the chloroplast (lane C) and protease-treatedchloroplast (lane C+) samples, and this almost certainly correspondsto stromal intermediate en route to the thylakoids. This isnot detected in the stroma, probably because the protein hasbeen fully translocated by the time the fractions are generated.

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FIGURE 2.
Assessment of trans-thylakoid ${Delta}$ pH in tobacco protoplasts. NPQ of chlorophyll a fluoresence was resolved into rapidly reversible (NPQf) and slowly reversible (NPQs) components based on their dark relaxation kinetics. NPQf represents an indirect measurement of trans thylakoid ${Delta}$ pH. The left panel shows dark relaxation kinetics for untreated protoplasts; the right-hand panel shows dark relaxation kinetics for protoplasts treated with 2 µM nigericin. Prior to measurement protoplasts were placed in the dark for 3-5 h.

The second panel shows an import assays carried out in the presenceof 2 µM nigericin. The nigericin totally inhibits transportacross the thylakoid membrane and the stromal iGFP form accumulates,confirming that this substrate, like other Tat substrates, iscompletely dependent on the thylakoid ${Delta}$ pH for transport intothe lumen. The non-processable pre-GFP ${Delta}$ TPP form is likewise dependenton the thylakoid ${Delta}$ pH, with the intermediate accumulating in thestroma in the presence of nigericin (data not shown).

Partial Translocation and Maturation of Pre-GFP Is ${Delta}$ pH-independentin Transfected Tobacco Protoplasts—We studied the samesubstrate in vivo using transfected tobacco protoplasts underconditions that have been used previously to study the intracellulartargeting of proteins by other pathways (24-26). In this assay,leaf protoplasts are transfected with plasmid DNA encoding pre-GFP,with expression driven by the strong cauliflower mosaic virus35S promoter. After 24-h incubation, the targeting of pre-GFPwas studied by pulse-chase analysis as detailed below. Assayswere carried out in the absence or presence of 2 µM nigericin.

It is not possible to directly measure the ${Delta}$ pH in vivo but chlorophyllfluorescence can be used as a non-invasive assay to confirmthat the thylakoid ${Delta}$ pH is indeed fully dissipated under theseconditions. A strong light-dependent quenching of chlorophylla fluorescence, known as NPQ, is a feature of higher plant chloroplasts(30). NPQ can be resolved into at least two key components onthe basis of the kinetics of relaxation in the dark (27). Arapidly relaxing component, referred to here as NPQf, reflectsthe safe dissipation of excess absorbed quanta as heat. Thisprocess, which serves to regulate the efficiency of light harvesting,is dependent upon a thylakoid ${Delta}$ pH for its formation. As suchit can be eliminated in the presence of uncouplers such as nigericin.To test the efficacy of the nigericin treatment of tobacco protoplastsin this study, chlorophyll a fluorescence quenching analysiswas used as a non invasive, indirect assessment of the thylakoid ${Delta}$ pH. Fig. 2 shows dark relaxation kinetics of NPQ in the tobaccoprotoplasts used in this study. In the untreated protoplasts(Fig. 2A) NPQ can be divided by linear regression into two distinctcomponents, NPQf and NPQs. The rapidly relaxing component, NPQf,reflects the removal of the ${Delta}$ pH in the dark and is complete within5-10 min of dark treatment. In the presence of nigericin (Fig.2B), the NPQf component is absent leaving only a single slowlyrelaxing component, NPQs. Since the rapidly relaxing componentis completely dependent upon the ${Delta}$ pH for its formation, thesedata demonstrate that the nigericin treatment of tobacco protoplastsin this study was successful in eliminating the ${Delta}$ pH. This isto be expected, since this concentration of nigericin blocksthe ${Delta}$ pH-dependent targeting of Tat substrates in chloroplastimport assays, where the chlorophyll concentration is higherthan that used in protoplast assays. A related approach to dissipatethe ${Delta}$ pH was used in the study on Chlamydomonas (22).

Pulse-chase assays were used to study the requirement for the ${Delta}$ pH during the targeting of pre-GFP and pre-GFP ${Delta}$ TPP in protoplasts,and the first data are shown in Fig. 3. The upper panel showsimmunoprecipitates of labeled GFP polypeptides after a pulseof 1 h and a 3-h chase. In this experiment the protoplasts werefractionated to generate samples of intact chloroplasts (laneC), stroma (lane S), thylakoids (lane T), and thermolysin-treatedthylakoids (lane T+). The data obtained for pre-GFP show thepresence of intermediate and mature size GFP (iGFP, GFP) inthe stroma, with only a minority of protein present in the thylakoids.In this experiment the thylakoid-associated mature GFP was calculatedto be 18% of total imported protein, but it should be notedthat a lower efficiency of thylakoid targeting is often observed(data not shown). In contrast, the pre-GFP ${Delta}$ TPP is imported andconverted to the intermediate form (iGFP), most of which (70%)associates with the thylakoids. A significant proportion ofthis thylakoid-associated protein is resistant to digestionby thermolysin, implying a buried location within the membrane,while other molecules are converted to a smaller degradationproduct (DP). These data closely resemble those obtained ina recent study (23), in which a variety of controls were usedto confirm that the stromal mature size GFP arose from partialtranslocation across the thylakoid by the Tat system, maturationby TPP, and return to the stroma.

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FIGURE 3.
Maturation of pre-GFP is ${Delta}$ pH-independent in tobacco protoplasts. A, pre-GFP and a variant containing a mutated TPP cleavage site (see "Results") were transiently expressed in tobacco protoplasts for 24 h, after which the protoplasts were pulsed with [³⁵S]methionine + cysteine for 1 h and chased with cold methionine for 3 h. After the chase period, chloroplasts were purified (lane C) and fractionated into stroma (lane S), thylakoids (lane T), or thermolysin-treated thylakoids (lane T+) prior to immunoprecipitation with antibodies to GFP. Mature size and intermediate forms of GFP are indicated, together with the mobility of a 30-kDa marker protein on the left. B, protoplasts expressing pre-GFP were analyzed in the absence of nigericin or the presence of 2 or 5 µM nigericin using a pulse of 1 h and chase periods of 0, 2.5, or 5 h as indicated. Samples of isolated chloroplasts were subjected to immunoprecipitation with antibodies to GFP. C, protoplasts expressing pre-GFP as in B were pulsed with [³⁵S]methionine + cysteine for 1 h in the presence or absence of 2 µM nigericin as indicated, after which the chloroplasts were isolated and fractionated as described for A except that samples of the intact chloroplasts were also treated with protease (lane C+). GFP forms were immunoprecipitated as described for A.

Fig. 3B shows that 2 µM nigericin does not block the maturationof pre-GFP during a 2.5- or 5-h chase period. The ratio of intermediate:mature size protein is similar in each case and maturation isalso observed in the presence of 5 µM nigericin, althoughthis concentration is somewhat toxic and some smearing of theprotein bands is apparent. Fig. 3C shows that the iGFP and mostof the mature size GFP is located in the stroma in both theabsence and presence of nigericin, as expected given the stromallocation of these forms in the absence of nigericin as shownin the upper panel. These data show that the thylakoid ${Delta}$ pH isnot required for the initiation of translocation by the Tattranslocon and partial translocation across the membrane.

The ${Delta}$ pH Is Not Required for the Complete Translocation of 23Kor the Stable Insertion of Pre-GFP ${Delta}$ TPP—To further probethe importance of the ${Delta}$ pH for Tat-dependent targeting, we studiedtwo substrates that are transported either partially or entirelyacross the membrane. The first is pre-GFP ${Delta}$ TPP, which is transportedinto a thermolysin-resistant location within the thylakoid membraneas shown in Fig. 3 and other studies (23). Fig. 4A shows chloroplastfractionation tests after 1 h pulse labeling + 3-h chase inthe absence or presence of nigericin, and Fig. 4 shows thatessentially identical results are obtained in each case. Approximatelyhalf of the imported intermediate form of pre-GFP ${Delta}$ TPP is localizedin the thylakoid membrane (T) where it is largely resistantto digestion by thermolysin. Some proteolytic clipping of thestromal intermediate is observed (degradation product denotedDP). The data demonstrate that the ${Delta}$ pH is not required for thispartial translocation process.

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FIGURE 4.
Tat-dependent targeting of pre-GFP ${Delta}$ TPP and pre-23K is ${Delta}$ pH-independent in tobacco protoplasts. A, pre-GFP ${Delta}$ TPP was expressed in protoplasts in the presence of [³⁵S]methionine + cysteine and the absence or presence of 2 µM nigericin, after which samples of the chloroplasts (lanes C and C+, stroma (lane S), thylakoids (lane T), and trypsin-treated thylakoids (lane T+) were subjected to immunoprecipitation with antibodies to GFP. Mobilities of the intermediate form generated by stromal processing peptidase (iGFP ${Delta}$ TPP) are indicated. DP denotes degradation product generated by thermolysin treatment of the thylakoid fraction. B, pea pre-23K was expressed in protoplasts under identical conditions to A, after which samples of intact chloroplasts, thermolysin-treated chloroplasts, stroma, thylakoids, and protease-treated thylakoids were analyzed by immunoprecipitation using antibodies to 23K. Mobilities of the precursor, intermediate, and mature size 23K polypeptides are indicated.

A further test is shown in Fig. 4B, where we studied the authenticTat substrate pre-23K. Note that the protein was modified bythe addition of two methionine residues at the extreme C terminus;this was carried out to facilitate radiolabeling of the protein,since mature pea 23K does not contain methionine. Like pre-GFP,this protein is subject to translocation reversal under theseexpression conditions but to a much lesser extent; we usuallyfind that about 30-40% of the protein is correctly targetedinto the thylakoid lumen. Some of the thylakoid-associated,mature size 23K is protected from proteolysis, suggestive ofa lumenal location (23). Fig. 4B shows fractionation tests todetermine the locations of the imported bands after pulse-chaseassays ± nigericin, and as with the previous experiments,the data show that nigericin has no significant effect on theoverall targeting process. In both the presence and absenceof nigericin, imported pre-23K is found as both the intermediateand mature size forms in the stroma, and mature size proteinis also present in the thylakoid fraction.

In higher plant leaves, the thylakoid proton motive force isalmost entirely in the form of ${Delta}$ pH under steady state conditions;the electrical potential, ${Delta}$ ${Psi}$ is negligible due to ion movementsacross the membrane (31). However, it has been suggested thatthe ${Delta}$ ${Psi}$ may actually contribute to the proton motive force undersome circumstances (32), and this may explain, at least in part,the ability of the Tat system to function in the absence ofa ${Delta}$ pH in Chlamydomonas. To completely exclude the role of eithercomponent in Tat-dependent targeting of these substrates, wecarried out a comparative test on the effects of selectivelydissipating the ${Delta}$ pH or ${Delta}$ ${Psi}$ alone with nigericin or valinomycin,respectively, or of eliminating both components using a combinationof the two compounds. Valinomycin was used at a concentrationof 2 µM, which is a 2-fold excess compared with the concentrationsused in previous studies (20, 21) to ensure that the ${Delta}$ ${Psi}$ was fullydissipated.

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FIGURE 5.
Maturation of pre-GFP occurs in the absence of a ${Delta}$ pH or ${Delta}$ ${Psi}$ . A, protoplasts exrpessing pre-GFP were pulsed with [³⁵S]methionine + cysteine for 1 h in the absence of inhibitor (control (Con) panel) and in the presence of 2 µM nigericin (Nig), 2 µM valinomycin (Val), or a combination of the two. After this incubation, samples were analyzed by immunoprecipitation with GFP antibodies immediately (0 h) or after a 5-h chase period as indicated above the lanes. Protoplasts expressing pre-GFP ${Delta}$ TPP were analyzed in parallel to provide a marker for iGFP. B, samples from the same control (Con), nigericin (Nig), valinomycin (Val), and nigericin + valinomycin (Nig+Val) assays (5 h chase samples) were analyzed by autoradiography.

Fig. 5A shows pulse-chase assays in which protoplasts expressingpre-GFP were labeled for 1 h in the presence of nigericin, valinomycin,or both as indicated and then analyzed immediately (0 h) orafter a 5-h chase as indicated. Cells expressing pre-GFP ${Delta}$ TPPwere analyzed in parallel to provide a size marker for the iGFPpolypeptide. The data show that, as before, the pre-GFP is convertedto a mixture of iGFP and mature size GFP. The efficiency ofmaturation is very similar in the control (Con) and + valinomycinsamples, confirming that the ${Delta}$ ${Psi}$ is not required for maturation.A reduction in maturation efficiency is observed in the presenceof nigericin alone or nigericin + valinomycin, but the inhibitionis only partial, and a substantial level of maturation is observedeven at the zero time point in the chase period. This showsthat the initial translocation of this protein can occur inthe complete absence of the proton motive force.

We considered it possible that the combined presence of nigericin+ valinomycin may have toxic side effects in vivo, possiblyas a result of inhibiting ATP synthesis in the cells. To addressthis possibility we tested whether protein synthesis is affectedby analyzing the total radio-labeled protein complement fromthe same samples. The data (Fig. 5B) show that protein synthesisis indeed inhibited to some extent in the nigericin-treatedcells, since the proteins are more weakly labeled. This mayrepresent a preliminary indication that the cells may indeedsuffer side effects under these conditions.

Summary—One current model for the operation of the thylakoidTat system involves the binding of substrate to the Hcf106-cpTatCcomplex and the subsequent recruitment of the Tha4 complex toform the fully active translocon. The presence of both substrateand a ${Delta}$ pH was proposed to be essential for the coalescence ofthe two complexes, on the basis that inter-complex cross-linkswere only observed under these conditions (19). The ${Delta}$ pH has alsobeen proposed to provide the driving force for translocationand the proton: substrate translocation stoichiometry has beencalculated in thylakoid import assays (33). However, all ofthese assays have been performed using in vitro reconstitutionassays, and recent studies have strongly suggested that additionalfactors may influence the Tat system in vivo. In one study,the targeting of Tat substrates was found to be ${Delta}$ pH-independentin the unicellular alga C. reinhardtii (22). In another, werecently found that expression of Tat substrates in transfectedtobacco protoplasts resulted in "translocation reversal" withinthe Tat translocon to a remarkable extent. This may stem fromthe high level expression of substrates in this system, butthis alone does not explain why translocation is aborted sofrequently, since this phenomenon was not observed in severalprevious studies when saturation of the Tat pathway was achievedin vitro (e.g. Ref. 34). Alternatively, the stress associatedwith protoplast generation may lead to the production of factorsthat indirectly induce translocation reversal. It should, however,be emphasized that the protoplasts expressing the Tat substratesin this study are intact, the chloroplasts are equally intact,and photosynthetic efficiency is high, indicating that the cellsas a whole are highly functional. Moreover, the same experimentalsystem has been successfully used to study intracellular proteintargeting by other pathways.

In vitro assays to study Tat function have invariably used higherplant chloroplasts and in this report we have sought to usethe tobacco protoplast system to analyze the role of the ${Delta}$ pHin Tat function in a higher plant. Barley leaves were also analyzedin the Chlamydomonas study described above (22), and a radiolabeled23-kDa protein was observed in the supernatant from chaotrope-treatedthylakoids even in the presence of nigericin, suggesting thatit had been transported across the membrane in a ${Delta}$ pH-independentmanner. However, the barley 23-kDa protein was not formallyidentified as 23K, the levels of 23K in the stroma were notanalyzed, and the kinetics of maturation were not addressed.These experiments are, technically, very difficult using intactleaves. The protoplast system, on the other hand, can be usedto address these issues because radiolabeling and organelleisolation is relatively straightforward. Athough the underlyingcauses of the observed translocation reversal observed recentlyare not understood, it is clear that the partial translocationof pre-GFP and the translocation of pre-23K to a protease-protectedlocation is mediated in each case by the Tat pathway, and theirmaturation is carried out by TPP on the trans side of the thylakoidmembrane (23).

In the present study we have used sensitive assays to studythe role of the ${Delta}$ pH in this process, and the results again pointto major differences between the in vitro and in vivo assays.While the transport of pre-GFP across the thylakoid membraneis entirely ${Delta}$ pH-dependent in isolated chloroplasts, as expectedfrom numerous previous studies on Tat substrates (e.g. (20)),dissipation of the ${Delta}$ pH has no significant inhibitory effect onthe maturation of either pre-GFP or pre-23K in transfected protoplasts.The data therefore demonstrate that the ${Delta}$ pH is not required forthe initial assembly of the Tat translocon in vivo or for partialtranslocation to the point where the signal peptide cleavagepoint is exposed on the trans side of the membrane. At thispoint, the GFP would be fully contained within the confinesof the membrane bilayer, assuming that translocation occursin a folded state. The data also raise the possibility thatthe ${Delta}$ pH is not required for full translocation into the lumen;while the efficiency of pre-GFP translocation is very low becauseof the extensive translocation reversal, the pre-23K does appearto be transported into the lumen with higher efficiency, andits transport is not significantly affected by ${Delta}$ pH removal. However,we are aware that 23K is transported with relatively low efficiencyunder these conditions and we cannot rule out the possibilitythat the ${Delta}$ pH may stimulate translocation under conditions wheretranslocation reversal is less prevalent. We conclude that keyfactors play a role in the energetics of Tat-dependent proteintransport in vivo, and given the remarkable differences betweenthe in vitro and in vivo targeting characterstics, a detailedunderstanding of these unknown factors is clearly essentialfor a full understanding of this system.

FOOTNOTES

^* This work was supported by Biotechnology and Biological SciencesResearch Council Grants C15308 [GenBank] and C15310 [GenBank] (to C. R.). The costsof publication of this article were defrayed in part by thepayment of page charges. This article must therefore be herebymarked "advertisement" in accordance with 18 U.S.C. Section1734 solely to indicate this fact.

¹ These authors contributed equally to this work.

² To whom correspondence should be addressed. Tel.: 44-2476-523557; Fax: 44-2476-523568; E-mail: Crobinson{at}bio.warwick.ac.uk.

³ The abbreviations used are: Tat, twin-arginine translocase;GFP, green fluorescent protein; iGFP, intermediate size GFP;23K, lumenal 23-kDa photosystem II polypeptide; TPP, thylakoidalprocessing peptidase; NPQ, non-photochemical quenching; NPQf,fast relaxing NPQ; NPQs, slow relaxing NPQ; C, chloroplast;C+, protease-treated chloroplast; T, thylakoid membrane; T+,thermolysin-treated thylakoid.

REFERENCES

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
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