©1996 by The American Society for Biochemistry and Molecular Biology, Inc.
Ricin A Chain Fused to a Chloroplast-targeting Signal Is Unfolded on the Chloroplast Surface Prior to Import across the Envelope Membranes (*)

(Received for publication, October 23, 1995; and in revised form, November 28, 1995)

Denise Walker (§) Alison M. Chaddock (§) John A. Chaddock Lynne M. Roberts J. Michael Lord Colin Robinson (¶)

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

ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
FOOTNOTES
REFERENCES

ABSTRACT

The initial stages of chloroplast protein import involve the binding of precursor proteins to surface-bound receptors prior to translocation across the envelope membranes in a partially folded conformation. We have analyzed the unfolding process by examining the conformation of a construct, comprising the presequence of a chloroplast protein linked to ricin A chain, before and after binding to the chloroplast surface. We show that the presequence is highly susceptible to proteolysis in solution, probably reflecting a lack of tertiary structure, whereas the A chain passenger protein is resistant to extremely high concentrations of protease, unless deliberately unfolded using denaturant. The A chain moiety is furthermore active, indicating that the presence of the presequence does not prevent formation of a tightly folded, native state. In contrast, receptor-bound p33KRA (fusion protein comprising the 33-kDa presequence plus 22 residues of mature protein, linked to the A chain of ricin) is quantitatively digested by protease concentrations that have little effect on the A chain in solution. We conclude that protein unfolding can take place on the chloroplast surface in the absence of translocation and without the aid of soluble factors.


INTRODUCTION

The translocation of proteins across the chloroplast envelope is a complex process requiring the activities of a number of proteins in both the outer and inner envelope membranes (reviewed in (1) ). Imported proteins are initially synthesized with amino-terminal presequences which contain specific targeting signals that ensure recognition by receptors on the chloroplast surface and subsequent translocation into the stroma, probably at contact sites between the two membranes(2) . The molecular nature of the chloroplast-targeting signals have remained elusive, but considerable progress has been made in identifying and characterizing components of the import apparatus in the envelope membranes(3, 4, 5, 6) .

Some aspects of the overall import mechanism have been largely elucidated, for example requirements for ATP hydrolysis in both the binding and translocation processes(7, 8) , but other aspects remain unclear. Of particular interest are the conformations of proteins during the early stages of the import process. Import intermediates have been identified which span both membranes, demonstrating that precursor proteins traverse the envelope in an unfolded or partially folded conformation(2, 9) . Because chloroplast protein import can proceed entirely posttranslationally, the key question arises as to how and when this unfolding is accomplished and in particular whether it is achieved before or after the precursor interacts with the chloroplast. Perhaps surprisingly, rather few studies have examined the conformations of precursor proteins in solution, possibly because most studies have employed in vitro translation systems in which proteins are synthesized in minute quantities, precluding detailed structural studies on the precursor proteins at any stage of the import process. There is some evidence that chloroplast protein presequences are substantially, if not completely unfolded(10, 11) , but there is no evidence for the presence of a factor in cell-free translation systems which maintains chloroplast precursor proteins in an unfolded conformation. On the contrary, the precursor of 5-enolpyruvylshikimate-3-phosphate 1-carboxyvinyltransferase was found to be catalytically active, and thus presumably correctly folded, after synthesis in a reticulocyte lysate(12) , and protease sensitivity studies on the precursor of a 23-kDa thylakoid lumen protein suggested that this protein comprised an unfolded presequence together with a folded mature moiety(13) . However, the only precursor protein to be studied in detail has been that of ferredoxin(10) , and this study concluded that the entire precursor protein was relatively unfolded. This may be because folding of this particular protein requires formation of the FeS groups, but it nevertheless remains the case that the structures of chloroplast protein precursors in general are poorly understood.

The driving force for the unfolding process is equally poorly defined and only one study has addressed the conformation of a protein following binding to the chloroplast. In this study (14) it was found that a presequence-dihydrofolate reductase construct was highly sensitive to proteolysis once bound to the chloroplast, whereas proteases converted the precursor protein primarily to mature size dihydrofolate reductase in solution. The interpretation was that the protein was relatively unfolded once bound to receptors. Furthermore, additional studies suggested that the unfolding activity may be quite powerful: dihydrofolate reductase becomes even more tightly folded once a substrate analog, methotrexate, binds in the active site, to the extent that translocation of chimeras into mitochondria is blocked (15) . However, this treatment did not prevent import into chloroplasts (16) , raising the possibility that a particularly potent unfolding activity is associated with the surface-exposed import machinery. In this report we have investigated the import characteristics of a different fusion protein (p33KRA) (^1)in which the presequence of a 33-kDa thylakoid lumen protein (33K) is linked to ricin A chain. Previous work (17) has shown this protein to be efficiently imported into intact chloroplasts, and assays are available to assess whether this protein is active even as an in vitro translation product. We show that the fusion protein is highly active in solution and that the A chain is remarkably resistant to proteolysis as a result of its tightly folded native conformation. We also show that the protein becomes susceptible to digestion once bound to the chloroplast import machinery, providing evidence that the chloroplast is able to partially unfold tightly folded proteins without the assistance of soluble import factors.


EXPERIMENTAL PROCEDURES

Synthesis of p33KRA and Binding/Import Assays

p33KRA was synthesized in vitro by transcription of a cDNA construct followed by translation in a wheat germ lysate in the presence of [S]methionine as detailed in Roberts et al.(17) . ATP was then removed from the translation mixture by passage through a NAP-10 desalting column (Pharmacia Biotech Inc.) pre-equilibrated in 50 mM Hepes-KOH, pH 8.0, 330 mM sorbitol (Hepes-sorbitol). Intact pea chloroplasts were isolated as detailed (17) and preincubated for 45 min in the dark, on ice, to deplete the organelles of internal ATP. The chloroplasts were then pelleted at 4500 times g for 1 min and resuspended in the NAP-10 eluate containing p33KRA to a final concentration of 0.2 mg/ml chlorophyll. MgATP was added to a final concentration of 10 µM, and the mixture was incubated in the dark at 20 °C for 15 min to allow binding to take place. The chloroplasts were then pelleted (1 min at 4500 times g), washed in 1 ml of Hepes-sorbitol, and resuspended in Hepes-sorbitol to a concentration of 0.2 mg/ml chlorophyll. Protease sensitivity assays were conducted by incubating the organelles with the appropriate concentration of proteinase K on ice for 40 min, after which the samples were boiled in SDS-sample buffer containing 1 mM phenylmethylsulfonyl fluoride prior to electrophoresis. ``Chase'' reactions involved adding MgATP to 1 mM, together with 5 mM methionine, and incubation for 20 min at 25 °C in an illuminated water bath.

Assay for A Chain Activity

p33KRA and A chain were prepared by transcription of cDNA clones followed by translation in a nuclease-treated rabbit reticulocyte lysate as detailed in (18) . The RNA was then extracted, incubated with aniline, and the rRNA analyzed as in (18) , except that Northern blotting was used to visualize the released fragment rather than ethidium bromide staining. Northern blotting of rRNA onto Hybond-N membranes was performed essentially as detailed by Sambrook et al.(19) using a Pharmacia Vacugene apparatus. Hybridization of P-labeled oligonucleotide probes specific to the 3` end of 28 S rRNA was performed overnight in fresh 6 times standard saline citrate hybridization solution at 37 °C. Filters were washed twice for 30 min in 2 times standard saline citrate, 0.1% (w/v) sodium dodecyl sulfate prior to exposure to x-ray fim.


RESULTS AND DISCUSSION

Ricin A Chain Is Tightly Folded and Extraordinarily Resistant to Digestion by Proteinase K

Previous studies (17) have analyzed the import characteristics of a chimeric protein comprising the presequence and 22 residues of mature 33K followed by mature ricin A chain, a cytotoxic ribosome-inactivating protein. It was shown that the presequence of 33K was able to direct A chain into isolated chloroplasts with high efficiency, although mature size A chain was found in the stromal phase rather than the thylakoid lumen as expected. It was suggested in this study that this may due to the ability of A chain to interact with membranes; there are strong suggestions(20, 21) that A chain may follow a ``retrograde translocation'' pathway in animal cells which culminates in reverse translocation across the endoplasmic reticulum. Given the similarities between the endoplasmic reticulum and thylakoid membrane protein translocation mechanisms(22) , it is by no means unlikely that A chain could be initially targeted into the thylakoid lumen and subsequently ``reverse-translocated'' back to the stromal phase. However, analysis of the x-ray crystal structure reveals an alternative explanation: A chain appears to be a protein that folds extremely tightly(23) , raising the possibility that the thylakoid protein import apparatus is incapable of unfolding A chain sufficiently for translocation to proceed to completion. In general, tightly folded proteins are more resistant to proteolysis, and we therefore tested the resistance of p33KRA to increasing concentrations of proteinase K. The results (Fig. 1) show that even low concentrations (5 µg/ml) are sufficient to quantitatively convert the fusion protein to a polypeptide that comigrates precisely with mature ricin A chain. Remarkably, this polypeptide is then largely resistant to digestion by even 1 mg/ml proteinase K (a massive concentration, which in our hands has totally degraded every other protein tested, including dihydrofolate reductase complexed with methotrexate). The logical interpretation of this result is that p33KRA consists of a 33K presequence/mature section that is relatively, if not completely, unfolded, together with an A chain moiety that is extremely tightly folded. The right-hand panel in Fig. 1shows that this polypeptide is smaller than the major imported species, as noted by Roberts et al.(17) in the initial import experiments. This is because removal of the 33K presequence during import leaves 22 residues of mature 33K attached to the NH(2) terminus of A chain.


Figure 1: Proteinase K converts p33KRA predominantly to mature size A chain. Left-hand panel, p33KRA was synthesized in a wheat germ lysate and incubated with proteinase K at the concentrations indicated above the lanes for 40 min at 0 °C. After incubation, samples were analyzed by SDS-polyacrylamide gel electrophoresis followed by fluorography. RA denotes mobility of authentic mature size A chain marker. Right-hand panel, p33KRA was incubated in the absence of protease or the presence of 50 µg/ml proteinase K as indicated; the sample denoted imp represents the results of importing p33KRA into intact pea chloroplasts. 33KRA represents imported p33KRA which has been proteolytically processed in the chloroplasts to yield A chain containing 22 residues of mature 33K at the amino terminus.



Further indications of the folding characteristics of A chain are shown in Fig. 2. In this experiment we tested whether A chain becomes more susceptible to proteolysis when deliberately unfolded in urea (to exclude the unlikely possibility that the A chain sequence does not contain proteinase K cleavage sites). p33KRA was incubated with 8 M urea to induce unfolding, and the mixture was then diluted 4-fold with buffer containing proteinase K. The data show that this treatment renders the A chain far more susceptible to digestion when compared with the minus-urea control, with the majority of p33KRA now being cleaved to low molecular weight forms (defined here as polypeptides smaller than mature size A chain) by concentrations of proteinase K of 50 µg/ml or greater. Quantitation of the data (shown as part of Fig. 4) indicates that a small proportion of p33KRA continues to be converted to mature size A chain, even at very high protease concentrations; possibly, these are molecules that were able to quickly refold into their correct tertiary structures when diluted from 8 to 2 M urea, whereas the majority were too slow and were degraded. Overall, however, the data provide compelling evidence that ricin A chain is highly resistant to proteolysis as a consequence of its tightly folded three-dimensional structure.


Figure 2: 33KRA is protease-sensitive when deliberately unfolded in urea. p33KRA was synthesized as detailed in the legend to Fig. 1and then diluted 4-fold into 50 mM Hepes, pH 8.0, 330 mM sorbitol-containing proteinase K (PK) at the indicated concentrations in µg/ml (left-hand panel) or incubated with 8 M urea for 30 min on ice, then diluted 4-fold with the same buffer containing proteinase K (right-hand panel). After incubation for 40 min, samples were analyzed as in Fig. 1.




Figure 4: Receptor-bound p33KRA is protease-sensitive and hence probably unfolded. Autoradiogram (A): p33KRA was incubated with pea chloroplasts in the presence of 10 µM MgATP as detailed under ``Experimental Procedures,'' and the chloroplasts were subsequently washed to remove unbound molecules. Aliquots of the chloroplasts were then incubated with proteinase K (PK) at the indicated concentrations (in µg/ml), and one aliquot was incubated with 1 mM MgATP to chase the bound p33KRA into the organelles (lane Ch). Symbols are the same as in Fig. 1and Fig. 2. The graph (B) shows a quantitative assessment of the percentage degradation of p33KRA to low molecular mass polypeptides (defined as smaller than mature size A chain) in the experiment outlined above (=bound graph) or when soluble p33KRA is incubated with proteinase K in the absence or presence of urea as shown in Fig. 2(graphs -/+ urea).



In Vitro Synthesized p33KRA Is Active on Mammalian Ribosomes

Perhaps the best test of correct folding under these circumstances is to determine whether the protein is enzymatically active, and this has been a major limitation with most proteins synthesized in vitro, because the commonly used translation systems produce extremely low quantities of protein. In the case of ricin A chain, however, this is not a limitation because, although the protein is only weakly active on wheat germ ribosomes, A chain has such high activity toward mammalian ribosomes that translational capacity in reticulocyte lysates is rapidly destroyed even by an A chain in vitro translation product during its synthesis(18) . Fig. 3shows an assay for A chain activity in which both p33KRA and mature size A chain were synthesized in a rabbit reticulocyte lysate, and the ribosomes were subsequently examined for the diagnostic, specific depurination of an adenine in 28 S RNA. This was achieved by brief treatment of the ribosomes with aniline, which has the effect of preferentially cleaving the phosphodiester backbone at the depurination site and releasing a 390-base fragment. This fragment, diagnostic of A chain-catalyzed depurination, was detected by Northern blotting with a labeled primer as detailed under ``Experimental Procedures.'' Fig. 3shows that both authentic A chain and p33KRA depurinate the 28 S RNA to a similar degree, confirming that the presence of the presequence does not affect folding of p33KRA to the extent that activity is blocked. The remaining panels of Fig. 3are controls, which show that depurination does not occur in the absence of additions or when the transcription vector minus p33KRA insert is transcribed and translated.


Figure 3: p33KRA has ribosomal RNA N-glycosidase activity. p33KRA (incubation 1) and A chain (incubation 2) were synthesized in a reticulocyte lysate for 60 min prior to extraction of rRNA as detailed(18) . A translation reaction was also conducted following transcription of pGem4Z vector containing no insert (incubation 3). Samples of the rRNA, and of rRNA that was extracted without prior incubation with transcription mixture (incubation 4), were blotted onto nitrocellulose before(-) or after (+) incubation with aniline. Release of a 390-base fragment (390 b) was detected by Northern blotting as detailed under ``Experimental Procedures.''



Receptor-bound p33KRA Is Highly Sensitive to Proteolysis and Hence Apparently Unfolded

The data shown in Fig. 1Fig. 2Fig. 3provide convincing evidence that the A chain moiety in p33KRA is extremely tightly folded in solution and that the presence of the amino-terminal presequence has little or no effect on the folding of this particular passenger protein. Having shown previously that p33KRA can be efficiently imported into chloroplasts, we used protease sensitivity as an indicator of folding to address the question: what is the conformation of p33KRA following binding to the chloroplast? The binding of precursor proteins to the chloroplast import apparatus requires lower concentrations of ATP than does translocation into the stroma(8) , and it is possible to accumulate receptor-bound precursor by incubation with intact chloroplasts in the presence of 10 µM MgATP. Under these conditions, analysis of the chloroplasts reveals bound precursor (Fig. 4A, lane 0) but little or no imported 33KRA protein (the major imported species consisting of 22 residues of mature 33K linked to A chain). This precursor is productively bound, because increasing the ATP concentration to 1 mM leads to efficient chasing into the stromal 33KRA form (lane Ch). Significantly, incubation of the receptor-bound p33KRA with proteinase K at concentrations above 50 µg/ml results in the almost quantitative degradation of p33KRA to low molecular weight forms, and we conclude from this result that the bound precursor protein has been at least partially unfolded. Quantitation of the data by phosphorimaging together with data from Fig. 1and Fig. 2shows that p33KRA is degraded to a similar extent when bound to chloroplasts or unfolded with urea (Fig. 4B). As with the urea experiment, a small proportion remains resistant to high concentrations of proteinase K (250-1000 µM), and we speculate that these molecules may in fact be nonspecifically bound to the chloroplasts rather than bound to receptors, in which case they would probably be fully folded.

In summary, we have provided further evidence that proteins can be targeted into chloroplasts without the benefit of a cytosolic antifolding factor and that the unfolding process instead takes place once bound to the chloroplasts, but before translocation across the envelope membranes. The identity of the ``unfoldase'' remains to be established. The precursor proteins may be passed on to an unfoldase activity after interaction with the initial import receptor, or the import receptor may fulfil both roles. It is also possible that envelope lipids play a role in the unfolding process, although it seems unlikely that lipids could achieve this level of unfolding without the input of dedicated proteins. Finally, it is interesting to speculate that the ATP hydrolysis required for stable binding of precursors may well be used to drive the unfolding process, possibly by Hsp70 molecules, which are known to be present in the import complex(9) . This could be achieved either by an ``active'' unfoldase activity in which the protein involved physically unfolds the precursor protein or a ``passive'' unfolding in which the precursor protein ``breathes'' and partially folded forms are progressively stabilized by the unfoldase. Clearly, this topic merits further attention in order to unravel in detail the early events in chloroplast import and in understanding the factors responsible for the presumed unfolding of ricin A chain within the endoplasmic reticulum of mammalian cells.


FOOTNOTES

*
This work was supported by Biotechnology and Biological Sciences Research Council Grants PO1132 and 88/T02035. The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore by hereby marked ``advertisement'' in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

§
The contributions of the first and second authors are regarded as being equal.

To whom correspondence should be addressed. Tel.: 44-1203-523557; Fax: 44-1203-523701.

(^1)
The abbreviations used are: p33KRA, fusion protein comprising the 33-kDa presequence plus 22 residues of mature protein, linked to the A chain of ricin; 33K, lumenal 33-kDa protein of the photosystem II oxygen-evolving complex; 33KRA, major imported species of p33KRA in which the presqeuence has been removed.


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©1996 by The American Society for Biochemistry and Molecular Biology, Inc.