In vivo and in vitro interaction of DnaK and a chloroplast transit peptide

Chloroplast transit peptides have been proposed to function as substrates for Hsp70 molecular chaperones. Many models of chloroplast protein import depict Hsp70s as the translocation motors that drive protein import into the organelle, but to our knowledge, no direct evidence has demonstrated that transit peptides function either in vivo or in vitro as substrates for the chaperone. In this report, we demonstrate that DnaK binds SStp (the full-length transit peptide for the precursor to the small subunit of Rubisco) in vivo when fused to either glutathione-S-transferase (GST) or to an His6-S-peptide tag (His-S) via an ATP-dependent mechanism. Three independent biophysical and biochemical assays confirm the ability of DnaK and SStp to interact in vitro. The cochaperones, DnaJ and GrpE, were also associated with the DnaK/SStp complex. Therefore, both GST-SStp and His-S-SStp can be used as affinity-tagged substrates to study prokaryotic chaperone/transit peptide interactions as well as to provide a novel functional probe to study the dynamics of DnaK/DnaJ/GrpE interactions in vivo. The combination of these results provides the first experimental support for a transit peptide-dependent interaction between a chloroplast precursor and Hsp70. These results are discussed in light of a general mechanism for protein translocation into chloroplasts and mitochondria.     

Precursors with altered affinity for Hsp70 in their transit peptides are efficiently imported into chloroplasts

Protein import into chloroplasts is postulated to occur with the involvement of molecular chaperones. We have determined that the transit peptide of ferredoxin-NADP(H) reductase precursor binds preferentially to an Hsp70 from chloroplast stroma. To investigate the role of Hsp70 molecular chaperones in chloroplast protein import, we analyzed the import into pea chloroplasts of preproteins with decreased Hsp70 binding affinity in their transit peptides. Our results indicate that the precursor with the lowest affinity for Hsp70 molecular chaperones in its transit peptide was imported to chloroplasts with similar apparent Km as the wild type precursor and a 2-fold increase in Vmax. Thus, a strong interaction between chloroplast stromal Hsp70 and the transit peptide seems not to be essential for protein import. These results indicate that in chloroplasts the main unfolding force during protein import may be applied by molecular chaperones other than Hsp70s. Although stromal Hsp70s undoubtedly participate in chloroplast biogenesis, the role of these molecular chaperones in chloroplast protein translocation differs from the one proposed in the mechanisms postulated up to date.     

Interaction of the targeting sequence of chloroplast precursors with Hsp70 molecular chaperones.

We have analyzed the interaction of DnaK and plant Hsp70 proteins with the wild-type ferredoxin-NADP+ reductase precursor (preFNR) and mutants containing amino-acid replacements in the targeting sequence. Using an algorithm already developed [Rüdiger, S., Germeroth, L., Schneider-Mergener, J. & Bukau, B. (1997) EMBO J. 16, 1501-1507] we observed that 75% of the 727 plastid precursor proteins analyzed contained at least one site with high likelihood of DnaK binding in their transit peptides. Statistical analysis showed a decrease of DnaK binding site frequency within the first 15 amino-acid residues of the transit peptides. Using fusion proteins we detected the interaction of DnaK with the transit peptide of the folded preFNR but not with the mature region of the protein. Discharge of DnaK from the presequence was favored by addition of MgATP. When a putative DnaK binding site was artificially added at the N-terminus of the mature protein, we observed formation of complexes with bacterial and plant Hsp70 molecular chaperones. Reducing the likelihood of DnaK binding by directed mutagenesis of the presequence increased the release of bound DnaK. The Hsp70 proteins from plastids and plant cell cytosol also interacted with the preFNR transit peptide. Overall results are discussed in the context of the proposed models to explain the organelle protein import.     

Chloroplast Hsp70s are not involved in the import of ferredoxin-NADP+ reductase precursor

Heat-shock protein 70 (Hsp70) chaperones function as molecular motors pulling precursor proteins across membranes. Although several Hsp70s have been identified in chloroplasts, their participation in protein translocation is still uncertain. A phylogenetic analysis of the peptide-binding domain from plant Hsp70s shows that they can be classified into defined groups related to their subcellular localizations, allowing differences in substrate specificities to be inferred. Using an algorithm developed by Blond-Elguindi et al. we detected three regions in the transit peptide of the pea ferredoxin-NADP⁺ reductase precursor (preFNR) that are related to binding with immunoglobulin heavy-chain binding protein (BiP), one of the members of the Hsp70 family resident in the endoplasmic reticulum. We constructed a mutant transit peptide in which prolines 18, 20 and 28 were substituted by serines. Thus, the theoretical probability of BiP-type binding of the peptide was abolished without modifying the sites for Hsp70 with DnaK-type binding. The stromal Hsp70 homolog CSS1 displayed lower affinity for this mutant transit peptide than for the wild-type presequence. Nevertheless, preFNR containing the mutant transit peptide was imported into isolated chloroplasts from pea with initial rates similar to that observed for the wild-type precursor, and only an 18% decrease in the total number of imported molecules was observed after 20 min of reaction. Our results support an import model for the preFNR in which neither DnaK- nor BiP-like Hsp70 molecular chaperones play a central role as motor of the translocation machinery in chloroplasts.     

Interaction of plant mitochondrial and chloroplast signal peptides with the Hsp70 molecular chaperone.

Most mitochondrial and chloroplast proteins are synthesized on cytosolic polyribosomes as precursor proteins, with an N-terminal signal sequence that targets the precursor to the correct organelle. In mitochondria, the chaperone Hsp70 functions as a molecular motor, pulling the precursor across the mitochondrial membranes; 97.0% of plant mitochondrial presequences contain an Hsp70 binding site. In chloroplasts, the outer envelope, intermembrane space and a stromal Hsp70 are thought to participate in protein import; 82.5% of chloroplast transit peptides have an Hsp70 binding site. The interaction of signal peptides with Hsp70 during the import process is supported by biochemical and bioinformatic studies.     

Stimulation of transit-peptide release and ATP hydrolysis by a cochaperone during protein import into chloroplasts

Three components of the chloroplast protein translocon, Tic110, Hsp93 (ClpC), and Tic40, have been shown to be important for protein translocation across the inner envelope membrane into the stroma. We show the molecular interactions among these three components that facilitate processing and translocation of precursor proteins. Transit-peptide binding by Tic110 recruits Tic40 binding to Tic110, which in turn causes the release of transit peptides from Tic110, freeing the transit peptides for processing. The Tic40 C-terminal domain, which is homologous to the C terminus of cochaperones Sti1p/Hop and Hip but with no known function, stimulates adenosine triphosphate hydrolysis by Hsp93. Hsp93 dissociates from Tic40 in the presence of adenosine diphosphate, suggesting that Tic40 functions as an adenosine triphosphatase activation protein for Hsp93. Our data suggest that chloroplasts have evolved the Tic40 cochaperone to increase the efficiency of precursor processing and translocation.     

Sequence-dependent peptide binding orientation by the molecular chaperone DnaK

Hsp70-class molecular chaperones interact with diverse polypeptide substrates, but there is limited information on the structures of different Hsp70-peptide complexes. We have used a site-directed fluorescence labeling and quenching strategy to investigate the orientation of different peptides bound to DnaK from Escherichia coli. DnaK was selectively labeled on opposite sides of the substrate-binding domain (SBD) with the fluorescent probe bimane, and the ability of peptides containing N- or C-terminal tryptophan residues to quench bimane fluorescence was measured. Tryptophan-labeled derivatives of the model peptide NRLLLTG bound with the same forward orientation previously observed in the crystal structure of the DnaK(SBD)-NRLLLTG complex. Derivatives of this peptide containing arginine in the C-terminal rather than N-terminal region, NTLLLRG, also bound in the forward direction indicating that charged residues in the flanking regions of the peptide are not the major determinant of peptide binding orientation. We also tested peptides having proline in one (ELPLVKI) or two (ELPPVKI) central positions. Tryptophan derivatives of each of these peptides bound with a strong preference for the reverse direction relative to that observed for the NRLLLTG and NTLLLRG peptides. Computer modeling the peptides NRLLLTG and ELPPVKI in both the forward and reverse orientations into the DnaK(SBD) indicated that differential hydrogen-bonding patterns and steric constraints of the central peptide residues are likely causes for differences in their binding orientations. These findings establish that DnaK is able to bind substrates in both forward and reverse orientations and suggest that the central residues of the peptide are the major determinants of directional preference.     

Conserved,Disordered C Terminus of DnaK Enhances Cellular Survival upon Stress and DnaK in Vitro Chaperone Activity

The 70-kDa heat shock proteins (Hsp70s) function as molecular chaperones through the allosteric coupling of their nucleotide- and substrate-binding domains, the structures of which are highly conserved. In contrast, the roles of the poorly structured, variable length C-terminal regions present on Hsp70s remain unclear. In many eukaryotic Hsp70s, the extreme C-terminal EEVD tetrapeptide sequence associates with co-chaperones via binding to tetratricopeptide repeat domains. It is not known whether this is the only function for this region in eukaryotic Hsp70s and what roles this region performs in Hsp70s that do not form complexes with tetratricopeptide repeat domains. We compared C-terminal sequences of 730 Hsp70 family members and identified a novel conservation pattern in a diverse subset of 165 bacterial and organellar Hsp70s. Mutation of conserved C-terminal sequence in DnaK, the predominant Hsp70 in Escherichia coli, results in significant impairment of its protein refolding activity in vitro without affecting interdomain allostery, interaction with co-chaperones DnaJ and GrpE, or the binding of a peptide substrate, defying classical explanations for the chaperoning mechanism of Hsp70. Moreover, mutation of specific conserved sites within the DnaK C terminus reduces the capacity of the cell to withstand stresses on protein folding caused by elevated temperature or the absence of other chaperones. These features of the C-terminal region support a model in which it acts as a disordered tether linked to a conserved, weak substrate-binding motif and that this enhances chaperone function by transiently interacting with folding clients.     

Determinants for removal and degradation of transit peptides of chloroplast precursor proteins

The stromal processing peptidase (SPP) cleaves a large diversity of chloroplast precursor proteins, removing an N-terminal transit peptide. We predicted previously that this key step of the import pathway is mediated by features of the transit peptide that determine precursor binding and cleavage followed by transit peptide conversion to a degradable substrate. Here we performed competition experiments using synthesized oligopeptides of the transit peptide of ferredoxin precursor to investigate the mechanism of these processes. We found that binding and processing of ferredoxin precursor depend on specific interactions of SPP with the region consisting of the C-terminal 12 residues of the transit peptide. Analysis of four other precursors suggests that processing depends on the same region, although their transit peptides are highly divergent in primary sequence and length. Upon processing, SPP terminates its interaction with the transit peptide by a second cleavage, converting it to a subfragment form. From the competition experiments we deduce that SPP releases a subfragment consisting of the transit peptide without its original C terminus. Interestingly, examination of the ATP-dependent metallopeptidase activity responsible for degradation of transit peptide subfragments suggests that it may recognize other unrelated peptides and, hence, act separately from SPP as a novel stromal oligopeptidase.     

A truncated analog of a pre-light-harvesting chlorophyll a/b protein II transit peptide inhibits protein import into chloroplasts

It is unclear how transit peptides target nuclear-encoded precursor proteins to the chloroplast. This study establishes the feasibility of using synthetic peptides as competitive inhibitors of chloroplast protein import and as probes for the function of domains within transit peptides. We show that peptide pL(1-20), MAASTMALSSPAFAGKAVNY, an analog of the NH2 terminus of a pre-light harvesting chlorophyll a/b protein II from Arabidopsis, inhibits the import of several Arabidopsis and pea precursor proteins into pea chloroplasts. Inhibition occurs at a step between the initial binding of precursors to the chloroplast and the first proteolytic cleavage event and is not due to interference with ATP availability or chloroplast integrity. Presumably this reflects specific binding of the peptide to the import machinery in the chloroplast envelope. Our data are consistent with the suggestion (Karlin-Neumann, G. A., and Tobin, E. M. (1986) EMBO J. 5, 9-13) that two conserved blocks of amino acids near the NH2-terminus of transit peptides (spanned by peptide pL(1-20] participate in protein targeting. Computer analysis also shows peptide pL(1-20) lacks the amphiphilic properties characteristic of pre-sequences of many nuclear-encoded mitochondrial proteins. This shows a difference in the mechanisms for targeting proteins to chloroplasts and mitochondria.     

A disulfide-bonded DnaK dimer is maintained in an ATP-bound state

DnaK, a major Hsp70 molecular chaperones in Escherichia coli, is a widely used model for studying Hsp70s. We recently solved a crystal structure of DnaK in complex with ATP and showed that DnaK was packed as a dimer in the crystal structure. Our previous biochemical studies supported the formation of a specific DnaK dimer as observed in the crystal structure in solution in the presence of ATP and suggested an important role of this dimer in efficient interaction with Hsp40 co-chaperones. In this study, we dissected the biochemical properties of this DnaK dimer. To restrict DnaK in this dimer form, we mutated two residues on the dimer interface to cysteine, A303C, and H541C. Upon oxidation, this DnaK-A303C-H541C protein formed a specific dimer linked by disulfide bonds formed between A303C and H541C only in the presence of ATP, consistent with the crystal structure. Intriguingly, this disulfide-bond-linked dimer of DnaK-A303C-H541C has reduced ATPase activity and decreased affinity for peptide substrate. More interestingly, unlike wild-type DnaK, the peptide substrate-binding kinetics of this dimer is drastically accelerated even in the absence of ATP, suggesting this dimer is restricted in an ATP-bound conformation regardless of nucleotide bound, which was further supported by our analysis using tryptophan fluorescence and ATP-induced peptide release. Thus, formation of the dimer restricted DnaK in an ATP-bound state and blocked the progression through the chaperone cycle. Productive progression through the chaperone cycle requires the dissociation of this transient dimer. Surprisingly, a significantly compromised interaction with Hsp40 co-chaperone was observed for this disulfide-bond-linked dimer. Thus, dissociation of this DnaK dimer is equally crucial for efficient Hsp40 interaction. An initial interaction between Hsp70 and Hsp40 requires the formation of DnaK dimer; but a stable Hsp70-Hsp40 interaction may follow the dissociation of the dimer.     

Ligand Recognition by the TPR Domain of the Import Factor Toc64 from Arabidopsis thaliana

The specific targeting of protein to organelles is achieved by targeting signals being recognised by their cognate receptors. Cytosolic chaperones, bound to precursor proteins, are recognized by specific receptors of the import machinery enabling transport into the specific organelle. The aim of this study was to gain greater insight into the mode of recognition of the C-termini of Hsp70 and Hsp90 chaperones by the Tetratricopeptide Repeat (TPR) domain of the chloroplast import receptor Toc64 from Arabidopsis thaliana (At). The monomeric TPR domain binds with 1∶1 stoichiometry in similar micromolar affinity to both Hsp70 and Hsp90 as determined by isothermal titration calorimetry (ITC). Mutations of the terminal EEVD motif caused a profound decrease in affinity. Additionally, this study considered the contributions of residues upstream as alanine scanning experiments of these residues showed reduced binding affinity. Molecular dynamics simulations of the TPR domain helices upon peptide binding predicted that two helices within the TPR domain move backwards, exposing the cradle surface for interaction with the peptide. Our findings from ITC and molecular dynamics studies suggest that AtToc64_TPR does not discriminate between C-termini peptides of Hsp70 and Hsp90.     

Analysis of chloroplast transit peptide function using mutations in the carboxyl-terminal region

Protein import into chloroplasts requires a transit peptide, which interacts with the chloroplast transport apparatus and leads to translocation of the protein across the chloroplast envelope. While the amino acid sequences of many transit peptides are known, functional domains have been difficult to identify. Previous studies suggest that the carboxyl terminus of the transit peptide for ribulose bisphosphate carboxylase small subunit is important for both translocation across the chloroplast envelope and proper processing of the precursor protein. We dissected this region using in vitro mutagenesis, creating a set of mutants with small changes in primary structure predicted to cause alterations in secondary structure. The import behavior of the mutant proteins was assessed using isolated chloroplasts. Our results show that removal of a conserved arginine residue in this region results in impaired processing, but does not necessarily affect import rates. In contrast, substituting amino acids with low reverse turn or amphiphilic potential for other original residues affected import rate but not processing.     

The Hsp40 J-domain Stimulates Hsp70 When Tethered by the Client to the ATPase Domain

The Escherichia coli Hsp40 DnaJ uses its J-domain (Jd) to couple ATP hydrolysis and client protein capture in Hsp70 DnaK. Fusion of the Jd to peptide p5 (as in Jdp5) dramatically increases the apparent affinity of the p5 moiety for DnaK in the presence of ATP, and Jdp5 stimulates ATP hydrolysis in DnaK by several orders of magnitude. NMR experiments with [¹⁵N]Jdp5 demonstrated that the peptide tethers the Jd to the ATPase domain. Thus, ATP hydrolysis and client protein binding in DnaK are coupled principally through the association of the client with DnaJ. Overexpression of a recombinant Jd was specifically toxic to cells that simultaneously expressed DnaK. No toxicity was observed when overexpressing Jdp5 or mutant Jd or when co-overexpressing the Jd and the nucleotide exchange factor GrpE. The results suggest that the Jd shifts DnaK to a client-bound form by stimulating the DnaK ATPase but only when the Jd is brought to DnaK by a client-Hsp40 complex.     

Maturation and subcellular compartmentation of potato starch phosphorylase.

The subcellular localization and maturation of starch phosphorylase (EC 2.4.1.1) was studied in developing potato tubers. The enzyme is localized inside the stroma of amyloplasts in young tubers, whereas in mature tubers it is found within the cytoplasm in the immediate vicinity of the plastids. A phosphorylase cDNA clone was isolated and used in RNA gel blot experiments to demonstrate that phosphorylase mRNAs are of the same size and abundance in both young and mature tubers. In vitro translation of mRNAs followed by immunoprecipitation with a phosphorylase antiserum indicates that the enzyme is synthesized as a higher molecular weight precursor in both young and mature tubers. The presence of a transit peptide at the N terminus of the protein was confirmed by the sequencing of the phosphorylase cDNA clone. The transit peptide has several structural features common to transit peptides of chloroplast proteins but contains a surprisingly large number of histidine residues. The mature form of the enzyme is present in both young and mature tubers, suggesting that a similar processing of the transit peptide may take place in two different subcellular locations.     

Molecular basis for interactions of the DnaK chaperone with substrates

Hsp70 chaperones assist a large variety of protein folding processes in the cell by transient association with short peptide segments of proteins. The substrate binding and release cycle is driven by the switching between the low affinity ATP bound state and the high affinity ADP bound state of Hsp70. Considerable progress has been made recently by the identification of in vivo substrates for the Escherichia coli homolog, DnaK, and the molecular mechanisms which govern the DnaK-substrate interactions. Here we review the processes that generate DnaK substrates in vivo and the properties of these substrates, and we describe insights gained from structural and kinetic analysis of DnaK-substrate interaction.     

Primary structure of maize pyruvate, orthophosphate dikinase as deduced from cDNA sequence

We have isolated two overlapping cDNA clones that encompass the entire structural gene for pyruvate, orthophosphate dikinase from maize. The analysis of the nucleotide sequence has revealed that the cDNA clones include an insert of a total of 3,171 nucleotides without a poly(A) tail and encode a polypeptide that contains 947 amino acid residues and has a molecular weight of 102,673. Comparison of the N-terminal amino acid sequence of purified pyruvate, orthophosphate dikinase protein with that deduced from the nucleotide sequence shows that the mature form of pyruvate, orthophosphate dikinase in the maize chloroplast consists of 876 amino acid residues and has a molecular weight of 95,353. The amino acid composition of the deduced sequence of pyruvate, orthophosphate dikinase is in good agreement with that of the purified enzyme. The region that contains the active and regulatory sites of pyruvate, orthophosphate dikinase can be found in the deduced sequence of amino acids. We have predicted the secondary structure and calculated the hydropathy pattern of this region. The extra 71 residues at the N terminus of the deduced sequence of amino acid residues corresponds to the transit peptide which is indispensable for the transport of the precursor protein into chloroplasts. We have compared the primary structure of the pyruvate, orthophosphate dikinase transit peptide to those of other proteins and found sequences similar to the consensus sequences found in other transit peptides.     

Possible association of non-binding of HSP70 to HLA-DRB1 peptide sequences and protection from rheumatoid arthritis

The beta-chains of HLA-DR molecules associated with susceptibility to rheumatoid arthritis (RA) share a common amino acid sequence in their third hypervariable region at position 70-74. This shared epitope could either contribute to preferential binding of a given disease-associated peptide, be involved in disease-induction by molecular mimicry or, by binding to heat shock proteins, influence antigen presentation. It is known that the Escherichia coli M(r)70,000 heat shock protein DnaK can bind peptides from the shared epitope. Using a highly sensitive method, we show that peptides covering the third hypervariable region of associated, but also most of the non-associated HLA-DR alleles, bind to DnaK. Similar binding specificities could be found for the constitutively expressed mammalian M(r)70,000 heat shock protein Hsc73 and the inducible mammalian Hsp72. However, peptides containing the amino acid sequence DERAA, found in HLA-DR alleles and strongly associated with protection from RA, did not bind any HSP70. Thus, our results suggest a possible association of non-binding of HSP70 to HLA-DR molecules or its 70-74 fragments and protection from RA.     

Effect of evolution of the C-terminal region on chaperone activity of Hsp70

Dynamic interdomain interactions within the Hsp70 protein is the basis for the allosteric and functional properties of Hsp70s. While Hsp70s are generally conserved in terms of structure, allosteric behavior, and some overlapping functions, Hsp70s also contain variable sequence regions which are related to distinct functions. In the Hsp70 sequence, the part with the greatest sequence variation is the C-terminal α-helical lid subdomain of substrate-binding domain (SBDα) together with the intrinsically disordered region. Dynamic interactions between the SBDα and β-sandwich substrate-binding subdomain (SBDβ) contribute to the chaperone functions of Hsp70s by tuning kinetics of substrate binding. To investigate how the C-terminal region of Hsp70 has evolved from prokaryotic to eukaryotic organisms, we tested whether this region can be exchanged among different Hsp70 members to support basic chaperone functions. We found that this region from eukaryotic Hsp70 members cannot substitute for the same region in Escherichia coli DnaK to facilitate normal chaperone activity of DnaK. In contrast, this region from E. coli DnaK and Saccharomyces cerevisiae Hsp70 (Ssa1 and Ssa4) can partially support some roles of human stress inducible Hsp70 (hHsp70) and human cognate Hsp70 (hHsc70). Our results indicate that the C-terminal region from eukaryotic Hsp70 members cannot properly support SBDα–SBDβ interactions in DnaK, but this region from DnaK/Ssa1/Ssa4 can still form some SBDα–SBDβ interactions in hHsp70 or hHsc70, which suggests that the mode for SBDα–SBDβ interactions is different in prokaryotic and eukaryotic Hsp70 members. This study provides new insight in the divergency among different Hsp70 homologs and the evolution of Hsp70s.     

Interaction of mitochondrial presequences with DnaK and mitochondrial hsp70.

Mitochondrial heat shock protein 70 (mt-hsp70) functions as a molecular chaperone in mitochondrial biogenesis. The chaperone in co-operation with its co-proteins acts as a translocation motor pulling the mitochondrial precursor into the matrix. Mt-hsp70s are highly conserved when compared to the bacterial hsp70 homologue, DnaK. Here we have used DnaK as a model to study the interaction of mitochondrial presequences with mt-hsp70 applying a DnaK-binding algorithm, computer modeling and biochemical investigations. DnaK-binding motifs have been analysed on all available, statistically relevant mitochondrial presequences found in the OWL database by running the algorithm. A total of 87 % of mammalian, 97 % of plant, 71 % of yeast and 100 % of Neurospora crassa presequences had at least one DnaK binding site. Based on the prediction, five 13-mer presequence peptides have been synthesized and their inhibitory effect on the molecular chaperone (DnaK/DnaJ/GrpE) assisted refolding of luciferase has been analysed. The peptide with the highest predicted binding likelihood showed the strongest inhibitory effect, whereas the peptide with no predicted binding capacity showed no inhibitory effect. A 3D structure of the pea mt-hsp70 has been constructed using homology modeling. The binding affinities of the 13-mer presequence peptides and additional control peptides to DnaK and pea mt-hsp70 have been theoretically estimated by calculating the buried hydrophobic surface area of the peptides docked to DnaK and to the mt-hsp70 structural model. These results suggest that mitochondrial presequences interact with the mt-hsp70 during or after mitochondrial protein import.