A Stromal Heat Shock Protein 70 System Functions in Protein Import into Chloroplasts in the Moss Physcomitrella patens

Heat shock protein 70s (Hsp70s) are encoded by a multigene family and are located in different cellular compartments. They have broad-ranging functions, including involvement in protein trafficking, prevention of protein aggregation, and assistance in protein folding. Hsp70s work together with their cochaperones, J domain proteins and nucleotide exchange factors (e.g., GrpEs), in a functional cycle of substrate binding and release accompanied by ATP hydrolysis. We have taken advantage of the gene targeting capability of the moss Physcomitrella patens to investigate the functions of chloroplast Hsp70s. We identified four Hsp70 genes and two GrpE cochaperone homolog genes (CGE) in moss that encode chloroplast proteins. Disruption of one of the Hsp70 genes, that for Hsp70-2, caused lethality, and protein import into heat-shocked chloroplasts isolated from temperature-sensitive hsp70-2 mutants was appreciably impaired. Whereas the double cge null mutant was not viable, we recovered a cge1 null/cge2 knock down mutant in which Hsp70-2 was upregulated. Chloroplasts isolated from this mutant demonstrated a defect in protein import. In addition, two different precursors staged as early import intermediates could be immunoprecipitated with an Hsp70-2–specific antibody. This immunoprecipitate also contained Hsp93 and Tic40, indicating that it represents a precursor still in the Toc/Tic translocon. Together, these data indicate that a stromal Hsp70 system plays a crucial role in protein import into chloroplasts.     

Molecular chaperones involved in chloroplast protein import.

Transport of cytoplasmically synthesized precursor proteins into chloroplasts, like the protein transport systems of mitochondria and the endoplasmic reticulum, appears to require the action of molecular chaperones. These molecules are likely to be the sites of the ATP hydrolysis required for precursor proteins to bind to and be translocated across the two membranes of the chloroplast envelope. Over the past decade, several different chaperones have been identified, based mainly on their association with precursor proteins and/or components of the chloroplast import complex, as putative factors mediating chloroplast protein import. These factors include cytoplasmic, chloroplast envelope-associated and stromal members of the Hsp70 family of chaperones, as well as stromal Hsp100 and Hsp60 chaperones and a cytoplasmic 14-3-3 protein. While many of the findings regarding the action of chaperones during chloroplast protein import parallel those seen for mitochondrial and endoplasmic reticulum protein transport, the chloroplast import system also has unique aspects, including its hypothesized use of an Hsp100 chaperone to drive translocation into the organelle interior. Many questions concerning the specific functions of chaperones during protein import into chloroplasts still remain that future studies, both biochemical and genetic, will need to address.     

Stromal Hsp70 Is Important for Protein Translocation into Pea and Arabidopsis Chloroplasts

Hsp70 family proteins function as motors driving protein translocation into mitochondria and the endoplasmic reticulum. Whether Hsp70 is involved in protein import into chloroplasts has not been resolved. We show here Arabidopsis thaliana knockout mutants of either of the two stromal cpHsc70s, cpHsc70-1 and cpHsc70-2, are defective in protein import into chloroplasts during early developmental stages. Protein import was found to be affected at the step of precursor translocation across the envelope membranes. From solubilized envelope membranes, stromal cpHsc70 was specifically coimmunoprecipitated with importing precursors and stoichiometric amounts of Tic110 and Hsp93. Moreover, in contrast with receptors at the outer envelope membrane, cpHsp70 is important for the import of both photosynthetic and nonphotosynthetic proteins. These data indicate that cpHsc70 is part of the chloroplast translocon for general import and is important for driving translocation into the stroma. We further analyzed the relationship of cpHsc70 with the other suggested motor system, Hsp93/Tic40. Chloroplasts from the cphsc70-1 hsp93-V double mutant had a more severe import defect than did the single mutants, suggesting that the two proteins function in parallel. The cphsc70-1 tic40 double knockout was lethal, further indicating that cpHsc70-1 and Tic40 have an overlapping essential function. In conclusion, our data indicate that chloroplasts have two chaperone systems facilitating protein translocation into the stroma: the cpHsc70 system and the Hsp93/Tic40 system.     

Chloroplast Hsp93 Directly Binds to Transit Peptides at an Early Stage of the Preprotein Import Process

Three stromal chaperone ATPases, cpHsc70, Hsp90C, and Hsp93, are present in the chloroplast translocon, but none has been shown to directly bind preproteins in vivo during import, so it remains unclear whether any function as a preprotein-translocating motor and whether they have different functions during the import process. Here, using protein crosslinking followed by ionic detergent solubilization, we show that Hsp93 directly binds to the transit peptides of various preproteins undergoing active import into chloroplasts. Hsp93 also binds to the mature region of a preprotein. A time course study of import, followed by coimmunoprecipitation experiments, confirmed that Hsp93 is present in the same complexes as preproteins at an early stage when preproteins are being processed to the mature size. In contrast, cpHsc70 is present in the same complexes as preproteins at both the early stage and a later stage after the transit peptide has been removed, suggesting that cpHsc70, but not Hsp93, is important in translocating processed mature proteins across the envelope.Most chloroplast proteins are encoded by the nuclear genome as higher M_r preproteins that are fully synthesized in the cytosol before being imported into the chloroplast. The import process is initiated by binding of the N-terminal transit peptide of the preprotein to the translocon at the outer envelope membrane of chloroplasts (TOC) complex, in which Toc159 and Toc34 function as receptors and Toc75 is the outer membrane channel. This step is followed by binding of the transit peptide to the translocon at the inner envelope membrane of chloroplasts (TIC) machinery, the central components of which include the Tic20/Tic56/Tic100/Tic214 channel complex and Tic110. Tic110 functions as the stromal receptor for transit peptides and also as a scaffold for tethering other translocon components (for reviews, see Li and Chiu, 2010; Shi and Theg, 2013; Paila et al., 2015). The actual translocation of the bound preproteins across the envelope is powered by hydrolysis of ATP in the stroma (Pain and Blobel, 1987; Theg et al., 1989), and it is therefore assumed that some stromal ATPase motor proteins bind the preproteins as they emerge from the inner membrane and use the energy of ATP hydrolysis to translocate the preproteins across the envelope into the stroma.Three stromal ATPases have been identified in the translocon complex: cpHsc70 (chloroplast heat shock cognate protein 70 kD), Hsp90C (chloroplast heat shock protein 90), and Hsp93/ClpC (93-kD heat shock protein). Hsp93, the first to be identified, belongs to the Hsp100 subfamily of AAA+ proteins (ATPases associated with various cellular activities) and was detected in coimmunoprecipitation experiments in complexes containing other translocon components and preproteins undergoing import (Akita et al., 1997; Nielsen et al., 1997; Chou et al., 2003; Rosano et al., 2011). In Arabidopsis (Arabidopsis thaliana), Hsp93 exists as two isoforms encoded by the genes HSP93III and HSP93V. Removal of the more abundant Hsp93V results in protein import defects, while double knockout of the two genes causes lethality (Constan et al., 2004; Kovacheva et al., 2007; Chu and Li, 2012; Lee et al., 2015). Purified recombinant Hsp93III can bind to the transit peptide of pea (Pisum sativum) ferredoxin-NADP+ reductase in vitro (Rosano et al., 2011). In addition, the N-terminal domain of Hsp93 is critical both for its in vivo functions and its association with chloroplast membranes and Tic110, suggesting that one of the major functions of Hsp93 requires it to be localized at the envelope with Tic110 (Chu and Li, 2012). However, because many prokaryotic Hsp100 family proteins function as the regulatory components of the Clp proteases (Kress et al., 2009; Nishimura and van Wijk, 2015), and, in Arabidopsis, some Clp proteolytic core components have also been found at the envelope fraction, it has been proposed that Hsp93 is involved in degradation of misfolded or damaged proteins at the envelope (Sjögren et al., 2014). However, whether the Clp proteolytic core can form a stable complex with Hsp93 in higher plant chloroplasts remains to be shown.In mitochondria and the endoplasmic reticulum, protein import is driven by the Hsp70 family of proteins. In chloroplasts, accumulating evidence also supports that Hsp70 is important for chloroplast protein import. Purified recombinant Hsp70 can bind in vitro to the transit peptide of the small subunit of RuBP carboxylase preprotein (prRBCS; Ivey et al., 2000). Stromal Hsp70 can be coimmunoprecipitated with preproteins undergoing import and with other translocon components, and mutations resulting in reduced or altered stromal Hsp70 activity cause protein import defects (Shi and Theg, 2010; Su and Li, 2010). Recently, it has been shown, in moss, that increasing the K_m for Hsp70 ATP hydrolysis results in an increased K_m for ATP usage in chloroplast protein import, indicating that stromal Hsp70 is indeed one of the proteins supplying ATP-derived energy to power import (Liu et al., 2014). Finally, stromal Hsp90C has been shown to be part of active translocon complexes in coimmunoprecipitation experiments (Inoue et al., 2013). As further evidence that Hsp90 is important for protein import into chloroplasts, the Hsp90 ATPase activity inhibitor radicicol reversibly inhibits the import of preproteins into chloroplasts (Inoue et al., 2013).Presence of the three ATPases in the translocon was demonstrated by coimmunoprecipitation after solubilization of chloroplast membranes under conditions that preserve the large membrane protein complexes, either by solubilization with nonionic detergents or by treating chloroplasts with crosslinkers that link all proteins in a complex together (Akita et al., 1997; Nielsen et al., 1997; Shi and Theg, 2010; Su and Li, 2010; Inoue et al., 2013). These complexes contain translocon components that directly bind to preproteins, and also other proteins that are associated with these translocon components but have no direct contacts with the preproteins. For example, Nielsen et al. (1997) demonstrated the presence of Hsp93 in the translocon by binding of prRBCS to isolated pea chloroplasts and then solubilization of chloroplast membranes with the nonionic detergent decylmaltoside. Under these conditions, an anti-Hsp93 antibody specifically immunoprecipitated Hsp93 together with Toc159, Toc75, Toc34, Tic110, and prRBCS (Nielsen et al., 1997). The result showed that Hsp93 is in the same complexes with these proteins but did not provide information whether Hsp93 directly binds to them. It is possible that Hsp93 only has direct contacts with, for example, Tic110, which then binds to prRBCS. Direct binding, in particular to the transit peptide region, would provide strong evidence that an ATPase functions as a protein translocating motor, rather than in assisting the assembly of other translocon components or in the folding or degradation of imported proteins. Furthermore, if all three ATPases were found to be involved in preprotein translocation, it would be important to understand how they work together; for example, whether they preferentially bind different preproteins, bind to different regions of a preprotein, or act at different stages of the import process.Here, we examined whether Hsp93 can directly bind to preproteins undergoing import into chloroplasts, and compared the timing of the binding of Hsp93 and cpHsc70 to the preproteins. We used isolated pea chloroplasts, rather than isolated Arabidopsis chloroplasts, because pea chloroplasts exhibit more robust import ability (Fitzpatrick and Keegstra, 2001). Various crosslinkers that react with cysteines were then used to achieve more specific crosslinkings, followed by solubilization with the ionic detergent lithium dodecyl sulfate (LDS) to thoroughly solubilize chloroplast membranes and to disrupt noncovalent protein-protein interactions. Our results show that Hsp93 directly binds to preproteins undergoing import. Import time course experiments further revealed that Hsp93 functions primarily during the early stage of import, whereas cpHsc70 associates with substrates being imported at both the early stage and a later stage after transit peptide removal.     

Pea Chloroplast DnaJ-J8 and Toc12 Are Encoded by the Same Gene and Localized in the Stroma

Toc12 is a novel J domain-containing protein identified in pea (Pisum sativum) chloroplasts. It was shown to be an integral outer membrane protein localizing in the intermembrane space of the chloroplast envelope. Furthermore, Toc12 was shown to associate with an intermembrane space Hsp70, suggesting that Toc12 is important for protein translocation across the chloroplast envelope. Toc12 shares a high degree of sequence similarity with Arabidopsis (Arabidopsis thaliana) DnaJ-J8, which has been suggested to be a soluble protein of the chloroplast stroma. Here, we isolated genes encoding DnaJ-J8 from pea and found that Toc12 is a truncated clone of one of the pea DnaJ-J8s. Protein import analyses indicate that Toc12 and DnaJ-J8s possess a cleavable transit peptide and are localized in the stroma. Arabidopsis mutants with T-DNA insertions in the DnaJ-J8 gene show no defect in chloroplast protein import. Implications of these results in the energetics and mechanisms of chloroplast protein import are discussed.Most chloroplast proteins are encoded by the nuclear genome and synthesized in the cytosol as higher molecular mass precursors with an N-terminal extension known as the transit peptide. Precursor proteins are imported into chloroplasts through a translocon complex located at the chloroplast envelope. Translocon components associated with the outer membrane are called Toc (for translocon of the outer envelope membrane of chloroplast) proteins, and those associated with the inner membrane are called Tic (for translocon of the inner envelope membrane of chloroplast) proteins. Cleavage of the transit peptide from the precursor by a specific stromal processing peptidase during translocation results in the production of the lower molecular mass mature protein. Various translocon components have been assigned functions in the basic steps of the import process (for review, see Inaba and Schnell, 2008; Jarvis, 2008; Li and Chiu, 2010). For example, Toc159 (the no. indicates the calculated molecular mass of the protein) and Toc34 are receptors for the transit peptides, and Toc75 is the protein-translocating channel across the outer membrane. Toc64, on the other hand, has a dual function: it serves as a docking site for the cytosolic Hsp90 through its cytosolic domain and as a scaffold for translocon components located in the intermembrane space through its intermembrane space domain (Qbadou et al., 2007).Protein import into chloroplasts involves at least two distinct ATP-consuming steps. The first step is called “early import intermediate” or “docking,” in which less than 100 μm ATP is required and precursors are translocated across the outer membrane and come into contact with translocon components in the inner membrane (Olsen et al., 1989; Kouranov and Schnell, 1997; Inaba et al., 2003; Inoue and Akita, 2008). It has been shown that the ATP is used in the intermembrane space (Olsen and Keegstra, 1992), most likely by a yet unidentified intermembrane space Hsp70 called imsHsp70 or Hsp70-IAP (ims for “intermembrane space” and IAP for “import intermediate-associated protein”; Marshall et al., 1990; Schnell et al., 1994; Qbadou et al., 2007). The second ATP-consuming step is the complete translocation of precursors across the two envelope membranes into the stroma. This step requires about 1 mm ATP. The ATP is most likely used by the stromal Hsp93 and chloroplast Hsc70 associated with the translocon to drive protein translocation into the stroma (Nielsen et al., 1997; Shi and Theg, 2010; Su and Li, 2010).Hsp70 family proteins are involved in many cellular processes, including protein folding, protein translocation across membranes, and regulation of protein degradation. Hsp70 proteins are often recruited to perform a certain function by specifically localized J domain-containing proteins. The J domain-containing proteins interact with Hsp70 when Hsp70 is bound to ATP and stimulate ATP hydrolysis by Hsp70. The specific J domain-containing cochaperone that recruits the stromal chloroplast Hsc70 to the inner envelope membrane to assist in protein translocation has not been identified. The specific J domain-containing cochaperone for imsHsp70 for its function in protein import into chloroplasts is proposed to be a protein named Toc12 (Becker et al., 2004).Toc12 was identified as a novel J domain-containing protein from pea (Pisum sativum) chloroplasts. It belongs to the type III J domain proteins containing only the J domain without the Gly- and Phe-rich domain (G/F domain) and the zinc-finger domain originally found in Escherichia coli DnaJ. It has been shown that the protein is synthesized at its mature size of 103 amino acids without a cleavable transit peptide. After import, the protein has been shown to anchor in the outer membrane by its N-terminal part, which has been suggested to form a β-barrel-type domain. Its C-terminal part, composed of the J domain, has been shown to localize in the intermembrane space. Toc12 has been shown to associate with imsHsp70. Toc12 and imsHsp70 interact with the intermembrane space domain of Toc64, which in turn associates with another intermembrane space translocon component, Tic22. It is proposed that the Toc12-imsHsp70-Toc64-Tic22 complex mediates protein translocation across the intermembrane space through specific precursor binding and ATP hydrolysis (Becker et al., 2004; Qbadou et al., 2007). However, the existence of imsHsp70 has only been shown on immunoblots by its reactivity to the monoclonal antibody SPA820 raised against human Hsp70. Its encoding gene has never been identified. The Arabidopsis (Arabidopsis thaliana) Hsp70 gene family has 14 members. Only two of them are localized in chloroplasts, and both have been shown to locate in the stroma (Ratnayake et al., 2008; Su and Li, 2008). A recent study has further shown that the major protein recognized by the SPA820 antibody in pea chloroplasts is located in the stroma, indicating that imsHsp70 is most likely a stromal protein (Ratnayake et al., 2008).Most translocon components were originally identified from pea chloroplasts. While all translocon components identified from pea have easily recognizable Arabidopsis homologs, Toc12 seems to be an exception. The Arabidopsis gene suggested to be the pea TOC12 homolog, At1g80920 (Inoue, 2007; Jarvis, 2008), encodes a protein that is much larger than pea Toc12 and is annotated as J8 (referred to as AtJ8 herein). The entire pea Toc12 has a high sequence similarity to the N-terminal two-thirds of AtJ8. AtJ8 contains an extra C-terminal domain of 60 amino acids that is highly conserved among J8 proteins from other higher plants. However, in contrast to pea Toc12, AtJ8 is predicted to locate in the stroma (Miernyk, 2001; www.arabidopsis.org). Indeed, a fusion protein consisting of the first 80 amino acids of AtJ8 fused at the N terminus of GFP was imported into the chloroplast stroma, and approximately 46 amino acids from the N terminus were processed after import (Lee et al., 2008), indicating that the first 46 amino acids of AtJ8 function as a cleavable stroma-targeting transit peptide. A T-DNA insertion in the AtJ8 gene that causes the truncation of the last three amino acids results in no visible phenotype. However, detailed analyses indicate that the mutant has lower CO₂ assimilation and Rubisco activity than the wild type (Chen et al., 2010).We are interested in identifying J domain-containing proteins interacting with stromal Hsp70. As part of the initial effort, we investigated the suborganellar location of J8 and examined the relationship between Toc12 and J8. We found that, in pea, there are at least two genes encoding J8, which we named PsJ8a and PsJ8b. TOC12 represents part of PsJ8b. Toc12, AtJ8, and the two PsJ8 proteins could be imported into chloroplasts and processed to stromally localized soluble mature proteins. Four alleles of AtJ8 mutants were analyzed, but none of them showed any defect in the import of various chloroplast precursor proteins.     

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.     

Alternative Processing of Arabidopsis Hsp70 Precursors during Protein Import into Chloroplasts

During protein import into chloroplasts, one of the Hsp70 proteins in pea (Hsp70-IAP), previously reported to localize in the intermembrane space of chloroplasts, was found to interact with the translocating precursor protein but the gene for Hsp70-IAP has not been identified yet. In an attempt to identify the Arabidopsis homolog of Hsp70-IAP, we employed an in vitro protein import assay to determine the localization of three Arabidopsis Hsp70 homologs (AtHsp70-6 through 8), predicted for chloroplast targeting. AtHsp70-6 and AtHsp70-7 were imported into chloroplasts and processed into similar-sized mature forms. In addition, a smaller-sized processed form of AtHsp70-6 was observed. All the processed forms of both AtHsp70 proteins were localized in the stroma. Organelle-free processing assays revealed that the larger processed forms of both AtHsp70-6 and AtHsp70-7 were cleaved by stromal processing peptidase, whereas the smaller processed form of AtHsp70-6 was produced by an unspecified peptidase.     

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.     

Interactions between ribulose-1,5-bisphosphate carboxylase and stromal metabolites. II. Corroboration of the role of this enzyme as a metabolite buffer

The capacity of ribulose-1,5-bisphosphate carboxylase to bind reversibly chloroplast metabolites which are the substrates for both thylakoid and stromal enzymes was assessed using spinach chloroplasts and chloroplast extracts and with pure wheat ribulose-1,5-bisphosphate carboxylase. Measurements of the rate of coupled electron flow to methyl viologen in ‘leaky’ chloroplasts (which retained the chloroplast envelope and stromal enzymes but which were permeable to metabolites) and also with broken chloroplasts and washed thylakoids were used to study the effects of binding ADP and inorganic phopshate to ribulose-1,5-bisphosphate carboxylase. The presence of ribulose-1,5-bisphosphate carboxylase significantly altered the values obtained for apparent K_m for inorganic phosphate and ADP of coupled electron transport. The K_m (P_i) in washed thylakoids was 60–80 μM, in ‘leaky’ chloroplasts it was increased to 180–200 μM, while in ‘leaky’ chloroplasts preincubated with KCN and ribulose 1,5-bisphosphate the value was decreased to 40–50 μM. Similarly, the K_m (ADP) of coupled electron transport in washed thylakoids was 60–70 μM, in ‘leaky’ chloroplasts it was 130–150 μM and with ‘leaky’ chloroplasts incubated in the presence of KCN and ribulose 1,5-bisphosphate a value of 45–50 μM was obtained. The ability of ribulose 1,5-bisphosphate carboxylase to reduce the levels of free glycerate 3-phosphate in the absence of ribulose 1,5-bisphosphate was examined using a chloroplast extract system by varying the concentrations of stromal protein or purified ribulose 1,5-bisphosphate carboxylase. The effect of binding glycerate 3-phosphate to ribulose-1,5-bisphosphate carboxylase on glycerate 3-phosphate reduction was to reduce both the rate an the amount of NADPH oxidation for a given amount of glycerate 3-phosphate added. The addition of ribulose 1,5-bisphosphate reinitiated NADPH oxidation but ATP or NADPH did not. Incubation of purified ribulose-1,5-bisphosphate carboxylase with carboxyarabinitolbisphosphate completely inhibited the catalytic activity of the enzyme and decreased inhibition of glycerate-3-phosphate reduction. Two binding sites with different affinities for glycerate 3-phosphate were observed with pure ribulose-1,5-bisphosphate carboxylase.     

The plastid-encoded protein Orf2971 is required for protein translocation and chloroplast quality control

Photosynthesis and the biosynthesis of many important metabolites occur in chloroplasts. In these semi-autonomous organelles, the chloroplast genome encodes approximately 100 proteins. The remaining chloroplast proteins, close to 3,000, are encoded by nuclear genes whose products are translated in the cytosol and imported into chloroplasts. However, there is still no consensus on the composition of the protein import machinery including its motor proteins and on how newly imported chloroplast proteins are refolded. In this study, we have examined the function of orf2971, the largest chloroplast gene of Chlamydomonas reinhardtii. The depletion of Orf2971 causes the accumulation of protein precursors, partial proteolysis and aggregation of proteins, increased expression of chaperones and proteases, and autophagy. Orf2971 interacts with the TIC (translocon at the inner chloroplast envelope) complex, catalyzes ATP (adenosine triphosphate) hydrolysis, and associates with chaperones and chaperonins. We propose that Orf2971 is intimately connected to the protein import machinery and plays an important role in chloroplast protein quality control.

Repression of Orf2971 induces accumulation of chloroplast precursor proteins and impaired chloroplast quality indicating that Orf2971 is required for protein import and chloroplast quality control.

IN A NUTSHELL Background: The chloroplast is an important bioreactor as well as a photosynthetic site. Approximately 3,000 plastid proteins encoded in the nucleus are translocated into the chloroplast envelope via the TOC (translocon at the outer chloroplast envelope) and TIC machineries. Most nucleus-encoded preproteins that enter the plastid are unfolded as they traverse the TOC–TIC import complexes. To prevent these unfolded or misfolded proteins from causing chloroplast damage, a quality control mechanism comprising molecular chaperones and proteases ensures that all polypeptides entering chloroplasts are either correctly folded or degraded. However, there is still no consensus on the TIC complex’s components, motor proteins, or mechanism for refolding proteins entering the chloroplast. Question: What is the precise function of each of the proteins in the TIC complex? What is the composition of the chloroplast protein import machinery motor? How are the newly imported chloroplast proteins refolded and assembled into functional complexes? Findings: We found that Orf2971, encoded by the largest gene in the Chlamydomonas reinhardtii chloroplast genome and proposed to be an ortholog of Ycf2, is directly associated with the protein import machinery and plays a crucial role in ensuring the quality of proteins targeted to the chloroplast. Orf2971 deficiency induces protein precursor accumulation, partial proteolysis and protein aggregation, increased expression of chaperones and proteases, and autophagy. We hypothesize that Orf2971 is intimately linked to the protein import machinery and plays a critical role in chloroplast protein quality control. Next steps: The next challenge is to identify the sorting components associated with this complex on the stromal side. Furthermore, additional experimental evidence is required to investigate the relationship between different import machineries, including the analysis of the accumulation of precursor proteins in the various import mutants.     

Reinvestigation of the requirement of cytosolic ATP for mitochondrial protein import

Protein import into mitochondria requires the energy of ATP hydrolysis inside and/or outside mitochondria. Although the role of ATP in the mitochondrial matrix in mitochondrial protein import has been extensively studied, the role of ATP outside mitochondria (external ATP) remains only poorly characterized. Here we developed a protocol for depletion of external ATP without significantly reducing the import competence of precursor proteins synthesized in vitro with reticulocyte lysate. We tested the effects of external ATP on the import of various precursor proteins into isolated yeast mitochondria. We found that external ATP is required for maintenance of the import competence of mitochondrial precursor proteins but that, once they bind to mitochondria, the subsequent translocation of presequence-containing proteins, but not the ADP/ATP carrier, proceeds independently of external ATP. Because depletion of cytosolic Hsp70 led to a decrease in the import competence of mitochondrial precursor proteins, external ATP is likely utilized by cytosolic Hsp70. In contrast, the ADP/ATP carrier requires external ATP for efficient import into mitochondria even after binding to mitochondria, a situation that is only partly attributed to cytosolic Hsp70.     

Alternative processing of Arabidopsis Hsp70 precursors during protein import into chloroplasts

During protein import into chloroplasts, one of the Hsp70 proteins in pea (Hsp70-IAP), previously reported to localize in the intermembrane space of chloroplasts, was found to interact with the translocating precursor protein but the gene for Hsp70-IAP has not been identified yet. In an attempt to identify the Arabidopsis homolog of Hsp70-IAP, we employed an in vitro protein import assay to determine the localization of three Arabidopsis Hsp70 homologs (AtHsp70-6 through 8), predicted for chloroplast targeting. AtHsp70-6 and AtHsp70-7 were imported into chloroplasts and processed into similar-sized mature forms. In addition, a smaller-sized processed form of AtHsp70-6 was observed. All the processed forms of both AtHsp70 proteins were localized in the stroma. Organelle-free processing assays revealed that the larger processed forms of both AtHsp70-6 and AtHsp70-7 were cleaved by stromal processing peptidase, whereas the smaller processed form of AtHsp70-6 was produced by an unspecified peptidase.     

A stromal Hsp100 protein is required for normal chloroplast development and function in Arabidopsis

Molecular chaperones are required for the translocation of many proteins across organellar membranes, presumably by providing energy in the form of ATP hydrolysis for protein movement. In the chloroplast protein import system, a heat shock protein 100 (Hsp100), known as Hsp93, is hypothesized to be the chaperone providing energy for precursor translocation, although there is little direct evidence for this hypothesis. To learn more about the possible function of Hsp93 during protein import into chloroplasts, we isolated knockout mutant lines that contain T-DNA disruptions in either atHSP93-V or atHSP93-III, which encode the two Arabidopsis (Arabidopsis thaliana) homologs of Hsp93. atHsp93-V mutant plants are much smaller and paler than wild-type plants. In addition, mutant chloroplasts contain less thylakoid membrane when compared to the wild type. Plastid protein composition, however, seems to be largely unaffected in atHsp93-V knockout plants. Chloroplasts isolated from the atHsp93-V knockout mutant line are still able to import a variety of precursor proteins, but the rate of import of some of these precursors is significantly reduced. These results indicate that atHsp93-V has an important, but not essential, role in the biogenesis of Arabidopsis chloroplasts. In contrast, knockout mutant plants for atHsp93-III, the second Arabidopsis Hsp93 homolog, had a visible phenotype identical to the wild type, suggesting that atHsp93-III may not play as important a role as atHsp93-V in chloroplast development and/or function.     

Lidocaine and ATPase inhibitor interaction with the chloroplast envelope

Photosynthetic capacity of isolated intact chloroplasts is known to be sensitive to K⁺ fluxes across the chloroplast envelope. However, little is known about the system of chloroplast envelope proteins that regulate this K⁺ movement. The research described in this report focused on characterizing some of the components of this transport system by examining inhibitor effects on chloroplast metabolism. Digitoxin, an inhibitor of membrane-bound Na⁺/K⁺ ATPases, was found to reduce stromal K⁺ at a range of external K⁺ and inhibit photosynthesis. Scatchard plot analysis revealed a specific protein receptor site with a K_m for digitoxin binding of 13 nanomolar. Studies suggested that the receptor site was on the interior of the envelope. The effect of a class of amine anesthetics that are known to be K⁺ channel blockers on chloroplast metabolism was also studied. Under conditions that facilitate low stromal pH and concomitant photosynthetic inhibition, the anesthetic, lidocaine, was found to stimulate photosynthesis. This stimulation was associated with the maintenance of higher stromal K⁺. Comparison of the effects on photosynthesis of lidocaine analogs which varied in lipophilicity suggested a lipophilic pathway for anesthetic action. The results of experiments with lidocaine and digitoxin were consistent with the hypothesis that a K⁺ channel and a K⁺-pumping envelope ATPase contribute to overall K⁺ flux across the chloroplast envelope. Under appropriate assay conditions, photosynthetic capacity of isolated chloroplasts was shown to be much affected by the activity of these putative envelope proteins.     

A mutant deficient in the plastid lipid DGD is defective in protein import into chloroplasts

Most proteins in chloroplasts are encoded by the nuclear genome and synthesized in the cytosol with N-terminal extensions called transit peptides. Transit peptides function as the import signal to chloroplasts. The import process requires several protein components in the envelope and stroma and also requires the hydrolysis of ATP. Lipids have been implicated in the import process based on theories or experiments with in vitro model systems. We show here that chloroplasts isolated from an Arabidopsis mutant deficient in the plastid lipid digalactosyl diacylglycerol (DGD) were normal in importing a chloroplast outer membrane protein, but were defective in importing precursor proteins targeted to the interior of chloroplasts. The impairment includes the binding, or docking, step of the import process that is supported by 100 μM ATP.     

In Vivo Function of Hsp90 Is Dependent on ATP Binding and ATP Hydrolysis

Heat shock protein 90 (Hsp90), an abundant molecular chaperone in the eukaryotic cytosol, is involved in the folding of a set of cell regulatory proteins and in the re-folding of stress-denatured polypeptides. The basic mechanism of action of Hsp90 is not yet understood. In particular, it has been debated whether Hsp90 function is ATP dependent. A recent crystal structure of the NH₂-terminal domain of yeast Hsp90 established the presence of a conserved nucleotide binding site that is identical with the binding site of geldanamycin, a specific inhibitor of Hsp90. The functional significance of nucleotide binding by Hsp90 has remained unclear. Here we present evidence for a slow but clearly detectable ATPase activity in purified Hsp90. Based on a new crystal structure of the NH₂-terminal domain of human Hsp90 with bound ADP-Mg and on the structural homology of this domain with the ATPase domain of Escherichia coli DNA gyrase, the residues of Hsp90 critical in ATP binding (D93) and ATP hydrolysis (E47) were identified. The corresponding mutations were made in the yeast Hsp90 homologue, Hsp82, and tested for their ability to functionally replace wild-type Hsp82. Our results show that both ATP binding and hydrolysis are required for Hsp82 function in vivo. The mutant Hsp90 proteins tested are defective in the binding and ATP hydrolysis–dependent cycling of the co-chaperone p23, which is thought to regulate the binding and release of substrate polypeptide from Hsp90. Remarkably, the complete Hsp90 protein is required for ATPase activity and for the interaction with p23, suggesting an intricate allosteric communication between the domains of the Hsp90 dimer. Our results establish Hsp90 as an ATP-dependent chaperone.     

Modulation of chloroplast phosphofructokinase by NADPH : a mechanism for linking light to the regulation of glycolysis

Phosphofructokinase has been partially purified from spinach (Spinacia oleracea) chloroplasts and studied from the standpoint of light/dark regulation. At concentrations reported to occur physiologically, NADPH effected a sharp inhibition of the enzyme by: (a) lowering its affinity (increasing the apparent K_m) for both of its substrates, ATP and fructose 6-phosphate; and (b) lowering its V_max. Inhibition by NADPH was independent of pH and was observed both at pH 7.9 (pH of chloroplast stroma in the light) and pH 7.0 (stromal pH in the dark). The results are consistent with the conclusion that NADPH provides a mechanism for linking light to the modulation of phosphofructokinase activity and thereby to the regulation of glycolysis in chloroplasts.     

Kinetics of ATP synthesis in pea cotyledon submitochondrial particles

A kinetic study of oxidative phosphorylation by pea submitochondrial particles gave two K_m values for ADP, one low, the other high. The high value probably reflected a damaged site or a population of leaky mitochondria. Only the high affinity site with a low K_m for ADP was involved in ATP synthesis. α,β-Methylene ADP was found to be a competitive inhibitor of ATP synthesis. The inorganic phosphate analog, thiophosphate, decreased the apparent K_m of ADP while the rate of the reaction remained approximately the same. Adenyl imidodiphosphate, a specific inhibitor of ATP hydrolysis activity, had little effect on oxidative phosphorylation. A slight decrease in the K_m of the high affinity binding site for ADP was noted. Aurovertin was found to be a potent inhibitor of oxidative phosphorylation in pea submitochondrial particles. The K_m of the high affinity site was increased 10-fold. Also, the inhibition normally exerted by ADP on ATPase activity was severely reduced by aurovertin. In contrast, increasing the concentration of aurovertin only slightly affected the level of inhibition caused by adenyl imidodiphosphate on ATP hydrolysis.     

Mutations in the chloroplast inner envelope protein TIC100 impair and repair chloroplast protein import and impact retrograde signaling

Chloroplast biogenesis requires synthesis of proteins in the nucleocytoplasm and the chloroplast itself. Nucleus-encoded chloroplast proteins are imported via multiprotein translocons in the organelle’s envelope membranes. Controversy exists around whether a 1-MDa complex comprising TIC20, TIC100, and other proteins constitutes the inner membrane TIC translocon. The Arabidopsis thaliana cue8 virescent mutant is broadly defective in plastid development. We identify CUE8 as TIC100. The tic100^cue8 mutant accumulates reduced levels of 1-MDa complex components and exhibits reduced import of two nucleus-encoded chloroplast proteins of different import profiles. A search for suppressors of tic100^cue8 identified a second mutation within the same gene, tic100^soh1, which rescues the visible, 1 MDa complex-subunit abundance, and chloroplast protein import phenotypes. tic100^soh1 retains but rapidly exits virescence and rescues the synthetic lethality of tic100^cue8 when retrograde signaling is impaired by a mutation in the GENOMES UNCOUPLED 1 gene. Alongside the strong virescence, changes in RNA editing and the presence of unimported precursor proteins show that a strong signaling response is triggered when TIC100 function is altered. Our results are consistent with a role for TIC100, and by extension the 1-MDa complex, in the chloroplast import of photosynthetic and nonphotosynthetic proteins, a process which initiates retrograde signaling.

Complementary mutations in TIC100 of the chloroplast inner envelope membrane cause reductions or corrective improvements in chloroplast protein import, and highlight a signaling role.

IN A NUTSHELLBackground: Plants harvest energy from the sun and CO₂ from the air and convert them into the energy-rich molecules they, and eventually us, are made of. Plants do this, photosynthesis, in bodies called chloroplasts inside their cells. Chloroplasts, made of protein and membrane material, were, before plants evolved, free-living bacteria, but the synthesis of most of their proteins occurs outside them, using information carried by the cell’s nuclear DNA, so most proteins have to be brought into developing chloroplasts, across the double membrane surrounding them, through dedicated, selective channels, formed by TOC (outer) and TIC (inner envelope) proteins. The identity of those channels matters as it helps determine versions of chloroplasts suited for particular environments. Which TIC proteins constitute the inner envelope channel has been a matter of controversy.Question: A mutant Arabidopsis plant called cue8 is slow-to-green (young leaves begin almost white) and shows delayed chloroplast and plant development. We looked for the molecular identity of the CUE8 gene. We also caused further mutations in this mutant and searched whether any corrected the defects in cue8.Findings: We found the mutated gene causing the cue8 defects is the TIC100 gene. This is one essential component of the “TIC 1-MDa complex,” one of the two versions of the TIC import complex under debate. That complex is made of several proteins, all present at reduced levels in cue8. In laboratory assays in which proteins are imported into isolated chloroplasts, cue8 performed worse than normal plants for a photosynthetic and a housekeeping chloroplast protein. A corrective, “suppressor” mutant was identified, and it carried a second mutation in TIC100, one physically complementary to the first one. Both the single and the double (suppressed) mutant still were slow-to-green, which evidences a signaling role for import defects to the nucleus, making photosynthetic genes active or not.Next steps: Surprisingly the grasses, including the cereals, have one core protein of the TIC 1 MDa complex but not the rest (including TIC100). We don’t know how their TIC channels operate. We also need to learn how the information on the defect in protein import, which occurs at the chloroplast envelope, is relayed to the cell’s nucleus (but we do have some clues).     

Chloroplast ATP synthase is reduced by both f-type and m-type thioredoxins

The activity of the molecular motor enzyme, chloroplast ATP synthase, is regulated in a redox-dependent manner. The γ subunit, CF₁-γ, is the central shaft of this enzyme complex and possesses the redox-active cysteine pair, which is reduced by thioredoxin (Trx). In light conditions, Trx transfers the reducing equivalent obtained from the photosynthetic electron transfer system to the CF₁-γ. Previous studies showed that the light-dependent reduction of CF₁-γ is more rapid than those of other Trx target proteins in the stroma. Although there are multiple Trx isoforms in chloroplasts, it is not well understood as to which chloroplast Trx isoform primarily contributes to the reduction of CF₁-γ, especially under physiological conditions. We therefore performed direct assessment of the CF₁-γ reduction capacity of each of the Trx isoforms. The kinetic analysis of the reduction process showed no significant difference in the reduction efficiency between two major chloroplast Trxs, namely Trx-f and Trx-m. Based on the thorough analyses of the CF₁-γ redox dynamics in Arabidopsis thaliana Trx mutant plants, we found that lack of Trx-f or Trx-m had no significant impact on the in vivo light-dependent reduction of CF₁-γ. The results showed that CF₁-γ can accept the reducing power from both Trx-f and Trx-m in chloroplasts.