Investigations on the in vitro import ability of mitochondrial precursor proteins synthesized in wheat germ transcription-translation extract

Mitochondrial precursor proteins synthesized in rabbit reticulocyte lysate (RRL) are readily imported into mitochondria, whereas the same precursors synthesized in wheat germ extract (WGE) fail to be imported. We have investigated factors that render import incompetence from WGE. A precursor that does not require addition of extramitochondrial ATP for import, the F(A)d ATP synthase subunit, is imported from WGE. Import of chimeric constructs between precursors of the F(A)d protein and alternative oxidase (AOX) with switched presequences revealed that the mature domain of the F(A)d precursor defines the import competence in WGE as only the construct containing the presequence of AOX and mature portion of F(A)d (pAOX-mF(A)d) could be imported. Import competence of F(A)d and pAOX-mF(A)d correlated with solubility of these precursors in WGE, however, solubilization of import-incompetent precursors with urea did not restore import competence. Addition of RRL to WGE-synthesized precursors did not stimulate import but addition of WGE to the RRL-synthesized precursors or to the over-expressed mitochondrial precursor derived from the F1beta ATP synthase precursor inhibited import into mitochondria. The dual-targeted glutathione reductase precursor synthesized in WGE was imported into chloroplasts, but not into mitochondria. Antibodies against the 14-3-3 guidance complex characterized for chloroplast targeting were able to immunoprecipitate all of the precursors tested except the F(A)d ATP synthase precursor. Our results point to the conclusion that the import incompetence of WGE-synthesized mitochondrial precursors is not presequence dependent and is a result of interaction of WGE inhibitory factors with the mature portion of precursor proteins.     

The requirement of heat shock cognate 70 protein for mitochondrial import varies among precursor proteins and depends on precursor length.

The cytosolic heat shock cognate 70-kDa protein (hsc70) is required for efficient import of ornithine transcarbamylase precursor (pOTC) into rat liver mitochondria (K. Terada, K. Ohtsuka, N. Imamoto, Y. Yoneda, and M. Mori, Mol. Cell. Biol. 15:3708-3713, 1995). The requirement of hsc70 for mitochondrial import of various precursor proteins and truncated pOTCs was studied by using an in vitro translation import system in which hsc70 was completely depleted. hsc70-dependent import of pOTC was about 60% of the total import, while import of the aspartate aminotransferase precursor, the serine:pyruvate aminotransferase precursor, and 3-oxoacyl coenzyme A thiolase was about 50, 30, and 0%, respectively. The subunit sizes of these four precursor proteins were 40 to 47 kDa. When pOTC was serially truncated from the COOH terminal, the hsc70 requirement decreased gradually and was not evident for the shortest truncated pOTCs of 90 and 72 residues. These truncated pOTCs were imported and proteolytically processed rapidly in 0.5 to 2 min at 25 degrees C, and the processed mature portions and the presequence portion were rapidly degraded. Sucrose gradient centrifugation analysis followed by import assay showed that pOTC synthesized in rabbit reticulocyte lysate forms an import-competent complex of about 11S in an hsc70-dependent manner. S values of import-competent forms of aspartate aminotransferase precursor, serine:pyruvate aminotransferase precursor, and 3-oxoacyl coenzyme A thiolase were 9S, 9S, and 4S, respectively. Thus, the S value decreased as the hsc70 dependency decreased. Precursor proteins were coimmunoprecipitated from the reticulocyte lysate containing the newly synthesized precursor proteins with an hsc70 antibody. The amount of coimmunoprecipitated proteins was much larger in the absence of ATP than in its presence. Among the four precursor proteins, the amount of coimmunoprecipitated protein decreased as the hsc70 dependency decreased.     

Presequence binding factor-dependent and -independent import of proteins into mitochondria.

A cytosolic protein factor(s) is involved in the import of precursor proteins into mitochondria. PBF (presequence binding factor) is a protein factor which binds to the precursor form (pOTC) of rat ornithine carbamoyltransferase (OTC) but not to the mature OTC, and is required for the mitochondrial import of pOTC. The precursors for aspartate aminotransferase and malate dehydrogenase as well as pOTC synthesized in a reticulocyte lysate were efficiently imported into the mitochondria. However, the precursors synthesized in the lysate depleted for PBF by treatment with pOTC-Sepharose were not imported. Readdition of the purified PBF to the depleted lysate fully restored the import. pOTC synthesized in the untreated lysate sedimented as a complex with a broad peak of around 9 S, whereas pOTC synthesized in the PBF-depleted lysate sedimented at an expected position of monomer (2.5 S). When the purified PBF was readded to the depleted lysate, pOTC sedimented as a complex of about 7 S. In contrast to most mitochondrial proteins, rat 3-oxoacyl-CoA thiolase is synthesized with no cleavable presequence and an NH2-terminal portion of the mature protein functions as a mitochondrial import signal. The thiolase synthesized in the PBF-depleted lysate could be efficiently imported into the mitochondria, and readdition of PBF had little effect on the import. The thiolase synthesized in the untreated, the PBF-depleted, or the PBF-readded lysate sedimented at an expected position of monomer (2.5 S). These observations provide support for the existence of PBF-dependent and -independent pathways of mitochondrial protein import.     

Mitochondrial precursor protein. Effects of 70-kilodalton heat shock protein on polypeptide folding, aggregation, and import competence

A hybrid precursor protein constructed by fusing the mitochondrial matrix-targeting signal of rat preornithine carbamyl transferase to murine cytosolic dihydrofolate reductase (designated pO-DHFR) was expressed in Escherichia coli. Following purification under denaturing conditions, pO-DHFR was capable of membrane translocation when diluted directly into import medium containing purified mitochondria but lacking cytosolic extracts. This import competence was lost with time, however, when the precursor was diluted and preincubated in medium lacking mitochondria, unless cytosolic proteins (provided by rabbit reticulocyte lysate) were present. Identical results were obtained for purified precursor made by in vitro translation. The ability of the cytosolic proteins to maintain the purified precursor in an import-competent state was sensitive to protease, N-ethylmaleimide (NEM), and was heat labile. Further, this activity appeared to be signal sequence dependent. ATP was not required for the maintenance of pO-DHFR competence, nor did purified 70-kDa heat shock protein (the constitutive form of Hsp70) substitute for this activity. Interestingly, however, purified Hsp70 prevented aggregation of the precursor in an ATP-dependent manner and, as well, retarded the apparent rate and extent of pO-DHFR folding. Partial purification of reticulocyte lysate proteins indicated that competence activity resides within a large mass protein fraction (200-250 kDa) that contains Hsp70. Sucrose density gradient analysis revealed that pO-DHFR reversibly interacts with components of this fraction. Pretreatment of the fraction with NEM, however, significantly stabilized the subsequent formation of a complex with the precursor. The results indicate that Hsp70 can retard precursor polypeptide folding and prevent precursor aggregation; however, by itself, Hsp70 cannot confer import competence to pO-DHFR. Maintenance of import competence correlates with interactions between the precursor and an NEM-sensitive cytosolic protein fraction. Efficient dissociation of the precursor from this complex appears to require a reactive thiol moiety on the cytosolic protein(s).     

Phosphorylation and Dephosphorylation of the Presequence of Precursor MULTIPLE ORGANELLAR RNA EDITING FACTOR3 during Import into Mitochondria from Arabidopsis

The nucleus-encoded mitochondria-targeted proteins, multiple organellar RNA editing factors (MORF3, MORF5, and MORF6), interact with Arabidopsis (Arabidopsis thaliana) PURPLE ACID PHOSPHATASE2 (AtPAP2) located on the chloroplast and mitochondrial outer membranes in a presequence-dependent manner. Phosphorylation of the presequence of the precursor MORF3 (pMORF3) by endogenous kinases in wheat germ translation lysate, leaf extracts, or STY kinases, but not in rabbit reticulocyte translation lysate, resulted in the inhibition of protein import into mitochondria. This inhibition of import could be overcome by altering threonine/serine residues to alanine on the presequence, thus preventing phosphorylation. Phosphorylated pMORF3, but not the phosphorylation-deficient pMORF3, can form a complex with 14-3-3 proteins and HEAT SHOCK PROTEIN70. The phosphorylation-deficient mutant of pMORF3 also displayed faster rates of import when translated in wheat germ lysates. Mitochondria isolated from plants with altered amounts of AtPAP2 displayed altered protein import kinetics. The import rate of pMORF3 synthesized in wheat germ translation lysate into pap2 mitochondria was slower than that into wild-type mitochondria, and this rate disparity was not seen for pMORF3 synthesized in rabbit reticulocyte translation lysate, the latter translation lysate largely deficient in kinase activity. Taken together, these results support a role for the phosphorylation and dephosphorylation of pMORF3 during the import into plant mitochondria. These results suggest that kinases, possibly STY kinases, and AtPAP2 are involved in the import of protein into both mitochondria and chloroplasts and provide a mechanism by which the import of proteins into both organelles may be coordinated.Chloroplasts and mitochondria are endosymbiotic organelles that are intimately involved in energy metabolism in plants (Araújo et al., 2014). The majority of proteins located in chloroplasts and mitochondria are encoded in the nucleus, translated in the cytosol, and imported into the organelles (Murcha et al., 2014). For both chloroplasts and mitochondria, over 1,000 different proteins are required to be specifically imported into each organelle. Furthermore, while most proteins are imported specifically into one organelle, a significant number of proteins are dually targeted to both via ambiguous targeting signals (Carrie et al., 2009a; Ye et al., 2012, 2015). The sorting of proteins to chloroplast and mitochondria is achieved through the inclusion of targeting signals in newly synthesized proteins that act in combination with receptor domains present in outer membrane multisubunit protein complexes to specifically direct proteins to their destination compartments (Jarvis, 2008; Shi and Theg, 2013; Murcha et al., 2014). Chloroplast targeting signals (transit peptides) and mitochondrial targeting signals (presequences) are recognized by receptors on the translocase of the outer chloroplast envelope (TOC) and the translocase of the outer mitochondria membrane (TOM), respectively (Ye et al., 2015). In addition to the targeting signals and protein receptors, it has been proposed that cytosolic chaperone proteins may also play a role in maintaining precursor proteins in an import-competent state and may play a role in determining targeting specificity. However, in plants, the role of cytosolic chaperones has only been characterized to some extent for protein import into chloroplasts (Jarvis, 2008; Fellerer et al., 2011; Flores-Pérez and Jarvis, 2013; Lee et al., 2013; Schweiger et al., 2013) but not into mitochondria.In addition to cytosolic chaperone factors, three STY kinases are also involved in phosphorylating the transit peptides of several chloroplast precursor proteins, such as the precursor for the small subunit of Rubisco (pSSU) and the precursor for HIGH CHLOROPHYLL FLUORESCENCE136 (pHCF136), but not the presequence of the tobacco (Nicotiana tabacum) precursor for the β-subunit of the mitochondria ATP synthase (pF1β; Martin et al., 2006; Lamberti et al., 2011a, 2011b). In addition, a pea (Pisum sativum) 14-3-3 protein has also been reported to bind to the phosphorylated Ser on the transit peptide of pSSU but not to an S→A mutant. The formation of the pSSU/14-3-3/HEAT SHOCK PROTEIN70 (HSP70) complex enhances the kinetics of the import of pSSU into chloroplasts, as free pSSU is imported relatively slowly (May and Soll, 2000). Phosphatase inhibitors, NaF and NaMoO₄, inhibit pSSU import into plastids in a reversible manner, suggesting that the dephosphorylation of the phosphorylated transit peptide of pSSU is required for import (Flügge and Hinz, 1986; Waegemann and Soll, 1996). A model for pSSU recognition and TOC translocation has been proposed in which the transit peptide of pSSU is phosphorylated at Ser-34 and the transit peptide binds to Toc33 and Toc159 to form a trimeric complex (Becker et al., 2004; Oreb et al., 2011). Hydrolysis of GTP at Toc33 dissociates it from the complex, and an as yet unknown phosphatase dephosphorylates pSer-34 on pSSU, allowing import to proceed through the combined action of Toc159 and Toc75 (Becker et al., 2004; Oreb et al., 2011). Phosphorylation seems to affect import, as phosphomimicking transit peptides of pSSU and pHCF136 reduced their import rates into chloroplasts (Lamberti et al., 2011a; Nickel et al., 2015).Unlike chloroplast import, there is no evidence that the phosphorylation and dephosphorylation of plant mitochondrial presequences are required for efficient protein import. In yeast (Saccharomyces cerevisiae), Tom22 functions as a cytosolic facing receptor and transfers precursor proteins to the Tom40 channel. It can be phosphorylated by Casein Kinase2 (CK2) and the mitochondria-bound CK1 to stimulate the activity and assembly of the TOM complex (Harbauer et al., 2014). Protein Kinase A (PKA) can phosphorylate Tom22, impairing its import rate. Thus, PKA, CK1, and CK2 act antagonistically. It has also been demonstrated that the cyclin-dependent kinase CDK1 stimulated assembly of the TOM complex by the phosphorylation of Tom6, an accessory subunit of the TOM complex, enhancing its import into mitochondria (Gerbeth et al., 2013). Thus, in yeast mitochondria, the phosphorylation of the protein import machinery itself appears to play a role in import.While the overall theme of mitochondrial protein targeting, machinery, and pathways utilized is conserved between different systems, significant variations have been observed in plants. First, the plant outer mitochondrial protein receptor Tom20 is not an ortholog to the yeast or mammalian receptors (Perry et al., 2006). Structural studies on the plant Tom20 import receptor suggest a discontinuous bidentate hydrophobic binding mechanism, somewhat different from that observed in other systems (Rimmer et al., 2011). Furthermore, plant mitochondria are required to distinguish between chloroplast and mitochondrial proteins. Transit peptides and presequences display some similarities in that both are enriched in positively charged residues. However, while mitochondrial presequences are proposed to form α-amphiphilic structures, chloroplast transit peptides do not and, instead, are predicted to form β-sheet secondary structures (Zhang and Glaser, 2002). The identification of a plant-specific outer membrane receptor, Toc64, involved in the import of specific precursor proteins (Chew et al., 2004) highlights the possibility of additional and varied mechanisms between plant mitochondrial protein targeting and other systems.Previously, we identified an outer mitochondrial membrane protein, called PURPLE ACID PHOSPHATASE2 (AtPAP2), that is also dually targeted to the outer envelope in chloroplasts (Sun et al., 2012a, 2012b). Similar to Toc33/34 and Tom20, AtPAP2 is anchored on the outer membranes by a C-terminal transmembrane motif. Overexpression of AtPAP2 resulted in an altered growth phenotype with elevated ATP levels (Sun et al., 2012b); thus, the function of this protein was investigated. Here, we show that the phosphorylation and dephosphorylation of the presequence of the precursor MULTIPLE ORGANELLAR RNA EDITING FACTOR3 (pMORF3) alter the kinetics of its import in Arabidopsis (Arabidopsis thaliana). Furthermore, it was shown that the phosphorylation of pMORF3, when translated in wheat germ lysate (WGL), resulted in relatively slow import kinetics, and the inhibition of phosphorylation by site-directed mutagenesis resulted in faster import kinetics. Together, these results show that the phosphorylation and dephosphorylation of a mitochondrial precursor protein play a role in its rate of import. The roles of the outer membrane AtPAP2 protein and STY kinases were also investigated, supporting a role for phosphorylation and dephosphorylation in the import of some precursor proteins into plant mitochondria.     

The cytosolic factor required for import of precursors of mitochondrial proteins into mitochondria

The mechanism of import of proteins into mitochondria was studied by using the peptide of the presequence of ornithine aminotransferase (the extrapeptide), which was chemically synthesized and is composed of 34 amino acids. When the extrapeptide was incubated with isolated mitochondria in the presence of a rabbit reticulocyte lysate at 25 degrees C, it was imported into the mitochondrial matrix, and the import depended on the inner membrane potential, but not added ATP. The import of several precursors of mitochondrial proteins was competitively inhibited by the presence of excess extrapeptide in the reaction system, indicating that the extrapeptide and mitochondrial proteins were imported by the same machinery. Import of the extrapeptide was significantly stimulated by addition of a rabbit reticulocyte lysate, and a component of the lysate (the cytosolic factor) stimulating import of the extrapeptide was purified about 20,000 times by successive column chromatography on DEAE-cellulose and aminopentyl-Sepharose 4B. The binding of the extrapeptide to liposomes composed of egg lecithin and partially purified receptor of the precursor of mitochondrial protein (Ono, H., and Tuboi, S., (1985) Biochem. Int. 10, 351-357) required the cytosolic factor when the concentration of the peptide was less than 1.5 X 10(-8) M, suggesting that the physiological binding of the precursors of mitochondrial proteins to the receptor is dependent on the cytosolic factor. The extrapeptide and the cytosolic factor were shown to form a complex. From these results, the mechanism of binding of the extrapeptide to the receptor of the mitochondrial outer membrane is suggested to be as follows: the peptide (the precursor of mitochondrial protein) and the cytosolic factor form a complex, and then the complex is recognized by and bound to the receptor.     

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.     

14-3-3蛋白家族的调控机制和生物学功能

14-3-3蛋白家族在真核细胞中广泛表达并高度保守,它们主要以同源／异源二聚体形式存在,可以同时与两个靶蛋白或一个靶蛋白的两个结构域相互作用。14-3-3蛋白通过磷酸化丝氨酸／苏氨酸介导和靶蛋白结合,从而发挥其调控功能。现对14-3-3蛋白的识别序列、与配体相互作用的特点,及其在细胞周期、凋亡、信号转导、线粒体／叶绿体前体蛋白跨膜转运中的调控机制和发挥的生物学功能进行综述。     

Different transport pathways of individual precursor proteins in mitochondria

Transport of mitochondrial precursor proteins into mitochondria of Neurospora crassa was studied in a cell-free reconstituted system. Precursors were synthesized in a reticulocyte lysate programmed with Neurospora mRNA and transported into isolated mitochondria in the absence of protein synthesis. Uptake of the following precursors was investigated: apocytochrome c, ADP/ATP carrier and subunit 9 of the oligomycin-sensitive ATPase. Addition of high concentrations of unlabelled chemically prepared apocytochrome c (1-10 microM) inhibited the appearance in the mitochondrial of labelled cytochrome c synthesized in vitro because the unlabelled protein dilutes the labelled one and because the translocation system has a limited capacity [apparent V is 1-3 pmol X min-1 X (mg mitochondrial protein)-1]. Concentrations of added apocytochrome c exceeding the concentrations of precursor proteins synthesized in vitro by a factor of about 10(4) did not inhibit the transfer of ADP/ATP carrier or ATPase subunit 9 into mitochondria. Carbonylcyanide m-chlorophenylhydrazone, an uncoupler of oxidate phosphorylation, inhibited transfer in vitro of ADP/ATP carrier and of ATPase subunit 9, but not of cytochrome c. These findings suggest that cytochrome c and the other two proteins have different import pathways into mitochondria. It can be inferred from the data presented that different 'receptors' on the mitochondria. It can be inferred from the data presented that different 'receptors' on the mitochondrial surface mediate the specific recognition of precursor proteins by mitochondria by mitochondria as a first step in the transport process.     

Cytosolic and mitochondrial surface factor-independent import of a synthetic peptide into mitochondria.

We chemically synthesized a peptide, 11 beta-45, which was composed of 45 amino acid residues including the whole extension peptide and some of the mature portion of bovine cytochrome P-450(11 beta) precursor. 11 beta-45 was imported into mitochondria in vitro depending on the mitochondrial membrane potential, but its import did not require extramitochondrial ATP. Although cytosolic protein factors in the high speed supernatant of reticulocyte lysate are known to stimulate the import of various precursor proteins into mitochondria, the import of 11 beta-45 was not stimulated by cytosolic factors in reticulocyte lysate. The import of the peptide did not require mitochondrial surface protein components because its import was not affected by trypsin treatment of mitochondria. On the other hand, trypsin treatment of mitoplasts resulted in a great reduction in the import of the peptide, indicating that 11 beta-45 interacts during the import process with some protein components located inside mitochondria. These observations indicated that the peptide 11 beta-45 was imported via the potential-dependent pathway as in the case of precursor proteins, but skipped the interactions with cytosolic factors and mitochondrial surface components normally required for the import of precursor proteins.     

The precursor to ornithine carbamyl transferase is transported to mitochondria as a 5S complex containing an import factor

The precursor to ornithine carbamyl transferase (Mr = 40,000) was synthesized in a rabbit reticulocyte lysate system and purified by immunoaffinity chromatography. Import of purified precursor by isolated mitochondria depended upon the presence of import factor(s) in fresh reticulocyte lysate. Velocity sedimentation analyses indicated that import factor binds to precursor to form a 5S complex (approximately 90 kDa); in this form, precursor was efficiently imported by isolated mitochondria. The ability of the 5S complex to deliver precursor into mitochondria was not affected by pretreatment with high concentrations of RNase. Import factor did not bind to mitochondria in the absence of precursor; upon binding of precursor to mitochondria in the presence of import factor, subsequent transmembrane uptake of precursor did not require the continued presence of additional lysate components.     

Role of heat shock cognate 70 protein in import of ornithine transcarbamylase precursor into mammalian mitochondria.

The roles of the 70-kDa cytosolic heat shock protein (hsp70) in import of precursor proteins into the mitochondria were postulated to be related to (i) unfolding of precursor proteins in the cytosol, (ii) maintenance of the import-competent state, and (iii) unfolding and transport of precursor proteins through contact sites, in cooperation with matrix hsp70. We examined roles of cytosolic hsp70 family members in import of ornithine transcarbamylase precursor (pOTC) into rat liver mitochondria, using an in vitro import system and antibodies against hsp70. Immunoblot analysis using an hsc70 (70-kDa heat shock cognate protein)-specific monoclonal antibody and a polyclonal antibody that reacts with both hsc70 and hsp70 showed that hsc70 is the only or major form of hsp70 family members in the rabbit reticulocyte lysate. The hsc70 antibody did not inhibit pOTC import when added prior to import assay. However, when pOTC was synthesized in the presence of the antibody and then subjected to import assay, pOTC import was markedly decreased. pOTC import was also decreased when the precursor was synthesized in the lysate depleted for hsc70 by treatment with hsc70 antibody-conjugated Sepharose. This reduction was almost completely restored by readdition of purified mouse hsc70 during pOTC synthesis. The readdition of hsc70 after pOTC synthesis and only during the import assay was not effective. Thus, once import competence of pOTC was lost, hsc70 was ineffective for restoration. Newly synthesized pOTC lost import competence in the absence of hsc70 somewhat more rapidly than in its presence. These results indicate that hsc70 is required during pOTC synthesis and not during import into the mitochondria. hsc70 presumably binds to pOTC polypeptide and maintains it in an import-competent form.     

Inhibition of the import of mitochondrial proteins by RNase

RNase treatment of a cell-free translation system prevents transport of mitochondrial precursor proteins from that system into isolated yeast mitochondria. This inhibition depends on the presence of ribosomes in the reticulocyte lysate; if they are cleared by centrifugation, RNase treatment does not specifically inhibit protein uptake by mitochondria. Since protein import can occur in the absence of polyribosomes, RNase treatment does not degrade a structure essential for this process. Rather, the inhibition may be an effect of degraded ribosomes.     

Transport of ornithine carbamoyltransferase precursor into mitochondria. Stimulation by potassium ion, magnesium ion, and a reticulocyte cytosolic protein(s)

The precursor of rat liver ornithine carbamoyltransferase (EC 2.1.3.3) synthesized in vitro was taken up and processed to the mature enzyme by isolated rat liver mitochondria. Potassium ion, magnesium ion, and a reticulocyte cytosolic protein(s), in addition to the precursor and the mitochondria, were required for maximal transport and processing of the precursor. The concentrations of potassium and magnesium ions required for maximal transport and processing were about 120 and 0.8-1.6 mM, respectively. Dialyzed postribosomal supernatant of rabbit reticulocyte lysate (36 mg of protein/ml), in combination with potassium and magnesium ions, stimulated the transport and processing severalfold. The stimulatory activity of the dialyzed lysate was inactivated by trypsin treatment or heating at 100 degrees C for 2 min. No significant amount of the precursor was associated with the mitochondria when incubation was performed in the absence of these components. These results suggest that potassium ion, magnesium ion, and a reticulocyte cytosolic protein(s) stimulate the binding and transport of the ornithine carbamoyltransferase precursor to the mitochondria. Dialyzed supernatant of rabbit erythrocyte lysate was equally effective in stimulating the precursor transport and processing, and a dialyzed cytosol fraction of Ehrlich ascites cells was partly stimulatory. On the other hand, dialyzed cytosol fractions of rat liver and rat kidney, and dialyzed supernatant of wheat germ extracts did not stimulate the precursor transport and processing but rather inhibited it.     

The Mas20p and Mas70p subunits of the protein import receptor of yeast mitochondria interact via the tetratricopeptide repeat motif in Mas20p: evidence for a single hetero-oligomeric receptor.

Protein import into yeast mitochondria is mediated by four integral outer membrane proteins which function as import receptors. These proteins (termed Mas20p, Mas22p, Mas37p and Mas70p) appear to exist as two subcomplexes: a Mas37p-Mas70p heterodimer and a less well characterized Mas20p-Mas22p complex. The subcomplexes interact functionally during protein import, but it has remained uncertain whether they are in direct contact with each other in vivo. Here we show that Mas20p and Mas70p can be cross-linked in intact mitochondria, or co-immunoprecipitated from digitonin-solubilized mitochondria. Furthermore, the cytosolic domains of these two proteins interact in the 'two-hybrid' system. Association of Mas20p and Mas70p is virtually abolished by a mutation in the single tetratricopeptide motif in Mas20p. This mutation specifically inhibits import of precursors that are first recognized by Mas37p-Mas70p and only then transferred to Mas20p-Mas22p. We conclude that the two receptor subcomplexes of the mitochondrial protein import receptor interact in vivo via their Mas20p and Mas70p subunits and that this interaction is functionally important.     

Protein import into mitochondria in a homologous yeast in vitro system

To study the import of proteins into mitochondria we developed a homologous in vitro system in which mitochondria and cell-free translation extract are both derived from the yeast Saccharomyces cerevisiae. This system allows the synthesis of precursor proteins in the presence of isolated mitochondria and offers a means of analyzing yeast mutants defective in mitochondrial protein import. The in vitro import of an artificial precursor protein into yeast mitochondria in the presence of its substrate analog was analyzed subsequent to synthesis in either a yeast or rabbit reticulocyte cell-free translation reaction. Results suggest that a component(s) present in the yeast cytosolic extract may interact with the precursor protein.     

Purified presequence binding factor (PBF) forms an import-competent complex with a purified mitochondrial precursor protein.

In vitro mitochondrial import of the purified precursor form (pOTC) of rat ornithine carbamoyltransferase (OTC) is stimulated by a cytosolic factor(s) contained in rabbit reticulocyte lysate. A protein factor that binds to pOTC but not to mature OTC and was named presequence binding factor or PBF, was purified 91,000-fold from the lysate by affinity chromatography using pOTC-bound Sepharose, DEAE-5PW HPLC and sucrose gradient centrifugation. The purified PBF migrated as a single polypeptide of 50,000 daltons on SDS-PAGE. On sucrose gradients, urea-denatured pOTC sedimented to the bottom, whereas PBF sedimented with an S20,w value of 5.5S. When pOTC and PBF were centrifuged together, both polypeptides sedimented as a complex of 7.1S. Formation of the pOTC-PBF complex was inhibited by micromolar concentrations of the synthetic presequence of pOTC and those of other mitochondrial precursor proteins. The purified PBF markedly stimulated the import of purified or in vitro synthesized pOTC into the mitochondria. PBF-stimulated pOTC import was further enhanced by a 70 kd heat shock protein (hsp 70) purified from yeast; the hsp70 alone had little effect. Thus, PBF binds to the presequence portion of the precursors and may hold them in a transport-competent form in cooperation with hsp70.     

14-3-3 proteins: regulation of signal-induced events

The field of signal transduction has experienced a significant paradigm shift as a result of an increased understanding of the roles of 14-3-3 proteins. There are many cases where signal-induced phosphorylation itself may cause a change in protein function. This simple modification is, in fact, the primary basis of signal transduction events in many systems. There are a large and growing number of cases, however, where simple phosphorylation is not enough to effect a change in protein function. In these cases, the 14-3-3 proteins can be required to complete the change in function. Therefore signal transduction can be either the relatively simple process where phosphorylation alters target activity, or it can be a more complex, multistep process with the 14-3-3 proteins playing the major role of bringing the signal transduction event to completion. This makes 14-3-3-modulated signal transduction a more complicated process with additional avenues for regulation and variety. Adding further complexity to the process is the fact that 14-3-3 proteins are present as multigene families in most organisms (Aitken et al. Trends Biochem Sci 17: 498–501, 1992; Ferl Annu Rev Plant Physiol Plant Molecular Biology 47: 49–73, 1996), with each member of the family being differentially expressed in various tissues and with potentially differential affinity for various target proteins. This review focuses on the 14-3-3 family of Arabidopsis as a model for further developing understanding of the roles of the 14-3-3 proteins as modulators of signal transduction events in plants. The primary approaches to these questions are not unlike the approaches that would be used in the functional dissection of any multigene family, but the interpretation of these data will have wide implications since the 14-3-3 s physically interact with other protein families.     

Metabolic enzymes as targets for 14-3-3 proteins

The 14-3-3 proteins are binding proteins that have been shown to interact with a wide array of enzymes involved in primary biosynthetic and energy metabolism in plants. In most cases, the significance of binding of the 14-3-3 protein is not known. However, most of the interactions are phosphorylation-dependent and most of the known binding partners are found in the cytosol, while some may also be localized to plastids and mitochondria. In this review, we examine the factors that may regulate the binding of 14-3-3s to their target proteins, and discuss their possible roles in the regulation of the activity and proteolytic degradation of enzymes involved in primary carbon and nitrogen metabolism.