Biosynthesis and processing of presumed neurosecretory proteins in single identified neurons of Aplysia californica.

The biosynthesis and processing of low molecular weight protein (presumed neurosecretory protein) in cells R15, R14 and L11 of Aplysia californica was studied at high resolution by polyacrylamide slab gel electrophoresis in sodium dodecylsulfate. The number of low molecular weight proteins detected in each cell ranges from 3 in R14 and L11 to 5 to 6 in R15. In each of the cells studied, the low molecular weight protein consists of a primary precursor of ca. 12,000 daltons, and its proteolytic processing products. In each cell, the smallest protein, or in the case of R14, one of the two smallest proteins, accumulates to a significant extent, suggesting that it might correspond to a final processed neurohormone. In cell R15, the biosynthesis of the primary precursor and its subsequent processing to smaller peptides is largely unaffected by removal of extracellular calcium, by replacement of calcium with cobalt or by inhibition of spontaneous bursting via stimulation of the brachial nerve.     

The processing of interleukin-1 beta studied with antibodies raised against synthetic peptides from the precursor N-terminal region

The exact sequence of events during processing of human interleukin-1 beta (IL-1 beta) and the fate of the N-terminal region are unknown. We have used anti-peptide sera specific for the precursor and mature regions of IL-1 beta to study biosynthesis. These were raised against peptides corresponding to amino acids 1-15, 17-32, and 43-54 of the precursor and a peptide corresponding to the C-terminal 33 amino acids of mature human IL-1 beta. Antiserum to the mature region peptide immunoprecipitated the 35-kD precursor from cell lysates and 17-kD mature IL-1 beta and a 31-kD protein from the culture supernatants from radiolabeled human peripheral blood monocytes stimulated with lipopolysaccharide (LPS). Antisera to peptides from the precursor region also immunoprecipitated the 35-kD IL-1 beta precursor but not the 31-kD or 17-kD forms. Of the precursor-specific sera, only antiserum to amino acids 1-15 specifically recognized any other proteins; a peptide of 18 kD and a low molecular weight peptide, both of which accumulated in the medium. The 18-kD protein was not recognized by any of the other antisera and is unlikely to be the N-terminal region of the precursor removed during processing. Pulse-chase experiments indicated that the 31-kD protein could be a processing intermediate and also that it was itself an end product along with full-length precursor. Only 17-kD mature IL-1 beta had biological activity.     

Proteins and Glycoproteins of Paramyxoviruses: a Comparison of Simian Virus 5, Newcastle Disease Virus, and Sendai Virus

The polypeptides of three paramyxoviruses (simian virus 5, Newcastle disease virus, and Sendai virus) were separated by polyacrylamide gel electrophoresis. Glycoproteins were identified by the use of radioactive glucosamine as a carbohydrate precursor. The protein patterns reveal similarities among the three viruses. Each virus contains at least five or six proteins, two of which are glycoproteins. Four of the proteins found in each virus share common features with corresponding proteins in the other two viruses, including similar molecular weights. These four proteins are the nucleocapsid protein (molecular weight 56,000 to 61,000), a larger glycoprotein (molecular weight 65,000 to 74,000), a smaller glycoprotein (molecular weight 53,000 to 56,000), and a major protein which is the smallest protein in each virion (molecular weight 38,000 to 41,000).     

Evidence for multiple somatic pools of individual axonally transported proteins

The idea that individual axonally transported proteins can exist in several kinetically distinct pools within the cell body was studied using the presumptive neurosecretory low molecular weight (LMW) proteins of Aplysia neurons L11 and R15. Pulse-chase experiments revealed that the loss of labeled LMW proteins from the soma by axonal transport does not follow single exponential kinetics as it should if they are being removed from single pools. Rather, decay of label occurs in at least two phases having half-lives of approximately 1 and 40 h. The LMW proteins are homogeneous by sequential SDS gel electrophoresis and isoelectric focusing, indicating that individual protein species exhibit multiphasic decay kinetics. Two types of evidence imply that the bulk of cellular LMW protein turns over at the slower rate: the LMW pool does not reach constant specific activity at the rapid rate during continuous exposure to labeled precursor, and long-term blockade of axonal transport does not produce an appreciable accumulation of these species in the cell body. These results suggest that some of the newly synthesized LMW protein enters a small somatic pool from which it is rapidly subjected to axonal transport, while the remainder enters a larger pool where it can mix with previously synthesized protein before transport. A cellular mechanism that would yield this behavior is suggested.     

Chemical and immunological characterizations of equine infectious anemia virus gag-encoded proteins.

The viral core proteins (p15, p26, p11, and p9) of equine infectious anemia virus (EIAV) (Wyoming strain) were purified by reverse-phase high-pressure liquid chromatography. Each purified protein was analyzed for amino acid content, N-terminal amino acid sequence, C-terminal amino acid sequence, and phosphoamino acid content. The results of N- and C-terminal amino acid sequence analysis of each gag protein, taken together with the nucleotide sequence of the EIAV gag gene (R. M. Stephens, J. W. Casey, and N. R. Rice, Science 231:589-594, 1986), show that the order of the proteins in the precursor is p15-p26-*-p11-p9, where a pentapeptide also found in the virus is represented by the asterisk. The data are in complete agreement with the predicted structure of the gag polyprotein and show the peptide bonds cleaved during proteolytic processing. The N-terminus of p15 is blocked to Edman degradation. The p11 protein is identical to the nucleic acid-binding protein of EIAV previously isolated (C. W. Long, L. E. Henderson, and S. Oroszlan, Virology 104:491-496, 1980). High-titer rabbit antiserum was prepared against each purified protein. These antisera were used to detect the putative gag precursor (Pr55gag) and intermediate cleavage products designated Pr49 (p15-p26-*-p11), Pr40 (p15-p26), and Pr35 (p26-*-p11) in the virus and in virus-infected cells. High-titer antisera to EIAV p15 and p26 showed cross-reactivity with the homologous protein of human T-cell lymphotropic virus type III/lymphadenopathy-associated virus.     

Identification from cDNA of the precursor form of a chondroitin sulfate proteoglycan core protein

The yolk sac carcinoma cell line L2 secretes a chondroitin/dermatan sulfate proteoglycan that has an Mr 10,000 core protein and carries an average of 14 glycosaminoglycan chains. The amino acid sequence of the mature core protein has been determined from cloned cDNA (Bourdon, M. A., Oldberg, A., Pierschbacher, M., and Ruoslahti, E. (1985) Proc. Natl. Acad. Sci. U. S. A. 82, 1321-1325). From additional cDNA sequences described in this report we have identified the prepro core protein precursor of the yolk sac carcinoma chondroitin/dermatan sulfate proteoglycan. From the amino acid sequence of the core protein precursor can be deduced the protein processing events in the biosynthesis of the proteoglycan. The amino acid sequence shows that the 104-amino acid mature core protein is processed from a 179-amino acid prepro core protein precursor which, in addition to the mature core protein, contains a 26-amino acid signal peptide as well as a 49-amino acid propeptide. The molecular weight of the prepro core protein predicted from the cDNA sequence (Mr = 18,600) was in good agreement with the molecular weight of the in vitro translation product (Mr = 19,000) of hybrid-selected mRNA. Accordingly, we have designated the proteoglycan core protein PG19. Further analysis of the PG19 mRNA by RNA sequencing confirmed the identification of the core protein translation initiation codon by revealing stop codons in all three reading frames of the upstream mRNA sequence. Primer extension analyses demonstrated that the 5' untranslated sequence of the proteoglycan mRNA is approximately 220 nucleotides in length, which, combined with the length of cDNA clones, accounts for the entire length of the coding sequence of PG19 mRNA from L2 cells. The cDNA sequences presented here establish the complete protein sequence of PG19 and provide evidence of polypeptide processing during the biosynthesis of the proteoglycan core protein.     

Possible existence of high molecular precursor proteins for substance P biosynthesis in rabbit spinal ganglia

The presence of precursor protein for substance P (SP) was examined. Sephadex G-75 chromatography of extracts from rabbit spinal ganglia incubated with [³⁵S]methionine gave two radioactive peaks. In the lower molecular weight peak SP was identified by radioimmunoassay, Sephadex G-15 and TLC. When higher molecular weight proteins were incubated with spinal ganglia microsomal preparation and applied to Sephadex G-75, G-15, TLC and HPLC, ³⁵S-labeled SP was identified and characterized as authentic by immunoprecipitation followed by Sephadex G-15. The amount of ³⁵S-labeled SP was reduced by prior heating of ganglia homogenates, addition of N-ethylmaleimide or p-chloromercuribenzoic acid but not by cycloheximide. Characterization of higher molecular weight proteins by Sephadex G-200, gel-permeation chromatography and chromatofocusing revealed that the proteins were of approx. 100,000 and 7000 dalton with isoelectric points of 9.0, 8.4 and 7.8. These results suggest that the processing from a precursor protein to SP may involve several steps and our high molecular weight protein of 7000 dalton may be one of these intermediate precursor peptides for SP.     

Characterization of the adenovirus E3 protein that down-regulates the epidermal growth factor receptor. Evidence for intermolecular disulfide bonding and plasma membrane localization.

We have characterized the biosynthesis and processing of a 91 amino acid hydrophobic integral membrane protein encoded by human group C adenoviruses which down-regulates the EGF receptor (Carlin, C. R., Tollefson, A. E., Brady, H. A., Hoffman, B. L., and Wold, W. S. M. (1989) Cell 57, 135-144). Previous studies have shown that two immunologically related proteins are produced in vivo, a 13.7-kDa protein encoded by E3 message f and a 11.3-kDa protein derived from 13.7 kDa by proteolysis (Hoffman, B. L., Ullrich, A., Wold, W. S. M., and Carlin, C. R. (1990) Mol. Cell. Biol. 10, 5521-5524; Tollefson, A. E., Krajcsi, P., Yei, S., Carlin, C. R., and Wold, W. S. M. (1990) J. Virol. 64, 794-801). We report here that the 13.7- and 11.3-kDa proteins form intermolecular disulfide bonds cotranslationally at Cys-31 and tend to migrate as high molecular weight aggregates under nonreducing conditions. Both proteins are also present at the cell surface, as evidenced by specific immunoprecipitation from intact monolayers enzymatically labeled with 125I. Moreover, an antiserum specific for a putative extracellular epitope recognizes the same viral proteins as antibodies directed against a C-terminal synthetic 15-mer. The 13.7- and 11.3-kDa proteins are detected at early time points during pulse-chase radiolabeling of infected cells, do not undergo any further changes in molecular weight, and focus at their predicted isoelectric points (7.4 and 7.2, respectively). Identical results are obtained in stable transfectants constitutively expressing only 13.7 and 11.3 kDa, suggesting that biosynthesis and processing is not dependent on other viral proteins. These results have been incorporated into a computer-based model to predict the orientation of 13.7 and 11.3 kDa in the lipid bilayer. This model provides a basis for testing predictions regarding the topology of the viral proteins, as well as putative interactions with heterologous proteins in the microenvironment of the plasma membrane that cause down-regulation of the epidermal growth factor receptor.     

Inhibition of disulfide bonding of von Willebrand protein by monensin results in small, functionally defective multimers

The biosynthesis of von Willebrand protein by human endothelial cells was impaired by the presence of the carboxylic ionophore monensin. Several processing steps that have been localized to the Golgi apparatus were affected in a dose-dependent manner, including carbohydrate processing, dimer multimerization, and precursor cleavage. Since multimerization was more susceptible to the ionophore than was precursor cleavage, it appears that these processing steps are separate events. As expected, dimer formation, which occurs in the rough endoplasmic reticulum, was unaffected by monensin. Thus, at high concentrations of monensin, only dimer molecules were produced and secreted. The observed inhibition of multimer formation and precursor cleavage were not likely the result of incomplete carbohydrate processing, since inhibition of complex carbohydrate formation by swainsonine did not interfere with the other processing steps. Monensin also affected the capacity of endothelial cells to store von Willebrand protein, as the ratio of secreted to cell-associated protein increased dramatically in the presence of monensin, and the processed forms could not be found in the treated cells. The low molecular weight multimers produced in the presence of monensin did not incorporate in the endothelial cells' extracellular matrix nor did they bind to the matrix of human foreskin fibroblasts. In summary, the presence of monensin in human endothelial cell culture produced experimental conditions that mimic Type IIA von Willebrand disease, in that the cells synthesized and secreted only low molecular weight von Willebrand protein multimers, which were functionally defective.     

Proteome analysis on an early transformed human bronchial epithelial cell line,BEP2D,after alpha-particle irradiation

To probe the mechanism of carcinogenesis of lung cancer at the molecular level and to find potential protein markers involved in the early phase of tumorgenesis, differential proteome analysis on primary passage cell line R15H, and early transformed cell line R15H20 derived from (238)Pu alpha-particle irradiation of human papillomavirus (HPV) 18-immortalized human bronchial epithelial cell line (BEP2D), was carried out using two-dimensional electrophoresis (2-DE) and peptide mass fingerprinting (PMF) with matrix-assisted laser desorption/ionisation-time of flight mass spectrometry. Image analysis and Student's t-test (p < 0.05) showed that three protein spots were only expressed in R15H, intensities of 43 protein spots on the gels were altered between R15H and R15H20. Two of the three spots that were only expressed in R15H were identified as high mobility group protein 1. Two proteins decreased in abundance in R15H20 were identified as maspin precursor, a tumor suppressor and aminoacylase-1. Ornithine aminotransferase and peptidyl-prolyl cis-trans isomerase A that were increased in R15H20, were also identified. Relationships between these differentially expressed proteins and the carcinogenesis mechanism of lung cancer are discussed. The protein expression profile of the R15H cell line was also constructed during the study as a reference map for further comparative proteome analysis of the irradiation induced BEP2D cell line. Of the 90 spots analyzed with PMF in the 2-DE gel of R15H cell line, 50 proteins were identified by searching the nonredundant protein database SWISS-PROT/TrEMBL.     

Biosynthetic processing of human interleukin-2 receptor (Tac antigen)

Biosynthetic processing of the T-cell surface receptor for interleukin-2 was investigated in a cultured human T-cell line MT-1 by means of metabolic and cell surface radiolabeling followed by immunoprecipitation with a monoclonal anti-receptor antibody (anti-Tac) and analysis by one- and two-dimensional polyacrylamide gel electrophoresis. The nascent precursor of the receptor (Mr = about 40,000, pI = 6.2-6.5) underwent a post-translational modification giving rise to the mature receptor (IL-2R; Mr = 60,000-65,000, pI = 4.2-4.7) within 2-4 hr. The post-translational processing of IL-2R caused a 20,000-25,000 increase in apparent molecular weight and a 2.0-2.5 acidic shift in the isoelectric point. The increase in molecular weight was attributable mainly to addition of sugar residues including glucosamine and galactose, and the charge shift to the addition of sialic acids. A carboxylic ionophore monensin completely blocked the maturation of IL-2R at the mid-stage of the processing. Fatty acid attachment appeared to comprise one of the steps of the post-translational modification. Two-dimensional analyses of IL-2R biosynthesis enabled identification of the precursor of IL-2R and its intermediate forms, from which it was partially possible to estimate reactions involved in the maturation of the precursor molecule.     

Effect of reduced membrane lipid fluidity on the biosynthesis of lipopolysaccharide of Escherichia coli

A low molecular weight precursor of lipopolysaccharide was accumulated under conditions in which the membrane lipids of a fatty acid auxotroph of Escherichia coli were reduced to a non-fluid state. The lipopolysaccharide precursor was detected, by sodium dodecyl sulfate/polyacrylamide gel electrophoresis and autoradiography, in membranes isolated from cells which were pulse-labeled with N-acetyl-[1-14C]glucosamine. The precursor could be chased into mature lipopolysaccharide by returning the membrane lipids to a normal fluid state. Conversion of the precursor to lipopolysaccharide was inhibited by the presence of potassium cyanide or sodium arsenate. The processing of several outer membrane protein precursors, including the promatrix proteins, was also inhibited under these conditions. Preliminary characterization of the lipopolysaccharide precursor was undertaken.     

Biosynthesis pathway of gp90MEL-14, the mouse lymph node-specific homing receptor

The mouse lymph node specific homing receptor gp90MEL-14 is a 95-kDa molecular mass ubiquitinated cell surface molecule involved in the binding of lymphocytes to high endothelial venules in peripheral lymph nodes. The molecule is thought to consist of a core protein to which ubiquitin side chains are covalently bound. Recently we cloned the cDNA encoding the core protein; this cDNA clone encodes for a polypeptide with an estimated molecular mass of 37 kDa. We have studied the biosynthesis of gp90MEL-14 in an effort to explain the difference in molecular mass between the core protein and the 95-kDa mature molecule. Pulse labeling experiments show a rapid synthesis of a 70-kDa precursor form that contains high-mannose N-linked oligosaccharides. On processing of the high-mannose oligosaccharides into complex N-linked oligosaccharides, the precursor matures in a single step into the 95-kDa form. Experiments using deglycosylating enzymes and inhibitors of N-linked glycosylation demonstrate that the molecular mass of deglycosylated gp90MEL-14 is 45 kDa; extensive N-linked glycosylation is responsible for the difference in molecular mass with the mature 95-kDa form. The core protein molecular weight of in vitro transcribed and translated gp90MEL-14 cDNA is consistent with the estimated molecular mass of 37 kDa, calculated from the cDNA sequence of the core protein, and 8 to 10 kDa less than the protein molecular mass of gp90MEL-14 translated in vivo in the presence of tunicamycin (45 kDa). Inasmuch as we have ruled out glycosylation as accounting for this discrepancy, this is consistent with the addition of one ubiquitin moiety to the core protein during biosynthesis. Limited proteolysis confirms the similarity between in vitro transcribed gp90MEL-14 cDNA and the tunicamycin form of gp90MEL-14.     

In maize,glutelin-2 and low molecular weight zeins are synthesized by membrane-bound polyribosomes and translocated into microsomal membranes

Summary Experiments to establish the site of biosynthesis and the possible translocation into microsomes of glutelins-2 (28 kD G2) and low molecular weight zeins (10, 14, 15 kD Z2) have been carried out. Free and membrane-bound polyribosomes as well as microsomal membranes were isolated from immature endosperms of W64A Zea mays L. In vitro translation studies were carried out in the presence and in the absence of membranes using [³⁵S]-methionine or [³⁵S]-cysteine as precursors. Cell-free translation products were characterized by electrophoretic mobility, solubility and antigenic properties. The results obtained indicate that 28 kD G2 and low molecular weight zeins are primarily synthesized on membrane-bound polysomes. From experiments using proteinase K as a probe, we also conclude that these proteins are translocated into microsomes where they accumulate. The translocated and pre-28 kD G2 proteins do not present changes in the apparent molecular weight. However we show that there are differences in their isoelectric points, a fact that indicates the existence of 28 kD G2 processing.     

Purification from brain of synenkephalin, the N-terminal fragment of proenkephalin

Abstract: The primary sequence of adrenal proenkephalin was recently deduced from the structure of the cloned cDNA that codes for this protein. Several enkephalin-containing proteins with molecular weights between 8,000 and 20,000 daltons were purified from the bovine adrenal medulla. These proteins appear to represent intermediates in the processing of proenkephalin into physiologically active opioid peptides. While the concentrations of these large processing intermediates in the adrenal medulla are quite high, similar proteins have not yet been shown to be present in brain, and there is some question as to whether the brain synthesizes an enkephalin precursor similar to adrenal proenkephalin. We report here the purification from bovine caudate nucleus of synenkephalin, the N-terminal fragment of adrenal proenkephalin. The amino acid composition of synenkephalin indicates that the protein represents residues 1–70 of adrenal proenkephalin. Thus the brain and adrenal glands appear to utilize a similar precursor for enkephalin biosynthesis.     

Synthesis and processing of cellulase from ripening avocado fruit

The biosynthesis and processing of cellulase from ripening avocado fruit was studied. The mature protein is a glycoprotein, as judged by concanavalin A binding, with a molecular weight of 54,200. Upon complete deglycosylation by treatment with trifluoromethane sulfonic acid the mature protein has a molecular weight of 52,800 whereas the immunoprecipitated in vitro translation product has a molecular weight of 54,000. This result indicates that cellulase is synthesized as a large molecular weight precursor, which presumably possesses a short-lived signal peptide. A membrane-associated and heavily glycosylated form of the protein was also identified. This putative secretory precursor was enzymically active and the carbohydrate side chains were sensitive to endoglycosidase H cleavage. Results of partial endoglycosidase H digestion suggest that this precursor form of the mature glycoprotein possesses two high-mannose oligosaccharide side chains. The oligosaccharide chains of the mature protein were insensitive to endoglycosidase H cleavage, indicating that transport of the membrane-associated cellulase to the cell wall was accompanied by modification of the oligosaccharide side chains. The presence of a large pool of endoglycosidase H-sensitive membrane-associated cellulase (relative to an endoglycosidase H-insensitive form) suggest that transit of this protein through the Golgi is rapid relative to transit through the endoplasmic reticulum.     

A single precursor protein for two separable mitochondrial enzymes in Neurospora crassa

The arg-6 locus of Neurospora crassa encodes two early enzymes of the arginine biosynthetic pathway, acetylglutamate kinase and acetylglutamyl-phosphate reductase. Previous genetic and biochemical analyses of this locus and its products showed that: 1) strains carrying polar nonsense mutations in the acetylglutamate kinase gene lacked both enzyme activities (Davis, R.H., and Weiss, R.L. (1983) Mol. Gen. Genet. 192, 46-50), and 2) the proteins isolated from mitochondria were completely separable (Wandinger-Ness, A., Wolf, E.C., Weiss, R.L., and Davis, R.H. (1985) J. Biol. Chem. 260,5974-5978). These data suggested that the two enzymes were initially synthesized as a single precursor which was subsequently cleaved into two distinct polypeptides. We report here the identification of a high molecular weight protein, synthesized in vitro from isolated N. crassa RNA, that contains sequences corresponding to acetylglutamate kinase as well as acetylglutamyl-phosphate reductase. An analogous precursor was identified in vivo by pulse-labeling experiments. The precursor was similar to other mitochondrial precursors in that its uptake and processing in vivo was rapid and required an intact mitochondrial electrochemical gradient. This represents the first report of a bifunctional protein precursor which gives rise to two mitochondrial enzymes.     

Lipid fluidity-dependent biosynthesis and assembly of the outer membrane proteins of E. coli.

The reduction of the membrane lipids of E. coli to a nonfluid state resulted in the accumulation in the cell envelope of a high molecular weight precursor of the protoIG protein, a major outer membrane protein. The protoIG protein was as sensitive to trypsin as the mature toIG protein assembled in the outer membrane. In contrast to the toIG protein, however, the accumulated protoIG protein was easily released from the envelope fraction by both sodium lauryl sarcosinate extraction and sonication. This indicated that the precursor protein was loosely associated with the cell membrane. When a fluid lipid state was restored, the protoIG protein was processed to the mature form which was then correctly assembled in the outer membrane. These results suggest that the protoIG protein produced under nonfluid lipid conditions was properly translocated across the cytoplasmic membrane, but could not be assembled in the outer membrane due either to the reversible inhibition of the processing of the ProtoIG to the toIG protein or to the lack of interaction with a specific outer membrane component(s). Reduced lipid fluidity also caused various alterations in the biosynthesis and assembly of other membrane proteins. In addition to the toIG protein, a large number of new proteins were accumulated in the membrane. Alternatively, the matrix protein as well as the promatrix protein were not detected in the cell envelope. On the other hand, the lipoprotein was normally produced, processed, modified and assembled in the outer membrane. These results indicate that the outer membrane proteins are synthesized and assembled according to several different mechanisms, on which the physical state of the membrane has various effects.     

Molecular identification of the ten subunits of cytochrome-c reductase from potato mitochondria

Cytochrome-c reductase (EC 1.10.2.2.) from Solanum tuberosum L. comprises ten subunits with apparent molecular sizes of 55, 53, 51, 35, 33, 25, 14, 12, 11 and 10 kDa on 14% SDS-PAGE. The identity of the subunits was analysed by direct amino-acid sequencing via cyclic Edman degradation. A large-scale purification procedure for the enzyme complex based on affinity chromatography and gelfiltraton is described. All subunits were enzymatically fragmented and the generated peptides were separated by reverse-phase HPLC. Complete or partial sequence determination of 33 peptides comprising a total of nearly 500 amino acids showed, that cytochrome-c reductase from potato contains three respiratory proteins (cytochrome b, cytochrome c ₁ and the Rieske iron-sulfur protein), four small proteins with molecular sizes below 15 kDa (so-called Q-binding, hinge, cytochrome-c ₁-linked and core-linked proteins) and three proteins in the 50-kDa range which show similarity to members of the core/PEP/MPP protein family (core/processing enhancing protein/mitochondrial processing peptidase). In fact these subunits show highest sequence identity either to MPP or PEP, which is in line with earlier findings, that isolated cytochrome-c reductase from potato exhibits processing activity towards mitochondrial precursor proteins.Abbreviations MPP mitochondrial processing peptidase - PEP processing enhancing protein This research was supported by the Deutsche Forschungsgemeinschaft.