Altered processing of the neurotensin/neuromedin N precursor in PC2 knock down mice: a biochemical and immunohistochemical study

Neurotensin (NT) and neuromedin N (NN) are generated by endoproteolytic cleavage of a common precursor molecule, pro-NT/NN. To gain insight into the role of prohormone convertases PC1, PC2, and PC7 in this process, we investigated the maturation of pro-NT/NN in the brain of PC7 (PC7-/-), PC2 (PC2-/-), and/or PC1 (PC1+/- and PC2-/-; PC1+/-) knock down mice. Inactivation of the PC7 gene was without effect, suggesting that this convertase is not involved in the processing of pro-NT/NN. By contrast, there was a 15% decrease in NT and a 50% decrease in NN levels, as measured by radioimmunoassay, in whole brain extracts from PC2 null as compared with wild type mice. Using immunohistochemistry, we found that this decrease in pro-NT/NN maturation products was uneven and that it was most pronounced in the medial preoptic area, lateral hypothalamus, and paraventricular hypothalamic nuclei. These results suggest that PC2 plays a critical role in the processing of pro-NT/NN in mouse brain and that its deficiency may be compensated to a regionally variable extent by other convertases. Previous data have suggested that PC1 might be subserving this role. However, there was no change in the maturation of pro-NT/NN in the brain of mice in which the PC1 gene had been partially inactivated, implying that complete PC1 knock down may be required for loss of function.     

Arg-X-Lys/Arg-Arg motif as a signal for precursor cleavage catalyzed by furin within the constitutive secretory pathway

Many peptide hormones are produced from larger precursors by endoproteolysis at pairs of basic amino acids (e.g. Lys-Arg and Arg-Arg) within the regulated secretory pathway in endocrine cells. However, many other secretory and membrane proteins appear to be produced from precursors through cleavage at multiple, rather than paired, basic residues within the constitutive secretory pathway in non-endocrine cells. By surveying various precursors processed constitutively, we noticed that most of them have the consensus sequence, Arg-X-Lys/Arg-Arg (RXK/RR), at the cleavage site. When expressed in endocrine and non-endocrine cells, a precursor with the RXKR sequence was cleaved in both types of cells, whereas that with the Lys-Arg pair was cleaved only in the endocrine cells. When the RXKR precursor was coexpressed with furin and PC3, both of which are mammalian homologues of the yeast precursor-processing endoprotease Kex2, in non-endocrine cells, enhancement of the precursor cleavage by furin but not by PC3 was observed. By contrast, when the Lys-Arg precursor was coexpressed with the two mammalian proteases in endocrine cells with no endogenous processing activity at dibasic sites, it was cleaved only by PC3. These results indicate that the basic pair and the RXK/RR sequence are the signals for precursor cleavages catalyzed by PC3 within the regulated secretory pathway and by furin within the constitutive pathway, respectively.     

Production of recombinant large proneurotensin/neuromedin N-derived peptides and characterization of their binding and biological activity.

Proneurotensin/neuromedin N (pro-NT/NN) is the common precursor of two biologically active related peptides, neuromedin N (NN) and neurotensin (NT). It undergoes a tissue-specific processing leading to the formation in some tissues and cancer cell lines of large peptides ending with the NT (large NT) or NN (large NN) sequence. In this study, we prepared and purified high amounts of recombinant large NT and large NN using the Drosophila S2 cell expression system. The binding and pharmacological properties of recombinant large peptides were characterized and compared to those of NT and NN using either COS cells transfected with the human subtype-1 NT receptor (hNTS1) or the human colon adenocarcinoma HT29 cell line that endogenously expresses hNTS1. Furthermore, the metabolic stability of the large peptides, when exposed to HT29 cells, was compared to that of NT and NN. Both large NT and large NN were able to bind to and activate hNTS1 with potencies that were approximately 10 times lower than that of their small counterpart. In addition, the large forms proved to be far less sensitive to degradation than the small peptides. Taken together, these data suggest that the large forms might represent endogenous, long-lasting activators of hNTS1 in a number of physiopathological situations.     

Consensus sequence for precursor processing at mono-arginyl sites. Evidence for the involvement of a Kex2-like endoprotease in precursor cleavages at both dibasic and mono-arginyl sites.

Many peptide hormones and neuropeptides are produced from larger, inactive precursors through endoproteolysis at sites usually marked by paired basic residues (primarily Lys-Arg and Arg-Arg), or occasionally by a monobasic residue (primarily Arg). Based upon data concerning processing of prorenin and its mutants around the native Lys-Arg cleavage site expressed in mouse pituitary AtT-20 cells, we present the following sequence rules that govern mono-arginyl cleavages: (a) a basic residue at the fourth (position -4) or the sixth (position -6) residue upstream of the cleavage site is required, (b) at position -4, Arg is more favorable than Lys, and (c) at position 1, a hydrophobic aliphatic residue is not suitable. These rules are compatible with those proposed by comparison of precursor sequences around mono-arginyl cleavage sites. We also provide evidence that precursor cleavages at mono-arginyl and dibasic sites can be catalyzed by the same Kex2-like processing endoprotease, PC1/PC3.     

Tissue distribution and processing of proSAAS by proprotein convertases

The conversion of inactive precursor proteins into bioactive neuropeptides and peptide hormones involves regulated secretory proteins such as prohormone convertases PC1 and PC2. The neuroendocrine protein 7B2 represents a specific binding protein for PC2, and the protein proSAAS, which interacts with PC1, exhibits certain structural and functional homologies with 7B2. With the intention of better understanding the physiological role of proSAAS and its derived peptides, we investigated its tissue localization using a new radioimmunoassay (RIA) to a C-terminal proSAAS-derived peptide. Immunoreactivity corresponding to this SAAS-derived peptide is mostly localized to the brain and gut. Analysis of the brain distribution of the proSAAS-derived peptides indicates that the hypothalamus and pituitary are the two richest areas, consistent with the previously described high expression of PC1 in these two areas. In order to investigate the cleavage of proSAAS by prohormone convertases, we incubated recombinant His-tagged proSAAS with recombinant mouse proPC2 or furin, separated the cleavage products using high-pressure gel permeation chromatography and analyzed the products by RIA. Our results indicate that either PC2 or furin can accomplish in vitro rapid removal and efficient internal processing of the C-terminal peptide, exposing the inhibitory hexapeptide to possible further digestion by carboxypeptidases. Finally, we also studied proSAAS processing in the brains of wild-type and PC2 null mice and found that proSAAS is efficiently processed in vivo. Whereas the C-terminal peptide is mostly internally cleaved in wild-type mouse brain, it is not processed as efficiently in the brain of PC2 null mice, suggesting that PC2 is partially responsible for this cleavage in vivo.     

Effect of neurophysin on enzymatic maturation of oxytocin from its precursor

We examined the extent to which rates of enzymatic conversion of the oxytocin biosynthetic precursor to mature peptide are modulated by intramolecular and intermolecular assembly of precursor and polypeptide intermediates. The biosynthesized precursor contains hormone and neurophysin sequences linked by a Gly-Lys-Arg sequence and undergoes enzymatic processing reactions which include endoproteolytic cleavage at the Lys-Arg dibasic sequence, carboxypeptidase B-like exoproteolytic cleavage, and enzymatic amidation. We evaluated the effect of neurophysin on such processing reactions using semisynthetic precursors of oxytocin/bovine neurophysin I and synthetic oxytocinyl precursor intermediates as substrates. Neurophysin I at high concentration (0.7 mM) reduced the rates of carboxy-peptidase B-like conversion of oxytocinyl-Gly-Lys-Arg to oxytocinyl-Gly and the enzymatic amidation of oxytocinyl-Gly to mature (C-terminal amidated) oxytocin. The dependence of rate suppression on the concentrations of peptide substrate and neurophysin I suggested that suppression is due to intermolecular formation of hormone-neurophysin complexes which are aggregated at least to dimers. An analogous intramolecular neurophysin effect was found for endoproteolytic processing of semisynthetic precursors. Endoproteinase Lys-C cleaved the Lys11-Arg12 peptide bond in a native-like semisynthetic precursor at a significantly slower rate than it did an assembly-deficient precursor analogue. The difference in semisynthetic precursor endoproteolysis rates is most substantial at the high concentrations at which the native-like precursor would form dimers but the assembly-deficient analogue would not. The native-like semisynthetic precursor was more stable than the assembly-deficient precursor analogue to tryptic digestion. The concentration-dependent effects of neurophysin, both intramolecularly as a precursor domain and intermolecularly as an interacting protein, are likely to occur in the secretory granules in which the biosynthetic precursors are packaged. The molecular organization of both hormone/neurophysin precursors and the noncovalently complexed hormone-neurophysin intermediates can be expected to play a role in modulating enzymatic processing reactions that lead to mature neurohypophysial hormones.     

Differential processing of the neurotensin/neuromedin N precursor in the mouse

Posttranslational processing of the neurotensin/neuromedin N (NT/NN) precursor has been investigated in mouse brain and small intestine by means of region-specific radioimmunoassays coupled to chromatographic fractionations. In brain, total NT/NN immunoreactivity measured with a common C-terminal antiserum was 15.72 pmol/g. NT measured with an N-terminal antiserum was 9.74 pmol/g and NN measured with an N-terminal antiserum was 5.98 pmol/g. In small intestine, combined NT/NN immunoreactivity was 108.55 pmol/g, consisting of 66.37 pmol/g NT but only 0.96 pmol/g NN. Gel permeation chromatography and reverse phase HPLC revealed that the large discrepancy in the NT and NN values obtained in small intestinal extracts was due to the presence of a high molecular weight, hydrophobic peptide, which was reactive only with the common C-terminally directed antiserum. Pepsinization of this generated an immunoreactive peptide with similar chromatographic characteristics to NN. In mouse intestine, NN is only partially cleaved from the common NT/NN precursor, resulting in the presence of an N-terminally extended molecular species. This novel molecular species of neuromedin N may be the physiological mediator of certain peripheral biological effects hitherto attributed to neurotensin or neuromedin N.     

Prohormone Thiol Protease and Enkephalin Precursor Processing: Cleavage at Dibasic and Monobasic Sites

Production of active enkephalin peptides requires proteolytic processing of proenkephalin at dibasic Lys-Arg, Arg-Arg, and Lys-Lys sites, as well as cleavage at a monobasic arginine site. A novel “prohormone thiol protease” (PTP) has been demonstrated to be involved in enkephalin precursor processing. To find if PTP is capable of cleaving all the putative cleavage sites needed for proenkephalin processing, its ability to cleave the dibasic and the monobasic sites within the enkephalin-containing peptides, peptide E and BAM-22P (bovine adrenal medulla docosapeptide), was examined in this study. Cleavage products were separated by HPLC and subjected to microsequencing to determine their identity. PTP cleaved BAM-22P at the Lys-Arg site between the two basic residues. The Arg-Arg site of both peptide E and BAM-22P was cleaved at the NH₂-terminal side of the paired basic residues to generate [Met]-enkephalin. Furthermore, the monobasic arginine site was cleaved at its NH₂-terminal side by PTP. These findings, together with previous results showing PTP cleavage at the Lys-Lys site of peptide F, demonstrate that PTP possesses the necessary specificity for all the dibasic and monobasic cleavage sites required for proenkephalin processing. In addition, the unique specificity of PTP for cleavage at the NH₂-terminal side of arginine at dibasic or monobasic sites distinguishes it from many other putative prohormone processing enzymes, providing further evidence that PTP appears to be a novel prohormone processing enzyme.     

Favourable side-chain orientation of cleavage site dibasic residues of prohormone in proteolytic processing by prohormone convertase 1/3.

Previous studies using selectively modified pro-ocytocin/neurophysin substrate analogues and the purified metalloprotease, pro-ocytocin/neurophysin convertase (magnolysin; EC 3.4 24.62), have shown that dibasic cleavage site processing is associated with a prohormone sequence organized in a beta-turn structure. We have used various peptide analogues of the pro-ocytocin-neurophysin processing domain, and recombinant prohormone convertase 1/3, to test the validity of this property towards this member of the family of prohormone convertases (PCs). The enzymatic cleavage analysis and kinetics showed that: (a) with methyl amide (N-Met) modification, a secondary structure beta-turn breaker, the enzyme substrate interaction was abolished; (b) cleavage was favoured when the dibasic substrate side-chains were oriented in opposite directions; (c) the amino acid present at the P'1 position is important in the enzyme-substrate interaction; (d) the flexibility of the peptide substrate is necessary for the interaction; (e) Addition of dimethylsulfoxide to the cleavage assay favoured the cleavage of the pro-ocytocin/neurophysin large substrate over that of the smaller one pGlu-Arg-Thr-Lys-Arg-methyl coumarin amide. These data allowed us to conclude that proteolytic processing of pro-ocytocin-related peptide substrates by PC1/3 as well as by the metalloenzyme, magnolysin, involves selective recognition of precise cleavage site local secondary structure by the processing enzyme. It is hypothesized that this may represent a general property of peptide precursor proteolytic processing systems.     

Mono- and dibasic proteolytic cleavage sites in insect neuroendocrine peptide precursors

Regulatory peptides are synthesized as part of larger precursors that are subsequently processed into the active substances. After cleavage of the signal peptide, further proteolytic processing occurs predominantly at basic amino acid residues. Rules have been proposed in order to predict which putative proteolytic processing sites are actually used, but these rules have been established for vertebrate peptide precursors and it is unclear whether they are also valid for insects. The aim of this paper is to establish the validity of these rules to predict proteolytic cleavage sites at basic amino acids in insect neuropeptide precursors. Rules describing the cleavage of mono- and dibasic potential processing sites in insect neuropeptide precursors are summarized below. Lys-Arg pairs not followed by an aliphatic or basic amino acid residue are virtually always cleaved in insect regulatory peptide precursors, but cleavages of Lys-Arg pairs followed by either an aliphatic or a basic amino acid residue are ambiguous, as is processing at Arg-Arg pairs. Processing at Arg-Lys pairs has so far not been demonstrated in insects and processing at Lys-Lys pairs appears very rare. Processing at single Arg residues occurs only when there is a basic amino acid residue in position -4, -6, or -8, usually an Arg, but Lys or His residues work also. Although the current number of such sites is too limited to draw definitive conclusions, it seems plausible that cleavage at these sites is inhibited by the presence of aliphatic residues in the +1 position. However, cleavage at single Arg residues is ambiguous. When several potential cleavage sites overlap the one most easily cleaved appears to be processed. It cannot be excluded that some of the rules formulated here will prove less than universal, as only a limited number of cleavage sites have so far been identified. It is likely that, as in vertebrates, ambiguous processing sites exist to allow differential cleavage of the same precursor by different convertases and it seems possible that the precursors of allatostatins and PBAN are differentially cleaved in different cell types. Arch. Insect Biochem. Physiol. 43:49-63, 2000.     

Evidence for conservation of the vasopressin/oxytocin superfamily in Annelida

Annetocin is a structurally and functionally oxytocin-related peptide isolated from the earthworm Eisenia foetida. We present the characterization of the annetocin cDNA. Sequence analyses of the deduced precursor polypeptide revealed that the annetocin precursor is composed of three segments: a signal peptide, an annetocin sequence flanked by a Gly C-terminal amidation signal and a Lys-Arg dibasic processing site, and a neurophysin domain, similar to other oxytocin family precursors. The proannetocin showed 37.4-45.8% amino acid homology to other prohormones. In the neurophysin domain, 14 cysteines and amino acid residues essential for association of a neurophysin with a vasopressin/oxytocin superfamily peptide were conserved, suggesting that the Eisenia neurophysin can bind to annetocin. Furthermore, in situ hybridization experiments demonstrated that the annetocin gene is expressed exclusively in neurons of the central nervous system predicted to be involved in regulation of reproductive behavior. These findings confirm that annetocin is a member of the vasopressin/oxytocin superfamily. This is the first identification of the cDNA encoding the precursor of an invertebrate oxytocin-related peptide and also the first report of the identification of an annelid vasopressin/oxytocin-related precursor.     

An in vivo characterization of the cleavage site specificity of the insulin cell prohormone processing enzymes

Most peptide hormones and neurotransmitters are synthesized as larger precursor proteins, which are post-translationally processed to mature bioactive products. An early event in prohormone maturation is endoproteolytic cleavage, occurring usually at pairs of basic amino acids (e.g. Lys-Arg). Since many of the characteristics of a prohormone endoprotease are unknown, distinguishing these enzymes from other cellular proteases in vitro has been difficult. In this report, the substrate specificity of a model prohormone processing system, the insulinoma cell line Rin m5F, was characterized in vivo to establish a set of criteria by which putative proinsulin endoproteases may be assessed. To determine the role of composition of the paired basic amino acid site in directing cleavage, a series of mutant prohormones containing altered cleavage sites was constructed and expressed in Rin m5F cells. Proopiomelanocortin (POMC) was used as a substrate since this prohormone was previously shown to be processed by these cells. To control for positional effects, all four permutations of lysine and arginine (Lys-Arg, Arg-Arg, Arg-Lys, and Lys-Lys) were introduced at both the efficiently processed cleavage site separating the ACTH and beta-lipotropin (beta-LPH) domains of POMC and at the inefficiently processed site in the beta-endorphin sequence near the COOH-terminus of the precursor. His-Arg and Met-Arg sites were also introduced at the ACTH/beta-LPH junction to assess the requirement for paired lysines and arginines. Identification of POMC-derived peptides demonstrated efficient processing of Lys-Arg and inefficient processing of Lys-Lys and Arg-Lys sites at both positions in the prohormone. The Arg-Arg sequence, however, was processed in a position-dependent manner, being efficiently cleaved between ACTH and beta-LPH but only about 50% processed within beta-endorphin. His-Arg was not cleaved in Rin m5F cells, although surprisingly Met-Arg was partially processed. These results indicate a strict preference of the insulinoma prohormone endoprotease(s) for paired basic amino acids ending in arginine, but that processing efficiency of some sequences may be modulated by location within the precursor molecule.     

Pepsin-mediated processing of synthetic precursor-like sequence yields neurotensin-like peptide.

A 15 amino acid synthetic peptide, which spanned the dibasic cleavage site C-terminal to neurotensin (NT), in its 170-residue canine precursor, was synthesized by solid-phase methods. Using this substrate in combination with a radioimmunoassay specific for the C-terminal region of NT, a simple assay was developed to monitor protease-mediated cleavage of the Leu8-Lys9 bond in the substrate. Hog pepsin and the related enzymes, rhizopus pepsin, bovine cathepsin D, and mouse renin, were found to be effective in this assay, pepsin cleaving only this bond to liberate the NT-like sequence. The pH dependence of the reaction indicated that pepsin, cathepsin D, and renin exhibited significant activity at pH's characteristic for secretory vesicles (pH 5.5-6.5). In addition, pepsin and cathepsin D were shown to process the native precursor at pH's as high as 5.5. These results, although not proof, are consistent with the idea that endoproteases with pepsin-like specificity may be involved in the processing of the NT precursor in neural/endocrine cells.     

Specificity of the dynorphin-processing endoprotease: comparison with prohormone convertases

The cleavage specificity of a monobasic processing dynorphin converting endoprotease is examined with a series of quench fluorescent peptide substrates and compared with the cleavage specificity of prohormone convertases. A dynorphin B-29-derived peptide, Abz-Arg-Arg-Gln-Phe-Lys-Val-Val-Thr-Arg-Ser-Glneddnp (where Abz is o-aminobenzoyl and eddnp is ethylenediamine 2,4-dinitrophenyl), that contains both dibasic and monobasic cleavage sites is efficiently cleaved by the dynorphin converting enzyme and not cleaved by two propeptide processing enzymes, furin and prohormone convertase 1. A shorter prorenin-related peptide, Dnp-Arg-Met-Ala-Arg-Leu-Thr-Leu-eddnp, that contains a monobasic cleavage site is cleaved by the dynorphin converting enzyme and prohormone convertase 1 and not by furin. Substitution of the P1' position by Ala moderately affects cleavage by the dynorphin-processing enzyme and prohormone convertase 1. It is interesting that this substitution results in efficient cleavage by furin. The site of cleavage, as determined by matrix-assisted laser desorption/ionization time of flight mass spectrometry, is N-terminal to the Arg at the P1 position for the dynorphin converting enzyme and C-terminal to the Arg at the P1 position for furin and prohormone convertase 1. Peptides with additional basic residues at the P2 and at P4 positions also serve as substrates for the dynorphin converting enzyme. This enzyme cleaves shorter peptide substrates with significantly lower efficiency as compared with the longer peptide substrates, suggesting that the dynorphin converting enzyme prefers longer peptides that contain monobasic processing sites as substrates. Taken together, these results suggest that the cleavage specificity of the dynorphin converting enzyme is distinct but related to the cleavage specificity of the prohormone convertases and that multiple enzymes could be involved in the processing of peptide hormones and neuropeptides at monobasic and dibasic sites.     

Structural studies of a neuropeptide precursor protein with an RGD proteolytic site

The snail Lymnaea stagnalis produces a neuropeptide precursor protein that contains seven Arg-Gly-Asp (RGD) sites. These sites are recognized and cleaved by one or more prohormone convertases in the first processing step to yield mature neuropeptides in the secretory pathway. Conformations of two synthetic RGD-containing peptides derived from the L. stagnalis precursor protein were determined by NMR spectroscopy. The peptides were tested in a platelet aggregation assay for RGD activity and were processed in vitro by PC2 and furin. The native peptide with a proline following the RGD site has minimal structure around the RGD region, does not inhibit platelet aggregation, and is properly processed by the enzymes PC2 and furin. A variant of the native fragment with a serine following the RGD sequence has a significant amount of a reverse turn around the RGD region, is a potent inhibitor of platelet aggregation, and is processed with the same specificity as the native fragment. The large conformational differences between the two peptides provide a molecular mechanism for effects of proline residues following the RGD site and suggest that precursor processing is influenced more by flexibility than by the conformation of the processing site.     

Evidence for the presence of a secondary structure at the dibasic processing site of prohormone: the pro-ocytocin model.

Bioactivation of pro-proteins by limited proteolysis is a general mechanism in the biosynthesis of hormones, receptors and viral protein precursors. This proceeds by cleavage of peptide bonds at the level of single or pairs of basic residues in the proforms. Examination of a number of cleavage loci in various precursors failed to reveal any consensus primary sequence around the dibasic cleavage sites. Thus it has been proposed, on the basis of secondary structure predictions [Rholam, M., Nicolas, P. and Cohen, P. (1986) FEBS Lett., 207, 1-6], that those basic residues which operate as signal loci for the proteolytic enzyme machinery are situated in, or next to, privileged precursor regions most often constituted by flexible and exposed motifs, e.g. beta-turns and/or loops. Peptides reproducing the N-terminal processing domain of the hormone precursor, pro-ocytocin-neurophysin, were examined by a combination of spectroscopical techniques including circular dichroism, infrared Fourier transform and one- and two-dimensional proton NMR. The results indicate that: (i) the region situated on the N terminus of the Lys-Arg doublet is organized as a beta-turn in solution; (ii) the sequential organization of the residues participating in the beta-turn determines the privileged relative orientation of the basic amino acid side chains and the subtype of turn; (iii) the peptide segment situated on the C-terminal side of the dibasic, corresponding to the N-terminal octapeptide of neurophysin, is organized as an alpha-helix.(ABSTRACT TRUNCATED AT 250 WORDS)     

A type-II beta-turn, proline-containing, cyclic pentapeptide as a building block for the construction of models of the cleavage site of pro-oxytocin.

Previous studies have indicated that proteolytic activation of pro-hormones and pro-proteins occurs most frequently at the level of basic amino acids arranged in doublets and that the dibasic sites are situated in or next to beta-turns. Investigations utilizing synthetic peptides reproducing the N-terminal processing domain of pro-oxytocin-neurophysin have suggested a close relationship between the secondary structure of the cleavage locus and enzyme recognition, the minimal recognized sequence being the -Pro-Leu-Gly-Gly-Lys-Arg-Ala-Val-Leu- segment of the native precursor. NMR investigations and energy minimization studies have demonstrated that this sequence is organized in two type-II beta-turns involving the -Pro-Leu-Gly-Gly- and -Lys-Arg-Ala-Val- sequences. To further strengthen the above reported hypothesis and to study the role of turn subtypes, a new proline containing cyclic substrate of the processing enzyme, in which the N-terminal side that comes before the Lys-Arg pair is constrained to adopt a type-lI beta-turn, has been synthesized. The presence of a type-II beta-turn structure in this cyclic peptide model has been demonstrated by a combined NMR, CD and FT-IR absorption investigation. A preliminary study shows that PC1 is able to recognize and process our constrained substrate.     

Proteolytic Processing of Chromogranin B and Secretogranin II by Prohormone Convertases

Abstract: Two experimental approaches were used to study the processing of chromogranin B and secretogranin II by prohormone convertases. In GH₃ cells various prohormone convertases were overexpressed together with the substrate chromogranin B by use of a vaccinia virus infection system. PC1 appeared to be by far the most active enzyme and converted chromogranin B to several smaller molecules, including the peptide PE-11. In brain this peptide is cleaved physiologically from chromogranin B. Some processing of chromogranin B and formation of free PE-11 were also observed with PC2 and PACE4. Furin produced larger fragments, whereas PC5-A and PC5-B had negligible effects. As a second model, PC12 cells were stably transfected with PC1 or PC2 to investigate the processing of endogenous chromogranins. Both enzymes effectively cleaved chromogranin B and secretogranin II, liberating the peptides PE-11 and secretoneurin, respectively. However, in transfection experiments the ability to generate the free peptides was more pronounced with PC2 than with PC1. The extent of proprotein processing achieved by prohormone convertases apparently differed depending on the experimental system applied. This suggests that in vivo mechanisms to support and fine-tune the activity of the processing enzymes exist, which might be overlooked by using only one methodological approach.