The proprotein convertase PC7: unique zymogen activation and trafficking pathways

The zymogen activation mechanism and physiological functions of the most ancient and highly conserved basic amino acid-specific proprotein convertase 7 (PC7) are not known. Herein, we characterized the biosynthesis, subcellular localization, and trafficking of the membrane-bound full-length rat and human PC7. The prosegment of PC7 is primarily secreted alone as a non-inhibitory protein via the conventional, Golgi-dependent, secretory pathway. Mature PC7 is partially sulfated and thus reaches the cell surface via the conventional route. However, a fraction of PC7 reaches the cell surface through a brefeldin A- and COPII-independent unconventional secretory pathway. The latter trafficking may explain the rapid (<10 min) transit of a fraction of PC7 from the ER to the cell surface. Electron microscopy further confirmed the localization of PC7 to the cell surface of HEK293 cells. Within the cytosolic tail, only two cysteines (Cys(699) and Cys(704)) are palmitoylated, but this modification does not affect the choice of trafficking pathway. Swapping the transmembrane-cytosolic tail (TMCT) sequences of the convertases Furin and PC7 revealed that PC7(TMCT-Furin) is much more sulfated and hence traffics more efficiently through the conventional secretory pathway. In contrast, the Furin(TMCT-PC7) is no longer sulfated and thus reaches the cell surface by the unconventional pathway. Because trafficking of PC7(CT-Furin) and Furin(CT-PC7) resemble their wild type counterparts, we deduce that the transmembrane domain of PC7 regulates the sorting of PC7 toward the unconventional secretory pathway. In conclusion, PC7 is distinct from other proprotein convertases in its zymogen activation, subcellular localization, and trafficking.     

Structure-function analysis of the prosegment of the proprotein convertase PC5A

To investigate if some residues within the prosegment of PC5A are important for its optimal proteolytic function, various PC5A mutants were cellularly expressed, and their processing activities were compared using pro-vascular endothelial growth factor C (pro-VEGF-C) as a substrate. Although wild type PC5A almost completely processes pro-VEGF-C, a prosegment deletion as well as both P1 mutants of the primary (R116A) and secondary (R84A) autocatalytic cleavage sites are inactive. The in vitro inhibitory potency of various decapeptides mimicking the C-terminal sequence of PC5 prosegment (pPC5) revealed that the native (107)QQVVKKRTKR(116) peptide is a nanomolar inhibitor, whereas its P6 mutant K111H is more selective toward PC5A than Furin. In vitro activity assays using the bacterially expressed pPC5 and its mutants revealed them to be very potent nanomolar inhibitors (IC(50)) and only approximately 6-fold more selective inhibitors of PC5A versus Furin. Expression of the preprosegment of PC5 (ppPC5) and its mutants in Chinese hamster ovary FD11 cells overexpressing pro-VEGF-C with either PC5A or Furin showed them to be as good inhibitors of PC5A as the serpin alpha1-antitrypsin Portland (alpha1-PDX), ppFurin, or ppPACE4 but less potent toward overexpressed Furin. In conclusion, cleavages of the prosegment of PC5A at both Arg(116) and Arg(84) are required for PC5A cellular activity, and ppPC5 is a very potent but modestly selective cellular inhibitor of PC5A.     

The proprotein convertase PC5A and a metalloprotease are involved in the proteolytic processing of the neural adhesion molecule L1

The transmembrane and multidomain neural adhesion molecule L1 plays important functional roles in the developing and adult nervous system. L1 is proteolytically processed at two distinct sites within the extracellular domain, leading to the generation of different fragments. In this report, we present evidence that the proprotein convertase PC5A is the protease that cleaves L1 in the third fibronectin type III domain, whereas the proprotein convertases furin, PC1, PC2, PACE4, and PC7 are not effective in cleaving L1. Analysis of mutations revealed Arg(845) to be the site of cleavage generating the N-terminal 140-kDa fragment. This fragment was present in the hippocampus, which expresses PC5A, but was not detectable in the cerebellum, which does not express PC5A. The 140-kDa L1 fragment was found to be tightly associated with the full-length 200-kDa L1 molecule. The complex dissociated from the membrane upon cleavage by a protease acting at a more membrane-proximal site of full-length L1. This proteolytic cleavage was inhibited by the metalloprotease inhibitor GM 6001 and enhanced by a calmodulin inhibitor. L1-dependent neurite outgrowth of cerebellar neurons was inhibited by GM 6001, suggesting that proteolytic processing of L1 by a metalloprotease is involved in neurite outgrowth.     

N-glycosylation controls trafficking, zymogen activation and substrate processing of proprotein convertases PC1/3 and subtilisin kexin isozyme-1

The limited proteolysis of proteins by the proprotein convertases (PCs) is a common means of producing bioactive proteins or peptides. The PCs are associated with numerous human pathologies and their activity can be reduced through the use of specific inhibitors. Here, we demonstrate an alternative approach to inhibiting PCs by altering their N-glycosylation. Through site-directed mutagenesis, we show that the convertase PC1/3 contains two N-glycans, only one of which is critical for its prosegment cleavage. The exact structure of PC1/3 N-glycans does not significantly affect its zymogen activation within endocrine cells, but glycosylation of Asn(146) is critical. Processing of the PC1/3's substrate proopiomelanocortin (POMC) was used in a cell-based assay to screen a collection of 45 compounds structurally related to known glycosidase inhibitors. Two 5-thiomannose-containing disaccharide derivatives were discovered to block PC1/3 and POMC processing into the analgesic peptide β-endorphin. These compounds also reduced the zymogen activation of the convertase subtilisin kexin isozyme-1 (SKI-1), blocked the processing of its substrate the sterol regulatory element-binding protein SREBP-2 and altered its glycosylation. Thus, modification of PC glycosylation may also be a means of blocking their activity, an effect which, in the case of SKI-1, may be of possible therapeutic use since SREBP-2 regulates sterol levels including cholesterol biosynthesis and its metabolism.     

A systematic study of site-specific GalNAc-type O-glycosylation modulating proprotein convertase processing

Site-specific GalNAc-type O-glycosylation is emerging as an important co-regulator of proprotein convertase (PC) processing of proteins. PC processing is crucial in regulating many fundamental biological pathways and O-glycans in or immediately adjacent to processing sites may affect recognition and function of PCs. Thus, we previously demonstrated that deficiency in site-specific O-glycosylation in a PC site of the fibroblast growth factor, FGF23, resulted in marked reduction in secretion of active unprocessed FGF23, which cause familial tumoral calcinosis and hyperostosis hyperphosphatemia. GalNAc-type O-glycosylation is found on serine and threonine amino acids and up to 20 distinct polypeptide GalNAc transferases catalyze the first addition of GalNAc to proteins making this step the most complex and differentially regulated steps in protein glycosylation. There is no reliable prediction model for O-glycosylation especially of isolated sites, but serine and to a lesser extent threonine residues are frequently found adjacent to PC processing sites. In the present study we used in vitro enzyme assays and ex vivo cell models to systematically address the boundaries of the region within site-specific O-glycosylation affect PC processing. The results demonstrate that O-glycans within at least ±3 residues of the RXXR furin cleavage site may affect PC processing suggesting that site-specific O-glycosylation is a major co-regulator of PC processing.     

Intracellular trafficking and activation of the furin proprotein convertase: localization to the TGN and recycling from the cell surface.

Furin is a membrane-associated endoprotease that efficiently cleaves precursor proteins on the C-terminal side of the consensus sequence, Arg-X-Lys/Arg-Arg1, and has been proposed to catalyze these reactions in both exocytic and endocytic compartments. To study its biosynthesis and routing, a furin construct (designated fur/f) containing the FLAG epitope tag inserted on the C-terminal side of the enzyme's autoproteolytic maturation site was used. Introduction of the epitope tag had no effect on the expression, proteolytic maturation or activity of furin. Analysis of the localization of fur/f by immunofluorescence microscopy showed that its staining pattern largely overlapped with those of several Golgi-associated markers. Treatment of cells with brefeldin A caused the fur/f distribution to collapse around the microtubule organizing center, indicating that furin is concentrated in the trans-Golgi network (TGN). Immunoelectron microscopy showed unequivocally that furin resides in the TGN where it colocalized with TGN38. In agreement with its proposed activity in multiple compartments, antibody uptake studies showed that fur/f cycles between the cell surface and TGN. Furthermore, targeting to the TGN requires sequences in the cytoplasmic tail of the enzyme. Pulse-chase and immunofluorescence analyses demonstrated that proregion removal occurs in the endoplasmic reticulum and that cleavage may be required for exist from this compartment. Finally, we show that proregion removal is necessary but not sufficient for enzyme activation.     

Proteolytic processing of chromogranin A by the prohormone convertase PC2

The neuroendocrine secretory protein chromogranin A (CgA) is a precursor for various biologically active peptides. Several single and paired basic residues are present within its primary amino acid sequence comprising cleavage sites for prohormone convertases. In this study, SH-SY5Y human neuroblastoma cells were stably transfected with the prohormone convertase PC2 to analyse the proteolytic processing of endogenous chromogranin A and, in particular, the formation of the chromogranin-A-derived peptide GE-25. Our analyses revealed a significant change in the pattern of proteolytic conversion of chromogranin A in cells expressing PC2. Mock-transfected control cells contained mainly the intact chromogranin A molecule and hardly any shorter products were found. On the other hand, PC2-transfected cells showed extensive processing of chromogranin A, resulting in significantly lower amounts of the intact precursor and especially high levels of the free peptide GE-25.     

The proprotein convertase (PC) PCSK9 is inactivated by furin and/or PC5/6A: functional consequences of natural mutations and post-translational modifications

PCSK9 is the ninth member of the proprotein convertase (PC) family. Some of its natural mutations have been genetically associated with the development of a dominant form of familial hyper- or hypocholesterolemia. The exact mechanism of action of PCSK9 is not clear, although it is known to enhance the intracellular degradation of the low density lipoprotein (LDL) receptor in acidic compartments, likely the endosomes/lysosomes. We analyzed the post-translational modifications of PCSK9 and show that it is sulfated within its prosegment at Tyr38. We also examined the susceptibility of PCSK9 to proteolytic cleavage by the other members of the PC family. The data show that the natural gain-of-function mutations R218S, F216L, and D374Y associated with hypercholesterolemia result in total or partial loss of furin/PC5/6A processing at the motif RFHR218 downward arrow. In contrast, the loss-of-function mutations A443T and C679X lead either to the lack of trans-Golgi network/recycling endosome localization and an enhanced susceptibility to furin cleavage (A443T) or to the inability of PCSK9 to exit the endoplasmic reticulum (C679X). Furthermore, we report the presence of both native and furin-like cleaved forms of PCSK9 in circulating human plasma. Thus, we propose that PCSK9 levels are finely regulated by the basic amino acid convertases furin and PC5/6A. The latter may reduce the lifetime of this proteinase and its ability to degrade the cell-surface LDL receptor, thereby regulating the levels of circulating LDL cholesterol.     

Production of soluble matriptase by human cancer cell lines and cell surface activation of its zymogen by trypsin

The membrane-bound serine proteinase matriptase, which is often released from the plasma membrane of epithelial and carcinoma cells, has been implicated to play important roles in both physiological and pathological conditions. However, the regulatory mechanism of its activity is poorly understood. In the present study, we examined expression and activation state of soluble matriptase in 24 human cancer cell lines. Soluble matriptase was detected in the conditioned media from all of 5 colon and 4 breast carcinoma cell lines and 8 of 10 stomach carcinoma cell lines tested. Only two of five lung cancer cell lines released the matriptase protein into the culture media. Out of the five matriptase-negative cell lines, two cell lines expressed the matriptase mRNA. Among 24 cancer cell lines tested, 13 cell lines secreted trypsin in an active or latent form and all of them released matriptase. Most of the 24 cell lines released a latent, single-chain matriptase of 75 kDa as a major form, as well as low levels of complex forms of an activated two-chain enzyme with its specific inhibitor HAI-1. Thus, these soluble matriptases appeared to have little proteolytic activity. Treatment of stomach and colon cancer cell lines with epidermal growth factor stimulated the release of matripatase/HAI-1 complexes. In cancer cell lines secreting active trypsin, however, matriptase was released mostly as an inhibitor-free, two-chain active form. Trypsin seemed to activate the membrane-bound, latent matriptase on the cell surface. These results suggest that matriptase and trypsin cooperatively function for extracellular proteolysis.     

Proprotein convertase PC7 enhances the activation of the EGF receptor pathway through processing of the EGF precursor

Although the processing profile of the membrane-bound epidermal growth factor precursor (pro-EGF) is tissue-specific, it has not been investigated at the cellular level nor have the cognate proteinases been defined. Among the proprotein convertases (PCs), only the membrane-bound PC7, the most ancient and conserved basic amino acid-specific PC family member, induces the processing of pro-EGF into an ～115-kDa transmembrane form (EGF-115) at an unusual VHPR(290)↓A motif. Because site-directed mutagenesis revealed that Arg(290) is not critical, the generation of EGF-115 by PC7 is likely indirect. This was confirmed by testing a wide range of protease inhibitors, which revealed that the production of EGF-115 is most probably achieved via the activation by PC7 of a latent serine and/or cysteine protease(s). EGF-115 is more abundant at the cell surface than pro-EGF and is associated with a stronger EGF receptor (EGFR) activation, as evidenced by higher levels of phosphorylated ERK1/2. This suggests that the generation of EGF-115 represents a regulatory mechanism of juxtacrine EGFR activation. Thus, PC7 is distinct from the other PCs in its ability to enhance the activation of the cell surface EGFR.     

The cysteine-rich domain of the secreted proprotein convertases PC5A and PACE4 functions as a cell surface anchor and interacts with tissue inhibitors of metalloproteinases

The proprotein convertases PC5, PACE4 and furin contain a C-terminal cysteine-rich domain (CRD) of unknown function. We demonstrate that the CRD confers to PC5A and PACE4 properties to bind tissue inhibitors of metalloproteinases (TIMPs) and the cell surface. Confocal microscopy and biochemical analyses revealed that the CRD is essential for cell surface tethering of PC5A and PACE4 and that it colocalizes and coimmunoprecipitates with the full-length and C-terminal domain of TIMP-2. Surface-bound PC5A in TIMP-2 null fibroblasts was only observed upon coexpression with TIMP-2. In COS-1 cells, plasma membrane-associated PC5A can be displaced by heparin, suramin, or heparinases I and III and by competition with excess exogenous TIMP-2. Furthermore, PC5A and TIMP-2 are shown to be colocalized over the surface of enterocytes in the mouse duodenum and jejunum, as well as in liver sinusoids. In conclusion, the CRD of PC5A and PACE4 functions as a cell surface anchor favoring the processing of their cognate surface-anchored substrates, including endothelial lipase.     

Binding of BiP to the processing enzyme lymphoma proprotein convertase prevents aggregation, but slows down maturation

Lymphoma proprotein convertase (LPC) is a subtilisin-like serine protease of the mammalian proprotein convertase family. It is synthesized as an inactive precursor protein, and propeptide cleavage occurs via intramolecular cleavage in the endoplasmic reticulum. In contrast to other convertases like furin and proprotein convertase-1, propeptide cleavage occurs slowly. Also, both a glycosylated and an unglycosylated precursor are detected. Here we demonstrate that the unglycosylated precursor form of LPC is localized in the cytosol due to the absence of a signal peptide. Using a reducible cross-linker, we found that glycosylated pro-LPC is associated with the molecular chaperone BiP. In addition, we show that pro-LPC is prone to aggregation and forms large complexes linked via interchain disulfide bonds. BiP is associated mainly with non-aggregated pro-LPC and pro-LPC dimers and trimers, suggesting that BiP prevents aggregation. Overexpression of wild-type BiP or a dominant-negative BiP ATPase mutant resulted in reduced processing of pro-LPC. Taken together, these results suggest that binding of BiP to pro-LPC prevents aggregation, but results in slower maturation.     

Insertion of dibasic residues directs a constitutive protein to the regulated secretory pathway.

The mechanisms for sorting proteins to the regulated secretory pathway (RSP) remains poorly understood. We recently reported that dibasic sequences that are cleaved by pro-protein convertases (PCs) in pro-neurotensin also acted as sorting signal for the precursor. Here we addressed two questions regarding the role of dibasics as sorting signal: (i) Are dibasics sufficient to direct proteins to the RSP? (ii) Do they sort proteins by virtue of their interaction with PCs? The first question was studied by inserting dibasics in beta-lactamase, a constitutively secreted protein and comparing the regulated secretion of beta-lactamase to that of its mutant in transfected endocrine cells. The second question was investigated by comparing the regulated release of pro-neurotensin in PC12 cells that are devoid of PCs to that in PC1- and PC2-transfected PC12 cells. The data show that the mutant beta-lactamase was indeed targeted in part to the RSP and that pro-neurotensin was sorted to the RSP without the assistance of the PCs, thus indicating that dibasics can act as sorting signal by themselves independently of their interaction with PCs.     

A critical role for the carboxy terminal region of the proprotein convertase, PACE4A, in the regulation of its autocatalytic activation coupled with secretion.

PACE4A is a member of the mammalian subtilisin-like proprotein convertase family which is responsible for the proteolytic activation of precursors into their biologically active forms. Previously we reported that the maturation of proPACE4A occurs via a intramolecular autoactivation and cleavage of the propeptide is a rate-limiting step for the secretion of PACE4A (Nagahama et al., FEBS Lett. (1998) 434, 155-159). Although PACE4A is a putative secretory enzyme, it matures and is secreted much slower than general secretory proteins. In this study, we investigated the molecular mechanism underlying this slow maturation. The deletion of 25 amino acids at the carboxy terminus is sufficient for a marked acceleration in both the maturation and secretion of PACE4A. The carboxyl-truncated proPACE4A existed only as a monomer-sized form in the endoplasmic reticulum, whereas the wild type of proPACE4A existed in larger forms. Further, the fusion construct of yellow fluorescent protein and the carboxy-terminal sequence of PACE4A associated with the proPACE4A moiety and inhibited maturation. Thus the carboxy terminus of PACE4A functions as a potent autoinhibitor of its activation, resulting in the retention of proPACE4A in the endoplasmic reticulum. These findings indicate that PACE4A activity is highly controlled by a unique system at post-translational level.     

Latent transforming growth factor beta-binding proteins-2 and -3 inhibit the proprotein convertase 5/6A

The basic amino acid-specific proprotein convertase 5/6 (PC5/6) is an essential secretory protease, as knock-out mice die at birth and exhibit multiple homeotic transformation defects, including impaired bone morphogenesis and lung structure. Some of the observed defects were attributed to impaired processing of the TGFβ-like growth differentiating factor 11 precursor (proGdf11). In this work we present evidence that the latent TGFβ-binding proteins 2 and 3 (LTBP-2 and -3) inhibit the extracellular processing of proGdf11 by PC5/6A. This is partly due to the binding of LTBPs in the endoplasmic reticulum to the zymogen proPC5/6A, thus allowing the complex to exit the endoplasmic reticulum and be sequestered as an inactive zymogen in the extracellular matrix but not at the cell surface. This results in lower levels of PC5/6A in the media, without affecting those of PACE4, Furin, or a soluble form of PC7. The secreted soluble protease-specific activity of PC5/6A or a variant lacking the C-terminal Cys-rich domain (PC5/6-ΔCRD) is significantly decreased when co-expressed with LTBPs in cells. A similar enzymatic inhibition seems to apply to PACE4 and Furin. In situ hybridization analyses revealed extensive co-localization of PC5/6 and LTBP-3 mRNAs in mice at embryonic day 15.5 and post partum day 1. In conclusion, this is the first time that a zymogen of the proprotein convertases was shown to exit the endoplasmic reticulum in the presence of LTBPs, representing a potential novel mechanism for the regulation of PC5/6A activity, e.g. in tissues such as bone and lung where LTBP-3 and PC5/6 co-localize.     

Inhibitory activity and structural characterization of a C-terminal peptide fragment derived from the prosegment of the proprotein convertase PC7

Mammalian proprotein convertases (PCs) belong to the family of recently discovered serine proteases responsible for the processing of a large number of precursor proteins into their active forms. The enzymatic activities of the convertases have been implicated in a variety of disease states, such as cancer and infectious and inflammatory diseases. Like many other proteases, PCs are also synthesized as inactive proenzymes with N-terminal extensions as their prosegments. Here, we present the inhibitory activities of a number of "putative" interfacial peptide fragments derived from the proregion of PC7. We found that a peptide fragment corresponding to the C-terminal region (residues 81p-104p, or C24: E(1)-A-V-L-A-K-H-E-A-V-R-W-H-S-E-Q-R-L-L-K-R-A-K-R(24)) of the PC7 prosegment displays a strong inhibition (K(i) = 7 nM) of the PC7 enzyme comparable to that of the full-length (104 residue) prosegment. The same 24 residue peptide shows significantly populated helical conformations in an aqueous solution close to the physiological condition. Structure calculations driven by NOE distance restraints revealed a slightly kinked helical conformation for the entire peptide, characterized by many side-chain/side-chain interactions including those involving charged residues E8-R11-E15 and hydrophobic residues W12 and L19. These results suggest that the C-terminal region of the prosegment of PC7 may play a dominant role in conferring the inhibitory potency to the cognate enzyme and this strong inhibitory activity may be a direct consequence of the folded conformation of the peptide fragment in solution. We surmise that such a structure-function correlation for an inhibitory peptide could lead to the design and discovery of molecules mimicking the specific interactions of the PC prosegments for their cognate proteases.     

The crystal structure of the proprotein processing proteinase furin explains its stringent specificity

In eukaryotes, many essential secreted proteins and peptide hormones are excised from larger precursors by members of a class of calcium-dependent endoproteinases, the prohormone-proprotein convertases (PCs). Furin, the best-characterized member of the mammalian PC family, has essential functions in embryogenesis and homeostasis but is also implicated in various pathologies such as tumor metastasis, neurodegeneration and various bacterial and viral diseases caused by such pathogens as anthrax and pathogenic Ebola virus strains. Furin cleaves protein precursors with narrow specificity following basic Arg-Xaa-Lys/Arg-Arg-like motifs. The 2.6 A crystal structure of the decanoyl-Arg-Val-Lys-Arg-chloromethylketone (dec-RVKR-cmk)-inhibited mouse furin ectodomain, the first PC structure, reveals an eight-stranded jelly-roll P domain associated with the catalytic domain. Contoured surface loops shape the active site by cleft, thus explaining furin's stringent requirement for arginine at P1 and P4, and lysine at P2 sites by highly charge-complementary pockets. The structure also explains furin's preference for basic residues at P3, P5 and P6 sites. This structure will aid in the rational design of antiviral and antibacterial drugs.     

The C-terminus of prohormone convertase 2 is sufficient and necessary for Raft association and sorting to the regulated secretory pathway

Prohormone convertase 2 (PC2) is a member of the subtilisin family of proteases involved in prohormone maturation in the granules of the regulated secretory pathway (RSP). It has been suggested that targeting of this enzyme to the RSP is dependent on its association with lipid rafts in membranes at the trans-Golgi network. Here, we investigate the orientation of PC2 in granule membranes and the role of the C-terminus in sorting of the enzyme to the RSP. Molecular modeling and circular dichroism showed that this domain of PC2 forms an alpha-helix and inserts into artificial membranes. Furthermore, we show that the C-terminus of PC2 can be biotinylated at the C-terminus in intact chromaffin granules, indicating that it is a transmembrane protein. To determine if the PC2 C-terminus is necessary for raft association and sorting, we transfected a chimera of CPEDelta15 (carboxypeptidase E without the last 15 residues) and the last 25 residues of PC2 (CPEDelta15-PC2), and a truncated PC2 mutant with the last 6 residues deleted (PC2Delta6) into Neuro2a cells. Whereas CPEDelta15 was not raft-associated or sorted to the RSP, addition of the 25 residues of PC2 C-terminus to CPEDelta15 restored raft association and localization to the RSP granules, as determined by immunocytochemistry. Deletion of the last 6 residues of PC2 eliminated lipid raft association and sorting of PC2Delta6 to the RSP. These results showed that the PC2 C-terminus confers raft association and is sufficient and necessary for sorting PC2 to the RSP.