Proprotein convertase models based on the crystal structures of furin and kexin: explanation of their specificity

In eukaryotes, many secreted proteins and peptide hormones are excised from larger precursors by calcium-dependent serine proteinases, the proprotein/prohormone convertases (PCs). These PCs cleave their protein substrates very specifically following multiple basic residues. The seven mammalian PCs and their yeast orthologue kexin are multi-domain proteinases consisting of a subtilisin-related catalytic domain, a conserved P-domain and a variable, often cysteine-rich domain, which in some PCs is followed by an additional C-terminal trans-membrane domain and a short cytoplasmic domain. The recently published crystal structures of the soluble mouse furin and yeast kexin ectodomains have revealed the relative arrangement of catalytic and P domains, the exact domain fold and the detailed architecture of the substrate binding clefts. Based on these experimental structures, we now have modelled the structures of the other human/mouse PCs. According to topology and to structure-based sequence comparisons, these other PCs closely resemble furin, with PC4, PACE4 and PC5/6 being more similar, and PC1/3, PC2 and PC7 being less similar to furin. Except for PC1 and PC2, this order of similarity is valid for the catalytic as well as for the P domains, and is almost reversed using kexin as a reference molecule. A similar order results from the number and clustering of negative charges lining the non-prime subsites, explaining the gradually decreasing requirement for basic residues N-terminal to substrate cleavage sites. The preference of the different PCs for distinct substrates seems to be governed by overall charge compensation and matching of the detailed charge distribution pattern.     

Barley serine proteinase inhibitor 2-derived cyclic peptides as potent and selective inhibitors of convertases PC1/3 and furin

Proprotein convertases (PCs) are serine proteases containing a subtilisin-like catalytic domain that are involved in the conversion of hormone precursors into their active form. This study aims at designing small cyclic peptides that would specifically inhibit two members of this family of enzymes, namely, the neuroendocrine PC1/3 and the ubiquitously expressed furin. We studied peptide sequences related to the 18-residue loop identified as the active site of the 83 amino acid barley serine protease inhibitor 2 (BSPI-2). Peptides incorporating mutations at various positions in the sequence were synthesized on solid phase and purified by HPLC. Cyclization was achieved by the introduction of a disulfide bridge between the two Cys residues located at both the N- and C-terminal extremities. Peptides VIIA and VIIB incorporating P4Arg, P2Lys, P1Arg, and P2'Lys were the most potent inhibitors with K(i) around 4 microM for furin and around 0.5 microM for PC1/3. Whereas peptide VIIB behaved as a competitive inhibitor of furin, peptide VIIA acted as a noncompetitive one. However, all peptides were eventually cleaved after variable incubation times by PC1/3 or furin. To avoid this problem, we incorporated at the identified cleavage site a nonscissile aminomethylene bond (psi[CH(2)-NH]). Those pseudopeptides, in particular peptide VIID, were shown not to be cleaved and to inhibit potently furin. Conversely, they were not able to inhibit PC1/3 at all. Those results show the validity of this approach in designing new effective PC inhibitors showing a certain level of discrimination between PC1/3 and furin.     

Template-assisted rational design of peptide inhibitors of furin using the lysine fragment of the mung bean trypsin inhibitor

Highly active, small-molecule furin inhibitors are attractive drug candidates to fend off bacterial exotoxins and viral infection. Based on the 22-residue, active Lys fragment of the mung bean trypsin inhibitor, a series of furin inhibitors were designed and synthesized, and their inhibitory activity towards furin and kexin was evaluated using enzyme kinetic analysis. The most potent inhibitor, containing 16 amino acid residues with a Ki value of 2.45x10(-9) m for furin and of 5.60x10(-7) m for kexin, was designed with three incremental approaches. First, two nonessential Cys residues in the Lys fragment were deleted via a Cys-to-Ser mutation to minimize peptide misfolding. Second, residues in the reactive site of the inhibitor were replaced by the consensus substrate recognition sequence of furin, namely, Arg at P1, Lys at P2, Arg at P4 and Arg at P6. In addition, the P7 residue Asp was substituted with Ala to avoid possible electrostatic interference with furin inhibition. Finally, the extra N-terminal and C-terminal residues beyond the doubly conjugated disulfide loops were further truncated. However, all resultant synthetic peptides were found to be temporary inhibitors of furin and kexin during a prolonged incubation, with the scissile peptide bond between P1 and P1' being cleaved to different extents by the enzymes. To enhance proteolytic resistance, the P1' residue Ser was mutated to D-Ser or N-methyl-Ser. The N-methyl-Ser mutant gave rise to a Ki value of 4.70x10(-8) m for furin, and retained over 80% inhibitory activity even after a 3 h incubation with the enzyme. By contrast, the d-Ser mutant was resistant to cleavage, although its inhibitory activity against furin drastically decreased. Our findings identify a useful template for the design of potent, specific and stable peptide inhibitors of furin, shedding light on the molecular determinants that dictate the inhibition of furin and kexin.     

Activation of the Kexin from Schizosaccharomyces pombe Requires Internal Cleavage of Its Initially Cleaved Prosequence

Members of the kexin family of processing enzymes are responsible for the cleavage of many proproteins during their transport through the secretory pathway. The enzymes themselves are made as inactive precursors, and we investigated the activation process by studying the maturation of Krp1, a kexin from the fission yeast Schizosaccharomyces pombe. Using a cell-free translation-translocation system prepared from Xenopus eggs, we found that Krp1 is made as a preproprotein that loses the presequence during translocation into the endoplasmic reticulum. The prosequence is also rapidly cleaved in a reaction that is autocatalytic and probably intramolecular and is inhibited by disruption of the P domain. Prosequence cleavage normally occurs at Arg-Tyr-Lys-Arg102↓ (primary cleavage site) but can occur at Lys-Arg82 (internal cleavage site) and/or Trp-Arg99 when the basic residues are removed from the primary site. Cleavage of the prosequence is necessary but not sufficient for activation, and Krp1 is initially unable to process substrates presented in trans. Full activation is achieved after further incubation in the extract and is coincident with the addition of O-linked sugars. O glycosylation is not, however, essential for activity, and the crucial event appears to be cleavage of the initially cleaved prosequence at the internal site. Our results are consistent with a model in which the cleaved prosequence remains noncovalently associated with the catalytic domain and acts as an autoinhibitor of the enzyme. Inhibition is then relieved by a second (internal) cleavage of the inhibitory prosequence. Further support for this model is provided by our finding that overexpression of a Krp1 prosequence lacking a cleavable internal site dramatically reduced the growth rate of otherwise wild-type S. pombe cells, an effect that was not seen after overexpression of the normal, internally cleavable, prosequence or prosequences that lack the Lys-Arg102 residues.     

Furin: the prototype mammalian subtilisin-like proprotein-processing enzyme. Endoproteolytic cleavage at paired basic residues of proproteins of the eukaryotic secretory pathway.

Furin, the translational product of the recently discovered fur gene, appears to be the first known mammalian member of the subtilisin family of serine proteases and the first known mammalian proprotein-processing enzyme with cleavage selectivity for paired basic amino acid residues. Structurally and functionally, it resembles the prohormone-processing enzyme, kexin (EC 3.4.21.61), which is encoded by the KEX2 gene of yeast Saccharomyces cerevisiae. Most likely, furin is primarily involved in the processing of precursors of proteins that are secreted via the constitutive secretory pathway. Here, we review the discovery of the fur gene and describe the isolation of cDNA clones corresponding to human and mouse fur and to two fur-like genes of Drosophila melanogaster, Dfur1 and Dfur2. We also compare the structural organization of the various deduced furin proteins to that of yeast kexin, and of other members of the subtilisin family of serine proteases. Furthermore, the biosynthesis of biologically active human and mouse furin is evaluated. Finally, the cleavage specificity for paired basic amino acid residues of human and mouse furin is demonstrated by the correct processing of the precursor for von Willebrand factor.     

Enhancing the proteolytic maturation of human immunodeficiency virus type 1 envelope glycoproteins

In virus-infected cells, the envelope glycoprotein (Env) precursor, gp160, of human immunodeficiency virus type 1 is cleaved by cellular proteases into a fusion-competent gp120-gp41 heterodimer in which the two subunits are noncovalently associated. However, cleavage can be inefficient when recombinant Env is expressed at high levels, either as a full-length gp160 or as a soluble gp140 truncated immediately N-terminal to the transmembrane domain. We have explored several methods for obtaining fully cleaved Env for use as a vaccine antigen. We tested whether purified Env could be enzymatically digested with purified protease in vitro. Plasmin efficiently cleaved the Env precursor but also cut at a second site in gp120, most probably the V3 loop. In contrast, a soluble form of furin was specific for the gp120-gp41 cleavage site but cleaved inefficiently. Coexpression of Env with the full-length or soluble form of furin enhanced Env cleavage but also reduced Env expression. When the Env cleavage site (REKR) was mutated in order to see if its use by cellular proteases could be enhanced, several mutants were found to be processed more efficiently than the wild-type protein. The optimal cleavage site sequences were RRRRRR, RRRRKR, and RRRKKR. These mutations did not significantly alter the capacity of the Env protein to mediate fusion, so they have not radically perturbed Env structure. Furthermore, unlike that of wild-type Env, expression of the cleavage site mutants was not significantly reduced by furin coexpression. Coexpression of Env cleavage site mutants and furin is therefore a useful method for obtaining high-level expression of processed Env.     

Furin directly cleaves proMMP-2 in the trans-Golgi network resulting in a nonfunctioning proteinase

Proprotein convertases play an important role in tumorigenesis and invasiveness. Here, we report that a dibasic amino acid convertase, furin, directly cleaves proMMP-2 within the trans-Golgi network leading to an inactive form of matrix metalloproteinase-2 (MMP-2). Co-transfection of COS-1 cells with both proMMP-2 and furin cDNAs resulted in the cleavage of the N-terminal propeptide of proMMP-2. The molecular mass of cleaved MMP-2 (63 kDa), detected in both cell lysates and conditioned medium, is between the intermediate and fully activated forms of MMP-2 induced by membrane type 1-MMP. Furin-cleaved MMP-2 does not possess proteolytic activity as examined in a cell-free assay. Treatment of transfected cells with a furin inhibitor resulted in a dose-dependent inhibition of proMMP-2 cleavage; recombinant tissue inhibitor of metalloproteinase-2, which binds to the active site of membrane type 1-MMP, had no inhibitory effect. Site-directed mutagenesis of amino acids in the furin consensus recognition motif of proMMP-2(R69KPR72) prevented propeptide cleavage, thereby identifying the scissile bond and characterizing the basic amino acids required for cleavage. Other experimental observations were consistent with intracellular furin cleavage of proMMP-2 in the trans-Golgi network. The furin cleavage site in other proMMPs was examined. MMP-3, which contains the RXXR furin consensus sequence, was cleaved in furin co-transfected cells, whereas MMP-1, which lacks an RXXR consensus sequence, was not cleaved. In conclusion, we report the novel observation that furin can directly cleave the RXXR amino acid sequence in the propeptide domain of proMMP-2 leading to inactivation of the enzyme.     

The precursor to the germ cell-specific PCSK4 proteinase is inefficiently activated in transfected somatic cells: evidence of interaction with the BiP chaperone

Proprotein convertase subtilisin/kexin type 4 (PCSK4), also known as proprotein convertase 4 (PC4), is a serine endoproteinase primarily expressed in testicular germ cells and in sperm. Inactivation of its gene in mouse causes male infertility. From studies of the biosynthesis of PCSK3/furin, its closest relative, it has been inferred that PCSK4 is synthesised in the endoplasmic reticulum as a zymogen; that it is rapidly matured by autocatalytic cleavage between the prodomain and the catalytic domain; that the cleaved prodomain remains attached to the mature enzyme; and that the enzyme is finally activated by the removal of the prodomain peptides following a secondary cleavage within the prodomain. In this study, we used human embryonic kidney 293 (HEK293) cells to study the biosynthesis of rat or human PCSK4. Our results show that the bulk of PCSK4 remains as an intracellular zymogen, presumably trapped in the endoplasmic reticulum, where it interacts with the general molecular chaperone glucose-regulated protein 78/Immunoglobulin heavy-chain binding protein (GRP78/BiP). These data suggest that, unlike other members of the convertase family, proPCSK4 cannot efficiently self-activate in somatic cells. These cells may lack the intracellular environment and the interacting molecules specific to testicular germ cells where this enzyme is normally expressed.     

The crystal structure of an oxidatively stable subtilisin-like alkaline serine protease, KP-43, with a C-terminal beta-barrel domain

The crystal structure of an oxidatively stable subtilisin-like alkaline serine protease, KP-43 from Bacillus sp. KSM-KP43, with a C-terminal extension domain, was determined by the multiple isomorphous replacements method with anomalous scattering. The native form was refined to a crystallographic R factor of 0.134 (Rfree of 0.169) at 1.30-A resolution. KP-43 consists of two domains, a subtilisin-like alpha/beta domain and a C-terminal jelly roll beta-barrel domain. The topological architecture of the molecule is similar to that of kexin and furin, which belong to the subtilisin-like proprotein convertases, whereas the amino acid sequence and the binding orientation of the C-terminal beta-barrel domain both differ in each case. Since the C-terminal domains of subtilisin-like proprotein convertases are essential for folding themselves, the domain of KP-43 is also thought to play such a role. KP-43 is known to be an oxidation-resistant protease among the general subtilisin-like proteases. To investigate how KP-43 resists oxidizing reagents, the structure of oxidized KP-43 was also determined and refined to a crystallographic R factor of 0.142 (Rfree of 0.212) at 1.73-A resolution. The structure analysis revealed that Met-256, adjacent to catalytic Ser-255, was oxidized similarly to an equivalent residue in subtilisin BPN'. Although KP-43, as well as proteinase K and subtilisin Carlsberg, lose their hydrolyzing activity against synthetic peptides after oxidation treatment, all of them retain 70-80% activity against proteinaceous substrates. These results, as well as the beta-casein digestion pattern analysis, have indicated that the oxidation of the methionine adjacent to the catalytic serine is not a dominant modification but might alter the substrate specificities.     

Furin and its biological role

The survey deals with structure, properties and biological role of furin, the calcium-dependent serine endoprotease, which is expressed in all tissues and cell lines examined. It is the best-characterized representative of the mammalian subtilisin-like family of proprotein convertases, which is capable to cleave precursors of a wide variety of proteins, including hormones, growth factors, serum proteins, proteases of the blood-clotting system, matrix metalloproteinases, receptors, viral envelope glycoproteins, and bacterial exotoxins, and so on. The enzyme plays the essential role in embryogenesis, homeostasis; it is also involved in tumor metastasis, activation and virulence of many bacterial and viral pathogens and in neurodegenerative processes associated with Alzheimer's disease. Furin is a very specific enzyme: it recognizes the cleavage-site sequence Arg-Xaa-Lys/Arg-Arg and catalyzes the hydrolysis of the precursors, containing a pair of basic amino acids Arg-Arg or Lys-Arg. The enzyme is a multidomain protein which is initially synthesized as 100 kDa glycosylated profurin consisting of 794 amino acid residues (for human furin) and including a N-terminal signal peptide, propeptide, catalytic domain, possessing approximately 30% homology to subtilisin, a well-conserved P-domain, Cys-rich domain, transmembrane domain and cytoplasmic domain. The active site cleft of furin differs considerably from that of subtilisin with respect to the depth, shape and molecule charge. In furin it is a canyon-like groove with clusters of negatively charged residues along it. Furin inhibitors are rather promising therapeutic agents for treating furin-mediated diseases and bacterial infections. Most furin inhibitors belong to proteins or peptides. The protein-based inhibitors include both naturally occurring and bioengineered variants of protease inhibitors. The peptide-based inhibitors are represented by polyarginines, peptidyl chloromethyl ketones, aminomethyl ketones or ketomethylene pseudopeptides, isostere-containing cyclic peptides, short peptides derived from the prosegments of furin or al-PDX-related peptides. The nonpeptide inhibitors are natural products of the andrographolide family, certain metal complexes of pyridine derivatives and small molecules derived from 2.5-dideoxystreptamine. The furin inhibitors may be used not only as valuable tools for studying furin action, but also as therapeutic agents for furin-dependent diseases.     

Furin-cleaved Proprotein Convertase Subtilisin/Kexin Type 9 (PCSK9) Is Active and Modulates Low Density Lipoprotein Receptor and Serum Cholesterol Levels

Proprotein convertase subtilisin/kexin 9 (PCSK9) regulates plasma LDL cholesterol levels by regulating the degradation of LDL receptors. Another proprotein convertase, furin, cleaves PCSK9 at Arg²¹⁸-Gln²¹⁹ in the surface-exposed “218 loop.” This cleaved form circulates in blood along with the intact form, albeit at lower concentrations. To gain a better understanding of how cleavage affects PCSK9 function, we produced recombinant furin-cleaved PCSK9 using antibody Ab-3D5, which binds the intact but not the cleaved 218 loop. Using Ab-3D5, we also produced highly purified hepsin-cleaved PCSK9. Hepsin cleaves PCSK9 at Arg²¹⁸-Gln²¹⁹ more efficiently than furin but also cleaves at Arg²¹⁵-Phe²¹⁶. Further analysis by size exclusion chromatography and mass spectrometry indicated that furin and hepsin produced an internal cleavage in the 218 loop without the loss of the N-terminal segment (Ser¹⁵³–Arg²¹⁸), which remained attached to the catalytic domain. Both furin- and hepsin-cleaved PCSK9 bound to LDL receptor with only 2-fold reduced affinity compared with intact PCSK9. Moreover, they reduced LDL receptor levels in HepG2 cells and in mouse liver with only moderately lower activity than intact PCSK9, consistent with the binding data. Single injection into mice of furin-cleaved PCSK9 resulted in significantly increased serum cholesterol levels, approaching the increase by intact PCSK9. These findings indicate that circulating furin-cleaved PCSK9 is able to regulate LDL receptor and serum cholesterol levels, although somewhat less efficiently than intact PCSK9. Therapeutic anti-PCSK9 approaches that neutralize both forms should be the most effective in preserving LDL receptors and in lowering plasma LDL cholesterol.     

Purification and characterization of furin, a Kex2-like processing endoprotease, produced in Chinese hamster ovary cells.

Furin, a mammalian homolog of the yeast Kex2 protease, is associated with Golgi membranes and is involved in cleavage of precursor proteins at sites marked by the Arg-X-Lys/Arg-Arg (RXK/RR) motif. We have recently shown that a furin mutant lacking the transmembrane domain can be secreted from cDNA-transfected cells with proteolytic activity for the fluorogenic peptide t-butoxycarbonyl-Arg-Val-Arg-Arg-4-methylcoumarin-7- amide. In this study, we purified and characterized the recombinant furin from the conditioned medium of these cells. Furin was purified as a mixture of 83- and 81-kDa forms and a 96-kDa form. The differences in molecular mass were not due to differences in molecular mass were not due to differences in glycosylation. Moreover, all forms had the same NH2-terminal sequence beginning at the residue after the Arg-Ala-Lys-Arg sequence. These data suggest that the three different forms may be produced by differential COOH-terminal processing of a furin molecule and that mature furin may be autocatalytically produced. Both enzyme preparations showed a pH optimum at 7.0, required Ca2+ for the activity, and showed essentially the same inhibitor profile. These properties resembled those of the Kex2 protease. Both preparations efficiently cleaved fluorogenic peptides with an RXK/RR sequence and moderately cleaved a peptide with an RXXR sequence, but did not cleave dibasic peptides. The sequence requirements determined in vitro were compatible with those determined by expression studies in cultured cells. These data unequivocally demonstrate that furin is an endogenous cellular protease responsible for cleavage of precursor proteins mainly at RXK/RR sites.     

Structural Basis for the Kexin-like Serine Protease from Aeromonas sobria as Sepsis-causing Factor

The anaerobic bacterium Aeromonas sobria is known to cause potentially lethal septic shock. We recently proposed that A. sobria serine protease (ASP) is a sepsis-related factor that induces vascular leakage, reductions in blood pressure via kinin release, and clotting via activation of prothrombin. ASP preferentially cleaves peptide bonds that follow dibasic amino acid residues, as do Kex2 (Saccharomyces cerevisiae serine protease) and furin, which are representative kexin family proteases. Here, we revealed the crystal structure of ASP at 1.65 Å resolution using the multiple isomorphous replacement method with anomalous scattering. Although the overall structure of ASP resembles that of Kex2, it has a unique extra occluding region close to its active site. Moreover, we found that a nicked ASP variant is cleaved within the occluding region. Nicked ASP shows a greater ability to cleave small peptide substrates than the native enzyme. On the other hand, the cleavage pattern for prekallikrein differs from that of ASP, suggesting the occluding region is important for substrate recognition. The extra occluding region of ASP is unique and could serve as a useful target to facilitate development of novel antisepsis drugs.Aeromonas species are Gram-negative facultative anaerobic bacteria found ubiquitously in a variety of aquatic environments (1). The main syndrome caused by infection with Aeromonas is gastroenteritis (2, 3), although, in severe cases, sepsis is induced as a deuteropathy (4, 5). Two species, Aeromonas hydrophila and Aeromonas sobria, are associated with human disease (6, 7). Factors thought to play important roles in the pathogenesis include fimbrial and afimbrial adherence factors; a variety of exotoxins, including hemolysin, cytotonic enterotoxin, heat-stable enterotoxin, and heat-labile enterotoxin; and several secreted proteases and lipases (8–12). Recently, we purified a 65-kDa A. sobria serine protease (ASP)² from the culture supernatant of A. sobria and found that the enzyme induces vascular leakage, reduces blood pressure through activation of the kallikrein/kinin system (13), promotes human plasma coagulation through activation of prothrombin (14), and causes the formation of pus and edema through the action of anaphylatoxin C5a (15). From these observations, we concluded that ASP mediates the induction of disseminated intravascular coagulation through α-thrombin production, which is a common and deadly consequence of sepsis (14).ASP is a kexin-like serine protease belonging to the subtilisin family (subtilases) (16), which can be subdivided into six groups: the subtilisins, thermitases, proteinase K, lantibiotic peptidases, pyrolysins, and kexins. Among the kexins, the first identified was Kex2 (17), which is expressed by Saccharomyces cerevisiae; subsequently, the mammalian kexin-like protease furin was identified (18). Furin processes the precursors of biologically active peptides and proteins via limited proteolysis at paired basic amino acids to generate biologically active molecules (19). The domain structures of kexins and furins include a signal peptide, a partially conserved propeptide, a highly conserved subtilisin-like domain containing the characteristic Asp, His, and Ser catalytic residues, a relatively well conserved region called the P-domain, and a transmembrane domain followed by a cytoplasmic tail (20–22). Kex2 usually shows a high degree of specificity for cleavage after dibasic (P2-P1: Lys-Arg or Arg-Arg) or multiple basic residues (23). Among the kexins, which are nearly all eukaryotic and share a substantial degree of sequence homology (>40%), ASP is positioned as the most distant member of this family on the phylogenetic tree (16). The domain structure of ASP consists of the propeptide, the catalytic subtilisin-like domain, and the P-domain. For maturation of ASP, the first 24 residues of the propeptide are cleaved, and although a functional P-domain is reportedly necessary for maturation of the subtilisin domain in kexins (24, 25), the function of the P-domain in ASP remains unknown. Notably, in an earlier study of ASP expression, we found that for the maturation of the ASP subtilisin domain, another gene product, encoded by open reading frame 2, is required to serve as a chaperone in the periplasmic space (26).Here, we report the crystal structure of wild-type ASP as a sepsis-related factor at 1.65 Å resolution. We found that ASP has a unique occluding region at the active site within the subtilisin domain and that a different form of ASP that is cleaved within the occluding region shows a different pattern of proteolysis from the native enzyme. Our findings suggested that the novel occluding region plays an important role in determining substrate specificity and that because it is unique, it could facilitate development of novel antisepsis drugs that have no inhibitory effect on furin-like human proteases.     

The carboxy‐terminal tail of Aeromonas sobria serine protease is associated with the chaperone

ASP is the only bacterial protease in the kexin group of the subtilisin family. Previous studies have revealed that the ORF2 protein encoded at the 3′ end of the asp operon is required for ASP to change from a nascent form into an active form in the periplasm. However, the mechanism by which ORF2 makes contact and interacts with ASP in the maturation process remains unknown. The present study examined the effect of mutations in the carboxy‐terminal region of ASP on the ASP maturation process. Both deletion‐mutation and amino acid‐substitution studies have demonstrated that the histidine residue at position 595 (His‐595), the sixth residue from the carboxyl terminus of ASP, is highly involved in the generation of active ASP molecules. An analysis by pull‐down assay revealed that mutation at His‐595 reduces the efficacy of nascent ASP to transition into active ASP by reducing the ability of ASP to make contact and interact with ORF2. Thus, it appears likely that nascent ASP in the periplasm interacts with ORF2 via the carboxy‐terminal region, and His‐595 of ASP appears to be an indispensable residue in this interaction.     

Interdomain hydrolysis of a truncated Pseudomonas exotoxin by the human immunodeficiency virus-1 protease

The specificity of HIV-1 (human immunodeficiency virus-1) protease has been evaluated relative to its ability to cleave the three-domain Pseudomonas exotoxin (PE66) and related proteins in which the first domain has been deleted or replaced by a segment of CD4. Native PE66 is not hydrolyzed by the HIV-1 protease. However, removal of its first domain produces a molecule which is an excellent substrate for the enzyme. The major site of cleavage in this truncated exotoxin, called LysPE40, occurs in a segment that connects its two major domains, the translocation domain (II), and the ADP-ribosyltransferase (III). This interdomain region contains the sequence ...Asn-Tyr-Pro-Thr... which is similar to that surrounding the scissile Tyr-Pro bond in the gag precursor polyprotein, a natural substrate of the HIV-1 protease. Nevertheless, it is not this sequence that is recognized and cleaved by the enzyme, but one 6 residues away, ...Ala-Leu-Leu-Glu... in which the Leu-Leu peptide bond is hydrolyzed. A second, slower cleavage takes place at the Leu-Ala bond 3 residues in from the NH2 terminus of LysPE40. When domain I of PE66 is replaced by a segment comprising the first two domains of CD4, the resulting chimeric protein is hydrolyzed at the same Leu-Leu bond by HIV-1 protease. Enzyme activities toward synthetic peptides modeled after the sequences defined above in LysPE40 are in complete accord, relative to specificity, kinetics, and pH optimum, with results obtained in the hydrolysis of the parent protein. These findings demonstrate that ideas concerning the specificity of the HIV-1 protease that are based solely upon its processing of natural viral polyproteins can be expanded by evaluation of other multidomain proteins as substrates. Moreover, it would appear that it is not a particular conformation, but sequence and accessibility that play the dominant role in defining sites in a protein substrate that are susceptible to hydrolysis by the enzyme.     

The role of eukaryotic subtilisin-like endoproteases for the activation of human immunodeficiency virus glycoproteins in natural host cells.

Proteolytic activation of the precursor envelope glycoproteins gp160 of human immunodeficiency virus type 1 (HIV-1) and gp140 of HIV-2, a prerequisite for viral infection, results in the formation of gp120/gp41 and gp125/gp36, respectively. Cleavage is mediated by cellular proteases. Furin, a member of the eukaryotic subtilisin family, has been shown to be an activating protease for HIV. Here, we compared the presence of furin and other mammalian subtilisins in lymphatic cells and tissues. Northern blot analyses revealed that furin and the recently discovered protease LPC/PC7 were the only subtilisin-like enzymes transcribed in such cells. Furin was identified as an enzymatically active endoprotease present in different lymphocytic, as well as monocytic, cell lines. When expressed from vaccinia virus vectors, the proprotein convertases were correctly processed, transported, and secreted into the media and enzymatically active. Coexpression of different subtilisins with the HIV envelope precursors revealed that furin and LPC/PC7 are able to cleave HIV-1 gp160. Moreover, both enzymes proteolytically processed the envelope precursor of HIV-2. gp140 was also cleaved to some extent by PC1, which is not, however, present in lymphatic cells. Furin- and LPC/PC7-catalyzed cleavage of HIV-1 gp160 resulted in biologically active envelope protein. In conclusion, among the known members of the subtilisin family, only furin and LPC/PC7 fulfill the requirements of a protease responsible for in vivo activation of HIV envelope glycoproteins.     

A furin-like convertase mediates propeptide cleavage of BACE, the Alzheimer's beta -secretase

The novel transmembrane aspartic protease BACE (for Beta-site APP Cleaving Enzyme) is the beta-secretase that cleaves amyloid precursor protein to initiate beta-amyloid formation. As such, BACE is a prime therapeutic target for the treatment of Alzheimer's disease. BACE, like other aspartic proteases, has a propeptide domain that is removed to form the mature enzyme. BACE propeptide cleavage occurs at the sequence RLPR downward arrowE, a potential furin recognition motif. Here, we explore the role of furin in BACE propeptide domain processing. BACE propeptide cleavage in cells does not appear to be autocatalytic, since an inactive D93A mutant of BACE is still cleaved appropriately. BACE and furin co-localize within the Golgi apparatus, and propeptide cleavage is inhibited by brefeldin A and monensin, drugs that disrupt trafficking through the Golgi. Treatment of cells with the calcium ionophore, leading to inhibition of calcium-dependent proteases including furin, or transfection with the alpha(1)-antitrypsin variant alpha(1)-PDX, a potent furin inhibitor, dramatically reduces cleavage of the BACE propeptide. Moreover, the BACE propeptide is not processed in the furin-deficient LoVo cell line; however, processing is restored upon furin transfection. Finally, in vitro digestion of recombinant soluble BACE with recombinant furin results in complete cleavage only at the established E46 site. Taken together, our results strongly suggest that furin, or a furin-like proprotein convertase, is responsible for cleaving the BACE propeptide domain to form the mature enzyme.     

ADAMTS1 cleaves aggrecan at multiple sites and is differentially inhibited by metalloproteinase inhibitors

ADAMTS1 is a secreted protein that belongs to the recently described ADAMTS (a disintegrin and metalloprotease with thrombospondin repeats) family of proteases. Evaluation of ADAMTS1 catalytic activity on a panel of extracellular matrix proteins showed a restrictive substrate specificity which includes some proteoglycans. Our results demonstrated that human ADAMTS1 cleaves aggrecan at a previously shown site by its mouse homolog, but we have also identified additional cleavage sites that ultimately confirm the classification of this protease as an 'aggrecanase'. Specificity of ADAMTS1 activity was further verified when a point mutation in the zinc-binding domain abolished its catalytic effects, and latency conferred by the prodomain was also demonstrated using a furin cleavage site mutant. Suppression of ADAMTS1 activity was accomplished with a specific monoclonal antibody and some metalloprotease inhibitors, including tissue inhibitor of metalloproteinases 2 and 3. Finally, we developed an activity assay using an artificial peptide substrate based on the interglobular domain cleavage site (E(373)-A) of rat aggrecan.     

Cloning and functional expression of Dfurin2, a subtilisin-like proprotein processing enzyme of Drosophila melanogaster with multiple repeats of a cysteine motif.

Production of a variety of regulatory eukaryotic proteins, such as growth factors and polypeptide hormones, often involves endoproteolytic processing of proproteins at cleavage sites consisting of paired basic residues. The first known mammalian proprotein processing enzyme with such specificity is the human fur gene product furin. Structurally and functionally, furin is related to the subtilisin-like serine endoprotease kexin (EC 3.4.21.61) of yeast Saccharomyces cerevisiae; unlike kexin, it contains a cysteine-rich region with an unknown function. Here, we describe cloning and sequencing of a 5.8-kbp cDNA of the Dfur2 gene, a fur-like gene of Drosophila melanogaster, which we found expressed during various stages of development. This Dfur2 cDNA has an open reading frame for a 1680-residue protein, called Dfurin2. Dfurin2 contains similar protein domains as mammalian furin, however, it has an extended amino-terminal region and its cysteine-rich region is much larger than that of mammalian furin. Because of this latter phenomenon, we were able to identify a particular cysteine motif that was repeated multiple times in Dfurin2 but present only twice in mammalian furin. Furthermore, we show that Dfur2 encodes an endoproteolytic enzyme with specificity for paired basic amino acid residues as, in cotransfection experiments, correct cleavage was demonstrated of the precursor of the von Willebrand factor but not of a cleavage mutant. Finally, Dfur2 was mapped to region 14C of the X chromosome of D. melanogaster.