Intracellular proteolysis of pancreatic zymogens.

Activation of pancreatic digestive zymogens within the pancreatic acinar cell may be an early event in the development of pancreatitis. To detect such activation, an immunoblot assay has been developed that measures the relative amounts of inactive zymogens and their respective active enzyme forms. Using this assay, high doses of cholecystokinin or carbachol were found to stimulate the intracellular conversion of at least three zymogens (procarboxypeptidase A1, procarboxypeptidase B, and chymotrypsinogen 2) to their active forms. Thus, this conversion may be a generalized phenomenon of pancreatic zymogens. The conversion is detected within ten minutes of treatment and is not associated with changes in acinar cell morphology; it has been predicted that the lysosomal thiol protease, cathepsin B, may initiate this conversion. Small amounts of cathepsin B are found in the secretory pathway, and cathepsin B can activate trypsinogen in vitro; however, exposure of acini to a thiol protease inhibitor (E64) did not block this conversion. Conversion was inhibited by the serine protease inhibitor, benzamidine, and by raising the intracellular pH, using chloroquine or monensin. This limited proteolytic conversion appears to require a low pH compartment and a serine protease activity. After long periods of treatment (60 minutes), the amounts of the active enzyme forms began to decrease; this observation suggested that the active enzyme forms were being degraded. Treatment of acini with E64 reduced this late decrease in active enzyme forms, suggesting that thiol proteases, including lysosomal hydrolases, may be involved in the degradation of the active enzyme forms. These findings indicate that pathways for zymogen activation as well as degradation of active enzyme forms are present within the pancreatic acinar cell.     

Differential effects of inhibitors on the gamma-secretase complex. Mechanistic implications

Gamma-secretase is a protease complex of four integral membrane proteins, with presenilin (PS) as the apparent catalytic component, and this enzyme processes the transmembrane domains of a variety of substrates, including the amyloid beta-protein precursor and the Notch receptor. Here we explore the mechanisms of structurally diverse gamma-secretase inhibitors by examining their ability to displace an active site-directed photoprobe from PS heterodimers. Most gamma-secretase inhibitors, including a potent inhibitor of the PS-like signal peptide peptidase, blocked the photoprobe from binding to PS1, indicating that these compounds either bind directly to the active site or alter it through an allosteric interaction. Conversely, some reported inhibitors failed to displace this interaction, demonstrating that these compounds do not interfere with the protease by affecting its active site. Differential effects of the inhibitors with respect to photoprobe displacement and in cell-based and cell-free assays suggest that these compounds are important mechanistic tools for deciphering the workings of this intramembrane-cleaving protease complex and its similarity to other polytopic aspartyl proteases.     

Human BACE forms dimers and colocalizes with APP

Beta-site APP-cleaving enzyme (BACE) is a membrane-bound aspartyl protease with no strict primary preference for cleavage. The molecular mechanisms that link the gamma-secretase multicomponent amyloid precursor protein (APP) processing complex to biochemical properties of BACE generating the N terminus of the amyloid beta-peptide have not, as yet, been identified. We found that in human brain tissue, BACE occurred as a dimer. The overall stability of the BACE homodimer was based on intermolecular interactions that were not affected by high salt, nonionic detergents or reducing conditions. BACE homodimers could only partially be separated even under strong denaturing conditions and revealed dramatic differences in the surface charge distribution compared with the monomer. In contrast, the soluble ectodomain of truncated BACE revealed a seemingly lower avidity to the prototypic aspartate protease inhibitor pepstatin and exclusively occurred in the monomeric form. Immunocytochemical studies colocalized APP and BACE in the plasma membrane of cells expressing endogenous levels of BACE and overexpressing APP. In cells that were cotransfected with APP and a putative active site D289A mutant of BACE, colocalization persisted. Remaining enzyme activity was found to be attributable to the mutant protease. Accordingly, inactivation of the carboxyl-terminal active site motif of BACE without an impairment of overall enzyme activity suggests that the enzyme may act as a dimer. Thus, homodimerization of BACE may help the enzyme to acquire specific mechanisms to associate with its substrates to exert catalytic activity.     

Generation of biologically active interleukin-1beta by meprin B

Interleukin-1beta (IL-1beta) is a proinflammatory cytokine that is synthesized as an inactive precursor molecule that must be proteolytically processed to generate the biologically active form. Maturation of the precursor is primarily performed by caspase-1, an intracellular cysteine protease; however, processing by other proteases has been described. Meprins are cell surface and secreted metalloproteases expressed by renal and intestinal brush-border membranes, leukocytes, and cancer cells. In this study we show that purified recombinant meprin B can process the interleukin-1beta precursor to a biologically active form. Amino-terminal sequencing and mass spectrometry analysis of the product of digestion by activated meprin B determined that proteolytic cleavage resulted in an additional six amino acids relative to the site utilized by caspase-1. The biological activity of the meprin B-cleaved cytokine was confirmed by measuring the proliferative response of helper T-cells. These results suggest that meprin may play an important role in activation of this proinflammatory cytokine in various pathophysiological conditions.     

Prion domains: sequences, structures and interactions

Mammalian and most fungal infectious proteins (also known as prions) are self-propagating amyloid, a filamentous beta-sheet structure. A prion domain determines the infectious properties of a protein by forming the core of the amyloid. We compare the properties of known prion domains and their interactions with the remainder of the protein and with chaperones. Ure2p and Sup35p, two yeast prion proteins, can still form prions when the prion domains are shuffled, indicating a parallel in-register beta-sheet structure.     

Design and synthesis of irreversible inhibitors of foot-and-mouth disease virus 3C protease

Foot-and-mouth disease virus (FMDV) causes a highly infectious and economically devastating disease of livestock. The FMDV genome is translated as a single polypeptide precursor that is cleaved into functional proteins predominantly by the highly conserved viral 3C protease, making this enzyme an attractive target for antiviral drugs. A peptide corresponding to an optimal substrate has been modified at the C-terminus, by the addition of a warhead, to produce irreversible inhibitors that react as Michael acceptors with the enzyme active site. Further investigation highlighted key structural determinants for inhibition, with a positively charged P2 being particularly important for potency.     

Characteristics, isolation and role in the infectious process of Pseudomonas aeruginosa protease

Pseudomonas aeruginosa produces the extracellular enzyme protease, which plays an important role in the development of the infectious process caused by this microorganism. Protease is produced in three types, I, II and III, with protease II being responsible for 75% of the total proteolytic activity of protease. The molecular mass of protease II has been determined by different methods; the values obtained are 23000 and 39500. This discrepancy may be associated with an autodigestion of the enzyme or with the presence in the periplasm of its producer of a nonactive precursor whose activation may lead to a change in the molecular mass. Pseudomonas aeruginosa protease is capable of cleaving high-molecular proteins into low-molecular ones, which are taken up by the microbial cell and serve as a source of nutrition. When injected into the bloodstream of animals, purified protease produces haemorrhagic lesions in internal organs; its subcutaneous injection provokes haemorrhage in the skin and subcutaneous tissues. Manifestation of high P. aeruginosa virulence on a model of burnt mouse skin requires that not only exotoxin A but also protease be produced. The protease is immunogenic and has, in toxoid form, been used experimentally in a multicomponent vaccine.     

Kosmotropic anions promote conversion of recombinant prion protein into a PrPSc-like misfolded form

Prions are self-propagating proteins involved in transmissible spongiform encephalopaties in mammals. An aberrant conformation with amyloid-like features of a cell surface protein, termed prion protein (PrP), is thought to be the essential component of the infectious particle, though accessory co-factor molecules such as lipids and nucleotides may be involved. The cellular co-factors and environmental conditions implicated in PrP misfolding are not completely understood. To address this issue, several studies have been done inducing misfolding of recombinant PrP (recPrP) into classical amyloid structures using partially denaturing conditions. In this work, we report that misfolding of recPrP into PrP(Sc)-like aggregates can be induced by simply incubating the protein in the presence of kosmotropic salts at concentrations that are known to retain or increase the stability of the protein. We used a simple experimental reaction (protein, buffer and salts) submitted to agitation/incubation cycles at physiological temperature and pH. The formation of protease resistant-recPrP was time and salt-concentration dependent and required the presence of kosmotropic anions such as F(-) or SO(4)(-2). The molecular weights of the protease resistant recPrP fragments are reminiscent of those found in degradation assays of bona fide PrP(Sc). The aggregates also exhibited PrP(Sc)-like ultrastructural features including rod-shape morphology under electron microscope, high beta-sheet content and thioflavin-T positive signal. The formation of recPrP aggregates with PrP(Sc) biochemical features under conditions closer to physiological in the absence of organic co-factor molecules provides a simple setup that may prove helpful to understand the molecular mechanism of PrP misfolding.     

Nuclear cysteine-protease involved in male chromatin remodeling after fertilization is ubiquitously distributed during sea urchin development

Previously we have identified a cysteine-protease involved in male chromatin remodeling which segregates into the nuclei of the two blastomeres at the first cleavage division. Here we have investigated the fate of this protease during early embryogenesis by immunodetecting this protein with antibodies elicited against its N-terminal sequence. As shown in this report, the major 60 kDa active form of this protease was found to be present in the extracts of chromosomal proteins obtained from all developmental stages analyzed. In morula and gastrula the 70 kDa inactive precursor, which corresponds to the major form of the zymogen found in unfertilized eggs, was detected. In plutei larvas, the major 60 kDa form of this enzyme was found together with a higher molecular weight precursor (90 kDa) which is consistent with the less abundant zymogen primarily detected in unfertilized eggs. As reported here, either the active protease or its zymogens were visualized in most of the embryonic territories indicating that this enzyme lacks a specific pattern of spatial-temporal developmental segregation. Taken together our results indicate that this protease persists in the embryo and is ubiquitously distributed up to larval stages of development, either as an active enzyme and/or as an inactive precursor. These results suggest that this enzyme may display yet unknown functions during embryonic development that complement its role in male chromatin remodeling after fertilization.     

The gamma-secretase complex: membrane-embedded proteolytic ensemble

Gamma-secretase is responsible for the proteolytic processing of a variety of membrane-associated fragments derived from type I integral membrane proteins, including the amyloid beta-protein precursor and the Notch receptor. This enzyme is composed of four different integral membrane proteins: presenilin, nicastrin, Aph-1, and Pen-2. During assembly and maturation of the protease complex, presenilin is endoproteolyzed into two subunits, each of which contributes one aspartate to the active site of an aspartyl protease. Substrate apparently interacts with an initial docking site before passing in whole or in part between the two presenilin subunits to the internal water-containing active site. The ectodomain of nicastrin also interacts with the N-terminus of the substrate as an essential step in substrate recognition and processing. Sites for allosteric regulation on the protease complex allow selective inhibition or modulation of APP processing without interfering with Notch signaling, and such selective agents may represent promising leads for the development of Alzheimer's disease therapeutics. Elucidation of detailed structural features of gamma-secretase and other membrane-embedded proteases is the next frontier in understanding how these enzymes carry out hydrolysis within the lipid bilayer.     

Prions of fungi: inherited structures and biological roles

The term 'prion' means an infectious protein that does not need an accompanying nucleic acid. There are six fungal prions, including four self-propagating amyloids and two enzymes that are necessary to activate their inactive precursors. Here we explore the scope of the prion phenomenon, the biological and evolutionary roles of prions, the structural basis of the amyloid prions and the prominent role of chaperones (proteins that affect the folding of other proteins) and other cellular components in prion generation and propagation.     

Active gamma-secretase complexes contain only one of each component

Gamma-secretase is an intramembrane aspartyl protease complex that cleaves type I integral membrane proteins, including the amyloid beta-protein precursor and the Notch receptor, and is composed of presenilin, Pen-2, nicastrin, and Aph-1. Although all four of these membrane proteins are essential for assembly and activity, the stoichiometry of the complex is unknown, with the number of presenilin molecules present being especially controversial. Here we analyze functional gamma-secretase complexes, isolated by immunoprecipitation from solubilized membrane fractions and able to produce amyloid beta-peptides and amyloid beta-protein precursor intracellular domain. We show that the active isolated protease contains only one presenilin per complex, which excludes certain models of the active site that require aspartate dyads formed between two presenilin molecules. We also quantified components in the isolated complexes by Western blot using protein standards and found that the amounts of Pen-2 and nicastrin were the same as that of presenilin. Moreover, we found that one Aph-1 was not co-immunoprecipitated with another in active complexes, evidence that Aph-1 is likewise present as a monomer. Taken together, these results demonstrate that the stoichiometry of gamma-components presenilin:Pen-2:nicastrin:Aph-1 is 1:1:1:1.     

Identification of beta-secretase-like activity using a mass spectrometry-based assay system

We describe an assay system for the identification of site-specific proteases. The assay is based on a protein substrate that is immobilized on ceramic beads. After incubation with cell homogenates, the beads are washed and digested with endoproteinase Lys-C to liberate a defined set of peptides. The peptide fragments are identified by mass spectrometry. The assay was used to screen for beta-secretase, the protease that cleaves amyloid precursor protein (APP) at the beta-site. Cathepsin D was identified as the enzyme responsible for beta-secretase-like activity in two cell lines. Subsequent analysis of the related aspartic protease, cathepsin E, revealed almost identical cleavage specificity. Both enzymes are efficient in cleaving Swedish mutant APP at the beta-site but show almost no reactivity with wild-type APP. Treatment of cell lines with pepstatin inhibited the production of amyloid peptide (Abeta) when they were transfected with a construct bearing the Swedish APP mutant. However, when the cells were transfected with wild-type APP, the generation of Abeta was increased. This suggests that more than one enzyme is capable of generating Abeta in vivo and that an aspartic protease is involved in the processing of Swedish mutant APP.     

Structural Studies of Truncated Forms of the Prion Protein PrP

Prions are proteins that adopt self-propagating aberrant folds. The self-propagating properties of prions are a direct consequence of their distinct structures, making the understanding of these structures and their biophysical interactions fundamental to understanding prions and their related diseases. The insolubility and inherent disorder of prions have made their structures difficult to study, particularly in the case of the infectious form of the mammalian prion protein PrP. Many investigators have therefore preferred to work with peptide fragments of PrP, suggesting that these peptides might serve as structural and functional models for biologically active prions. We have used x-ray fiber diffraction to compare a series of different-sized fragments of PrP, to determine the structural commonalities among the fragments and the biologically active, self-propagating prions. Although all of the peptides studied adopted amyloid conformations, only the larger fragments demonstrated a degree of structural complexity approaching that of PrP. Even these larger fragments did not adopt the prion structure itself with detailed fidelity, and in some cases their structures were radically different from that of pathogenic PrP^Sc.     

BAG-1M is up-regulated in hippocampus of Alzheimer's disease patients and associates with tau and APP proteins

The accumulation of tau and amyloid beta proteins is the major molecular pathology of Alzheimer's disease (AD). The mechanisms leading to the accumulation of these proteins are not completely clear. Hsc-70/Hsp-70, a chaperone protein, has been shown to bind both these proteins and regulate their degradation. We have previously shown that the co-chaperone protein BAG-1 can inhibit the degradation of tau by forming a complex with Hsc-70 and tau. In this current work, we show that there is an increase in the BAG-1M isoform in the hippocampus of AD patients. In addition, BAG-1 binds to both tau and amyloid precursor protein physically, and is found highly expressed in the same neurons that contain intracellular tau or amyloid in hippocampal sections from AD patients. Over-expression of BAG-1M in cell culture also induced an increase in both tau and amyloid precursor protein levels. In conclusion, we report a specific increase of BAG-1M in human AD patients, which is both physically and functionally associated to the two major molecular markers of AD.     

Self-replicating protein conformations and information transfer: The adaptive β-sheet model

The deposition of proteins with a highly ordered β-sheet conformation is characteristic of several amyloid diseases. However, recent data indicate that amyloid formation is not always pathological, but may also be physiological. Based on the new insights in understanding the structural arrangements and the self-propagating properties of the β-conformational proteins in combination with the progress in elucidating the mechanisms of prion genetics and chaperone-controlled protein folding, a model of an adaptive β-sheet information system was developed. The idea is advanced that exogenous information can be specifically stored in the protease-resistant β-sheet rich protein aggregates in a prion-like mode creating a cytoplasmic molecular memory. The conformationally-bound information can then be transmitted to next cell generations by way of the self-propagating potential of the amyloidogenic structure. Controlled by a network of input-sensitive molecular chaperones, the β-conformation based information system could constitute a form of soft inheritance characterized by adaptability and plasticity. It is suggested that the β-system represents an evolutionary conserved primordial inheritance mechanism based on protein conformation.     

Complex N-linked glycosylated nicastrin associates with active gamma-secretase and undergoes tight cellular regulation

The intramembranous proteolysis of Notch and the amyloid precursor protein by gamma-secretase exemplifies an unusual and newly recognized mechanism of signal transduction in multicellular organisms. Here, we show that only a form of nicastrin (NCT) containing N-linked complex oligosaccharides is present in active gamma-secretase complexes. Overexpression of NCT does not generate more of this mature protein, a phenomenon analogous to the strictly regulated formation of mature presenilin heterodimers from immature holoprotein. The absence of presenilin severely limits the maturation of NCT, yet combined overexpression of both proteins does not increase respective mature types. Taken together, our findings describe unusual regulatory features of this key signaling protease: the association of NCT with gamma-secretase is tightly regulated via glycosylation; at least one other cofactor exists; the least abundant member of the complex becomes limiting; and the cofactor that serves this role may vary by cell type.     

Human brain pericytes as a model system to study the pathogenesis of cerebrovascular amyloidosis in Alzheimer's disease.

Cerebrovascular amyloidosis belongs to the pathological hallmarks of Alzheimer's disease brains. Although definite proof is still lacking, it is very well possible that the amyloid and its associated proteins are produced locally in the brain. In this paper we describe the development of a model system of cultured human brain pericytes to study the mechanisms of microvascular amyloid formation in vitro. These cultured cells may serve to study several aspects of cerebrovascular amyloidosis, which include the production of the amyloid precursor protein and of amyloid beta-protein-associated proteins as well as cytotoxic effects of amyloid beta-protein on perivascular cells. We demonstrated that pericytes produce and metabolize the amyloid precursor protein, and that they produce amyloid beta-protein-associated proteins, such as heparan sulfate proteoglycans, apolipoprotein E, and complement factor C1q. They are also prone to cellular degeneration after treatment with amyloid beta-protein, which is accompanied by increased expression of a number of amyloid beta-protein-associated proteins. This may be an important mechanism to explain the cell death observed in vivo. Our data indicate that this cell culture model of human brain pericytes provides a useful and pathophysiologically relevant tool to study cerebrovascular amyloidosis.     

Purification and characterization of a novel thiol protease involved in processing the enkephalin precursor

Proteolytic processing enzymes are required to convert the enkephalin precursor to active opioid peptides. In this study, a novel 33-kDa thiol protease that cleaves complete precursor in the form of [35S]methionine preproenkephalin was purified from bovine adrenal medullary chromaffin granules. Chromatography on concanavalin A-Sepharose and Sephacryl S-200, chromatofocusing, and chromatography on thiopropyl-Sepharose resulted in an 88,000-fold purification with a recovery of 35% of enzyme activity. The thiol protease is a glycoprotein with a pI of 6.0. It cleaves [35S]methionine preproenkephalin with a pH optimum of 5.5, indicating that it is functional at the intragranular pH of 5.5-6.0. Interestingly, production of trichloroacetic acid-soluble products was optimal at pH 4.0, suggesting that processing of initial precursor and intermediates may require slightly different pH conditions. The protease requires dithiothreitol for activity and is inhibited by the thiol protease inhibitors iodoacetate, p-hydroxymercuribenzoate, mercuric chloride, and cystatin. These properties distinguish it from other thiol proteases (cathepsins B, H, L, N, and S), indicating that a unique thiol protease has been identified. The enzyme converted [35S]cysteine preproenkephalin (possessing [35S]cysteine residues specifically within the precursor's NH2-terminal segment) to 22.1-, 21.6-, 17.7-, 17.3-, and 15.0-kDa intermediates that contain the precursor's NH2-terminal segment; proenkephalin in vivo is converted to similar intermediates. The enzyme cleaves peptide F at Lys-Arg and Lys-Lys dibasic amino acid sites to generate methionine enkephalin and intermediates. The appropriate vesicular localization, pH optimum, proteolytic products, and cleavage site specificity suggest that this thiol protease may be involved in enkephalin precursor processing. Most interestingly, [35S]methionine beta-preprotachykinin, a precursor of substance P, is minimally cleaved, suggesting that the thiol protease may possess some selectivity for the enkephalin precursor.     

Modeling of substrate specificity of the Alzheimer's disease amyloid precursor protein beta-secretase

The enzyme BACE (beta-site APP-cleaving enzyme) has recently been identified as the beta-secretase that cleaves the amyloid precursor protein (APP) to produce the N terminus of the Abeta peptide found in plaques in the brains of Alzheimer's disease patients. BACE is an aspartic protease similar to pepsin and renin. Comparative modeling of the three-dimensional structure of BACE in complex with its substrate shows that several residues confer specificity of the enzyme for APP. In particular, Arg296 forms a salt-bridge with the P1' Asp of the APP substrate, explaining the unusual preference of BACE among aspartic proteases for a P1' residue that is negatively charged. Several hydrophobic residues in the enzyme form a pocket for the P1 hydrophobic residue (Met in wild-type APP and Leu in APP with the "Swedish mutation" associated with early-onset of Alzheimer's disease). Inhibitors that can bind to the BACE active site may prove useful for drugs to treat and prevent Alzheimer's disease.