Molecular analysis of dibasic endoproteolytic cleavage signals.

Biologically active peptide hormones are synthesized from larger precursor proteins by a variety of post-translational processing reactions. To characterize these processing reactions further we have expressed preprogastrin in two endocrine cell lines and examined the molecular determinants involved in endoproteolysis at dibasic cleavage sites. The Gly93-Arg94-Arg95 carboxyl-terminal processing site of progastrin must be processed sequentially by an endoprotease, a carboxypeptidase, and an amidating enzyme to produce bioactive gastrin. For these studies the dibasic Arg94-Arg95 residues that serve as signals for the initiation of this processing cascade were mutated to Lys94-Arg95, Arg94-Lys95, and Lys94-Lys95. In the GH3 cells the Lys94-Arg95 mutation slightly diminished synthesis of carboxyl-terminally amidated gastrin, whereas in the MTC 6-23 cells this mutation had no effect on amidated gastrin synthesis. In contrast, both Arg94-Lys95 and Lys94-Lys95 mutations resulted in significantly diminished production of amidated gastrin in both cell lines. A specific hierarchy of preferred cleavage signals at this progastrin processing site was demonstrated in both cell lines, indicating that cellular dibasic endoproteases have stringent substrate specificities. Progastrins with the Lys94-Arg95 mutation in GH3 cells also demonstrated diminished processing at the Lys74-Lys75 dibasic site, thus single amino acid changes at one processing site may alter cleavage at distant sites. These studies provide insight into the post-translational processing and biological activation of not only gastrin but other peptide hormones as well.     

Calpain-dependent endoproteolytic cleavage of PrPSc modulates scrapie prion propagation

Previous studies using post-mortem human brain extracts demonstrated that PrP in Creutzfeldt-Jakob disease (CJD) brains is cleaved by a cellular protease to generate a C-terminal fragment, referred to as C2, which has the same molecular weight as PrP-(27-30), the protease-resistant core of PrP(Sc) (1). The role of this endoproteolytic cleavage of PrP in prion pathogenesis and the identity of the cellular protease responsible for production of the C2 cleavage product has not been explored. To address these issues we have taken a combination of pharmacological and genetic approaches using persistently infected scrapie mouse brain (SMB) cells. We confirm that production of C2 is the predominant cleavage event of PrP(Sc) in the brains of scrapie-infected mice and that SMB cells faithfully recapitulate the diverse intracellular proteolytic processing events of PrP(Sc) and PrP(C) observed in vivo. While increases in intracellular calcium (Ca(2+)) levels in prion-infected cell cultures stimulate the production of the PrP(Sc) cleavage product, pharmacological inhibitors of calpains and overexpression of the endogenous calpain inhibitor, calpastatin, prevent the production of C2. In contrast, inhibitors of lysosomal proteases, caspases, and the proteasome have no effect on C2 production in SMB cells. Calpain inhibition also prevents the accumulation of PrP(Sc) in SMB and persistently infected ScN2A cells, whereas bioassay of inhibitor-treated cell cultures demonstrates that calpain inhibition results in reduced prion titers compared with control-treated cultures assessed in parallel. Our observations suggest that calpain-mediated endoproteolytic cleavage of PrP(Sc) may be an important event in prion propagation.     

pH-Dependent exposure of endoproteolytic cleavage sites of the adenovirus 2 hexon protein

Abstract Physiological ionic strength conditions prevented low pH-mediated destabilization of the adenovirion. A conformational change of the virion was induced at low pH as demonstrated by endoproteolytic cleavage of virions with dispase at pH 5.0. Hidden cleavage sites of the hexons were exposed and upon enzymatic digestion, virions still were intact as physical entities. Enzymatic cleavage of the hexon protein increased its hydrophobicity.     

Study of the endoproteolytic cleavage of platelet glycoprotein IIb using oligonucleotide-mediated mutagenesis.

The precursor of platelet membrane glycoprotein IIb (GPIIb) undergoes endoproteolytic cleavage into heavy and light chains post-translation. Endoproteolysis occurs within a 17-amino acid stretch of the precursor that contains 4 arginine residues, 3 in dibasic sequences [Lys-Arg (855-856) and Arg-Arg (858-859)] and a single arginine at 871. To determine the site of GPIIb cleavage and its role in the function of the glycoprotein IIb/IIIa heterodimer, we mutated arginine 856, the di-arginine sequence 858-859, and arginine 871 and coexpressed the mutants with glycoprotein IIIa (GPIIIa) in COS-1 cells. Each GPIIb mutant formed recombinant GPIIb-IIIa heterodimers, but mutants lacking arginine at 856 or 858-859 failed to undergo cleavage. Nevertheless, heterodimers containing the uncleaved GPIIb were expressed on the cell surface. Because endoproteolysis most often occurs after arginines in dibasic sequences, we next expressed GPIIb mutants containing lysine at 856 or aspartic acid at 855 with GPIIIa. Both mutants were cleaved and surface-expressed, indicating that the dibasic sequence at 858-859, but not at 855-856, is required for GPIIb cleavage. Lastly, we tested the function of GPIIb-IIIa containing uncleaved GPIIb by measuring adhesion of transfected cells to immobilized fibrinogen. We found no difference in the adhesion of cells expressing either wild-type or mutant GPIIb, indicating GPIIb-IIIa heterodimers containing uncleaved GPIIb maintain their ability to interact with fibrinogen.     

Differential activation of the NF-kappaB-like factors Relish and Dif in Drosophila melanogaster by fungi and Gram-positive bacteria

The current model of immune activation in Drosophila melanogaster suggests that fungi and Gram-positive (G(+)) bacteria activate the Toll/Dif pathway and that Gram-negative (G(-)) bacteria activate the Imd/Relish pathway. To test this model, we examined the response of Relish and Dif (Dorsal-related immunity factor) mutants to challenge by various fungi and G(+) and G(-) bacteria. In Relish mutants, the Cecropin A gene was induced by the G(+) bacteria Micrococcus luteus and Staphylococcus aureus, but not by other G(+) or G(-) bacteria. This Relish-independent Cecropin A induction was blocked in Dif/Relish double mutant flies. Induction of the Cecropin A1 gene by M. luteus required Relish, whereas induction of the Cecropin A2 gene required Dif. Intact peptidoglycan (PG) was necessary for this differential induction of Cecropin A. PG extracted from M. luteus induced Cecropin A in Relish mutants, whereas PGs from the G(+) bacteria Bacillus megaterium and Bacillus subtilis did not, suggesting that the Drosophila immune system can distinguish PGs from various G(+) bacteria. Various fungi stimulated antimicrobial peptides through at least two different pathways requiring Relish and/or Dif. Induction of Attacin A by Geotrichum candidum required Relish, whereas activation by Beauvaria bassiana required Dif, suggesting that the Drosophila immune system can distinguish between at least these two fungi. We conclude that the Drosophila immune system is more complex than the current model. We propose a new model to account for this immune system complexity, incorporating distinct pattern recognition receptors of the Drosophila immune system, which can distinguish between various fungi and G(+) bacteria, thereby leading to selective induction of antimicrobial peptides via differential activation of Relish and Dif.     

Importation of nuclease colicins into E coli cells: endoproteolytic cleavage and its prevention by the immunity protein

A major group of colicins comprises molecules that possess nuclease activity and kill sensitive cells by cleaving RNA or DNA. Recent data open the possibility that the tRNase colicin D, the rRNase colicin E3 and the DNase colicin E7 undergo proteolytic processing, such that only the C-terminal domain of the molecule, carrying the nuclease activity, enters the cytoplasm. The proteases responsible for the proteolytic processing remain unidentified. In the case of colicin D, the characterization of a colicin D-resistant mutant shows that the inner membrane protease LepB is involved in colicin D toxicity, but is not solely responsible for the cleavage of colicin D. The lepB mutant resistant to colicin D remains sensitive to other colicins tested (B, E1, E3 and E2), and the mutant protease retains activity towards its normal substrates. The cleavage of colicin D observed in vitro releases a C-terminal fragment retaining tRNase activity, and occurs in a region of the amino acid sequence that is conserved in other nuclease colicins, suggesting that they may also require a processing step for their cytotoxicity. The immunity proteins of both colicins D and E3 appear to have a dual role, protecting the colicin molecule against proteolytic cleavage and inhibiting the nuclease activity of the colicin. The possibility that processing is an essential step common to cell killing by all nuclease colicins, and that the immunity protein must be removed from the colicin prior to processing, is discussed.     

Intracellular degradation of unassembled asialoglycoprotein receptor subunits: a pre-Golgi, nonlysosomal endoproteolytic cleavage

The human asialoglycoprotein receptor is a heterooligomer of the two homologous subunits H1 and H2. As occurs for other oligomeric receptors, not all of the newly made subunits are assembled in the RER into oligomers and some of each chain is degraded. We studied the degradation of the unassembled H2 subunit in fibroblasts that only express H2 (45,000 mol wt) and degrade all of it. After a 30 min lag, H2 is degraded with a half-life of 30 min. We identified a 35-kD intermediate in H2 degradation; it is the COOH-terminal, exoplasmic domain of H2. After a 90-min chase, all remaining intact H2 and the 35- kD fragment were endoglycosidase H sensitive, suggesting that the cleavage generating the 35-kD intermediate occurs without translocation to the medial Golgi compartment. Treatment of cells with leupeptin, chloroquine, or NH4Cl did not affect H2 degradation. Monensin slowed but did not block degradation. Incubation at 18-20 degrees C slowed the degradation dramatically and caused an increase in intracellular H2, suggesting that a membrane trafficking event occurs before H2 is degraded. Immunofluorescence microscopy of cells with or without an 18 degrees C preincubation showed a colocalization of H2 with the ER and not with the Golgi complex. We conclude that H2 is not degraded in lysosomes and never reaches the medial Golgi compartment in an intact form, but rather degradation is initiated in a pre-Golgi compartment, possibly part of the ER. The 35-kD fragment of H2 may define an initial proteolytic cleavage in the ER.     

Activation of initiation factor 2 by ligands and mutations for rapid docking of ribosomal subunits

We previously identified mutations in the GTPase initiation factor 2 (IF2), located outside its tRNA-binding domain, compensating strongly (A-type) or weakly (B-type) for initiator tRNA formylation deficiency. We show here that rapid docking of 30S with 50S subunits in initiation of translation depends on switching 30S subunit-bound IF2 from its inactive to active form. Activation of wild-type IF2 requires GTP and formylated initiator tRNA (fMet-tRNA(i)). In contrast, extensive activation of A-type IF2 occurs with only GTP or with GDP and fMet-tRNA(i), implying a passive role for initiator tRNA as activator of IF2 in subunit docking. The theory of conditional switching of GTPases quantitatively accounts for all our experimental data. We find that GTP, GDP, fMet-tRNA(i) and A-type mutations multiplicatively increase the equilibrium ratio, K, between active and inactive forms of IF2 from a value of 4 × 10(-4) for wild-type apo-IF2 by factors of 300, 8, 80 and 20, respectively. Functional characterization of the A-type mutations provides keys to structural interpretation of conditional switching of IF2 and other multidomain GTPases.     

Activation of C1r by proteolytic cleavage.

C1r was unable to cleave and activate proenzyme C1s unless first incubated at 37 degrees C in the absence of calcium before the addition of C1s. The acquisition of ability to activate C1s was associated with, and paralleled by, cleavage of each of the two noncovalently bonded 95,000 dalton chains of the molecule into disulfide linked subunits of 60,000 and 35,000 daltons, respectively. Thus, C1r is converted from an inactive form into an enzyme, C1r, able to cleave and activate C1s by proteolytic cleavage in marked analogy to the activation of several other complement enzymes. Trypsin was also found to cleave C1r but at a different site, and its action did not lead to C1r activation. C1r activation was inhibited by calcium, polyanethol sulfonate, C1 inactivator, and DFP but not by a battery of other protease inhibitors. C1 inactivator inhibited C1r by forming a complex with C1r via sites located on the light chain of the molecule. In other studies, cleavage of C1r was not accelerated by the addition of C1r ot C1s. C1r and C1r were found to have the same m.w., sedimentation coefficient, and diffusion coefficients. They differed, however, in charge with C1r migrating as a Beta-globulin and C1r as a gammaglobulin on electrophoresis in agarose. The amino acid composition of C1r and of each of the two polypeptide chains of Clr was determined. Both chains contained carbohydrate. Proteolytic cleavage of the C1r molecule was found to occur on addition of aggregated IgG to a mixture of C1q, C1r, and C1s in the presence of calcium. Neither C1q, C1s nor aggregated IgG alone, not C1r nor C1s induced C1r cleavage. Liquoid, an inhibitor of C1 activation, inhibited C1r cleavage. Thus, proteolytic cleavage of C1r appears to be a biologically meaningful event occurring during the activation of C1.     

The cleavage of Drosophila melanogaster DNA by restriction endonucleases

Drosophila melanogaster DNA, together with λ and E. coli DNAs as controls, was digested with three different restriction endonucleases: EcoR_I, Hind, and Hae. The size distributions of the segments were characterized by gel electrophoresis. More than 85% of the D. melanogaster DNA was found in a broad distribution of segment lengths consistent with random location of restriction sites. However, some DNA was spared and recovered in very long (≥20500bp) segments. These segments proved to be mostly simple sequence DNA. No complex spared segments could be found in Hind and Hae digests, while 50% of the spared EcoR_I segments had a complexity exceeding that of the E. coli DNA spared by this enzyme. These data do not support the hypothesis that chromomeres contain long regions of purely tandemly repeating sequences.     

Activation of NF-kappaB by FADD, Casper, and caspase-8

Fas-associated death domain protein (FADD), caspase-8-related protein (Casper), and caspase-8 are components of the tumor necrosis factor receptor type 1 (TNF-R1) and Fas signaling complexes that are involved in TNF-R1- and Fas-induced apoptosis. Here we show that overexpression of FADD and Casper potently activates NF-kappaB. In the presence of caspase inhibitors, overexpression of caspase-8 also activates NF-kappaB. A caspase-inactive point mutant, caspase-8(C360S), activates NF-kappaB as potently as wild-type caspase-8, suggesting that caspase-8-induced apoptosis and NF-kappaB activation are uncoupled. NF-kappaB activation by FADD and Casper is inhibited by the caspase-specific inhibitors crmA and BD-fmk, suggesting that FADD- and Casper-induced NF-kappaB activation is mediated by caspase-8. FADD, Casper, and caspase-8-induced NF-kappaB activation are inhibited by dominant negative mutants of TRAF2, NIK, IkappaB kinase alpha, and IkappaB kinase beta. A dominant negative mutant of RIP inhibits FADD- and caspase-8-induced but not Casper-induced NF-kappaB activation. A mutant of Casper and the caspase-specific inhibitors crmA and BD-fmk partially inhibit TNF-R1-, TRADD, and TNF-induced NF-kappaB activation, suggesting that FADD, Casper, and caspase-8 function downstream of TRADD and contribute to TNF-R1-induced NF-kappaB activation. Moreover, activation of caspase-8 results in proteolytic processing of NIK, which is inhibited by crmA. When overexpressed, the processed fragments of NIK do not activate NF-kappaB, and the processed C-terminal fragment inhibits TNF-R1-induced NF-kappaB activation. These data indicate that FADD, Casper, and pro-caspase-8 are parts of the TNF-R1-induced NF-kappaB activation pathways, whereas activated caspase-8 can negatively regulate TNF-R1-induced NF-kappaB activation by proteolytically inactivating NIK.