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ABSTRACT: Methionyl aminopeptidases (MetAPs) are metallo-dependent proteases responsible for removing of N-terminal methionine residue of peptides and proteins during protein maturation and activation. In this report we use a comprehensive strategy to screen the substrate specificity of three methionyl aminopeptidases: Homo sapiens MetAP-1, Homo sapiens MetAP-2 and Escherichia coli MetAP-1. By utilizing a 65-membered fluorogenic substrate library consisting of natural and unnatural amino acids we established detailed substrate preferences of each enzyme in the S1 pocket. Our results show that this pocket is highly conserved for all investigated MetAPs, very stringent for methionine, and that several unnatural amino acids with methionine-like characteristics were also well hydrolyzed by MetAPs. The substrate-derived results were verified using several phosphonate and phosphinate-based inhibitors.
Biochimie 11/2011; 94(3):704-10. · 3.02 Impact Factor
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Current opinion in cell biology 12/2010; 22(6):764-5. · 14.15 Impact Factor
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ABSTRACT: The covalent attachment of SUMO (small ubiquitin-like protein modifier) to target proteins results in modifications in their activity, binding interactions, localization or half-life. The reversal of this modification is catalysed by SENPs (SUMO-specific processing proteases). Mammals contain four SUMO paralogues and six SENP enzymes. In the present paper, we describe a systematic analysis of human SENPs, integrating estimates of relative selectivity for SUMO1 and SUMO2, and kinetic measurements of recombinant C-terminal cSENPs (SENP catalytic domains). We first characterized the reaction of each endogenous SENP and cSENPs with HA-SUMO-VS [HA (haemagglutinin)-tagged SUMO-vinyl sulfones], active-site-directed irreversible inhibitors of SENPs. We found that all cSENPs and endogenous SENP1 react with both SUMO paralogues, whereas all other endogenous SENPs in mammalian cells and tissues display high selectivity for SUMO2-VS. To obtain more quantitative data, the kinetic properties of purified cSENPs were determined using SUMO1- or SUMO2-AMC (7-amino-4-methylcoumarin) as substrate. All enzymes bind their respective substrates with high affinity. cSENP1 and cSENP2 process either SUMO substrate with similar affinity and catalytic efficiency; cSENP5 and cSENP6 show marked catalytic specificity for SUMO2 as measured by Km and kcat, whereas cSENP7 works only on SUMO2. Compared with cSENPs, recombinant full-length SENP1 and SENP2 show differences in SUMO selectivity, indicating that paralogue specificity is influenced by the presence of the variable N-terminal domain of each SENP. Our data suggest that SUMO2 metabolism is more dynamic than that of SUMO1 since most SENPs display a marked preference for SUMO2.
Biochemical Journal 09/2010; 430(2):335-44. · 4.90 Impact Factor
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ABSTRACT: Death domain complexes are key protein arrangements in the regulation of various cellular signaling events. One of the most prominent death domain complexes first described in the initiation of apoptosis is formed by the transmembrane receptor Fas, the cytosolic adaptor protein FADD, and caspase-8 and is referred to as the Fas/FADD/caspase-8 death inducing signaling complex (DISC). The recent structure of the Fas/FADD death domain complex reveals how formation of this signaling platform can be stringently regulated utilizing only Fas receptor clustering to form a death domain network. This work reveals that an opening mechanism of Fas is needed to expose binding sites for the FADD death domain and sets the stage for a conditional interaction, which is characterized by weak interactions adapted for a regulatory function. The overall crystal structure reveals a tetrameric arrangement of four primary Fas/FADD complexes. Intriguingly all contacts mediating the tetramer are solely provided through Fas/Fas interactions and are entirely dependent on the open form. These findings are instrumental in depicting a mechanism for DISC regulation where Fas receptor clustering leads to the stabilization of the open Fas death domains which are then capable of binding FADD in a weak interaction. At the same time this mechanism ensures that in the absence of a sufficient stimulus no interaction between Fas and FADD is possible. Therefore the conformation dependent, conditional Fas/FADD death domain interaction represents the regulatory element per se. This interaction contrasts the classic constitutive interactions of adaptor domains, which cannot provide regulatory function themselves. This model portrays how sole death domains are able to mediate signaling upon receptor clustering in the complete absence of enzyme activity.
Cell cycle (Georgetown, Tex.) 10/2009; 8(17):2723-7. · 5.36 Impact Factor
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ABSTRACT: The caspase-3 zymogen has essentially zero activity until it is cleaved by initiator caspases during apoptosis. However, a mutation of V266E in the dimer interface activates the protease in the absence of chain cleavage. We show that low concentrations of the pseudo-activated procaspase-3 kill mammalian cells rapidly and, importantly, this protein is not cleaved nor is it inhibited efficiently by the endogenous regulator XIAP (X-linked inhibitor of apoptosis). The 1.63 A (1 A = 0.1 nm) structure of the variant demonstrates that the mutation is accommodated at the dimer interface to generate an enzyme with substantially the same activity and specificity as wild-type caspase-3. Structural modelling predicts that the interface mutation prevents the intersubunit linker from binding in the dimer interface, allowing the active sites to form in the procaspase in the absence of cleavage. The direct activation of procaspase-3 through a conformational switch rather than by chain cleavage may lead to novel therapeutic strategies for inducing cell death.
Biochemical Journal 09/2009; 424(3):335-45. · 4.90 Impact Factor
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ABSTRACT: Abundant cell death is observed when human embryonic stem cells (hESCs) undergo neuralization, a critical first step for future cell-based therapies addressing neurodegeneration. Using hESC neuralization as an in vitro model of human development, we demonstrated that the developing neuroepithelium acquires increased susceptibility to spontaneous cell death. We found that poly(ADP-ribose) polymerase-1 (PARP1)/apoptosis-inducing factor (AIF)-mediated cell death (parthanatos) is a dominant mechanism responsible for cell loss during hESC neuralization. The demise of neural progenitor cells, at least in part, is due to decreased endogenous antioxidant defenses and enhanced reactive oxygen species leakage from mitochondria fuelled by nonphysiological culture conditions. Under such conditions, PARP1 overactivation triggered cell death through the mitochondrial-nuclear translocation of AIF. Blocking PARP1 activity with small hairpin RNA interference or nicotinamide dramatically enhanced hESC neuralization, providing optimal survival of the developing neuroepithelium. Because nicotinamide is a physiological metabolite, our results raise the possibility that neural stem/progenitor cell survival in vivo requires a metabolic niche. We argue that small natural metabolites provide a powerful physiological tool to optimize hESC differentiation compatible with the requirements of regenerative medicine.
Stem Cells 05/2009; 27(8):1772-81. · 7.78 Impact Factor
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ABSTRACT: DUBs (deubiquitinating enzymes) are a family of proteases responsible for the specific removal of ubiquitin attached to target proteins and thus control the free cellular pools of this molecule. DUB activity is usually assayed using full-length ubiquitin, and these enzymes generally show low activity towards small substrates that constitute the P4-P1 LRGG (Lys-Arg-Gly-Gly) C-terminal motif of ubiquitin. To gain insight into the C-terminal recognition region of ubiquitin by DUBs, we synthesized positional scanning libraries of fluorigenic tetrapeptides and tested them on three examples of human DUBs [OTU-1 (ovarian tumour 1), Iso-T (isopeptidase T) and UCH-L3 (ubiquitin C-terminal hydrolase L3)] and one viral ubiquitin-specific protease, namely PLpro (papain-like protease) from SARS (severe acute respiratory syndrome) virus. In most cases the results show flexibility in the P4 position, very high specificity for arginine in the P3 position and glycine in the P2 position, in accord with the sequence of the natural substrate, ubiquitin. Surprisingly, screening of the P2 position revealed that UCH-L3, in contrast with all the other tested DUBs, demonstrates substantial tolerance of alanine and valine at P2, and a parallel analysis using the appropriate mutation of the full-length ubiquitin confirms this. We have also used an optimal tetrapeptide substrate, acetyl-Lys-Arg-Gly-Gly-7-amino-4-methylcoumarin, to investigate the activation mechanism of DUBs by ubiquitin and elevated salt concentration. Together, our results reveal the importance of the dual features of (1) substrate specificity and (2) the mechanism of ubiquitin binding in determining deubiquitination by this group of proteases.
Biochemical Journal 08/2008; 415(3):367-75. · 4.90 Impact Factor
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Aaron D Schimmer,
Kate Welsh,
Clemencia Pinilla,
Zhiliang Wang,
Maryla Krajewska,
Marie-Josee Bonneau,
Irene M Pedersen,
Shinichi Kitada,
Fiona L Scott,
Beatrice Bailly-Maitre,
Gennadi Glinsky,
Dominick Scudiero,
Edward Sausville, Guy Salvesen,
Adel Nefzi,
John M Ostresh,
Richard A Houghten,
John C Reed
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ABSTRACT: Apoptosis resistance commonly occurs in cancers, preventing activation of Caspase family cell death proteases. XIAP is an endogenous inhibitor of Caspases overexpressed in many cancers. We developed an enzyme derepression assay, based on overcoming XIAP-mediated suppression of Caspase-3, and screened mixture-based combinatorial chemical libraries for compounds that reversed XIAP-mediated inhibition of Caspase-3, identifying a class of polyphenylureas with XIAP-inhibitory activity. These compounds, but not inactive structural analogs, stimulated increases in Caspase activity, directly induced apoptosis of many types of tumor cell lines in culture, and sensitized cancer cells to chemotherapeutic drugs. Active compounds also suppressed growth of established tumors in xenograft models in mice, while displaying little toxicity to normal tissues. These findings validate IAPs as targets for cancer drug discovery.
Cancer Cell 02/2004; 5(1):25-35. · 26.57 Impact Factor
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John C Reed,
Kutbuddin Doctor,
Ana Rojas,
Juan M Zapata,
Christian Stehlik,
Loredana Fiorentino,
Jason Damiano,
Wilfried Roth,
Shu-Ichi Matsuzawa,
Ruchi Newman,
Shinichi Takayama,
Hiroyuki Marusawa,
Famming Xu, Guy Salvesen,
Adam Godzik
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ABSTRACT: Apoptosis (programmed cell death) plays important roles in many facets of normal mammalian physiology. Host-pathogen interactions have provided evolutionary pressure for apoptosis as a defense mechanism against viruses and microbes, sometimes linking apoptosis mechanisms with inflammatory responses through NFkappaB induction. Proteins involved in apoptosis and NFkappaB induction commonly contain evolutionarily conserved domains that can serve as signatures for identification by bioinformatics methods. Using a combination of public (NCBI) and private (RIKEN) databases, we compared the repertoire of apoptosis and NFkappaB-inducing genes in humans and mice from cDNA/EST/genomic data, focusing on the following domain families: (1) Caspase proteases; (2) Caspase recruitment domains (CARD); (3) Death Domains (DD); (4) Death Effector Domains (DED); (5) BIR domains of Inhibitor of Apoptosis Proteins (IAPs); (6) Bcl-2 homology (BH) domains of Bcl-2 family proteins; (7) Tumor Necrosis Factor (TNF)-family ligands; (8) TNF receptors (TNFR); (9) TIR domains; (10) PAAD (PYRIN; PYD, DAPIN); (11) nucleotide-binding NACHT domains; (12) TRAFs; (13) Hsp70-binding BAG domains; (14) endonuclease-associated CIDE domains; and (15) miscellaneous additional proteins. After excluding redundancy due to alternative splice forms, sequencing errors, and other considerations, we identified cDNAs derived from a total of 227 human genes among these domain families. Orthologous murine genes were found for 219 (96%); in addition, several unique murine genes were found, which appear not to have human orthologs. This mismatch may be due to the still fragmentary information about the mouse genome or genuine differences between mouse and human repertoires of apoptotic genes. With this caveat, we discuss similarities and differences in human and murine genes from these domain families.
Genome Research 07/2003; 13(6B):1376-88. · 13.61 Impact Factor
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Biochemical Society Symposium 02/2003; · 2.74 Impact Factor
