Activity of ulilysin, an archaeal PAPP-A-related gelatinase and IGFBP protease

Tallant, C.; García‐Castellanos, Raquel; Marrero, Aniebrys; Canals, Françesc; Yang, Yongzheng; Reymond, Jean‐Louis; Solà, Marı́a; Baumann, Ulrich; Gomis‐Rüth, F. Xavier

doi:10.1515/bc.2007.143

Cited by 15 publications

(27 citation statements)

References 62 publications

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“…It is coordinated by the N ⑀2 atoms of the three consensus histidines (two histidine N ⑀2 atoms and one aspartate O ␦2 atom in snapalysin) and the catalytic solvent molecule, substituted by other ligands in the enzyme/inhibitorproduct complexes reported (supplemental Table 1). Some metzincins display an additional protein ligand at a slightly greater distance from the catalytic cation in the form of a tyrosine O atom, as seen in unbound astacin and serralysins and as hypothesized in ulilysin (21). This tyrosine residue lies two positions ahead of the Met-turn methionine.…”

Section: The Zinc-binding Sitementioning

confidence: 97%

“…The CSD shows two disulfide bonds and a unique two-calcium site. This site is a molecular switch for activity, as the proteinase can be reversibly inhibited through calcium chelators (15,20,21). Finally, in the absence of an unbound structure, ulilysin may possess a fifth zinc-binding tyrosine ligand provided by the Met-turn that is swung out upon substrate binding.…”

Section: Distinguishing Features Of Each Familymentioning

confidence: 99%

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Catalytic Domain Architecture of Metzincin Metalloproteases

Gomis‐Rüth

2009

Journal of Biological Chemistry

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Section: The Zinc-binding Sitementioning

confidence: 97%

Section: Distinguishing Features Of Each Familymentioning

confidence: 99%

Catalytic Domain Architecture of Metzincin Metalloproteases

Gomis‐Rüth

2009

Journal of Biological Chemistry

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206

178

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“…Both 38-kDa proulilysin C269A and its selenomethionine variant undergo calcium-mediated autoactivation at two sites, one upstream and one downstream of the catalytic moiety, to render mature 29-kDa ulilysin quantitatively after 24 h at room temperature (16,17,27 Fig. 1 in 27), respectively, and agreed well with the specificity of the enzyme for basic residues in subsite P 1Ј .…”

Section: Resultsmentioning

confidence: 59%

“…Site-directed Mutagenesis-Plasmids based on pET28a, which were modified to encode for both M. acetivorans proulilysin wild-type and variant C269A (16,17), were used as a template to mutate Met 290 to alanine, leucine, valine, phenylalanine, glycine, serine, cysteine, aspartate, lysine, and histidine (M290X mutants). The vector employed attached a His 6 tag to the protein N terminus, followed by a thrombin protease cleavage site, and conferred resistance to kanamycin.…”

Section: Methodsmentioning

confidence: 99%

“…Protease Assays-Purified M290X and C269A ulilysin mutants and the wild-type enzyme were tested (at 1 mg/ml in 20 mM Tris-HCl, pH 7.5, 100 mM NaCl, 5 mM CaCl 2 ) for proteolytic activity against the specific quenched fluorescent peptide substrate, DABCYL-Leu-Ala-Arg-Val-Glu-EDANS (Bachem) at 37°C for 2 h (16,17). The increase in fluorescence intensity ( ex ϭ 355 nm; em ϭ 460 nm) upon substrate cleavage was monitored on a fluorescence microplate reader (FLx800; BIOTEK), and kinetic parameters (K m and k cat ) were derived by using different substrate concentrations (10, 25, 50, 100, 150, and 175 M).…”

Section: Methodsmentioning

confidence: 99%

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On the Relevance of the Met-turn Methionine in Metzincins

Tallant

García‐Castellanos²,

Baumann³

et al. 2010

Journal of Biological Chemistry

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The metzincins are a clan of metallopeptidases consisting of families that share a series of structural elements. Among them is the Met-turn, a tight 1,4-turn found directly below the zincbinding site, which is structurally and spatially conserved and invariantly shows a methionine at position 3 in all metzincins identified. The reason for this conservation has been a matter of debate since its discovery. We have studied this structural element in Methanosarcina acetivorans ulilysin, the structural prototype of the pappalysin family, by generating 10 mutants that replaced methionine with proteogenic amino acids. We compared recombinant overexpression yields, autolytic and tryptic activation, proteolytic activity, thermal stability, and three-dimensional structure with those of the wild type. All forms were soluble and could be purified, although with varying yields, and three variants underwent autolysis, could be activated by trypsin, and displayed significant proteolytic activity. All variants were analyzed for the thermal stability of their zymogens. None of the mutants analyzed proved more stable or active than the wild type. Both bulky and small side chains, as well as hydrophilic ones, showed diminished thermal stability. Two mutants, leucine and cysteine, crystallized and showed three-dimensional structures that were indistinguishable from the wild type. These studies reveal that the Met-turn acts as a plug that snugly inserts laterally into a core structure created by the protein segment engaged in zinc binding and thus contributes to its structural integrity, which is indispensable for function. Replacement of the methionine with residues that deviate in size, side-chain conformation, and chemical properties impairs the plug-core interaction and prejudices molecular stability and activity.Evolutionary conservation of structural elements in proteins usually results from stringent steric requirements for function. Specific structures enable particular chemical groups to be placed appropriately in three-dimensional space for reaction, transport, regulation, and scaffolding (1). One such case of conserved structural elements is the Met-turn, found in the catalytic domains of all structurally characterized families of the metzincin clan of zinc-dependent metallopeptidases. These include astacins, ADAMs 4 /adamalysins, serralysins, matrix metalloproteinases (MMPs), leishmanolysins, snapalysins, and pappalysins (2-5). The catalytic domains span between ϳ130 and ϳ260 residues and fold into globular moieties, which are divided by an active site cleft into an upper N-terminal and a lower C-terminal subdomain when viewed in the standard orientation (Fig. 1A) (5). The N-terminal subdomain comprises a ␤-sheet and two helices, the backing helix and the active-site helix, as the minimum common core of repetitive secondary structure elements (5). The latter helix includes the first stretch of a zinc-binding consensus sequence, HEXX-HXXG/NXXH/D (amino acid one-letter code), which includes three protein ligands of the ca...

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Architecture and function of metallopeptidase catalytic domains

2013

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The cleavage of peptide bonds by metallopeptidases (MPs) is essential for life. These ubiquitous enzymes participate in all major physiological processes, and so their deregulation leads to diseases ranging from cancer and metastasis, inflammation, and microbial infection to neurological insults and cardiovascular disorders. MPs cleave their substrates without a covalent intermediate in a singlestep reaction involving a solvent molecule, a general base/acid, and a mono-or dinuclear catalytic metal site. Most monometallic MPs comprise a short metal-binding motif (HEXXH), which includes two metalbinding histidines and a general base/acid glutamate, and they are grouped into the zincin tribe of MPs. The latter divides mainly into the gluzincin and metzincin clans. Metzincins consist of globular~130-270-residue catalytic domains, which are usually preceded by N-terminal pro-segments, typically required for folding and latency maintenance. The catalytic domains are often followed by C-terminal domains for substrate recognition and other protein-protein interactions, anchoring to membranes, oligomerization, and compartmentalization. Metzincin catalytic domains consist of a structurally conserved N-terminal subdomain spanning a five-stranded b-sheet, a backing helix, and an active-site helix. The latter contains most of the metal-binding motif, which is here characteristically extended to HEXXHXXGXX(H,D). Downstream C-terminal subdomains are generally shorter, differ more among metzincins, and mainly share a conserved loop-the Met-turn-and a C-terminal helix. The accumulated structural data from more than 300 deposited structures of the 12 currently characterized metzincin families reviewed here provide detailed knowledge of the molecular features of their catalytic domains, help in our understanding of their working mechanisms, and form the basis for the design of novel drugs.Keywords: structural biochemistry; metzincin clan; catalytic domains; active-site cleft; hydrolytic enzymes; matrix metalloproteases; astacins; ADAM; adamalysins; serralysins; metalloprotease; metalloproteinase PeptidasesThe term "peptidase" is currently recommended for proteolytic enzymes, proteases, and proteinases in general.1 Peptidases are distributed among all kingdoms of life. 2,3 They target peptide bonds of proteins and/or peptides and some catalyze extensive protein-

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Activity of ulilysin, an archaeal PAPP-A-related gelatinase and IGFBP protease

Cited by 15 publications

References 62 publications

Catalytic Domain Architecture of Metzincin Metalloproteases

Catalytic Domain Architecture of Metzincin Metalloproteases

On the Relevance of the Met-turn Methionine in Metzincins

Architecture and function of metallopeptidase catalytic domains

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