39 research outputs found

    Isolation, Cloning and Structural Characterisation of Boophilin, a Multifunctional Kunitz-Type Proteinase Inhibitor from the Cattle Tick

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    Inhibitors of coagulation factors from blood-feeding animals display a wide variety of structural motifs and inhibition mechanisms. We have isolated a novel inhibitor from the cattle tick Boophilus microplus, one of the most widespread parasites of farm animals. The inhibitor, which we have termed boophilin, has been cloned and overexpressed in Escherichia coli. Mature boophilin is composed of two canonical Kunitz-type domains, and inhibits not only the major procoagulant enzyme, thrombin, but in addition, and by contrast to all other previously characterised natural thrombin inhibitors, significantly interferes with the proteolytic activity of other serine proteinases such as trypsin and plasmin. The crystal structure of the bovine α-thrombin·boophilin complex, refined at 2.35 Å resolution reveals a non-canonical binding mode to the proteinase. The N-terminal region of the mature inhibitor, Q16-R17-N18, binds in a parallel manner across the active site of the proteinase, with the guanidinium group of R17 anchored in the S1 pocket, while the C-terminal Kunitz domain is negatively charged and docks into the basic exosite I of thrombin. This binding mode resembles the previously characterised thrombin inhibitor, ornithodorin which, unlike boophilin, is composed of two distorted Kunitz modules. Unexpectedly, both boophilin domains adopt markedly different orientations when compared to those of ornithodorin, in its complex with thrombin. The N-terminal boophilin domain rotates 9° and is displaced by 6 Å, while the C-terminal domain rotates almost 6° accompanied by a 3 Å displacement. The reactive-site loop of the N-terminal Kunitz domain of boophilin with its P1 residue, K31, is fully solvent exposed and could thus bind a second trypsin-like proteinase without sterical restraints. This finding explains the formation of a ternary thrombin·boophilin·trypsin complex, and suggests a mechanism for prothrombinase inhibition in vivo

    Identification and characterization of the mre gene region of Streptomyces coelicolor A3(2)

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    During a search for new differentiation factors in Streptomyces coelicolor A3(2), a locus at 11 o'clock on the S. coelicolor map was identified which harbours several genes that show extensive similarity to cell division and differentiation genes from Escherichia coli and Bacillus subtilis. From the sequence data it was concluded that the region contains the genes mreB, mreC, mreD (murein formation gene cluster E), pbp83 (high-molecular-weight penicillin-binding protein) and sfr (member of the spoVE/ftsW/rodA family). Mre gene products are reported to be responsible for determining cell shape in E. coli and Bacillus. The S. coelicolor mreC gene was inactivated by gene disruption, resulting in mutants which showed significant growth retardation in comparison to the wild type. Inactivation of the mreB gene was incompatible with viability, and thus mreB represents a Streptomyces cell division gene that is essential for survival. Promoter-probe experiments led to the identification of an operon structure, with promoters located upstream of mreB, pbp83 and sfr. Detailed studies of mreB transcription revealed the existence of three promoters; two of them are constitutively transcribed, whereas the third is developmentally regulated

    FEBS Lett.

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    We examined the influence of Ser/Ala190 in the S1 site on P1 substrate selectivity in several serine proteases. The impact of residue 190 on the selectivity was constant, regardless of differences in original selectivity or reactivity. Substrate binding in S1 was optimised in all wild-type enzymes, while the effects on k(cat) depended on the combination of residue 190 and substrate. Mutagenesis of residue 190 did not affect the S2-S4 sites. Pronounced selectivity for arginine residues was coupled with low enzymatic activity, in particular in recombinant factor IXa. This is due to the dominance of the S1- P1 interaction over substrate binding in the S2-S4 sites. (C) 2002 Published by Elsevier Science B.V. on behalf of the Federation of European Biochemical Societies

    Physiological fIXa activation involves a cooperative conformational rearrangement of the 99-loop

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    Coagulation factor IXa (fIXa) plays a central role in the coagulation cascade. Enzymatically, fIXa is characterized by its very low amidolytic activity that is not improved in the presence of cofactor, factor VIIIa (fVIIIa), distinguishing fIXa from all other coagulation factors. Activation of the fIXa-fVIIIa complex requires its macromolecular substrate, factor X (fX). The 99-loop positioned near the active site partly accounts for the poor activity of fIXa because it adopts a conformation that interferes with canonical substrate binding in S2-S4. Here we show that residues Lys-98 and Tyr-99 are critically linked to the amidolytic properties of fIXa. Exchange of Tyr-99 with smaller residues resulted not only in an overall decreased activity but also in impaired binding in S1. Replacement of Lys-98 with smaller and uncharged residues increased activity. Simultaneous mutagenesis of Lys-98, Tyr-177, and Tyr-94 produced an enzyme with 7000-fold increased activity and altered specificity. This triple mutant probably mimics the conformational changes that are physiologically induced by cofactor and substrate binding. It therefore provides a cooperative two-step activation model for fIXa. Tyr-177 locks the 99-loop in an inactive conformation which, in the physiologic complex, is released by cofactor fVIIIa. FX is then able to rearrange the unlocked 99-loop and subsequently binds to the active site cleft

    J. Biol. Chem.

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    The influence of residue 190 in the S1 site of trypsin-like serine proteases on substrate selectivity is universally conserved

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    We examined the influence of Ser/Ala190 in the S1 site on P1 substrate selectivity in several serine proteases. The impact of residue 190 on the selectivity was constant, regardless of differences in original selectivity or reactivity. Substrate binding in S1 was optimised in all wild-type enzymes, while the effects on k(cat) depended on the combination of residue 190 and substrate. Mutagenesis of residue 190 did not affect the S2-S4 sites. Pronounced selectivity for arginine residues was coupled with low enzymatic activity, in particular in recombinant factor IXa. This is due to the dominance of the S1- P1 interaction over substrate binding in the S2-S4 sites. (C) 2002 Published by Elsevier Science B.V. on behalf of the Federation of European Biochemical Societies

    J. Mol. Biol.

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    Factor VIIa initiates the extrinsic coagulation cascade; this event requires a delicately balanced regulation that is implemented on different levels, including a sophisticated multi-step activation mechanism of factor VII. Its central role in hemostasis and thrombosis makes factor VIIa a key target of pharmaceutical research. We succeeded, for the first time, in recombinantly producing N-terminally truncated factor VII (rf7) in an Escherichia coli expression system by employing an oxidative, in vitro, folding protocol, which depends critically on the presence of ethylene glycol. Activated recombinant factor VIIa (rf7a) was crystallised in the presence of the reversible S1-site inhibitor benzamidine. Comparison of this 1.69 Angstrom crystal structure with that of an inhibitor-free and sulphate-free, but isomorphous crystal form identified structural details of factor VIIa stimulation. The stabilisation of Asp189-Ser190 by benzamidine and the capping of the intermediate helix by a sulphate ion appear to be sufficient to mimic the disorder-order transition conferred by the cofactor tissue factor (TF) and the substrate factor X. Factor VIIa shares with the homologous factor IXa, but not factor Xa, a bell-shaped activity modulation dependent on ethylene glycol. The ethylene glycol-binding site of rf7a was identified in the vicinity of the 60 loop. Ethylene glycol binding induces a significant conformational rearrangement of the 60 loop. This region serves as a recognition site of the physiologic substrate, factor X, which is common to both factor VIIa and factor IXa. These results provide a mechanistic framework of substrate-assisted catalysis of both factor VIIa and factor IXa. (C) 2002 Elsevier Science Ltd. All rights reserved

    Crystal structures of uninhibited factor VIIa link its cofactor and substrate-assisted activation to specific interactions

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    Factor VIIa initiates the extrinsic coagulation cascade; this event requires a delicately balanced regulation that is implemented on different levels, including a sophisticated multi-step activation mechanism of factor VII. Its central role in hemostasis and thrombosis makes factor VIIa a key target of pharmaceutical research. We succeeded, for the first time, in recombinantly producing N-terminally truncated factor VII (rf7) in an Escherichia coli expression system by employing an oxidative, in vitro, folding protocol, which depends critically on the presence of ethylene glycol. Activated recombinant factor VIIa (rf7a) was crystallised in the presence of the reversible S1-site inhibitor benzamidine. Comparison of this 1.69 Angstrom crystal structure with that of an inhibitor-free and sulphate-free, but isomorphous crystal form identified structural details of factor VIIa stimulation. The stabilisation of Asp189-Ser190 by benzamidine and the capping of the intermediate helix by a sulphate ion appear to be sufficient to mimic the disorder-order transition conferred by the cofactor tissue factor (TF) and the substrate factor X. Factor VIIa shares with the homologous factor IXa, but not factor Xa, a bell-shaped activity modulation dependent on ethylene glycol. The ethylene glycol-binding site of rf7a was identified in the vicinity of the 60 loop. Ethylene glycol binding induces a significant conformational rearrangement of the 60 loop. This region serves as a recognition site of the physiologic substrate, factor X, which is common to both factor VIIa and factor IXa. These results provide a mechanistic framework of substrate-assisted catalysis of both factor VIIa and factor IXa. (C) 2002 Elsevier Science Ltd. All rights reserved

    Crystal structures of uninhibited factor VIIa link its cofactor and substrate-assisted activation to specific interactions

    No full text
    Factor VIIa initiates the extrinsic coagulation cascade; this event requires a delicately balanced regulation that is implemented on different levels, including a sophisticated multi-step activation mechanism of factor VII. Its central role in hemostasis and thrombosis makes factor VIIa a key target of pharmaceutical research. We succeeded, for the first time, in recombinantly producing N-terminally truncated factor VII (rf7) in an Escherichia coli expression system by employing an oxidative, in vitro, folding protocol, which depends critically on the presence of ethylene glycol. Activated recombinant factor VIIa (rf7a) was crystallised in the presence of the reversible S1-site inhibitor benzamidine. Comparison of this 1.69 Angstrom crystal structure with that of an inhibitor-free and sulphate-free, but isomorphous crystal form identified structural details of factor VIIa stimulation. The stabilisation of Asp189-Ser190 by benzamidine and the capping of the intermediate helix by a sulphate ion appear to be sufficient to mimic the disorder-order transition conferred by the cofactor tissue factor (TF) and the substrate factor X. Factor VIIa shares with the homologous factor IXa, but not factor Xa, a bell-shaped activity modulation dependent on ethylene glycol. The ethylene glycol-binding site of rf7a was identified in the vicinity of the 60 loop. Ethylene glycol binding induces a significant conformational rearrangement of the 60 loop. This region serves as a recognition site of the physiologic substrate, factor X, which is common to both factor VIIa and factor IXa. These results provide a mechanistic framework of substrate-assisted catalysis of both factor VIIa and factor IXa. (C) 2002 Elsevier Science Ltd. All rights reserved
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