Publications
2011
Kellenberger Christine, Leone Philippe, Coquet Laurent, Jouenne Thierry, Reichhart Jean-Marc, Roussel Alain
Structure-function analysis of grass clip serine protease involved in Drosophila Toll pathway activation Article de journal
Dans: J. Biol. Chem., vol. 286, no. 14, p. 12300–12307, 2011, ISSN: 1083-351X.
Résumé | Liens | BibTeX | Étiquettes: Animals, Catalytic Domain, Cell Line, M3i, reichhart, Serine Proteases, Signal Transduction, Structure-Activity Relationship, Toll-Like Receptors
@article{kellenberger_structure-function_2011,
title = {Structure-function analysis of grass clip serine protease involved in Drosophila Toll pathway activation},
author = {Christine Kellenberger and Philippe Leone and Laurent Coquet and Thierry Jouenne and Jean-Marc Reichhart and Alain Roussel},
doi = {10.1074/jbc.M110.182741},
issn = {1083-351X},
year = {2011},
date = {2011-04-01},
journal = {J. Biol. Chem.},
volume = {286},
number = {14},
pages = {12300--12307},
abstract = {Grass is a clip domain serine protease (SP) involved in a proteolytic cascade triggering the Toll pathway activation of Drosophila during an immune response. Epistasic studies position it downstream of the apical protease ModSP and upstream of the terminal protease Spaetzle-processing enzyme. Here, we report the crystal structure of Grass zymogen. We found that Grass displays a rather deep active site cleft comparable with that of proteases of coagulation and complement cascades. A key distinctive feature is the presence of an additional loop (75-loop) in the proximity of the activation site localized on a protruding loop. All biochemical attempts to hydrolyze the activation site of Grass failed, strongly suggesting restricted access to this region. The 75-loop is thus proposed to constitute an original mechanism to prevent spontaneous activation. A comparison of Grass with clip serine proteases of known function involved in analogous proteolytic cascades allowed us to define two groups, according to the presence of the 75-loop and the conformation of the clip domain. One group (devoid of the 75-loop) contains penultimate proteases whereas the other contains terminal proteases. Using this classification, Grass appears to be a terminal protease. This result is evaluated according to the genetic data documenting Grass function.},
keywords = {Animals, Catalytic Domain, Cell Line, M3i, reichhart, Serine Proteases, Signal Transduction, Structure-Activity Relationship, Toll-Like Receptors},
pubstate = {published},
tppubtype = {article}
}
2010
Whisstock James C, Silverman Gary A, Bird Phillip I, Bottomley Stephen P, Kaiserman Dion, Luke Cliff J, Pak Stephen C, Reichhart Jean-Marc, Huntington James A
Serpins flex their muscle: II. Structural insights into target peptidase recognition, polymerization, and transport functions Article de journal
Dans: J. Biol. Chem., vol. 285, no. 32, p. 24307–24312, 2010, ISSN: 1083-351X.
Résumé | Liens | BibTeX | Étiquettes: Animals, Biological, Biological Transport, Biophysics, Catalytic Domain, Hormones, Humans, Kinetics, M3i, Models, Peptide Hydrolases, Protein Binding, Protein Conformation, Protein Structure, reichhart, Serpins, Substrate Specificity, Tertiary, Thrombin
@article{whisstock_serpins_2010,
title = {Serpins flex their muscle: II. Structural insights into target peptidase recognition, polymerization, and transport functions},
author = {James C Whisstock and Gary A Silverman and Phillip I Bird and Stephen P Bottomley and Dion Kaiserman and Cliff J Luke and Stephen C Pak and Jean-Marc Reichhart and James A Huntington},
doi = {10.1074/jbc.R110.141408},
issn = {1083-351X},
year = {2010},
date = {2010-08-01},
journal = {J. Biol. Chem.},
volume = {285},
number = {32},
pages = {24307--24312},
abstract = {Inhibitory serpins are metastable proteins that undergo a substantial conformational rearrangement to covalently trap target peptidases. The serpin reactive center loop contributes a majority of the interactions that serpins make during the initial binding to target peptidases. However, structural studies on serpin-peptidase complexes reveal a broader set of contacts on the scaffold of inhibitory serpins that have substantial influence on guiding peptidase recognition. Structural and biophysical studies also reveal how aberrant serpin folding can lead to the formation of domain-swapped serpin multimers rather than the monomeric metastable state. Serpin domain swapping may therefore underlie the polymerization events characteristic of the serpinopathies. Finally, recent structural studies reveal how the serpin fold has been adapted for non-inhibitory functions such as hormone binding.},
keywords = {Animals, Biological, Biological Transport, Biophysics, Catalytic Domain, Hormones, Humans, Kinetics, M3i, Models, Peptide Hydrolases, Protein Binding, Protein Conformation, Protein Structure, reichhart, Serpins, Substrate Specificity, Tertiary, Thrombin},
pubstate = {published},
tppubtype = {article}
}