Mechanism of Heparin Acceleration of Tissue Inhibitor of Metalloproteases-1 (TIMP-1) Degradation by the Human Neutrophil Elastase

Heparin has been shown to regulate human neutrophil elastase (HNE) activity. We have assessed the regulatory effect of heparin on Tissue Inhibitor of Metalloproteases-1 [TIMP-1] hydrolysis by HNE employing the recombinant form of TIMP-1 and correlated FRET-peptides comprising the TIMP-1 cleavage site. Heparin accelerates 2.5-fold TIMP-1 hydrolysis by HNE. The kinetic parameters of this reaction were monitored with the aid of a FRET-peptide substrate that mimics the TIMP-1 cleavage site in pre-steady-state conditionsby using a stopped-flow fluorescence system. The hydrolysis of the FRET-peptide substrate by HNE exhibits a pre-steady-state burst phase followed by a linear, steady-state pseudo-first-order reaction. The HNE acylation step (k2 = 21±1 s−1) was much higher than the HNE deacylation step (k3 = 0.57±0.05 s−1). The presence of heparin induces a dramatic effect in the pre-steady-state behavior of HNE. Heparin induces transient lag phase kinetics in HNE cleavage of the FRET-peptide substrate. The pre-steady-state analysis revealed that heparin affects all steps of the reaction through enhancing the ES complex concentration, increasing k1 2.4-fold and reducing k−1 3.1-fold. Heparin also promotes a 7.8-fold decrease in the k2 value, whereas the k3 value in the presence of heparin was increased 58-fold. These results clearly show that heparin binding accelerates deacylation and slows down acylation. Heparin shifts the HNE pH activity profile to the right, allowing HNE to be active at alkaline pH. Molecular docking and kinetic analysis suggest that heparin induces conformational changes in HNE structure. Here, we are showing for the first time that heparin is able to accelerate the hydrolysis of TIMP-1 by HNE. The degradation of TIMP-1is associated to important physiopathological states involving excessive activation of MMPs

Influence de l'environnement cellulaire sur le repliement et l'assemblage de fragments protéiques

PARIS7-Bibliothèque centrale (751132105) / SudocSudocFranceF

Repliement et production de proteines recombinantes

The biotechnology of recombinant protein production is now entering its most advanced stage, and the growth of industrial protein pharmaceuticals provides solid proof of this evolution. However, the systematic conversion of genetic information into a biologically active protein is constantly confronted by the fundamental problem of protein folding in cells, and many recombinant proteins are not produced in their native state. Instead, they aggregate into a biologically inactive state. Although this aggregation reaction has some practical advantages, in vitro renaturation of recombinant proteins, after solubilization of cellular aggregates, is still an empiric and random process. Thus, it is better to control cellular expression conditions to minimize this problem inside the cells. The most attractive approach is certainly the development of high throughput genetic screens to monitor efficient protein folding

Quantitative and dynamic analysis of PTEN phosphorylation by NMR

International audienceThe dual lipid and protein phosphatase PTEN is a tumor suppressor controlling key biological processes, such as cell growth, proliferation and neuro-survival. Its activity and intracellular trafficking is finely regulated notably by multi-site phosphorylation of its C-terminal tail. The reversible and highly dynamic character of these regulatory events confers a temporal dimension to the cell for triggering crucial decisions. In this review, we describe how a recently developed time-resolved NMR spectroscopy approach unveils the dynamic establishment of the phosphorylation events of PTEN C-terminal tail controlled by CK2 and GSK3β kinases. Two cascades of reactions have been identified, in vitro and in extracts of human neuroblastoma cells. They are triggered independently on two nearby clusters of sites (S380-S385 and S361-S370) and occur on different timescales. In each cascade, the reactions follow an ordered model with a distributive kinetic mechanism. The vision of these cascades as two delay timers activating distinct or time-delayed regulatory responses gives a temporal dimension on PTEN regulation and is discussed in relation to the known functional roles of each cluster

1H NMR characterization of renatured lysozyme obtained from fully reduced lysozyme under folding/oxidation conditions: A high resolution liquid NMR study at magic angle spinning

International audienceMagic angle spinning (MAS) has long been used as a powerful technique in studies of heterogeneous samples such as powdered solids, compartmentalized liquids and heterogeneous solid-liquid mixtures. Recently it has been shown that higher resolution could be achieved if high-resolution magnetic susceptibility matching probe technology was used in conjunction with MAS (Nano-probe). In this paper the possibilities and advantages of generating high-resolution spectra of liquids is illustrated using the Nano.nmr probe for the study in solution of lysozyme subjected to various treatments

Kinetics of secondary structure recovery during the refolding of reduced hen egg white lysozyme.

International audienceWe have shown previously that, in less than 4 ms, the unfolded/oxidized hen lysozyme recovered its native secondary structure, while the reduced protein remained fully unfolded. To investigate the role played by disulfide bridges in the acquisition of the secondary structure at later stages of the renaturation/oxidation, the complete refolding of reduced lysozyme was studied. This was done in a renaturation buffer containing 0.5 M guanidinium chloride, 60 microM oxidized glutathione, and 20 microM reduced dithiothreitol, in which the aggregation of lysozyme was minimized and where a renaturation yield of 80% was obtained. The refolded protein could not be distinguished from the native lysozyme by activity, compactness, stability, and several spectroscopic measurements. The kinetics of renaturation were then studied by following the reactivation and the changes in fluorescence and circular dichroism signals. When bi- or triphasic sequential models were fitted to the experimental data, the first two phases had the same calculated rate constants for all the signals showing that, within the time resolution of these experiments, the folding/oxidation of hen lysozyme is highly cooperative, with the secondary structure, the tertiary structure, and the integrity of the active site appearing simultaneously

The isolated C-terminal (F2) fragment of the Escherichia coli tryptophan synthase beta 2-subunit folds into a stable, organized nonnative conformation.

International audienceProteolysis of the beta 2-subunit of Escherichia coli tryptophan synthase by the endoproteinase Glu C from Staphylococcus aureus V8 yields a peptide, F2, corresponding to the C-terminal 101 residues of the beta-chain. The conformation and stability of isolated F2 in phosphate buffer at pH 7.8 (where native beta 2 is stable) have been investigated. Circular dichroism spectra in the far-UV showed the presence of large amounts of secondary structure (19% alpha-helices, 34% extended beta-structures). Circular dichroism spectra in the near-UV and sedimentation velocity studies indicated an open globular structure with the aromatic side chains in a symmetric (or disordered) environment. NMR spectra and rates of amide proton exchange showed that F2 fluctuates rapidly between several conformations. The thermal denaturation of F2 observed by the loss of far-UV circular dichroism with increasing temperature appeared noncooperative, and indicates a high thermal stability (Tm = 70 degrees C). Differential scanning microcalorimetry confirmed the absence of cooperativity and indicated a very low value for the calorimetric enthalpy of denaturation (delta H = 17 kJ/mol). All these properties were compatible with a molten globule. However, the low sedimentation coefficient of F2 suggested a very hydrated and/or expanded structure, and the secondary structure content of isolated F2 (see above) differed widely from that reported in the literature for F2 within the context of native beta 2 (49% alpha-helices and 13% extended beta-structures). Thus, neither the secondary nor the tertiary structure of isolated F2 resembled those of native F2. In this respect, isolated F2 is not a "molten globule".(ABSTRACT TRUNCATED AT 250 WORDS

Antifolding Activity of the SecB Chaperone Is Essential for Secretion of HasA, a Quickly Folding ABC Pathway Substrate

International audienceWe have previously shown that SecB, the ATP-independent chaperone of the Sec pathway, is required for the secretion of the HasA hemophore from Serratia marcescens via its type I secretion pathway, both in the reconstituted system in Escherichia coli and in the original host. The refolding of apo-HasA after denaturation with guanidine HCl was followed by stopped-flow measurements of fluorescence of its single tryptophan, both in the absence and presence of SecB. In the absence of SecB, HasA folds very quickly with one main phase (45 s(-1)) accounting for 92% of the signal. SecB considerably slows down HasA folding. At stoichiometric amounts of SecB and HasA, a single phase (0.014 s(-1)) of refolding is observed. Two double point mutants of HasA were made, abolishing two hydrogen bonds between N-terminal and C-terminal side chain residues. In both cases, the mutants essentially maintained the same secondary and tertiary structure as wild-type HasA and were fully functional. Refolding of both mutants was much slower than that of wild-type HasA and they were secreted essentially independently of SecB. We conclude that SecB has mainly an antifolding function in the HasA ABC secretion pathway

Amino acid residues important for folding of thioredoxin are revealed only by study of the physiologically relevant reduced form of the protein

International audienceThioredoxin-1 from Escherichia coli has frequently been used as a model substrate in protein folding studies. However, for reasons of convenience, these studies have focused largely on oxidized thioredoxin and not on reduced thioredoxin, the more physiologically relevant species. Here we describe the first extensive characterization of the refolding kinetics and conformational thermodynamics of reduced thioredoxin. We have previously described a genetic screen that yielded mutant thioredoxin proteins that fold more slowly in both the oxidized and reduced forms. In this study, we apply our more detailed analysis of reduced thioredoxin folding to a larger number of folding mutants that includes those obtained from continuation of the genetic screen. We have identified mutant proteins that display folding defects specifically in the reduced state but not the oxidized state. Some of these substitutions represent unusual folding mutants in that they result in semiconservative substitutions at solvent-exposed positions in the folded conformation and do not appear to affect the conformational stability of the protein. Further, the genetic selection yields mutants at only a limited number of sites, pointing to perhaps the most critical amino acids in the folding pathway and underscoring, in particular, the role of the carboxy-terminal amino acids in the folding of thioredoxin. Our results demonstrate the importance of studying the physiologically relevant folding species