Pascal Maurice

The PDZ Protein Mupp1 Promotes Gi Coupling and Signaling of the Mt1 Melatonin Receptor

Intracellular signaling events are often organized around PDZ (PSD-95/Drosophila Disc large/ZO-1 homology) domain-containing scaffolding proteins. The ubiquitously expressed multi-PDZ protein MUPP1, which is composed of 13 PDZ domains, has been shown to interact with multiple viral and cellular proteins and to play important roles in receptor targeting and trafficking. In this study, we show that MUPP1 binds to the G protein-coupled MT1 melatonin receptor and directly regulates its Gi-dependent signal transduction. Structural determinants involved in this interaction are the PDZ10 domain of MUPP1 and the valine of the canonical class III PDZ domain binding motif DSV of the MT1 carboxyl terminus. This high affinity interaction (Kd ∼ 4 nm), which is independent of MT1 activation, occurs in the ovine pars tuberalis of the pituitary expressing both proteins endogenously. Although the disruption of the MT1/MUPP1 interaction has no effect on the subcellular localization, trafficking, or degradation of MT1, it destabilizes the interaction between MT1 and Gi and abolishes Gi-mediated signaling of MT1. Our findings highlight a previously unappreciated role of PDZ proteins in promoting G protein coupling to receptors.

A Generic Approach for the Purification of Signaling Complexes That Specifically Interact with the Carboxyl-terminal Domain of G Protein-coupled Receptors

G protein-coupled receptors (GPCRs) constitute the largest family of membrane receptors and are major drug targets. Recent progress has shown that GPCRs are part of large protein complexes that regulate their activity. We present here a generic approach for identification of these complexes that is based on the use of receptor subdomains and that overcomes the limitations of currently used genetics and proteomics approaches. Our approach consists of a carefully balanced combination of chemically synthesized His6-tagged baits, immobilized metal affinity chromatography, one- and two-dimensional gel electrophoresis separation and mass spectrometric identification. The carboxyl-terminal tails (C-tails) of the human MT1 and MT2 melatonin receptors, two class A GPCRs, were used as models to purify protein complexes from mouse brain lysates. We identified 32 proteins that interacted with the C-tail of MT1, 14 proteins that interacted with the C-tail of MT2, and eight proteins that interacted with both C-tails. Several randomly selected proteins were validated by Western blotting, and the functional relevance of our data was further confirmed by showing the interaction between the full-length MT1 and the regulator of G protein signaling Z1 in transfected HEK 293 cells and native tissue. Taken together, we have established an integrated and generic purification strategy for the identification of high quality and functionally relevant GPCR-associated protein complexes that significantly widens the repertoire of available techniques.

Platelet adhesion and signaling induced by the octapeptide primary binding sequence (KOGEOGPK) from type III collagen

Platelet adhesion to vascular collagens is an essential step in the initiation of hemostasis and thrombosis. Several platelet receptors interact with type I and type III collagens, including GP Ia/IIa and GP VI. We recently described a new platelet receptor (TIIICBP) specific for a type III collagen‐related pri‐mary binding sequence, the KOGEOGPK octapeptide. Here, we characterize platelet adhesion to the immobi‐lized octapeptide and demonstrate that this adhesion 1) is Ca2+ and Mg2+ independent, suggesting a nonin‐volvement of GP Ia/IIa; 2) is not inhibited by an antibody against GP VI; and 3) triggers platelet protein tyrosine phosphorylation. Whereas TXA2 has minimal effects, released ADP via only P2Y12 potentiates plate‐let adhesion to the octapeptide. Octapeptide‐induced platelet adhesion triggers platelet signaling through tyrosine phosphorylation of the 68 kDa subunit of TIIICBP, Syk, PLCgamma2, and FAK. Tyrosine phos‐phorylation of the FcR gamma‐chain and LAT is also observed but to a lesser extent than with type III collagen, suggesting the requirement of GP VI for full tyrosine phosphorylation of FcR gamma‐chain and LAT. The present study provides evidence for a critical role for the type III collagen‐related KOGEOGPK octapeptide in mediating platelet adhesion and signal‐ing, and consequently in platelet‐collagen interactions.—Maurice, P., Legrand, C., Fauvel‐Lafeve, F. Platelet adhesion and signaling induced by the octapep‐tide primary binding sequence (KOGEOGPK) from type III collagen. FASEB J. 18, 1339–1347 (2004)

The platelet receptor for type III collagen (TIIICBP) is present in platelet membrane lipid microdomains (rafts)

Platelet interactions with collagen are orchestrated by the presence or the migration of platelet receptor(s) for collagen into lipid rafts, which are specialized lipid microdomains from the platelet plasma membrane enriched in signalling proteins. Electron microscopy shows that in resting platelets, TIIICBP, a receptor specific for type III collagen, is present on the platelet membrane and associated with the open canalicular system, and redistributes to the platelet membrane upon platelet activation. After platelet lysis by 1% Triton X-100 and the separation of lipid rafts on a discontinuous sucrose gradient, TIIICBP is recovered in lipid raft-containing fractions and Triton X-100 insoluble fractions enriched in cytoskeleton proteins. Platelet aggregation, induced by type III collagen, was inhibited after disruption of the lipid rafts by cholesterol depletion, whereas platelet adhesion under static conditions did not require lipid raft integrity. These results indicate that TIIICBP, a platelet receptor involved in platelet interaction with type III collagen, is localized within platelet lipid rafts where it could interact with other platelet receptors for collagen (GP VI and α2β1 integrin) for efficient platelet activation.

Elastin-Derived Peptides Are New Regulators of Thrombosis

Objective— Elastin is the major structural extracellular matrix component of the arterial wall that provides the elastic recoil properties and resilience essential for proper vascular function. Elastin-derived peptides (EDP) originating from elastin fragmentation during vascular remodeling have been shown to play an important role in cell physiology and development of cardiovascular diseases. However, their involvement in thrombosis has been unexplored to date. In this study, we investigated the effects of EDP on (1) platelet aggregation and related signaling and (2) thrombus formation. We also characterized the mechanism by which EDP regulate thrombosis. Approach and Results— We show that EDP, derived from organo-alkaline hydrolysate of bovine insoluble elastin (kappa-elastin), decrease human platelet aggregation in whole blood induced by weak and strong agonists, such as ADP, epinephrine, arachidonic acid, collagen, TRAP, and U46619. In a mouse whole blood perfusion assay over a collagen matrix, kappa-elastin and VGVAPG, the canonical peptide recognizing the elastin receptor complex, significantly decrease thrombus formation under arterial shear conditions. We confirmed these results in vivo by demonstrating that both kappa-elastin and VGVAPG significantly prolonged the time for complete arteriole occlusion in a mouse model of thrombosis and increased tail bleeding times. Finally, we demonstrate that the regulatory role of EDP on thrombosis relies on platelets that express a functional elastin receptor complex and on the ability of EDP to disrupt plasma von Willebrand factor interaction with collagen. Conclusions— These results highlight the complex nature of the mechanisms governing thrombus formation and reveal an unsuspected regulatory role for circulating EDP in thrombosis.

New Insights into Molecular Organization of Human Neuraminidase-1: Transmembrane Topology and Dimerization Ability

Neuraminidase 1 (NEU1) is a lysosomal sialidase catalyzing the removal of terminal sialic acids from sialyloconjugates. A plasma membrane-bound NEU1 modulating a plethora of receptors by desialylation, has been consistently documented from the last ten years. Despite a growing interest of the scientific community to NEU1, its membrane organization is not understood and current structural and biochemical data cannot account for such membrane localization. By combining molecular biology and biochemical analyses with structural biophysics and computational approaches, we identified here two regions in human NEU1 - segments 139–159 (TM1) and 316–333 (TM2) - as potential transmembrane (TM) domains. In membrane mimicking environments, the corresponding peptides form stable α-helices and TM2 is suited for self-association. This was confirmed with full-size NEU1 by co-immunoprecipitations from membrane preparations and split-ubiquitin yeast two hybrids. The TM2 region was shown to be critical for dimerization since introduction of point mutations within TM2 leads to disruption of NEU1 dimerization and decrease of sialidase activity in membrane. In conclusion, these results bring new insights in the molecular organization of membrane-bound NEU1 and demonstrate, for the first time, the presence of two potential TM domains that may anchor NEU1 in the membrane, control its dimerization and sialidase activity.

Tandem affinity purification and identification of GPCR-associated protein complexes.

The first tandem affinity purification (TAP) protocol was described in 1999. Originally designed for the purification of protein complexes in yeast RNA splicing, its application rapidly expanded towards whole proteome analysis in yeast and mammalian cells. More recently, TAP has been applied to the purification of G protein-coupled receptor (GPCR)-associated protein complexes (GAPCs). This approach is particularly attractive for GPCRs, as the native, seven transmembrane structure is used as bait to purify GAPCs from mammalian cells expressing receptors at physiological levels. Here, a detailed protocol of the TAP method applied to GPCRs is presented.

Impact of sialic acids on the molecular dynamic of bi-antennary and tri-antennary glycans

Sialic acids (SA) are monosaccharides that can be located at the terminal position of glycan chains on a wide range of proteins. The post-translational modifications, such as N-glycan chains, are fundamental to protein functions. Indeed, the hydrolysis of SA by specific enzymes such as neuraminidases can lead to drastic modifications of protein behavior. However, the relationship between desialylation of N-glycan chains and possible alterations of receptor function remains unexplored. Thus, the aim of the present study is to establish the impact of SA removal from N-glycan chains on their conformational behavior. We therefore undertook an in silico investigation using molecular dynamics to predict the structure of an isolated glycan chain. We performed, for the first time, 3 independent 500u2009ns simulations on bi-antennary and tri-antennary glycan chains displaying or lacking SA. We show that desialylation alters both the preferential conformation and the flexibility of the glycan chain. This study suggests that the behavior of glycan chains induced by presence or absence of SA may explain the changes in the protein function.

Platelet type III collagen binding protein (TIIICBP) presents high biochemical and functional similarities with kindlin-3

Type III collagen binding protein (TIIICBP) was previously described as a platelet membrane protein that recognizes the KOGEOGPK peptide sequence within type III collagen. In order to better characterize this protein, we performed different approaches including mass spectrometry sequencing and functional experiments. This study leads to identify high biochemical and functional similarities between TIIICBP and kindlin-3, a member of a family of focal adhesion proteins. Indeed, mass spectrometry surveys indicated that TIIICBP contains several peptides identical to kindlin-3, covering 41% of the amino acid sequence. Polyclonal antibodies raised against a kindlin-3 specific N-terminal sequence, recognized and immunoprecipitated TIIICBP from platelet lysates. Electron microscopy and flow cytometry experiments showed that kindlin-3, as well as TIIICBP, were present associated to platelet membrane and a translocation of cytosolic kindlin-3 to the platelet membrane was observed after platelet activation. Similarly to anti-TIIICBP antibodies and the KOGEOGPK peptide, anti-kindlin-3 antibodies inhibited platelet interactions with type III collagen under flow conditions and slowed down platelet aggregation induced by glycoprotein VI agonists; e.g. collagen-related peptides and convulxin. In addition, the anti-kindlin-3 antibody inhibited platelet aggregation induced by low - but not high - doses of ADP or thrombin which depends on α(IIb)β(3) integrin function. In conclusion, our results show that the peptides identified by mass spectrometry from purified TIIICBP correspond to the kindlin-3 protein and demonstrate biochemical and functional similarities between TIIICBP and kindlin-3, strengthening a key role for TIIICBP/kindlin-3 in platelet interactions with collagen by cooperating with glycoprotein VI activation and integrin clustering in focal adhesion complexes.

Peptide affinity purification for the isolation and identification of GPCR-associated protein complexes.

Protein networks and their dynamic regulation play a fundamental role in biological systems. Seven transmembrane-spanning G protein-coupled receptors (GPCRs) constitute the largest family of membrane receptors controlling the flow of information from the extracellular environment into cells by inducing intracellular signaling pathways. Several GPCR-associated protein complexes (GAPCs), particularly those binding to the intracellular carboxyl-terminus (C-terminus), have been identified over the last 20 years. Recent optimizations in purification protocols and advances in mass spectrometry-based protein identification techniques have considerably accelerated the identification of GAPCs. We will concentrate here on a description of the latest version of the peptide affinity purification approach dedicated to the purification of GAPCs interacting with GPCR C-termini or any other soluble receptor subdomain.