Mécanisme d'activation au sein d'un dimère de récepteur couplé aux protéine G / Activation mecanism in a G-protein coupled receptor dimer

Damian, Marjorie

16 December 2011

Les récepteurs couplés de protéines G (RCPG) sont des capteurs biologiques polyvalents responsables de la majorité des réponses cellulaires aux hormones et neurotransmetteurs ainsi que des sens de la vue, de l'odorat et du goût. La transduction des signaux est associée à un ensemble de changements dans la structure tertiaire des récepteurs entraînant l'activation de partenaires intracellulaires dont les protéines G. La dimérisation est un élément central du mode de fonctionnement des RCPG ; cependant, son influence sur la façon dont le signal est transmis est encore mal définie.Nous avons utilisé ici le récepteur BLT1 du leucotriène B4 comme modèle afin d'analyser les changements de conformation au cours de l'activation. Pour cela, nous avons produit le récepteur suivant une approche qui consiste à l'exprimer dans les corps d'inclusion bactériens puis à le renaturer à l'aide de détergents et/ou surfactants originaux. L'accès au récepteur purifié nous a permis de montrer que la protéine G induit une asymétrie dans les changements de conformation au sein de l'homodimère de BLT1. De plus, nous avons pu établir que l'activation de la protéine G se fait essentiellement par le protomère ayant fixé l'agoniste (cis-activation). Enfin, nous avons montré que la forme monomérique du récepteur est parfaitement capable d'induire l'activation de la protéine G, même si le dimère apporte une modulation de la réponse. Ceci indique qu'un monomère de récepteur possède tous les déterminants moléculaires nécessaires à la transmission du signal. L'ensemble de ces résultats apporte un éclairage nouveau sur la façon dont les dimères de RCPG fonctionnent et peuvent moduler la réponse biologique. / G-protein coupled receptors are versatile biological sensors that are responsible for the majority of cellular responses to hormones and neurotransmitters as well as for the sense of sight, smell and taste. Signal transduction is associated with a set of changes in the tertiary structure of the receptor that are recognized by the associated intracellular partners, in particular the G proteins. There is compelling evidence that GPCR can assemble as dimers but the way these assemblies function at the molecular level is still under investigation.We used here the leukotriene B4 receptor BLT1 as a model to analyze the conformational changes occurring during activation. To this end, we first produced the receptor in E. coli inclusion bodies and subsequently folded it back to its native state in vitro using original membrane mimetics. Using the purified dimeric receptor, we showed that (i) the G protein induces an asymmetric arrangement of the BLT1 homodimer where each of the protomers is in a distinct conformation, and (ii) the G protein is cis-activated, i.e. the protomer that binds the agonist also activates Gα. Finally, we brought evidence that, although the dimer fully activates its G protein partner, the monomer has per se all the molecular determinant for an efficient functioning. All these data are original evidence that sheds light into the way GPCR dimers are activated and in turn modulate G protein-mediated signaling.

Rcpg

Leucotriène B4

Amphipol

Détergents

Mecanisme d'activation

Changements conformationnels

Gpcr

Leukotriene B4

Amphipol

Surfactant

Activation mecanism

Conformational changes

Etude du mécanisme dactivation du zymogène de lallergène Der p 1 de lacarien Dermatophagoides pteronyssinus

Chevigné, Andy

26 September 2008

The major allergen Der p 1 of the house dust mite Dermatophagoides pteronyssinus is a papain-like cysteine protease (CA1) associated to the development of allergic diseases such as asthma, rhinitis or atopic dermatitis. This allergen is expressed as an inactive precursor, called proDer p 1, formed by a 25 kDa catalytic domain downstream to an 10 kDa N-terminal propeptide, which blocks the active site cleft. The propeptide of Der p 1 exhibits a specific fold, which makes it unique in the CA1 propeptide family as it is characterised by the presence of four alpha helices and the absence of ERFNIN motif. In this study, we investigated the activation steps involved in the maturation of recombinant proDer p 1 expressed in Pichia pastoris under acidic conditions and we studied the influence of acidic pH on the structure of both propeptide and catalytic domain. Therefore, we characterized the interaction between the propeptide and mature Der p 1 at different pH values in terms of activity inhibition, structural stability and proteolytic susceptibility. According to our results, the auto-activation of proDer p 1 is a multistep mechanism, characterized by at least two intermediates (ATFE- and SNGG-) corresponding to the loss of the first and second propeptide alpha helices, respectively. The propeptide strongly inhibits unglycosylated and glycosylated recombinant Der p 1 (KD= 7 nM) at neutral pH. This inhibition is pH dependent, decreasing from pH 7 to pH 4 and can be related to structural changes of the propeptide initiated by the protonation of the aspartate residue of Lys17-Asp51-Tyr19 structural triad presents within the propeptide N-terminal domain. This protonation triggers conformational changes of the first propeptide alpha helix leading to an increase of the propeptide flexibility, an increase of its proteolytic sensitivity and the formation of a molten globule state. In addition, we compare mature protease, zymogen and propeptide pH unfolding and stability and highlights that the presence of the propeptide does not influence the catalytic domain pH unfolding and stability as the propeptide displays a weaker pH stability than the protease domain. These results confirmed that the propeptide unfolding is the key event of the activation process. Finally, we unravel the intermolecular contribution of mature Der p 1 in the activation process and highlights that activation of the precursor can be achieved, under acidic conditions, by intermolecular process but initial auto-activation most probably occurs through an intramolecular process or by the proteolysis by the catalytic domain of another zymogen in which the propeptide is unfolded. According to our results, we proposed that activation of the zymogen at pH 4 reflects a compromise between activity preservation and propeptide unfolding and that the location of the activation sites on the propeptide structure is a compromise between sequence recognition specificity and proteolytic susceptibility of the corresponding area.

house dust mite/acarien

Allergy/allergie

pH unfolding

propeptide

Der p 1