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Biophysics of Proteins at Surfaces: Assembly, Activation, Signaling

Wednesday Speaker Abstracts

Biophysical Studies of Myristoylated Unique and SH3 Domains of Src Kinase and their

Interaction with Lipid Membranes

Anabel-Lise Le Roux

2,1

, Borja Mateos López

1

, Bruno Castro

3

, Maria-Antonia Busquets Viñas

1

,

Maria Gracia Parajo

3

, Francesc Sagués

1

, Miquel Pons

1

.

1

University of Barcelona, Barcelona, Spain,

2

Institute for Research in Biomedicine, Barcelona,

Spain,

3

Institute of Photonic Sciences, Castelldefels, Spain.

C-Src is a member of the Src family of non-receptor tyrosine kinases, which are involved in

many signaling pathways. It is composed of the N-terminal, the SH3, SH2, kinase and C-

terminal domains, and is anchored to membranes via cooperative electrostatic and hydrophobic

interactions. Indeed the N-terminal intrinsically disordered region (Unique Domain UD) is

myristoylated. Weak interactions with lipids in the Unique and SH3 domains and intramolecular

interactions between them were recently found in the non-myristoylated form. Our objective

consisted in characterizing the myristoylated form of the Unique + SH3 domain (MyrUSH3).

Binding kinetics to liposomes was followed using surface plasmon resonance (SPR) and revealed

two MyrUSH3 populations, a dominant form binding with fast association and dissociation, and

a minor persistently bound (PB) population not described earlier, found to possibly be MyrUSH3

dimers. In a construct in which the SH3 domain was replaced by the GFP protein, single

molecule photobleaching experiments of these PB species bound to liposomes were conducted.

A major population of dimers over the bilayer surface was detected. Lower affinity lipid binding

regions in the UD and SH3 domains were studied by nuclear magnetic resonance (NMR), as well

as their intermolecular interactions. The latter were conserved in presence of the myristoyl chain,

but secondary lipid binding regions were found to behave differently in presence or absence of

the acyl moeity. The SPR and fluorescence studies revealed autoassociation tendencies of the

myristoylated N-terminal domain of c-Src upon binding to liposomes. NMR data highlighted the

interplay between the lipid biding regions of UD and SH3 and the intermolecular interactions

and revealed a myristoyl interacting loop in SH3. Thus, the myristoylated intrinsically disordered

UD may act in c-Src regulation at the lipid bilayer interface.

QCM-D: A Powerful Surface Analysis Tool for Protein Studies

Jennie Ringberg

Biolin, Sweden

No Abstract