N-Myristoylation-Dependent c-Src Interactions

[spa] c-Src es miembro de una importante familia de tirosina quinasas, que está involucrada en la transducción de señales en las células. c-Src está formada por una región N-terminal desordenada (compuesta de los dominios SH4 y Único), por los dominios plegados SH3, SH2, SH1 (el dominio quinasa), y por una cola C-terminal. c-Src es una proteína miristoilada en su extremo N-terminal, lo cual permite su unión a membranas, unión reforzada por la interacción del dominio SH4 polibásico con los lípidos cargados negativamente. En ausencia del grupo miristoilo, se encontraron zonas de unión a lípidos y de interacciones intramoleculares en los dominios Único y SH3. El objetivo de este trabajo es la obtención y la caracterización de la forma miristoilada de los dominios Único y SH3 (MyrUSH3). Se desarrollaron protocolos que permitieron la producción de proteínas miristoiladas. La cinética de unión de MyrUSH3 a liposomas se estudió con resonancia de plasmones superficiales. Se observó una población mayoritaria con una asociación y una disociación relativamente rápidas, y una población minoritaria con una unión persistente a liposomas. Esta segunda especie se estudió por detección secundaria via un anticuerpo y se dedujo que estaba posiblemente formada por dímeros. El dominio SH3 se remplazó por una proteína verde fluorescente (MyrUGFP) y se estudió la unión de MyrUGFP a liposomas, mediante su observación con microscopía confocal, usando la técnica de fotoblanqueo de moléculas individuales. Se observó una población mayoritaria de dímeros. A continuación, se estudió la proteína MyrUSH3 con resonancia magnética nuclear, en solución o unida a liposomas. En solución, se encontró un sitio de unión al grupo miristoil en el dominio SH3. Tras la inserción del grupo miristoil en la bicapa lipídica, se perdió la capacidad de unión a lípidos en los dominios Único y SH3 (excepto el dominio SH4), y algunas interacciones intramoleculares fueron afectadas.[eng] c-Src is the leading member of the Src family of non-receptor tyrosine kinases, which are involved in many signaling pathways. Its deregulation affects cell migration, proliferation and survival. c-Src is composed of the intrinsically disordered N-terminal SH4 and Unique domains, of the folded SH3, SH2, kinase domains and of a C-terminal tail. c-Src is myristoylated at its N-terminal region and anchored to membranes via cooperative electrostatic and hydrophobic interactions. Weak interactions with lipids in the Unique and SH3 domains and intramolecular interactions between them were recently found in the non-myristoylated form. These interactions involve the Unique Lipid Binding region (ULBR) in the Unique domain, and the RT and nSrc loops in the SH3 domain. Our objective consisted in obtaining and characterizing the myristoylated form of the Unique and SH3 domains (MyrUSH3). Protocols for the efficient production of myristoylated proteins were developed. The incorporation of shorter acyl chains was characterized as a general problem in the preparation of myristoylated proteins, and conditions enabling to minimize their formation were found, in particular in the case of expression in minimum media. A well-defined myristoylation-induced cleavage site was identified and characterized in the Unique Lipid Binding Region of the Unique Domain of c-Src. Conditions to obtain degradation-free samples for structural studies were established. The kinetics of MyrUSH3 binding to liposomes was followed using surface plasmon resonance (SPR) and revealed two MyrUSH3 populations, a dominant form binding with relatively fast association and dissociation, and a minor persistently bound (PB) population not described earlier. This PB form was studied in an assay involving detection by a secondary antibody and the model better explaining the experimental results described these PB species to be dimer forms of MyrUSH3. In a construct in which the SH3 domain was replaced by the GFP protein, single molecule photobleaching experiments of these PB species bound to supported lipid bilayers were conducted. A major population of dimers over the bilayer surface was detected. When binding of the myristoylated SH4 (MyrSH4) peptide to liposomes by SPR, a PB population was also observed. Monitoring of the surface activity of MyrSH4 revealed the micelar behavior of the peptide at low concentrations. Nuclear Magnetic Resonance (NMR) measurements permitted to study the effect of the myristoyl group on the intramolecular interactions between the Unique and SH3 domains, as well as on the binding of the ULBR and RT loops to liposomes when the protein was anchored in the bilayer. 1H-15N spectra of the myristoylated Unique domain (MyrUSrc) confirmed the propensity of the ULBR to bind liposomes, but in a different manner depending on the nature of the lipid in the bilayer. These measurements of MyrUSrc also pointed out some intermolecular propensities in the MyrSH4 domain. 1H-15N spectra of MyrUSH3 in solution revealed the presence of a myristoyl binding site has been found in the RT loop. Interaction of the myristoyl chain with lipids results in the loss of other lipid binding interactions in the Unique and SH3 domains that were observed in the non-myristoylated form. The interaction between the SH4 and the SH3 domains that restricts the conformational space of the Unique domain was preserved in the myristoylated forms and in the presence of lipids. The SPR and single molecule fluorescence studies revealed the formation of self-associated complexes of limited size upon binding of MyrUSH3 or MyrUGFP to liposomes, possibly driven by the presence of the MyrSH4 domain. The NMR data highlighted the interplay between the lipid binding regions of the Unique and SH3 domains, in presence or absence of liposomes. Therefore, the myristoylated intrinsically disordered Unique domain may act in c-Src regulation at the lipid bilayer interface

Single molecule fluorescence reveals dimerization of myristoylated Src N-terminal region on supported lipid bilayers

The proto-oncogene tyrosine-protein kinase Src is a key ele- ment of signaling cascades involved in the invasive and meta- stasis-forming capacity of cancer cells. While membrane ty- rosine-kinase receptors are known to dimerize, Src is classified as a non-receptor kinase and assumed to remain always mono- meric. Here we demonstrate the formation of stable dimers by the first domains of myristoylated Src previously shown to be sufficient for Src trafficking. Src dimers fused to green fluo- rescent protein (GFP) on supported lipid bilayers were identi- fied using single-molecule photobleaching experiments. Com- petition with a protein containing only native Src domains without GFP confirms that dimerization is a previously over- looked intrinsic property of Src. Dimerization is concomitant to membrane binding by the myristoylated forms of Src and may constitute a new regulation layer for the Src oncogene

The plasma membrane as a mechanochemical transducer

Cells are constantly submitted to external mechanical stresses, which they must withstand and respond to. By forming a physical boundary between cells and their environment that is also a biochemical platform, the plasma membrane (PM) is a key interface mediating both cellular response to mechanical stimuli, and subsequent biochemical responses. Here, we review the role of the PM as a mechanosensing structure. We first analyse how the PM responds to mechanical stresses, and then discuss how this mechanical response triggers downstream biochemical responses. The molecular players involved in PM mechanochemical transduction include sensors of membrane unfolding, membrane tension, membrane curvature or membrane domain rearrangement. These sensors trigger signalling cascades fundamental both in healthy scenarios and in diseases such as cancer, which cells harness to maintain integrity, keep or restore homeostasis and adapt to their external environment

Kinetics characterization of c-Src binding to lipid membranes: switching from labile to persistent binding

Cell signaling by the c-Src proto-oncogen requires the attachment of the protein to the inner side of theplasma membrane through the myristoylated N-terminal region, known as the SH4 domain. Additionalbinding regions of lower affinity are located in the neighbor intrinsically disordered Unique domainand the structured SH3 domain. Here we present a surface plasmon resonance study of the binding of amyristoylated protein including the SH4, Unique and SH3 domains of c-Src to immobilized liposomes. Twodistinct binding processes were observed: a fast and a slow one. The second process lead to a persistentlybound form (PB) with a slower binding and a much slower dissociation rate than the first one. Theassociation and dissociation of the PB form could be detected using an anti-SH4 antibody. The kineticanalysis revealed that binding of the PB form follows a second order rate law suggesting that it involvesthe formation of c-Src dimers on the membrane surface. A kinetically equivalent PB form is observedin a myristoylated peptide containing only the SH4 domain but not in a construct including the threedomains but with a 12-carbon lauroyl substituent instead of the 14-carbon myristoyl group. The PB formis observed with neutral lipids but its population increases when the immobilized liposomes containnegatively charged lipids. We suggest that the PB form may represent the active signaling form of c-Srcwhile the labile form provides the capacity for fast 2D search of the target signaling site on the membranesurfac

The SH3 domain acts as a scaffold for the N-terminal intrinsically disordered regions of c-Src

Regulation of c-Src activity by the intrinsically disordered Unique domain has been recently demonstrated. However, its connection with the classical regulatory mechanisms is still missing. Here we show that the Unique domain is part of a long loop closed by the interaction of the SH4 and SH3 domains. The conformational freedom of the Unique domain is further restricted through direct contacts with SH3 that are allosterically modulated by binding of a poly-proline ligand in the presence and in the absence of lipids. Our results highlight the scaffolding role of the SH3 domain for the c-Src N-terminal intrinsically disordered regions and suggest a connection between the regulatory mechanisms involving the SH3 and Unique domains

A myristoyl binding site in the SH3 domain modulates c-Src membrane anchoring

The c-Src oncogene is anchored to the cytoplasmic membrane through its N-terminal myristoylated SH4 domain. This domain is part of an intramolecular fuzzy complex with the SH3 and Unique domains. Here we show that the N-terminal myristoyl group binds to the SH3 domain in the proximity of the RT loop, when Src is not anchored to a lipid membrane. Residues in the so-called Unique Lipid Binding Region modulate this interaction. In the presence of lipids, the myristoyl group is released from the SH3 domain and inserts into the lipid membrane. The fuzzy complex with the SH4 and Unique domains is retained in the membrane-bound form, placing the SH3 domain close to the membrane surface and restricting its orientation. The apparent affinity of myristoylated proteins containing the SH4, Unique, and SH3 domains is modulated by these intramolecular interactions, suggesting a mechanism linking c-Src activation and membrane anchoring

N-lauroylation during the expression of recombinant N- myristoylated proteins: implications and solutions

Incorporation of myristic acid to the N-terminus of proteins is a crucial modification that promotes membrane binding and proper localization of important components of signaling pathways. Recombinant expression of N-myristoylatyed proteins in E. coli can be achieved by co-expressing yeast N-myristoyltransferase and supplementing the growth medium with myristic acid. However, undesired incorporation of the 12-carbon fatty acid lauric acid can occur (leading to heterogeneous samples), especially when the available carbon sources are scarce, as it is the case in minimal medium for the expression of isotopically enriched samples. By applying this method to the Brain-acid soluble protein 1 and the 1- 185 N-terminal region of c-Src, we show the significant, and protein- specific, differences in the membrane binding properties of lauroylated and myristoylated forms. We also present a robust strategy for obtaining lauryl free-samples of myristoylated proteins in both rich and minimal media

The force loading rate drives cell mechanosensing through both reinforcement and cytoskeletal softening.

Cell response to force regulates essential processes in health and disease. However, the fundamental mechanical variables that cells sense and respond to remain unclear. Here we show that the rate of force application (loading rate) drives mechanosensing, as predicted by a molecular clutch model. By applying dynamic force regimes to cells through substrate stretching, optical tweezers, and atomic force microscopy, we find that increasing loading rates trigger talin-dependent mechanosensing, leading to adhesion growth and reinforcement, and YAP nuclear localization. However, above a given threshold the actin cytoskeleton softens, decreasing loading rates and preventing reinforcement. By stretching rat lungs in vivo, we show that a similar phenomenon may occur. Our results show that cell sensing of external forces and of passive mechanical parameters (like tissue stiffness) can be understood through the same mechanisms, driven by the properties under force of the mechanosensing molecules involved

Mechanical strain stimulates COPII‐dependent secretory trafficking via Rac1

Cells are constantly exposed to various chemical and physical stimuli. While much has been learned about the biochemical factors that regulate secretory trafficking from the endoplasmic reticulum (ER), much less is known about whether and how this trafficking is subject to regulation by mechanical signals. Here, we show that subjecting cells to mechanical strain both induces the formation of ER exit sites (ERES) and accelerates ER‐to‐Golgi trafficking. We found that cells with impaired ERES function were less capable of expanding their surface area when placed under mechanical stress and were more prone to develop plasma membrane defects when subjected to stretching. Thus, coupling of ERES function to mechanotransduction appears to confer resistance of cells to mechanical stress. Furthermore, we show that the coupling of mechanotransduction to ERES formation was mediated via a previously unappreciated ER‐localized pool of the small GTPase Rac1. Mechanistically, we show that Rac1 interacts with the small GTPase Sar1 to drive budding of COPII carriers and stimulates ER‐to‐Golgi transport. This interaction therefore represents an unprecedented link between mechanical strain and export from the ER

Membrane tension controls adhesion positioning at the leading edge of cells

Cell migration is dependent on adhesion dynamics and actin cytoskeleton remodeling at the leading edge. These events may be physically constrained by the plasma membrane. Here, we show that the mechanical signal produced by an increase in plasma membrane tension triggers the positioning of new rows of adhesions at the leading edge. During protrusion, as membrane tension increases, velocity slows, and the lamellipodium buckles upward in a myosin II-independent manner. The buckling occurs between the front of the lamellipodium, where nascent adhesions are positioned in rows, and the base of the lamellipodium, where a vinculin-dependent clutch couples actin to previously positioned adhesions. As membrane tension decreases, protrusion resumes and buckling disappears, until the next cycle. We propose that the mechanical signal of membrane tension exerts upstream control in mechanotransduction by periodically compressing and relaxing the lamellipodium, leading to the positioning of adhesions at the leading edge of cells