Abstract
Both spatiotemporal analyses of adhesion signalling and the development of pharmacological inhibitors of integrin receptors currently suffer from the lack of an assay to measure integrin-effector binding and the response of these interactions to antagonists. Indeed, anti-integrin compounds have failed in the clinic because of secondary side effects resulting from agonistic activity. Here, we have expressed integrin-GFP and effector-mRFP pairs in living cells and quantified their association using fluorescence lifetime imaging microscopy (FLIM) to measure fluorescence resonance energy transfer (FRET). Association of talin with beta1 integrin and paxillin with alpha4 integrin was dependent on both the ligand and receptor activation state, and was sensitive to inhibition with small molecule RGD and LDV mimetics, respectively. An adaptation of the assay revealed the agonistic activity of these small molecules, thus demonstrating that these compounds may induce secondary effects in vivo via integrin activation. This study provides insight into the dependence of the activity of small molecule anti-integrin compounds upon receptor conformation, and provides a novel quantitative assay for the validation of potential integrin antagonists.
Highlights
Integrins are cell-adhesion receptors that provide physical support for tissues and enable directed migration during development and tissue homeostasis
Initially, a full-length human 1 integrin construct was Cterminally tagged with green fluorescent protein (GFP)
Other -integrin-GFPs have been described (Ballestrem et al, 2001), 1-integrin-GFP has not been previously generated because the ubiquitous distribution and high endogenous expression of 1 integrin in most cells makes it difficult to express
Summary
Integrins are cell-adhesion receptors that provide physical support for tissues and enable directed migration during development and tissue homeostasis (van der Neut et al, 1996; Wagner et al, 1996). Genes encoding 18 ␣ and 8  integrins produce polypeptides that combine to form 24 heterodimeric receptors (Hynes, 2002), 12 of which contain the 1 subunit. Both subunits are noncovalently associated, type I transmembrane proteins with large extracellular and mostly short cytoplasmic domains. Transmembrane or cytoplasmic domain separation, triggered either by the binding of FERM domain-containing cytoplasmic proteins (such as talin and myosin X) (Zhang et al, 2004; Tadokoro et al, 2003; Garcia-Alvarez et al, 2003) or extracellular ligands, is currently thought to be the mechanism for the bidirectional transmembrane signal transduction that regulates adhesion (Kim et al, 2003)
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