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“While the production of pharmacological reagents targeted to membrane signaling proteins has been a major objective for both academic laboratories and the pharmaceutical industry, many important membrane proteins are still without specific blockers. Moreover, where specific blockers exist, they often have high affinity and are selective only at low concentrations, so that the onset of their effect upon exposure takes a long time to develop and they bind so tightly that they are difficult to remove. The development of photoswitched tethered ligands (PTLs) that are targeted to an introduced cysteine near ligand binding sites
of membrane proteins opened the door to the reversible control of membrane signaling, by using two wavelengths to photoisomerize the tether between BMN 673 in vivo one state that permits ligand binding and a second state, which prevents binding (Szobota and Isacoff, 2010). Because specificity derives from the unique geometric relationship between the ligand binding site and the engineered anchoring site, rather than from tight binding, photoisomerization to the nonbinding state rapidly removes the ligand. Moreover, the
high effective concentration www.selleckchem.com/products/gsk1120212-jtp-74057.html of the ligand near its binding site in the permissive state leads to rapid binding upon photoisomerization, itself a very rapid transition (Szobota and Isacoff, 2010). Together, these properties enable highly selective optical control of binding and unbinding on the millisecond timescale and micron space-scale (Szobota and Isacoff, 2010). So far, optical control with PTLs has been applied to ion channels and receptors that are overexpressed in cells. Because the introduction of the anchoring site can usually be done with minimal perturbation to protein function (Szobota and Isacoff, 2010), it should be possible to introduce the mutation into the native protein via genetic knockin. Still, generation of a knockin animal is laborious and expensive,
making sense only when one is directly interested in the signaling by the targeted protein, very but not for exploring the function of several candidate proteins as in typical pharmacological experiments. To address this, we developed a scheme for targeting optical control via a PTL to native proteins without the requirement for genetic knockin. Our approach is to express a “photoswitchable conditional subunit” (PCS) that contains a PTL anchoring site and a mutation that retains the subunit inside the cell. This engineered subunit will not function in cells where native subunits are missing. However, in cells that express the native subunits that are required to form the functional protein complex, the native and engineered subunits will assemble inside the cell and the complex will be trafficked to the plasma membrane, thereby placing the native protein under optical control provided by the coassembled engineered subunit.