Thomas Seine, Dirk Schaible, Friedrich Roder, Christian Richter, Yulia Podoplelowa, Samuel Clarke, Jacob Piehler, Sara Löchte, Gilles Uzé, Stephan Wilmes, Changjiang You, Oliver Beutel, Maxime Dahan, and Fabien Pinaud
Tracking the motion of individual proteins on the surface of live cells has contributed considerably towards unveiling the functional organization of proteins in the plasma membrane. Individual proteins labeled with quantum dots (QDs) can be imaged over long time periods with ultrahigh spatial and temporal resolution, yielding powerful information on the spatiotemporal dynamics of proteins at the plasma membrane in live cells. A key challenge for the application of QDs is to site-specifically attach proteins to the surface of these nanoparticles in a stoichiometric manner without affecting protein function. Several procedures for rendering surfaces of QDs biocompatible have been described, thus reducing non-specific binding and protein denaturation on the QD surface. However, functionalized biocompatible QDs used to target cell surface proteins generally result in multipoint attachment to the target proteins because the number of functional groups on the QDs is very difficult to control. Such multiply functionalized QDs induce clustering of target proteins on the cell surface, biasing not only lateral diffusion but also the functional properties of these proteins. As a consequence, increased endocytosis has been observed upon binding of QDs functionalized with multiple epidermal grow factor (EGF) molecules to cell-surface EGF receptors. Stochastic functionalization of multiple reactive sites on the QD offers the choice of obtaining only a minor fraction of the QDs with a single functional group, or a significant fraction of QDs with multiple functional groups. Preparation of homogeneous, monofunctional QDs currently relies on electrophoretic purification, which has been achieved only for very small QDs. These compact QDs are designed with very thin surface coatings, which have the disadvantage of showing relatively strong non-specific interactions. Most approaches for targeting proteins using QDs in live cells are based on biotin–streptavidin interactions, which form quasi-irreversible complexes. For multiplexed, generic labeling of proteins on the cell surface, further targeting strategies are required. We have recently described tris(hydroxymethyl)methylamine–nitrilotriacetic acid (Tris-NTA) moieties for highly specific and stable attachment of fluorophores and other functional units to histidine-tagged proteins in vitro and on the surface of live cells. The lifetime of Tris-NTA complexes with His-tagged proteins is in the order of several hours, which is well-suited to medium-term single molecule tracking applications. Herein, we have attempted to control the functionalization degree of QDs with Tris-NTA by means of electrostatic repulsion. We devised a bottom-up coupling chemistry based on a novel Tris-NTA derivative (1; Figure 1a), which comprises a thiol-terminated hepta(ethylene glycol) linker. This compound was generated in situ by reduction of the disulfide-linked dimer (1a ; see the Supporting Information, Scheme S1) and coupled to commercially available polymer-coated and amine-functionalized QDs by means of a hetero-bifunctional cross-linker (Figure 1b). Covalently attachment of 1 to surfaces modified with maleimide-functionalized polyethylene glycol (PEG) polymer brush and specific immobilization of His-tagged proteins was confirmed by label-free detection (Supporting Information, Figure S1). To control the degree of functionalization with Tris-NTA on the QD surface, the reaction of 1 with surface maleimide groups was performed at low ionic strength. Under these conditions, all QDs were reacted with Tris-NTA, as confirmed by an increase in negative charges detected by anion exchange chromatography and agarose gel electrophoreses (Figure 1c,d). These assays indicated relatively monodisperse electrostatic properties after coupling of 1, despite the fact that it was reacted at a large excess (660 mm of compound 1 to 1 mm QD). Coupling of 1 at higher ionic strength yielded QDs with a substantially higher degree of functionalization, as confirmed by a further shift of the signals both in anion exchange chromatography and agarose gel electrophoresis (Figure 1c,d). To characterize the functional properties of Tris-NTAcoupled QDs, binding to immobilized hexahistidine (H6) [*] Dr. C. You, S. Wilmes, O. Beutel, S. L chte, Y. Podoplelowa, F. Roder, C. Richter, T. Seine, D. Schaible, Prof. Dr. J. Piehler Division of Biophysics, Universit t Osnabr ck Barbarstrasse 11, 49076 Osnabr ck (Germany) Fax: (+49)541-969-2262 E-mail: piehler@uos.de Homepage: http://www.biologie.uni-osnabrueck.de/Biophysik/ Piehler/