Stéphanie Claudel‐Gillet scite author profile

Turnip yellow mosaic virus (TYMV) is an icosahedral plant virus with an average diameter of 28 nm and can be isolated in gram quantities from turnip or Chinese cabbage inexpensively. In this study, it was selected as a prototype bionanoparticle for time-resolved fluoroimmuno assay (TRFIA). Two types of reactive amino acid residues were employed to anchor luminescent terbium complexes and biotin groups based on orthogonal chemical reactions. While terbium complexes were used as luminescent signaling groups, biotin motifs acted as a model ligand for protein binding. The bioconjugation results were confirmed by MS and Western blot analysis. Steady-state and time-resolved luminescence study of the dual-modified viruses demonstrated that the spectroscopic properties of the Tb complex are unperturbed by the labeling procedure. The dual-modified particle was probed by fluorescence resonance energy transfer (FRET) experiments using avidin labeled with an Alexa488 fluorophore, which bound to the biotin on the surface of the particle, as an energy acceptor, and terbium complexes as an energy donor. The emission and excitation spectra of the dual-labeled TYMV particle displayed residual virus fluorescence and Tb luminescence upon ligand-centered excitation. The Tb luminescence lifetime was 1.62 ms and could be effectively fitted with a single-exponential behavior. In the TRFIA, an efficient transfer of 66% was observed, and the calculation using the Förster radius of 41 A allowed for an estimation of the average donor-acceptor distance of 36 A. Our studies show that the two reactive sites can communicate with each other on the surface of a nanoscale biological assembly. In particular, the ligand-receptor binding (biotin and avidin in this paper) was not interfered with when anchored to the surface of TYMV. Therefore, as a prototype of polyvalent bionanoparticles, TYMV can be used as scaffold for sensor development with TRFIA.

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Lanthanide‐Based Conjugates as Polyvalent Probes for Biological Labeling

Claudel‐Gillet

Steibel

Weibel

et al. 2008

Eur J Inorg Chem

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A series of lanthanide complexes of [LnL(H2O)] composition, suitable for biological labeling has been studied, in which L is a strongly chelating ligand containing chromophoric bipyridylcarboxylate units and Ln = Sm, Eu, Gd, Tb, and Dy. For the Gd complex, a combined 17O NMR and 1H NMRD study has been performed. The water exchange rate obtained, kex298 = (5.2 ± 0.6) × 106 s–1, is slightly higher than those for [Gd(dota)(H2O)]– or [Gd(dtpa)(H2O)]2–. Transformation of the uncoordinated carboxylate function of the ligand into an activated ester ensures covalent linking of the complex to bovine serum albumine (BSA). The relaxivity properties of the Gd complex labeled on BSA revealed a limited increase of both longitudinal and transversal relaxivities. This can be related to the partial replacement of the inner‐sphere water molecules by coordinating functions of the protein. Additionally, the Sm and Dy complexes are described and chemically characterized. Their photophysical properties were investigated by means of absorption, steady‐state and time‐resolved spectroscopy, evidencing efficient photosensitization of the lanthanide emission by ligand excitation (antenna effect). Luminescence lifetime measurements confirmed the presence of a water molecule in the first coordination sphere that partly explained the relatively poor luminescence properties of the Dy and Sm complexes in aqueous solutions. The spectroscopic properties of the series of complexes are questioned in terms of time‐resolved acquisition techniques. Finally, their availability for use in time‐resolved luminescence microscopy is demonstrated by staining experiments of rat brain slices, where the complex showed enhanced localization in some hydrophilic regions of the blood–brain barrier (BBB).(© Wiley‐VCH Verlag GmbH & Co. KGaA, 69451 Weinheim, Germany, 2008)

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Stéphanie Claudel‐Gillet

Prototype Protein Assembly as Scaffold for Time-Resolved Fluoroimmuno Assays

Lanthanide‐Based Conjugates as Polyvalent Probes for Biological Labeling

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