Salgado GF , Cazenave C , Kerkour A , Mergny JL .

	Fig. 1. Display of a typical tetrad of guanines, held by a network of hydrogen bonds, coordinating with a central metal cation in between two tetrads (a). Schematic representation of a stack of four tetrads commonly found in d(TG4T)4 (b). A 5 mm NMR Shigemi tube loaded with ∼200 Xenopus oocytes in 20% Ficoll buffer (c). Structure of ligand 360A (d). Imino signature of d(TG4T)4 in KCl buffer (e) obtained using a 1H–15N SOFAST-HMQC pulse sequence.
	Fig. 2. Time spectral evolution of d(TG4T)4 inside Xenopus oocytes. Spectra obtained after a period of 8 h (a), 16 h (b), 26 h (c) and 32 h (d) from assembly of ∼200 oocytes in the NMR tube. The sample buffer surrounding the oocytes inside the NMR tube was replaced every ∼12 h with a fresh solution, and a spectrum of the buffer where the oocytes were resuspended was measured under the same conditions as the control. All controls revealed that no apparent leakage occurred for periods up to 24 h. Between 26 and 32 h some leakage was visible and after 36 h there were several damaged cells and naturally the “leakage” into the surrounding buffer was substantial (data not shown). The results show that d(TG4T)4 is a robust structure that possesses a good spectral time-window (∼24 h), allowing the study of its interaction with ligands inside Xenopus laevis oocytes. Arrows indicate the most pronounced chemical shift deviation (∼0.1 ppm).
	Fig. 3. Probing the ligand interaction with d(TG4T)4 using 1H–15N SOFAST-HMQC in vitro and in-cell. (a) Ligand incubated and freely diffused from the NMR tube buffer to the oocytes interior, previously microinjected with d(TG4T)4. In (b) we can see the in-cell spectrum that resulted from the incubation of a 2.5 molar ratio of ligand 360A with d(TG4T)4 for a period of 4 hours (room temperature) prior to co-microinjection in ∼200 Xenopus oocytes. Part (c) depicts the NMR titration experiments in vitro without ligand (blue), after incubation with 1 (red) and 2.5 (black) molar ratios of ligand to moles of d(TG4T)4. (d) Shows different spectra from (a) and (b) overlaid with the black spectrum of (c). All spectra were acquired at 16 °C. The spectra clearly show important differences in the organization of the d(TG4T)4 tetrads after ligand binding in vitro compared to the changes observed in-cell. All spectra were analysed taking into account peak assignments described previously12,32 together with in vitro 1H–15N HSQC titration of d(TG4T)4 with 360A.

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