The majority of conventional fluorophores

The majority of conventional fluorophores I-BET151 chemical structure have a small (10–30 nm) Stokes shift (the spectral separation between the emission and absorption maxima) causing a significant spectral overlap. High molar extinction of the common fluorescent dyes also contributes to quenching. On the contrary, lanthanide luminescent probes possess an extremely large Stokes shift (150–250 nm), which prevents efficient energy transfer between the excited and non-excited fluorophore molecules [12]. Previously, this approach

was explored on streptavidin with Eu3+ chelate [12]. Parent protein, avidin possesses 32 lysine residues at which luminescent labels can be attached, which makes it a superior scaffold for multiple label attachment Selleckchem Onalespib comparing to streptavidin (which has 12 lysine residues). In the present study, we obtained avidin conjugates with a new generation of high-quantum-yield lanthanide chelates of Eu3+ and Tb3+ containing cs124 and cs124-CF3 antennae-fluorophores (Fig. 1) synthesized by us in the course of current and previous studies [13]. We find that unlike typical fluorophore BODIPY, the light emission efficiency of the Eu3+ probes was not affected by self-quenching. In fact, the cumulative luminescence of the conjugate as a function of the number of the attached residues displayed a super-linear behavior, suggesting synergistic

effect [12]. We found that this effect was due to the enhanced antenna-to-lanthanide energy transfer. We tested the same approach with Tb3+-based luminescent probes, which

possess higher quantum yield compared to the cs124 Eu3+ chelates. Significant self-quenching Astemizole was observed when these multiple Tb3+ probes were attached to avidin. However, introduction of a biphenyl spacer between the chelate and the crosslinking group completely suppressed the quenching, yielding highly bright conjugates. The obtained luminescent avidin constructs were used for labeling bacterial and mammalian cells giving highly contrast images in time-resolved detection mode. These new probes can find a broad range of applications in the biological and biomedical fields that rely on high detection sensitivity. The following reagents were purchased from Sigma Aldrich: Avidin, diethylenetriaminepentaacetic acid dianhydride (DTPA), triethylamine; butylamine; 1,3-phenylenediamine; ethyl 4,4,4-trifluoroacetoacetate; ethylacetoacetate, 1,3-dicyclohexylcarbodiimide (DCC), ethylenedianime; methylbromacetate; anhydrous dimethylformamide and dimethylsulfoxide; 1-butanol, ethylacetate, chloroform; acetonitrile; ethanol; sodium and potassium hydroxide; TbCl3 and EuCl3; silica gel TLC plates on aluminum foil (200 μm layer thick with a fluorescent indicator). Distilled and deionized water (18 MΩ cm−1) was used.

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