Europium cryptate-tethered ribonucleotide for the labeling of RNA and its detection by time-resolved amplification of cryptate emission.

TRACE (time-resolved amplification of cryptate emission), also called HTRF for pharmaceutical applications, is a homogeneous time-resolved fluorescence technique well adapted for the study of molecular interactions. It is based on fluorescence resonance energy transfer (FRET) between europium trisbipyridine cryptate (TBPEu(3+)) as energy donor and cross-linked allophycocyanin, symbolized by XL665, as acceptor, leading to a long-lived FRET signal. TBPEu(3+)-labeled uridine triphosphate (UTP), referred to as K-11-UTP in the text, was obtained by coupling TBPEu(3+) moiety to a C-5 functionalized UTP analog. K-11-UTP can be directly incorporated in RNA strands during enzymatic synthesis. This was demonstrated in an in vitro transcription reaction promoted by T(7) RNA polymerase. The reaction was performed in the presence of K-11-UTP and biotin-labeled cytidine triphosphate (biotin-16-CTP) in admixture with natural ribonucleotides. After the addition of streptavidin-XL665 conjugate (SA-XL665), which binds on biotinylated cytidine residues, a long-lived FRET signal was obtained. This proved that both europium cryptate and biotin were incorporated into the same RNA strand and are close enough to generate a FRET signal. The study of this FRET detection assay format showed that such doubly labeled RNA can be easily detected even when a very low percentage of K-11-UTP is used (less than 1% of total UTP concentration). Europium-cryptate-labeled RNA can also be monitored using a homogeneous hybridization assay format involving a biotinylated probe. After the addition of SA-XL665, the FRET signal generated demonstrates the formation of RNA:DNA hybrids. Europium-cryptate-labeled nucleotide thus gives access to a new type of RNA nonisotopic labeling and homogeneous detection assays.