Abstract

We have developed a rapid and sensitive single-well dual-parametric method introduced in linked RAS nucleotide exchange and RAS/RAF-RBD interaction assays. RAS mutations are frequent drivers of multiple different human cancers, but the development of therapeutic strategies has been challenging. Traditionally, efforts to disrupt the RAS function have focused on nucleotide exchange inhibitors, GTP-RAS interaction inhibitors, and activators increasing GTPase activity of mutant RAS proteins. As the amount of biological knowledge grows, targeted biochemical assays enabling high-throughput screening have become increasingly interesting. We have previously introduced a homogeneous quenching resonance energy transfer (QRET) assay for nucleotide binding studies with RAS and heterotrimeric G proteins. Here, we introduce a novel homogeneous signaling technique called QTR-FRET, which combine QRET technology and time-resolved Förster resonance energy transfer (TR-FRET). The dual-parametric QTR-FRET technique enables the linking of guanine nucleotide exchange factor-induced Eu3+-GTP association to RAS, monitored at 615 nm, and subsequent Eu3+-GTP-loaded RAS interaction with RAF-RBD-Alexa680 monitored at 730 nm. Both reactions were monitored in a single-well assay applicable for inhibitor screening and real-time reaction monitoring. This homogeneous assay enables separable detection of both nucleotide exchange and RAS/RAF interaction inhibitors using low nanomolar protein concentrations. To demonstrate a wider applicability as a screening and real-time reaction monitoring method, the QTR-FRET technique was also applied for G(i)α GTP-loading and pertussis toxin-catalyzed ADP-ribosylation of G(i)α, for which we synthesized a novel γ-GTP-Eu3+ molecule. The study indicates that the QTR-FRET detection technique presented here can be readily applied to dual-parametric assays for various targets.

Highlights

  • We introduced a method named as QTR-FRET, which was demonstrated to reduce background signals in time-resolved Förster resonance energy transfer (TR-FRET) assays.[41]

  • We studied Eu3+-GTP binding to KRAS in the coupled reaction to monitor active KRAS

  • With 50 nM KRAS, especially the TR-FRET signal level monitored at 730 nm was compromised. These results clearly indicate that the single-well QTR-FRET assay can be used, instead of two separate assays, to monitor nucleotide exchange and KRAS/RAF-RBD interactions at the same time in real time

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Summary

■ RESULTS AND DISCUSSION

Many enzymatic reactions are coupled with other reactions occurring simultaneously or in a specific order. We performed combined real-time measurements using a reaction where both Eu3+-GTP and RBD-Alexa[680] were present before the SOScat addition These assays confirmed the observation that K27 blocks both nucleotide exchange and subsequent KRAS/RAF-RBD interaction, but K55 blocks only the interaction between Eu3+-GTP-loaded KRAS and RBDAlexa[680] (Figures 2 and 3). To study if glycosylation would block the KRAS/RAFRBD interaction, we modified the QTR-FRET assay scheme by performing the nucleotide exchange with either Eu3+-GTP or Eu3+-GDP before the TpeL reaction. The assay confirmed the expected KRAS/RAF-RBD interaction blocking in TpeL titration with UDP-GlcNAc (Figure 4B) It proved the correct assay functionality as no TR-FRET signal was observed after RBD-Alexa[680] addition if Eu3+-GDP was used in KRAS nucleotide loading. As seen with KRAS, the addition of preformed γ-GTP-Eu3+ and the MG mixture solution can improve the QTR-FRET functionality further (data not shown)

■ CONCLUSIONS
■ ACKNOWLEDGMENTS
■ REFERENCES

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