Promega's Cookie Policy

We use cookies and similar technologies to make our website work, run analytics, improve our website, and show you personalized content and advertising. Some of these cookies are essential for our website to work. For others, we won’t set them unless you accept them. To find out more about cookies and how to manage cookies, read our Cookie Policy.

Monitoring intracellular protein interactions using NanoLuc® Binary Technology (NanoBiT)

Part # PS272

Abstract

Brock Binkowski, Christopher Eggers, Braeden Butler, Marie Schwinn, Michael Slater, Thomas Machleidt, Mei Cong, Keith Wood & Frank Fan
Promega Corporation, 2800 Woods Hollow Rd, Madison, WI 53711-5399

Protein:protein interactions (PPIs) are essential to the cellular signal transduction pathways that contribute to cancer. Although numerous approaches exist to monitor PPIs in vitro, methods for intracellular detection have been more limited. We developed NanoLuc® Binary Technology (NanoBiT), a two-subunit system based on NanoLuc® luciferase that can be applied to the intracellular detection of PPIs. Large BiT (LgBiT; 18 kDa) and Small BiT (SmBiT; 11 amino acid peptide) subunits are expressed as fusions to proteins of interest, where PPI facilitates subunit complementation to give a bright, luminescent enzyme. Unlike related approaches where an enzyme or protein is simply split, LgBiT was independently optimized for structural stability and SmBiT was selected from a peptide library specifically for the PPI application. The result is a subunit pair that weakly associates (KD = 190 μM) yet still maintains 30% of the activity of full-length NanoLuc at saturation. In contrast to many split systems, the LgBiT:SmBiT interaction is reversible, allowing the detection of rapidly dissociating proteins. PPI dynamics can be followed in real-time in living cells using the Nano-Glo® Live Cell Reagent, a non-lytic detection reagent containing the cell-permeable furimazine substrate. Advantages over split systems include better sensitivity, reversibility, fusion to a peptide or a small, structurally stable protein domain, real-time measurements using a non-lytic assay format, and subunits with reduced affinity for self-association.

Printed in USA.