NanoLuc® Luciferase

NanoLuc® luciferase is a small (19.1kDa), highly-stable enzyme derived from a deep-sea shrimp and engineered for optimal performance as a luminescent reporter. The enzyme is about 100-fold brighter than either firefly (Photinus pyralis) or Renilla reniformis luciferase using a novel substrate, furimazine, to produce high intensity, glow-type luminescence. The luminescent reaction is ATP-independent and designed to suppress background luminescence for maximal assay sensitivity. In addition to use as a traditional genetic reporter, the small size and extreme brightness of NanoLuc® luciferase make it an ideal protein fusion partner, expanding its utility to the study of live-cell protein dynamics.

NanoLuc® Binary Technology (NanoBiT) is a structural complementation reporter system based on NanoLuc® luciferase. It is composed of an optimized LgBiT subunit (18kDa) and a small 11 amino acid complimentary peptide subunit which can have varying affinities for LgBiT. The low affinity complimentary peptide is called SmBiT. For the study of cellular protein:protein interactions, the LgBiT and SmBiT subunits are expressed as fusions to target proteins of interest and expressed in cells. When the two proteins interact, the subunits come together to form an active NanoBiT® enzyme and generate a bright luminescent signal in the presence of Nano-Glo® substrate. This technology enables the study of real-time protein-protein interactions in live cells with high sensitivity and specificity.

The low affinity LgBiT and SmBiT subunits  have been further adapted for immunodetection giving rise to Lumit® Immunoassays. In this configuration of NanoBiT® technology antibodies are chemically labeled with LgBiT and SmBiT subunits. When these labeled antibodies bind to the target analyte, SmBiT and LgBiT come into close proximity, forming the active NanoBiT® luciferase and generating a luminescent signal in the presence of Lumit® detection reagents. Lumit® Immunoassays offer a simple alternative to traditional ELISA assays with fewer wash steps and have been developed in direct, indirect, and competitive binding formats for a number of popular targets including cytokines and glucagon as well as DIY solutions.

The LgBiT subunit can also be complemented by a high affinity small subunit called HiBiT to create the HiBiT Protein Tagging System. In this configuration of the technology, LgBiT and HiBiT spontaneously interact to reconstitute the bright NanoBiT® enzyme. HiBiT is used as a quantitative protein tag that can be introduced through traditional cloning methods or at endogenous loci through CRISPR-Cas9 gene editing. The HiBiT-tagged fusion protein can be detected using LgBiT-containing detection reagents, in live cells co-expressing the LgBiT subunit, or directly using a highly sensitive anti-HiBiT monoclonal antibody. The HiBiT protein tagging system is a simple and flexible protein detection option with high sensitivity to accurately detect even low abundance proteins at endogenous levels of expression.

NanoBRET® technology is a bioluminescence resonance energy transfer (BRET)-based method used to measure either protein:protein interactions or compound target engagement in live cells. NanoLuc® luciferase is an optimal BRET energy donor due to its bright signal and narrow, blue-shifted emission spectrum. For NanoBRET® Protein:Protein Interaction Assays, one protein partner is expressed as a NanoLuc® Luciferase fusion. The second protein is expressed as a HaloTag® fusion, which is labeled with a cell permeable NanoBRET® 618 fluorophore. The bright, blue-shifted donor signal and optimized red-shifted acceptor create optimal spectral overlap, resulting in increased signal and lower background compared to conventional BRET assays. Predesigned assays for a number of popular targets, DIY systems, and custom NanoBRET® PPI development services are available.

NanoBRET® technology can also be applied for live-cell compound binding assays, referred to as NanoBRET® Target Engagement (TE). In this assay format, the target protein is expressed in cells as a NanoLuc® luciferase fusion. A cell-permeable fluorescent NanoBRET® tracer, which reversibly binds to the target protein, is added. Fluorescent tracer binding to the NanoLuc® fusion protein results in energy transfer and a BRET signal. Test compounds that bind to the target protein compete with the tracer and result in loss of NanoBRET® signal enabling quantitative measurement of intracellular compound affinity. NanoBRET® TE can also be used to calculate fractional occupancy, compound selectivity, intracellular compound availability and compound residence time. Recent configurations of NanoBRET® TE use reconstituted NanoBiT® luciferase as the energy donor, enabling the study of target engagement on intracellular protein complexes. Pre-designed assays are available for a number of key drug targets, including 340+ kinases. DIY tools, and custom development  and cellular kinase selectivity profiling services are also available.