Bio-layer Interferometry for Measuring Kinetics of Protein-protein Interactions and Allosteric Ligand Effects

Naman B. Shah; Thomas M. Duncan

doi:10.3791/51383

Bio-layer Interferometry for Measuring Kinetics of Protein-protein Interactions and Allosteric Li...

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JoVE Journal Chemistry

Bio-layer Interferometry for Measuring Kinetics of Protein-protein Interactions and Allosteric Ligand Effects

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13:57 min

February 18, 2014

DOI: 10.3791/51383-v

Naman B. Shah¹, Thomas M. Duncan¹

¹Department of Biochemistry and Molecular Biology,SUNY Upstate Medical University

Overview

This article presents protocols for measuring protein-protein interactions using Bio-layer Interferometry (BLI). The focus is on the interaction between F-type ATP synthase and its ε subunit, which plays a role in energy metabolism in bacteria.

Key Study Components

Area of Science

Neuroscience
Biochemistry
Protein Interactions

Background

F-type ATP synthase is crucial for cellular energy production.
The ε subunit can inhibit the activity of ATP synthase.
Understanding these interactions is important for insights into metabolic regulation.
Bio-layer Interferometry allows real-time measurement of these interactions.

Purpose of Study

To measure the kinetics of protein-protein interactions.
To investigate the allosteric effects of small ligands on these interactions.
To adapt BLI for studying the catalytic complex of ATP synthase.

Methods Used

Preparation of proteins with biotin for immobilization.
Use of streptavidin-coated biosensors for binding assays.
Real-time measurement of binding and dissociation using optical interference.
Analysis of protein complexes formed during the interaction.

Main Results

Successful measurement of binding kinetics between ATP synthase and its ε subunit.
Real-time data on the dissociation of protein complexes.
Insights into the allosteric regulation of ATP synthase activity.
Demonstration of BLI as a valuable tool for studying protein interactions.

Conclusions

BLI is effective for studying protein-protein interactions.
The interaction between ATP synthase and its ε subunit is critical for understanding metabolic control.
Future studies can build on these methods to explore other protein interactions.

Frequently Asked Questions

What is Bio-layer Interferometry?

Bio-layer Interferometry (BLI) is a technique used to measure the binding interactions between biomolecules in real-time.

Why is F-type ATP synthase important?

F-type ATP synthase is essential for ATP production in cells, making it a key player in energy metabolism.

How does the ε subunit affect ATP synthase?

The ε subunit can inhibit ATP synthase activity, influencing energy production in bacterial cells.

What are the advantages of using BLI?

BLI allows for real-time monitoring of binding events without the need for labels, providing accurate kinetic data.

Can BLI be used for other protein interactions?

Yes, BLI is versatile and can be applied to study various protein-protein and protein-ligand interactions.

The protocols here describe kinetic assays of protein-protein interactions with Bio-layer Interferometry. F-type ATP synthase, which is involved in cellular energy metabolism, can be inhibited by its ε subunit in bacteria. We have adapted Bio-layer Interferometry to study interactions of the catalytic complex with ε’s inhibitory C-terminal domain.

The overall goal of the following experiment is to measure kinetics of protein, protein interactions and the allosteric effects of small ligands on those interactions using biolayer interferometry, BLI. This is achieved by preparing one of the proteins with specific biotin and immobilizing it on the surface of strep. Aden coated biosensors in parallel.

As a second step, the sensor bound protein is exposed to buffer containing its binding partner, and binding is measured in real time by its effect on optical interference at the sensor surface. Next, each sensor is transferred to buffer without the binding partner in order to measure realtime dissociation of the protein. Protein complexes.

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