Native gel electrophoresis techniques, such as blue or clear native gel electrophoresis (BNE or CNE), are widely used to separate and characterize proteins. However, in high-resolution CNE, mild anionic or neutral detergents are often used at concentrations too low to prevent membrane-protein aggregation. Additionally, the identification of proteins is hampered by the lack of suitable molecular-weight markers, like those used in SDS-PAGE. Here, we introduce a novel approach that combines charged polymer-encapsulated nanodiscs and fluorescence correlation spectroscopy (FCS) to address both challenges. Membrane proteins are first extracted using Glyco-DIBMA, a negatively charged amphiphilic copolymer. This enables the spontaneous formation of nanodiscs harboring the fluorescently labeled target protein within a native-like lipid-bilayer environment, which is confirmed by FCS. The nanodiscs are then subjected to detergent-free CNE. As the number of protomers increases, the nanodiscs grow larger resulting in increased migration distances in CNE due to higher charge densities. Crucially, the nanodiscs remain intact throughout CNE, as demonstrated by FCS analysis of resolubilized bands excised from the gels. Moreover, the membrane proteins used in this study: a potassium channel (KvAP), a sodium channel (NavMs), a water channel (GlpF), and a urea channel (HpUreI) show only negligible aggregation, as shown by the fluorescent brightnesses and diffusion times of individual nanodiscs. Moreover, the oligomeric states of membrane proteins can be deduced from the brightness per nanodisc. Since purified membrane proteins remain within a native-like lipid-bilayer environment and avoid detergent exposure, they are immediately suitable for downstream structural and functional studies.

Native gel electrophoresis techniques, such as blue or clear native gel electrophoresis (BNE or CNE), are widely used to separate and characterize proteins. However, in high-resolution CNE, mild anionic or neutral detergents are often used at concentrations too low to prevent membrane-protein aggregation. Additionally, the identification of proteins is hampered by the lack of suitable molecular-weight markers, like those used in SDS-PAGE. Here, we introduce a novel approach that combines charged polymer-encapsulated nanodiscs and fluorescence correlation spectroscopy (FCS) to address both challenges. Membrane proteins are first extracted using Glyco-DIBMA, a negatively charged amphiphilic copolymer. This enables the spontaneous formation of nanodiscs harboring the fluorescently labeled target protein within a native-like lipid-bilayer environment, which is confirmed by FCS. The nanodiscs are then subjected to detergent-free CNE. As the number of protomers increases, the nanodiscs grow larger resulting in increased migration distances in CNE due to higher charge densities. Crucially, the nanodiscs remain intact throughout CNE, as demonstrated by FCS analysis of resolubilized bands excised from the gels. Moreover, the membrane proteins used in this study: a potassium channel (KvAP), a sodium channel (NavMs), a water channel (GlpF), and a urea channel (HpUreI) show only negligible aggregation, as shown by the fluorescent brightnesses and diffusion times of individual nanodiscs. Moreover, the oligomeric states of membrane proteins can be deduced from the brightness per nanodisc. Since purified membrane proteins remain within a native-like lipid-bilayer environment and avoid detergent exposure, they are immediately suitable for downstream structural and functional studies.

Fluorescent labeling of membrane proteins is essential for exploring their functions, signaling pathways, interaction partners, and structural dynamics. Organic fluorophores are commonly used for this purpose due to their favorable photophysical properties and photostability. However, a persistent challenge is the inaccessibility of surface-exposed cysteine residues required for site-specific labeling, as these residues often become sequestered within detergent micelles during protein extraction. To address this limitation, we developed an approach based on polymer-encapsulated nanodiscs that preserves the protein’s native-like lipid-bilayer environment while ensuring accessibility of surface-exposed cysteine residues. In this method, His-tagged proteins embedded in native nanodiscs are retained on a nickel affinity column, allowing for simultaneous purification and labeling by adding fluorescent dyes. This versatile technique was demonstrated with two challenging-to-label membrane proteins, the potassium channel KvAP and the urea channel HpUreI, for which detergent-based labeling had failed. It opens new possibilities for studying a wide range of fluorescently labeled membrane proteins in near-native states, advancing applications in biophysics, structural biology, and drug discovery.

Fluorescent labeling of membrane proteins is essential for exploring their functions, signaling pathways, interaction partners, and structural dynamics. Organic fluorophores are commonly used for this purpose due to their favorable photophysical properties and photostability. However, a persistent challenge is the inaccessibility of surface-exposed cysteine residues required for site-specific labeling, as these residues often become sequestered within detergent micelles during protein extraction. To address this limitation, we developed an approach based on polymer-encapsulated nanodiscs that preserves the protein’s native-like lipid-bilayer environment while ensuring accessibility of surface-exposed cysteine residues. In this method, His-tagged proteins embedded in native nanodiscs are retained on a nickel affinity column, allowing for simultaneous purification and labeling by adding fluorescent dyes. This versatile technique was demonstrated with two challenging-to-label membrane proteins, the potassium channel KvAP and the urea channel HpUreI, for which detergent-based labeling had failed. It opens new possibilities for studying a wide range of fluorescently labeled membrane proteins in near-native states, advancing applications in biophysics, structural biology, and drug discovery.