Editorial Feature

Nanodiscs: What Are They and How Are They Shaping the Future of Medicine?

Nanodiscs are synthetic phospholipid particles with a distinct morphology and size that enhance their efficiency in drug delivery applications.1 First developed by Sligar et al. in the early 2000s, these model membrane systems measure around 10 nm in diameter with a thickness between 4.6 and 5.6 nm.2 Structurally, nanodiscs are similar to high-density lipoproteins.

Nanodiscs: What Are They and How Are They Shaping the Future of Medicine?

Image Credit: Kateryna Kon/Shutterstock.com

In medical applications, nanotechnology advancements have positioned nanodiscs as valuable tools for diagnosing and treating various diseases. These disc-shaped particles can preserve membrane proteins in their functional state outside the cellular environment, making them valuable in biomedical applications.1

Nanodiscs stabilize fragile proteins, enhance drug delivery, and provide a structured bilayer surface, proving highly effective for studying cellular signaling complexes on membrane surfaces.1 Their versatility continues to support advancements in modern medicine.

Classification of Nanodiscs

Nanodiscs can be categorized based on the stabilizer used to maintain their structure.3

Membrane Scaffold Protein Nanodiscs

Membrane scaffold protein (MSP) nanodiscs use amphipathic membrane scaffold proteins as stabilizers. These scaffold proteins encircle a stable, discoidal phospholipid bilayer containing embedded transmembrane proteins, forming the nanodisc structure.

MSP is typically a truncated form of apolipoprotein A-I (apoA-I), a component of high-density lipoproteins. It wraps around a small segment of the phospholipid bilayer to create the disc-shaped nanodisc.3

MSP provides a hydrophobic surface for lipid tails and a hydrophilic outer surface, making nanodiscs highly soluble in water. During assembly, excess detergent is used and later removed with bio-beads, allowing membrane proteins to stay in solution without detergents.

These nanodiscs are well-suited for studying membrane proteins in both prokaryotic and eukaryotic systems, including key structures like transporters, ion channels, and G protein-coupled receptors (GPCRs).4

Saposin nanodiscs

The saposin protein family consists of four members, saposin A–D, each with a molecular weight of around 10 kDa. Saposin A is most commonly used for assembling saposin nanodiscs. Frauenfeld et al. (2016) demonstrated the use of saposin proteins as scaffolds to reconstitute various membrane proteins within a phospholipid environment.5

Saposin nanodiscs self-assemble from saposin proteins, phospholipids, and membrane proteins into a stable structure that is adaptable to various membrane protein sizes without requiring scaffold construction or lipid ratio adjustments.3 Although a recent development, they are widely applied in structure-based techniques like NMR and cryo-EM, providing distinct advantages for both methods.

For example, in a solution-based NMR study, three membrane proteins were successfully incorporated into saposin nanodiscs: bacterial outer membrane protein X (OmpX), sensory receptor rhodopsin II (pSRII), and the β1-adrenergic receptor (β1AR).6

Copolymer Nanodiscs

Copolymer nanodiscs extract membrane proteins directly from cell membranes, preserving their native state and endogenous phospholipids. Synthetic polymers encapsulate the proteins into nanosized discs, stabilizing a portion of the native membrane. These nanodiscs use the cell's natural phospholipids, with the polymer acting as both solubilizer and stabilizer, removing the need for additional detergents.3

Synthetic copolymers like styrene-maleic acid (SMA), diisobutylene maleic acid (DIBMA), and polymethacrylate (PMA) are used to stabilize nanodiscs, maintaining the lipid bilayer in aqueous solutions. These non-protein polymers self-assemble into stable structures and offer higher purity than MSP nanodiscs. They are widely used in membrane protein research, drug delivery, and biosensor applications.3

SMA nanodiscs have been successfully employed to purify and study integral membrane proteins from bacterial and eukaryotic systems. Once reconstituted into SMA nanodiscs, these proteins are well-suited for high-resolution structural analysis via cryo-EM, as well as for receptor-ligand binding assays and functional activity studies.7

Applications of Nanodiscs in Medicine

Drug Delivery

Nanodiscs offer an effective platform for enhancing drug delivery systems, particularly for drugs with low water solubility. Their lipid bilayer structure can encapsulate hydrophobic drugs, protecting them from premature degradation while enhancing their bioavailability.3

Chen et al. designed lipid nanodiscs functionalized with cyclic RGD peptide (cRGD) on either the edges or planes, creating two distinct anisotropic targeting nanocarriers (E-cRGD-NDs and P-cRGD-NDs) for siRNA delivery.8 E-cRGD-NDs demonstrated significant advantages in siRNA loading, cellular uptake, gene silencing efficiency, protein expression, and in vivo performance.

In a 2023 study, Yu et al. developed antibodies targeting matrix protein 2 (M2) of the influenza A virus. M2 (1-46) was incorporated into nanodiscs to form a membrane-embedded tetrameric structure, closely resembling its natural physiological state within the influenza virus envelope.9

Companies like Cube Biotech are actively developing nanodisc-based drug delivery systems that can be customized for different therapeutic needs. Its lipid-based nanodiscs offer a flexible platform for encapsulating and delivering various pharmaceuticals, including biologics and small-molecule drugs.

Vaccine Development

Nanodiscs have emerged as promising platforms for developing personalized tumor immunotherapy and vaccines against infectious diseases. They can be loaded with antigenic peptides or tumor markers, preserving the structure and activity of membrane proteins, which makes them highly immunogenic.1

Aldehyde dehydrogenase (ALDH) has been extensively used as a marker for isolating cancer stem cells (CSCs). These cells are characterized by high proliferation rates and play a role in tumor metastasis and recurrence.10 ALDH-positive CSCs have been identified in over 20 different tumor types.1

In a 2020 study, James J. Moon's research group developed synthetic nanodiscs for vaccines targeting ALDHhigh CSCs. These nanodiscs improve antigen delivery to lymph nodes and trigger strong ALDH-specific T-cell responses, offering a promising new approach for cancer immunotherapy focused on CSCs.11

Diagnostic Tools

Nanodiscs offer considerable potential for creating advanced diagnostic tools. Their ability to stabilize membrane proteins in their native conformation makes them excellent tools for studying protein-protein interactions, enzymatic functions, and other cellular processes.12

NMR has long been used to gather structural information on soluble proteins. Rienstra and colleagues were the first to report solid-state NMR (ssNMR) spectra of nanodiscs, confirming that membrane scaffold proteins are organized in a "belt" configuration.13

Recently, there has been substantial growth in the use of both solution and ssNMR methods with nanodiscs, providing critical insights into the structure and function of membrane proteins. For instance, the complete three-dimensional structure of OmpX in nanodiscs, obtained through solution NMR, highlighted the ability to detect subtle conformational differences in a native bilayer environment.14

Conclusion

Nanodiscs represent a transformative innovation in medicine, with applications spanning protein stabilization, drug delivery, vaccine development, and diagnostics. Their ability to mimic natural cell membranes while remaining stable in various environments allows for broad applications in both research and clinical contexts.

Looking ahead, the future of nanodiscs in healthcare is strong. Continued research into polymer-based and MSP nanodiscs could lead to more robust and customizable platforms for therapeutic and diagnostic use.

As more companies and research institutions explore these applications, nanodiscs are likely to support more precise, effective, and personalized treatments in modern medicine.

More from AZoNano: What are Mesoporous Silica Nanoparticles?

References and Further Reading

1.        Mu, Q., Deng, H., An, X., Liu, G. Liu, C. (2024). Designing nanodiscs as versatile platforms for on-demand therapy. Nanoscale. https://pubs.rsc.org/en/content/articlelanding/2024/nr/d3nr05457h 

2.        Nath, A., Atkins, WM. Sligar, SG. (2007). Applications of Phospholipid Bilayer Nanodiscs in the Study of Membranes and Membrane Proteins. Biochemistry. https://pubmed.ncbi.nlm.nih.gov/17263563/

3.        Dong, Y., Tang, H., Dai, H., Zhao, H. Wang, J. (2024). The application of nanodiscs in membrane protein drug discovery & development and drug delivery. Front. Chem. https://pmc.ncbi.nlm.nih.gov/articles/PMC11445163/

4.        Zhang, M. et al. (2021). Cryo-EM structure of an activated GPCR–G protein complex in lipid nanodiscs. Nat. Struct. Mol. Biol. https://pubmed.ncbi.nlm.nih.gov/33633398/

5.        Frauenfeld, J. et al. (2016). A saposin-lipoprotein nanoparticle system for membrane proteins. Nat. Methods. https://pubmed.ncbi.nlm.nih.gov/26950744/

6.        Chien, C.-T. H. et al. (2017). An adaptable phospholipid membrane mimetic system for solution NMR studies of membrane proteins. J. Am. Chem. Soc. https://pubmed.ncbi.nlm.nih.gov/28990386/

7.        Swainsbury, DJK. et al. (2023). Cryo-EM structure of the four-subunit Rhodobacter sphaeroides cytochrome bc 1 complex in styrene maleic acid nanodiscs. Proc. Natl. Acad. Sci. https://www.pnas.org/doi/10.1073/pnas.2217922120

8.        Chen, X., Zhou, Y., Zhao, Y. Tang, W. (2023). Targeted degradation of extracellular secreted and membrane proteins. Trends Pharmacol. Sci. https://pubmed.ncbi.nlm.nih.gov/37758536/

9.        Yu, C. et al. (2023). Screening and characterization of inhibitory vNAR targeting nanodisc-assembled influenza M2 proteins. Iscience. https://pubmed.ncbi.nlm.nih.gov/36570769/

10.     Marcato, P., Dean, CA., Giacomantonio, CA. Lee, PWK. (2011). Aldehyde dehydrogenase: its role as a cancer stem cell marker comes down to the specific isoform. Cell cycle. https://pubmed.ncbi.nlm.nih.gov/21552008/

11.     Hassani Najafabadi, A. et al. (2020). Cancer immunotherapy via targeting cancer stem cells using vaccine nanodiscs. Nano Lett. https://pmc.ncbi.nlm.nih.gov/articles/PMC7572838/

12.     Denisov, IG. Sligar, SG. (2017). Nanodiscs in membrane biochemistry and biophysics. Chem. Rev. https://pubmed.ncbi.nlm.nih.gov/28177242/

13.     Li, Y., Kijac, AZ., Sligar, SG., Rienstra, CM. (2006). Structural analysis of nanoscale self-assembled discoidal lipid bilayers by solid-state NMR spectroscopy. Biophys. J. https://pubmed.ncbi.nlm.nih.gov/16905610/

14.     Hagn, F., Wagner, G. (2015). Structure refinement and membrane positioning of selectively labeled OmpX in phospholipid nanodiscs. J. Biomol. NMR. https://pubmed.ncbi.nlm.nih.gov/25430058/

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Atif Suhail

Written by

Atif Suhail

Atif is a Ph.D. scholar at the Indian Institute of Technology Roorkee, India. He is currently working in the area of halide perovskite nanocrystals for optoelectronics devices, photovoltaics, and energy storage applications. Atif's interest is writing scientific research articles in the field of nanotechnology and material science and also reading journal papers, magazines related to perovskite materials and nanotechnology fields. His aim is to provide every reader with an understanding of perovskite nanomaterials for optoelectronics, photovoltaics, and energy storage applications.

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