Structural Flexibility and Disassembly Kinetics of Single Ferritin Molecules Using Optical Nanotweezers

Yousefi, Arman; Zheng, Ze; Zargarbashi, Saaman; Assadipapari, Mahya; Hickman, Graham J.; Parmenter, Christopher D. J.; Bueno-Alejo, Carlos J.; Sanderson, Gabriel; Craske, Dominic; Xu, Lei; Perry, Carole C.; Rahmani, Mohsen; Ying, Cuifeng

doi:10.1021/acsnano.4c01221

ACS Nano

2024

DOI: 10.1021/acsnano.4c01221

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Structural Flexibility and Disassembly Kinetics of Single Ferritin Molecules Using Optical Nanotweezers

Arman Yousefi,

Ze Zheng,

Saaman Zargarbashi

et al.

Abstract: Ferritin, a spherical protein shell assembled from 24 subunits, functions as an efficient iron storage and release system through its channels. Understanding how various chemicals affect the structural behavior of ferritin is crucial for unravelling the origins of iron-related diseases in living organisms including humans. In particular, the influence of chemicals on ferritin's dynamics and iron release is barely explored at the single-protein level. Here, by employing optical nanotweezers using double-nanohol… Show more

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Cited by 2 publications

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Challenges in Exploiting Human H Ferritin Nanoparticles for Drug Delivery: Navigating Physiological Constraints

Macone,

Cappelletti,

Incocciati

et al. 2024

WIREs Nanomed Nanobiotechnol

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Over the past two decades, ferritin has emerged as a promising nanoparticle for drug delivery, catalyzing the development of numerous prototypes capable of encapsulating a wide array of therapeutic agents. These ferritin‐based nanoparticles exhibit selectivity for various molecular targets and are distinguished by their potential biocompatibility, unique symmetrical structure, and highly controlled size. The hollow interior of ferritin nanoparticles allows for efficient encapsulation of diverse therapeutic agents, enhancing their delivery and effectiveness. Despite these promising features, the anticipated clinical advancements have yet to be fully realized. As a physiological protein with a central role in both health and disease, ferritin can exert unexpected effects on physiology when employed as a drug delivery system. Many studies have not thoroughly evaluated the pharmacokinetic properties of the ferritin protein shell when administered in vivo, overlooking crucial aspects such as biodistribution, clearance, cellular trafficking, and immune response. Addressing these challenges is crucial for achieving the desired transition from bench to bedside. Biodistribution studies need to account for ferritin's natural accumulation in specific organs (liver, spleen, and kidneys), which may lead to off‐target effects. Moreover, the mechanisms of clearance and cellular trafficking must be elucidated to optimize the delivery and reduce potential toxicity of ferritin nanoparticles. Additionally, understanding the immune response elicited by exogenous ferritin is essential to mitigate adverse reactions and enhance therapeutic efficacy. A comprehensive understanding of these physiological constraints, along with innovative solutions, is essential to fully realize the therapeutic potential of ferritin nanoparticles paving the way for their successful clinical translation.

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Challenges in Exploiting Human H Ferritin Nanoparticles for Drug Delivery: Navigating Physiological Constraints

Macone,

Cappelletti,

Incocciati

et al. 2024

WIREs Nanomed Nanobiotechnol

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Energy landscape of conformational changes for a single unmodified protein

Peters,

Zhao,

George

et al. 2024

npj Biosensing

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Resolving the free energy landscapes that govern protein biophysics has been obscured by ensemble averaging. While the folding dynamics of single proteins have been observed using fluorescent labels and/or tethers, a simpler and more direct measurement of the conformational changes would not require modifications to the protein. We use nanoaperture optical tweezers to resolve the energy landscape of a single unmodified protein, Bovine Serum Albumin (BSA), and quantify changes in the three-state conformation dynamics with temperature. A Markov model with Kramers’ theory transition rates is used to model the dynamics, showing good agreement with the observed state transitions. This first look at the intrinsic energy landscape of proteins provides a transformative tool for protein biophysics and may be applied broadly, including mapping out the energy landscape of particularly challenging intrinsically disordered proteins.

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Structural Flexibility and Disassembly Kinetics of Single Ferritin Molecules Using Optical Nanotweezers

Cited by 2 publications

References 59 publications

Challenges in Exploiting Human H Ferritin Nanoparticles for Drug Delivery: Navigating Physiological Constraints

Challenges in Exploiting Human H Ferritin Nanoparticles for Drug Delivery: Navigating Physiological Constraints

Energy landscape of conformational changes for a single unmodified protein

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