Molecular jenga: the percolation phase transition (collapse) in virus capsids

Brunk, Nicholas E.; Lee, Lye Siang; Glazier, James A.; Butske, William; Zlotnick, Adam

doi:10.1088/1478-3975/aac194

Cited by 11 publications

(21 citation statements)

References 57 publications

(94 reference statements)

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“… 16 , 18 The simplicity of these comparably limited, strictly topological assumptions is reflected in the ease of the percolation model’s implementation, which is much simpler than large-scale reaction kinetic models and molecular dynamics simulations. Nevertheless, this strictly topological percolation model and its prediction of the fragmentation threshold of HBV is in excellent agreement with experiment as outlined above, 7 , 19 demonstrating that our approach captures essential features of capsid fragmentation. Indeed, our approach makes predictions that are testable experimentally and will enable experimentalists to detect the equivalent thresholds for any virus of interest.…”

Section: Discussionsupporting

confidence: 81%

“…The maximal fraction of subunits that could be removed before capsid fragmentation occurred was identified, and agreed well with the predicted value of the fragmentation threshold ( f T ) of approximately 26%. 19 This threshold was also observed for capsids assembled from passivated subunits only via the titration of mild amounts of denaturant. This strongly suggests that the theoretical predictions made here are robust against the specifics of the experimental setup.…”

Section: Resultsmentioning

confidence: 78%

“…As in previous work, we refer to a complete capsid as and any partially disassembled capsid randomly missing i tiles (vertices v ) as . 19 The fraction of deleted vertices is thus f v d = i / V 0 and the fraction remaining is p i v = 1 – f v d , both of which are symmetric common variables in percolation theory. We use here the fraction deleted, f v d .…”

Section: Resultsmentioning

confidence: 99%

“…This is consistent with our previous work on the fragmentation threshold of Hepatitis B virus, validated by single-particle detection methods with near single-subunit resolution, such as Charge Detection Mass Spectroscopy (CDMS) and nanofluidics. 7 , 19 Such methods detect any dissociating singlets, much like the f T metric itself. The observed sensitivity to the possibility of fragmented singlets or small clusters is also consistent with the size dependence of the fragmentation threshold f T established here, which is not the case for the percolation threshold p c in general.…”

Section: Discussionmentioning

confidence: 99%

“…Single particle mass spectrometry was used to interrogate the resulting particles, revealing a marked absence of any particles fewer than 90 protein dimers, in excellent agreement with the theoretically predicted fragmentation threshold. 7 , 19 However, the dependence of capsid disassembly on capsid geometry and topology has not been investigated before. We are closing this gap here by developing a generalized percolation theory for virus capsid disassembly.…”

Section: Introductionmentioning

confidence: 99%

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Percolation Theory Reveals Biophysical Properties of Virus-like Particles

Brunk

Twarock

2021

ACS Nano

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The viral protein containers that encapsulate a virus’ genetic material are repurposed as virus-like particles in a host of nanotechnology applications, including cargo delivery, storage, catalysis, and vaccination. These viral architectures have evolved to sit on the knife’s edge between stability, to provide adequate protection for their genetic cargoes, and instability, to enable their efficient and timely release in the host cell environment upon environmental cues. By introducing a percolation theory for viral capsids, we demonstrate that the geometric characteristics of a viral capsid in terms of its subunit layout and intersubunit interaction network are key for its disassembly behavior. A comparative analysis of all alternative homogeneously tiled capsid structures of the same stoichiometry identifies evolutionary drivers favoring specific viral geometries in nature and offers a guide for virus-like particle design in nanotechnology.

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Section: Discussionsupporting

confidence: 81%

Section: Resultsmentioning

confidence: 78%

Section: Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Percolation Theory Reveals Biophysical Properties of Virus-like Particles

Brunk

Twarock

2021

ACS Nano

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Disassembly of Single Virus Capsids Monitored in Real Time with Multicycle Resistive-Pulse Sensing

2021

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Virus assembly and disassembly are critical steps in the virus lifecycle; however, virus disassembly is much less well understood than assembly. For hepatitis B virus (HBV) capsids, disassembly of the virus capsid in the presence of guanidine hydrochloride (GuHCl) exhibits strong hysteresis that requires additional chemical energy to initiate disassembly and disrupt the capsid structure. To study disassembly of HBV capsids, we mixed T = 4 HBV capsids with 1.0–3.0 M GuHCl, monitored the reaction over time by randomly selecting particles, and measured their size with resistive-pulse sensing. Particles were cycled forward and backward multiple times to increase the observation time and likelihood of observing a disassembly event. The four-pore device used for resistive-pulse sensing produces four current pulses for each particle during translocation that improves tracking and identification of single particles and increases the precision of particle-size measurements when pulses are averaged. We studied disassembly at GuHCl concentrations below and above denaturing conditions of the dimer, the fundamental unit of HBV capsid assembly. As expected, capsids showed little disassembly at low GuHCl concentrations (e.g., 1.0 M GuHCl), whereas at higher GuHCl concentrations (≥1.5 M), capsids exhibited disassembly, sometimes as a complex series of events. In all cases, disassembly was an accelerating process, where capsids catastrophically disassembled within a few 100 ms of reaching critical stability; disassembly rates reached tens of dimers per second just before capsids fell apart. Some disassembly events exhibited metastable intermediates that appeared to lose one or more trimers of dimers in a stepwise fashion.

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Engineering Metastability into a Virus-like Particle to Enable Triggered Dissociation

et al. 2023

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For a virus-like particle (VLP) to serve as a delivery platform, the VLP must be able to release its cargo in response to a trigger. Here, we use a chemical biology approach to destabilize a self-assembling capsid for a subsequent triggered disassembly. We redesigned the dimeric hepatitis B virus (HBV) capsid protein (Cp) with two differentially addressable cysteines, C150 for reversibly crosslinking the capsid and C124 to react with a destabilizing moiety. The resulting construct, Cp150-V124C, assembles into icosahedral, 120-dimer VLPs that spontaneously crosslink via the C-terminal C150, leaving C124 buried at a dimer–dimer interface. The VLP is driven into a metastable state when C124 is reacted with the bulky fluorophore, maleimidyl BoDIPY-FL. The resulting VLP is stable until exposed to modest, physiologically relevant concentrations of reducing agent. We observe dissociation with FRET relaxation of polarization, size exclusion chromatography, and resistive-pulse sensing. Dissociation is slow, minutes to hours, with a characteristic lag phase. Mathematical modeling based on the presence of a nucleation step predicts disassembly dynamics that are consistent with experimental observations. VLPs transfected into hepatoma cells show similar dissociation behavior. These results suggest a generalizable strategy for designing a VLP that can release its contents in an environmentally responsive reaction.

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Molecular jenga: the percolation phase transition (collapse) in virus capsids

Cited by 11 publications

References 57 publications

Percolation Theory Reveals Biophysical Properties of Virus-like Particles

Percolation Theory Reveals Biophysical Properties of Virus-like Particles

Disassembly of Single Virus Capsids Monitored in Real Time with Multicycle Resistive-Pulse Sensing

Engineering Metastability into a Virus-like Particle to Enable Triggered Dissociation

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