Gaussian curvature and the budding kinetics of enveloped viruses

Hagan, Michael F.; Bruinsma, Robijn; Dharmavaram, Sanjay; She, Selene Baochen; Lázaro, Guillermo R.

doi:10.1101/457135

Cited by 4 publications

(7 citation statements)

References 59 publications

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“…Retroviruses assemble either inside the cytoplasm of an infected cell or on the cytoplasmic membrane (hereafter PM) 91 . In either case, they acquire a lipid envelope when they bud from the PM 92 . The resulting spherical immature particle is not yet infectious.…”

Section: Viral Maturationmentioning

confidence: 99%

Physics of viral dynamics

2021

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Section: Viral Maturationmentioning

confidence: 99%

Physics of viral dynamics

2021

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“…The expression penalizes bending from 0 of a symmetric membrane and for any stretching of the membrane. The Gaussian curvature is invariant absent a topological change 45 . Since the buds remain attached to the surface, the Gaussian curvature of the vesiculating membrane is invariant during the process of budding (See Supplementary Fig.…”

Section: The Budding and Merging Model Explains The Effects Of Surfacmentioning

confidence: 99%

“…4 and Supplementary Text for a discussion of the morphology and connectivity of the buds). A region of negative Gaussian curvature develops at the neck of the bud that equals the positive Gaussian curvature of the spherical bud 45 . We thus only consider changes in elastic energy of the membrane due to changes in the mean curvature.…”

Section: The Budding and Merging Model Explains The Effects Of Surfacmentioning

confidence: 99%

Nanoscale curvature promotes high yield spontaneous formation of cell-mimetic giant vesicles

Pazzi¹,

Subramaniam²

2020

Preprint

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To date, surface-assisted assembly of cell-like giant vesicles use planar surfaces and require the application of electric fields or dissolved molecules to obtain adequate yields. Here, we present the use of nanoscale surface curvature and hydrophilic surface chemistry to promote the high yield assembly of GUVs. We show that assembly on surfaces composed of entangled hydrophilic nanocellulose fibers results in an unprecedented 100,000-fold reduction in costs while increasing yields compared to extant techniques. Quantitative measurements of yields provide mechanistic insight on the effect of nanoscale curvature and the effect of surface chemistry. We present a thermodynamic ‘budding and merging’, BNM, model that unifies observations of assembly. The BNM model considers the change in free energy by balancing elastic, adhesion, and membrane edge energies in the formation of surface-attached spherical buds. Due to curvature and the hydrophilicity of cellulose, energetically unfavorable formation of buds on planar and spherical surfaces becomes favorable (spontaneous) on surfaces composed of cylindrical cellulose nanofibers.TOC Graphic

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“…In the synaptic nerve terminals, vesicles are filled with neurotransmitters and released by exocytosis 3 . Moreover, many viruses are enveloped by a lipid membrane which mediates the fusion of the virus with the host cell membrane; some examples are HIV-1, herpesviruses, the Ebola virus 5 , and coronaviruses 7 like SARS-CoV-2.…”

Section: Introductionmentioning

confidence: 99%

“…There has been extensive research for protein mediated fission. The dynamin superfamily 8,[18][19][20] or the ESCRT machinery 5,21,22 are two different sets of proteins that mediate in budding and fission. For example, the dynamin Drp1 is considered a major component in mitochondrial division; other dynamins are considered to either help or be necessary for the fission process.…”

Section: Introductionmentioning

confidence: 99%

On Gaussian Curvature and Membrane Fission

Rueda-Contreras

Gallen

Romero-Arias

et al. 2021

Preprint

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We propose a three-dimensional mathematical model to describe dynamical processes of membrane fission. The model is based on a phase field equation that includes the Gaussian curvature contribution to the bending energy. With the addition of the Gaussian curvature energy term numerical simulations agree with the predictions that tubular shapes can break down into multiple vesicles. A dispersion relation obtained with linear analysis predicts the wavelength of the instability and the number of formed vesicles. Finally, a membrane shape diagram is obtained for the different Gaussian and bending modulus, showing different shape regimes.

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Gaussian curvature and the budding kinetics of enveloped viruses

Cited by 4 publications

References 59 publications

Physics of viral dynamics

Physics of viral dynamics

Nanoscale curvature promotes high yield spontaneous formation of cell-mimetic giant vesicles

On Gaussian Curvature and Membrane Fission

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