Crowding tunes the organization and mechanics of actin bundles formed by crosslinking proteins

Park, Jinho; Lee, Myeongsang; Lee, Briana; Castaneda, Nicholas; Tetard, Laurene; Kang, Hyeran

doi:10.1002/1873-3468.13949

Cited by 9 publications

(10 citation statements)

References 88 publications

(154 reference statements)

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“…The organization of the filaments (Gov, 2008) and the thickness of bundles (Lieleg et al, 2007) could be key factors in determining bundle nanomechanics-for example, actin bundles induced by depletion interactions were shown to increase in thickness as well as elastic modulus with an increase in the concentrations of PEG (Tharmann et al, 2006). A recent study has shown that crowding can tune the diameter of actin bundles crosslinked by actin binding proteins and possibly impact filament spacing (Park et al, 2021). Divalent cations were previously shown to alter the interfilament distance in bundles, with the greatest filament spacing at ∼7 nm for 30 mM Mg 2+ (Castaneda et al, 2018).…”

Section: Discussionmentioning

confidence: 99%

Actin Bundle Nanomechanics and Organization Are Modulated by Macromolecular Crowding and Electrostatic Interactions

Castaneda

Feuillie

Molinari

et al. 2021

Front. Mol. Biosci.

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The structural and mechanical properties of actin bundles are essential to eukaryotic cells, aiding in cell motility and mechanical support of the plasma membrane. Bundle formation occurs in crowded intracellular environments composed of various ions and macromolecules. Although the roles of cations and macromolecular crowding in the mechanics and organization of actin bundles have been independently established, how changing both intracellular environmental conditions influence bundle mechanics at the nanoscale has yet to be established. Here we investigate how electrostatics and depletion interactions modulate the relative Young’s modulus and height of actin bundles using atomic force microscopy. Our results demonstrate that cation- and depletion-induced bundles display an overall reduction of relative Young’s modulus depending on either cation or crowding concentrations. Furthermore, we directly measure changes to cation- and depletion-induced bundle height, indicating that bundles experience alterations to filament packing supporting the reduction to relative Young’s modulus. Taken together, our work suggests that electrostatic and depletion interactions may act counteractively, impacting actin bundle nanomechanics and organization.

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Section: Discussionmentioning

confidence: 99%

Actin Bundle Nanomechanics and Organization Are Modulated by Macromolecular Crowding and Electrostatic Interactions

Castaneda

Feuillie

Molinari

et al. 2021

Front. Mol. Biosci.

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“…In a living cell, actin bundles induced by ABPs are formed in a crowded cytoplasm; therefore, it is important to understand how crowding modulates ABP-induced bundling. Changes in filament bending stiffness and conformations in crowded environments [ 39 ] can influence interactions between filaments and ABPs, including actin-crosslinking proteins (e.g., fascin and α-actinin) [ 9 ] and severing proteins (e.g., gelsolin) [ 65 ]. Crowders with different sizes and concentrations [PEG and methylcellulose (MC)] have been shown to affect the organization patterns and potentially nucleation/growth of microtubule bundles crosslinked with microtubule-associated protein (MAP65) [ 66 ].…”

Section: The Influence Of Crowding and Cation Interactions On The Organization And Mechanics Of Actin Bundles Crosslinked By Actin-bindinmentioning

confidence: 99%

“…Crowders with different sizes and concentrations [PEG and methylcellulose (MC)] have been shown to affect the organization patterns and potentially nucleation/growth of microtubule bundles crosslinked with microtubule-associated protein (MAP65) [ 66 ]. Potential competitive interactions between crowding (PEG, sucrose, and Ficoll) and actin-crosslinking proteins, fascin, and α-actinin, have recently begun to be explored [ 9 ]. Macromolecular crowding influences the organization of either fascin or α-actinin bundles by reducing binding interactions between actin filaments and crosslinking proteins ( Figure 1C and Table 1 ), evidenced by fluorescence microscopy and atomic force microscopy imaging along with MD simulations [ 9 ].…”

Section: The Influence Of Crowding and Cation Interactions On The Organization And Mechanics Of Actin Bundles Crosslinked By Actin-bindinmentioning

confidence: 99%

“…Potential competitive interactions between crowding (PEG, sucrose, and Ficoll) and actin-crosslinking proteins, fascin, and α-actinin, have recently begun to be explored [ 9 ]. Macromolecular crowding influences the organization of either fascin or α-actinin bundles by reducing binding interactions between actin filaments and crosslinking proteins ( Figure 1C and Table 1 ), evidenced by fluorescence microscopy and atomic force microscopy imaging along with MD simulations [ 9 ]. MD simulations indicated that macromolecular crowding increases interaction energy between fascin or α-actinin and filaments, and reduces the number of hydrogen bonds [ 9 ].…”

Section: The Influence Of Crowding and Cation Interactions On The Organization And Mechanics Of Actin Bundles Crosslinked By Actin-bindinmentioning

confidence: 99%

“…Actin bundling proteins bind to actin filament (gray; unbound state, blue and green; bound state) during bundle formation with k on , which is slower than k off due to reduced bundling interactions between actin filament and bundling proteins. Compared with small crosslinkers (e.g., fascin; blue), longer crosslinkers (e.g., α-actinin; green) yield a significant decrease in D since their orientation switches from perpendicular to angled on filament, affecting bundle compactness [ 9 ]. (D) ABP-induced bundle formation in the presence of cations can result in modulations to association/dissociation constant k on and k off by cations influencing bundle organization.…”

Section: Figure 1 ∣mentioning

confidence: 99%

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Regulation of Actin Bundle Mechanics and Structure by Intracellular Environmental Factors

2021

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The mechanical and structural properties of actin cytoskeleton drive various cellular processes, including structural support of the plasma membrane and cellular motility. Actin monomers assemble into double-stranded helical filaments as well as higher-ordered structures such as bundles and networks. Cells incorporate macromolecular crowding, cation interactions, and actin-crosslinking proteins to regulate the organization of actin bundles. Although the roles of each of these factors in actin bundling have been well-known individually, how combined factors contribute to actin bundle assembly, organization, and mechanics is not fully understood. Here, we describe recent studies that have investigated the mechanisms of how intracellular environmental factors influence actin bundling. This review highlights the effects of macromolecular crowding, cation interactions, and actin-crosslinking proteins on actin bundle organization, structure, and mechanics. Understanding these mechanisms is important in determining in vivo actin biophysics and providing insights into cell physiology.

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Self-organized spatial targeting of contractile actomyosin rings for synthetic cell division

Reverte-López,

Kanwa,

Qutbuddin

et al. 2024

Preprint

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One of the challenges of bottom-up synthetic biology is the engineering of a minimal module for self-division of synthetic cells. To produce the contractile forces required for the controlled excision of cell-like compartments such as giant unilamellar vesicles (GUVs), reconstituted cytokinetic rings made of actin are considered to be among the most promising structures of a potential synthetic division machinery. Although the targeting of actin rings to GUV membranes and their myosin-induced constriction have been previously demonstrated, large-scale vesicle deformation has been precluded due to the lacking spatial control of these contractile structures. Here, we show the combinedin vitroreconstitution of actomyosin rings and the bacterial MinDE protein system, effective in targetingE.coliZ-rings to mid-cell, within GUVs. Incorporating this spatial positioning tool, which induces active transport of any diffusible molecule on membranes, yields self-organized assembly of actomyosin rings at the equatorial plane of vesicles. Remarkably, the synergistic effect of Min oscillations and the contractile nature of actomyosin bundles induces mid-vesicle membrane deformation and striking bleb-like protrusions, leading to shape remodeling and symmetry breaking. Our system showcases how functional machineries from various organisms may be synergistically combinedin vitro, leading to the emergence of new functionality towards a synthetic division system.

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Crowding tunes the organization and mechanics of actin bundles formed by crosslinking proteins

Cited by 9 publications

References 88 publications

Actin Bundle Nanomechanics and Organization Are Modulated by Macromolecular Crowding and Electrostatic Interactions

Actin Bundle Nanomechanics and Organization Are Modulated by Macromolecular Crowding and Electrostatic Interactions

Regulation of Actin Bundle Mechanics and Structure by Intracellular Environmental Factors

Self-organized spatial targeting of contractile actomyosin rings for synthetic cell division

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