Melting transition in lipid vesicles functionalised by mobile DNA linkers

Bachmann, Stephan; Kotar, Jurij; Parolini, Lucia; Šarić, Anđela; Cicuta, Pietro; Michele, Lorenzo Di; Mognetti, Bortolo Matteo

doi:10.1039/c6sm01515h

Cited by 30 publications

(48 citation statements)

References 82 publications

(145 reference statements)

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“…9a). This configuration is relevant to a number of experimental studies on equilibrium liposome-liposome [19,109] and liposome-SLB interactions [16], discussed in Sec. 3.1.…”

Section: Competition Between Bridge and Loop Formationmentioning

confidence: 99%

“…3.1). In many situations, however, the analytical approach turns out to be unfeasible, for example when attempting to model the reversible, temperature-dependent, self-assembly of relatively small LUVs in which thermal fluctuations have a large influence [109] (Sec. 3.1).…”

Section: Accounting For the Elastic Deformation Of The Interfacesmentioning

confidence: 99%

“…Importantly, Ref. [109] found that, to an excellent approximation, the overall interaction free energy, accounting for both the multivalent adhesion terms and the vesicle-deformation terms, increases linearly with the number of bridges formed. This results, along with results from MD simulations [192,193], could allow parametrising more coarsened models in which the effect of the deformability is implicitly accounted for.…”

Section: Accounting For the Elastic Deformation Of The Interfacesmentioning

confidence: 99%

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Programmable interactions with biomimetic DNA linkers at fluid membranes and interfaces

2019

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At the heart of the structured architecture and complex dynamics of biological systems are specific and timely interactions operated by biomolecules. In many instances, biomolecular agents are spatially confined to flexible lipid membranes where, among other functions, they control cell adhesion, motility and tissue formation. Besides being central to several biological processes, multivalent interactions mediated by reactive linkers confined to deformable substrates underpin the design of syntheticbiological platforms and advanced biomimetic materials. Here we review recent advances on the experimental study and theoretical modelling of a heterogeneous class of biomimetic systems in which synthetic linkers mediate multivalent interactions between fluid and deformable colloidal units, including lipid vesicles and emulsion droplets. Linkers are often prepared from synthetic DNA nanostructures, enabling full programmability of the thermodynamic and kinetic properties of their mutual interactions. The coupling of the statistical effects of multivalent interactions with substrate fluidity and deformability gives rise to a rich emerging phenomenology that, in the context of self-assembled soft materials, has been shown to produce exotic phase behaviour, stimuli-responsiveness, and kinetic programmability of the self-assembly process. Applications to (synthetic) biology will also be reviewed.

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“…9a). This configuration is relevant to a number of experimental studies on equilibrium liposome-liposome [19,109] and liposome-SLB interactions [16], discussed in Sec. 3.1.…”

Section: Competition Between Bridge and Loop Formationmentioning

confidence: 99%

Section: Accounting For the Elastic Deformation Of The Interfacesmentioning

confidence: 99%

Section: Accounting For the Elastic Deformation Of The Interfacesmentioning

confidence: 99%

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Programmable interactions with biomimetic DNA linkers at fluid membranes and interfaces

2019

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“…† While the formation of inter-particle bridges induce particle-particle aggregation, a prominence of intra-particle loops tends to stabilise a colloidal gas phase. 24 Free-energy minimisation and combinatorial entropy demand the coexistence of inter-and intra-particle bonds. 11,17,[24][25][26] The equilibrium between the two bond-type populations can be systematically tuned by changing the total number of linkers and inert constructs per particle.…”

Section: Complete Information Of Sample Preparation Methods and Matermentioning

confidence: 99%

Adaptable DNA interactions regulate surface triggered self assembly

et al. 2020

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“…Building on our previous work on mimetic systems 9 , we functionalize the GUVs and the SLB with a binary mixture of DNA constructs that can bridge the two membranes and mediate adhesion. Such DNA constructs are particularly attractive because their length, flexibility and binding strength can be readily modified [14][15][16][17][18][19][20][21] . We support these experimental advances by extending the recently developed Monte Carlo scheme for modeling adhesion with multiple types of ligand-receptor pairs 13 , to modeling the formation of DNA bridges of different lengths.…”

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confidence: 99%

Coexistence of long and short DNA constructs within adhesion plaques

Kamal

Stumpf

et al. 2020

Preprint

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Adhesion domains forming at the membrane interfaces between two cells or a cell and the extracellular matrix commonly involve multiple proteins bridges. However, the physical mechanisms governing the domain structures are not yet fully resolved. Here we present a joint experimental and theoretical study of a mimetic model-system, based on giant unilammelar vesicles interacting with supported lipid bilayers, with which the underlying physical effects can be clearly identified. In our case, adhesion is induced by simultaneous action of DNA linkers with two different lengths. We study the organization of bridges into domains as a function of relative fraction of long and short DNA constructs. Irrespective of the composition, we systematically find adhesion domains with coexisting DNA bridge types, despite their relative differences in length of 9 nm. However, at short length scales, below the optical resolution of the microscope, simulations suggest the formation of nanodomains by the minority fraction. The nano-aggregation is more significant for long bridges, which are also more stable, even though the enthalpy of membrane insertion is the same for both species.Cell adhesion is a fundamental biological process that relies on the formation of complex macromolecular assemblies, involving a number of proteins with different binding affinities, elastic properties and lengths 1 . These proteins may mediate adhesion in either a sequential manner, as it is the case of weak selectin adhesion preceding strong integrin adhesion in rolling leukocytes 2-4 , or simultaneously, for example during the formation of immune synapses. In this case T-cell receptors and integrins segregate 5,6 , presumably because of the differences in the length of their respective adhesive constructs 7 . However, the full understanding of the length-induced separation is still missing.One proven approach to study these mechanisms is using cell mimetic systems consisting of functionalized giant unilamelar vesicles (GUVs) adhering to supported lipid bilayers (SLB). So far, most mimetic adhesion systems involved only one protein pair, or + contributed equally mixtures between binders and repellers 8,9 , while the design of systems consisting of more than one binding pair is still challenging, and an active field of studies 10 .

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Melting transition in lipid vesicles functionalised by mobile DNA linkers

Cited by 30 publications

References 82 publications

Programmable interactions with biomimetic DNA linkers at fluid membranes and interfaces

Programmable interactions with biomimetic DNA linkers at fluid membranes and interfaces

Adaptable DNA interactions regulate surface triggered self assembly

Coexistence of long and short DNA constructs within adhesion plaques

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