Publications

The endosomal sorting complex required for transport (ESCRT) is a multi-protein machinery involved in several membrane remodeling processes. Different approaches have been used to resolve how ESCRT proteins scission membranes. However, the underlying mechanisms generating membrane deformations are still a matter of debate. Here, giant unilamellar vesicles, microfluidic technology, and micropipette aspiration are combined to continuously follow the ESCRT-III-mediated membrane remodeling on the single-vesicle level for the first time. With this approach, we identify different mechanisms by which a minimal set of three ESCRT-III proteins from Entamoeba histolytica reshape the membrane. These proteins modulate the membrane stiffness and spontaneous curvature to regulate bud size and generate intraluminal vesicles even in the absence of ATP. We demonstrate that the bud stability depends on the protein concentration and membrane tension. The approaches introduced here should open the road to diverse applications in synthetic biology for establishing artificial cells with several membrane compartments.© 2022 The Author(s).

JTD Keywords: bilayer, curvature, diffusion-coefficients, identification, membrane-scission, phase-diagram, reveals, sorting complex, structural basis, Biophysics, Biotechnology, Cell biology, Giant vesicles, Membranes

Nature has developed processes and robust materials, which possess superior physical, chemical, and electromagnetic properties that can withstand the most extreme conditions. We need to take inspiration from nature to obtain a more sustainable development. By combining our knowledge of processes and the knowledge of natural systems, we can create “biomimetic” solutions to the problems that we are facing as a consequence of the over-exploitation of our natural resources. Nice, France, the capital city of the French Riviera, once again welcomes the 4th edition of the International Conference on Bioinspired and Biobased Chemistry and Materials (“Nature Inspires Creativity Engineers” or N.I.C.E. 2018 Conference) from 14 to 17 of October, 2018. As in the previous editions, we are expecting hundreds of scientists and engineers to share the latest developments in the growing field of bioinspired and biobased chemistry and materials. It is a unique opportunity to understand the new challenges, to initiate new collaborations and to envisage sustainable solutions for the future.

JTD Keywords: Nanotechnology, Biotech, Smartech

A method for the simultaneous (bio)chemical and topographical patterning of enclosed structures in poly(dimethyl siloxane) (PDMS) is presented. The simultaneous chemical and topography transference uses a water-soluble chitosan sacrificial mold to impart a predefined pattern with micrometric accuracy to a PDMS replica. The method is compared to conventional soft-lithography techniques on planar surfaces. Its functionality is demonstrated by the transference of streptavidin directly to the surface of the three-dimensional PDMS structures as well as indirectly using streptavidin-loaded latex nanoparticles. The streptavidin immobilized on the PDMS is tested for bioactivity by coupling with fluorescently labeled biotin. This proves that the streptavidin is immobilized on the PDMS surface, not in the bulk of the polymer, and is therefore accessible for use as signaling/binding element in micro and bioengineering. The use of a biocompatible polymer and processes enables the technique to be used for the chemical patterning of tissue constructions.

JTD Keywords: Biotechnology, Chitosan, Microfabrication, MEMs, Soft lithography