Mimicking Adhesion in Minimal Synthetic Cells.

Cell adhesions to the extracellular matrix and to neighboring cells are fundamental to cell behavior and have also been implemented into minimal synthetic cells, which are assembled from molecular building blocks from the bottom-up. Investigating adhesion in cell mimetic models with reduced complexity provides a better understanding of biochemical and biophysical concepts underlying the cell adhesion machinery. In return, implementing cell-matrix and cell-cell adhesions into minimal synthetic cells allows reconstructing cell functions associated with cell adhesions including cell motility, multicellular prototissues, fusion of vesicles, and the self-sorting of different cell types.

Independent Blue and Red Light Triggered Narcissistic Self-Sorting Self-Assembly of Colloidal Particles.

The ability of living systems to self-sort different cells into separate assemblies and the ability to independently regulate different structures are one ingredient that gives rise to their spatiotemporal complexity. Here, this self-sorting behavior is replicated in a synthetic system with two types of colloidal particles; where each particle type independently self-assembles either under blue or red light into distinct clusters, known as narcissistic self-sorting. For this purpose, each particle type is functionalized either with the light-switchable protein VVDHigh or Cph1, which homodimerize under blue and red light, respectively.

Reversible Social Self-Sorting of Colloidal Cell-Mimics with Blue Light Switchable Proteins.

Toward the bottom-up assembly of synthetic cells from molecular building blocks, it is an ongoing challenge to assemble micrometer sized compartments that host different processes into precise multicompartmental assemblies, also called prototissues. The difficulty lies in controlling interactions between different compartments dynamically both in space and time, as these interactions determine how they organize with respect to each other and how they work together. In this study, we have been able to control the self-assembly and social self-sorting of four different types of colloids, which we use as a model for synthetic cells, into two separate families with visible light.