Active viscoelastic condensates provide controllable mechanical anchor points

Abstract: Many biological materials must couple mechanical strength with the ability to rapidly self-assemble at a specific location. In particular, biomolecular condensates readily self-assemble via phase separation, but may also need to resist external forces to fulfil their function. Spatial localisation of condensate formation can be controlled by active cores that preferentially drive the production of condensate material at a particular point, while resistance to external forces can be facilitated by viscoelastic material properties. To investigate the interplay of these two processes, we develop a continuum model of viscoelastic growth around an active core. We find that viscoelastic stresses restrict condensate growth, but also impart resistance to deformation. We investigate the effect of different incorporation schemes on growth dynamics, and test the influence of mechanical properties on condensate strength. Finally, we compare the predictions of our model to experimental data from centrosomes in C. elegans embryos, identifying a parameter regime in which rapid growth can be combined with appropriate mechanical strength, and studying how strain-dependent material incorporation may lead to isotropic growth of scaffold material. Our results provide general design principles for other materials that must reconcile rapid, localised self-assembly with mechanical strength, such as focal adhesions.