Enhanced cell wall mechanics in VirtualLeaf enable realistic simulations of plant tissue dynamics

Computational modelling has become essential to advancing our understanding of plant
developmental and physiological processes, necessitating the development of new
computational approaches and software. Here, we present VirtualLeaf-2.0, an updated
version of this modelling framework for the biophysical and biomechanical interactions
between cells in plant tissues, with novel features for more detailed modelling of the cell
wall. In particular, the updated version of VirtualLeaf enables detailed modelling of
variations in cell wall stability and cell wall sliding up to the level of individual cell wall
elements. The plant cell wall plays a pivotal role in plant development and survival,
with younger cells generally having thinner, more flexible (primary) walls than older
cells. Cell wall stability is further affected by signalling in growth processes and
pathogen infection. The improvements of VirtualLeaf lay the groundwork for using
VirtualLeaf to address novel questions involving plant tissue dynamics during growth,
tissue formation and pathogen defence, as illustrated with example simulations.