Pollen Patterns Form from Modulated Phases

TL;DR

This paper demonstrates that the diverse surface patterns of pollen grains can be explained by a physical process involving phase separation of polysaccharides, leading to spatially modulated phases that influence pattern formation.

Contribution

It introduces a physical model of pattern formation via modulated phases, linking phase separation in polysaccharides to pollen surface pattern diversity.

Findings

Primexine density changes lead to spatially modulated phases.

Patterned primexine guides sporopollenin deposition.

Most pollen patterns can result from physical modulated phase processes.

Abstract

Pollen grains are known for their impressive variety of species-specific, microscale surface patterning. Despite having similar biological developmental steps, pollen grain surface features are remarkably geometrically varied. Previous work suggests that a physical process may drive this pattern formation and that the observed diversity of patterns can be explained by viewing pollen pattern development as a phase transition to a spatially modulated phase. Several studies have shown that the polysaccharide material of plant cell walls undergoes phase separation in the absence of cross-linking stabilizers of the mixed phase. Here we show experimental evidence of a change in density of the extracellular polysaccharide material (primexine) during pollen cell development leads to a spatially modulated phase. The spatial pattern of this phase-separated primexine is also mechanically coupled to the undulation of the pollen cell membrane. The resulting patterned pools of denser primexine form the negative template of the ultimate sites of sporopollenin deposition, leading to the final micropattern observed in the mature pollen. We then present a general physical model of pattern formation via modulated phases. Using analytical and numerical techniques, we find that most of the pollen micropatterns observed in biological evolution could result from a physical process of modulated phases. However, an analysis of the relative rates of transitions from states that are equilibrated to or from states that are not equilibrated suggests that while equilibrium states of this process have occurred throughout evolutionary history, there has been no particular evolutionary selection for distinctly patterned equilibrated states.