Diffusion and bulk flow in phloem loading - a theoretical analysis of the polymer trap mechanism in plants

TL;DR

This paper presents a theoretical analysis of the polymer trap mechanism in plant phloem loading, showing it can function through diffusion and bulk flow, with implications for water transport without additional membrane uptake.

Contribution

It provides a detailed model of symplasmic loading via the polymer trap, highlighting the roles of diffusion and bulk flow in sugar and water transport in plants.

Findings

Water flow through plasmodesmata accounts for 10-20% of sucrose flux.

Main sugar translocation into sieve elements is likely via bulk water flow.

The polymer trap mechanism can theoretically operate under realistic biological parameters.

Abstract

Plants create sugar in the mesophyll cells of their leaves by photosynthesis. This sugar, mostly sucrose, has to be loaded via the bundle sheath into the phloem vascular system (the sieve elements), where it is distributed to growing parts of the plant. We analyze the feasibility of a particular loading mechanism, active symplasmic loading, also called the polymer trap mechanism, where sucrose is transformed into heavier sugars, such as raffinose and stachyose, in the intermediary-type companion cells bordering the sieve elements in the minor veins of the phloem. Keeping the heavier sugars from diffusing back requires that the plasmodesmata connecting the bundle sheath with the intermediary cell act as extremely precise filters, which are able to distinguish between molecules that differ by less than 20% in size. In our modeling, we take into account the coupled water and sugar movement across the relevant interfaces, without explicitly considering the chemical reactions transforming the sucrose into the heavier sugars. Based on the available data for plasmodesmata geometry, sugar concentrations and flux rates, we conclude that this mechanism can in principle function. We find that the water flow through the plasmodesmata, which has not been quantified before, contributes only 10-20% to the sucrose flux into the intermediary cells, while the main part is transported by diffusion. On the other hand, the subsequent sugar translocation into the sieve elements would very likely be carried predominantly by bulk water flow through the plasmodesmata. Thus, in contrast to apoplasmic loaders, all the necessary water for phloem translocation would be supplied in this way with no need for additional water uptake across the plasma membranes of the phloem.