Spatio-temporal dynamics of the metabolome of climacteric fruit during ripening and post-harvest storage

Fruit quality traits are determined to a large extent by their metabolome. The metabolite content of climacteric fruit changes drastically during ripening and post-harvest storage, and has been investigated extensively. However, the spatial distribution of metabolites and how it changes in time has received much less attention as fruit are usually considered as homogenous plant organs. Yet, spatio-temporal changes of starch, which is hydrolyzed during ripening, has been used for a long time as a ripening index. As vascular transport of water, and hence convective transport of metabolites, slows down in mature fruit and even stalls after detachment, spatio-temporal changes in their concentration are probably affected by diffusive transport of gaseous molecules that act as substrate (O-2), inhibitor (CO2), or regulator (ethylene and NO) of the metabolic pathways that are active during climacteric ripening. In this review, we discuss such spatio-temporal changes of the metabolome and how they are affected by transport of metabolic gases and gaseous hormones. As there are currently no techniques available to measure the metabolite distribution repeatedly by non-destructive means, we introduce reaction-diffusion models as an in silico tool to compute it. We show how the different components of such a model can be integrated and used to better understand the role of spatio-temporal changes of the metabolome in ripening and post-harvest storage of climacteric fruit that is detached from the plant, and discuss future research needs. The metabolome of climacteric fruit changes in space and time during ripening and post-harvest storage. Reaction-diffusion models can be used advantageously to study such spatio-temporal changes in silico.

Automated summary

Fruit quality is greatly influenced by its metabolome, which undergoes drastic changes during ripening and post-harvest storage. However, the spatial distribution of metabolites and their changes over time have received less attention. This review discusses the spatio-temporal changes of the metabolome and how they are affected by transport of metabolic gases and gaseous hormones. Reaction-diffusion models are proposed as a tool to study these changes in a simulated environment.