AUTHOR=Génard Michel , Lescourret Françoise , Bertin Nadia , Vercambre Gilles 

TITLE=Resource Translocation Modelling Highlights Density-Dependence Effects in Fruit Production at Various Levels of Organisation

JOURNAL=Frontiers in Plant Science

VOLUME=13

YEAR=2022

URL=https://www.frontiersin.org/journals/plant-science/articles/10.3389/fpls.2022.931297

DOI=10.3389/fpls.2022.931297

ISSN=1664-462X

ABSTRACT=<p>The size of fruit cells, seeds and fruits depends on their number. Could this density-dependence effect result from sugar resource sharing and, if so, does it involve phloem sugar flow or the intensity of sugar unloading to the sink? A density-dependence model (DDM) describing these processes was designed and parameterised for six species at five levels of organisation: cells and seeds within fruits, fruits within clusters, fruits within plants and plants within plots. Sugar flow was driven by phloem conductance, determined by parameters <italic>α</italic>, governing the shape of its relationship to population size, and <italic>κ</italic>, its value for a population size of one. Sugar unloading followed Michaelis–Menten kinetics with parameters <italic>V<sub>m</sub></italic> (maximal unloading rate) and <italic>K<sub>m</sub></italic> (Michaelis constant). The DDM effectively reproduced the observed individual mass dynamics, the undercompensating density dependence observed in most species at all sub-plant levels and the undercompensating, exact and overcompensating density dependence observed at the plant level. Conductance (<italic>κ</italic>) was a scaling factor varying with the level of organisation. <italic>V<sub>m</sub></italic> was positively correlated with density dependence, and α was negatively correlated with density dependence only if the plant-within-plot level was not considered. Analysis of the model’s behaviour indicates that density dependence of fruit growth could be a result of sugar sharing, and that both phloem sugar flow and sugar unloading contribute to these effects.</p>