Endosperm ontogeny through the lens of epigenetics

Abstract

Endosperm tissue is crucial to seed development. Monocots and dicots have evolved different fates for their endosperm: it is usually consumed in dicots during seed development, while monocots seeds retain the endosperm till maturity. Recently, Wu et al. addressed the role of divergent epigenetic regulation over functionally conserved IKU2 gene contributing to silenced or persistent endosperm proliferation and has provided insights into diverged seed ontogeny pattern in plants. Here, we highlight the novel findings of this study and their potential significance. Seed production represents a remarkable life-history adaptation that has been established during plant evolution. In flowering plants, a double fertilization event initiates seed development, producing embryo and the endosperm. Endosperm (3n) is a triploid outcome of second fertilization, which occurs when a female central cell (2n) fuses with one of the two male gametes (n) carried by the pollen tube (Ingram, 2020). It develops precociously and is primed to perform nutritional and developmental functions for embryo growth (Povilus & Gehring, 2022). Different taxa have evolved specific seed formation patterns that elicit different levels of endosperm perseverance during development (Baroux et al., 2002). As a result of this, the endosperm-to-embryo ratio in mature seeds has varied gradually among different plants. As an example, endosperm in cereals is formed and retained as a nutritive reserve till seed maturity. In several eudicots such as Arabidopsis, early formed endosperm is substantially devoured to serve during embryo maturation. In peas with non-persistent endosperm, the tissue appears to be absorbed in the early free nuclear division phase before cell wall formation. The Podostomenaceae and Orchidaceae are the two endosperm-free lineages because their seeds lack or terminate endosperm nuclear divisions during early stages. Endosperm develops through two major phases: first syncytial involving continuous nuclear divisions, and the subsequent cellularization in which the free nuclear state develops cell wall (Baroux et al., 2002). Despite that the embryo produces the next generation progeny, endosperm proliferation and cellularization timing is crucial to embryo viability.