The contribution of cell wall remodeling and signaling to lateral organs formation

Lateral organs are formed in plants by post embryonic developmental programs. Leaves, and flowers differentiate from the shoot apical meristem and lateral roots from the primary root pericycle meristem. Adventitious roots are roots formed from non-root lateral meristematic tissues, mostly the cambium, in many cases in response to stress signals. The ability of plants to regenerate adventitious roots is fundamental for selection and breading programs which are based on vegetative propagation of elite clones. Thus, recalcitrant plants, losing their rooting capability, may form a genuine commercial barrier in agricultural and forestry improvement programs. Some cellular mechanisms underlying adventitious root formation have been revealed, but much is yet to be clarified. The plant primary cell wall is a dynamic organ that can change its form, and perceive and relay molecular signals inward and outward during certain stages of development in particular cells. Therefore, before the secondary cell wall is deposited and plants become the wood from which walls and furniture are built, and the fibers from which cloths are woven, primary cell walls actively participate in plant cell differentiation and developmental programs. While auxin is a major regulator, cell walls are important in regulating coherent formative cell division and synchronized polar elongation of cell lineages that are necessary for lateral organ induction and formation, and collaborative cell functioning. Nevertheless, little is known of how cell wall changes are molecularly sensed and translated to intracellular signals during differentiation of adventitious roots. Here we summarize recent data linking, directly or indirectly, cell wall events to auxin signaling and to lateral or adventitious root induction and formation.

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