Re-interpreting plant morphological responses to UV-B radiation

There is a need to reappraise the effects of UV-B radiation on plant morphology in light of improved mechanistic understanding of UV-B effects, particularly elucidation of the UV RESISTANCE LOCUS 8 (UVR8) photoreceptor. We review responses at cell and organismal levels, and explore their underlying regulatory mechanisms, function in UV protection and consequences for plant fitness. UV-induced morphological changes include thicker leaves, shorter petioles, shorter stems, increased axillary branching and altered root:shoot ratios. At the cellular level, UV-B morphogenesis comprises changes in cell division, elongation and/or differentiation. However, notwithstanding substantial new knowledge of molecular, cellular and organismal UV-B responses, there remains a clear gap in our understanding of the interactions between these organizational levels, and how they control plant architecture. Furthermore, despite a broad consensus that UV-B induces relatively compact architecture, we note substantial diversity in reported phenotypes. This may relate to UV-induced morphological changes being underpinned by different mechanisms at high and low UV-B doses. It remains unproven whether UV-induced morphological changes have a protective function involving shading and decreased leaf penetration of UV-B, counterbalancing trade-offs such as decreased photosynthetic light capture and plant-competitive abilities. Future research will need to disentangle seemingly contradictory interactions occurring at the threshold UV dose where regulation and stress-induced morphogenesis overlap. We review the effects of UV-B on plant morphology, using the improved mechanistic understanding of UV perception and signalling following elucidation of the UVR8 photoreceptor to reappraise published results. Despite a substantially improved understanding of molecular, cellular and organismal UV-B responses, there remains a clear gap in our knowledge of the interactions between these organisational levels, their function in UV-protection, and consequences for plant fitness and plant-plant interactions. Future research will need to disentangle the seemingly contradictory interactions and substantial diversity in reported phenotypes that occur at the threshold UV dose where regulation and stress-induced morphogenesis overlap.