Functional divergence of the repressors of photomorphogenesis SPA2 and SPA3 during Arabidopsis seedling deetiolation

The COP1/SPA ubiquitin ligase is a key repressor of photomorphogenesis that is inactivated by photoreceptors to initiate light signalling. The four SPA proteins (SPA1-SPA4) confer functional specificity to COP1 during plant growth, yet the underlying molecular mechanisms remain unclear. Here, we used a domain-swap approach in transgenic seedlings to address the functional divergence of SPA2 and SPA3. We show that the respective N-terminal kinase domain determines the contrasting protein stabilities of SPA2 and SPA3 in light-grown seedlings. The instability of SPA2 correlates with a specific ability of the SPA2 N-terminal domain to bind phytochrome A in the light, suggesting that phytochrome A promotes the CUL4DET1/COP1-dependent degradation of SPA2 but not of SPA3. We uncover that the coiled-coiled and WD-repeat domains of SPA2 and SPA3 substantially differ in their activity in repression of photomorphogenesis, with those of SPA2 being more active repressors than those of SPA3. Thus, SPA2 combines a potent repressor activity with light-induced instability. We conclude that the evolution of SPA2 instability in response to light counterbalances its inherent strong repressor activity, thereby allowing seedling etiolation in darkness followed by rapid reduction in COP1 activity through SPA2 degradation upon light-exposure as seedlings emerge from soil to initiate photosynthetic growth. HighlightThe repressor of light signaling SPA2 combines a phytochrome A-interacting instability domain with a potent repressor domain to allow greatly contrasting activities of COP1 in skoto- and photomorphogenesis.