Gymnosperm Resprouting—A Review

Evolution of the JULGI-SMXL4/5 module for phloem development in angiosperms

Bifacial cambium, which produces xylem and phloem, and monopodial architecture, characterized by apical dominance and lateral branching from axillary buds, are key developmental features of seed plants, consisting of angiosperms and gymnosperms. These allow seed plants to adapt to diverse environments by optimizing resource allocation and structural integrity. In seed plants, SUPPRESSOR OF MAX2-LIKE (SMXL) family members function in phloem development and strigolactone-induced inhibition of axillary bud outgrowth. Although strigolactone signaling regulates most SMXL family members, the only known regulator of SMXL4 and SMXL5 is the RNA-binding protein JULGI. We demonstrate that in angiosperms, by directly regulating SMXL4/5 expression, JULGI uncouples SMXL4/5 activity from strigolactone signaling. JULGI and ancestral SMXLs from seedless vascular plants or SMXL4/5 from seed plants are coexpressed in the phloem tissues of vascular plants, from lycophytes to angiosperms. Core angiosperm SMXL4/5 mRNAs contain a G-rich element in the 5' untranslated region (UTR) that serves as a target sequence for JULGI to negatively regulate SMXL4/5 expression. Heterologous expression of JULGIs from various angiosperms rescued the Arabidopsis jul1 jul2 mutant. Expressing SMXL4/5s from seed plants and ancestral SMXLs rescued Arabidopsis smxl4 smxl5. Angiosperm SMXL4/5s lack an RGKT motif for proteasomal degradation. Indeed, treatment with the synthetic strigolactone analog rac-GR24 induced proteasomal degradation of SMXL from ferns and SMXL5a from gymnosperms, but not SMXL4/5 from angiosperms. These findings suggest that in ancestral angiosperms, the 5' UTR of SMXL4/5 gained G-rich elements, creating a regulatory module with JULGI that allows the phloem development pathway to act independently of strigolactone signaling.

Fire in the tree: The origin and distribution of fire-adapted traits within conifers and their influence on speciation rates across the conifer phylogeny

PREMISE

Considering rapidly changing fire regimes due to anthropogenic disturbances to climate and fuel loads, it is crucial to understand the underpinnings driving fire-adapted trait evolution. Among the oldest lineages affected by fire is Coniferae. This lineage occupies a variety of fire prone and non-fire prone habitats across all hemispheres and has four fire-adapted traits: (1) thick bark; (2) serotiny; (3) seedling grass stage; and (4) resprouting ability. We seek to determine the historic origins of these traits, the degree of convergent evolution among species, how fire adaptations affect diversification rates in conifers, and if there is a link between climate and the evolution of fire adaptations.

METHODS

To investigate these questions, we use a combination of ancestral state reconstructions, multiple diversification analyses, and Pagel trait correlations.

RESULTS

Our results point to multiple evolutionary origins of fire adaptations. We find certain climates, particularly Subtropical and Mediterranean, are highly correlated with species possessing fire adaptations. Several lineages evolved fire adaptations after the Mid-Miocene Climactic Optimum, which coincides with the expansion of the then novel Mediterranean Climate type. Generally possessing a fire adaptation does not increase diversification rates, with the possible exceptions of Pinus subsections Australes and Ponderosae.

CONCLUSIONS

The appearance of novel climates and associated fire regimes seem to have been the primary drivers of fire adaptation evolution in conifers. However, most increases in diversification rates are within clades that responded favorably to cooler drier climates post Mid-Miocene Climactic Optimum, regardless of whether the clade is fire adapted.