Divergent selection for timing of vegetative phase change.

Vegetative phase change is a key trait in plant development and marks the transition from juvenile to adult growth phases. In maize (Zea mays L.), juvenile plants and plants with a late phase change can be identified by the increased production of tillers, aerial roots, and distinctive epicuticular wax. Resistance to agronomically significant pathogens can also differ between juvenile and adult plants. Using last leaf with juvenile wax as the target of selection, the maize population Minnesota 11 underwent 16 cycles of divergent selection. The objectives of this research were to identify emergent trends for each trait and to determine the magnitude and direction of phenotypic changes over long‐term selection compared to the source population. Phenotypic data on plant architecture traits, ear traits, and common rust resistance were collected in 2020 and 2021 by concurrently growing plants from selection cycles representing both directions of selection. Last leaf with juvenile wax, the direct target of selection increased to leaf 17.8 in the late phase change population and decreased to leaf 5 in the early phase change population from leaf 9 in the source population. Late vegetative phase change was positively correlated with increased common rust infection and plant height, and negatively correlated with ear size traits. This study shows that the observed phenotypic changes follow patterns of genetic variation consistent with divergent selection, but with possible effects of inbreeding. Core Ideas: Divergent recurrent selection is effective for manipulating vegetative phase change.Late vegetative phase change increases common rust susceptibility in maize.In the divergently selected populations, the limits of selection for vegetative phase have not been reached. [ABSTRACT FROM AUTHOR]