Model of florigen regulation in autonomous maize and photoperiod-induced
teosinte. Autonomous maize (left) requires ID1 regulatory protein activity
(orange stars) in developing leaves to establish chromatin modifications that
allow the expression of florigen genes (ZCN7 and
ZCN8). Thus, the id1 gene acts in immature
leaves to establish a chromatin signature and prime the leaf for florigen
synthesis as the leaf develops. Active chromatin is specified by H3ac. Once the distal portion of the leaf
develops, another signal (unknown) activates florigen production in leaf
vasculature, which then migrates to the shoot apical meristem (SAM) to activate
flowering genes (purple dotted line). The autonomous signal may consist,
partly, of changes in metabolic activity. Metabolic changes could also
indirectly activate florigen production (?). In teosinte (right), floral
induction is dependent on SD
photoperiods and the circadian clock to activate florigen production. Similar
to id1, the photoperiod pathway also establishes chromatin
modifications in immature leaves, which enable florigen synthesis in mature
leaves, but the pattern of histone modifications related to its activity is
different from the one created by id1 in the autonomous
pathway (i.e. open chromatin is specified by H3K4me2/H3K4me3). The
horizontal dashed lines across the mature maize and teosinte leaves delineate
the regions of the immature, developing leaf zone (bottom) from the mature leaf
blade (top).