Role of B3 domain transcription factors of the AFL family in maize kernel filling

•Maize ZmAFL2 and ZmAFL3/ZmVp1 are putative orthologs of FUS3 and ABI3, respectively.•Maize ZmAFL4, ZmAFL5 and ZmAFL6 are putative co-orthologs of LEC2.•Conserved expression profiles of FUS3 and ABI3 between dicots and monocots.•ZmAFL4 knockdown perturbs carbon metabolism and reduces starch content.•ZmAFL3/ZmVp1 and ZmAFL4 trans-activate a maize oleosin promoter.

In the dicot Arabidopsis thaliana, the B3 transcription factors, ABA-INSENSITIVE 3 (ABI3), FUSCA 3 (FUS3) and LEAFY COTYLEDON 2 (LEC2) are key regulators of seed maturation. This raises the question of the role of ABI3/FUS3/LEC2 (AFL) proteins in cereals, where not only the embryo but also the persistent endosperm accumulates reserve substances. Among the five ZmAFL genes identified in the maize genome, ZmAFL2 and ZmAFL3/ZmVp1 closely resemble FUS3 and ABI3, respectively, in terms of their sequences, domain structure and gene activity profiles. Of the three genes that fall into the LEC2 phylogenetic sub-clade, ZmAFL5 and ZmAFL6 have constitutive gene activity, whereas ZmAFL4, like LEC2, has preferential gene activity in pollen and seed, although its seed gene activity is restricted to the endosperm during reserve accumulation. Knock down of ZmAFL4 gene activity perturbs carbon metabolism and reduces starch content in the developing endosperm at 20 DAP. ZmAFL4 and ZmAFL3/ZmVp1 trans-activate a maize oleosin promoter in a heterologous moss system. In conclusion our results suggest, based on gene activity profiles, that the functions of FUS3 and ABI3 could be conserved between dicot and monocot species. In contrast, LEC2 function may have partially diverged in cereals where our findings provide first evidence of the specialization of ZmAFL4 for roles in the endosperm.