Abnormal hypophyseal and suspensor divisions in Arabidopsis dcl1 embryos are not attributable to a single miR156-targeted SQUAMOSA PROMOTER BINDING PROTEIN-LIKE (SPL) gene, but likely involve redundan

The first division of the Arabidopsis zygote is asymmetric, resulting in an apical cell lineage that generates most of the embryo proper, and a basal cell lineage that produces the root meristem and the extraembryonic suspensor. Loss of function mutations in the microRNA processing enzyme genes DICER-LIKE 1 (DCL1) and SERRATE (SE) show cell division defects in the embryo proper, hypophyseal cell, and suspensor. Previous transcriptome analyses showed that the microRNA156-targeted transcription factor genes SQUAMOSA PROMOTER BINDING PROTEIN-LIKE2 (SPL2), SPL3 and SPL11 were upregulated in both globular stage dcl1 and se embryos, while SPL10 was upregulated in dcl1. It was previously proposed that upregulation of SPL10 and SPL11 could explain some abnormal phenotypes in dcl1 embryos. In this work, we used T-DNA and CRISPR-Cas9-induced loss of function alleles to further explore the function of SPL2, SPL3, SPL10 and SPL11 in early embryogenesis and their contribution to the dcl1 phenotype. On their own, spl2, spl3, spl10, and spl11 single mutants and an spl10 spl11 double mutant showed no abnormal cell divisions in early embryogenesis. In the dcl1/+ background, loss of function of SPL2 or SPL3 did not change the proportion of cell division defects in hypophyseal cells or suspensors observed in dcl1/+. Loss of spl10 or spl11 in dcl1/+ resulted in a slight decrease or increase (respectively) in the penetrance of abnormal suspensor divisions in heart stage embryos, while the spl10 spl11 double mutant caused a small increase in the penetrance of abnormal hypophyseal divisions in dcl1 embryos. The differences between our results and previous studies are likely due to genetic redundancy of miR156-targeted SPL genes, variable environmental conditions or the effect of genetic background on the penetrance of the dcl1 phenotype. In the future, analysis of higher order mutations in SPL and MIR156 genes will help to better understand the role of these important developmental regulators in early embryo development.