Sugars can be as energy sources and signaling molecules in plant growth and development. In plant, MYB transcription factor is a family that composed 1–4 imperfect DNA-binding domains (DBD). Each repeat of DBD contains approximately 50 amino acids in length and forms to 3 α-helices. Base on copy number of DBD, MYB transcription factors have been group into four types, R2R3, R1/2, R1R2R3, and R1R2R2R1/2. Previously, our lab has demonstrated that R1/2 type OsMYBSs are involved in sugar- and hormone-regulated α-amylase gene expression mechanism in rice. To further investigate the biological roles of AtMYBSs protein in Arabidopsis, we identified two OsMYBS1 homologous genes,AtMYBS1 and AtMYBS2, in Arabidopsis. Rice embryo transient expression assays indicated that both AtMYBS1 and AtMYBS2 was able to bind sugar response element (TATCCA)to activated sugar response element containing promoter. The atmybs1mutant confers hypersensitivity to glucose and ABA, whereas atmybs2 mutant exhibited hyposensitivity to those treatments. Moreover, AtMYBS1 and AtMYBS2 are involved in the control of Glc-response gene expression, as the atmybs1 mutant displays increased expression of hexokinases dependent (HXK1), photosynthetic (CAB1), starch synthesis (APL3) and anthocyanin biosynthesis (CHS) gene, whereas atmybs2 mutant exhibited decreased those gene expression, indicating that the AtMYBS1 and AtMYBS2 play a role in sugar sensing in Arabidopsis. In addition, the ABA biosynthesis inhibitor fluridone partially rescues the sugar-mediated growth arresting. Moreover, the mRNA level of four ABA biosynthesis genes and two ABA signaling genes were increased Glc treatedatmybs1 seedlings, whereas decreased in atmybs2 seedlings. These results suggested that, AtMYBS1 and AtMYBS2 play opposite roles in regulated Glc and ABA signaling during early seedling development.