Abstract
In contrast to animals, plant development involves continuous organ formation, which requires strict regulation of cell proliferation. The core cell cycle machinery is conserved across plants and animals, but plants have developed new mechanisms that precisely regulate cell proliferation in response to internal and external stimuli. Here, we report that the DOF transcription factor OBP4 negatively regulates cell proliferation and expansion. OBP4 is a nuclear protein. Constitutive and inducible overexpression of OBP4 reduced the cell size and number, resulting in dwarf plants. Inducible overexpression of OBP4 in Arabidopsis also promoted early endocycle onset and inhibited cell expansion, while inducible overexpression of OBP4 fused to the VP16 activation domain in Arabidopsis delayed endocycle onset and promoted plant growth. Furthermore, gene expression analysis showed that cell cycle regulators and cell wall expansion factors were largely down-regulated in the OBP4 overexpression lines. Short-term inducible analysis coupled with in vivo ChIP assays indicated that OBP4 targets the CyclinB1;1, CDKB1;1 and XTH genes. These results strongly suggest that OBP4 is a negative regulator of cell cycle progression and cell growth. These findings increase our understanding of the transcriptional regulation of the cell cycle in plants.
Highlights
The AP2 transcription factor ANT (AINTEGUMENTA) gene can maintain the meristematic competence of cells by regulating CYCD3;1 expression[37]
Other members of the OBP family were identified using the sequence of the OBF binding protein 1 (OBP1) DNA binding with one finger (DOF) domain to screen an Arabidopsis cDNA library
The cell cycle is controlled by numerous mechanisms that ensure correct cell division, i.e., regulation of cyclin-dependent kinases (CDKs) by cyclins, CDK inhibitors and phosphorylation[50]
Summary
The AP2 transcription factor ANT (AINTEGUMENTA) gene can maintain the meristematic competence of cells by regulating CYCD3;1 expression[37]. The mechanisms by which developmental signals interact with plant cell cycle progression remain unclear. A conserved N-terminal DNA-binding domain is present in typical DOF proteins, and the N-terminal domain can bind to DNA sequences harbouring an AAAG core motif and interact with other proteins. Other DOF transcription family proteins, OBP2 and OBP3, were identified to have the ability to bind OBF4 and to enhance their binding to the OCS element in the downstream target genes[21]. OBP4 controlled plant growth by regulating core cell cycle genes involved in the replication machinery and cell expansion regulators. Based on the expression profile and genetic results, we propose that OBP4 is a novel regulator of cell cycle progression and cell expansion
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