TCP proteins are plant-specific transcription factors identified so far only in angiosperms and shown to be involved in specifying plant morphologies. However, the functions of these proteins remain largely unknown. Our study is the first phylogenetic analysis comparing the TCP genes from higher and lower plants, and it dates the emergence of the TCP family to before the split of the Zygnemophyta. EST database analysis and CODEHOP PCR amplification revealed TCP genes in basal land plant genomes and also in their close freshwater algal relatives. Based on an extensive survey of TCP genes, families of TCP proteins were characterized in the Arabidopsis thaliana, poplar, rice, club-moss, and moss genomes. The phylogenetic trees indicate a continuous expansion of the TCP family during the diversification of the Phragmoplastophyta and a similar degree of expansion in several angiosperm lineages. TCP paralogues were identified in all genomes studied, and Ks values indicate that TCP genes expanded during genome duplication events. MEME and SIMPLE analyses detected conserved motifs and low-complexity regions, respectively, outside of the TCP domain, which reinforced the previous description of a "mosaic" structure of TCP proteins.
SummaryWe have focused our interest on two cis-regulatory elements, named site II motif and telo box, identi®ed within the promoter of plant proliferating cellular nuclear antigen (PCNA) and putatively involved in meristematic expression of the gene. A conserved topological association between site II motifs and telo boxes is observed in the promoter of numerous genes expressed in cycling cells, including several cell cyclerelated genes and 153 Arabidopsis genes encoding ribosomal proteins. Meristematic expression of a GUS reporter gene was observed in plants under the control of Arabidopsis site II motif within a minimal promoter. This expression is strongly enhanced by addition of a telo box within this chimaeric promoter. We showed by gel retardation experiments that the site II motif is a target for several DNA-binding activities present in Arabidopsis crude cell extract and can bind a transcription factor, At-TCP20, from the Teosinte branched 1, Cycloidea, PCF (TCP)-domain protein family. In yeast two-hybrid experiments, At-TCP20 appears to be a potential partner of AtPura, which was previously shown to bind telo boxes. An important consequence of this analysis is to reveal new and conserved regulatory processes concerning the regulation of plant ribosomal gene expression in cycling cells. The implication of these observations in plant-speci®c developmental pathways is discussed.
AtTCP20 is a transcription factor belonging to the Arabidopsis (Arabidopsis thaliana) TCP-P subfamily, characterized by its capacity to bind to site II motifs (TGGGCY). Our aim was to understand the role of AtTCP20 in plant development. The expression pattern of a translational fusion of PromTCP20:CDS20∷GUS∷GFP suggested a function for AtTCP20 in several plant organs and stages of development. The role of AtTCP20 was challenged in planta by inducing expression of AtTCP20 proteins fused with either a transcriptional activator domain (VP16) or a repressor domain (EAR). Expression of both modified proteins led to severe developmental phenotypes. In-depth analysis suggested that AtTCP20 may participate in the regulation of cell expansion, cell division, and cell differentiation. Gene expression profiling in roots and hypocotyls revealed that 252 genes were down-regulated in both organs after induction of the AtTCP20∷EAR repressor gene. Site II motifs (TGGGCY) were underrepresented in their promoters. Conversely, GG(A/T)CCC sequences related to binding sites identified for TCP proteins in rice (Oryza sativa) were overrepresented, and a TCP20 fusion protein was shown to bind to these sequences in vitro. Gene ontology indicated that many targeted genes were involved in cell wall biogenesis and modification during expansion and also encoded numerous transcription factors controlling plant development. Our results are consistent with the previous proposal that AtTCP20 is involved in cell division and growth coordination. Moreover, they further suggest that AtTCP20 also contributes to cell expansion control and indicate a different involvement of this protein in plant morphogenesis depending on the organ and the developmental stage.
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