In synergy with various cis-acting elements, plant insterstitial telomere motifs regulate gene expression in Arabidopsis root meristems

The telo-box, an interstitial telomere motif, was shown to regulate gene expression in root meristems, in synergy with a cis-acting element involved in the activation of expression of plant eEF1A genes, encoding the translation elongation factor EF1A, and of several ribosomal protein genes. We demonstrate here that the telo-box is also required for transcription activation by two other cis elements present within the promoter of genes encoding the acidic ribosomal protein rp40 and the proliferating cell nuclear antigen respectively. The control of gene expression by telo-boxes during cell cycle progression in Arabidopsis root meristems is discussed. A parallel is drawn with the function of telomeric sequences in Saccharomyces cerevisiae.

Plant interstitial telomere motifs participate in the control of gene expression in root meristems

The promoters of Arabidopsis eEF1A genes contain a telomere motif, the telo-box, associated with an activating sequence, the tef-box. Database searches indicated the presence of telo-boxes in the 5' region of numerous genes encoding components of the translational apparatus. By using several promoter constructs we demonstrate that the telo-box is required for the expression of a beta-glucoronidase gene in root primordia of transgenic Arabidopsis. This effect was observed when a telo-box was inserted upstream or downstream from the transcription initiation site, and occurred in synergy with the tef-box. These results clearly indicate that interstitial telomere motifs in plants are involved in control of gene expression. South-western screening of a lambdaZAP library with a double-stranded Arabidopsis telomere motif resulted in characterization of a protein related to the conserved animal protein Puralpha. The possibility of a regulation process similar to that achieved by the Rap1p in Saccharomyces cerevisiae is discussed.

Characterization and properties of heteromeric plant protein complexes that interact with tef cis-acting elements in both RNA polymerase II-dependent promoters and rDNA spacer sequences

The tef box, a cis-acting element identified in promoters of several plant genes encoding components of the translation apparatus, is involved in the activation of gene expression in cycling cells. In vitro, this element mediates the formation of two protein complexes called C1 and C2. A tef-like box is also found within the intergenic transcribed spacer of several plant rRNA genes. In radish this sequence has already been described as a protein-binding site putatively involved in the regulation of rDNA expression and is sufficient for formation of C1 complexes. By using mutated tef boxes, we show that tef-dependent activation of transcription is correlated with formation of both C1 and C2 complexes in a context-dependent manner. In transient expression experiments, the activation of a minimal promoter-GUS gene fusion is associated with the formation of C2 complexes. In contrast, the ability to form C1 complexes appears to allow activation of reporter gene expression in root meristems of transgenic Arabidopsis. SDS-PAGE analysis of purified protein fractions containing either the C1 or the C2 activity indicates a complex heteromeric structure for these potential regulators. Thus, the tef box seems to be a central component of the regulation of gene transcription in distinct and overlapping developmental programs, and could be involved in co-regulation of transcription by RNA polymerases I and II.

A new D-type cyclin of Arabidopsis thaliana expressed during lateral root primordia formation

D-type cyclins are believed to regulate the onset of cell division upon mitogenic signaling. Here, the isolation is reported of a new D-type cyclin gene (CYCD4;1) of Arabidopsis thaliana (L.) Heynh. during a two-hybrid screen using the cyclin-dependent kinase CDC2aAt as bait. Transcription of CYCD4;1 can be induced by sucrose. The co-regulated expression of CYCD4;1 and CDC2aAt in starved suspension cultures upon mitogenic stimulation indicates that the formation of a complex between these two partners is important for the resumption of cell division activity. By in-situ hybridizations CYCD4;1 was shown to be expressed during vascular tissue development, embryogenesis, and formation of lateral root primordia. Expression during the latter process suggests that the induced expression of D-type cyclins by mitogenic stimuli might be one of the rate-limiting events for the initiation of lateral roots.