Interaction plots show the relative normalized expression values for all seven A-type ARR genes present on the CATMA V2.4 array plotted against the time points of cytokinin treatment: BA0 (control), BA15 (15 min of BA treatment), and BA120 (120 min of BA treatment). B, Interaction plots of A-type ARR genes. The ACTIN2 gene was used as a loading control. Northern blots were hybridized with a probe specific for the cytokinin response genes ARR5 and ARR7. Total RNA was isolated from 5-d-old wild-type and 35S: ARR1-SRDX seedlings before treatment and after 15, 30, and 120 min of treatment with 5 μ m BA. A, Northern-blot analysis of ARR5 and ARR7 transcript levels. ARR1-S-8 and ARR1-S-10 are two independent lines of 35S: ARR1-SRDX transgenic plants.ģ5S: ARR1-SRDX gene expression dampens the early cytokinin response. The number of lateral roots between the wild type and the transgenic lines was significantly different ( P < 0.01). The number of lateral roots was determined following growth on vertical plates for 9 DAG. C, Cytokinin sensitivity of lateral root formation. The original data for the transgenic lines were significantly different from the wild-type data, with 0.001 < P < 0.01 as calculated by pairwise Student's t test. The root elongation of each line is expressed as a percentage of its DMSO control. Root elongation was measured for each line between 4 and 9 DAG. B, Cytokinin sensitivity of primary root elongation. Time 0 indicates the chlorophyll concentration at the beginning of the experiment. Fully expanded leaves were excised from 24-d-old plants and floated for 10 d in the dark on water supplemented with various concentrations of cytokinin before the chlorophyll concentration was determined. A, Chlorophyll retention in dark-incubated leaves by cytokinin. ģ5S: ARR1-SRDX plants are less sensitive to cytokinin. ARR1-S-8 and ARR1-S-10 are two independent lines of 35S: ARR1-SRDX transgenic plants. Pairwise Student's t test was used to compare values with the wild type. Seed weight was determined by weighing 10 pools of 200 seeds for each line. F, The seeds of 35S: ARR1-SRDX transgenic plants have increased weight. E, Seeds of 35S: ARR1-SRDX transgenic lines compared with the wild type. D, Siliques of 35S: ARR1-SRDX transgenic plants compared with wild-type plants. C, Flower morphology of 35S: ARR1-SRDX transgenic plants compared with the wild type. The graph shows the time (DAG) of flower bud opening in transgenic plants compared with the wild type. B, Quantitative analysis of the early-flowering phenotype of 35S: ARR1-SRDX transgenic plants. The plants were grown under long-day conditions and photographed at 19 DAG. A, Flower induction occurs earlier in 35S: ARR1-SRDX transgenic plants compared with wild-type plants. Reproductive development of 35S: ARR1-SRDX transgenic plants. This study demonstrates the usefulness of chimeric repressor silencing technology to overcome redundancy in transcription factor families for functional studies. In addition, a role for B-type ARRs in mediating cross talk with other pathways is supported by the resistance of 35S:ARR1-SRDX seeds to phytochrome B-mediated inhibition of germination by far-red light. Collectively, the suppression of pleiotropic cytokinin activities by a dominant repressor version of a B-type ARR indicates that this protein family is involved in mediating most, if not all, of the cytokinin activities in Arabidopsis. The transcript levels of more than 500 genes were more than 2.5-fold reduced in 35S:ARR1-SRDX transgenic seedlings, suggesting a broad function of B-type ARRs. The rapid induction of a large part of the cytokinin response genes was dampened. Several bioassays showed that 35S:ARR1-SRDX plants have an increased resistance toward cytokinin. 35S:ARR1-SRDX transgenic Arabidopsis plants showed phenotypic changes reminiscent of plants with a reduced cytokinin status, such as a strongly reduced leaf size, an enhanced root system, and larger seeds. In a protoplast test system, ARR1-SRDX suppressed ARR6:beta-glucuronidase reporter gene activation by different B-type ARRs. We generated a dominant repressor version of the Arabidopsis (Arabidopsis thaliana) response regulator ARR1 (ARR1-SRDX) using chimeric repressor silencing technology in order to study the extent of the contribution of B-type response regulators to cytokinin activities. In planta functional analysis of this family is hampered by the high level of functional redundancy of its 11 members. One component of this system are B-type response regulators, transcription factors mediating at least part of the response to cytokinin. The signal transduction of the phytohormone cytokinin is mediated by a multistep histidine-to-aspartate phosphorelay system.
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