The expression of chalcone synthase (CHS) genes, which encode the first enzyme of the flavonoid pathway, is under developmental control as well as affected by external stimuli such as light. Varying fragments of the 1 kb upstream region of the CHS1 gene from white mustard (Sinapis alba L.) were fused to the GUS-coding region, and the light-regulated expression of these constructs was analysed in transgenic Arabidopsis and tobacco plants. Studies performed with Arabidopsis seedlings indicate the presence of two elements within the CHS1 promoter mediating light responses via different photoreceptors. One element, located about 150 bp upstream of the transcription start site, is homologous to Unit 1 of the parsley CHS gene, the second, far more upstream element carries sequences similar to Unit 2 of the same gene. Detailed studies on Unit 1-driven expression indicate that this element transfers the expression characteristics of the original gene to both Arabidopsis and tobacco. Although the expression characteristics of Unit 1 are indistinguishable from those of the full-length promoter within the same species, we observed differences in mustard CHS promoter regulation between Arabidopsis and tobacco plants transgenic for the identical construct. The difference in photoreceptor usage by the same promoter element in different transgenic species (Unit 1 from mustard in Arabidopsis vs. tobacco) was also observed for different but homologous promoter elements in the same transgenic species (Unit 1 from mustard and parsley in tobacco). We therefore conclude that the same promoter and even the same promoter element (Unit 1) can mediate different spatial patterns of expression and modes of light regulation in different transgenic species.
Overexpression of phytochrome A results in an increased inhibition of hypocotyl elongation under red and far-red light. We used this approach to assay for the function of N-terminal mutations of rice (Oryza sativa L.) phytochrome A. Transgenic tobacco seedlings that express the wild-type rice phytochrome A (RW), a rice phytochrome A lacking the first 80 amino acids (NTD) or a rice phytochrome A with a conversion of the first 10 serines into alanine residues (S/A) were compared with untransformed wild-type tobacco (Nicotiana tabacum L. cv. Xanthi) seedlings. Experiments under different fluence rates showed that RW and, even more strongly, S/A increased the response under both red and far-red light, whereas NTD decreased the response under far-red light but hardly altered the response under red light. These results indicate that NTD not only lacks residues essential for an increased response under red light but also distorts the wild-type response under far-red light. Wild-type rice phytochrome A and, even more so, S/A mediate an enhanced phytochrome A as well as phytochrome B function, whereas NTD interferes with the function of endogenous tobacco phytochrome A as well as that of rice phytochrome A when co-expressed in a single host. Experiments with seedlings of different ages and various times of irradiation under far-red light demonstrated that the effect of NTD is dependent on the stage of development. Our results suggest that the lack of the first 80 amino acids still allows a rice phytochrome A to interact with the phytochrome transduction pathway, albeit non-productively in tobacco seedlings.
The white mustard (Sinapis alba L.) Lhcb1*1 and PsbP*1 genes that code for proteins related to photosystem II (PSII) in chloroplasts were examined by analysis of promoter fragment β‐glucuronidase (GUS) reporter constructs in transgenic tobacco (Nicotiana tabacum L.) seedlings. The endogenous tobacco genes and the introduced mustard genes follow the same kinetics during seedling development and they show the same expression characteristics for light regulation and for the influence of a ‘plastidic signal’. Hence, the cellular environment of the host plant always dominates the regulation of Lhcb1*1 and PsbP*1 gene expression; as with the mustard system clear differences in the temporal pattern and the physiological responses could be seen. The spatio‐temporal pattern of gene expression was analysed in the different organs of the transgenic tobacco seedlings. In the cotyledons, expression at the PsbP*1 promoter starts in advance, and both genes show a rather uniform distribution of expression during seedling development. In the hypocotyl, a sequential basipetal pattern could be detected and a coordinated expression for the two promoters was analysed. The hypocotyl base is only included in this expression pattern if the seedlings receive light at early stages of development, whereas in later stages gene expression is repressed. A model is proposed that divides tobacco seedling development into three main phases.
Abstract.To analyse the control of rice phytochrome A (phyA) overexpression (wild type or variously mutated) on gene regulation, transgenic tobacco lines overexpressing various rice phyA constructs were crossed with transgenic tobacco lines containing mustard Lhcbl or Chsl promoters fused to the uidA reporter gene (13-glucuronidase). It was demonstrated that the temporal pattern of competence to respond to phytochrome was not altered by rice phyA overexpression. Also, overexpression of rice phyA did not change the spatial pattern of gene expression. The responsiveness to red and far-red light, on the other hand, depended on the type of overexpressed rice phyA in a structure-function relation: the serine-to-alanine mutant mediated an enhanced response both under continuous red and far-red light, whereas the N-terminal deletion mutant showed a dominant negative effect under continuous far-red light and even after red light pulses. However, the effectiveness of rice phyA overexpression depended on the promoter construct and the developmental stage of the seedlings. The Lhcbl promoter also conferred 13-glucuronidase activity in etiolated seedlings. This dark expression could be decreased by a long-wavelength farred light pulse given early in development (24 h after sowing), indicating that this phenomenon is under the control of stable types of phytochrome.
When analyzing tobacco lines overexpressing various types of rice phytochrome A, we observed seedlings with fused cotyledons. Phytochrome A is a member of the phytochrome family of plant red/far‐red absorbing photoreceptors. Reciprocal crossings with wild‐type tobacco indicated that this abnormal phenotype was maternally inherited. Mother plants that were expected to produce abnormal seedlings, were raised under different conditions and seeds collected separately from individual capsules. The frequency of abnormal seedlings increased in seeds from later flowers but decreased when mother plants were raised under continuous white light. The interaction of the overexpressed phytochrome A proteins with endogenous plant hormones might be responsible for cotyledon fusion. The abnormal phenotype could partially be recovered by application of gibberellic acid to intact flowers at the time of pollination. In contrast, the synthetic auxin NAA slightly enhanced the degree of cotyledon fusion. Even wild‐type tobacco seedlings exhibited partial fusion of cotyledons if flowers were treated with 2,4‐D and occasionally the shoot apex was replaced by a second root. Application of GA3 to the flowers, in contrast, impaired the development of the radicule. These observations are discussed with respect to maternal effects in plant embryogenesis.
SummaryApical hook opening in tobacco seedlings can be induced by a single red light pulse and this induction can be reverted by a subsequent far-red light pulse. The slow hook opening kinetics and the reversibility of an inductive light pulse even after 8 h of darkness indicate the involvement of stable phytochrome. Compared with wild-type, transgenic BN1 seedlings which overexpress rice phytochrome A exhibit a higher sensitivity to low irradlance red light pulses. Moreover, in BN1 seedlings an inductive red light pulse is only partially reversible even after 30 min, whereas wild-type tobacco seedlings show complete reversibility during the entire hook opening process. The data found show that rice phytochrome A is active in transgenic tobacco seedlings in controlling hook opening and that the introduced rice phytochrome A and the endogenous stable phytochrome behave differently in this response.
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