Project description:To understand the effect of high and low GA levels on plant metabolism and development in Arabidopsis we made use of the GA biosynthesis inhibitor paclobutrazol (PBZ) and exogenously applied GA. The whole genome response at the translation level was assessed by immunopurification of polysomes from PBZ- and GA treated plants expressing FLAG-tagged ribosomal protein L18 (RPL18B). Polysomal associated RNA was isolated and subjected to affymterix ATH1 CHIP analysis. A total of 140 genes were statistically determined to be differentially translated after GA treatment whereas 89 genes where affected PBZ treatment. Our analysis revealed that GA and PBZ have opposing effects on the expression of cell wall and wax layer biosynthesis related genes. In addition, many genes involved in secondary metabolism are upregulated upon PBZ treatment. A set of SAUR-like genes important for mediating auxin responses are downregulated by PBZ, which is of interest to coordinatian of GA levels with growth and development. Interestingly, GA treatment induces the upregulation of transcription factors related to plant defense and senescence, which is in agreement with the early flowering upon GA treatment. Our study provides a first picture of the response of Arabidopsis to altered GA levels at the translation level, and thus will be valuable for understanding gene regulation at the polysome level.

Project description:To understand the effect of high and low GA levels on plant metabolism and development in Arabidopsis we made use of the GA biosynthesis inhibitor paclobutrazol (PBZ) and exogenously applied GA. The whole genome response at the translation level was assessed by immunopurification of polysomes from PBZ- and GA treated plants expressing FLAG-tagged ribosomal protein L18 (RPL18B). Polysomal associated RNA was isolated and subjected to affymterix ATH1 CHIP analysis. A total of 140 genes were statistically determined to be differentially translated after GA treatment whereas 89 genes where affected PBZ treatment. Our analysis revealed that GA and PBZ have opposing effects on the expression of cell wall and wax layer biosynthesis related genes. In addition, many genes involved in secondary metabolism are upregulated upon PBZ treatment. A set of SAUR-like genes important for mediating auxin responses are downregulated by PBZ, which is of interest to coordinatian of GA levels with growth and development. Interestingly, GA treatment induces the upregulation of transcription factors related to plant defense and senescence, which is in agreement with the early flowering upon GA treatment. Our study provides a first picture of the response of Arabidopsis to altered GA levels at the translation level, and thus will be valuable for understanding gene regulation at the polysome level. Two replicates for each treatment including GA, PBZ and control samples.

Project description: Not available

Project description:The proper transition between the skotomorphogenic and photomorphogenic developmental programs is key for seedling survival and it is therefore tightly regulated. Besides light, which is the major cue that triggers this transition, several hormone pathways participate in this control, mainly antagonizing the light effect. Two of these hormones are gibberellins (GA) and brassinosteroids (BR). Both hormones promote the skotomorphogenesis and prevent photomorphogenesis, as evidenced by the partially de-etiolated phenotype caused by GA or BR deficiency, or by a blockage in the respective signaling pathways. We have previously shown that BR mediate GA activity in the control of this transition. For instance, treatment of dark-grown, GA-deficient seedlings with BRs was able to partially restore morphological phenotypes such as hypocotyl growth, and importantly to restore completely the molecular phenotype of CAB2 and RbcS gene expression. On the contrary, GA-treatment did not alter the same phenotypes in the BR deficient det2 mutant. Thus, the aim of this study was to investigate to what extent BRs mediate GA activity in dark-grown seedlings, and for that purpose we have the examined global changes in gene expression caused by treatment with GA and BRs in BR- and GA-deficient seedlings, respectively.

Project description:The proper transition between the skotomorphogenic and photomorphogenic developmental programs is key for seedling survival and it is therefore tightly regulated. Besides light, which is the major cue that triggers this transition, several hormone pathways participate in this control, mainly antagonizing the light effect. Two of these hormones are gibberellins (GA) and brassinosteroids (BR). Both hormones promote the skotomorphogenesis and prevent photomorphogenesis, as evidenced by the partially de-etiolated phenotype caused by GA or BR deficiency, or by a blockage in the respective signaling pathways. We have previously shown that BR mediate GA activity in the control of this transition. For instance, treatment of dark-grown, GA-deficient seedlings with BRs was able to partially restore morphological phenotypes such as hypocotyl growth, and importantly to restore completely the molecular phenotype of CAB2 and RbcS gene expression. On the contrary, GA-treatment did not alter the same phenotypes in the BR deficient det2 mutant. Thus, the aim of this study was to investigate to what extent BRs mediate GA activity in dark-grown seedlings, and for that purpose we have the examined global changes in gene expression caused by treatment with GA and BRs in BR- and GA-deficient seedlings, respectively. We performed two sets of experiments, each one including three different samples. The first experiment included dark-grown, WT Col-0 mock-treated seedlings, or seedlings treated with either the GA biosynthesis inhibitor paclobutrazol (PAC) or with PAC+epibrassinolide (EBR). In this experiment, PAC samples were labelled with Cy3 and compared to WT and PAC+EBR samples, which were labelled with Cy5. Two biological repeast were performed. The second experiment included dark-grown, WT Col-0 seedlings and the det2-1 mutant, which was either mock-treated or treated with GA3. Two biological replicates were performed, in the first one the WT and det2-1+GA3 were labelled with Cy3 and the det2-1 sample with Cy5. The reverse labelling was used in the second replicate.

Project description:The aim of this study is to analize the genes that are up or down-regulated in response to sprouting promoting effectors such as GAs and light, in order to elucidate the signalling cascades triggered during this process. Half sections of certified pathogen tested Spunta tubers were put into sterile MS-agar (0.7%) containing flasks at 16„aC and subjected to different treatments: Dark controls: Tuber sections were incubated for 10 or 35 days in complete darkness. Light control: Tuber sections were incubated for 10 days under continuous light conditions. Treatments performed in complete darkness during 35 days: a) GA treatment: 5 uM gibberellic acid (C19H22O6) = GA3 (Sigma) b) Sucrose treatment: 1% sucrose c) GA & sucrose treatment: 5 uM GA3 (Sigma) + 1% sucrose Treatments performed in light (10 days)d) GA treatment : 5 uM GA3 (Sigma). Three independent biological replicates of each condition (3 controls and 4 treatments) wereperformed. At the moment of harvest (10 or 35 days) sprout length was measured and photographs of the different samples were taken. Sprouts were excised and frozen in liquid Nitrogen. Total RNA was obtained using the Trizol reagent (Invitrogen) according to the manufacturer¡¦s instructions. RNAs were quantified by OD: 260/280 and checked in agarose gels. Keywords: Loop design

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Project description: Not available