Project description:Upf1, Upf2, and Upf3 are the central regulators of nonsense-mediated mRNA decay (NMD), the eukaryotic mRNA quality control pathway generally triggered when a premature termination codon is recognized by the ribosome. The NMD-related functions of the Upf proteins likely commence while these factors are ribosome-associated, but little is known of the timing of their ribosome binding, their specificity for ribosomes translating NMD substrates, or the nature and role of any ribosome:Upf complexes. Here, we have elucidated details of the ribosome-associated steps of NMD. By combining yeast genetics with selective ribosome profiling and co-sedimentation analyses of polysomes with wild-type and mutant Upf proteins, our approaches have identified distinct states of ribosome:Upf association. All three Upf factors manifest progressive polysome association as mRNA translation proceeds, but these events appear to be preceded by formation of a Upf1:80S complex as mRNAs initiate translation. This complex is likely executing an early mRNA surveillance function.

Project description:Upf1, Upf2, and Upf3 are the central regulators of nonsense-mediated mRNA decay (NMD), the eukaryotic mRNA quality control pathway generally triggered when a premature termination codon is recognized by the ribosome. The NMD-related functions of the Upf proteins likely commence while these factors are ribosome-associated, but little is known of the timing of their ribosome binding, their specificity for ribosomes translating NMD substrates, or the nature and role of any ribosome:Upf complexes. Here, we have elucidated details of the ribosome-associated steps of NMD. By combining yeast genetics with selective ribosome profiling and co-sedimentation analyses of polysomes with wild-type and mutant Upf proteins, our approaches have identified distinct states of ribosome:Upf association. All three Upf factors manifest progressive polysome association as mRNA translation proceeds, but these events appear to be preceded by formation of a Upf1:80S complex as mRNAs initiate translation. This complex is likely executing an early mRNA surveillance function.

Project description:The nonsense-mediated mRNA decay pathway (NMD) is a quality control mechanism that detects and degrades mRNAs that contain premature translation termination codons (PTCs), thus preventing the production of potentially harmful truncated proteins. NMD has been studied in a number of organisms including humans, yeast, Drosophila, C. elegans and recently Arabidopsis. Recently the NMD process has been shown to have a wider significance in regulating the levels of mRNA expression for a wide range of genes in yeast and Drosophila. Several genes have been found to be required for NMD in a variety of organisms, including UPF1 and UPF3. We have identified and characterised a number of alleles of UPF1 and UPF3 in Arabidopsis that are defective in NMD. By doing a transcriptomic analysis of two NMD mutants, upf1-1 and upf3-1, and wild type plants we aim to identify the subset of genes that are co-regulated by UPF1 and UPF3 and, therefore, by NMD in Arabidopsis. RNA will be extracted from 17-day-old mutant and wild type seedlings grown at 22-24 C under constant light.

Project description:Eukaryotic cells have evolved a mechanism called nonsense mediated mRNA decay (NMD) that detects and degrades aberrant mRNAs that contain premature termination codons (PTCs). NMD has recently acquired broader importance as it has been found to regulate not only aberrant mRNAs but also a great diversity of transcripts, including wild type genes in mammals, Drosophila and yeast. Seven proteins are the core of the NMD complex: SMG1, SMG2 (UPF1), SMG3 (UPF2), SMG4 (UPF3), SMG5, SMG6 and SMG7. Plants have orthologues of most of these proteins. We have identified and characterized a number of alleles of UPF1, UPF3 and SMG5 and made 35S:UPF2 RNAi (upf2i) transgenic plants, all of which share some phenotypic characteristics. Transcriptome analysis of upf1 and upf3 mutants has identified a subset of genes coregulated by UPF1 and UPF3 and, therefore, by NMD (unpublished data). By doing further transcriptome analysis on smg5 mutants and upf2i plants we aim to build a more robust subset of NMD targets in Arabidopsis. RNA will be extracted from 17 day-old mutant, transgenic and wild type seedlings grown at 22-24 C under constant light. 6 samples were used in this experiment

Project description:Eukaryotic cells have evolved a mechanism called nonsense mediated mRNA decay (NMD) that detects and degrades aberrant mRNAs that contain premature termination codons (PTCs). NMD has recently acquired broader importance as it has been found to regulate not only aberrant mRNAs but also a great diversity of transcripts, including wild type genes in mammals, Drosophila and yeast. Seven proteins are the core of the NMD complex: SMG1, SMG2 (UPF1), SMG3 (UPF2), SMG4 (UPF3), SMG5, SMG6 and SMG7. Plants have orthologues of most of these proteins. We have identified and characterized a number of alleles of UPF1, UPF3 and SMG5 and made 35S:UPF2 RNAi (upf2i) transgenic plants, all of which share some phenotypic characteristics. Transcriptome analysis of upf1 and upf3 mutants has identified a subset of genes coregulated by UPF1 and UPF3 and, therefore, by NMD (unpublished data). By doing further transcriptome analysis on smg5 mutants and upf2i plants we aim to build a more robust subset of NMD targets in Arabidopsis. RNA will be extracted from 17 day-old mutant, transgenic and wild type seedlings grown at 22-24 C under constant light.

Project description:The nonsense-mediated mRNA decay pathway (NMD) is a quality control mechanism that detects and degrades mRNAs that contain premature translation termination codons (PTCs), thus preventing the production of potentially harmful truncated proteins. NMD has been studied in a number of organisms including humans, yeast, Drosophila, C. elegans and recently Arabidopsis. Recently the NMD process has been shown to have a wider significance in regulating the levels of mRNA expression for a wide range of genes in yeast and Drosophila. Several genes have been found to be required for NMD in a variety of organisms, including UPF1 and UPF3. We have identified and characterised a number of alleles of UPF1 and UPF3 in Arabidopsis that are defective in NMD. By doing a transcriptomic analysis of two NMD mutants, upf1-1 and upf3-1, and wild type plants we aim to identify the subset of genes that are co-regulated by UPF1 and UPF3 and, therefore, by NMD in Arabidopsis. RNA will be extracted from 17-day-old mutant and wild type seedlings grown at 22-24 C under constant light. 7 samples were used in this experiment.

Project description:Plants can regenerate from a variety of tissues on culturing in appropriate media. However, the metabolic shifts involved in callus formation and shoot regeneration are largely unknown. The metabolic profiles of callus generated from tomato (Solanum lycopersicum) cotyledons and that of shoot regenerated from callus were compared with the pct1-2 mutant that exhibits enhanced polar auxin transport and the shr mutant that exhibits elevated nitric oxide levels. The transformation from cotyledon to callus involved a major shift in metabolite profiles with denser metabolic networks in the callus. In contrast, the transformation from callus to shoot involved minor changes in the networks. The metabolic networks in pct1-2 and shr mutants were distinct from wild type and were rewired with shifts in endogenous hormones and metabolite interactions. The callus formation was accompanied by a reduction in the levels of metabolites involved in cell wall lignification and cellular immunity. On the contrary, the levels of monoamines were upregulated in the callus and regenerated shoot. The callus formation and shoot regeneration were accompanied by an increase in salicylic acid in wild type and mutants. The transformation to the callus and also to the shoot downregulated LST8 and upregulated TOR transcript levels indicating a putative linkage between metabolic shift and TOR signalling pathway. The network analysis indicates that shift in metabolite profiles during callus formation and shoot regeneration is governed by a complex interaction between metabolites and endogenous hormones.

Project description:Auxin and cytokinin can regulate callus formation from developed plant organs and shoot regeneration from callus. The regulation of dedifferentiation and regeneration of plant cells by auxin and cytokinin stimulation was considered to be caused by the regulation of reprograming of callus cells, but the hypothesis had been argued still in now. Although elucidation of the regulatory mechanisms of callus formation and shoot regeneration has helped advance plant biotechnology research, many plant species are intractable to transformation because of difficulties with callus regulation. In this study, we identified the compound Fipexide (FPX) as a useful regulatory compound through chemical biology-based screening. Compared with the activity of auxin and cytokinin, FPX showed higher efficiency as a chemical inducer in callus formation, shoot regeneration, and Agrobacterium infection. In regards to morphology, the cellular organization of FPX-induced callus differed from that produced under auxin/cytokinin conditions. According to a microarray analysis, the expressions of approximately 971 genes were two-fold up-regulated by FPX treatment for 2 days. Among these genes, 598 genes were also induced by auxin/cytokinin, while 373 genes, including metabolic regulation-related genes, were specifically expressed only under FPX treatment. FPX can promote callus formations in rice, poplar, and several vegetables. FPX should be a useful tool to reveal unknown mechanisms of plant development and to increase the number of transgenic plant species.

Project description:Auxin and cytokinin can regulate callus formation from developed plant organs and shoot regeneration from callus. The regulation of dedifferentiation and regeneration of plant cells by auxin and cytokinin stimulation was considered to be caused by the regulation of reprograming of callus cells, but the hypothesis had been argued still in now. Although elucidation of the regulatory mechanisms of callus formation and shoot regeneration has helped advance plant biotechnology research, many plant species are intractable to transformation because of difficulties with callus regulation. In this study, we identified the compound Fipexide (FPX) as a useful regulatory compound through chemical biology-based screening. Compared with the activity of auxin and cytokinin, FPX showed higher efficiency as a chemical inducer in callus formation, shoot regeneration, and Agrobacterium infection. In regards to morphology, the cellular organization of FPX-induced callus differed from that produced under auxin/cytokinin conditions. According to a microarray analysis, the expressions of approximately 971 genes were two-fold up-regulated by FPX treatment for 2 days. Among these genes, 598 genes were also induced by auxin/cytokinin, while 373 genes, including metabolic regulation-related genes, were specifically expressed only under FPX treatment. FPX can promote callus formations in rice, poplar, and several vegetables. FPX should be a useful tool to reveal unknown mechanisms of plant development and to increase the number of transgenic plant species.

Project description:Nonsense-mediated mRNA decay (NMD) is a major translation-dependent RNA degradation pathway required for embryo development and telomere maintenance. Core NMD factors Upf1, Upf2 and Upf3 are conserved from yeast to mammals but a model of the NMD machinery compatible with all eukaryotes is not yet available. We performed the first large-scale quantitative characterization of yeast NMD complexes through affinity purification and mass-spectrometry with 7 different NMD-related factors, with or without Rnase, in strains deleted or not for NMD genes. This extensive characterization of NMD complexes identified two distinct complexes associated with Upf1: Detector (Upf1/2/3) and Effector. Effector contained, in addition to Upf1, the mRNA decapping enzyme and two potential equivalents of mammalian Smg6/5/7: Nmd4 and Ebs1. Like the Smg proteins, Nmd4 and Ebs1 were required for efficient NMD. Our results suggest that the core eukaryotic NMD machinery is conserved across species and operates through successive Upf1-bound Detector and Effector complexes.