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1.
Plant J ; 107(5): 1363-1386, 2021 09.
Article in English | MEDLINE | ID: mdl-34160110

ABSTRACT

The photosynthetic capacity of mature leaves increases after several days' exposure to constant or intermittent episodes of high light (HL) and is manifested primarily as changes in chloroplast physiology. How this chloroplast-level acclimation to HL is initiated and controlled is unknown. From expanded Arabidopsis leaves, we determined HL-dependent changes in transcript abundance of 3844 genes in a 0-6 h time-series transcriptomics experiment. It was hypothesized that among such genes were those that contribute to the initiation of HL acclimation. By focusing on differentially expressed transcription (co-)factor genes and applying dynamic statistical modelling to the temporal transcriptomics data, a regulatory network of 47 predominantly photoreceptor-regulated transcription (co-)factor genes was inferred. The most connected gene in this network was B-BOX DOMAIN CONTAINING PROTEIN32 (BBX32). Plants overexpressing BBX32 were strongly impaired in acclimation to HL and displayed perturbed expression of photosynthesis-associated genes under LL and after exposure to HL. These observations led to demonstrating that as well as regulation of chloroplast-level acclimation by BBX32, CRYPTOCHROME1, LONG HYPOCOTYL5, CONSTITUTIVELY PHOTOMORPHOGENIC1 and SUPPRESSOR OF PHYA-105 are important. In addition, the BBX32-centric gene regulatory network provides a view of the transcriptional control of acclimation in mature leaves distinct from other photoreceptor-regulated processes, such as seedling photomorphogenesis.


Subject(s)
Acclimatization/genetics , Arabidopsis Proteins/metabolism , Arabidopsis/genetics , Carrier Proteins/metabolism , Gene Expression Regulation, Plant , Transcriptome , Acclimatization/radiation effects , Arabidopsis/physiology , Arabidopsis/radiation effects , Arabidopsis Proteins/genetics , Bayes Theorem , Carrier Proteins/genetics , Chloroplasts/radiation effects , Gene Expression Profiling , Gene Regulatory Networks , Light , Photosynthesis/radiation effects , Plant Leaves/genetics , Plant Leaves/physiology , Plant Leaves/radiation effects
2.
Plant Cell ; 28(2): 345-66, 2016 Feb.
Article in English | MEDLINE | ID: mdl-26842464

ABSTRACT

In Arabidopsis thaliana, changes in metabolism and gene expression drive increased drought tolerance and initiate diverse drought avoidance and escape responses. To address regulatory processes that link these responses, we set out to identify genes that govern early responses to drought. To do this, a high-resolution time series transcriptomics data set was produced, coupled with detailed physiological and metabolic analyses of plants subjected to a slow transition from well-watered to drought conditions. A total of 1815 drought-responsive differentially expressed genes were identified. The early changes in gene expression coincided with a drop in carbon assimilation, and only in the late stages with an increase in foliar abscisic acid content. To identify gene regulatory networks (GRNs) mediating the transition between the early and late stages of drought, we used Bayesian network modeling of differentially expressed transcription factor (TF) genes. This approach identified AGAMOUS-LIKE22 (AGL22), as key hub gene in a TF GRN. It has previously been shown that AGL22 is involved in the transition from vegetative state to flowering but here we show that AGL22 expression influences steady state photosynthetic rates and lifetime water use. This suggests that AGL22 uniquely regulates a transcriptional network during drought stress, linking changes in primary metabolism and the initiation of stress responses.


Subject(s)
Abscisic Acid/metabolism , Arabidopsis Proteins/metabolism , Arabidopsis/genetics , Gene Expression Regulation, Plant , Plant Growth Regulators/metabolism , Transcription Factors/metabolism , Arabidopsis/growth & development , Arabidopsis/physiology , Arabidopsis Proteins/genetics , Bayes Theorem , Cluster Analysis , Droughts , Gene Regulatory Networks , Mutation , Phenotype , Photosynthesis/physiology , Stress, Physiological , Transcription Factors/genetics
3.
Plant Cell ; 27(11): 3038-64, 2015 Nov.
Article in English | MEDLINE | ID: mdl-26566919

ABSTRACT

Transcriptional reprogramming is integral to effective plant defense. Pathogen effectors act transcriptionally and posttranscriptionally to suppress defense responses. A major challenge to understanding disease and defense responses is discriminating between transcriptional reprogramming associated with microbial-associated molecular pattern (MAMP)-triggered immunity (MTI) and that orchestrated by effectors. A high-resolution time course of genome-wide expression changes following challenge with Pseudomonas syringae pv tomato DC3000 and the nonpathogenic mutant strain DC3000hrpA- allowed us to establish causal links between the activities of pathogen effectors and suppression of MTI and infer with high confidence a range of processes specifically targeted by effectors. Analysis of this information-rich data set with a range of computational tools provided insights into the earliest transcriptional events triggered by effector delivery, regulatory mechanisms recruited, and biological processes targeted. We show that the majority of genes contributing to disease or defense are induced within 6 h postinfection, significantly before pathogen multiplication. Suppression of chloroplast-associated genes is a rapid MAMP-triggered defense response, and suppression of genes involved in chromatin assembly and induction of ubiquitin-related genes coincide with pathogen-induced abscisic acid accumulation. Specific combinations of promoter motifs are engaged in fine-tuning the MTI response and active transcriptional suppression at specific promoter configurations by P. syringae.


Subject(s)
Arabidopsis/immunology , Immunosuppression Therapy , Pathogen-Associated Molecular Pattern Molecules/metabolism , Plant Immunity/genetics , Plant Leaves/immunology , Pseudomonas syringae/physiology , Transcription, Genetic , Arabidopsis/genetics , Arabidopsis/microbiology , Base Sequence , Chromatin/metabolism , Gene Expression Profiling , Gene Expression Regulation, Plant , Gene Ontology , Gene Regulatory Networks , Genes, Plant , Molecular Sequence Data , Nucleotide Motifs/genetics , Plant Diseases/genetics , Plant Diseases/immunology , Plant Diseases/microbiology , Plant Leaves/genetics , Plant Leaves/microbiology , Promoter Regions, Genetic/genetics , Pseudomonas syringae/growth & development , Transcription Factors/metabolism
4.
Plant J ; 75(1): 26-39, 2013 Jul.
Article in English | MEDLINE | ID: mdl-23578292

ABSTRACT

A model is presented describing the gene regulatory network surrounding three similar NAC transcription factors that have roles in Arabidopsis leaf senescence and stress responses. ANAC019, ANAC055 and ANAC072 belong to the same clade of NAC domain genes and have overlapping expression patterns. A combination of promoter DNA/protein interactions identified using yeast 1-hybrid analysis and modelling using gene expression time course data has been applied to predict the regulatory network upstream of these genes. Similarities and divergence in regulation during a variety of stress responses are predicted by different combinations of upstream transcription factors binding and also by the modelling. Mutant analysis with potential upstream genes was used to test and confirm some of the predicted interactions. Gene expression analysis in mutants of ANAC019 and ANAC055 at different times during leaf senescence has revealed a distinctly different role for each of these genes. Yeast 1-hybrid analysis is shown to be a valuable tool that can distinguish clades of binding proteins and be used to test and quantify protein binding to predicted promoter motifs.


Subject(s)
Arabidopsis Proteins/genetics , Arabidopsis/genetics , Botrytis/physiology , Gene Expression Regulation, Plant , Stress, Physiological , Arabidopsis/physiology , Arabidopsis Proteins/metabolism , Cellular Senescence , Gene Expression Profiling , Gene Regulatory Networks , Mutation , Oligonucleotide Array Sequence Analysis , Plant Diseases/microbiology , Plant Leaves/genetics , Plant Leaves/physiology , Plants, Genetically Modified , Promoter Regions, Genetic/genetics , Protein Binding , Transcription Factors/genetics , Transcription Factors/metabolism , Two-Hybrid System Techniques
5.
J Exp Bot ; 64(11): 3467-81, 2013 Aug.
Article in English | MEDLINE | ID: mdl-23828547

ABSTRACT

Heat-stressed crops suffer dehydration, depressed growth, and a consequent decline in water productivity, which is the yield of harvestable product as a function of lifetime water consumption and is a trait associated with plant growth and development. Heat shock transcription factor (HSF) genes have been implicated not only in thermotolerance but also in plant growth and development, and therefore could influence water productivity. Here it is demonstrated that Arabidopsis thaliana plants with increased HSFA1b expression showed increased water productivity and harvest index under water-replete and water-limiting conditions. In non-stressed HSFA1b-overexpressing (HSFA1bOx) plants, 509 genes showed altered expression, and these genes were not over-represented for development-associated genes but were for response to biotic stress. This confirmed an additional role for HSFA1b in maintaining basal disease resistance, which was stress hormone independent but involved H2O2 signalling. Fifty-five of the 509 genes harbour a variant of the heat shock element (HSE) in their promoters, here named HSE1b. Chromatin immunoprecipitation-PCR confirmed binding of HSFA1b to HSE1b in vivo, including in seven transcription factor genes. One of these is MULTIPROTEIN BRIDGING FACTOR1c (MBF1c). Plants overexpressing MBF1c showed enhanced basal resistance but not water productivity, thus partially phenocopying HSFA1bOx plants. A comparison of genes responsive to HSFA1b and MBF1c overexpression revealed a common group, none of which harbours a HSE1b motif. From this example, it is suggested that HSFA1b directly regulates 55 HSE1b-containing genes, which control the remaining 454 genes, collectively accounting for the stress defence and developmental phenotypes of HSFA1bOx.


Subject(s)
Arabidopsis Proteins/metabolism , Arabidopsis/metabolism , DNA-Binding Proteins/metabolism , Droughts , Transcription Factors/metabolism , Water/metabolism , Arabidopsis/genetics , Arabidopsis/microbiology , Arabidopsis Proteins/genetics , DNA-Binding Proteins/genetics , Disease Resistance/genetics , Heat Shock Transcription Factors , Hot Temperature , Pseudomonas syringae/pathogenicity , Transcription Factors/genetics
6.
Life (Basel) ; 10(4)2020 Apr 24.
Article in English | MEDLINE | ID: mdl-32344775

ABSTRACT

In the 'Rocket Science' project, storage of Eruca sativa (salad rocket) seeds for six months on board the International Space Station resulted in delayed seedling establishment. Here we investigated the physiological and molecular mechanisms underpinning the spaceflight effects on dry seeds. We found that 'Space' seed germination vigor was reduced, and ageing sensitivity increased, but the spaceflight did not compromise seed viability and the development of normal seedlings. Comparative analysis of the transcriptomes (using RNAseq) in dry seeds and upon controlled artificial ageing treatment (CAAT) revealed differentially expressed genes (DEGs) associated with spaceflight and ageing. DEG categories enriched by spaceflight and CAAT included transcription and translation with reduced transcript abundances for 40S and 60S ribosomal subunit genes. Among the 'spaceflight-up' DEGs were heat shock proteins (HSPs), DNAJ-related chaperones, a heat shock factor (HSFA7a-like), and components of several DNA repair pathways (e.g., ATM, DNA ligase 1). The 'response to radiation' category was especially enriched in 'spaceflight-up' DEGs including HSPs, catalases, and the transcription factor HY5. The major finding from the physiological and transcriptome analysis is that spaceflight causes vigor loss and partial ageing during air-dry seed storage, for which space environmental factors and consequences for seed storage during spaceflights are discussed.

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