Project description:Small RNA diversity and function has been widely characterized in various tissues of the sporophytic generation of the angiosperm model Arabidopsis thaliana. In contrast, there is limited knowledge about small RNA diversity and their roles in developing male gametophytes. We thus carried out small RNA sequencing on RNA isolated from four stages of developing Arabidopsis thaliana pollen. Spores from 4 stages of pollen development (UNM: Uninucleate microspore M-bM-^@M-^S BCP: Bicellular pollen M-bM-^@M-^S TCP: Tricellular pollen M-bM-^@M-^S MP: Mature pollen) were isolated using a percoll gradient-based method (Honys and Twell, 2004) and the small RNA fraction for each sample was isolated and sequenced by Illumina technology. Reference: Honys, D. and Twell, D. (2004) Transcriptome analysis of haploid male gametophyte development in Arabidopsis. Genome Biol. 5/11/R85.

Project description:Following our initial transcriptomic analyses of the male gametophyte development (Honys and Twell, Genome Biol 5:R85, 2004), we identified several candidate genes for the function of transcriptional regulators of the male gametophyte development. Two transcription factors with verified function (bZIP and C2H2 ZF) were selected for the identification of their regulons. Mature pollen was isolated as published previously (Honys and Twell Plant Physiol 132:640-652, 2003) from Col-0 wild type plants and T-DNA insertion mutants (SAIL) homozygous for tested genes. 6 samples were used in this experiment.

Project description:Aims We aim to use transcriptome analysis to establish on a genome-wide scale the identity and regulatory clusters of genes that specify microgametogenesis from the haploid microspore to mature functional pollen in Arabidopsis. Background Pollen as the haploid male gametophyte plays a vital role in plant fertility and crop production through the ability to deliver the male gametes in fertilisation. Despite the obvious importance for plant fertility and crop production we have a very limited understanding of the regulatory mechanisms that have evolved to specify male gametophyte development and functions and less than 150 genes have been identified that are gametophytically expressed in the anther.The availability of functional genomic resources now provides the opportunity to undertake a comprehensive approach to describing cellular development in terms of the transcriptome. This approach is particularly powerful where the complete transcriptome of a single developing cell can be analysed. The male gametophyte is a uniquely accessible cell type for such studies, enabling RNA analysis from distinct purified cell populations during development.The proposed experiments are designed to support a current application (P19208, Twell) to investigate the gametophytic transcriptome and transcription factor networks. The results obtained will extend our knowledge of the contribution of haploid gene expression to anther development and will be used directly to extend BBSRC funded work (P15086, Wilson) to investigate the role and targets the MALE STERILE 1 gene (MS1). In particular the data will be used in collaboration to extract haploid gene expression from datasets of transcriptome analysis of staged flower buds of wild type (Ler) and ms1. This work will also complement BBSRC funded work on sporogenesis (G13338, Dickinson and Scott) and meiosis (G15941, Franklin and Jones) that are focussed on earlier steps in anther development. Biological material and methods. Isolated microspores and pollen at 4 different developmental stages will be analysed. We will isolate spores from developmentally staged buds of Ler grown under defined growth conditions. Buds from several batches of 100 plants will be rapidly sorted into 4 groups according to developmental age, uninucleate microspores (UM), bicellular pollen (BP) tricellular pollen (TP) and mature pollen. Spores will be released by gentle mechanical tissue disruption and purified by filtration and purification of spores. We are confident that our spore isolation procedures are rigorous since we could not detect even trace expression of highly abundant sporophytic transcripts such RbcS and Cab transcripts in microarray data from pollen RNA. Keywords: development_or_differentiation_design

Project description:The haploid multicellular male gametophyte of plants, the pollen grain, is a terminally differentiated structure whose function ends at fertilization. Unlike pollen grains, the immature gametophyte retains its capacity for totipotent growth when cultured in vitro. Haploid embryo production from cultured immature male gametophytes is a widely used plant breeding and propagation technique that was described nearly 50 years ago, but one that is poorly understood at the mechanistic level. Using a chemical approach, we show that the switch to haploid embryogenesis is controlled by the activity of histone deacetylases (HDACs). Blocking HDAC activity with trichostatin A (TSA) in cultured immature male gametophytes of Brassica napus leads to a large increase in the proportion of cells that switch from pollen to embryogenic growth. Embryogenic growth is enhanced by, but not dependent on, the high temperature stress that is normally used to induce haploid embryogenesis in B. napus. The immature male gametophyte of Arabidopsis thaliana, which is recalcitrant for haploid embryo development in culture, also forms embryogenic cell clusters after TSA treatment. TSA treatment of immature male gametophytes for as little as eight hours was accompanied by hyperacetylation of histones H3 and H4, and by the upregulation of genes involved in cell-cycle progression, the auxin pathway and cell wall catabolism pathways. We propose that the totipotency of the immature male gametophyte in planta is kept in check by an HDAC-dependent mechanism, and that high temperature or other stresses used to induce haploid embryo development in culture impinge on this HDAC-dependent pathway.

Project description:The haploid multicellular male gametophyte of plants, the pollen grain, is a terminally differentiated structure whose function ends at fertilization. Unlike pollen grains, the immature gametophyte retains its capacity for totipotent growth when cultured in vitro. Haploid embryo production from cultured immature male gametophytes is a widely used plant breeding and propagation technique that was described nearly 50 years ago, but one that is poorly understood at the mechanistic level. Using a chemical approach, we show that the switch to haploid embryogenesis is controlled by the activity of histone deacetylases (HDACs). Blocking HDAC activity with trichostatin A (TSA) in cultured immature male gametophytes of Brassica napus leads to a large increase in the proportion of cells that switch from pollen to embryogenic growth. Embryogenic growth is enhanced by, but not dependent on, the high temperature stress that is normally used to induce haploid embryogenesis in B. napus. The immature male gametophyte of Arabidopsis thaliana, which is recalcitrant for haploid embryo development in culture, also forms embryogenic cell clusters after TSA treatment. TSA treatment of immature male gametophytes for as little as eight hours was accompanied by hyperacetylation of histones H3 and H4, and by the upregulation of genes involved in cell-cycle progression, the auxin pathway and cell wall catabolism pathways. We propose that the totipotency of the immature male gametophyte in planta is kept in check by an HDAC-dependent mechanism, and that high temperature or other stresses used to induce haploid embryo development in culture impinge on this HDAC-dependent pathway. 8 samples were analyzed. We generated the following pairwise comparisons between treatment and the corresponding mock treatment: TSA+CHX (2 replicates) vs CHX (2 replicates); TSA (2 replicates) vs DMSO (2 replicates).

Project description:Arabidopsis acetate non-utilizing mutants were isolated based on fluoroacetate resistant germination. Interestingly, a number of these mutants exhibited altered developmental characteristics in response to exogenous sucrose supply, such as bleaching of the cotyledons. A preliminary microarray experiment has already been conducted on one of the mutants, acn1-2. The gene expression analysis was done using 3 day-old seedlings of acn1-2 and the parent, Col-7, which were germinated on agar plates with and without exogenous sucrose. A cross-comparison of acn1-2 and Col-7 revealed that the expression of a number of carbohydrate responsive genes was altered in the mutant. The request for further microarray analysis is to confirm this result. Experiment Overall Design: Number of plants pooled:3 x 1000 seedlings

Project description:This proposal is aimed at providing transcriptome data to underpin a long-term joint research programme of Steve Smith and Alison Smith. We are jointly studying starch synthesis and breakdown in Arabidopsis leaves, and individually studying other enzymes of carbohydrate metabolism (eg. sucrose synthases, invertases, sugar transporters). Collectively these enzymes are encoded by up to 100 known genes, but there are many others of relevance to our studies. For several years we have employed a defined set of growth conditions for this work (resulting in numerous publications). We have extensive data for changes in the amounts of starch, malto-oligosaccharides and sugars throughout the diurnal cycle in these plants, and we intend to quantitate numerous key enzymes. We now wish to profile changes in transcripts in these plants, so that this information can be correlated with changes in the amounts of key enzymes and metabolites. Analysis of the data sets will help us to relate the synthesis of certain enzymes to particular metabolic functions, and also to help identify genes encoding novel proteins involved in carbohydrate metabolism. Current research is aimed at discovering such novel proteins using proteomics approaches (BBSRC Grant: _Discovery and Functional Analysis of the Starch Proteome_). While the growth conditions (12h photoperiod, 150 umol/m2/s, 20C) and ecotype (Col-0) are specifically tailored to our experiments, they will be of value to the wider community, and could form the basis for collaborative studies with other groups. The experiment has involved sampling leaves at eleven different time points as follows: 0, 1, 2, 4, 8, 12, 13, 14, 16, 20, and 24 h (where time 0 is the onset of dark and 12 h is the onset of light). The 24 h time point is a repeat of 0 h. This sequence provides relatively more samples immediately after the light-dark transitions, when changes in metabolism are most pronounced. Plants were grown in a controlled environment chamber under defined conditions, and selected for harvest according to a random number generator. Three fully expanded leaves were harvested from each of 20 plants for each sample. Leaves were frozen at -80 C and a portion saved for metabolite and enzyme assays while RNA was isolated from the remainder. The RNA has been purified and is ready to send to Nottingham. Experiment Overall Design: Number of plants pooled:20 Experiment Overall Design: Biological replicates: 2

Project description:Our goals are to discover the basis of the stress-sensitive phenotypes of the sfr2, sfr3 and sfr6 mutants, and to distinguish damage-repair from damage-prevention-related transcription in the wild type. The effects of sfr2 and sfr3 on cold-induced gene expression will be observed. Since sfr6 causes sensitivity to drought as well as freezing, the effects of sfr6 on the transcriptional response to drought is studied; an observation of cold-induced sfr6 expression is needed for direct comparison to the effect of drought. Unstressed mutants, and equivalently-stressed wild types, are necessary controls. The above experiments are conducted on tissue-culture-grown plants grown under 24 hr illumination for maximum reproducibility and comparability to other transcriptomic experiments.Freezing causes physiological changes even in a hardy, cold-acclimated wild type. During the recovery period, gene expression will reflect the induction of damage-repair processes distinct from the damage-prevention associated with cold acclimation. This will be detected by observing the wild-type transcriptome at two time points during recovery from a freezing episode. The appropriate controls is the unfrozen, cold-acclimated wild type. Plants for this experiment will be soil-grown in an 9/15 day/night cycle to the rosette stage, and this regime will be maintained during acclimation and freezing treatments.Cold-induction will be 10 days at 4°C; drought will be imposed by placing excised leaves in a desiccator for 6 h. The youngest fully-expanded rosette leaves will be harvested for RNA extraction. Experiment Overall Design: Number of plants pooled:18

Project description:This application is the second part of a BBSRC-funded grant to compare and contrast the plastid-signalling pathways disrupted by Norflurazon and far-red light treatment of Arabidopsis seedlings. The first application of this laboratory to GARNet's Affymetrix service (2002-08-25-17.41.49_McCormac) addressed the Norflurazon pathway; this application addresses the far-red pathway. The assembly of photosynthetic complexes in developing chloroplasts is critical to the establishment of the autotrophic plant. This requires light-mediated upregulation of both nuclear- and chloroplast-encoded genes. The expression of such photosynthetically-associated nuclear genes is also often dependant on a retrograde plastid signal which emanates from chloroplasts to modulate nuclear transcription. Extensive studies using the herbicide Norflurazon to knock-out the plastid signal (including this lab's previous Affymetrix application to GARNet) are identifying the affected gene sets. However, genetic studies have indicated the existence of more than one plastid signalling pathway. We have recently investigated a phytochrome A-mediated, far-red (FR) input pathway which blocks subsequent chloroplast development under white light (WL). This has also been found to inhibit the transcription of a small group of known nuclear-encoded plastidic proteins. Here we wish to establish how wide-reaching this FR-effect is on nuclear transcription, and will directly compare the affected gene groups with those identified from our earlier (and other's) studies with a Norflurazon treatment. In this array experiment we will compare RNA from seedlings grown in complete darkness (D) before transfer to WL, with that of seedlings preconditioned under a restricted wavelength FR source before exposure to WL. This comparison of FR- and Norflurazon-affected gene groupings will indicate whether the plastid signalling pathways are likely to be the same, overlapping or highly divergent. As well as wild-type seedlings, the gun1,gun5 mutant line is to be used as both these alleles are well established as alleviating the Norflurazon-inhibited pathway, but their affect on the FR-pathway is less clear. A single replicate of a phyA-null mutant line will also be included in order to differentiate between specific phytochromeA-mediated responses and other FR effects. It is envisaged that, in general, D- and FR-treated samples of the phyA mutant line will respond in the same way as each other and as the wild-type D-treated samples and, thus, the lack of a biological repeat in this case is not a major short-fall. The proposed experiment will consist of: wild-type: D-pretreated (x2 biological replicates) wild-type: FR-preconditioned (x2) gun1,gun5: D-pretreated (x2) gun1,gun5: FR-preconditioned (x2) phyA: D-pretreated (x1) phyA: FR-preconditioned (x1) Experiment Overall Design: Number of plants pooled:300 seedlings

Project description:The mutants iae1 and iae2 have been mapped to two distinct loci on chromosome 2. With the aid of the GetCID service, we believe iae1 has been localised to a relatively small region (~100kb); while mapping has restricted iae2 to a small interval (~50kb) with a very limited number of candidate genes. Although it has proved difficult to determine which gene is mutated in iae1, we belive that use of the transcriptomics service will help identify which genes are affected (directly and indirectly) in this background. The iae2 locus is sufficiently restricted by genetics and by molecular data that identifying a candidate (and any downstream loci affected) should be straightforward. We require the use of the full genome chips. The data from this experiment should help tie together the data we have for a paper that is currently in preparation. Experiment Overall Design: Number of plants pooled:30 (done)