Project description:Rain-fed plants are subjected to cycles of drought and re-watering. Thus, efficient recovery from drought may be among the key determinants in the success of these plants, yet the mechanisms by which plant recover from drought have been historically understudied. To parse out the specific molecular processes leading to stress recovery, we performed a fine-scale time course of bulk RNA sequencing starting just 15 minutes after rehydration. We revealed that transcriptional drought recovery is an active and rapid process involving activating thousands of recovery-specific genes. To map the immediate recovery responses in diverse leaf-cell-types, we performed a single-nucleus transcriptome analysis of the onset of recovery from long-term moderate drought. Here we show the formation of unique cell states initiated rapidly following plant rehydration. We reveal the activation of a microbial-autonomic induction of the immune system and demonstrate that the onset of recovery leads to increased resistance against pathogens in Arabidopsis (Arabidopsis thaliana), wild tomato (Solanum pennellii) and domesticated tomato (Solanum lycopersicum cv. M82). Our findings uncover that the preventive immune activation was preserved despite extensive selection during tomato domestication. Since rehydration increases microbial proliferation and, thus, the risk for infection, pre-activating immunity may be crucial for plants survival in natural environments. This work lays the foundation for unraveling the complexed processes actively facilitating stress recovery within plant leaves.

Project description:High throughput sequencing was used to investigate the production of small RNAs from cultivated tomato cultivar M82 and its wild relative Solanum pennellii. In order to understand the pattern of inheritance of the samll RNAs, interspecific hybrids (F1 and F2) along with series of introgressed lines comprising precise short genomic regions from S. pennellii in M82 background were used. Examination of small RNA production in several tomato lines.

Project description:High throughput sequencing was used to investigate the production of small RNAs from cultivated tomato cultivar M82 and its wild relative Solanum pennellii. In order to understand the pattern of inheritance of the samll RNAs, interspecific hybrids (F1 and F2) along with series of introgressed lines comprising precise short genomic regions from S. pennellii in M82 background were used.

Project description:The intent of the experiment was to infer, from transcriptome analysis, the occurrence of competent LTR retrotransposons in shoot apical meristems of Solanum lycopersicum. For this, we performed Illumina pair-end RNA-seq in M82 tomato samples of meristems, leaves and flowers. We also harvested meristems in plants subjected to long-term heat. In addition, we performed RNA-seq in meristems, leaves and flowers samples from Solanum pennellii, to aid phylogenetic interpretations.

Project description:RNA-seq of seedlings of four tomato species Solanum habrochaites, Solanum lycopersicum, Solanum pimpinelliolium, and Solanum pennellii. An additional panel of samples include many tissues from Solanum lycopersicum and Solanum pennellii in two light conditions

Project description:Seven different Solanaceae species, Potato (Solanum tubersosum), Tomato (Solanum lycopersicum), Eggplant (Solanum melongena), Pepper (Capsicum annuum), Tobacco (Nicotiana tabaccum), Petunia and Nicotiana benthiamana were subjected to drought stress. Drought stress was applied by stopping watering of the plants, control plants were normally watered with nutrient solution. Samples were collected at 0, 1, 3, 5, 7 and 10 days after the first application of the drought stress. RNA was isolated using Qiagen RNeasy. Keywords: Direct comparison

Project description:Transcriptomics study which main goal is to elucidate the programme of gene expression triggered by water stress in leaflets of the drought-tolerant wild-related tomato Solanum pennellii (acc. PE47) compared with domesticated tomato (S. lycopersicum, cv. P73). In this study we used S. lycopersicum (Sl) (cv. P73) and S. pennellii (Sp) (acc. PE47) species displaying remarkable divergences regarding drought tolerance, to investigate the physiological and molecular responses in leaves of plants grown without stress (control) and after four days of water withholding (water stress, WS), when plant water loss was significant but leaves did not show visual dehydration symptoms yet. Significant physiological differences between species were found, showing Sp leaves higher ability to avoid water loss. Leaf transcriptomic analysis showed important constitutive expression differences between Sp and Sl, including genes with unknown function. In relation to the genes specifically induced by drought in Sp, those linked to stomatal closure, cell wall and primary carbohydrate metabolism and, specially, nitrogen metabolism were identified. Thus, genes linked to NH4+ assimilation, GOGAT/GS cycle and the GDH- and GABA-shunt were specifically induced by water stress in leaves of Sp. Our results showed also the up-regulation in Sp of genes involved in JA biosynthesis pathway, which were induced in both conditions, whereas genes involved in ET biosynthesis were specifically induced under WS. Regarding ET signaling, ERF genes were up-regulated by WS in Sp, hinting at the importance of these transcriptional regulators in the drought response of Sp.

Project description:The goal of this study was to perform RNA-seq expression analysis on Solanum lycopersicum cv. M82 X S. pennellii introgression lines, deriving expression Quantitative Trait Loci which were analyzed together with pre-existing genomic and phenotypic data to define genes and regulatory pathways controlling tomato root development and observed natural variation. We completed the RNAseq expression profiling analysis and developed a tool to display this information graphically in collaboration with Nicholas Provart at the University of Toronto: http://bar.utoronto.ca/efp_tomato/cgi-bin/efpWeb.cgi?dataSource=ILs_Root_Tip_Brady_Lab To identify candidate genes and pathways we focussed on one root growth trait, root growth angle, and identified two statistically significant genomic regions within tomato root growth angle QTL containing two candidate genes that likely control the gravitropic setpoint angle (CDC73 and PAP27), both of which are conserved between Arabidopsis and tomato, and which we tested using transgenic lines of the Arabidopsis orthologs. A possible regulatory role for suberin in root growth angle control was also identified.

Project description:Tomatoes are one of the valuable sources of antioxidants such as carotenes, ascorbic acid (AsA), and phenolic compounds (flavonoids and hydroxycinnamic acid derivatives). These secondary metabolites have been proved to be beneficial for humans and animals because their involvement in the prevention of many proliferative and degenerative diseases. The aim of this work is to gain greater insights in the genetic control of phenylpropanoid accumulation in tomato fruit by using genomics-based strategies. In order to identify QTLs controlling antioxidant accumulation in tomato fruit we carried out a comparative analysis of Solanum pennellii x S. lycopersicum cv. M82 introgression lines (ILs) over three year trials in greenhouse environment. Among all, IL7-3 showed higher fruit content of total phenolics and the HPLC-UV profile revealed that chlorogenic acid mainly accounted for the higher performance of this line. To investigate in details genetic mechanisms and candidate genes controlling phenols synthesis and accumulation in IL7-3 fruit we performed a comparative transcriptomic analysis in tomato pericarp. In particular, RNA was extracted from percarp of IL7-3 and M82 parental line and hybridized on a 90k Combimatrix TomatArray 1.0. The experiment was repeated over two consecutive years. The transcriptomic approach allowed to identify 291 differentially expressed transcripts, 149 showing up-rgulation and 142 down-regulation. The ethylene signaling pathway has been involved in the modulation of the level of total phenolics in ripe fruit. In particular, an Ethilene Responsive Factor 1 (ERF1) was functionally characterized by TILLING (Targeting Local Lesion IN Genomes) approach. The mutant line expressed lower accumulation of phenolics in the fruit and additional insights on the regulation of phenolics in tomato ripe fruit were provided. Comparative microarray analysis between a tomato introgression line (IL7-3) expressing higher level of fruit total phenolics and its parental cultivar M82 (reference) was performed. In particular, samples were generated by pooling red-ripe fruit from the same plant and discarding the seeds, jelly parenchyma, columella and placenta tissues. Three plant replica were used for each line (IL7-3 and M82) and the experiment was replicated over two consecutive years.

Project description:We report here the RNAseq data generated from a drought experiment using tomato leaves (Solanum lycopersicum), in which three timepoints and two treatments were collected. More specifically, RNAseq was generated from tomato plants prior to drought (T0), during a period of drought (T1) and after a period of recovery from drought (T2). At timepoints 1 and 2 (T1 & T2), a control set of plants that were continuously watered are also included. Furthermore, at each timepoint, each leaf was dissected into two parts, including the vein and intervein. The samples are therefore named as Tissue/Timepoint/Treatment, and include VT0W (vein, T0, watered), VT1W (vein, T1, watered), VT1D (vein, T1, drought), VT2D, VT2W and IVT0W (intervein, T0, Watered), IVT1D, IVT1W, IVT2D, IVT2W. Note that VT2D and IVT2D, while named "drought", were actually recovered from drought.