Project description:The Atss3 mutant and WT plants were arranged according to a Randomized Complete Block Design. The plants were planted in rows with seven rows in each flat; two plants of the same genotype/pot. Plants were grown under a SD photoperiod (8 h light/16 h dark) in a growth chamber as described. Eight randomly selected rows were harvested for each time point from different flats. Plant material was harvested at five time points in the diurnal cycle (1, 4, 8.5, 12, and 16 h; Time 0 is the beginning of the light period); harvesting was conducted under a green safety light. Each sample consisted of rosette leaves (leaves 5 to 8, staged following Bowmann (1994); photosynthetically active (Stessman et al., 2002)) from sixteen six-week-old plants. Leaf samples were frozen in liquid N2 immediately after harvest and stored at -80‚°C for RNA extraction. The experiment was done twice and independent randomizations for plant growth and harvest were used for the two replicates.

Project description:Transcriptome analysis of RNA samples from WT and antisense-acetyl-CoA (ACLA) mutant. The antisense-ACLA mutant and WT plants were arranged according to a Randomized Complete Block Design. The plants were planted in rows with seven rows in each flat; two plants of the same genotype/pot. Plants were grown under a SD photoperiod (8 h light/16 h dark) in a growth chamber as described. Eight randomly selected rows were harvested for each time point from different flats. Plant material was harvested at 11 time points in the diurnal cycle (0, 0.5,1, 4, 6, 8,12 h in the dark condition, and 0, 0.5, 1, 4 h in the light condition; Time 0 is the beginning of the light/dark period); harvesting was conducted under a green safety light. Each sample consisted of rosette leaves (leaves 5 to 8, staged following Bowmann (1994); photosynthetically active (Stessman et al., 2002)) from sixteen six-week-old plants. Leaf samples were frozen in liquid N2 immediately after harvest and stored at -80‚°C for RNA extraction. The experiment was done twice and independent randomizations for plant growth and harvest were used for the two replicates.

Project description:Time-course expression profiles of Bgh challenged barley cultivar C.I. 16151 (harboring the Mla6 powdery mildew resistance allele) and its fast-neutron-derived "Bgh-induced tip cell death1" mutant, bcd1, were compared using the 22K Barley1 GeneChip. Planting, stage of seedlings, harvesting, and experimental design were part of a larger experiment described by Caldo et al. (2004). PLEXdb BB4. Experiment Design: C.I. 16151 (wildtype) and bcd1 (mutant) were planted in separate 20 x 30-cm flats using sterilized potting soil. Each experimental flat consisted of six rows of 15 seedlings, with rows randomly assigned to one of six harvest time points (0, 8, 16, 20, 24, and 32 hai). Seedlings grown to the 1st leaf stage with 2nd leaf unfolded were inoculated with a high density of fresh conidiospores (84 +/- 19 spores/mm2). Groups of flats were placed at 18C (8-hour darkness, 16-hour light) in separate controlled growth chambers corresponding to the Bgh isolates. Rows of plants were harvested at each assigned time points and snap frozen in liquid nitrogen. The entire experiment was repeated three times in a standard split-split-plot design with 72 experimental units (2 genotypes x 2 pathogen isolates x 6 time points x 3 replications). Treatment Description: The samples constituted pairwise combinations of the the cultivar C.I. 16151(containing the Mla6 resistance allele), and its fast-neutron-derived "Bgh-induced tip cell death1" mutant, bcd1 with the two Bgh (Blumeria graminis f. sp. hordei) isolates, 5874 (AvrMla6, AvrMla1) and K1 (AvrMla13, AvrMla1). For each replication, individual genotypes were planted in separate 20 x 30 cm flats using sterilized potting soil. Each experimental flat consisted of six rows of 15 seedlings, with rows randomly assigned to one of six harvest times (0, 8, 16, 20, 24, and 32 hai). Seedlings were grown to the 2nd-leaf stage with 1st leaf unfolded, and inoculation was performed at 4 PM Central Standard Time by tipping the flats at 45oC and dusting the plants with a high density of fresh conidiospores [84 +/- 19 spores/mm2]. This procedure was repeated from the opposite angle to ensure that a high proportion of the cells are in contact with the fungus. This conidial density per unit leaf area routinely results in greater than 50% of epidermal cells that are successfully infected. Groups of flats were placed at 18oC (8 hours darkness, 16 hours light, 8 hours darkness) in separate controlled growth chambers corresponding to the Bgh isolate. Rows of plants were harvested at their assigned harvest times and flash-frozen in liquid nitrogen. ****[PLEXdb(http://www.plexdb.org) has submitted this series at GEO on behalf of the original contributor, Roger P Wise. The equivalent experiment is BB46 at PLEXdb.]

Project description:Time-course expression profiles of Bgh challenged barley cultivar C.I. 16151 (harboring the Mla6 powdery mildew resistance allele) and its fast-neutron-derived "Bgh-induced tip cell death1" mutant, bcd1, were compared using the 22K Barley1 GeneChip. Planting, stage of seedlings, harvesting, and experimental design were part of a larger experiment described by Caldo et al. (2004). PLEXdb BB4. Experiment Design: C.I. 16151 (wildtype) and bcd1 (mutant) were planted in separate 20 x 30-cm flats using sterilized potting soil. Each experimental flat consisted of six rows of 15 seedlings, with rows randomly assigned to one of six harvest time points (0, 8, 16, 20, 24, and 32 hai). Seedlings grown to the 1st leaf stage with 2nd leaf unfolded were inoculated with a high density of fresh conidiospores (84 +/- 19 spores/mm2). Groups of flats were placed at 18C (8-hour darkness, 16-hour light) in separate controlled growth chambers corresponding to the Bgh isolates. Rows of plants were harvested at each assigned time points and snap frozen in liquid nitrogen. The entire experiment was repeated three times in a standard split-split-plot design with 72 experimental units (2 genotypes x 2 pathogen isolates x 6 time points x 3 replications). Treatment Description: The samples constituted pairwise combinations of the the cultivar C.I. 16151(containing the Mla6 resistance allele), and its fast-neutron-derived "Bgh-induced tip cell death1" mutant, bcd1 with the two Bgh (Blumeria graminis f. sp. hordei) isolates, 5874 (AvrMla6, AvrMla1) and K1 (AvrMla13, AvrMla1). For each replication, individual genotypes were planted in separate 20 x 30 cm flats using sterilized potting soil. Each experimental flat consisted of six rows of 15 seedlings, with rows randomly assigned to one of six harvest times (0, 8, 16, 20, 24, and 32 hai). Seedlings were grown to the 2nd-leaf stage with 1st leaf unfolded, and inoculation was performed at 4 PM Central Standard Time by tipping the flats at 45oC and dusting the plants with a high density of fresh conidiospores [84 +/- 19 spores/mm2]. This procedure was repeated from the opposite angle to ensure that a high proportion of the cells are in contact with the fungus. This conidial density per unit leaf area routinely results in greater than 50% of epidermal cells that are successfully infected. Groups of flats were placed at 18oC (8 hours darkness, 16 hours light, 8 hours darkness) in separate controlled growth chambers corresponding to the Bgh isolate. Rows of plants were harvested at their assigned harvest times and flash-frozen in liquid nitrogen. ****[PLEXdb(http://www.plexdb.org) has submitted this series at GEO on behalf of the original contributor, Roger P Wise. The equivalent experiment is BB46 at PLEXdb.] genotype: Mla6 - pathogen isolates: 5874 - time: 0(3-replications); genotype: Mla6 - pathogen isolates: 5874 - time: 8(3-replications); genotype: Mla6 - pathogen isolates: 5874 - time: 16(3-replications); genotype: Mla6 - pathogen isolates: 5874 - time: 20(3-replications); genotype: Mla6 - pathogen isolates: 5874 - time: 24(3-replications); genotype: Mla6 - pathogen isolates: 5874 - time: 32(3-replications); genotype: Mla6 - pathogen isolates: K1 - time: 0(3-replications); genotype: Mla6 - pathogen isolates: K1 - time: 8(3-replications); genotype: Mla6 - pathogen isolates: K1 - time: 16(3-replications); genotype: Mla6 - pathogen isolates: K1 - time: 20(3-replications); genotype: Mla6 - pathogen isolates: K1 - time: 24(3-replications); genotype: Mla6 - pathogen isolates: K1 - time: 32(3-replications); genotype: 11542 - pathogen isolates: 5874 - time: 0(3-replications); genotype: 11542 - pathogen isolates: 5874 - time: 8(3-replications); genotype: 11542 - pathogen isolates: 5874 - time: 16(3-replications); genotype: 11542 - pathogen isolates: 5874 - time: 20(3-replications); genotype: 11542 - pathogen isolates: 5874 - time: 24(3-replications); genotype: 11542 - pathogen isolates: 5874 - time: 32(3-replications); genotype: 11542 - pathogen isolates: K1 - time: 0(3-replications); genotype: 11542 - pathogen isolates: K1 - time: 8(3-replications); genotype: 11542 - pathogen isolates: K1 - time: 16(3-replications); genotype: 11542 - pathogen isolates: K1 - time: 20(3-replications); genotype: 11542 - pathogen isolates: K1 - time: 24(3-replications); genotype: 11542 - pathogen isolates: K1 - time: 32(3-replications)

Project description:Stripe rust, caused by Puccinia striiformis f. sp. tritici, is a destructive disease of wheat worldwide. Genetic resistance is the preferred method for controlling stripe rust, of which two major types are race-specific and race non-specific resistance. Race-specific resistance includes the qualitatively inherited all-stage resistance, controlled by single major resistance (R) genes. Conversely, adult-plant resistance is race non-specific, inherited quantitatively, and is durable. Previously, we characterized the gene expression signatures involved in Yr5-controlled all-stage resistance and Yr39-controlled adult-plant resistance using the Affymetrix Wheat GeneChip. For this study, we designed and constructed custom oligonucleotide microarrays containing probes for the 116 and 207 transcripts that we had found important for the Yr5 and Yr39 resistance responses, respectively. We used this custom microarray to profile the resistance responses of eight wheat genotypes with all-stage resistance (Yr1, Yr5, Yr7, Yr8, Yr9, Yr10, Yr15, and Yr17). The aim of this analysis was to identify common and unique gene expression signatures involved in race-specific resistance accross genotypes, which were used to infer information regarding the general pathways involved in all-stage resistance. Keywords: Stress response Eight wheat genotypes with defined single gene all-stage resistance to particular stripe rust (Pst) isolates were selected for this study, as well as the Pst susceptible genotype ‘Avocet Susceptible’ (AVS). Near Isogenic Lines (NILs) for each of eight Yr resistance genes (Yr1, Yr5, Yr7, Yr8, Yr9, Yr10, Yr15 and Yr17) were developed at the Plant Breeding Institute, Sydney, Australia, by backcrossing the Yr gene donors with the recurrent susceptible spring wheat genotype (Triticum aestivum L.) AVS six times (AVS*6/Yr*) and selecting for the appropriate resistance at each generation. Both virulent and avirulent isolates of Pst were selected for each NIL, except for Yr15, for which no virulent isolate is currently known. Care was taken to select the fewest isolates needed to satisfy the spectrum of virulence/avirulence required, resulting in the use of six isolates identified as PST-17, PST-21, PST-43, PST-45, PST-78 and PST-AUS. Each isolate was selected and maintained on susceptible genotypes. For each of three biological replications, individual genotypes were planted in separate 25 X 42.5-cm flats using a potting mix (6 peat moss: 4 vermiculite with lime: 3 sand: 3 commercial potting mix: 2 perlite: 1.7 g/L lime: 3.3 g/L Osmocote: 2.2 g/L ammonium nitrate). Each flat consisted of three rows of six seedlings, with rows randomly assigned one of two harvest times (24 and 48 h post-inoculation). Seedlings from the 3rd row were used to monitor the expected disease responses to inoculation. Seedlings were grown to the second leaf stage (Feekes 1.2, emergence with second leaf unfolded, ~10 days after planting) in a greenhouse with a diurnal temperature cycle of 10ºC (2:00 am) to 25ºC (2:00 pm) and a 16 h light/8 h dark cycle. Inoculation was performed by misting the plants with sterile water and applying a 1:20 urediniospore:talc mixture to leaves with a sterile brush. Talc was used to aid in the spread and adhesion of spores over leaf surfaces. Control flats were treated the same way except for the absence of spores in the talc. All treatments for each biological replication were performed at 9 am Pacific Standard Time. To promote spore germination, all flats were transferred to a dew chamber (100% RH) operating at 10ºC in the dark for 24 h, before being placed in a growth chamber with a diurnal temperature cycle of 4ºC (2:00 am) to 20ºC (2:00 pm) and a 16 h light/8 h dark cycle. Rows of plants were harvested from all flats at the assigned times for RNA extraction.

Project description:Cotton seeds (Gossypium hirsutum cv. CCRI12) were grown in a growth chamber under 29/25°C temperature and a 16:8 h light:dark cycle, and water was added every two days. All plants were used in experiments at the 6-7 fully expanded true leaf stage, which occurred 5-6 weeks after sowing. Cotton bollworm (CBW; Helicoverpa armigera) larvae were reared on an artificial diet and maintained at 27 ± 2°C, 75 ± 10% relative humidity, and 14:10 h light:dark in the laboratory. For insect treatment, seven H. armigera larvae (third instars) were placed on a group of three plants, which were kept within plastic bags (30 × 40 cm), until time of harvest, with samples for each time point maintained separately. Undamaged plants maintained under the same conditions were used as controls. Cotton leaves from control plants and plants exposed to H. armigera were harvested at 6 h, 12 h, 24 h, and 48 h after onset of herbivory. For each treatment group and time point, cotton leaves were harvested from the three plants per treatment group and flash frozen in liquid nitrogen. For each time point, three replicate treatments and controls were performed. For insect treatment, seven H. armigera larvae (third instars) were placed on a group of three plants, which were kept within plastic bags (30 × 40 cm), until time of harvest, with samples for each time point maintained separately. Undamaged plants maintained under the same conditions were used as controls. Cotton leaves from control plants and plants exposed to H. armigera were harvested at 6 h, 12 h, 24 h, and 48 h after onset of herbivory. For each treatment group and time point, cotton leaves were harvested from the three plants per treatment group and flash frozen in liquid nitrogen. For each time point, three replicate treatments and controls were performed.

Project description:The goal of this project is to compare the primary metabolite profile in different tissue types of the model plant Arabidopsis thaliana. Specifically, plants were grown hydroponically under the long-day (16hr light/day) condition at 21C. Tissue samples, including leaves, inflorescences, and roots were harvest 4 1/2 weeks post sowing. Untargeted primary metabolites profiling was carried out using GCTOF.

Project description:RESEARCH SUMMARY Bacterial blight and bacterial leaf streak, two of the most serious diseases of rice, are caused by Xanthomonas oryzae pathovar (pv.) oryzae (Xoo) and X. oryzae pv. oryzicola (Xoc) respectively. Xoo is a vascular pathogen that invades the xylem, whereas Xoc is non-vascular and colonizes the mesophyll apoplast. These distinctive types of infection represent the two most common ways plant pathogenic bacteria produce disease. As closely related pathogens of a model plant host, Xoo and Xoc constitute a powerful comparative system. We hypothesize that tissue-specific susceptibility to pathogenic bacteria can be explained partially by differential host responses during infection. To establish the global structure of susceptible responses to infection by Xoo and Xoc, we used the Affymetrix Rice Genome Array to analyze the abundance of transcripts in rice plants over four days after inoculation with virulent strains. MATERIAL AND METHODS - Plant Material: Oryza sativa ssp. japonica cv. Nipponbare plants were grown in pots containing LC-1 soil mixture, and arranged in flats of 20 pots, in growth chambers under a 12-h, 28ºC light and a 12-h, 25ºC dark cycle. To allow inversion of the flats for inoculation (modified dip-inoculation method, Niño-Liu et al, 2005, Journal of Phytopathology) seeds were sown through 1-cm perforations in a fibreglass tray resting on top of the pots. Peters Professional Fertilizer and iron chelate micronutrient were applied with watering every two days at rates of 0.25 and 4.5 g/L, respectively, until the day before inoculation. - Bacterial Strains and preparation of inoculum: Xoo strain PXO99A and Xoc strain BLS256 were used. For each, a single colony from a glucose yeast extract (GYE) agar plate was transferred to 5 ml of GYE liquid medium and incubated for 24 h at 28ºC with constant shaking at 250 rpm. Subsequently, 2 ml of this culture was transferred to 300 ml of fresh GYE liquid medium and incubated as above for an additional 18 h. Cells were pelleted by centrifugation at 4000 rpm. for 10 min, washed twice and resuspended in sterile 10 mm MgCl2 to an OD600 of 0.05, yielding 7 liters of inoculum. Tween-20 was added to a final concentration of 0.5%. - Modified dip-inoculation method: Fourteen days after sowing, and 2 h after the beginning of the light period, seedlings were inverted into inoculum, one flat each for Xoo, Xoc and Mock inoculum consisting of sterile 10 mM MgCl2 with 0.5% Tween-20, and vaccuum infiltrated at 500mm Hg for two minutes, two consecutive times, in a custom-made chamber. Following inoculation, plants were returned to the growth chamber. During growth, plants were cycled weekly in the same order through three growth chambers. In this way all plants could be incubated in the same final chamber following inoculation. For each replicate, position of the flats in the growth chamber (from left to right, used also for the order of inoculation and harvest) was determined by a split-plot design. - Timepoints, tissue collection: Within flats, assignment of pots for the harvest of inoculated tissue at 2, 4, 8, 24 and 96 h was made using a separate randomized complete block design. Tissue was harvested from plants in four pots (approximately 2g fresh weight) for each timepoint per inoculum per replication. Harvested tissue was immediately frozen in liquid nitrogen and stored at -80ºC until processing. - RNA isolation, purification, labeling, hybridizations, scanning: Total RNA was initially isolated from frozen whole plant tissue using the hot TRIzol reagent protocol for barley as described by Caldo et al (Plant Cell, 2004). The RNA was purified using Qiagen RNeasy spin columns, and adjusted to a final concentration of 1 ug/uL. Probe synthesis, labeling, and hybridization were performed at the Iowa State University GeneChip Core facility. ACKNOWLEDGEMENTS This work was supported by a grant (0227357) from the Plant Genome Research Program of the National Science Foundation. ****[PLEXdb(http://www.plexdb.org) has submitted this series at GEO on behalf of the original contributor, David O Niño-Liu. The equivalent experiment is OS3 at PLEXdb.] XOC - time: 2 hai (4-replications) XOC - time: 4 hai (4-replications) XOC - time: 8 hai (4-replications) XOC - time: 24 hai (4-replications) XOC - time: 96 hai (4-replications) XOO - time: 2 hai (4-replications) XOO - time: 4 hai (4-replications) XOO - time: 8 hai (4-replications) XOO - time: 24 hai (4-replications) XOO - time: 96 hai (4-replications) MOCK - time: 2 hai (4-replications) MOCK - time: 4 hai (4-replications) MOCK - time: 8 hai (4-replications) MOCK - time: 24 hai (4-replications) MOCK - time: 96 hai (4-replications)

Project description:Cotton seeds (Gossypium hirsutum cv. CCRI12) were grown in a growth chamber under 29/25°C temperature and a 16:8 h light:dark cycle, and water was added every two days. All plants were used in experiments at the 6-7 fully expanded true leaf stage, which occurred 5-6 weeks after sowing. Cotton bollworm (CBW; Helicoverpa armigera) larvae were reared on an artificial diet and maintained at 27 ± 2°C, 75 ± 10% relative humidity, and 14:10 h light:dark in the laboratory. For insect treatment, seven H. armigera larvae (third instars) were placed on a group of three plants, which were kept within plastic bags (30 Ã? 40 cm), until time of harvest, with samples for each time point maintained separately. Undamaged plants maintained under the same conditions were used as controls. Cotton leaves from control plants and plants exposed to H. armigera were harvested at 6 h, 12 h, 24 h, and 48 h after onset of herbivory. For each treatment group and time point, cotton leaves were harvested from the three plants per treatment group and flash frozen in liquid nitrogen. For each time point, three replicate treatments and controls were performed. For insect treatment, seven H. armigera larvae (third instars) were placed on a group of three plants, which were kept within plastic bags (30 Ã? 40 cm), until time of harvest, with samples for each time point maintained separately. Undamaged plants maintained under the same conditions were used as controls. Cotton leaves from control plants and plants exposed to H. armigera were harvested at 6 h, 12 h, 24 h, and 48 h after onset of herbivory. For each treatment group and time point, cotton leaves were harvested from the three plants per treatment group and flash frozen in liquid nitrogen. For each time point, three replicate treatments and controls were performed. In this study we present dynamic transcriptome analysis and volatile profiling of cotton plants fed upon by larvae of a leaf-chewing herbivore CBW. Plant transcriptomic changes induced by CBW were analyzed using Affymetrixâ??s Cotton GeneChips. Samples from a time course of six hour to 48 hours following onset of CBW feeding were analyzed to identify target genes and key pathways involved in the activation of herbivory-induced indirect defense and to explore genetic basis of such defense. In addition, we monitored the accumulation of VOCs, which represent changes in cotton plant phenotype, following CBW infestation.

Project description:Background: Maize plants developed typical gray leaf spot disease (GLS) symptoms initiating at the lower leaves and progressing to upper leaves through the season. Leaf material was collected at 77 days after planting, at which stage there were a large number of GLS disease necrotic lesions on lower leaves (8% surface area on average determined by digital image analysis), but very few lesions and only at chlorotic stage on leaves above the ear (average of 0.2% lesion surface area). Method:To collect material that reflected a difference between C.zeina infected B73 leaves and control B73 leaf material, samples were collected from two lower GLS infected leaves (second and third leaf internode below ear) , and two upper leaves with minimal GLS symptoms (second and third internode above ear), respectively. The two lower leaves from each plant were pooled prior to RNA extraction, and the two upper leaves from each plant were pooled prior to RNA extraction. Upper and lower leaf samples from three maize B73 plants were subjected to RNA sequencing individually. The three maize plants were selected randomly as one plant per row from three rows of ten B73 plants each. Result: A systems genetics strategy revealed regions on the maize genome underlying co-expression of genes in susceptible and resistance responses, including a set of 100 genes common to the susceptible response of sub-tropical and temperate maize.