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:The fungus Puccinia striiformis f.sp. tritici (PST) is the causal pathogen of stripe rust in wheat. New highly virulent PST races appeared at the beginning of this century and spread rapidly causing significant yield losses in wheat production worldwide. Race PST-08/21 was isolated in the UK in 2008 Yr1, Yr2, Yr3, Yr4, Yr6, Yr9, Yr17, Yr27, Yr32, YrRob, YrSol. We applied the RNAseq approach to refine the gene prediction in de novo assembled PST 08/21 contigs and to determine which genes are expressed during wheat infections. Total RNA was extracted from a pool of stripe rust infected wheat leaves and from two biological replicates of haustoria isolates.

Project description:The fungus Puccinia striiformis f.sp. tritici (PST) is the causal pathogen of stripe rust in wheat. New highly virulent PST races appeared at the beginning of this century and spread rapidly causing significant yield losses in wheat production worldwide. Race PST-08/21 was isolated in the UK in 2008 Yr1, Yr2, Yr3, Yr4, Yr6, Yr9, Yr17, Yr27, Yr32, YrRob, YrSol. We applied the RNAseq approach to refine the gene prediction in de novo assembled PST 08/21 contigs and to determine which genes are expressed during wheat infections.

Project description:The wheat gene Lr34 confers partial resistance to all races of Puccinia triticina, the causal agent of wheat leaf rust. However, the biological basis for the exceptional durability of Lr34 is unclear. The Affymetrix wheat genome array was used to identify wheat genes differentially expressed in a compatible interaction (Tc), an R-gene mediated incompatible interaction (Tc-Lr1), and a race non-specific resistance interaction (Tc-Lr34) in response to infection challenge by P. triticina race 1 at anthesis. Transcriptome interrogation was conducted by comparing mock- and P. triticina-inoculated leaves harvested at 3 and 7 days post inoculation (dpi). Keywords: Time course

Project description:The wheat gene Lr34 confers partial resistance to all races of Puccinia triticina, the causal agent of wheat leaf rust. However, the biological basis for the exceptional durability of Lr34 is unclear. The Affymetrix wheat genome array was used to identify wheat genes differentially expressed in a compatible interaction (Tc), an R-gene mediated incompatible interaction (Tc-Lr1), and a race non-specific resistance interaction (Tc-Lr34) in response to infection challenge by P. triticina race 1 at anthesis. Transcriptome interrogation was conducted by comparing mock- and P. triticina-inoculated leaves harvested at 3 and 7 days post inoculation (dpi). SUBMITTER_CITATION: Bolton, M.D., Kolmer, J.A., Xu, W.W., and Garvin, D.F. 2008. Lr34-mediated leaf rust resistance in wheat: transcript profiling reveals a high energetic demand supported by transient recruitment of multiple metabolic pathways. Molecular Plant-Microbe Interactions 21:1515-1527. Experiment Overall Design: The Affymetrix wheat genome array was used to identify wheat genes differentially expressed in a compatible interaction (Tc), an R-gene mediated incompatible interaction (Tc-Lr1), and a race non-specific resistance interaction (Tc-Lr34) in response to infection challenge by P. triticina race 1 at anthesis. Transcriptome interrogation was conducted on leaves harvested at 3 and 7 days post inoculation (dpi). The study utilized a randomized complete block design with three replicates for each genotype, and employed univariate analysis (t-tests) between mock- and P. triticina-inoculated plants within each genotype at each timepoint, for a total of six comparisons across the entire experiment, utilizing a total 36 Affymetrix Wheat Genome Array GeneChips.

Project description:High plasticity of common wheat is attributed to the captured and polyploidization-promoted diversity. However, uncontrolled subgenome diversification can lead to hybrid conflict and dysgenesis, resulting in decreased diversity. How genomic diversity is maintained and interpreted to increase plasticity is unclear. By data-mining from the binding of 193 genome-wide trans-factors and genetic perturbations in common wheat, we identified LHP1 as a major regulator of subgenome-diversified defense genes, enhancer RNAs, and metabolite synthesis-related gene clusters via H3K27me3. Stripe rust infection leads to a global decrease in LHP1-mediated H3K27me3, deprivation of which enhances common wheat stripe rust resistance. We also revealed the consistency between subgenome diversity and population diversity, potentially promoted by LHP1, implying the recent diversification preferentially occurred in the captured subgenome-diversified regions regulated by LHP1. Thus, common wheat benefitted from multi-faced role of LHP1 in promoting sequence diversity and repressing subgenome-diversified defenses; this constraint is eliminated by pathogen infections, enabling timely release and fixation of favorable variations, conferring the evolutionary advantage and high plasticity of common wheat.

Project description:Comparative analysis of transcripts associated with all-stage resistance to stripe rust in wheat

Project description:Stem rust of wheat is a deleterious fungal disease across the globe causing severe yield losses. Although, many stem rust resistance genes (Sr) are being used in wheat breeding programs, new emerging stem rust pathotypes are a challenge to important Sr genes. In recent years, multiple studies on leaf and yellow rust molecular mechanism have been done, however, for stem rust such studies are lacking. Current study investigated stem rust induced response in the susceptible wheat genotype C306 and its Near Isogenic Line (NIL) for Sr24 gene, HW2004, using microarray analysis to understand the transcriptomic differences at different stages of infection. Results showed that HW2004 has higher basal levels of several important genes involved in pathogen detection, defence, and display early activation of multiple defence mechanisms. Further Gene Ontology (GO) and pathway analysis identified important genes responsible for pathogen detection, downstream signalling cascades and transcription factors (TFs) involved in activation and mediation of defence responses. Results suggest that generation of Reactive Oxygen Species (ROS), cytoskeletal rearrangement, activation of multiple hydrolases, and lipid metabolism mediated biosynthesis of certain secondary metabolites are collectively involved in Sr24-mediated defence in HW2004, in response to stem rust infection. Novel and unannotated, but highly responsive genes were also identified, which may also contribute towards resistance phenotype. Furthermore, certain DEGs also mapped close to the Sr24-linked marker on Thinopyrum elongatum translocated fragment on wheat 3E chromosome, which advocate further investigations for better insights of the Sr24-mediated stem rust resistance.

Project description:WGS of wheat stripe rust isolates

Project description:The wheat gene Lr1 imparts resistance to certain races of the leaf rust pathogen Puccinia triticina. However, the biological basis underlying the complex resistance mechanisms remains largely unknown. Gene expression profiling analyses using the Affymetrix GeneChipM-BM-. Wheat Genome Array were performed with six independent Lr1 transgenic lines sampled before inoculation (0h) and at 6 and 24 h after inoculation with the avirulent P. triticina race CCDS. For the 6 and 24 h time points, 3M-BM- 384 probe sets corresponding to 2M-BM- 978 transcripts were differentially expressed as compared to the plants before inoculation. Genes involved in defence signalling were triggered as early as 6 h post inoculation (HPI) and included COI1, the primary component of jasmonic acid signalling. By 24 HPI, a shift in plant cellular metabolism, namely carbon conservation, was notable. The enzymes of glycolysis and gluconeogenesis were down-regulated, however, enzymes linked to alternative carbon sequestration processes such as the glyoxylate cycle were up-regulated. Also at 24 HPI, various secondary signalling molecules belonging to the various hormone signalling pathways were triggered. These microarray data suggest that the Lr1 mediated leaf rust resistance is achieved by early onset of defence signalling followed by co-ordinated interplay of metabolism alteration and elicitation of defence responses. We used microarrays to detail the early gene expression events underlying Lr1-mediated resistance to Puccinia triticina pathogen in wheat. Three biological replicates with six independent Lr1 transgenic lines were used in this study to eliminate the possibility of false discovery of genes due to copy number variation or the position of insertion of the transgene Lr1. Early time points of 6 and 24 HPI were compared to 0 h (prior to inoculation) to capture the early signalling events involved in Lr1-mediated response to rust infection.