Project description:The green peach aphid (Myzus persicae) is a phloem-feeding insect that causes economic damage on a wide array of crops. Using a luminol-based assay, a superoxide-responsive reporter gene (Zat12::luciferase), and a probe specific to hydrogen peroxide (HyPer), we demonstrated that this aphid induces accumulation of reactive oxygen species (ROS) in Arabidopsis thaliana. Similar to the apoplastic oxidative burst induced by pathogens, this response to aphids was rapid and transient, with two peaks occurring within 1 and 4 hr after infestation. Aphid infestation also induced an oxidative response in the cytosol and peroxisomes, as measured using a redox-sensitive variant of green fluorescent protein (roGFP2). This intracellular response began within minutes of infestation but persisted 20 hr or more after inoculation, and the response of the peroxisomes appeared stronger than the response in the cytosol. Our results suggest that the oxidative response to aphids involves both apoplastic and intracellular sources of ROS, including ROS generation in the peroxisomes, and these different sources of ROS may potentially differ in their impacts on host suitability for aphids.

Project description:In addition to the important role of abscisic acid (ABA) in abiotic stress signalling, basal and high ABA levels appear to have a negative effect on disease resistance. Using the ABA-deficient sitiens tomato (Solanum lycopersicum) mutant and different application methods of exogenous ABA, we demonstrated the influence of this plant hormone on disease progression of Erwinia chrysanthemi. This necrotrophic plant pathogenic bacterium is responsible for soft rot disease on many plant species, causing maceration symptoms mainly due to the production and secretion of pectinolytic enzymes. On wild-type (WT) tomato cv. Moneymaker E. chrysanthemi leaf inoculation resulted in maceration both within and beyond the infiltrated zone of the leaf, but sitiens showed a very low occurrence of tissue maceration, which never extended the infiltrated zone. A single ABA treatment prior to infection eliminated the effect of pathogen restriction in sitiens, while repeated ABA spraying during plant development rendered both WT and sitiens very susceptible. Quantification of E. chrysanthemi populations inside the leaf did not reveal differences in bacterial growth between sitiens and WT. Sitiens was not more resistant to pectinolytic cell-wall degradation, but upon infection it showed a faster and stronger activation of defence responses than WT, such as hydrogen peroxide accumulation, peroxidase activation and cell-wall fortifications. Moreover, the rapid activation of sitiens peroxidases was also observed after application of bacteria-free culture filtrate containing E. chrysanthemi cell-wall-degrading enzymes and was absent during infection with an out E. chrysanthemi mutant impaired in secretion of these extracellular enzymes.

Project description:BACKGROUND:The green peach aphid (GPA), Myzus persicae (Sülzer), is a widespread phloem-feeding insect that significantly influences the yield and visual quality of peach [Prunus persica (L.) Batsch]. Single dominant gene (Rm3)-based resistance provides effective management of this invasive pest, although little is known about the molecular responses of plants to GPA feeding. RESULTS:To illustrate the molecular mechanisms of monogenic resistance in peach to young tissue-infecting GPAs, aphid-resistant/aphid-susceptible peach lines from a segregating population with Rm3/rm3 and rm3/rm3 genotypes were infested with GPAs for 3 to 72 h. Transcriptome analysis of the infested tissues identified 3854 differentially expressed genes (DEGs). Although the majority of the DEGs in the resistant line also responded to aphid attack in the susceptible line, the overall magnitude of change was greater in the resistant line than in the susceptible line. The enriched gene ontology of the 3854 DEGs involved in plant defence responses included redox situation, calcium-mediated signalling, transcription factor (e.g., WRKY, MYB, and ERF), MAPK signalling cascade, phytohormone signalling, pathogenesis-related protein, and secondary metabolite terms. Of the 53 genes annotated in a 460 kb interval of the rm3 locus, seven genes were differentially expressed between the aphid-resistant and aphid-susceptible peach lines following aphid infestation. CONCLUSIONS:Together, these results suggest that the Rm3-dependent resistance relies mainly on the inducible expression of defence-related pathways and signalling elements within hours after the initiation of aphid feeding and that the production of specific secondary metabolites from phenylpropanoid/flavonoid pathways can have major effects on peach-aphid interactions.

Project description:Lineages of the generalist hemipteran herbivore Myzus persicae (green peach aphid) that have expanded their host range to include tobacco often have elevated nicotine tolerance. The tobacco-adapted M. persicae lineage used in this study was able to reproduce on nicotine-containing artificial diets at concentrations that were 15-fold higher than those that were lethal to a non-adapted M. persicae lineage. Fecundity of the nicotine-tolerant M. persicae lineage was increased by 100 ?M nicotine in artificial diet, suggesting that this otherwise toxic alkaloid can serve as a feeding stimulant at low concentrations. This lineage also was pre-adapted to growth on tobacco, exhibiting no drop in fecundity when it was moved onto tobacco from a different host plant. Although growth of the non-tobacco-adapted M. persicae lineage improved after three generations on tobacco, this higher reproductive rate was not associated with increased nicotine tolerance. Myzus persicae gene expression microarrays were used to identify transcripts that are up-regulated in response to nicotine in the tobacco-adapted lineage. Induced expression was found for CYP6CY3, which detoxifies nicotine in M. persicae, other genes encoding known classes of detoxifying enzymes, and genes encoding secreted M. persicae salivary proteins.

Project description:Copper-based antimicrobial compounds are widely and historically used to control plant diseases, such as late blight caused by Phytophthora infestans, which seriously affects the yield and quality of potato. We previously identified that copper ion (Cu2+ ) acts as an extremely sensitive elicitor to induce ethylene (ET)-dependent immunity in Arabidopsis. Here, we found that Cu2+ induces the defence response to P. infestans in potato. Cu2+ suppresses the transcription of the abscisic acid (ABA) biosynthetic genes StABA1 and StNCED1, resulting in decreased ABA content. Treatment with ABA or inhibitor fluridone made potato more susceptible or resistance to late blight, respectively. In addition, potato with knockdown of StABA1 or StNCED1 showed greater resistance to late blight, suggesting that ABA negatively regulates potato resistance to P. infestans. Cu2+ also promotes the rapid biosynthesis of ET. Potato plants treated with 1-aminocyclopropane-1-carboxylate showed enhanced resistance to late blight. Repressed expression of StEIN2 or StEIN3 resulted in enhanced transcription of StABA1 and StNCED1, accumulation of ABA and susceptibility to P. infestans. Consistently, StEIN3 directly binds to the promoter regions of StABA1 and StNCED1. Overall, we concluded that Cu2+ triggers the defence response to potato late blight by activating ET biosynthesis to inhibit the biosynthesis of ABA.

Project description:Reference: De Vos and Jander, 2009 - Plant, Cell, and Environment Aim: Identification of genes responding to aphid saliva. Background: During feeding on phloem sap aphids repeatedly salivate into the sieve element. It is thought that compounds in aphid saliva play a role in sustainable feeding. These compounds may include proteins and small molecules, which can function as virulence factors. Growth conditions Plants: Seeds of wild-type Arabidopsis thaliana (Col-0) were obtained from the were kept in 0.1% Phytagar (Invitrogen, Carlsbad, CA) for 24 h at 4°C prior to planting on Cornell mix with Osmocoat fertilizer. Plants were grown in Conviron growth chambers in 20- x 40-cm nursery flats at a photosynthetic photon flux density of 200 mmol m-2 s-1 and a 16-h photoperiod. The temperature in the chambers was 23°C and the relative humidity was 50%. Plants were grown for 3 weeks and used in experiments before flowering. Aphids: All experiments were conducted with a tobacco-adapted red lineage of M. persicae. Aphids were raised on cabbage (Brassica oleracea) with a 16-h day (150 mmol m-2 s-1 at 24°C) and an 8-h night (19°C) at 50% relative humidity. Experimental set-up/treatment: Fifty aphids were allowed to feed from 50 µL artificial diet, containing sucrose and amino acids (Kim and Jander, 2007) between two layers of Parafilm. After 24 h, artificial diet from 20 aphids and control (0 aphids) diet cups was collected and infiltrated into leaves of intact Arabidopsis plants using a 1-mL syringe without the needle. Plants for control diet and aphid saliva containing diet were grown in the same pot to allow for a paired comparison. Eighteen leaves (3 leaves from 6 plants) treated with control and aphid saliva containing diet were harvested and immediately frozen in liquid nitrogen. This experiment was repeated 3 times to function as independent biological replicates. RNA extraction + processing: RNA was extracted using the Qiagen Plant RNeasy kit. RNA quality and quantity was assessed with an Agilent BioAnalyser 2100. Samples were processed by the Cornell Microarray facility. Whole genome gene expression profiling was done using Affymetrix ATH1 GeneChips. Data analysis: Raw data from the microarrays was normalized at probe-level using gcRMA algorithm. The detection calls (present, marginal, absent) for each probe set was obtained using the GCOS system. Significance of gene expression was determined using the LIMMA (Smyth, 2004) program and raw p values of multiple tests were corrected using False Discovery Rate (FDR).

Project description:Novel male-biased expression in paralogs of the aphid slilmfast nutrient amino acid transporter expansion

Project description:Insecticide resistance mechanisms Myzus persicae: Genotypes Insecticide vs. Genotypes Control

Project description:Small RNA sequencing of Myzus persicae exposed to PLRV and PVY

Project description:The genetic architecture of an aphid (Myzus persicae) host shift: an adaptive walk protected an aphid (Myzus p. nicotianae) and its endosymbiont from plant chemical defences