Heat shock protein 70 and defence responses in plants: salicylic acid and programmed cell death.

Cronje, Marianne Jacqueline

06 May 2008

Background: Heat-shock (HS) proteins (HSP) are induced or increasingly expressed to protect against lethal environmental stresses. Hsp70 in particular, provides protection against various stresses including oxidative stress, is implicated in thermotolerance and appears to have an anti-apoptotic function. Anti-inflammatory salicylates potentiate the induction of the 70 kDa HSP (Hsp70) in mammals in response to HS, enhance thermotolerance and induce apoptosis. In plants, salicylic acid (SA) is a natural signalling molecule, mediating resistance in response to avirulent pathogens. The effects of salicylic acid-mediated increases in Hsp70/Hsc70 expression and its relation to events associated with PCD/ apoptosis in plants are unknown. Hypothesis and Objectives: The hypothesis studied in this investigation was that SA influences Hsp70 expression similar to that found in mammalian cells and may influence the choice between survival or death, whether apoptosis or necrosis. In order to verify this hypothesis the effect of SA alone or in combination with HS on Hsp70/Hsc70 accumulation and events associated with apoptosis were investigated through three main objectives: 1) Determine whether SA in plants, as in mammalian cells, can potentiate heat-induced Hsp70/Hsc70 accumulation or induce Hsp70/Hsc70 by itself at elevated levels. This was done by investigating the effect of SA at various concentrations on Hsp70/Hsc70 expression at normal temperatures or following heat. 2) Establish flow cytometry as a rapid and quantitative alternative for the evaluation of Hsp70 accumulation in plant protoplasts to be evaluated in concert with various parameters indicative of cellular integrity. 3) Investigate whether Hsp70/Hsc70 expression modulated by SA influences cell death (apoptosis/necrosis) or associated events such as mitochondrial membrane permeability (MMP) or reactive oxygen species (ROS) in plant protoplasts using flow cytometry. Materials and Methods: The effect of SA alone or in combination with HS on Hsp70/Hsc70 levels in tomato cells was investigated using biometabolic labelling and Western blotting. A flow cytometric assay was developed to determine Hsp70/Hsc70 levels in tobacco protoplasts. MMP and ROS were monitored by the fluorescent probes DiIC1(5) and H2DCFDA respectively, phosphatidylserine externalisation by annexin V binding and DNA fragmentation by the TUNEL assay in protoplasts treated with SA and/or HS. Results: Results obtained in the attainment of the three main objectives were: 1) In plants, as in mammals, low concentrations of SA do not induce Hsp70/Hsc70 but significantly potentiate heat-induced Hsp70/Hsc70 levels while cytotoxic levels significantly induce Hsp70/Hsc70. In cell suspension cultures, this induction was preceded by increased membrane permeability. 2) Flow cytometry can be implemented as a rapid, quantitative alternative to detect intracellular Hsp70/Hsc70 accumulation in protoplasts. 3) In protoplasts exposed to low doses of SA at normal temperatures, PCD/apoptosis is increased as reflected by increased DNA fragmentation and phosphatidylserine externalisation, but not by increased MMP or ROS. High doses of SA were associated with increased levels of necrosis. Exposure of protoplasts to low doses of SA in combination with HS showed suppression of PCD/apoptosis (reflected by decreased DNA fragmentation and phosphatidylserine externalisation), accompanied by decreased levels of ROS and increased MMP. Discussion: These results suggest that SA-mediated increases in Hsp70/Hsc70 accumulation at normal temperatures are associated with cellular damage and protect cells against necrosis. On the other hand, low doses of SA that potentiate heat-induced Hsp70/Hsc70 accumulation abrogated the induction of apoptosis that was induced by low doses of SA at normal temperatures. The anti-apoptotic effects of Hsp70 could therefore influence plant resistance by interfering with the execution of PCD. These results could contribute to our understanding of heat-induced disease susceptibility, and the manipulation of SA-modulated Hsp70/Hsc70 should be carefully considered in the light of its ability to affect cell death, which may be advantageous or deleterious to the plant cell. / Prof. L. Bornman

plant disease and pest resistance

plant-pathogen relationships

cell death

plant defenses

heat shock proteins

Phosphoprotein changes in Arabidopsis thaliana cells in response to elicitation by lipopolysaccharides.

Roux, Milena

16 May 2008

Plants respond to pathogen attack by inducing a coordinated resistance strategy, which results in the expression of defense gene products. When a plant-pathogen interaction results in disease establishment, parasite colonization is caused by a delayed plant defense response, not due the absence of any response. Thus, the speed and intensity of the plant response and intracellular signalling determines the outcome of a plant-pathogen interaction. The acceleration of plant responses by the application of resistance inducers could provide a commercially, biologically and environmentally feasible alternative to existing pathogen control methods. Lipopolysaccharides are amphipathic lipoglycans that are attached to the outer bacterial membrane by a lipidic entity inserted into the bacterial phospholipid monolayer, with the saccharidic part oriented towards the exterior. The general structure of this compound is comprised of an anchor named lipid A associated with a core polysaccharide, which bears an O-antigen domain. LPS has been described as one of the pathogen-associated molecular patterns (PAMPs) capable of eliciting the activation of the plant innate immune system. LPS present in the outer membranes of plant growth-promoting rhizobacteria (PBPR) are major determinants of induced systemic resistance (ISR). In addition, LPS may function as an activator of systemic acquired resistance (SAR), providing non-specific immunization against later infection. Evidence suggests that LPS may advance plant disease resistance using the mechanism of ISR or SAR through its application to plants as a sensitizing agent, priming them to respond more effectively to subsequent pathogen attack. Phosphorylation plays a major role during the plant defense response, exemplified by its phosphorylation of transcription factors, required for the expression of defense-related genes. One of the most extensively documented phosphorylation responses is that of MAP kinase activation by phosphorylation in response to elicitation by race-specific and non-racespecific elicitors in various plant species.Proteins that undergo differential phosphorylation as a result of elicitation could be components of signal transduction pathways which connect pathogen perception with defense responses. Thus the identification of protein kinases, protein phosphatases and their substrates is essential in the elucidation of plant defense responses. The hypothesis behind this dissertation is that LPS elicitation results in alterations in the phosphorylation profile of Arabidopsis thaliana proteins. In this study, LPS was extracted from the cell walls of Burkholderia cepacia, a bacterial endophyte, and characterized by SDS-PAGE. The exposure of Arabidopsis callus culture cells to LPS resulted in distinctive changes in the phosphoprotein profile of the cells. Radioactive phosphorous labelling of proteins provided evidence that phosphorylation occurs in Arabidopsis following LPS perception, as part of a defense response related to LPS elicitation. Further investigation of differential protein phosphorylation via immunoblotting with antiphosphotyrosine antibodies revealed that tyrosine phosphorylation of Arabidopsis proteins occurs in response to LPS. One of the tyrosine-phosphorylated proteins was found to be a 42 kDa kinase, activated in response to LPS elicitation. The identity of the kinase as a mitogen-activated protein (MAP) kinase was confirmed by immunoblotting with anti-active MAP kinase antibodies. In addition, an assay of MAP kinase activity demonstrated the ability of the LPS-responsive MAP kinase to phosphorylate the ERK-MAP kinase substrate Elk1. In terms of the global phosphoproteome of Arabidopsis in response to LPS, phosphopeptides were purified from a crude protein digest by immobilized metal affinity chromatography and analyzed by liquid chromatography-tandem mass spectrometry (LCMS/ MS). While LC indicated both quantitative and qualitative differences resulting from LPS elicitation, no peptides could be positively identified as phosphopeptides by MS analysis. This work can however be repeated with further precautions to prevent the loss of phosphate groups prior to analysis. The results obtained in this study indicate that LPS causes specific alterations in Arabidopsis protein phosphorylation as a post-translational modification in response to the perception of LPS during a plant-pathogen interaction, proving the original hypothesis. / Prof. I.A. Dubery

plantphosphorylation

endotoxins

plant defenses

plant disease and pest resistance

plant-pathogen relationships

phosphoproteins

Arabidopsis thaliana