Protein kinases in the plant defence response

Protein kinases play a central role in signalling during pathogen recognition and the subsequent activation of plant defence mechanisms. Members of different kinase subfamilies, such as calcium-dependent protein kinases and MAP kinases, are involved. Nevertheless, often, only a single component of a signalling cascade in an experimental plant system has been characterised. The future challenge is to understand how these kinases work, which cellular responses they mediate, and how they fit into the bigger picture of defence signalling. This challenge has become increasingly feasible with the recent introduction of new techniques: these techniques include reverse genetics, which will allow the allocation of biological function to kinase isoforms, (phospho) proteomics combined with mass spectrometry, and transient expression of kinases in a (constitutively) active form, mimicking the induction of defence responses in a biological system.     

Mechanisms for the generation of reactive oxygen species in plant defence response

Recent data indicate that plants, in a manner similar to the situation found in mammalian phagocytotic cells, produce reactive oxygen species (ROS) in response to pathogen infection. This reaction could be very quick when using pre-existing, usually exocellular, components and/or, when biochemical machinery of the cell is activated, relatively late and long-lasting. The oxidative burst is defined as a rapid, transient production of high levels of ROS in response to external stimuli. Two major models depicting the origin of ROS in the oxidative burst are described, namely: the NADPH oxidase system and the pH-dependent generation of hydrogen peroxide by exocellular peroxidases. Additionally, the participation of exocellular ROS-generating enzymes, like germin-like oxalate oxidases and amine oxidases, in plant defence response is demonstrated. The involvement of protoplasmic ROS-generating systems is also indicated.     

GSNOR-mediated de-nitrosylation in the plant defence response

A key feature of the plant defence response is the transient engagement of a nitrosative burst, resulting in the synthesis of reactive nitrogen intermediates (RNIs). Specific, highly reactive cysteine (Cys) residues of low pK_a are a major site of action for these intermediates. The addition of an NO moiety to a Cys thiol to form an S-nitrosothiol (SNO), is termed S-nitrosylation. This redox-based post-translational modification is emerging as a key regulator of protein function in plant immunity. Here we highlight recent advances in our understanding of de-nitrosylation, the mechanism that depletes protein SNOs, with a focus on S-nitrosoglutathione reductase (GSNOR). This enzyme controls total cellular S-nitrosylation indirectly during the defence response by turning over S-nitrosoglutathione (GSNO), a major cache of NO bioactivity.     

Regulation of the plant defence response in arbuscular mycorrhizal symbiosis

The response of plants to arbuscular mycorrhizal fungi involves a temporal and spatial activation of different defence mechanisms. The activation and regulation of these defences have been proposed to play a role in the maintenance of the mutualistic status of the association, however, how these defences affect the functioning and development of arbuscular mycorrhiza remains unclear. A number of regulatory mechanisms of plant defence response have been described during the establishment of the arbuscular mycorrhizal symbiosis, including elicitor degradation, modulation of second messenger concentration, nutritional and hormonal plant defence regulation, and activation of regulatory symbiotic gene expression. The functional characterization of these regulatory mechanisms on arbuscular mycorrhiza, including cross-talk between them, will be the aim and objective of future work on this topic.     

A simple procedure for the manual isolation and identification of plant heterokaryons

A simple procedure is described for the aseptic manual isolation of individual heterokaryons. Heterokaryons were identified with bright field illumination using an inverted microscope and isolated by means of a micro-manipulator and capillary pipette coupled to a specially constructed syringe. When cell suspension protoplasts were labelled with fluorescein isothiocyanate and fused with mesophyll protoplasts, the heterokaryons exhibited an apple green cytoplasmic fluorescence (from cell suspension protoplasts) and a red chloroplast fluorescence (from mesophyll protoplasts). By this double fluorescence procedure, these manually isolated heterokaryons, identified initially using brightfield could be confirmed as heterokaryons.     

Suppression of plant defence response by a mycorrhiza helper bacterium

The aim of the present study was to determine whether the mycorrhiza helper bacterium Streptomyces sp. AcH 505 could serve as a biocontrol agent against Heterobasidion root and butt rot. Bacterial influence on mycelial growth of Heterobasidion sp. isolates, on the colonization of wood discs and Norway spruce (Picea abies) roots was determined. The effect of AcH 505 on plant photosynthesis, peroxidase activity and gene expression, and needle infections were investigated. AcH 505 was antagonistic to 11 of 12 tested fungal Heterobasidion isolates. The antagonism resulted in a suppression of fungal colonization of Norway spruce roots and wood discs. Mycelial growth rate of the 12th strain, Heterobasidion abietinum 331 was not affected by AcH 505, and colonization of roots by this fungal strain was promoted by AcH 505. Bacterial inoculation led to decreased peroxidase activities and gene expression levels in roots. AcH 505 promotes plant root colonization by Heterobasidion strains that are tolerant to antifungal metabolites produced by the bacterium. This may result from unknown bacterial factors that suppress the plant defence response.     

An affinity-based scoring scheme for predicting DNA-binding activities of modularly assembled zinc-finger proteins

Zinc-finger proteins (ZFPs) have long been recognized for their potential to manipulate genetic information because they can be engineered to bind novel DNA targets. Individual zinc-finger domains (ZFDs) bind specific DNA triplet sequences; their apparent modularity has led some groups to propose methods that allow virtually any desired DNA motif to be targeted in vitro. In practice, however, ZFPs engineered using this ‘modular assembly’ approach do not always function well in vivo. Here we report a modular assembly scoring strategy that both identifies combinations of modules least likely to function efficiently in vivo and provides accurate estimates of their relative binding affinities in vitro. Predicted binding affinities for 53 ‘three-finger’ ZFPs, computed based on energy contributions of the constituent modules, were highly correlated (r = 0.80) with activity levels measured in bacterial two-hybrid assays. Moreover, K_d values for seven modularly assembled ZFPs and their intended targets, measured using fluorescence anisotropy, were also highly correlated with predictions (r = 0.91). We propose that success rates for ZFP modular assembly can be significantly improved by exploiting the score-based strategy described here.     

Antibiotic activities of peptides, hydrogen peroxide and peroxynitrite in plant defence.

Genes encoding plant antibiotic peptides show expression patterns that are consistent with a defence role. Transgenic over-expression of defence peptide genes is potentially useful to engineer resistance of plants to relevant pathogens. Pathogen mutants that are sensitive to plant peptides in vitro have been obtained and a decrease of their virulence in planta has been observed, which is consistent with their hypothetical defence role. A similar approach has been followed to elucidate the potential direct anti-microbial role of hydrogen peroxide. Additionally, a scavenger of peroxynitrite has been used to investigate its involvement in plant defence.     

An improved phage display procedure for identification of lipopolysaccharide-binding peptides

We successfully implemented several modifications to the regular phage display procedure and significantly improved the lipopolysaccharides-binding properties of the peptides selected. Specifically, the number of biopannings was increased and peptides with consensus sequences were obtained. A dual selection procedure (referred to as subtractive panning) was used to simultaneously select for the desired target and deselect for an undesired target, thereby increasing the binding specificity. In addition, binding and washing conditions in the subtractive panning were also modified to favor the selection of peptides with higher binding strength. As a result, two peptides, ASFPPAF and SSHTISF, were identified with much improved binding properties compared to those selected with regular panning. The binding specificities of these two peptides, as measured by the ratio of phages bound to the desired and undesired targets, were severalfold higher than previously reported. These modifications could easily be implemented with many other target molecules, indicating the general applicability of the procedure.     

An efficient procedure for isolation of nuclei from plant protoplasts

Summary The present communication describes an easy, efficient and rapid method for isolation of nuclei from plant protoplasts. Release of nuclei is accomplished by disruption of protoplasts in an appropriate buffer containing a very low concentration (0.01%) of the detergent Triton X-100. The pH of the nuclei isolation buffer (5.3) played a critical role in the recovery of stable nuclei in large numbers. Supplementation of buffer (10 mM MES) with spermine (0.1 mM), dithiothreitol (2.5 mM), ethylenediaminetetraacetic acid (2.5 mM) and Nad and KCl (10 mM each) improved nuclear yield and quality. With the method developed it is possible to routinely recover 95% nuclei from the protoplasts within 30 minutes. The nuclear preparations are of high purity with little detectable cytoplasmic contamination and no clumping of the nuclei. The structural integrity of the nuclei has been assessed and confirmed by Nomarski differential interference contrast optics and ultrastructural observations.     

Phosphate-solubilizing peanut associated bacteria: screening for plant growth-promoting activities

Carbon and nitrogen are supplied by a variety of sources in the desert food web; both vascular and non-vascular plants and cyanobacteria supply carbon, and cyanobacteria and plant-associated rhizosphere bacteria are sources of biological nitrogen fixation. The objective of this study was to compare the relative influence of vascular plants and biological soil crusts on desert soil nematode and protozoan abundance and community composition. In the first experiment, biological soil crusts were removed by physical trampling. Treatments with crust removed had fewer nematodes and a greater relative ratio of bacterivores to microphytophages than treatments with intact crust. However, protozoa composition was similar with or without the presence of crusts. In a second experiment, nematode community composition was characterized along a spatial gradient away from stems of grasses or shrubs. Although nematodes generally occurred in increasing abundance nearer to plant stems, some genera (such as the enrichment-type Panagrolaimus) increased disproportionately more than others (such as the stress-tolerant Acromoldavicus). We propose that the impact of biological soil crusts and desert plants on soil microfauna, as reflected in the community composition of microbivorous nematodes, is a combination of carbon input, microclimate amelioration, and altered soil hydrology.