A. Schouten

The C-terminal KDEL sequence increases the expression level of a single-chain antibody designed to be targeted to both the cytosol and the secretory pathway in transgenic tobacco

The effects of subcellular localization on single-chain antibody (scFv) expression levels in transgenic tobacco was evaluated using an scFv construct of a model antibody possessing different targeting signals. For translocation into the secretory pathway a secretory signal sequence preceded the scFv gene (scFv-S). For cytosolic expression the scFv antibody gene lacked such a signal sequence (scFv-C). Also, both constructs were provided with the endoplasmic reticulum (ER) retention signal KDEL (scFv-SK and scFv-CK, respectively). The expression of the different scFv constructs in transgenic tobacco plants was controlled by a CaMV 35S promoter with double enhancer. The scFv-S and scFv-SK antibody genes reached expression levels of 0.01% and 1% of the total soluble protein, respectively. Surprisingly, scFv-CK transformants showed considerable expression of up to 0.2% whereas scFv-C transformants did not show any accumulation of the scFv antibody. The differences in protein expression levels could not be explained by the steady-state levels of the mRNAs. Transient expression assays with leaf protoplasts confirmed these expression levels observed in transgenic plants, although the expression level of the scFv-S construct was higher. Furthermore, these assays showed that both the secretory signal and the ER retention signal were recognized in the plant cells. The scFv-CK protein was located intracellularly, presumably in the cytosol. The increase in scFv protein stability in the presence of the KDEL retention signal is discussed.

Functional analysis of H2O2-generating systems in Botrytis cinerea: the major Cu-Zn-superoxide dismutase (BCSOD1) contributes to virulence on French bean, whereas a glucose oxidase (BCGOD1) is dispensable

SUMMARY The oxidative burst, a transient and rapid accumulation of reactive oxygen species (ROS), is a widespread defence mechanism of higher plants against pathogen attack. There is increasing evidence that the necrotrophic fungal pathogen Botrytis cinerea itself generates ROS, and that this capability could contribute to the virulence of the fungus. Two potential H(2)O(2)-generating systems were studied with respect to their impact on the interaction of B. cinerea and its host plant Phaseolus vulgaris. A Cu-Zn-superoxide dismutase gene (bcsod1) and a putative glucose oxidase gene (bcgod1) were cloned and characterized, and deletion mutants were created using a gene-replacement methodology. Whereas the Deltabcgod1-mutants displayed normal virulence on bean leaves, the Deltabcsod1 mutants showed a significantly retarded development of lesions, indicating that the Cu-Zn SOD-activity is an important single virulence factor in this interaction system. Whether dismutation of (fungal or host) superoxide, or generation of H(2)O(2) (or both), are important for pathogenesis in this system remains to be elucidated.

Resveratrol acts as a natural profungicide and induces self-intoxication by a specific laccase.

The grapevine (Vitis) secondary metabolite resveratrol is considered a phytoalexin, which protects the plant from Botrytis cinerea infection. Laccase activity displayed by the fungus is assumed to detoxify resveratrol and to facilitate colonization of grape. We initiated a functional molecular genetic analysis of B. cinerea laccases by characterizing laccase genes and evaluating the phenotype of targeted gene replacement mutants. Two different laccase genes from B. cinerea were characterized, Bclcc1 and Bclcc2. Only Bclcc2 was strongly expressed in liquid cultures in the presence of either resveratrol or tannins. This suggested that Bclcc2, but not Bclcc1, plays an active role in the oxidation of both resveratrol and tannins. Gene replacement mutants in the Bclcc1 and Bclcc2 gene were made to perform a functional analysis. Only Bclcc2 replacement mutants were incapable of converting both resveratrol and tannins. When grown on resveratrol, both the wild type and the Bclcc1 replacement mutant showed inhibited growth, whereas Bclcc2 replacement mutants were unaffected. Thus, contrary to the current theory, BcLCC2 does not detoxify resveratrol but, rather, converts it into compounds that are more toxic for the fungus itself. The Bclcc2 gene was expressed during infection of B. cinerea on a resveratrol‐producing host plant, but Bclcc2 replacement mutants were as virulent as the wild‐type strain on various hosts. The activation of a plant secondary metabolite by a pathogen introduces a new dimension to plant–pathogen interactions and the phytoalexin concept.

Improving scFv antibody expression levels in the plant cytosol

Expression of single‐chain antibody fragments (scFvs) in the plant cytosol is often cumbersome. It was unexpectedly shown that addition at the C‐terminus of the ER retention signal KDEL resulted in significantly improved expression levels. In this report the cytosolic location of the scFv‐CK was confirmed, excluding possible mistranslocation to other subcellular compartments. It was shown that expression of several other scFvs was also improved in tobacco protoplasts. In addition expression was improved in transgenic potato. Changing from KDEL to KDEI did not affect the enhanced protein expression level. Addition of the KDEL motif is a simple and straightforward tool to stabilize in planta cytosolic expression of many scFvs.

Defense Responses of Fusarium oxysporum to 2,4-Diacetylphloroglucinol, a Broad-Spectrum Antibiotic Produced by Pseudomonas fluorescens

A collection of 76 plant-pathogenic and 41 saprophytic Fusarium oxysporum strains was screened for sensitivity to 2,4-diacetylphloroglucinol (2,4-DAPG), a broad-spectrum antibiotic produced by multiple strains of antagonistic Pseudomonas fluorescens. Approximately 17% of the F. oxysporum strains were relatively tolerant to high 2,4-DAPG concentrations. Tolerance to 2,4-DAPG did not correlate with the geographic origin of the strains, formae speciales, intergenic spacer (IGS) group, or fusaric acid production levels. Biochemical analysis showed that 18 of 20 tolerant F. oxysporum strains were capable of metabolizing 2,4-DAPG. For two tolerant strains, analysis by mass spectrometry indicated that deacetylation of 2,4-DAPG to the less fungitoxic derivatives monoacetylphloroglucinol and phloroglucinol is among the initial mechanisms of 2,4-DAPG degradation. Production of fusaric acid, a known inhibitor of 2,4-DAPG biosynthesis in P. fluorescens, differed considerably among both 2,4-DAPG-sensitive and -tolerant F. oxysporum strains, indicating that fusaric acid production may be as important for 2,4-DAPG-sensitive as for -tolerant F. oxysporum strains. Whether 2,4-DAPG triggers fusaric acid production was studied for six F. oxysporum strains; 2,4-DAPG had no significant effect on fusaric acid production in four strains. In two strains, however, sublethal concentrations of 2,4-DAPG either enhanced or significantly decreased fusaric acid production. The implications of 2,4-DAPG degradation, the distribution of this trait within F. oxysporum and other plant-pathogenic fungi, and the consequences for the efficacy of biological control are discussed.

Cloning and characterization of a glutathione S-transferase homologue from the plant pathogenic fungus Botrytis cinerea

Abstract A gene was cloned from Botrytis cinerea that encodes a protein homologous to glutathione S-transferase (GST). The gene, denominated Bcgst1, is present in a single copy and represents the first example of such a gene from a filamentous fungus. The biochemical function of GSTs is to conjugate toxic compounds to glutathione, thereby detoxifying the compound. In many other organisms, GST plays a role in chemical stress tolerance. We anticipated that GST functions for B. cinerea as a potential virulence factor, enabling the fungus to tolerate fungitoxic plant defence compounds. The expression of Bcgst1 mRNA under various presumably stressful conditions was investigated. Bcgst1 mRNA is expressed at a basal level in liquid cultures and is induced upon addition of hydrogen peroxide to the medium. The level of Bcgst1 mRNA expression during infection of tomato leaves parallels the level of actin mRNA. The role of the Bcgst1 gene in the virulence of Botrytis cinerea was evaluated by constructing gene disruption mutants. Three independent disruption mutants were obtained. The virulence of two mutants on tomato leaves was evaluated. Neither of the mutants showed a decrease in virulence, indicating that the Bcgst1 gene is not essential for virulence on tomato leaves under the conditions tested.

Involvement of the ABC transporter BcAtrB and the laccase BcLCC2 in defence of Botrytis cinerea against the broad‐spectrum antibiotic 2,4‐diacetylphloroglucinol

The genetic and biochemical basis of defence mechanisms in plant pathogenic fungi against antifungal compounds produced by antagonistic microorganisms is largely unknown. The results of this study show that both degradative and non-degradative defence mechanisms enable the plant pathogenic fungus Botrytis cinerea to resist the broad-spectrum, phenolic antibiotic 2,4-diacetylphloroglucinol (2,4-DAPG). The efflux pump BcAtrB provides the first line of defence for B. cinerea, preventing accumulation of 2,4-DAPG in the cell to toxic concentrations, whereas the extracellular laccase BcLCC2 mediates, via conversion of tannic acid, subsequent degradation of 2,4-DAPG. Expression of BcatrB is induced by 2,4-DAPG and efflux gives B. cinerea sufficient time to more effectively initiate the process of BcLCC2-mediated antibiotic degradation. This is supported by the observations that the BcatrB mutant is significantly more sensitive to 2,4-DAPG than its parental strain, and is substantially less effective in 2,4-DAPG degradation. The results of this study further showed that BcLCC2 itself is not able to degrade 2,4-DAPG, but requires tannic acid as a mediator for 2,4-DAPG degradation. To our knowledge, this is the first time that the laccase-mediator system is shown to play a role in the detoxification of a broad-spectrum antibiotic compound from bacterial origin. We postulate that yet unknown constituents present in tannic acid act as substrate(s) of BcLCC2, thereby generating radicals that mediate 2,4-DAPG degradation.

‘Plantibodies’: a flexible approach to design resistance against pathogens

Engineering resistance against various diseases and pests is hampered by the lack of suitable genes. To overcome this problem we started a research program aimed at obtaining resistance by transfecting plants with genes encoding monoclonal antibodies against pathogen specific proteins. The idea is that monoclonal antibodies will inhibit the biological activity of molecules that are essential for the pathogenesis. Potato cyst nematodes are chosen as a model and it is thought that monoclonal antibodies are able to block the function of the saliva proteins of this parasite. These proteins are, among others, responsible for the induction of multinucleate transfer cells upon which the nematode feeds. It is well documented that the ability of antibodies to bind molecules is sufficient to inactivate the function of an antigen and in view of the potential of animals to synthesize antibodies to almost any molecular structure, this strategy should be feasible for a wide range of diseases and pests.Antibodies have several desirable features with regard to protein engineering. The antibody (IgG) is a Y-shaped molecule, in which the domains forming the tips of the arms bind to antigen and those forming the stem are responsible for triggering effector functions (Fc fragments) that eliminate the antigen from the animal. Domains carrying the antigen-binding loops (Fv and Fab fragments) can be used separately from the Fc fragments without loss of affinity. The antigen-binding domains can also be endowed with new properties by fusing them to toxins or enzymes. Antibody engineering is also facilitated by the Polymerase Chain Reaction (PCR). A systematic comparison of the nucleotide sequence of more than 100 antibodies revealed that not only the 3′-ends, but also the 5′-ends of the antibody genes are relatively conserved. We were able to design a small set of primers with restriction sites for forced cloning, which allowed the amplification of genes encoding antibodies specific for the saliva proteins ofGlobodera rostochiensis. Complete heavy and light chain genes as well as single chain Fv fragments (scFv), in which the variable parts of the light (VL) and heavy chain (VH) are linked by a peptide, will be transferred to potato plants. A major challenge will be to establish a correct expression of the antibody genes with regard to three dimensional folding, assembly and intracellular location.

Functional analysis of NLP genes from Botrytis elliptica

SUMMARY We functionally analysed two Nep1-like protein (NLP) genes from Botrytis elliptica (a specialized pathogen of lily), encoding proteins homologous to the necrosis and ethylene-inducing protein (NEP1) from Fusarium oxysporum. Single gene replacement mutants were made for BeNEP1 and BeNEP2, providing the first example of transformation and successful targeted mutagenesis in this fungus. The virulence of both mutants on lily leaves was not affected. BeNEP1 and BeNEP2 were individually expressed in the yeast Pichia pastoris, and the necrosis-inducing activity was tested by infiltration of both proteins into leaves of several monocots and eudicots. Necrotic symptoms developed on the eudicots tobacco, Nicotiana benthamiana and Arabidopsis thaliana, and cell death was induced in tomato cell suspensions. No necrotic symptoms developed on leaves of the monocots rice, maize and lily. These results support the hypothesis that the necrosis-inducing activity of NLPs is limited to eudicots. We conclude that NLPs are not essential virulence factors and they do not function as host-selective toxins for B. elliptica.

Mechanisms Involved in Nematode Control by Endophytic Fungi

Colonization of plants by particular endophytic fungi can provide plants with improved defenses toward nematodes. Evidently, such endophytes can be important in developing more sustainable agricultural practices. The mechanisms playing a role in this quantitative antagonism are poorly understood but most likely multifactorial. This knowledge gap obstructs the progress regarding the development of endophytes or endophyte-derived constituents into biocontrol agents. In part, this may be caused by the fact that endophytic fungi form a rather heterogeneous group. By combining the knowledge of the currently characterized antagonistic endophytic fungi and their effects on nematode behavior and biology with the knowledge of microbial competition and induced plant defenses, the various mechanisms by which this nematode antagonism operates or may operate are discussed. Now that new technologies are becoming available and more accessible, the currently unresolved mechanisms can be studied in greater detail than ever before.