Experimental Neurology By Prof Paul Glees Pp xii + 532 (Oxford: Clarendon Press; London: Oxford University Press, 1961) 75s net

The Nervous System

Plants produce a diverse array of secondary metabolites, many of which have antifungal activity. Some of these compounds are constitutive, existing in healthy plants in their biologically active forms. Others, such as cyanogenic glycosides and glucosinolates, occur as inactive precursors and are activated in response to tissue damage or pathogen attack. This activation often involves plant enzymes, which are released as a result of breakdown in cell integrity. Compounds belonging to the latter category are still regarded as constitutive because they are immediately derived from preexisting constituents (Mansfield, 1983). VanEtten et al. (i994) have proposed the term “phytoanticipin” to distinguish these preformed antimicrobial compounds from phytoalexins, which are synthesized from remote precursors in response to pathogen attack, probably as a result of de novo synthesis of enzymes. In recent years, studies of plant disease resistance mechanisms have tended to focus on phytoalexin biosynthesis and other active responses triggered after pathogen attack (Hammond-Kosack and Jones, 1996, in this issue). In contrast, preformed inhibitory compounds have received relatively little attention, despite the fact that these plant antibiotics are likely to represent one of the first chemical barriers to potential pathogens. The distribution of preformed inhibitors within plants is often tissue specific (e.g., Price et ai., 1987; Poulton, 1988; Davis, 1991; Fenwick et ai., 1992; Bennett and Wallsgrove, 1994), and r there is a tendency for these compounds to be concentrated in the outer cell layers of plant organs, suggesting that they may indeed act as deterrents to pathogens and pests. Some diffusible preformed inhibitors, such as catechol and protocatechuic acid (which are found in onion scales), may influence fungal growth at the plant surface. In general, however, preformed antifungal compounds are commonly sequestered in vacuoles or organelles in healthy plants. Therefore, the concentrations that are encountered by an invading fungus will depend on the extent to which that fungus causes tissue damage. Biotrophs may avoid the release of preformed inhibitors by minimizing damage to the host, whereas necrotrophs are likely to cause substantial release of these compounds. The nature and leve1 of preformed inhibitors to which a potential pathogen is exposed will also vary, depending on factors such as host genotype, age, and environmental conditions (Price et ai., 1987; Davis, 1991). There have been numerous attempts to associate natural variation in levels of preformed inhibitors in plants with resistance to particular pathogens, but often these attempts have failed to reveal any positive correlation. However, whereas preformed inhibitors may be effective against a broad spectrum of potential pathogens, successful pathogens are likely to be able to circumvent the effects of these antibiotics either by avoiding them altogether or by tolerating or detoxifying them (Schonbeck and Schlosser, 1976; Fry and Myers, 1981; Bennett and Wallsgrove, 1994; VanEtten et al., 1995; Osbourn, 1996). The isolation of plant mutants defective in the biosynthesis of preformed inhibitors would allow a direct genetic test of the importance of these compounds in plant defense. However, in most cases this approach is technically difficult because of the problems associated with screening for lossof the compounds. In the absence of plant mutants, a complementary approach involving the study of fungal mechanisms of resistance to preformed inhibitors, and of the contribution of this resistance to fungal pathogenicity to the relevant host plants, offers another route toward investigating the importance of these inhibitors in plant defense. A large number of constitutive plant compounds have been reported to have antifungal activity. Well-known examples include phenols and phenolic glycosides, unsaturated lactones, sulphur compounds, saponins, cyanogenic glycosides, and glucosinolates (reviewed in Ingham, 1973; Schonbeck and Schlosser, 1976; Fry and Myers, 1981; Mansfield, 1983; Ku6, 1992; Bennett and Wallsgrove, 1994; Grayer and Harborne, 1994; Osbourn, 1996). More recently, 5-alkylated resorcinols and dienes have been associated with disease resistance, in this case, resistance of subtropical fruits to infection by Collefotrichum gloeosporioides (Prusky and Keen, 1993). However, only a few classes of preformed inhibitor have been studied in detail to determine their possible roles in plant defense against fungal pathogens. This review focuses on three of these classes-saponins, cyanogenic glycosides, and glucosinolates-and summarizes our current knowledge of the role of these preformed inhibitors in determining the outcome of encounters between plants and phytopathogenic fungi.

Preformed Antimicrobial Compounds and Plant Defense against Fungal Attack.

http://faculty.ucr.edu/~jkzhu/articles/2002/ROS1%20Final.pdf

ROS1, a repressor of transcriptional gene silencing in Arabidopsis, encodes a DNA glycosylase/lyase

Many plants produce low-molecular-weight compounds which inhibit the growth of phytopathogenic fungi in vitro. These compounds may be preformed inhibitors that are present constitutively in healthy plants (also known as phytoanticipins), or they may be synthesized in response to pathogen attack (phytoalexins). Successful pathogens must be able to circumvent or overcome these antifungal defenses, and this review focuses on the significance of fungal resistance to plant antibiotics as a mechanism of pathogenesis. There is increasing evidence that resistance of fungal pathogens to plant antibiotics can be important for pathogenicity, at least for some fungus-plant interactions. This evidence has emerged largely from studies of fungal degradative enzymes and also from experiments in which plants with altered levels of antifungal secondary metabolites were generated. Whereas the emphasis to date has been on degradative mechanisms of resistance of phytopathogenic fungi to antifungal secondary metabolites, in the future we are likely to see a rapid expansion in our knowledge of alternative mechanisms of resistance. These may include membrane efflux systems of the kind associated with multidrug resistance and innate resistance due to insensitivity of the target site. The manipulation of plant biosynthetic pathways to give altered antibiotic profiles will also be valuable in telling us more about the significance of antifungal secondary metabolites for plant defense and clearly has great potential for enhancing disease resistance for commercial purposes.

Fungal Resistance to Plant Antibiotics as a Mechanism of Pathogenesis

Taxonomy: Kingdom Fungi; Phylum Ascomycota; Class Sordariomycetes; Order Hypocreales; Family Nectriaceae; genus Fusarium. Host range: Very broad at the species level. More than 120 different formae speciales have been identified based on specificity to host species belonging to a wide range of plant families. Disease symptoms: Initial symptoms of vascular wilt include vein clearing and leaf epinasty, followed by stunting, yellowing of the lower leaves, progressive wilting, defoliation and, finally, death of the plant. On fungal colonization, the vascular tissue turns brown, which is clearly visible in cross-sections of the stem. Some formae speciales are not primarily vascular pathogens, but cause foot and root rot or bulb rot. Economic importance: Can cause severe losses in many vegetables and flowers, field crops, such as cotton, and plantation crops, such as banana, date palm and oil palm. Control: Use of resistant varieties is the only practical measure for controlling the disease in the field. In glasshouses, soil sterilization can be performed. Useful websites: http://www.broad.mit.edu/annotation/genome/fusarium_group/MultiHome.html; http://www.fgsc.net/Fusarium/fushome.htm; http://www.phi-base.org/query.php

Pathogen profile update: Fusarium oxysporum

Fusarium as a model for studying virulence in soilborne plant pathogens

Plants produce a variety of secondary metabolites, many of which have antifungal activity. Saponins are plant glycosides that may provide a preformed chemical barrier against phytopathogenic fungi. Fusarium oxysporum f. sp. lycopersici and other tomato pathogens produce extracellular enzymes known as tomatinases, which deglycosylate alpha-tomatine to yield less toxic derivatives. We have cloned and characterized the cDNA and genomic DNA encoding tomatinase from the vascular pathogen of tomato F. oxysporum f. sp. lycopersici. This gene encodes a protein (FoTom1) with no amino acid sequence homology to any previously described saponinase, including tomatinase from Septoria lycopersici. Although FoTom1 is related to family 10 glycosyl hydrolases, which include mainly xylanases, it has no detectable xylanase activity. We have overexpressed and purified the protein with a bacterial heterologous system. The purified enzyme is active and cleaves alpha-tomatine into the less toxic compounds tomatidine and lycotetraose. Tomatinase from F. oxysporum f. sp. lycopersici is encoded by a single gene whose expression is induced by alpha-tomatine. This expression is fully repressed in the presence of glucose, which is consistent with the presence of two putative CREA binding sites in the promoter region of the tomatinase gene. The tomatinase gene is expressed in planta in both roots and stems throughout the entire disease cycle of F. oxysporum f. sp. lycopersici.

Tomatinase from Fusarium oxysporum f. sp. lycopersici defines a new class of saponinases.

The nematode Caenorhabditis elegans has a very well-defined and genetically tractable nervous system which offers an effective model to explore basic mechanistic pathways that might be underpin complex human neurological diseases. Here, the role C. elegans is playing in understanding two neurodegenerative conditions, Parkinson's and Alzheimer's disease (AD), and a complex neurological condition, autism, is used as an exemplar of the utility of this model system. C. elegans is an imperfect model of Parkinson's disease because it lacks orthologues of the human disease-related genes PARK1 and LRRK2 which are linked to the autosomal dominant form of this disease. Despite this fact, the nematode is a good model because it allows transgenic expression of these human genes and the study of the impact on dopaminergic neurons in several genetic backgrounds and environmental conditions. For AD, C. elegans has orthologues of the amyloid precursor protein and both human presenilins, PS1 and PS2. In addition, many of the neurotoxic properties linked with Aβ amyloid and tau peptides can be studied in the nematode. Autism spectrum disorder is a complex neurodevelopmental disorder characterised by impairments in human social interaction, difficulties in communication, and restrictive and repetitive behaviours. Establishing C. elegans as a model for this complex behavioural disorder is difficult; however, abnormalities in neuronal synaptic communication are implicated in the aetiology of the disorder. Numerous studies have associated autism with mutations in several genes involved in excitatory and inhibitory synapses in the mammalian brain, including neuroligin, neurexin and shank, for which there are C. elegans orthologues. Thus, several molecular pathways and behavioural phenotypes in C. elegans have been related to autism. In general, the nematode offers a series of advantages that combined with knowledge from other animal models and human research, provides a powerful complementary experimental approach for understanding the molecular mechanisms and underlying aetiology of complex neurological diseases.

Caenorhabditis elegans as an experimental tool for the study of complex neurological diseases: Parkinson's disease, Alzheimer's disease and autism spectrum disorder

The antifungal compound alpha-tomatine, present in tomato plants, has been reported to provide a preformed chemical barrier against phytopathogenic fungi. Fusarium oxysporum f. sp. lycopersici, a tomato pathogen, produces an extracellular enzyme inducible by alpha-tomatine. This enzyme, known as tomatinase, catalyzes the hydrolysis of alpha-tomatine into its nonfungitoxic forms, tomatidine and beta-lycotetraose. The maximal tomatinase activity in the fungal culture medium was observed after 48 h of incubation of germinated conidia at an alpha-tomatine concentration of 20 micrograms/ml. The enzymatic activity in the supernatant was concentrated against polyethylene glycol 35,000, and the enzyme was then purified to electrophoretic homogeneity by a procedure that includes preparative isoelectric focusing and preparative gel electrophoresis as main steps. The purification procedure had a yield of 18%, and the protein was purified about 40-fold. Tomatinase was found to be a monomer of 50 kDa by both native gel electrophoresis and sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The analytical isoelectric focusing of the native tomatinase showed at least five isoforms with pIs ranging from 4.8 to 5.8. Treatment with N-glycosidase F gave a single protein band of 45 kDa, indicating that the 50-kDa protein was N glycosylated. Tomatinase activity was optimum at 45 to 50 degrees C and at pH 5.5 to 7. The enzyme was stable at acidic pH and temperatures below 50 degrees C. The enzyme had no apparent requirement for cofactors, although Co2+ and Mn2+ produced a slight stimulating effect on tomatinase activity. Kinetic experiments at 30 degrees C gave a K(m) of 1.1 mM for alpha-tomatine and a Vmax of 118 mumol/min/mg. An activation energy of 88 kJ/mol was calculated.

https://aem.asm.org/content/aem/62/5/1604.full.pdf

Purification and characterization of tomatinase from Fusarium oxysporum f. sp. lycopersici

Strain TA102 of S. typhimurium is a new histidine-requiring mutant, particularly suited to the detection of oxidative mutagens acting at A·T base pairs. 10 oxidizing chemicals, previously tested in strain TA102, were used to evaluate the mutagenic sensitivity of the L -arabinose forward mutation assay of S. typhimurium with respect to those types of mutagens. The mutagenicity of each compound was determined by liquid test, measuring both the frequency of mutants among the survivors and the absolute number of mutants growing in selective plates with traces of D -glucose. Strain BA13 with a wild-type lipopolysaccharide barrier was used as compared to the deep rough derivative strain BA9. The chemicals studied were: bleomycin, t-butyl hydroperoxide, chromium trioxide, cumeme hydroperoxide, formaldehyde, glyoxal, glutaraldehyde, hydrogen peroxide, paraquat, and phenylhydrazine. Additionally, ultrasonic oscillation was used as a presumable non-mutagenic lethal control treatment. The L -arabinose forward mutation assay detected the mutagenic activity of all the chemicals under study with a high degree of sensitivity, including paraquat which is unable to revert strain TA102. Positive responses were obtained at doses equivalent to or 10 times lower than the doses detected by strain TA102. The results support the idea that the L -arabinose forward mutation assay could replace the set of specific tester strains used by the histidine reverse mutation assay in general screening for genetic toxins.

Manuel Ruiz-Rubio

Papers

Fusarium as a model for studying virulence in soilborne plant pathogens

Tomatinase from Fusarium oxysporum f. sp. lycopersici defines a new class of saponinases.

Caenorhabditis elegans as an experimental tool for the study of complex neurological diseases: Parkinson's disease, Alzheimer's disease and autism spectrum disorder

Purification and characterization of tomatinase from Fusarium oxysporum f. sp. lycopersici

Oxidative mutagens specific for A-T base pairs induce forward mutations to L-arabinose resistance in Salmonella typhimurium.