580 Pflanzen (Botanik)
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Plants exposed to herbivory may defend themselves by attracting the “enemies of their enemies”, a phenomenon called induced indirect defense (IID). In this process, the de novo production and emission of volatile organic compounds (VOC) by the affected plant is activated via a jasmonic acid (JA) dependent signaling cascade. VOC can be very specific for the inducing herbivore as well as for the emitting plant. Carnivores as predatory mites and parasitoid wasps use these substances as prey- or host-finding cues. If the herbivore is parasitized successfully, its development is slowed and thus the damage of the plant is decreased. Additional abiotic stress may modulate the plant’s ability to produce and/or emit herbivore induced VOC. Ultraviolet (UV) radiation can have multiple physiological effects on plants, amongst others the activation of the expression of genes that are also activated during anti-herbivore defense. To investigate UV effects, foils with different UV transmittance were used to manipulate ambient solar radiation. One foil was permeable for the whole solar spectrum including UV radiation whereas the other excluded radiation below a wavelength of 400 nm. Soybean exposed to UV increased concentrations of isorhamnetin- and quercetin-based flavonoids as effective photo-protective compounds in the leaves and showed a reduced growth compared to plants exposed to ambient radiation lacking UV. The altered chemical composition of the leaves had no effect on food choice and performance of herbivorous Spodoptera frugiperda larvae. Photo-protection by flavonoids seems to be efficient to prevent further UV effects on IID as plants of both treatments emitted the same blend of induced VOC and hence females of the parasitoid Cotesia marginiventris did not prefer plants from on of the treatments in the olfactometer. Nitrogen is one important macronutrient for all trophic levels and thus deficiency of this nutrient was expected to affect IID of soybean profoundly. To manipulate N availability for soybean plants hydroponic culture was used. One treatment was cultured in a standard hydroponic solution whereas in the N deficiency treatment in the solution all salts containing N were replaced with N-free salts. In N deficient plants root biomass was increased to allow the plant to forage more efficiently for the nutrient. Despite this morphological adaptation, photosynthetic efficiency as well as leaf N and soluble protein content were reduced significantly in N deficient soybean. The N deficiency was passed on to the third trophic level as herbivores fed with the affected leaves had a reduced body N content on her part and showed a decreased growth but no feeding preference for the superior food. Parasitoids reared in such N deficient herbivores had significant lower pupal weight compared to parasitoids reared in hosts fed with fully fertilized soybean. N deficient plants emitted a quantitatively altered herbivore induced blend. The two terpenes β-Bergamotene and (E,E)-α-Farnesene were emitted in higher amounts whereas (Z)-3-Hexenyl-α-methylbutyrate was emitted in significantly lower amount. Despite this quantitatively modified VOC blend the parasitoids host-searching behavior was not affected. Heavy metals (HM) are proposed to affect various biochemical pathways in plants including defense pathways by production of reactive oxygen species (ROS) in the tissue. The ROS on its part may affect production and release of endogenous JA, an important messenger in defense signaling. In this study maize plants were grown hydroponically and exposed to different increased concentrations of copper and cadmium. Maize seems to be able to exclude the excess HM from the leaves because the HM were found mainly in the roots and only to a minor degree in the shoots of the plants. Despite this exclusion the HM significantly affected uptake of other metal ions into the plant. The excess of the HM in combination with the attenuated uptake of other ions led to a reduced growth of roots and shoots as well as to reduced photosynthetic efficiency. Thus the nutritional value of the plants for the herbivore was lowered either by direct toxic effects of the HM or indirectly by altering plant chemical composition. S. frugiperda larvae fed with leaves exposed to high HM concentrations showed a significantly reduced growth but they did prefer neither control nor HM treated plants in a food-choice assay. Cu had a transient priming effect on JA as pre-exposure to a high excess of Cu led to higher amounts of herbivore induced JA compared to control plants exposed only to standard concentration of Cu. As anticipated the increased JA was followed by an increase in herbivore induced VOC in high-Cu treated plants caused by a increase of the green leaf volatiles (E)-3-Hexenal, (Z)-3-Hexenol and (Z)-3-Hexenylacetat and the terpenes Linalool, (E)-α-Bergamotene, (E)-β-Farnesene, and β-Sesquiphellandrene. Despite these profound changes in herbivore induced VOC the parasitoids host searching behavior was not affected. As described, the abiotic stresses UV, N deficiency and excess HM affected the morphology and physiology of soybean and maize, the performance of the herbivore S. frugiperda and even the performance of the parasitoid C. marginiventris. However the host searching behavior of the parasitoid was not affected even if the herbivore induced VOC blend was altered. Thus parasitoids seem to be a very reliable defender for plants and IID a very robust way of herbivore defense.
Regulation of pathogen-inducible volatile compounds in Arabidopsis and their role in plant defense
(2010)
Plants are constantly attacked by pathogenic microbes. As a result, they have evolved a plethora of constitutive and inducible defense responses to defend against attempted pathogen infection. Although volatile organic compounds have been implicated in plant defense, direct evidence of their function in plant resistance is still lacking. I have examined the role of VOCs in Arabidopsis defense against the hemibiotrophic bacterial pathogen Pseudomonas syringae pv. maculicola. The obtained results show that the vegetative parts of Arabidopsis produces and emits the volatile phenylpropanoid MeSA and three kinds of terpenoids, (E,E)-4,8,12-trimethyltrideca-1,3,7,11-tetraene (TMTT), alpha-ionon and beta-farnesen, upon avirulent and virulent P. syringae inoculation. Whereas the most abundant volatiles, MeSA and TMTT, are already produced at early stages of infection in the compatible and incompatible interaction, enhanced emission of alpha-ionon and beta-farnesen can only be detected in later stages of the compatible interaction. It was revealed that pathogen-induced synthesis of TMTT in Arabidopsis requires the JA signaling pathway but occurs independently of SA defense signaling. Similarly, the production of MeSA is dependent on JA signaling but not on the SA defense signaling pathway. Furthermore, production of MeSA is dependent on the function of ISOCHORISMATE SYNTHASE1, which produces its precursor SA. Upon inoculation with avirulent P. syringae, endogenously produced JA activates the JA signalling pathway to mediate MeSA and TMTT synthesis. By contrast, in the compatible Arabidopsis-Psm interaction, production of MeSA predominantly depends on the P. syringea the virulence factor coronatine, which activates JA downstream signaling. To learn more about the role of inducible VOCs in plant defense responses, I have identified an Arabidopsis T-DNA insertions line with a defect in the TERPENE SYNTHASE4 (TPS4) gene. Emission profiles from this mutant revealed that the induced production of TMTT but not of alpha-ionone, beta-farnesene or MeSA are abolished, demonstrating that TPS4 specifically regulates the P. syringae-induced synthesis of TMTT in Arabidopsis. The lack of TMTT in tps4 mutants, however, does not affect plant defense responses and resistance induction against P. syringae. This excludes a role of the terpenoid as an effective phytoalexin in Arabidopsis leaves against the bacterial pathogen. Moreover, tps4 mutant plants are still able to mount a SAR response, excluding a signaling function of TMTT during SAR. An important aim of our studies was to address the defensive role of MeSA, the major VOC emitted from P. syringae-inoculated Arabidopsis leaves. MeSA has been recently proposed as a critical long distance signal in the development of SAR. I found that two independent T-DNA insertions lines with defects in expression of the pathogen-inducible SA methyl transferase gene BSMT1 are completely devoid of pathogen-induced production of MeSA. However, bsmt1 mutant plants are capable to increase the level of SA in systemic, non-infected leaves of Arabodopsis and develop SAR like wild-type plants upon local P. syringae-inoculation. Thus, MeSA does not function as a critical SAR signal in Arabidopsis. Further experiments showed that SA accumulation in distant leaves occurs due to de novo synthesis through isochorismate synthase. In addition, we also ruled out a critical defensive role of MeSA at inoculation sites, because bsmt1 mutants are able to build up SA-dependent defense responses and local resistance in a wild-type-like manner. The conversion of SA to MeSA and subsequently emission of MeSA from the plant might help the plant to detoxify an excess of SA. This process is regulated by the JA pathway and might be one means to mediate negative crosstalk between JA and SA signaling. Moreover, the COR-triggered conversion of SA to MeSA and emission of the volatile methyl ester could be a way by which virulent P. syringae is able to attenuate the SA-defense pathway.