Your search keyword '"Gundel, Pedro E"' showing total 9 results

1. Seed-borne fungal endophytes constrain reproductive success of host plants under ozone pollution.

Author

Ueno AC, Gundel PE, Ghersa CM, Agathokleous E, and Martínez-Ghersa MA

Subjects

Endophytes, Seeds, Epichloe, Lolium, Ozone toxicity

Abstract

Tropospheric ozone is among the global change factors that pose a threat to plants and microorganisms. Symbiotic microorganisms can assist plants to cope with stress, but their role in the tolerance of plants to ozone is poorly understood. Here, we subjected endophyte-symbiotic and non-symbiotic plants of Lolium multiflorum, an annual species widely distributed in temperate grasslands, to high and low (i.e., charcoal-filtered air) ozone levels at vegetative and reproductive phases. Exposure to high ozone reduced leaf photochemical efficiency and greenness in both symbiotic and non-symbiotic plants. However, ozone-induced oxidative damage at biochemical level (i.e., lipid peroxidation) was mostly detected in symbiotic plants. Ozone exposure at the vegetative phase did not affect the reproductive investment in seeds, indicating full recovery from stress. Ozone exposure at the reproductive phase reduced biomass and seed production only in symbiotic plants indicating a symbiont-associated cost. At low ozone, endophyte-symbiotic plants showed a steeper slope in the relationship between seed number and seed weight (i.e., a number-weight trade-off) compared to non-symbiotic plants. However, when plants were treated at the reproductive phase, ozone increased the imbalance between seed number and seed weight in both endophyte-symbiotic and non-symbiotic plants. Plants with endophytes at the reproductive stage produced fewer seeds, which were not compensated by increased seed weight. Thus, fungal mycelium growing within ovaries or ozone-induced antioxidant systems may result in costs that finally depress the fitness of plants. Despite ozone pollution could destabilize plant-endophyte mutualisms and render them dysfunctional, other endophyte-mediated benefits (e.g., resistance to herbivory, tolerance to drought) could over-compensate these losses and explain the high incidence of the symbiosis in nature., (Copyright © 2021 Elsevier Inc. All rights reserved.)

Published

2021

2. Getting ready for the ozone battle: Vertically transmitted fungal endophytes have transgenerational positive effects in plants.

Author

Ueno AC, Gundel PE, Molina-Montenegro MA, Ramos P, Ghersa CM, and Martínez-Ghersa MA

Subjects

Biomass, Lolium drug effects, Lolium microbiology, Seedlings physiology, Symbiosis, Endophytes physiology, Epichloe physiology, Lolium physiology, Ozone pharmacology

Abstract

Ground-level ozone is a global air pollutant with high toxicity and represents a threat to plants and microorganisms. Although beneficial microorganisms can improve host performance, their role in connecting environmentally induced maternal plant phenotypes to progeny (transgenerational effects [TGE]) is unknown. We evaluated fungal endophyte-mediated consequences of maternal plant exposure to ozone on performance of the progeny under contrasting scenarios of the same factor (high and low) at two stages: seedling and young plant. With no variation in biomass, maternal ozone-induced oxidative damage in the progeny that was lower in endophyte-symbiotic plants. This correlated with an endophyte-mediated higher concentration of proline, a defence compound associated with stress control. Interestingly, ozone-induced TGE was not associated with reductions in plant survival. On the contrary, there was an overall positive effect on seedling survival in the presence of endophytes. The positive effect of maternal ozone increasing young plant survival was irrespective of symbiosis and only expressed under high ozone condition. Our study shows that hereditary microorganisms can modulate the capacity of plants to transgenerationally adjust progeny phenotype to atmospheric change., (© 2021 John Wiley & Sons Ltd.)

Published

2021

3. Episodes of high tropospheric ozone reduce nodulation, seed production and quality in soybean (Glycine max (L.) merr.) on low fertility soils.

Author

Biancari L, Cerrotta C, Menéndez AI, Gundel PE, and Martínez-Ghersa MA

Subjects

Humans, Nitrogen Fixation, Seeds, Soil, Ozone toxicity, Glycine max

Abstract

Driven by human activities, air pollution and soil degradation are threatening food production systems. Rising ozone in the troposphere can affect several physiological processes in plants and their interaction with symbiotic microorganisms. Plant responses to ozone may depend on both soil fertility and the ontogenetic stage in which they are exposed. In this work, we studied the effects of ozone episodes and soil fertility on soybean plants. We analysed soybean plant responses in the production of aboveground and belowground biomass, structural and functional attributes of rhizobia, and seed production and quality. The experiment was performed with plants grown in two substrates with different fertility (commercial soil, and soil diluted (50%, v/v) with sand). Plants were exposed to acute episodes of ozone during vegetative and reproductive stages. We observed that ozone significantly reduced belowground biomass (≈25%), nodule biomass (≈30%), and biological nitrogen fixation (≈21%). Plants exposed to ozone during reproductive stage growing in soil with reduced fertility had lower seed production (≈10% lower) and seed protein (≈12% lower). These responses on yield and quality can be explained by the observed changes in belowground biomass and nitrogen fixation. The negative impact of ozone on the symbiotic interaction with rhizobia, seed production and quality in soybean plants were greater in soils with reduced fertility. Our results indicate that food security could be at risk in the future if trends in ozone concentration and soil degradation processes continue to increase., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2020 Elsevier Ltd. All rights reserved.)

Published

2021

4. Ontogenetic and trans-generational dynamics of a vertically transmitted fungal symbiont in an annual host plant in ozone-polluted settings.

Author

Ueno AC, Gundel PE, Ghersa CM, Demkura PV, Card SD, Mace WJ, and Martínez-Ghersa MA

Subjects

Endophytes drug effects, Endophytes physiology, Lolium drug effects, Lolium physiology, Seeds microbiology, Stress, Physiological, Air Pollutants adverse effects, Epichloe drug effects, Epichloe physiology, Lolium microbiology, Ozone adverse effects, Symbiosis drug effects

Abstract

Tropospheric ozone is an abiotic stress of increasing importance in the context of global climate change. This greenhouse gas is a potent phytotoxic molecule with demonstrated negative effects on crop yield and natural ecosystems. Recently, oxidative stress has been proposed as a mechanism that could regulate the interaction between cool-season grasses and Epichloë endophytes. We hypothesized that exposure of Lolium multiflorum plants, hosting endophytes to an ozone-polluted environment at different ontogenetic phases, would impact the trans-generational dynamics of the vertically transmitted fungal symbiont. Here, we found that the ozone-induced stress on the mother plants did not affect the endophyte vertical transmission but it impaired the persistence of the fungus in the seed exposed to artificial ageing. Endophyte longevity in seed was reduced by exposure of the mother plant to ozone. Although ozone exposure did not influence either the endophyte mycelial concentration or their compound defences (loline alkaloids), a positive correlation was observed between host fitness and the concentration of endophyte-derived defence compounds. This suggests that fungal defences in grass seeds were not all produced in situ but remobilized from the vegetative tissues. Our study reveals ozone trans-generational effects on the persistence of a beneficial symbiont in a host grass., (© 2020 John Wiley & Sons Ltd.)

Published

2020

5. Legacy of historic ozone exposure on plant community and food web structure.

Author

Martínez-Ghersa MA, Menéndez AI, Gundel PE, Folcia AM, Romero AM, Landesmann JB, Ventura L, and Ghersa CM

Subjects

Animals, Argentina, Arthropods physiology, Atmosphere, Biodiversity, Food Chain, Plant Dispersal, Plant Weeds growth & development, Plant Weeds parasitology, Population Dynamics, Air Pollutants toxicity, Ozone toxicity, Plant Weeds drug effects

Abstract

Information on whole community responses is needed to predict direction and magnitude of changes in plant and animal abundance under global changes. This study quantifies the effect of past ozone exposure on a weed community structure and arthropod colonization. We used the soil seed bank resulting from a long-term ozone exposure to reestablish the plant community under a new low-pollution environment. Two separate experiments using the same original soil seed bank were conducted. Plant and arthropod richness and species abundance was assessed during two years. We predicted that exposure to episodic high concentrations of ozone during a series of growing cycles would result in plant assemblies with lower diversity (lower species richness and higher dominance), due to an increase in dominance of the stress tolerant species and the elimination of the ozone-sensitive species. As a consequence, arthropod-plant interactions would also be changed. Species richness of the recruited plant communities from different exposure histories was similar (≈ 15). However, the relative abundance of the dominant species varied according to history of exposure, with two annual species dominating ozone enriched plots (90 ppb: Spergula arvensis, and 120 ppb: Calandrinia ciliata). Being consistent both years, the proportion of carnivore species was significantly higher in plots with history of higher ozone concentration (≈3.4 and ≈7.7 fold higher in 90 ppb and 120 ppb plots, respectively). Our study provides evidence that, past history of pollution might be as relevant as management practices in structuring agroecosystems, since we show that an increase in tropospheric ozone may influence biotic communities even years after the exposure.

Published

2017

6. Ozone exposure of a weed community produces adaptive changes in seed populations of Spergula arvensis.

Author

Landesmann JB, Gundel PE, Martínez-Ghersa MA, and Ghersa CM

Subjects

Germination physiology, Plant Development physiology, Plant Dormancy physiology, Plant Weeds physiology, Seeds physiology, Soil, Caryophyllaceae growth & development, Caryophyllaceae physiology, Ozone adverse effects, Plant Weeds growth & development, Seeds growth & development

Abstract

Tropospheric ozone is one of the major drivers of global change. This stress factor alters plant growth and development. Ozone could act as a selection pressure on species communities composition, but also on population genetic background, thus affecting life history traits. Our objective was to evaluate the consequences of prolonged ozone exposure of a weed community on phenotypic traits of Spergulaarvensis linked to persistence. Specifically, we predicted that the selection pressure exerted by high ozone concentrations as well as the concomitant changes in the weed community would drive population adaptive changes which will be reflected on seed germination, dormancy and longevity. In order to test seed viability and dormancy level, we conducted germination experiments for which we used seeds produced by S. arvensis plants grown within a weed community exposed to three ozone treatments during four years (0, 90 and 120 ppb). We also performed a soil seed bank experiment to test seed longevity with seeds coming from both the four-year ozone exposure experiment and from a short-term treatment conducted at ambient and added ozone concentrations. We found that prolonged ozone exposure produced changes in seed germination, dormancy and longevity, resulting in three S. arvensis populations. Seeds from the 90 ppb ozone selection treatment had the highest level of germination when stored at 75% RH and 25 °C and then scarified. These seeds showed the lowest dormancy level when being subjected to 5 ºC/5% RH and 25 ºC/75% followed by 5% RH storage conditions. Furthermore, ozone exposure increased seed persistence in the soil through a maternal effect. Given that tropospheric ozone is an important pollutant in rural areas, changes in seed traits due to ozone exposure could increase weed persistence in fields, thus affecting weed-crop interactions, which could ultimately reduce crop production.

Published

2013

7. Mutualism effectiveness of a fungal endophyte in an annual grass is impaired by ozone.

Author

Ueno, Andrea C., Gundel, Pedro E., Omacini, Marina, Ghersa, Claudio M., Bush, Lowell P., Martínez‐Ghersa, María Alejandra, and Bennett, Alison

Subjects

*ITALIAN ryegrass, *ENDOPHYTIC fungi, *MUTUALISM (Biology), *PHYSIOLOGICAL effects of ozone, *HERBIVORES, *ALKALOIDS, *APHIDS

Abstract

Ozone is an increasing tropospheric contaminant of climate change. Exposure to ozone may affect the symbiotic relationship between plants and beneficial microorganisms. In particular, the herbivore resistance mechanism conferred by fungal endophytes (defensive mutualism) may be affected, as any of the ozone-triggered effects (such as elicitation of defence mechanisms against biotrophic fungi or oxidative stress in the apoplastic space) may target the symbiont., Symbiotic and non-symbiotic Lolium multiflorum plants were exposed to ozone for two consecutive days (2 h per day), after which half were infested with 10 aphids ( Rhopalosiphum padi). We measured variables related to performance of plants, the endophyte symbiont (alkaloids) and the herbivores., Aphid populations were smaller on symbiotic plants than in non-symbiotic plants in low-ozone conditions. However, this difference disappeared in exposed plants to high-ozone conditions. Under low-ozone conditions, structure of aphid populations on endophyte-symbiotic plants was characterized by a low number of nymphs and a high number of adults. This pattern was not observed with high-ozone exposure. Level of fungal alkaloids (lolines) was not affected by either ozone or herbivory., Results indicate that ozone impairs the grass-endophyte symbiosis without affecting production of alkaloids generally linked with aphids' response to endophyte presence. Since neither plant biomass nor alkaloid level were affected by ozone, other ozone-mediated mechanisms at molecular or biochemical level may underlie plant-herbivore interaction mediated by fungal endophytes. Thus, the mechanism behind this effect must be determined in future experiments. [ABSTRACT FROM AUTHOR]

Published

2016

8. Maternal Exposure to Ozone Modulates the Endophyte-Conferred Resistance to Aphids in Lolium multiflorum Plants.

Author

Bubica Bustos, Ludmila M., Ueno, Andrea C., Di Leo, Tara D., Crocco, Carlos D., Martínez-Ghersa, M. Alejandra, Molina-Montenegro, Marco A., and Gundel, Pedro E.

Subjects

ITALIAN ryegrass, MATERNAL exposure, PLANT biomass, OZONE, APHIDS, RYEGRASSES, PLANT defenses

Abstract

Simple Summary: Global change is driving the incidence of novel stress factors such as the tropospheric pollutant ozone. Plants can overcome the environmental challenges by adjusting their phenotypes that eventually, can be transmitted to the progeny. Plants also establish symbiotic interactions with beneficial fungal endophytes, some of which can be transmitted to the progeny through the seeds. We worked with the grass Lolium multiflorum and its common endophyte, Epichloë occultans that benefits the host by coffering resistance to herbivores. Specifically, we studied the effect of exposing endophyte-symbiotic and non-symbiotic plants to ozone on the level of resistance to herbivorous aphids in the progeny. The ozone history impaired the endophyte-conferred resistance to aphids in progeny. This was evident at individual weight level of aphids but not so at population level. Defensive compounds were higher in endophyte-symbiotic seeds but depressed by mother plants exposure to ozone. Despite the negative effect of maternal ozone on the resistance level of plants, symbiotic plants showed a superior biomass compared to endophyte-free plants. Our work illustrates how the environment explored by parent plants can persist transgenerationally and, depending on the symbiotic state, will affect the fate of the progeny. Plants are challenged by biotic and abiotic stress factors and the incidence of one can increase or decrease resistance to another. These relations can also occur transgenerationally. For instance, progeny plants whose mothers experienced herbivory can be more resistant to herbivores. Certain fungal endophytes that are vertically transmitted endow plants with alkaloids and resistance to herbivores. However, endophyte-symbiotic plants exposed to the oxidative agent ozone became susceptible to aphids. Here, we explored whether this effect persists transgenerationally. We exposed Lolium multiflorum plants with and without fungal endophyte Epichloë occultans to ozone (120 or 0 ppb), and then, challenged the progeny with aphids (Rhopalosiphum padi). The endophyte was the main factor determining the resistance to aphids, but its importance diminished in plants with ozone history. This negative ozone effect on the endophyte-mediated resistance was apparent on aphid individual weights. Phenolic compounds in seeds were increased by the symbiosis and diminished by the ozone. The endophyte effect on phenolics vanished in progeny plants while the negative ozone effect persisted. Independently of ozone, the symbiosis increased the plant biomass (≈24%). Although ozone can diminish the importance of endophyte symbiosis for plant resistance to herbivores, it would be compensated by host growth stimulation. [ABSTRACT FROM AUTHOR]

Published

2020

9. The negative effect of a vertically-transmitted fungal endophyte on seed longevity is stronger than that of ozone transgenerational effect.

Author

Ueno, Andrea C., Gundel, Pedro E., Seal, Charlotte E., Ghersa, Claudio M., and Martínez-Ghersa, María Alejandra

Subjects

*SEED viability, *ENDOPHYTES, *OZONE, *ANNUALS (Plants), *ENDOPHYTIC fungi, *PHANEROGAMS, *SYMBIODINIUM

Abstract

• Parental environment affects functional characteristics of seeds. • Seed-transmitted fungal endophytes mediate transgenerational effects in plants. • Negative effects of transgenerational ozone were detected in endophyte-symbiotic seeds but not in non-symbiotic seeds. • Parental ozone impacted seed progeny when it occurs close to reproductive phase of the plant. • Under accelerated ageing conditions, endophyte-symbiotic seeds showed deteriorated physiological state and reduced longevity. The transition from mother plant seed production to seedlings recruitment is critical for annual plant species but also for vertically transmitted microbial symbionts. Evidence indicates that microbial symbionts play important roles in plant response to environmental changes. However, their role in plant facing gaseous tropospheric pollutants such as the highly reactive and phytotoxic ozone, have been scarcely studied. Here, we experimentally tested the consequences of maternal plant exposure to ozone on the longevity of Lolium mutiflorum seeds mediated by a vertically-transmitted fungal endophyte (Epichloë occultans). Seeds were produced by mother plants exposed to contrasting levels of ozone (low and high concentrations) in two phases of the life cycle (vegetative and reproductive). We first characterized the consequences of plant exposure to ozone on the state of the antioxidant glutathione in the seeds. Then, we examined viability dynamics of the seeds through an accelerated ageing trial and followed the physiological variables seed water content (SWC) and electrical conductivity (EC). Irrespectively of maternal ozone, seeds produced by endophyte-symbiotic plants presented higher contents of the oxidised form of glutathione. In the same direction, the fungal endophyte presence was associated with a dramatic reduction in seed longevity. The SWC was higher in endophyte-symbiotic seeds that in endophyte-free seeds. As time under accelerated ageing condition advanced, EC increased more in endophyte-symbiotic seeds than in endophyte-free seeds. Mother plant exposure to ozone tended to have a negative synergistic effect with the endophyte symbiosis. Ozone transgenerational effect was not detected on endophyte-free seeds. Our work contributes to understand the transgenerational effects of vertically transmitted fungal endophytes in plants in response to a currently important factor of stress. [ABSTRACT FROM AUTHOR]

Published

2020