Interação de Paracoccidioides brasiliensis com células dendríticas pulmonares induz produção de IL-10 e expressão de TLR2: possíveis mecanismos de suscetibilidade / Interaction of Paracoccidioides brasiliensis with pulmonary dendritic cells induces IL-10 production and TLR2 expression: possible mechanisms of susceptibility

Ferreira, Karen Spadari

11 June 2007

A resposta imune adaptativa do tipo Th1 é necessária para proteção contra P. Brasiliensis. Sabendo que células dendrítica são APCs eficientes na ativação da resposta imune mediada por células, investigamos o potencial dessas células em iniciar a resposta imune inata em camundongos suscetíveis (B10.A) e resistentes (A/J) a PCM. Inicialmente, observamos que células dendríticas pulmonares de camundongos B10.A são mais fagocíticas quando comparadas com células de camundongos A/J. Além disso, observamos que a fagocitose na presença de laminarina foi inibida somente em células dendríticas pulmonares de animais B10.A. A produção de citocinas por células dendríticas pulmonares de camundongos A/J mostrou baixa concentração de IL-10, IL-12 e TNF-α. Ao contrário, células dendríticas pulmonares de camundongos B10.A produziram altas concentrações de TNF-α e IL-10, mas, a produção de IL-10 foi significativamente inibida na presença de laminarina. Nós também observamos que células dendríticas pulmonares de camundongos TLR-2KO foram deficientes na produção de IL-10. Além disso, a expressão gênica para TLR-2 aumentou após infecção em camundongos B10.A, mas não nos A/J. Posteriormente, observamos que a capacidade de células dendríticas pulmonares de camundongos suscetíveis em induzir ativação de células T foi diminuída. De acordo com nossos resultados, sugerimos que P. brasiliensis induz células dendríticas regulatórias em camundongos suscetíveis, os quais promovem a produção de IL-10, contribuindo para a suscetibilidade de camundongos B10.A contra a infecção por P. brasiliensis. / An adaptive Th1-type immune response is required for protection against P.brasiliensis. Knowing that DC are the most effective APCs for inducing cellmediated immune responses, it is thus important to investigate lung DC and their potential to initiate an immune response in mice susceptible and resistant to PCM. Initially, we observed that lung DC from susceptible mice were more phagocytic than cells from resistant mice and we observed that phagocytosis in the presence of laminarin was inhibited only in DC from susceptible mice. Cytokines produced by DC from resistant mice showed a low concentration of IL-10, IL-12 and TNF-α. In contrast, DC from susceptible mice produced a high concentration of TNF-α and IL-10, but IL-10 production was significantly inhibited in the presence of laminarin. We also observed that DC from TLR-2KO mice presented a defective production of IL-10. We found that the gene expression for TLR2 is increased after infection in B10.A, but not in A/J mice. Thus, the capacity of lung DC from susceptible mice in inducing T cell activation was decreased. In conclusion, our data suggest that P.brasiliensis induces regulatory DC in susceptible mice, which promotes IL-10 production contributing to the susceptibility of B10.A mice against P.brasiliensis infection.

Antigen-presenting cells

Apresentação de antígeno

Células dendríticas (Imunologia)

Células dendríticas pulmonares

Dendritic Cells (Immunology)

Lung dendritic cells

Medical Mycology (Experiments)

Micologia médica (Experimentos)

Paracoccidioidomicose

Paracoccidioidomycosis

Receptores \"Toll like\"

\"Toll Like\" receptors

Ecology and diversity of indigenous Trichoderma species in vegetable cropping systems

Bourguignon, Emmanuel

January 2008

The overall aim of this research was to improve the understanding of the ecology and diversity of Trichoderma species within the soil and rhizosphere of onion (Allium cepa L.) and potato (Solanum tuberosum L.) under intensive management in New Zealand. The indigenous Trichoderma population was measured in a field trial at Pukekohe over a three year period under six different crop rotation treatments. The treatments included two continuous onion and potato rotations (intensive), two onion/potato mixed rotation (conventional), and two green manure rotations (sustainable). Results showed that Trichoderma populations were stable in both the rhizosphere and bulk soil (1.5 x 10² to 8.5 x 10³ CFU g⁻¹ ODS). The planting and incorporation of an oat (Avena sativa L.) green manure in the sustainable rotations positively increased Trichoderma colony forming unit (CFU) numbers in the rhizosphere soil from 3.4 x 10² to 2.5 x 10³ g⁻¹ ODS. A Trichoderma species identification method was developed based on colony morphology. Representative isolates were verified using restriction fragment length polymorphism (RFLP) and DNA sequencing. The method allowed for rapid and reliable identification of isolated Trichoderma species. Five species were identified in the Pukekohe soil: T. asperellum, T. atroviride, T. hamatum, T. harzianum and T. koningii. Results showed identical species diversity between the rhizosphere, rhizoplane and bulk soil. The species did not strongly compete between each other for the rhizosphere ecological niche and differences in species proportions seemed to be caused by environmental factors rather than the rotation treatments. The incorporation of oat green manure in pots did not significantly promote the indigenous Trichoderma population size and diversity in the rhizosphere of onion plants up to 4 months old. The identified species were the same as in the field trial. The incorporation of onion scale residues was shown to result in low Trichoderma and high Penicillium CFU numbers and a reduction in plant size. Additionally, the presence of high levels (6.0 x 10⁵ CFU g⁻¹ ODS) of Penicillium CFU was negatively correlated with the presence of Trichoderma CFU. The effect of oat incorporation on Trichoderma saprophytic growth was also investigated in a soil sandwich assay and revealed no significant differences. A series of experiments indicated that onion extract obtained from dry onion scale residues had no antifungal activity against either Trichoderma or Penicillium and instead tended to promote their hyphal growth and sporulation. It also showed that competition between Penicillium and Trichoderma isolates was limited despite the ability of Penicillium to produce a wide range of inhibitory substances. Four indigenous Trichoderma species (T. atroviride, T. hamatum, T. harzianum and T. koningii) were shown to be rhizosphere competent in a split tube experiment over a 6 week period. The results of this experiment revealed that, the Trichoderma species clearly displayed differences in their ability to colonise the rhizosphere of young onion seedlings. Species such as T. koningii had the greatest rhizosphere colonising ability regardless of soil depth while T. harzianum displayed the weakest ability. Results also indicated that when inoculated as a mixture the four species competed with one another to colonise the rhizosphere. Overall, this research indicated that the studied crop rotation treatments and the use of oat as a green manure did not strongly promote indigenous Trichoderma populations. Species diversity was constant throughout the research with T. hamatum and T. koningii being the most frequently isolated species.

Trichoderma

rhizosphere

ecology

indigenous

population

crop rotation

Allium cepa L.

Solanum tuberosum L.

Avena sativa L.

green manure

amendments

species diversity

identification

RFLP

Penicillium

rhizosphere competence

Interação de Paracoccidioides brasiliensis com células dendríticas pulmonares induz produção de IL-10 e expressão de TLR2: possíveis mecanismos de suscetibilidade / Interaction of Paracoccidioides brasiliensis with pulmonary dendritic cells induces IL-10 production and TLR2 expression: possible mechanisms of susceptibility

Karen Spadari Ferreira

11 June 2007

A resposta imune adaptativa do tipo Th1 é necessária para proteção contra P. Brasiliensis. Sabendo que células dendrítica são APCs eficientes na ativação da resposta imune mediada por células, investigamos o potencial dessas células em iniciar a resposta imune inata em camundongos suscetíveis (B10.A) e resistentes (A/J) a PCM. Inicialmente, observamos que células dendríticas pulmonares de camundongos B10.A são mais fagocíticas quando comparadas com células de camundongos A/J. Além disso, observamos que a fagocitose na presença de laminarina foi inibida somente em células dendríticas pulmonares de animais B10.A. A produção de citocinas por células dendríticas pulmonares de camundongos A/J mostrou baixa concentração de IL-10, IL-12 e TNF-α. Ao contrário, células dendríticas pulmonares de camundongos B10.A produziram altas concentrações de TNF-α e IL-10, mas, a produção de IL-10 foi significativamente inibida na presença de laminarina. Nós também observamos que células dendríticas pulmonares de camundongos TLR-2KO foram deficientes na produção de IL-10. Além disso, a expressão gênica para TLR-2 aumentou após infecção em camundongos B10.A, mas não nos A/J. Posteriormente, observamos que a capacidade de células dendríticas pulmonares de camundongos suscetíveis em induzir ativação de células T foi diminuída. De acordo com nossos resultados, sugerimos que P. brasiliensis induz células dendríticas regulatórias em camundongos suscetíveis, os quais promovem a produção de IL-10, contribuindo para a suscetibilidade de camundongos B10.A contra a infecção por P. brasiliensis. / An adaptive Th1-type immune response is required for protection against P.brasiliensis. Knowing that DC are the most effective APCs for inducing cellmediated immune responses, it is thus important to investigate lung DC and their potential to initiate an immune response in mice susceptible and resistant to PCM. Initially, we observed that lung DC from susceptible mice were more phagocytic than cells from resistant mice and we observed that phagocytosis in the presence of laminarin was inhibited only in DC from susceptible mice. Cytokines produced by DC from resistant mice showed a low concentration of IL-10, IL-12 and TNF-α. In contrast, DC from susceptible mice produced a high concentration of TNF-α and IL-10, but IL-10 production was significantly inhibited in the presence of laminarin. We also observed that DC from TLR-2KO mice presented a defective production of IL-10. We found that the gene expression for TLR2 is increased after infection in B10.A, but not in A/J mice. Thus, the capacity of lung DC from susceptible mice in inducing T cell activation was decreased. In conclusion, our data suggest that P.brasiliensis induces regulatory DC in susceptible mice, which promotes IL-10 production contributing to the susceptibility of B10.A mice against P.brasiliensis infection.

Apresentação de antígeno

Células dendríticas (Imunologia)

Células dendríticas pulmonares

Micologia médica (Experimentos)

Paracoccidioidomicose

Receptores \"Toll like\"

Antigen-presenting cells

Dendritic Cells (Immunology)

Lung dendritic cells

Medical Mycology (Experiments)

Paracoccidioidomycosis

\"Toll Like\" receptors

Thousand Cankers Disease of Eastern Black Walnut: Ecological Interactions in the Holobiont of a Bark Beetle-Fungal Disease

Geoffrey M Williams (11186766)

27 July 2021

<p>Eastern black walnut (<i>Juglans nigra</i> L.) ranks among the most highly valued timber species in the central hardwood forest and across the world. This valuable tree fills a critical role in native ecosystems as a mast bearing pioneer on mesic sites. Along with other <i>Juglans</i> spp. (Juglandaceae), <i>J. nigra</i> is threatened by thousand cankers disease (TCD), an insect-vectored disease first described in 2009. TCD is caused by the bark beetle <i>Pityophthorus juglandis</i> Blackman (Corthylini) and the phytopathogenic fungus <i>Geosmithia morbida</i> Kol. Free. Ut. & Tiss. (Bionectriaceae). Together, the <i>P. juglandis</i>-<i>G. morbida</i> complex has expanded from its historical range in southwest North America throughout the western United States (U.S.) and Europe. This range expansion has led to widespread mortality among naïve hosts <i>J. nigra</i> and <i>J. regia</i> planted outside their native distributions.</p> <p> The severity of TCD was previously observed to be highest in urban and plantation environments and outside of the host native range. Therefore, the objective of this work was to provide information on biotic and abiotic environmental factors that influence the severity and impact of TCD across the native and non-native range of <i>J. nigra</i> and across different climatic and management regimes. This knowledge would enable a better assessment of the risk posed by TCD and a basis for developing management activities that impart resilience to natural systems. Through a series of greenhouse-, laboratory- and field-based experiments, environmental factors that affect the pathogenicity and/or survival of <i>G. morbida</i> in <i>J. nigra</i> were identified, with a focus on the microbiome, climate, and opportunistic pathogens. A number of potentially important interactions among host, vector, pathogen and the rest of the holobiont of TCD were characterized. The <i>holobiont</i> is defined as the whole multitrophic community of organisms—including <i>J. nigra</i>, microinvertebrates, fungi and bacteria—that interact with one another and with the host.</p> <p>Our findings indicate that interactions among host, vector, pathogen, secondary pathogens, novel microbial communities, and novel abiotic environments modulate the severity of TCD in native, non-native, and managed and unmanaged contexts. Prevailing climatic conditions favor reproduction and spread of <i>G. morbida</i> in the western United States due to the effect of wood moisture content on fungal competition. The microbiome of soils, roots, and stems of trees and seedlings grown outside the host native range harbor distinct, lower-diversity communities of bacteria and fungi compared to the native range, including different communities of beneficial or pathogenic functional groups of fungi. The pathogen <i>G. morbida</i> was also associated with a distinct community of microbes in stems compared to <i>G. morbida</i>-negative trees. The soil microbiome from intensively-managed plantations facilitated positive feedback between <i>G. morbida</i> and a disease-promomting endophytic <i>Fusarium solani</i> species complex sp. in roots of <i>J. nigra</i> seedlings. Finally, the nematode species <i>Bursaphelenchus juglandis</i> associated with <i>P. juglandis</i> synergizes with <i>G. morbida</i> to cause foliar symptoms in seedlings in a shadehouse; conversely, experiments and observations indicated that the nematode species <i>Panagrolaimus</i> sp. and cf. <i>Ektaphelenchus</i> sp. could suppress WTB populations and/or TCD outbreaks.</p> <p>In conclusion, the composition, function, and interactions within the <i>P. juglandis</i> and <i>J. nigra</i> holobiont play important roles in the TCD pathosystem. Managers and conservationists should be aware that novel associations outside the host native range, or in monocultures, intensive nursery production, and urban and low-humidity environments may favor progression of the disease through the effects of associated phytobiomes, nematodes, and climatic conditions on disease etiology. Trees in higher diversity, less intensively managed growing environments within their native range may be more resilient to disease. Moreover, expatriated, susceptible host species (<i>i.e.</i>, <i>J. nigra</i>) growing in environments that are favorable to novel pests or pest complexes (<i>i.e.</i>, the western U.S.) may provide connectivity between emergent forest health threats (<i>i.e.</i>, TCD) and native host populations (<i>i.e.</i>, <i>J. nigra</i> in its native range).</p>

Microbiology

Molecular Biology

Botany

Bioinformatics

Plant Biology

Terrestrial Ecology

Biogeography and Phylogeography

Host-Parasite Interactions

Microbial Ecology

Mycology

Plant Pathology

Global Change Biology

Forest pathology

Symbiosis

Biological invasion

Endosphere

Rhizosphere

Emergent disease

Invasive species

Alternative stable state

Microbiome

Juglandaceae

Walnut

Bark beetle

Hypocreales

Geosmithia morbida

Mutualism (Biology)

Climate change

Central hardwood forest

Juglans

Pityophthorus

Corthylini

Nematode

Parasitology

Fungi

Mycobiome

Holobiont

Network analysis

Soil science

Sustainability

Biodiversity

Forest management

Endophyte

Phyllosphere

Caulosphere

Multitrophic interaction

Aboveground-belowground interactions

Soil feedback