Impact of Arbuscular Mycorrhiza symbiosis on photosynthesis in Medicago truncatula

Mettupalli, Dhanunjaya Reddy

January 2011

The Arbuscular mycorrhiza (AM) symbiosis is a mutual association formed by plant roots and soil fungi. Most vascular flowering plants have the ability to form AM associations, which show significant impact on ecosystem function and plant health. This association is based on the mutual exchange of nutrients between plant and fungus. Therefore, AM association leads to increased demands for photosynthesis. The main aim of this study was to investigate the pathway used by plants during AM to increase the photosynthetic performance. To achieve this aim, we used the model legume Medicago truncatula. We have found out that AM symbiosis develops in roots, where AM fungi colonize the roots, leading to better plant growth and more biomass. Furthermore, AM symbiosis increases chlorophyll content and photosynthetic electron transport rate in leaves. Based on these results we suggest that AM symbiosis increases both efficiency and capacity of photosynthetic apparatus in Medicago truncatula

Arbuscular Mycorrhiza

Medicago truncatula

ETR

The Genetics of Arbuscular Mycorrhizal Fungi

Mathieu, Stephanie

30 September 2021

Sexual reproduction is an important process amongst eukaryotic organisms, with one function being to maintain genetic variation. The idea that complex eukaryotic species can persist for millions of years in the absence of sex defies fundamental evolutionary dogma, yet a group of organisms known as ancient asexuals were thought to have evolved clonally under deep evolutionary time. Prominent among these are the arbuscular mycorrhizal fungi (AMF), which are obligate plant symbionts that colonize the root cells of plants and extend their hyphae into the soil assisting the plant in acquiring key nutrients. Unlike most eukaryotes, AMF cells are multinucleate with thousands of nuclei moving through a continuous cytoplasm. Genomic analyses have identified a putative mating-type (MAT) locus within the nuclear genomes of model AMF Rhizophagus irregularis, a region that in other fungi dictates the process of sexual reproduction. Additional findings demonstrated that AMF strains carry one of two nuclear organizations. They can be either homokaryotic (AMF homokaryons), where all nuclei within the cytoplasm are virtually identical, or heterokaryotic (AMF dikaryons), where two MAT-locus variants co-exist within the cytoplasm. Despite a lack of observable traits indicative of sex, this homo/heterokaryotic dichotomy is reminiscent of the nuclear organization of sexual fungi. My research aims to build on these findings to investigate the actual role of the MAT-locus in driving AMF reproduction. To address this, I build my thesis into three main chapters. The first chapter reviews our current understanding of AMF genetics and what drives genome evolution in these organisms. The second chapter establishes a relatively easy, inexpensive, and reproducible approach to genotype known MAT variants of R. irregularis in natural and experimental conditions. The last chapter uses experimental crossings between strains to assess cytoplasmic compatibility and nuclear exchange. I demonstrate that dikaryotic spore progenies can be formed after co-culturing two distinct AMF homokaryotic strains. Further analyses of various genomic regions also reveal possible recombination in homokaryotic spore progenies from co-cultures. Overall, this research provides new experimental insights into the origin of genetic diversity in AMF. These findings open avenues to produce genetically new AMF strains in the lab using conventional crossing procedures and provide a glimpse of the mechanisms that generate AMF genetic diversity in the field.

arbuscular mycorrhiza

mating-type locus

recombination

genotyping

Interaction of Vesicular Arbuscular Mycorrhiza, nematode and phytonematicides on growth and nutritional content of Cleome gynandra

Rabothata, Masia Rodney

January 2017

Thesis (M. Sc.(Agronomy)) -- University of Limpopo, 2017. / Cleome gynandra is increasingly becoming an important strategy for achieving food and nutrition security among rural households in many developing countries. Root-knot (Meloidogyne species) nematodes, with limited nematode management strategies, limit the successful production of this vegetable crop. Nemafric-BL and Nemarioc-AL phytonematicides are separately being developed in South Africa for sustainable crop production systems. However, the two products have not been simultaneously tested for managing the notorious Meloidogyne species and absorption of phosphorus, with a combination of Vesicular arbuscular mycorrhiza (VAM). The objective of this study therefore was to determine the interactive effects of VAM and each of the two phytonematicides on nutrient content, growth of C. gynandra. A 2 × 2 × 2 factorial experiment, with the first, second and third factors being VAM (V), nematode (N) and Nemafric-BL phytonematicide (P). The eight treatments included (1) untreated control (V0N0P0), (2) nematodes alone (V0N1P0), (3) VAM alone (V1N0P0) (4) Nemarioc-AL phytonematicide alone (V0N0P1), (5) V1N1P0, (6) V0N1P1, (7) V1N0P1 and (8) V1N1P1, were laid out in a randomised complete block design, with ten replications. The same layout experiment was done for the Nemarioc-AL phytonematicide trial which had a similar layout. Seedlings were irrigated with 250 ml chloride-free tapwater every other day for 56 days. Multifeed and NPK (2:3:2(22) fertilisers were applied at transplanting. The second order interaction (V1N1P1), was highly significant (P ≤ 0.01) for plant height contributing 54% in TTV (Total Treatment Variation) of the variable. Among the main factors (N, P and V), only nematode had highly significant effects on stem diameter. All interactions of VAM, nematode and Nemarioc-AL phytonematicide and main factors each had no significant effect on Cleome. The second order (V1N1P1) and the first order interaction (V1N1P1) did not have significant effects on the three nutrient elements except for the first order interaction (V1N0P1) which was significant on foliar Zn contributing 42% in TTV of the variable. Also nematode had highly significant effect on foliar K and significant effect on foliar Zn contributing 49 and 31% in TTV of the respective variables. Using the two-way table, VAM and Nemafric-BL phytonematicide each increased foliar Zn by 27% and 29%, respectively. The second and first order interactions of VAM, N and Nemarioc-AL phytonematicide and the main factors did not have significant effect on foliar K, Fe and Zn. The second order interaction of VAM, nematode and Nemafric-BL phytonematicide had significant effects on gall rating, contributing 2% in TTV of the variable. VAM, nematode and Nemarioc-AL phytonematicide showed that the second and first order interaction except for V1N0P1 interaction on gall rating, were not significant for nematode variables. The V1N0P1 interaction contributed 20% in TTV of gall rating. Using a two-way table, VAM and phytonematicide each increased root galls by 7% and 74%, respectively. Combined, VAM and phytonematicide reduced root galls by 64%. The innovative products interacted together and that Nemafric-BL and Nemarioc-AL phytonematicides and VAM alone could be used in managing nematodes. / National Research Foundation, Agricultural Research Council-Universities Collaboration Centre

Vesicular Arbuscular Mycorrhiza

Nematode

Phytonematicides

Cleome gynandra

Capparaceae -- South Africa

Mycorrhizal colonization and plant performance in arcto-alpine conditions

Ruotsalainen, A. L. (Anna Liisa)

02 May 2003

Abstract Mycorrhizal symbiosis is generally advantageous for plants in nutrient-poor soils. Arcto-alpine areas are relatively nutrient-poor, but abundantly inhabited by non-mycorrhizal species. Possibly, mycorrhizal symbiosis is not favoured due to the harsh climatic conditions and the short growing season, which constrain the photosynthetic gain and growth of the arcto-alpine plants. This hypothesis was theoretically evaluated by assuming that optimal mycorrhizal colonization maximizes the net carbon gain of the host plant. In addition, the prevalence of arbuscular mycorrhizal (AM) and dark-septate endophytic (DSE) fungi along an altitudinal gradient was studied in the field, and their effects on the plant performance were tested in the laboratory. In the model, the photosynthetic nutrient use efficiency (PNUE) had a key role in determining whether mycorrhizal strategy would be optimal for the plant net carbon gain. The model generated several colonization patterns depending on possible changes in PNUE and soil nutrient concentrations along altitudinal gradients. Field studies indicated that species-level colonizations do not yield a consistent pattern along the altitude except for fine endophyte, which increased along an altitudinal gradient. In a high-alpine field site root fungal colonizations were rare. Seasonal shifts in colonizations in low-alpine conditions were not found. DSE fungi were common root-associates in the field. In the laboratory, AM had a positive impact on the performance of Gnaphalium norvegicum at 15°C, but not at 8°C. DSE-inoculation did not colonize the roots, but it had a positive impact on seedling performance, which may be due to the saprophytic activity of the fungus in the substrate. Additionally, mycorrhizal inoculum was found to decrease the performance of a non-mycorrhizal plant in a competition experiment. Species-level mycorrhizal colonization patterns may differ from community-level pattern along altitudinal gradients and the relative abundance of different fungal symbionts may change along with the altitude. The performance of mycorrhizal plants in high-alpine conditions may be decreased due to several factors e.g. low temperature constraints on plant and fungal physiology and allocation, soil disturbances and low availability of inoculum. Climatic constraints for plant photosynthesis may thus affect the mycorrhizal colonization patterns in arcto-alpine conditions, but are not necessarily the primary cause for lower performance of mycorrhizal plants at higher altitudes.

alpine ecology

arbuscular mycorrhiza

benefit

cost

dark-septate endophytes

Plant-fungus interactions and their implications for nutrient cycling and biomass growth: Insights from modelling arbuscular mycorrhizal fungi in a heterogeneous environment

Kleinmann, Joachim Ulrich

15 May 2017

A continuously growing world population with a projected size of more than 9 billion inhabitants in the year 2040 requires huge efforts in food production while concurrently avoiding adverse side effects such as the use of pesticides or fertilizers. Among them phosphorous (P) is an important mineral fertilizer for which only few renewable sources exist and which is becoming increasingly scarce. Therefore, methods to reduce P fertilization or enhance fertilization efficiency are urgently needed. One idea is to look how plants in natural ecosystems cope with the problem of nutrient limitation. A strategy, found in almost all plant species is interaction with mycorrhizal fungi. Plants usually deliver carbohydrates (C) to the fungi and get nutrients, like phosphorous (P), in exchange. In natural ecosystems, plants usually interact with multiple fungi which perform differently in their P delivery. However, in agro-ecosystems not all these fungi are helpful. Fungi which are carbon demanding but deliver just few P, might even result in lower plant growth. Therefore a deep knowledge of the mechanisms driving the P and C dynamics is necessary. This can be gained by a computer simulation model which is possible to examine the influence of different nutrient exchange strategies in detail and make prediction how they perform. In this PhD thesis, a spatially explicit simulation model of arbuscular mycorrhizal fungi (AMF) was developed and specific laboratory experiments have been conducted and used for model calibration. This model has been used to evaluate the performance of different nutrient exchange strategies by the emerging maximum achievable fungal biomass, the C uptake rate from the plant and the P delivery rate to the plant. On this basis, three functional types could be identified: parasitic type, intermediate type, mutualistic type. In further steps these functional types have been used to investigate their performance to smooth temporal P pulses (i.e., by transforming them into a continuous P flux delivered to the plant) and to take up spatially heterogeneously distributed P. In both cases, the mutualistic type was found to perform worst and parasitic type best. Two key mechanisms for efficient resource use in spatiotemporally heterogeneous environments could be identified. By the ability of quick fungal biomass growth, AMF can efficiently explore space and store P inside the fungal mycelium. By the creation of spores that do not need C for 6 maintenance, AMF can use the saved C to grow new hypha for further spatial exploration. Through these two mechanisms AMF are able to adapt their mycelium to the spatial and temporal conditions of the P distribution and thus have the potential to largely enhance Puse efficiency. This finally might reduce the application of P fertilizers.

Arbuscular Mycorrhiza

Modelling

Phorphorus

Nutrient cycling

ddc:570

ddc:500

Význam společenstev arbuskulárně mykorhizních hub pro růst vybraných rostlinných druhů na opuštěném poli / Importance of arbuscular mycorrhizal fungal communities for the growth of selected plant species on an abandonned field

Voříšková, Alena

January 2014

The thesis deals with the effect of arbuscular mycorrhiza (AM) on the growth of selected plant species at a locality in České středohoří. This locality is characterized by close neighborhood of a semi-natural dry grassland and a former field abandonned in the 1990s, typical for the mosaic of biotopes in the region. The study is based on previous findings that some plant species, which are common at the semi-natural dry grasslands, do not colonize the abandoned fields. As AM is an important factor affecting diversity and productivity of plant communities we hypothesized that this phenomenon could be related to changes in AM fungal communities at the abandoned field. The hyphothesis was tested in a greenhouse pot experiment with three taxonomically related pairs of plant species, always one species growing at the abandoned field and the second one not. Growth and phosphorus uptake of the plants was followed in soils of both biotopes after factorial inoculation with AM fungal communities from both biotopes. The experiment was complemented by description of AM fungal communities in the roots of six plant species pairs from the locality using terminal restriction fragment length polymorphism (T-RFLP). The greenhouse experiment revealed positive mycorrhizal response in all plant species, but the origin...

Análises do proteoma de raízes de cana-de-açúcar e da expressão de uma peroxidase apoplástica responsiva à micorriza arbuscular / Analysis of the sugarcane roots proteome and expression of an arbuscular mycorrhizaresponsive apoplastic peroxidase

Souza, Simão Lindoso de

14 December 2006

Micorrizas arbusculares (MAs) são associações simbióticas entre os fungos do filo Glomeromycota e a maioria das plantas. Os mecanismos moleculares que controlam o processo de colonização e desenvolvimento das MAs são ainda pouco conhecidos, mas proteínas com acúmulo diferencial em MAs podem ter papel regulatório importante. O presente trabalho teve como objetivo detectar, por meio de eletroforese bi-dimensional (2D-PAGE) e espectrometria de massas, proteínas com acúmulo diferencial no fluido intercelular (FI), membrana plasmática ou tecido radicular de cana-de-açúcar colonizada por Glomus clarum. Plântulas de cana-de-açúcar micropropagadas foram inoculadas com G. clarum e cultivadas com 20 ou 200 mg de P kg-1 de substrato. Raízes micorrizadas e não-micorrizadas, 8 semanas após a inoculação, foram utilizadas para a extração de proteínas do FI, membrana plasmática e tecido radicular (solúveis totais). As proteínas foram separadas por 2D-PAGE e analisadas por espectrometria de massas. Os perfis de proteínas solúveis totais e de membrana plasmática não revelaram proteínas relacionadas à simbiose. No entanto, três proteínas do FI, uma hidrolase aspártica putativa, uma histidina quinase putativa e uma peroxidase putativa apresentaram acúmulo induzido em raízes micorrizadas. As atividades de peroxidases nas raízes e apoplasto das raízes foram determinadas. A atividade de peroxidase apoplástica foi maior em raízes colonizadas e cultivadas em baixo teor de P, quando comparado com controles não-inoculados. Com base na seqüência parcial de aminoácidos dessa peroxidase, um fragmento de seu gene (POX1) foi amplificado e clonado a partir de cDNA de raízes de cana-de-açúcar. A sequência obtida mostrou 90% e 91% de identidade com peroxidase de milho (NCBI) e cana-de-açúcar (TIGR), respectivamente. A análise de expressão de POX1 foi feita por PCR quantitativo a partir de transcritos extraídos de raízes micorrizadas e não-micorrizadas, em condições de baixo e alto P. O acúmulo de transcritos de POX1 em raízes micorrizadas em condições de baixo P foi 6,8 vezes maior do que em raízes micorrizadas cultivadas em condições de alto P. Raízes micorrizadas e cultivadas em condições de alto P apresentaram acúmulo de transcritos 3,9 vezes menor do que em raízes nãomicorrizadas cultivadas nas mesmas condições de P. Os dados obtidos sugerem que o controle do metabolismo de espécies ativas de oxigênio é um dos fatores que contribuem para a regulação do desenvolvimento de MAs. Estudos com plantas alteradas para a expressão de POX1 são, no entanto, necessários para elucidar a essencialidade dessa peroxidase nas MAs. / Arbuscular mycorrhizae (AM) are symbiotic associations between fungi of the phylum Glomeromycota and most of the plant species. Even though the molecular mechanisms controlling the colonization process and AM development are largely unknown, proteins with differential accumulation in AM may have important regulatory roles. The aim of this work was to detect, by bi-dimensional electrophoresis (2D-PAGE) and mass spectrometry, proteins with differential accumulation in the intercellular fluid (IF), plasma membrane or radicular tissue of sugarcane colonized by Glomus clarum Micropropagated sugarcane plantlets were inoculated with G. clarum and growth under low or high P conditions, 20 or 200 mg P kg-1 substrate, respectively. Mycorrhizal and non-mycorrhizal roots, eight weeks after inoculation, were used to extract proteins from the IF, plasma membrane and root tissue (total soluble proteins). Protein separation and analyses were performed using 2D-PAGE and mass spectrometry. The total soluble and plasma membrane protein profiles did not reveled symbiosis-related proteins. However, three proteins from the IF, a putative aspartic hydrolase, a putative histidine kinase and a putative peroxidase showed induced accumulation in mycorrhizal roots. Peroxidase activities in roots and apoplastic fluid were determined, and shown to be higher in mycorrhizal roots at low P than in non-mycorrhizal control roots. Based on the partial amino acid sequence of this peroxidase, a partial cDNA sequence of its gene (POX1) was cloned from PCR-amplified cDNA from sugarcane roots. The POX1 sequence showed 90% and 91% identity to maize (NCBI) and sugarcane (TIGR) peroxidase, respectively. Expression analyses of POX1 were perfomed using quantitative PCR of reverse transcripts from mycorrhizal and non-mycorrhizal roots at low and high P conditions. The steady state level of POX1 transcripts in mycorrhizal roots at low P condition was 6.8-fold higher than in mycorrhizal roots at high P conditions. In mycorrhizal roots at high P conditions the steady state level of POX1 transcripts was 3.9-fold lower than in nonmycorrhizal control roots. These data suggest that the metabolism of reactive oxygen species may be an important factor controlling the development of AM. Studies with plants altered in POX1 expression are, however, required to elucidate the essentiality of this peroxidase in AM.

Apoplast

Arbuscular mycorrhiza

Cana-de-açúcar

Células

Micorriza

Peroxidase

Peroxidase

Proteínas

Proteome

Sugarcane

Análises do proteoma de raízes de cana-de-açúcar e da expressão de uma peroxidase apoplástica responsiva à micorriza arbuscular / Analysis of the sugarcane roots proteome and expression of an arbuscular mycorrhizaresponsive apoplastic peroxidase

Simão Lindoso de Souza

14 December 2006

Micorrizas arbusculares (MAs) são associações simbióticas entre os fungos do filo Glomeromycota e a maioria das plantas. Os mecanismos moleculares que controlam o processo de colonização e desenvolvimento das MAs são ainda pouco conhecidos, mas proteínas com acúmulo diferencial em MAs podem ter papel regulatório importante. O presente trabalho teve como objetivo detectar, por meio de eletroforese bi-dimensional (2D-PAGE) e espectrometria de massas, proteínas com acúmulo diferencial no fluido intercelular (FI), membrana plasmática ou tecido radicular de cana-de-açúcar colonizada por Glomus clarum. Plântulas de cana-de-açúcar micropropagadas foram inoculadas com G. clarum e cultivadas com 20 ou 200 mg de P kg-1 de substrato. Raízes micorrizadas e não-micorrizadas, 8 semanas após a inoculação, foram utilizadas para a extração de proteínas do FI, membrana plasmática e tecido radicular (solúveis totais). As proteínas foram separadas por 2D-PAGE e analisadas por espectrometria de massas. Os perfis de proteínas solúveis totais e de membrana plasmática não revelaram proteínas relacionadas à simbiose. No entanto, três proteínas do FI, uma hidrolase aspártica putativa, uma histidina quinase putativa e uma peroxidase putativa apresentaram acúmulo induzido em raízes micorrizadas. As atividades de peroxidases nas raízes e apoplasto das raízes foram determinadas. A atividade de peroxidase apoplástica foi maior em raízes colonizadas e cultivadas em baixo teor de P, quando comparado com controles não-inoculados. Com base na seqüência parcial de aminoácidos dessa peroxidase, um fragmento de seu gene (POX1) foi amplificado e clonado a partir de cDNA de raízes de cana-de-açúcar. A sequência obtida mostrou 90% e 91% de identidade com peroxidase de milho (NCBI) e cana-de-açúcar (TIGR), respectivamente. A análise de expressão de POX1 foi feita por PCR quantitativo a partir de transcritos extraídos de raízes micorrizadas e não-micorrizadas, em condições de baixo e alto P. O acúmulo de transcritos de POX1 em raízes micorrizadas em condições de baixo P foi 6,8 vezes maior do que em raízes micorrizadas cultivadas em condições de alto P. Raízes micorrizadas e cultivadas em condições de alto P apresentaram acúmulo de transcritos 3,9 vezes menor do que em raízes nãomicorrizadas cultivadas nas mesmas condições de P. Os dados obtidos sugerem que o controle do metabolismo de espécies ativas de oxigênio é um dos fatores que contribuem para a regulação do desenvolvimento de MAs. Estudos com plantas alteradas para a expressão de POX1 são, no entanto, necessários para elucidar a essencialidade dessa peroxidase nas MAs. / Arbuscular mycorrhizae (AM) are symbiotic associations between fungi of the phylum Glomeromycota and most of the plant species. Even though the molecular mechanisms controlling the colonization process and AM development are largely unknown, proteins with differential accumulation in AM may have important regulatory roles. The aim of this work was to detect, by bi-dimensional electrophoresis (2D-PAGE) and mass spectrometry, proteins with differential accumulation in the intercellular fluid (IF), plasma membrane or radicular tissue of sugarcane colonized by Glomus clarum Micropropagated sugarcane plantlets were inoculated with G. clarum and growth under low or high P conditions, 20 or 200 mg P kg-1 substrate, respectively. Mycorrhizal and non-mycorrhizal roots, eight weeks after inoculation, were used to extract proteins from the IF, plasma membrane and root tissue (total soluble proteins). Protein separation and analyses were performed using 2D-PAGE and mass spectrometry. The total soluble and plasma membrane protein profiles did not reveled symbiosis-related proteins. However, three proteins from the IF, a putative aspartic hydrolase, a putative histidine kinase and a putative peroxidase showed induced accumulation in mycorrhizal roots. Peroxidase activities in roots and apoplastic fluid were determined, and shown to be higher in mycorrhizal roots at low P than in non-mycorrhizal control roots. Based on the partial amino acid sequence of this peroxidase, a partial cDNA sequence of its gene (POX1) was cloned from PCR-amplified cDNA from sugarcane roots. The POX1 sequence showed 90% and 91% identity to maize (NCBI) and sugarcane (TIGR) peroxidase, respectively. Expression analyses of POX1 were perfomed using quantitative PCR of reverse transcripts from mycorrhizal and non-mycorrhizal roots at low and high P conditions. The steady state level of POX1 transcripts in mycorrhizal roots at low P condition was 6.8-fold higher than in mycorrhizal roots at high P conditions. In mycorrhizal roots at high P conditions the steady state level of POX1 transcripts was 3.9-fold lower than in nonmycorrhizal control roots. These data suggest that the metabolism of reactive oxygen species may be an important factor controlling the development of AM. Studies with plants altered in POX1 expression are, however, required to elucidate the essentiality of this peroxidase in AM.

Cana-de-açúcar

Células

Micorriza

Peroxidase

Proteínas

Apoplast

Arbuscular mycorrhiza

Peroxidase

Proteome

Sugarcane

Análise da comunidade de fungos em áreas de monoculturas e consórcio de Eucalyptus grandis e Acacia mangium / Analysis of the fungal community in monoculture and consortium areas of Eucalyptus grandis and Acacia mangium

Santana, Maiele Cintra

19 January 2018

Os fungos representam cerca de 75% da biomassa microbiana em áreas florestais, desempenhando funções importantes, desde a mineralização dos resíduos orgânicos até a disponibilização de nutrientes para plantas por meio das associações micorrízicas, o que influencia a ciclagem de nutrientes e, consequentemente, o crescimento das árvores. O objetivo desse trabalho foi avaliar a comunidade de fungos do solo, da rizosfera e do sistema radicular de Eucalyptus grandis e Acacia mangium plantados em monocultivos e em consórcio, e encontrar respostas para os padrões observados por meio da correlação com os atributos físicos, químicos, biológicos e a profundidade do solo. A coleta das amostras foi realizada na Estação Experimental de Ciências Florestais de Itatinga, em 2016, quando as plantas estavam com 2 anos de idade. Foram coletadas amostras em quatro tratamentos: monoculturas de E. grandis e de A. mangium e consórcios de E. grandis e de A. mangium, nos quais foram construídas trincheiras para coleta das amostras nas camadas de 0-10, 10-20, 20-50 e 50-100 cm de profundidade. Foram caracterizados os atributos físicos e biológicos do solo e os atributos químicos do solo, da rizosfera e das raízes. Para a avaliação micorrízica, foi quantificado o número de esporos de fungos micorrízicos arbusculares (FMA) e as taxas de colonização radicular por FMA e por fungos ectomicorrízicos. Foi avaliada a morfologia das estruturas das micorrizas arbusculares e ectomicorriza (ECM). A estrutura da comunidade de fungos do solo e da rizosfera foi avaliada por meio da técnica de Terminal restriction fragment length polymorphism (T-RFLP). Para isso, o DNA foi amplificado utilizando os primers ITS1f-FAM e ITS4 e a restrição dos fragmentos foi realizada com a enzima HaeIII. A abundância de cópias do gene ITS do solo e da rizosfera foi quantificada por PCR quantitativo (qPCR), utilizando os primers ITS1f e 5.8s. Os atributos físicos, químicos e biológicos tiveram poucas variações entre os tratamentos avaliados, sendo as maiores diferenças encontradas entre as profundidades. O número de esporos (<29) e as taxas de colonização micorrízica (<48%) foram baixos em todos os tratamentos, e se reduziram com o aumento da profundidade. As plantas de A. mangium não formaram micorrizas arbusculares. Nas raízes de E. grandis, não houve a formação de arbúsculos, mas foi verificada a presença de hifas enroladas (hyphal coils), estrutura de micorriza do tipo Paris. A anatomia das ECM confirmou a colonização destes fungos nas raízes das plantas estudadas. O qPCR mostrou maior abundância de genes ITS na rizosfera em relação ao solo, assim como nas camadas superficiais (0-10 cm) em relação às mais profundas (10 cm abaixo). A Análise de Coordenadas Principais revelou diferenças na estrutura das comunidades de fungos nos tratamentos estudados, principalmente para a região da rizosfera, diferenciando o perfil de fungos do monocultivo de E. grandis dos demais tratamentos, assim como a influência da A. mangium na estruturação da comunidade. A análise de redundância mostrou a influência de alguns atributos químicos nas taxas de colonização e estruturação da comunidade. Dessa forma, conclui-se que em sistema de consórcio, uma espécie de planta parece ser mais influente do que a outra na estruturação da comunidade de fungos e essa influência é mais evidente na rizosfera. Além disso, os atributos químicos são fatores importantes na organização da comunidade fúngica. / The fungi represent about 75% of the microbial biomass in forest areas, performing important functions, from the mineralization of the organic residues to the availability of nutrients to plants through mycorrhizal associations, which influences the nutrient cycling and, consequently, the growth of trees. The objective of this work was to evaluate the community of fungi of the soil, rhizosphere and root system of Eucalyptus grandis and Acacia mangium planted in monocultures and consortium, and to find explanations for the observed patterns through the correlation with physical and chemical soil attributes and soil depth. The samples were collected at the Experimental Station of Forest Sciences of Itatinga in 2016, when the plants were 2 years old. Samples were collected in four treatments: monocultures of E. grandis and A. mangium and consortia of E. grandis and A. mangium, in which trenches were constructed to collect samples in the 0-10, 10-20, 20 -50 and 50-100 cm deep. The physical and biological attributes of the soil and the chemical attributes of soil, rhizosphere and roots were characterized. For the mycorrhizal evaluation, the number of spores of arbuscular mycorrhizal fungi (AMF) and the rates of root colonization by AMF and ectomycorrhizal fungi were quantified. The morphology of arbuscular mycorrhizal and ectomycorrhizal (ECM) structures was evaluated. The structure of the soil and rhizosphere fungi community by was evaluated by the technique of Terminal restriction fragment length polymorphism (T-RFLP). For this, the DNA was amplified using primers ITS1f-FAM and ITS4 and restriction of the fragments was performed with the enzyme HaeIII. The abundance of ITS gene copies of soil and rhizosphere was quantified by quantitative PCR (qPCR), using primers ITS1f and 5.8s. The physical, chemical and biological attributes had few variations among the evaluated treatments, being the greatest differences found between the depths. The number of spores (<29) and mycorrhizal colonization rates (<48%) were low in all treatments, and reduced with increasing depth. A. mangium plants did not form FMA. In the roots of E. grandis, there was no formation of arbuscules, but we found the presence of hyphal coils, mycorrhizal structures of the Paris type. The anatomy of the ECM confirmed the colonization of these fungi in the roots of the studied plants. The qPCR showed higher abundance of ITS genes in the rhizosphere in relation to the soil, as well as in the superficial layers (0-10 cm) in relation to the deeper ones (10 cm below). The Principal Coordinates Analysis revealed differences in the structure of the fungal communities in the treatments studied, especially for the rhizosphere region, differentiating the fungal profile of the E. grandis monoculture from the other treatments, as well as the influence of A. mangium on the structure of the community. The redundancy analysis showed the influence of some chemical soil attributes on the rates of colonization and community structuring. Thus, it is concluded that in a consortium system, one plant species seems to be more influential than the other in structuring the fungal community, and this influence is more evident in the rhizosphere. In addition, chemical attributes are important factors in the organization of the fungal community.

Arbuscular mycorrhiza

Ectomicorriza

Ectomycorrhiza

Micorriza arbuscular

Raiz

Rhizosphere

Rizosfera

Root

Solo

T-RFLP

T-RFLP

Comunidades de fungos micorrízicos arbusculares no solo e raízes de cana-de-açúcar / Arbuscular mycorrhizal fungi communities in soil and sugarcane roots

Azevedo, Lucas Carvalho Basilio de

13 February 2009

Os fungos micorrízicos arbusculares (FMAs, filo Glomeromycota) formam associações simbióticas com a maioria das plantas vasculares. Normalmente, as hifas dos FMAs crescem no solo e colonizam o interior das raízes. No entanto, não se sabe se as espécies mais abundantes detectadas no solo, por meio da identificação com base na morfologia dos esporos assexuais, são também as mais abundantes no interior das raízes, devido às dificuldades para a identificação dos FMAs com base nas estruturas intrarradiculares. Assim, o objetivo do presente trabalho foi avaliar a estrutura da comunidade de FMAs em cana-de-açúcar sob dois manejos de colheita por meio da identificação das espécies que estão no solo na forma de esporos assexuais e aquelas que estão nas raízes usando o sequenciamento de clones do gene rRNA 18S. Amostras de solo e raízes de cana-de-açúcar de três variedades e dois manejos de colheita: SEM QUEIMA prévia e COM QUEIMA prévia à colheita, foram coletadas em um experimento localizado no município de Novo Horizonte, SP. Foram utilizadas três abordagens para a identificação dos FMAs no interior das raízes: emprego de (1) iniciador específico para fungos em geral, (2) iniciador específico para FMAs e (3) iniciadores específicos para grupos de FMAs. O número de esporos por 50 g de solo, a riqueza de espécies observada e estimada e a diversidade de esporos não diferiram significativamente entre os manejos SEM QUEIMA e COM QUEIMA. Efeitos significativos de variedades de cana-de-açúcar ou na interação dos fatores manejo e variedade não foram observados. A análise de ordenação com base nos esporos identificados também não indicou separação das amostras em função dos tratamentos. Entretanto, plantas do tratamento sob manejo SEM QUEIMA apresentaram as maiores taxas de colonização micorrízica arbuscular, quando comparadas às plantas do tratamento sob manejo COM QUEIMA. Esses dados indicam que a taxa de colonização micorrízica arbuscular é um indicador mais sensível à mudança de manejo de colheita da cana-de-açúcar do que os outros indicadores avaliados. Após a extração de DNA das raízes, o uso dos iniciadores específicos para fungos em geral, para FMAs e iniciadores específicos para grupo de FMAs não resultou em sequências de Glomeromycota. Mesmo assim, a comunidade de fungos associados às raízes detectada por sequenciamento do gene rRNA 18S foi avaliada. Os resultados indicam que a estrutra da comunidade fúngica associada às raízes de cana-de-açúcar diferiu significativamente entre os manejos de colheita SEM QUEIMA e COM QUEIMA prévia, apesar de não haver diferenças na riqueza e índices de diversidade de unidades taxonômicas operacionais observadas. Em geral, estudos adicionais devem ser feitos para otimizar as condições para amplificação do gene rRNA 18S de FMAs para melhor entender a ecologia dos mesmos. / Arbuscular mycorrhizal fungi (AMF, Glomeromycota) form mutualistic symbioses with most land plants. AMF hypha generally grow through the soil and colonize the cortical tissue of the plant roots. However, it is not known whether the most abundant species in the soil, determined based on the morphology of asexual spores are the most abundant inside the roots, due the difficulties in identifying AMF based on intraradical structures. Therefore, the aim of this study was to evaluate the AMF community structure in sugarcane rhizosphere and roots under two harvesting managements, based on spores in the soil and sequencing of 18S rRNA gene clones, respectively. Sugarcane rhizosphere soil and roots were sampled from three varieties, under two harvesting managements: without pre-harvesting burning and with pre-harvesting burning, at an experimental field located in Novo Horizonte (São Paulo, Brazil). Three approaches were used to identify AMF inside the roots: (1) using fungi-specific primers, (2) using AMF-specific primers and (3) using AMF group-specific primers. The number of spores in the soil, the observed and estimated species richness and the diversity of AMF spores in the treatments without and with pre-harvesting burning were not statistically different. Statistically significant effects of sugarcane varieties or the interaction of the factors Harvesting Management and Varieties were not observed. Ordination analysis based on the identified spores did not show clustering by treatments. However, intraradical root colonization rates were higher in the treatment without pre-harvesting burning, as compared to the treatment with pre-harvesting burning. These data indicate that intraradical colonization rate may be used as a more sensitive indicator of environmental changes due to harvesting management, as compared to the other indicators evaluated. The use of fungi-specific, AMF-specific and AMF group-specific primers did not allow the detection of Glomeromycota in the sugarcane roots sampled from the field experiment. Nonetheless, the fungal communities associated with sugarcane roots detected by 18S rRNA gene clone sequencing were evaluated. The results indicate that the fungal communities associated with sugarcane roots from the treatments without and with pre-harvesting burning were statistically different, even though no differences in operational taxonomic unit richness and diversity indices were observed. In general, additional studies are necessary to optimize AMF 18S rRNA gene amplification for a better understanding of their ecology.

18S rRNA

Arbuscular mycorrhiza

Cana-de açúcar

Ecologia do solo

Ecology

Fungi.

Micorriza

Raízes

Sequenciamento genético.