Changes in the bacterial rare biosphere after permanent application of composted tannery sludge in a tropical soil

Composted tannery sludge (CTS) promotes shifts in soil chemical properties, affecting microbial communities. Although the effect of CTS application on the bacterial community has been studied, it is unclear whether this impact discriminates between the dominant and rare species. This present study investigated how the dominant and rare bacterial communities respond over time to different concentrations of CTS application (0, 2.5, 5, 10, and 20 tons/ha) for 180 days. The richness of operational taxonomic units (OTU) was 30-fold higher in the rare than in the dominant biosphere. While some phyla shifted their relative abundance differently in the dominant and rare biosphere, some genera increased their relative abundance under higher CTS concentrations, such as Nocardioides (∼100%), Rubrobacter (∼300%), and Nordella (∼400%). Undominated processes largely governed the dominant biosphere (76.97%), followed by homogeneous (12.51%) and variable (8.03%) selection, and to a lesser extent, the dispersal limitation (2.48%). The rare biosphere was driven by the CTS application as evidenced by the exclusively homogeneous selection (100%). This study showed that the rare biosphere was more sensitive to changes in soil chemical parameters due to CTS application, which evidences the importance explore this portion of the bacterial community for its biotechnological use in contaminated soils.</p

O microbioma relacionado à ciclagem de carbono e nitrogênio em plantações puras e mistas de Eucalyptus grandis e Acacia mangium

The introduction of N2-fixing trees in mixed forest systems is a recent strategy that can reduce the use of external inputs and increase the Eucalyptus plantations sustainability. In these systems, there is a strong interconnection between the trees, which occurs through a complex network of interactions between microorganisms, above and belowground. These interactions result in innumerable biological functions and ecosystem services, which are essential for soil and plant health. Moreover, the result of the Eucalyptus-microbiome-Acacia interaction has been pointed out as essential in achieving higher Eucalyptus productivity indexes in mixed systems. Our aim was to explore the dynamics of microbiome related to nutrient cycling in pure and mixed Eucalyptus grandis and Acacia mangium plantations. Specifically, our efforts were focused on the microbiome benefits to the biological functions improvement in commercial Eucalyptus plantations driving by Acacia introduction in the system. We also give details regarding as the knowledge of the microbiome diversity, composition and functions can help us to understand their close relationship with carbon (C) and nitrogen (N) cycling in soil and litter layers. We believe that holistic approaches in which we can explore the biological interactions in systems using plants of high ecological value (Acacia) and high economic value (Eucalyptus) will be inevitable in the near future. If we learn how to manipulate important processes mediated by the microbiome involved in these interactions, we will take an important step to overcome the current resource constraints, combining increased productivity with the ecological intensification of forest plantations and the environmental sustainability.A inserção de árvores fixadoras de nitrogênio (N2) em sistemas florestais mistos é uma estratégia recente que pode reduzir o uso de inputs externos e aumentar a sustentabilidade das plantações de Eucalipto. Nesses sistemas, existe uma forte interconexão entre as árvores, a qual ocorre por uma complexa rede de interações entre micro-organismos, acima e abaixo do solo. Essas interações resultam em inúmeros processos biológicos e serviços ecossistêmicos, os quais são essenciais para a saúde do solo e das plantas. Além do mais, o resultado da interação Eucalipto-microbioma-Acácia tem sido apontado como essencial no alcance de maiores índices de produtividade do Eucalipto em sistemas mistos. Nosso objetivo foi explorar a dinâmica do microbioma relacionado à ciclagem de nutrientes em plantações puras e mistas de Eucalyptus grandis e Acacia mangium. Especificamente, nossos esforços focaram nos benefícios do microbioma para a melhoria de funções biológicas, principalmente aquelas promovidas pela introdução da Acácia em plantações comerciais de Eucalipto. Por exemplo, abordamos detalhes como o conhecimento da diversidade, composição e funções desse microbioma pode nos ajudar a compreender sua íntima relação com a ciclagem de carbono (C) e nitrogênio (N) no solo e na serapilheira. Acreditamos que abordagens holísticas, com as quais possamos explorar as interações biológicas em sistemas com plantas de alto valor ecológico (Acácia) e alto valor econômico (Eucalipto) serão inevitáveis no futuro. Se aprendermos a manipular alguns processos mediados pelo microbioma envolvido nessas interações, daremos um passo importante para superar as atuais limitações de recursos, aliando o aumento da produtividade com a intensificação ecológica das plantações florestais e a sustentabilidade do meio ambiente

Soil depth and crop management of Eucalyptus grandis and Acacia mangium plantations influence the structure of soil microbial communities

Pesquisas atuais demonstram respostas positivas em plantios de Eucalipto consorciados com Acacia mangium. O objetivo principal desse trabalho foi avaliar a influência dos sistemas puros e mistos de Eucalyptus grandis e A. mangium na estrutura das comunidades de bactérias e fungos do solo. Avaliou-se a estrutura dessas comunidades num gradiente de profundidade do solo. Foram abertas trincheiras profundas em plantios puros de Acácia (100A), Eucalipto (100E) e em sistemas mistos entre as duas espécies (A+E). No plantio misto fizeram-se coletas de solo e raízes na base da Acácia A(A+E) e na base do Eucalipto E(E+A). Cerca de 10 camadas do solo foram avaliadas ao longo do perfil das trincheiras, sendo coletados pontos de 0 a 800 cm, com 4 repetições cada. As comunidades microbianas foram monitoradas por PCR-DGGE, onde foi observado um forte efeito da profundidade do solo nas comunidades microbianas. Agrupamentos específicos foram formados em cada profundidade amostrada. Plantios puros de Eucalipto selecionaram grupos de bactérias diferentes dos que foram encontrados em 100A, A(A+E) e E(E+A). A comunidade de fungos totais não sofreu diferenciação de grupos nos plantios estudados, ao passo que os perfis de fungos micorrízicos arbusculares (FMA) do solo no tratamento A(A+E), foram significativamente diferentes dos grupos encontrados nos demais tratamentos. Numa análise de correlação, realizada por RDA, ficou indicado que a comunidade de FMA do tratamento A(A+E) correlacionou-se positivamente com os valores de P no solo. Outra variável quantificada foi a abundância de bactérias e fungos, indicadas pelo número de cópias do gene ribossomal 16S DNAr e ITS, respectivamente. Quando comparadas as camadas superficiais do solo (0-20 cm), não foi possível encontrar diferenças na abundância de cópias dos genes 16S e ITS em todos os tratamentos. Ocorreu uma queda exponencial no número de cópias desses genes com o aumento da profundidade do solo. Porém, o tratamento 100E apresentou maior número de cópias em profundidade (de 300-800 cm) dos genes 16S e ITS do que qualquer outro tratamento. Em relação a presença específica de FMA, houve baixa colonização e baixa abundância de esporos de FMA em todos os tratamentos, sendo o tratamento 100E mais colonizado que os demais. Ao todo foram encontradas 16 espécies de FMA, sendo a maior parte pertencente ao gênero Acaulospora. Ao contrário dos FMA, os plantios apresentaram colonização radicular pronunciada por ECM. Conclui-se que nestes sistemas florestais uma espécie de planta parece ser mais importante que a outra na estruturação da comunidade microbiana e que alguns fatores do solo podem ser preponderantes nessa separação. O conhecimento dessas comunidades é de suma importância em plantios florestais, principalmente por estarem envolvidos diretamente nos ciclos biogeoquímicos e, sobretudo, por se tratar de uma forma de plantio florestal nova, promissora e que aborda parâmetros de sustentabilidade.Recently discoveries have shown positive responses in Eucalyptus plantations intercropped with Acacia mangium. The aim of this study was to evaluate the influence of pure and mixed systems (Eucalyptus grandis and A. mangium) on the microbial communities\' structure in soil. We evaluated the structure of these communities in a gradient of soil depth. In this context, deep trenches were digged in pure stands of Acacia (100A), Eucalyptus (100E) and mixed systems (A+E). In mixed forest plantations, soil and roots were sampled at the base of Acacia (A+E) and the base of Eucalyptus (E+A). Soil over 10 layers along the profile from 0 to 800cm were sampled, with 4 replicates each. The microbial communities were monitored by PCRDGGE, where we observed a strong effect of soil depth on microbial communities. As a result, specific clusters were formed in each soil layer. The community composition of Eucalyptus grandis stands was different from the community structure found in the 100A, A (A+E) and E (E+A) systems. The total fungal community did not show any group differentiation due to the plantation system, while the profiles of mycorrhizal fungi (AMF) of these three groups were significantly different from that of the treatment A (A+E). A correlation analysis performed by RDA indicated that the FMA community of the treatment (A+E) was correlated positively with P values in the soil. Another variable quantified was the community of bacteria and fungi, indicated by the number of copies of ribosomal 16S rDNA and ITS, respectively. Comparing the upper soil layers (0-20 cm), we couldn\'t find differences in the abundance of copies of 16S rRNA and ITS region genes in all treatments, but we observed an exponential decrease in 16S rRNA copy numbers with increasing soil depth. Regarding the presence of AMF, we found low root colonization and low abundance of AMF spores in all treatments, although 100E presented higher colonization rates than the others. Altogether, 16 AMF species were found, most of them belonging to the genus Acaulospora. We conclude that these forest systems a plant species seems to be more important than the other in the structuring of the microbial community and that some soil factors may be preponderant in this separation. The processes involving the dynamics of the microbial community structure is a crucial point in understanding the development of forest plantations, mainly by involving the biogeochemical cycles, when seeking for new promising approaches and sustainability parameters

Microbial enzymatic stoichiometry and the acquisition of C, N, and P in soils under different land-use types in Brazilian semiarid

International audienceThe enzymatic stoichiometry varied between land-use in both soil depth.? The values of C-and N-acquiring enzymes were higher at 0-5 cm depth.? Soils under different land-use types in the Brazilian semiarid are P-limited.This study hypothesized that different land-use affect the microbial enzymatic stoichiometry and C-, N-, and P-acquisition in Brazilian semiarid soils. Thus, the enzymes beta-glucosidase (C-acquiring enzyme), urease (N-acquiring enzyme), and acid phosphatase (P-acquiring enzyme) were assessed in soil samples collected at 0-5 and 5-10 cm depth from a tropical dry forest, a protected area with Angico, a protected area with Ipe, scrub area, and an agricultural area with maize. The values of C-, N-, and P-acquiring enzymes were used to calculate the enzymatic C:N, C:P, and N:P ratios. The values of C:P and N:P ratios were higher at 0-5 cm depth, while no significant variation, between soil depth, was observed for C:N ratio. The values of C-and N-acquiring enzymes were higher at 0-5 cm in tropical dry forest areas and Angico forest, respectively. In all land use types, the values of vectors L and A were higher than 1 degrees and 45 degrees, respectively. This study showed that both land-use and soil depth influence the enzymatic stoichiometry, showing higher values of C-and N-acquiring enzymes in native and protected forests at soil surface

Bioprospection and genetic diversity of endophytic bacteria associated with cassava plant

<div><p>ABSTRACT Cassava is mostly planted in sandy soils which are usually of low fertility, thereby making it necessary to perform beneficial associations with microorganisms that can promote their growth. In this perspective, the possibility of selecting bacterial isolates efficient in promoting the growth of the culture is evident, which can provide subsidies for future inoculants. The objective of this study was to isolate, identify, select and evaluate the genetic diversity of endophytic bacteria in roots and stems of cassava grown in Garanhuns - PE, with features involved in promoting plant growth. The isolation was performed on culture medium semisolid LGI-P. The selected isolates were evaluated for the potential to fix N2, as the ability to produce indole acetic acid, for their ability to solubilize inorganic phosphate and produce exopolysaccharides. Some bacterial isolates had their 16S rRNA gene sequenced by the Sanger method. A total of 52 endophytic bacteria isolates were obtained from cassava. Regarding the potential to fix N2, 15% of the isolates were positive. As for the production of IAA, 78% of the isolates produced this phytohormone in a medium with increased L-tryptophan. Approximately 31% of the isolates were able to solubilize inorganic phosphate and 60% had exopolysaccharide. The identification of 19 isolates allowed the grouping into six bacterial genera, namely: Achromobacter, Bacillus, Burkholderia, Enterobacter, Pantoea and Pseudomonas. Cassava plants grown in Garanhuns - PE present interaction with different groups of endophytic bacteria and there are bacterial groups with several characteristics involved in promoting plant growth.</p></div