RÉSUMÉ
RESUMO Tendo em vista os vários problemas ambientais e de saúde que o uso crescente de agrotóxicos vem causando, é necessário a otimização de técnicas que visem a sua rápida degradação. A atrazina é um herbicida utilizado no controle de ervas daninhas, principalmente nas culturas de milho e cana-de-açúcar. Nesse sentido, o objetivo deste estudo foi verificar a eficiência da levedura Saccharomyces cerevisiae na degradação do herbicida atrazina em solo contaminado com diferentes concentrações do produto comercial. Foi igualmente testado o efeito da adição de palha de milho no experimento. A fim de determinar a quantidade de gás carbônico (CO2) liberado durante os ensaios, o qual reflete a atividade da microbiota do solo responsável pela degradação de compostos orgânicos, foi utilizada a técnica da respiração basal do solo. E, paralelamente a isso, para verificar a concentração de atrazina ao longo do experimento (tempo inicial, aos 7, 14 e 63 dias), foi utilizada a análise de cromatografia gasosa acoplada ao espectrômetro de massas (CG-MS). Por meio da análise estatística dos dados de respiração basal do solo, o fator de bioaumento com a levedura foi o mais significativo, seguido da adição de palha de milho. Verificou-se o declínio da concentração de atrazina por intermédio das análises cromatográficas. Assim, sugere-se que a biorremediação com S. cerevisiae tem potencial para elevar as taxas de degradação do herbicida no solo.
ABSTRACT Considering the various environmental and health problems that the increasing use of pesticides has been causing, it is necessary to optimize techniques aimed at their rapid degradation. Atrazine is a herbicide used to control weeds, especially in maize and sugarcane crops. Thus, the objective of this study was to verify the efficiency of the Saccharomyces cerevisiae yeast in the degradation of the herbicide atrazine in soil contaminated with different concentrations of the commercial product. The effect of addition of corn straw on the experiment was also tested. In order to determine the amount of carbon dioxide (CO2) released during the tests, which reflects the activity of the soil microorganism responsible for the degradation of organic compounds, the soil basal respiration technique was used. At the same time, the concentration of atrazine during the experiment (start time, at 7, 14, and 63 days) was analyzed by gas chromatography coupled to the mass spectrometer (CG-MS). Through the statistical analysis of the basal respiration data of the soil, the bioaugmentation factor with yeast was the most significant, followed by the addition of corn straw, and the decline in atrazine concentration was verified through chromatographic analyses. Thus, it is suggested that bioremediation with S. cerevisiae has the potential to increase the rates of degradation of the herbicide in the soil.
RÉSUMÉ
An incubation experiment was conducted to investigate the effects of simulated saltwater treatment with different percentages of artificial seawater on degradation dynamics of herbicide glyphosate and microbial activities in a riparian soil in Chongming Island, China. The results showed that 10% seawater treatment showed significantly enhancing effects on degradation efficiency of glyphosate with the lowest residual concentration among all the treatments. However, glyphosate degradation was markedly decreased in the riparian soil with 20% and 50% seawater treatments. The half-lives for 20% and 50% seawater treatments were prolonged by 12.1 and 39.0%, respectively, as compared to control. Microbial investigation indicated that 10% seawater treatment significantly stimulated microbial activities in the glyphosate-spiked riparian soil throughout the incubation period. At 42 day of incubation experiment, flourescein diacetate (FDA) hydrolysis rate, microbial adenosine triphosphate (ATP), and basal soil respiration (BSR) in the glyphosate-spiked riparian soil with 10% seawater were 59.2, 42.5 and 31.8% higher than those with no saltwater treatment, respectively. In contrast, saltwater treatment with 50% seawater significantly inhibited microbial activities. Especially, FDA hydrolysis rate, microbial ATP and BSR were decreased by 66.4, 58.6 and 66.8%, respectively, as compared to control. The results indicate that levels of simulated saltwater can exert variable effects on herbicide degradation dynamics and microbial parameters in the riparian soil.
RÉSUMÉ
In this study, changes in organic carbon (OC), basal soil respiration (BSR), nitrate nitrogen (NO3-N), electrical conductivity (EC) and aggregate stability (AS) of a clay loam soil due to tobacco waste (TOW) application were monitored for 240 days. After incorporating 5% TOW into soil according to oven dry weight basis, soil samples were incubated at field capacity for 20, 40, 80, 140 and 240 days under a greenhouse condition. TOW application significantly increased all soil properties over the control treatment. Soil OC and AS values had significant positive correlations each other and with the other soil properties. Soil OC, BSR and AS values significantly increased from 0.12%, 0.03 μg CO2-C g-1 dry soil 24 hr and 20.7% in control treatment to 1.13%, 3.7 μg CO2-C g-1 dry soil 24 hr and 54.4% in TOW treatment, respectively, in 20 days. While the highest NO3-N (1780 ppm) was found in 40 days, the highest EC (3.35 dS m-1) was in 240 days after TOW application. Disaggregation occurred in all treatments after 20 days of incubation due to probably the more substrate demands of microorganisms in soil.