Ractionation during CO2 consumption by hydrogenotrophic methanogenesis [23] and also during reactions between gaseous CO2 and bicarbonate/carbonate [46].4. Practical considerationsOur study demonstrated the possibility to determine the partitioning of CH4 and CO2 flux from degradation of straw, soil organic matter, and plant root-derived carbon, by treating soil with 13C-labeled rice straw. The procedure is more practical than labeling of the rice plants with 13CO2 that requires cumbersome incubation techniques or expensive FACE treatment. For calculation of fROC, it was important that the d13C of the two RS applications were sufficiently different from each other, and in addition were sufficiently different from the d13C of both ROC and SOM. This was achieved by two RS treatments using the same amount of RS but 13C-labeled to different extent. As a result, the d13C of emitted CH4 (Fig. 2B), d13C of dissolved and produced CH4 and CO2 (Fig. 4) were substantially higher than the controlwithout RS, and of course they were always higher in treatment II than treatment I. Calculation of fRS was simply achieved by using the d13C values of the applied RS and the CH4 derived from the two RS treatments (Eq. 7) assuming that ROC was not differently affected by the two RS treatments. This assumption was in agreement with the observation that the 13C values of the rice plants in the two RS treatments were not significantly different (Fig 1). Notably, these values were significantly higher than those in the control microcosms without RS, probably because some of the RS carbon was assimilated (probably via CO2) by the plants [20,21]. However, the difference was only a few permil and did not prevent computation of flux partitioning, since the difference to the d13C of the labeled RS was quite large. In summary, application of labeled RS may be a convenient technique to determine flux partitioning in rice fields on a routine basis. The determination requires in total three planted field plots and three unplanted ones, i.e., two RS treatments and one untreated control, everything with appropriate replication. Technical installation is not required. Hence, it should be feasible to increase the data basis on the partitioning of CH4 production from ROC, RS and SOM on a regional and seasonal scale. This will help improving process-based modeling of CH4 emission from rice fields.AcknowledgmentsWe thank P. Claus and M. Klose for laboratory technical assistance, R. Angel for help in statistical analysis.Author ContributionsConceived and designed the experiments: QY RC. Performed the experiments: QY. Analyzed the data: QY RC. Contributed reagents/ materials/analysis tools: JP. Wrote the paper: QY RC.
Weight loss and malnutrition are among the most common clinical findings observed in patients with untreated 50-14-6 supplier acquired immunodeficiency syndrome (AIDS) [1]. Malnutrition in these patients has multiple determinants, including reduction in food intake, nutrient malabsorption, and increased energy expenditure due to the hypercatabolic state caused by the human immunodeficiency virus (HIV) infection itself and opportunistic diseases [2,3]. In turn, malnutrition further compromises the immunesystem and has been consistently associated with increased risk of death [4?]. P7C3 site Introduction of highly active antiretroviral therapy (HAART) has dramatically changed the course of HIV infection in countries that prioritized its distribution. Brazil was an early adopter of freely availab.Ractionation during CO2 consumption by hydrogenotrophic methanogenesis [23] and also during reactions between gaseous CO2 and bicarbonate/carbonate [46].4. Practical considerationsOur study demonstrated the possibility to determine the partitioning of CH4 and CO2 flux from degradation of straw, soil organic matter, and plant root-derived carbon, by treating soil with 13C-labeled rice straw. The procedure is more practical than labeling of the rice plants with 13CO2 that requires cumbersome incubation techniques or expensive FACE treatment. For calculation of fROC, it was important that the d13C of the two RS applications were sufficiently different from each other, and in addition were sufficiently different from the d13C of both ROC and SOM. This was achieved by two RS treatments using the same amount of RS but 13C-labeled to different extent. As a result, the d13C of emitted CH4 (Fig. 2B), d13C of dissolved and produced CH4 and CO2 (Fig. 4) were substantially higher than the controlwithout RS, and of course they were always higher in treatment II than treatment I. Calculation of fRS was simply achieved by using the d13C values of the applied RS and the CH4 derived from the two RS treatments (Eq. 7) assuming that ROC was not differently affected by the two RS treatments. This assumption was in agreement with the observation that the 13C values of the rice plants in the two RS treatments were not significantly different (Fig 1). Notably, these values were significantly higher than those in the control microcosms without RS, probably because some of the RS carbon was assimilated (probably via CO2) by the plants [20,21]. However, the difference was only a few permil and did not prevent computation of flux partitioning, since the difference to the d13C of the labeled RS was quite large. In summary, application of labeled RS may be a convenient technique to determine flux partitioning in rice fields on a routine basis. The determination requires in total three planted field plots and three unplanted ones, i.e., two RS treatments and one untreated control, everything with appropriate replication. Technical installation is not required. Hence, it should be feasible to increase the data basis on the partitioning of CH4 production from ROC, RS and SOM on a regional and seasonal scale. This will help improving process-based modeling of CH4 emission from rice fields.AcknowledgmentsWe thank P. Claus and M. Klose for laboratory technical assistance, R. Angel for help in statistical analysis.Author ContributionsConceived and designed the experiments: QY RC. Performed the experiments: QY. Analyzed the data: QY RC. Contributed reagents/ materials/analysis tools: JP. Wrote the paper: QY RC.
Weight loss and malnutrition are among the most common clinical findings observed in patients with untreated acquired immunodeficiency syndrome (AIDS) [1]. Malnutrition in these patients has multiple determinants, including reduction in food intake, nutrient malabsorption, and increased energy expenditure due to the hypercatabolic state caused by the human immunodeficiency virus (HIV) infection itself and opportunistic diseases [2,3]. In turn, malnutrition further compromises the immunesystem and has been consistently associated with increased risk of death [4?]. Introduction of highly active antiretroviral therapy (HAART) has dramatically changed the course of HIV infection in countries that prioritized its distribution. Brazil was an early adopter of freely availab.