Development of an effective method of human DNA extraction from soil as forensic evidence.

In forensic investigations, it is crucial to detect a suspect's DNA from the available evidence. In an outdoor crime scene, the evidence may be mixed with the soil. However, soil is speculated to inhibit DNA extraction from forensic science samples. In the field of soil microbiology, it is necessary to extract DNA directly from soil to analyse its microbial composition. In this study, we investigated whether skim milk used in procedure of DNA extraction from soil samples could be applied to forensic science to enhance human DNA extraction efficiency from soil mixed with forensic evidence, such as blood, buccal cells, and skin cells. The use of additive reagents, skim milk and bovine serum albumin (BSA), are known to blocking reagent. In the selection of additive reagents experiment, about blood sample, using the skim milk and BSA were found to increase the DNA yield. Therefore, we observed extracted DNA yield from blood, buccal cells, and skin cells when skim milk and BSA were used as additive reagents. The DNA recovery rate was high across all samples upon addition of skim milk. However, in STR analysis, a non-specific peak was detected in the extracted DNA in the presence of skim milk, which was not detected in the presence of BSA, indicating its suitability in forensic analysis. Our study suggests that addition of BSA can efficiently aid the extraction of DNA from forensic evidence mixed with soil.

Effect of Flooding and the nosZ Gene in Bradyrhizobia on Bradyrhizobial Community Structure in the Soil.

We investigated the effects of the water status (flooded or non-flooded) and presence of the nosZ gene in bradyrhizobia on the bradyrhizobial community structure in a factorial experiment that examined three temperature levels (20°C, 25°C, and 30°C) and two soil types (andosol and gray lowland soil) using microcosm incubations. All microcosms were inoculated with Bradyrhizobium japonicum USDA6T, B. japonicum USDA123, and B. elkanii USDA76T, which do not possess the nosZ gene, and then half received B. diazoefficiens USDA110Twt (wt for the wild-type) and the other half received B. diazoefficiens USDA110ΔnosZ. USDA110Twt possesses the nosZ gene, which encodes N2O reductase; 110ΔnosZ, a mutant variant, does not. Changes in the community structure after 30- and 60-d incubations were investigated by denaturing-gradient gel electrophoresis and an image analysis. USDA6T and 76T strains slightly increased in non-flooded soil regardless of which USDA110T strain was present. In flooded microcosms with the USDA110Twt strain, USDA110Twt became dominant, whereas in microcosms with the USDA110ΔnosZ, a similar change in the community structure occurred to that in non-flooded microcosms. These results suggest that possession of the nosZ gene confers a competitive advantage to B. diazoefficiens USDA110T in flooded soil. We herein demonstrated that the dominance of B. diazoefficiens USDA110Twt within the soil bradyrhizobial population may be enhanced by periods of flooding or waterlogging systems such as paddy-soybean rotations because it appears to have the ability to thrive in moderately anaerobic soil.