TY - JOUR
T1 - Corrigendum to
T2 - Application of stable-isotope labelling techniques for the detection of active diazotrophs (Environmental Microbiology, (2018), 20, 1, (44-61), 10.1111/1462-2920.13954)
AU - Angel, Roey
AU - Panhölzl, Christopher
AU - Gabriel, Raphael
AU - Herbold, Craig
AU - Wanek, Wolfgang
AU - Richter, Andreas
AU - Eichorst, Stephanie A.
AU - Woebken, Dagmar
N1 - Publisher Copyright:
© 2022 Society for Applied Microbiology and John Wiley & Sons Ltd.
PY - 2022/10/1
Y1 - 2022/10/1
N2 - In the above article, it came to the authors' attention that the 15N-N2 gas used only for the ‘Comparison of 15N2-tracer assay with the acetylene reduction assay’ (data in Figure 1A,C) contained traces of 15N-labeled ammonia gas (155.16 ppm). The authors repeated the experiment with 15N-N2 gas free of such contamination and observed the same patterns, as shown in the figure below (Figure 1A,C); they detected incorporation of 15N with the 15N2-tracer assay when nitrogenase activity was not detectable with the acetylene reduction assay. 1 FIGURE (Figure presented.) Comparison of ARA and 15N2 tracer assay. ARA performed on a forest soil sample incubated with either fructose or artificial root exudates (RE) (panels A). ‘Soil, C2H4 contr.’ indicates an ethylene consumption control performed on the forest soil sample. ‘Soil, C2H2’ refers to soil samples incubated with acetylene in the ARA. Graphs depict average ethylene concentration (ppm) +/− standard error. Panels C depict the incorporation of 15N from 15N2 gas (average δ15N +/− standard error) in the same soil samples used for ARA. ‘Contr.’ indicates incubation with lab air. Thus, this repeat confirmed that the application of the 15N2-tracer assay had a higher sensitivity than the acetylene reduction assay. The updated results do not change the implications or interpretations of the study. The authors thank Gaute Lavik from the Max Planck Institute for Marine Microbiology, Bremen, Germany, for analyzing the 15N-N2 gas samples.
AB - In the above article, it came to the authors' attention that the 15N-N2 gas used only for the ‘Comparison of 15N2-tracer assay with the acetylene reduction assay’ (data in Figure 1A,C) contained traces of 15N-labeled ammonia gas (155.16 ppm). The authors repeated the experiment with 15N-N2 gas free of such contamination and observed the same patterns, as shown in the figure below (Figure 1A,C); they detected incorporation of 15N with the 15N2-tracer assay when nitrogenase activity was not detectable with the acetylene reduction assay. 1 FIGURE (Figure presented.) Comparison of ARA and 15N2 tracer assay. ARA performed on a forest soil sample incubated with either fructose or artificial root exudates (RE) (panels A). ‘Soil, C2H4 contr.’ indicates an ethylene consumption control performed on the forest soil sample. ‘Soil, C2H2’ refers to soil samples incubated with acetylene in the ARA. Graphs depict average ethylene concentration (ppm) +/− standard error. Panels C depict the incorporation of 15N from 15N2 gas (average δ15N +/− standard error) in the same soil samples used for ARA. ‘Contr.’ indicates incubation with lab air. Thus, this repeat confirmed that the application of the 15N2-tracer assay had a higher sensitivity than the acetylene reduction assay. The updated results do not change the implications or interpretations of the study. The authors thank Gaute Lavik from the Max Planck Institute for Marine Microbiology, Bremen, Germany, for analyzing the 15N-N2 gas samples.
UR - http://www.scopus.com/inward/record.url?scp=85140149130&partnerID=8YFLogxK
U2 - 10.1111/1462-2920.16213
DO - 10.1111/1462-2920.16213
M3 - Comment/debate
C2 - 36254867
AN - SCOPUS:85140149130
SN - 1462-2912
VL - 24
SP - 4962
EP - 4963
JO - Environmental Microbiology
JF - Environmental Microbiology
IS - 10
ER -