Nitrogen dynamics in stream wood samples incubated with [14C]lignocellulose and potassium [15N]nitrate

Surface wood samples obtained from a Douglas fir log ( Pseudotsuga menziesii ) in a Pacific Northwest stream were incubated in vitro with [ 14 C]lignocellulose in a defined mineral salts medium supplemented with 10 mg of N liter −1 of 15 N-labeled NO 3 − (50 atom% 15 N). Evolution of 14 CO 2 , distribution and isotopic dilution of 15 N, filtrate N concentrations, and the rates of denitrification, N 2 fixation, and respiration were measured at 6, 12, and 18 days of incubation. The organic N content of the lignocellulose-wood sample mixture had increased from 132 μg of N to a maximum of 231 μg of N per treatment after 6 days of incubation. Rates of [ 14 C]lignocellulose decomposition were greatest during the first 6 days and then began to decline over the remaining 12 days. Total CO 2 evolution was also highest at day 6 and declined steadily over the remaining duration of the incubation. Filtrate NH 4 + -N increased from background levels to a final value of 57 μg of N per treatment. Filtrate NO 3 − N completely disappeared by day 6, and organic N showed a slight decline between days 12 and 18. The majority of the 15 N that could be recovered appeared in the particulate organic fraction by day 6 (41 μg of N), and the filtrate NH 4 + N fraction contained 11 μg of 15 N by day 18. The 15 N enrichment values of the filtrate NH 4 + and the inorganic N associated with the particulate fraction had increased to approximately 20 atom% 15 N by 18 days of incubation, whereas the particulate organic fraction reached its highest enrichment by day 6. Measurements of N 2 fixation and denitrification indicated an insignificant gain or loss of N from the experimental system by these processes. The data show that woody debris in stream ecosystems might function as a rapid and efficient sink for exogenous N, resulting in stimulation of wood decomposition and subsequent activation of other N cycling processes.