MICROBIAL IMMOBILIZATION OF N-15 FROM LEGUME RESIDUES IN SOILS OF DIFFERING TEXTURES - MEASUREMENT BY PERSULFATE OXIDATION AND AMMONIA DIFFUSION METHODS
Gp. Sparling et al., MICROBIAL IMMOBILIZATION OF N-15 FROM LEGUME RESIDUES IN SOILS OF DIFFERING TEXTURES - MEASUREMENT BY PERSULFATE OXIDATION AND AMMONIA DIFFUSION METHODS, Soil biology & biochemistry, 28(12), 1996, pp. 1707-1715
The immobilization of N-15 by the soil microbial biomass was measured
in three soils of differing texture (sandy loam, a loamy sand and a sa
ndy clay loam), amended with N-15-labelled legume residues of differin
g N status. Modifications to a persulphate oxidation and ammonia micro
-diffusion method are described to measure total N and N-15 contents i
n 0.5 M K2SO4 soil extracts using an automated CN analyzer in series w
ith a stable isotope ratio mass spectrometer (ANCA-MS). The three soil
s were amended with 10 mg g(-1) of shoot or root material from subterr
anean clover (Trifolium subterraneum) containing 1.59 and 2.40% N, res
pectively; lupin leaf (Lupinus angustifolius) containing 1.42% N, or a
defined substrate of glucose (10 mg g(-1)) plus ammonium sulphate (1
mg g(-1)). The amended soils were incubated al 45% maximum water holdi
ng capacity, at 25 degrees C, and measurements taken after 0, 7 and 14
days incubation. Microbial biomass N and N-15 were measured by fumiga
tion-extraction, followed by persulphate oxidation, diffusion and ANCA
-MS; microbial N was also estimated using the ninhydrin method. There
was reasonable agreement between microbial N estimated by both methods
(r = 0.74, 0.85 and 0.92, measured 0, 7, and 14 days after amendment,
respectively). There was a maximum of a four-fold increase in microbi
al N after incubation with added substrates. After 14 days about 23, 1
4 and 18% of the N-15 from clover shoots, clover roots. and lupin leaf
, respectively, had been incorporated into microbial N-15. Clover root
residues had the lowest incorporation into microbial N despite having
the highest N content. There was little effect of soil texture on mic
robial immobilization of legume N, with all three soils showing a simi
lar pattern of incorporation. This was in contrast to ammonium sulphat
e N, where, in the presence of glucose, 21% of the added N was estimat
ed to be incorporated into the microbial biomass of the sandy loam soi
l after 14 days, compared to the 28 and 29% microbial incorporation of
the two finer-textured soils. (C) 1997 Elsevier Science Ltd.