Assessment of the biochemical composition of oilseed rape (Brassica napus L.) 13C-labelled residues by global methods,FTIR and 13C NMR CP/MAS

The biochemical composition of stems, pod walls and roots of oilseed rape (Brassica napus L.) plants, grown in a growth chamber with two levels of N fertiliser, was assessed by two global methods, i.e., serial extraction with the Van Soest's technique and temperature-programmed pyroanalysis (TP-Py). Statistical analysis of the effect of various parameters on the proportion of soluble components, hemicellulose, cellulose and lignin-like components in oilseed rape organs showed that the composition of plant materials depended on the N nutrition conditions during plant growth. Contents of soluble and hemicellulose fractions were affected by the technique used. Elsewhere, both global techniques resulted in similar proportions of skeletal cellulose (respectively 41 and 36% in low and high N stems, 37 and 30% in low and high N pod walls, 32 and 29% in low and high N roots) and of lignin-like components which ranged from about 7% in high N stems and pod walls to 16% in low N roots. Spectroscopy by FTIR showed a significant band at 1650 cm^–1 (amide I in proteins) in the root material (organ with the lowest C/N ratio) and the absence of lignin-specific bands. Carbon distribution by ¹³C NMR CP/MAS of labelled plants indicated that 60–64% was (cellulose + hemicellulose)-C, close to the values obtained by global methods. The proportion of aromatic-C (110–160 ppm) and phenolic ether was higher in roots than in stems and pod walls. Organs from oilseed rape plants with higher N contents exhibited a larger proportion of C in the 171 ppm chemical shift attributed to the peptide bond. The concomitance of a high level of aromatic and proteinaceous components in roots would reveal the presence of tannin–protein complexes in addition with true lignin.     

The fate of nitrogen from winter-frozen rapeseed leaves: mineralization,fluxes to the environment and uptake by rapeseed crop in spring

For environmental purposes, very early sowing of winter rapeseed may reduce winter nitrate leaching thanks to the high N uptake capacities of rapeseed in autumn. However, freezing could lead to high losses of leaf nitrogen, amounting to more than 100 kg N ha^-1 (Dejoux et al., 1999). Here we investigated the agronomic and environmental consequences of the decomposition of fallen leaves, based on field and laboratory studies with ¹⁵N labeled leaves (C:N=9). The potential kinetics of decomposition of leaves were measured by incubation in the laboratory. In the field, all leaves were removed at beginning of winter and replaced by labeled leaves, artificially frozen at −15°C , which were laid on the soil surface. Compared on a thermal time basis, decomposition proceeded as quickly in the field as in the incubations and was complete after 116 normalized days at 15 °C. The proportion of ¹⁵N derived from labeled leaves, absorbed again by the rape plants, was 28% at flowering and 24% at harvest. This high N recovery is assumed to result from the synchronization of leaves decomposition and active N absorption by rape in spring. Leaf N mineralization did not increase soil N mineral content at flowering or at harvest, but we observed a 40% loss of ¹⁵N. As no leaching was simulated, this loss was supposed to be gaseous. Such a high percentage could be explained by the fact that the decomposing leaves lay on the soil surface, and by climatic conditions conducive to such emissions. For environmental purposes, the quantity and nature of these gaseous N emissions have to be studied for other climatic conditions and types of leaves. As a proportion of N is reabsorbed, N fertilizer application rates could be reduced accordingly. This revised version was published online in August 2006 with corrections to the Cover Date.