ADAPTABILITY MECHANISM OF NITROGEN-EFFICIENT GERMPLASM OF NATURAL VARIATION TO LOW NITROGEN STRESS IN BRASSICA NAPUS

摘要

Previous studies showed that wide genotype differences in nitrogen (N) efficiency exists among cultivars of rapeseed (Brassica napus L.), but the mechanisms behind those differences are still unknown. In the present study, our aim was to analyze the adaptability mechanism of N-efficient rapeseed to low-N stress by employing two genotypes of natural variation in N efficiency. Nitrogen-efficient genotype, 'BG51', and N-inefficient genotype, 'BG88', were grown in a solution culture experiment under conditions of high-N (6.0 mM N) and low-N (0.6 mM N) supply. After growing 30 d, roots and shoots were sampled for the analysis of dry weight, N concentration and accumulation, N use efficiency (NUE), N transport efficiency (NTE), root system vigor parameters, nitrate redutase (NR) activity, and glutamine synthetase (GS) activity. Nitrogen deficiency decreased shoot and root dry weight significantly, but 'BG51' exhibited a significantly lower decrease in shoot dry weight and had significantly higher biomass production than 'BG88'. Under low N supply 'BG51' accumulated more N in shoot, root and whole plant than 'BG88', and presented higher NUE in both shoot and root. Low-N stress induced an increase in maximum root length by 28.3% for 'BG88' and 55.1% for 'BG51' compared with the high-N treatment. And 'BG51' presented larger root volume, higher root vigor, larger root total absorbing area and root active absorbing area than 'BG88' in low-N treatment. Furthermore, 'BG51' had significantly higher NR and GS activity in both leaf and root in low N treatment than 'BG88', while there was no evident difference between them in high N treatment. These results suggested that N-efficient rapeseed germplasm of natural variation involves an integrated adaptability mechanism responding to low-N stress. Namely, N-efficient genotype could form more developed root system to accumulate more N, and presented efficient N assimilation by higher NR activity and GS activity than N-inefficient genotype. These ultimately resulted in high tolerance of N-efficient genotype to low-N stress and high biomass production.