ABSTRACT
Rape is known to require more sulfur (S) than is necessary for the secondary metabolite synthesis. It is hypothesized that its coarse root system harbors more homogenous microbial biomass specific for sulfur immobilization/remobilization. In a growth chamber experiment, this work examined the ability of rape and barley to take up the labile 35S (including 35S–SO4 2− and 35S-organic extracted by hot water). For that, the endogenous compounds of soil organic matter were previously labeled with 35S–SO4 2− for three months prior to plant growth. The use of “rhizobag”, a polyamide bag, easily allows the separation of rhizosphere from non-rhizosphere soil. In order to simulate the high input agrosystems, the soil received just before sowing, a unique dose of 76.9 mg N kg−1 soil as ammonium nitrate and three levels of S (20.4, 30.8, and 61.5 mg kg−1 soil) as MgSO4. Despite the dilutions made by levels of additional S–SO4 2−, the results showed an increase in 35S uptake by rape in contrary to barley, which showed a progressive decrease with increasing S–SO4 2− dilutions. The mean percentage values of total 35S taken up by rape were higher than barley (8.9, 22.2, and 28.2% at day 20, 42, and 56 after sowing vs. 3.7, 17.1, and 21.8% respectively). Correlated to 35S-uptake, significant coefficient was found with the 35S–SO4 2− (0.78, p<0.01), and 35S extracted by hot water at 70°C for 18 h in rape rhizosphere (r 2=0.75, p<0.05) but not in barley. Similarly, significant correlation coefficient was observed between soil arylsulfatase and root 35S uptake of rape (r 2=0.79, p<0.01) but not of barley. These results clearly showed the higher capacity of rape rhizosphere in regulating via the arylsulfatase activity the uptake of 35S-endogenous compounds.