Possible reasons for tolerance to mercury of Lupinus albus cv. G1 inoculated with Hg-resistant and sensitive Bradyrhizobium canariense strains

Inoculation with a mercury (Hg)-resistant Bradyrhizobium canariense strain (L7AH) confers on Lupinus albus the ability to grow under high concentrations of Hg and to accumulate this heavy metal. To elucidate the mechanism/s implicated in the acquisition of this tolerance, lupins were inoculated with resistant (L7AH) and sensitive (L3) strains and fed with different Hg solutions (0–200 μM HgCl2). Mercury application resulted in cellular alterations in leaves and nodules, depending on the strain inoculated. Mesophyll cell chloroplasts from L7AH-inoculated plants treated with Hg showed similar structure to those in control plants, while those of L3-inoculated plants treated with Hg showed a large increase in the number and size of starch granules. This resulted in a large increase in chloroplast and cell size which produced altered grana distribution with a totally disorganized thylakoid structure and clear signs of degradation. The preservation of the distribution and morphology of chloroplasts in L7AH-inoculated plants may be a reason why the photosynthetic efficiency remained unchanged even after treatment with 200 μM of Hg. Mercury exposure produced changes in L3-infected nodule ultrastructure, with evident signs of degradation, especially in bacteroids. However, only slight alterations of nodule morphology were noticed in L7AH-infected nodules. X-ray microanalysis showed that, while Hg was present in the nodules formed by L3, in both cortex and infected zone, in those formed by L7AH only low levels of Hg in the outermost layers of the cortex were detected. The exclusion of Hg from the infected zone together with the conservation of the symbiosome structure in nodules from L7AH-inoculated plants may explain the maintenance of nitrogenase activity.