Physiological and symbiotic variation of a long-term evolved Rhizobium strain under alkaline condition.

Physiological variation and adaptation of the long-term evolved rhizobia to alkaline environments where no host plant existence and the stability of their symbiotic properties when they are reinoculated to legume host remain unclear. A highly effective N2-fixing Rhizobium yanglingense strain CCBAU 01603 was used as the ancestral strain and was cultured continuously with/without addition of extra alkaline reagent (KOH) in laboratory conditions for approximately 500 generations. Total 60 evolved clones obtained were checked for their adaptation to higher alkaline pH level and inoculated to their host plant Caragana microphylla to evaluate their symbiotic efficiencies. Most of the evolved clones showed increased adaptation to higher alkaline pH but all of them decreased symbiotic efficiencies, resulting in the formation of irregular root nodules with lower nitrogenase activity, production of abnormal bacteroids, and accumulation more starch grains in uninfected nodule cells. Further demonstration of lower symbiotic efficiencies came from the down-regulated expression of genes related to nitrogen fixation in the bacteroids by transcriptome comparison. In addition, genes related to transporters and other diverse functions were up- or down-regulated in the evolved clones in free-living conditions (like yjiS gene) or in symbiotic situations, demonstrating the significant variations in cellular physiology and symbiosis. Our study revealed that the enhancement of alkaline adaptation but loss of symbiotic efficiencies of the evolved clones had happened during the long-term evolution in alkaline environments where no selective pressures from host plant, offering new insight into the molecular mechanism and direction of rhizobial evolution in nature.

Competition between rhizobia under different environmental conditions affects the nodulation of a legume.

Mutualistic symbiosis and nitrogen fixation of legume rhizobia play a key role in ecological environments. Although many different rhizobial species can form nodules with a specific legume, there is often a dominant microsymbiont, which has the highest nodule occupancy rates, and they are often known as the "most favorable rhizobia". Shifts in the most favorable rhizobia for a legume in different geographical regions or soil types are not well understood. Therefore, in order to explore the shift model, an experiment was designed using successive inoculations of rhizobia on one legume. The plants were grown in either sterile vermiculite or a sandy soil. Results showed that, depending on the environment, a legume could select its preferential rhizobial partner in order to establish symbiosis. For perennial legumes, nodulation is a continuous and sequential process. In this study, when the most favorable rhizobial strain was available to infect the plant first, it was dominant in the nodules, regardless of the existence of other rhizobial strains in the rhizosphere. Other rhizobial strains had an opportunity to establish symbiosis with the plant when the most favorable rhizobial strain was not present in the rhizosphere. Nodule occupancy rates of the most favorable rhizobial strain depended on the competitiveness of other rhizobial strains in the rhizosphere and the environmental adaptability of the favorable rhizobial strain (in this case, to mild vermiculite or hostile sandy soil). To produce high nodulation and efficient nitrogen fixation, the most favorable rhizobial strain should be selected and inoculated into the rhizosphere of legume plants under optimum environmental conditions.

Quantification of the impact of land-use changes on ecosystem services: a case study in Pingbian County, China.

Pingbian Miao Autonomous County is one of the poorest rural areas in China. Land-use changes, mainly driven by agricultural expansion and deforestation, may significantly impact ecosystem services and functions, but such effects are difficult to quantify. In the present study, Landsat image data were combined with the published coefficients about the world and China ecosystem to quantify land-use and ecosystem service changes in the mountainous area. A sensitivity analysis was employed to determine the effect of manipulating these coefficients on the estimated values. Our results show that during the past decades (from 1973 to 2004) forests and grasslands were converted into shrubland and cropland, respectively, resulting in a continuous decrease in ecosystem service (from 124.5 US$ x 10(6) in 1973 to 100.4 US$ x 10(6) in 2004). We found that the decrease of mixed forest in the study area was the largest contributor (i.e., 25.4 US$ x 10(6)) to the decline of the ecosystem service. Therefore we propose that future land-use policy should pay more attention to the crucial ecosystem functions of these forests (including tropical forest), and that it is necessary to balance the relationship between the livelihood of local farmers and environmental protection in order to maintain a healthy and stable ecosystem.