Migratory benthic fishes may induce regime shifts in a tropical floodplain pond

1. Alternative states are a widely recorded phenomenon in shallow lakes, which may shift between turbid‐ and clear‐water conditions. Here, we investigate whether such shifts in a tropical floodplain pond may be related to the effect of the flood pulse regime on the community structures of fish and macrophytes. 2. Using a long‐term data set, we demonstrate how benthic fish migration together with colonisation by submerged plants affected the transition from a turbid to a macrophyte‐dominated state in a floodplain pond without top‐down control. 3. In our study, the turbid state occurred mostly during low water phases and was largely characterised by high values for the biomass of benthic fish, chlorophyll‐a and total phosphorous. 4. During the period of rising water levels, the migration of benthic fish out of the pond occurs simultaneously with the establishment of submerged plants, while water turbidity decreases along with phytoplankton and nutrient concentrations, inducing a clear‐water phase. However, when submerged plants are absent and fish migration is low, a transient state is generated. 5. We suggest that, in contrast to temperate ponds and shallow lakes, where the main driving mechanisms establishing alternative states are related to cascading effects via the food chain, in tropical ponds and shallow lakes it is resuspension of sediments by benthic fish that plays the most significant role in establishing alternative states. However, the effect of the flood pulse regime plays an important role in the temporal dynamics of fish community structure by controlling benthic fish migration.     

Using space‐for‐time substitution and time sequence approaches in invasion ecology

1. Invasion biologists use two main approaches to evaluate the effects of non‐native species (NNS) on diversity of native species (DNS), namely space‐for‐time and time approaches. These approaches have pitfalls related to lack of controls: the former lacks pre‐invasion data, while the latter often lacks data from non‐invaded sites. 2. We propose a framework that combines space‐for‐time and time approaches and which should result in more focused mechanistic hypotheses and experiments to test the causes of invasibility and the effects of NNS on DNS. We illustrate the usefulness of our framework using two case studies: one with the submersed macrophyte, Hydrilla verticillata, in reservoir and the other with the fish, Geophagus proximus, in a large river–floodplain system. 3. Hydrilla verticillata invaded sites with DNS similar to that found in non‐invaded sites, indicating that biotic and/or abiotic factors did not influence invasion success; however, DNS increased over time in invaded sites compared with non‐invaded sites, suggesting that H. verticillata facilitated natives. In contrast, G. proximus invaded sites with higher DNS than non‐invaded sites, suggesting that biotic and/or abiotic factors favouring natives were important for invasion success, but DNS increased in invaded and non‐invaded sites over time, indicating that an independent factor contributed to DNS increases. 4. Conclusions from both studies would have been inaccurate or incomplete if the space‐for‐time and time approaches had not been used in combination as proposed in our framework.     

Rhizobium Strain Effects on Nitrogen Transport and Distribution in Soybeans

Neves, M. C. P, Didonet, A. D., Duque, F. F. and Dobereiner,J. 1985. Rhizobium strain effects on nitrogen transport anddistribution in soybeans.—J. exp. Bot. 36: 1179–1192. The role of six Rhizobium strains in the nitrogen metabolismof soybeans (Glycine max Merril) was studied under glasshouseand field conditions. The strains could be divided into twogroups, group I which produced a large nodule mass with relativelylow efficiency and group II which produced less nodule massbut which fixed the same amount of nitrogen. Plants inoculatedwith group I strains remobilized nitrogen faster from leavesbut also lost more nitrogen in senesced leaves. Although thetotal nitrogen transported in the xylem was similar for allstrains, plants inoculated with group I strains contained lessnitrogen in ureides in the xylem sap during the whole growthcycle. This difference was reflected in the nitrogen partitioningwithin the shoot, and smaller nitrogen harvest indexes wereobserved in these plants than in those inoculated with strainsof group II. The role of ureides in the nitrogen partitioningand grain yield was confirmed by the significant correlationbetween mean ureide content in xylem sap and nitrogen partitioningor yield. Further, nodules formed with group I strains evolvedmore hydrogen than those formed with group II strains and thepossible significance of this is discussed. Key words: Ureides, hydrogen evolution, grain yield, grain yield, harvest index, nitrogen fixation