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     

The impact of red howler monkey latrines on the distribution of main nutrients and on topsoil profiles in a tropical rain forest

Scarcity of organic matter and nutrients in the topsoil is a typical feature of lowland primary tropical rain forests. However, clumped defecation by vertebrate herbivore troops and further dung beetle processing may contribute to locally improve soil biological activity and plant growth. We studied the impact of clumped defecation by the red howler monkey (Alouatta seniculus), a frugivorous primate, on the vertical distribution of topsoil (0–6 cm) main nutrients and microstructures in a tropical rain forest (French Guiana). Three latrines, where monkey troops regularly defecate, were sampled, together with adjoining controls for carbon, nitrogen, phosphorus and microscopic components. The vertical distribution of C and N was affected by clumped defecation: nutrients were mostly restricted to the top 2 cm in control areas while latrines exhibited homogeneously distributed C and N, resulting in higher C and N content below 2 cm. No marked effect of defecation was registered on Olsen P. A small although significant increase in pH (0.1–0.3 pH units) and a marked increase in soil respiration (×1.5–2.5) were registered in latrines. Soil microstructures were studied by the small‐volume method. Variation according to depth, site and clumped defecation was analysed by Redundancy Analysis. The three latrines were characterized by an increase in root‐penetrated mineral‐organic assemblages, mainly composed of recent and old earthworm faeces. The local stimulation of plant roots, microbial and earthworm activity was prominent, together with an increase in soil fertility. Consequences for the regeneration of tropical rain forests in the Amazonian basin were discussed, in the light of existing knowledge.     

Development and characterization of microsatellite loci in the endangered oyster mussel Epioblasma capsaeformis (Bivalvia: Unionidae)

Primers for 10 polymorphic microsatellite loci were developed and characterized for the endangered oyster mussel Epioblasma capsaeformis from the Clinch River, Tennessee. Microsatellite loci also were tested in four other populations or species. Amplification was successful for most loci in these closely related endangered species or populations; therefore, a high level of flanking sequence similarity was inferred for this group of species and populations. Allelic diversity ranged from nine to 20 alleles/locus, and averaged 13.6/locus. This study demonstrated the feasibility of using polymerase chain reaction (PCR) primers to amplify microsatellite loci across freshwater mussel species to conduct population genetics studies.     

PATTERNS OF GENETIC DIFFERENTIATION AND CONSERVATION OF THE SLABSIDE PEARLYMUSSEL, LEXINGTONIA DOLABELLOIDES (LEA, 1840) IN THE TENNESSEE RIVER DRAINAGE

The restoration and recovery of imperiled mussel species willrequire the re-establishment of populations into historicallyoccupied habitats. The possible existence of genetic differentiationamong populations should be considered before inter-basin transfersare made. Eighty individuals of the federal candidate speciesLexingtonia dolabelloides were sampled from populations in theNorth Fork Holston, Middle Fork Holston, Clinch, Paint Rockand Duck rivers of the Tennessee River basin in the southeasternUnited States. We sequenced 603 base-pairs of a mitochondrialDNA gene (ND-1) and 512 base-pairs of a nuclear DNA gene (ITS-1).Analyses of molecular variation (AMOVA) values for both genesindicated that the majority of variation in L. dolabelloidesresided within populations (82.9–88.3%), with 11.7–17.1%of variation among populations. Haplotype frequencies differedsignificantly among populations for both genes sequenced. Clusteringof haplotypes in minimum-spanning networks did not conform stringentlyto population boundaries, reflecting high within-populationand low between-population variability. Maximum parsimony analysisdid not identify any population as a monophyletic lineage. AMantel test showed no significant correlation between geographicalstream distance and genetic distance, thus not supporting apattern of isolation-by-distance. Overall, results providedsupport to manage fragmented populations of L. dolabelloidesin the Tennessee River drainage as two management units (MUs),but did not provide evidence for the existence of ESUs followingpublished molecular criteria. (Received 26 October 2004; accepted 29 April 2005)     

Impending extinctions of North American freshwater mussels (Unionoida) following the zebra mussel (Dreissena polymorpha) invasion

1. Freshwater mussels (Order Unionoida) are the most imperiled faunal group in North America; 60% of described species are considered endangered or threatened, and 12% are presumed extinct. Widespread habitat degradation (including pollution, siltation, river channelization and impoundment) has been the primary cause of extinction during this century, but a new stress was added in the last decade by the introduction of the Eurasian zebra mussel, Dreissena polymorpha , a biofouling organism that smothers the shells of other molluscs and competes with other suspension feeders for food. Since the early 1990s, it has been spreading throughout the Mississippi River basin, which contains the largest number of endemic freshwater mussels in the world. In this report, we use an exponential decay model based on data from other invaded habitats to predict the long-term impact of D. polymorpha on mussel species richness in the basin.
2. In North American lakes and rivers that support high densities (>3000 m⁻²) of D. polymorpha , native mussel populations are extirpated within 4–8 years following invasion. Significant local declines in native mussel populations in the Illinois and Ohio rivers, concomitant with the establishment of dense populations of D. polymorpha , suggest that induced mortality is occurring in the Mississippi River basin.
3. A comparison of species loss at various sites before and after invasion indicates that D. polymorpha has accelerated regional extinction rates of North American freshwater mussels by 10-fold. If this trend persists, the regional extinction rate for Mississippi basin species will be 12% per decade. Over 60 endemic mussels in the Mississippi River basin are threatened with global extinction by the combined impacts of the D. polymorpha invasion and environmental degradation.     

A Chamber Designed for Continuous, Long-term Monitoring of Legume Root Respiration

A chamber is described which allows for continuous, long-termmonitoring of legume root respiration by infrared gas analysisof CO₂ production. The chamber can accommodate either an automaticor manually operated irrigation system and is constructed fromreadily available raw materials. A series of trials throughout the entire growth period (66 d)of cowpea cv. K 2809 have demonstrated that vegetative growthand reproductive development are closely similar for plantsrooted in the respiration chamber and those grown in standardpots using conventional culture techniques. Ontogenetic changesin root respiration rate were recorded and are discussed inrelation to vegetative and reproductive periods of plant growth.