Standardized mapping of nodulation patterns in legume roots.

Optimizing nodulation in legumes is a target for crop improvement, and the spatial control of nodulation is just beginning to be unravelled. However, there is currently no method for standard phenotyping of nodulation patterns. Here we present a method and software for the quantitative analysis of nodulation phenotypes. Roots of nodulated peas (Pisum sativum), wild-type and two mutants, were photographed. Data from the photographs were extracted using custom image and data analysis software. The software makes it possible to extract each nodule's position along primary and lateral roots, and to represent the nodulated root system in a standardized way independent of the way roots are arranged in the soil. A wide variety of nodulation and root variables are calculated, and average spatial nodulation patterns can be computed from multiple samples. Standardized spatial analysis of nodulation patterns opens the way for comparative analyses among genotypes of a single legume species, as here in pea. This approach could also be used to compare nodulation patterns among crops, among plants grown under different environmental conditions, or among plants exposed to different pharmacological treatments. The proposed method should therefore prove useful for studies on nodule organogenesis and nodule physiology and for optimizing nodulation in crops.

Effects of cytokinin on ethylene production and nodulation in pea (Pisum sativum) cv. Sparkle.

In this study, we were interested in learning if cytokinins play a role in the developmental process that leads to nodulation in the pea cv. Sparkle. We demonstrate that the application of the synthetic cytokinin BAP (6-benzyl-amino-purine) results in a number of nodulation-related changes. BAP stimulates the production of ethylene, a known inhibitor of nodulation. At low levels (up to 1 &mgr;M), BAP also stimulates nodulation but as its concentration is increased (up to 25 &mgr;M), nodule number decreases. In BAP-treated roots, the infection threads are abnormal; they are twisted, very knotty, and generally grow in a direction parallel to the root surface. In addition, the centers of cell division in the inner cortex are very few. Thus, BAP-treated Sparkle appears to phenocopy the low-nodulating pea mutant R50 [Guinel FC, Sloetjes LL (2000) Ethylene is involved in the nodulation phenotype of Pisum sativum R50 (sym 16), a pleiotropic mutant that nodulates poorly and has pale green leaves. J Exp Bot 51: 885-894]. However, it appears doubtful that there is a direct correlation between the actions of cytokinin and ethylene in causing a reduction in nodule organogenesis because nodulation is not restored by treating BAP-treated Sparkle with ethylene inhibitors.