Imaging Nutrient Distribution in the Rhizosphere Using FTIR Imaging.

Symbiotic associations in the rhizosphere between plants and microorganisms lead to efficient changes in the distribution of nutrients that promote growth and development for each organism involved. Understanding these nutrient fluxes provides insight into the molecular dynamics involved in nutrient transport from one organism to the other. To study such a nutrient flow, a new application of Fourier transform infrared imaging (FTIRI) was developed that entailed growing Populus tremulodes seedlings on a thin, nutrient-enriched Phytagel matrix that allows pixel to pixel measurement of the distribution of nutrients, in particular, nitrate, in the rhizosphere.

High efficiency poplar transformation.

With the completion of the poplar tree genome database, Populus species have become one of the most useful model systems for the study of woody plant biology. Populus tremuloides (quaking aspen) is the most wide-spread tree species in North America, and its rapid growth generates the most abundant wood-based biomass out of any other plant species. To study such beneficial traits, there is a need for easier and more efficient transformation procedures that will allow the study of large numbers of tree genes.

SEP-class genes in Populus tremuloides and their likely role in reproductive survival of poplar trees.

One of the most important processes to the survival of a species is its ability to reproduce. In plants, SEPALLATA-class MADS-box genes have been found to control the development of the inner whorls of flowers. However, while much is known about floral development in herbaceous plants, similar systems in woody trees remain poorly understood.