In Situ extraction of rhizosphere organic compounds from contrasting plant communities

Abstract

Currently there is no effective method for capture, identification and quantification of root exudates and rhizosphere secondary metabolites in situ. The purpose of the work reported was to assess if capsules containing non‐ionic carbonaceous resins could be used to non‐destructively sample and compare rhizosphere organic compounds associated with contrasting plant communities. Polyester capsules (Unibest, Inc., Bozeman, MT) containing non‐ionic carbonaceous resins, Ambersorb 563 or XAD‐7 (Rohm and Haas, Inc.), were placed within the rhizosphere of spotted knapweed (Centaurea maculosa), and the native grass, Idaho fescue (Festuca idahoensis), as well as a bare‐soil control in both greenhouse and field studies. At the end a 14‐day period, resins were removed and extracted with sequential elution by water, 50% methanol, and 100% methanol. The eluent fractions were then analyzed for total organic carbon (TOC), total hexose sugars as anthrone reactive carbon (ARC), and total phenols. Samples were then concentrated by rotary evaporating to dryness and analyzed on HPLC equipped with a C‐18 column and tunable ultra‐violet (UV) detector or a photodiode array (PDA) detector. Ambersorb 563 resin extracts from greenhouse and field trials consistently showed 2 times more soluble C and 3–7 times more total soluble sugars in the rhizosphere of knapweed compared to Idaho fescue during the 1996 and 1997 field seasons. This difference was not observed using the XAD‐7 resins during the rather wet field season of 1998. In these studies fescue was found to release higher levels of sugars than knapweed, but not significantly different than control soils. Compounds sorbed to the resins from the knapweed rhizosphere were more effectively eluted by methanol than water and demonstrated both the presence of carbohydrate groups and UV absorption. The XAD‐7 resins allow for sorption of phenolic compounds similar to that of Ambersorb 563, but allow for far greater desorption of these compounds. Non‐ionic resins may provide an effective means of capturing rhizosphere organic compounds in situ, but the low concentrations of sorbed compounds may limit their utility.