Fluorescent pseudomonas isolates from Mississippi Delta oxbow lakes: In vitro herbicide biotransformations

Fluorescent pseudomonads were a major component [log (10) 4.2–6.1 colony‐forming units mL−1] of the culturable heterotrophic gram‐negative bacterioplankton observed in three Mississippi Delta oxbow lakes in this study. Pure cultures of fluorescent pseudomonads were isolated from three Mississippi Delta oxbow lakes (18 per lake), using selective media S‐1. Classical physiological tests and Biolog GN plates were used in criteria for taxonomic identification. Most isolates were identified as biotypes of Pseudomonas fluorescens 55% (II), 7% (III), and 25% (V). About 7% of the isolates were identified as P. putida and 7% as non‐fluorescent Pseudomonas‐like. Cell suspensions of these isolates were tested for their ability to metabolize/co‐metabolize six 14C‐radiolabeled herbicides (2,4‐dichlorophenoxyacetic acid (2,4‐D), cyanazine, fluometuron, metolachlor, propanil, and trifluralin) that are commonly used for crop production in this geographical area. Almost all (53 of 54) isolates transformed trifluralin via aromatic nitroreduction. Most isolates (70%) dechlorinated metolachlor to polar metabolites via glutathione conjugation. About 60% of the isolates hydrolyzed the amide bond of propanil (a rice herbicide) to dichloroaniline, with the highest frequency of propanil‐hydrolyzing isolates observed in the lake from the watershed with rice cultivation. All propanil‐hydrolyzing isolates were identified as P. fluorescens biotype II. No metabolism of cyanazine or fluometuron was observed by any isolates tested, indicating little or no potential for N‐dealkylation among this group of bacterioplankton. No mineralization of 2,4‐D labeled in either the carboxyl or ring position was observed. These results indicate that reductive and hydrolytic pathways for herbicide co‐metabolism (aromatic nitroreduction, aryl acylamidase, and glutathione conjugation) are common in Mississippi Delta aquatic fluorescent pseudomonads; however, the potential for certain oxidative transformations (N‐dealkylation, cyano group oxidation) may be rare in this group of bacterioplankton. © 2001 John Wiley & Sons, Inc. Environ Toxicol 16: 9–19, 2001