Ubiquity and Diversity of Dissimilatory (Per)chlorate-Reducing Bacteria

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Applied and Environmental Microbiology, December 1999, p. 5234-5241, Vol. 65, No. 12
0099-2240/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

Ubiquity and Diversity of Dissimilatory (Per)chlorate-Reducing Bacteria

John D. Coates,^* Urania Michaelidou, Royce A. Bruce, Susan M. O'Connor, Jill N. Crespi, and Laurie A. Achenbach

Department of Microbiology and Center for Systematic Biology, Southern Illinois University, Carbondale, Illinois 62901

Received 25 June 1999/Accepted 8 September 1999

Environmental contamination with compounds containing oxyanions of chlorine, such as perchlorate or chlorate [(per)chlorate]or chlorine dioxide, has been a constantly growing problem overthe last 100 years. Although the fact that microbes reduce thesecompounds has been recognized for more than 50 years, only sixorganisms which can obtain energy for growth by this metabolicprocess have been described. As part of a study to investigatethe diversity and ubiquity of microorganisms involved in the microbialreduction of (per)chlorate, we enumerated the (per)chlorate-reducingbacteria (ClRB) in very diverse environments, including pristineand hydrocarbon-contaminated soils, aquatic sediments, paper millwaste sludges, and farm animal waste lagoons. In all of the environmentstested, the acetate-oxidizing ClRB represented a significant population,whose size ranged from 2.31 × 10³ to 2.4 × 10⁶ cells per g of sample. In addition, we isolated 13 ClRB fromthese environments. All of these organisms could grow anaerobicallyby coupling complete oxidation of acetate to reduction of (per)chlorate.Chloride was the sole end product of this reductive metabolism.All of the isolates could also use oxygen as a sole electron acceptor,and most, but not all, could use nitrate. The alternative electrondonors included simple volatile fatty acids, such as propionate,butyrate, or valerate, as well as simple organic acids, such aslactate or pyruvate. Oxidized-minus-reduced difference spectraof washed whole-cell suspensions of the isolates had absorbancemaxima close to 425, 525, and 550 nm, which are characteristicof type c cytochromes. In addition, washed cell suspensions ofall of the ClRB isolates could dismutate chlorite, an intermediatein the reductive metabolism of (per)chlorate, into chloride andmolecular oxygen. Chlorite dismutation was a result of the activityof a single enzyme which in pure form had a specific activityof approximately 1,928 µmol of chlorite per mg of protein permin. Analyses of the 16S ribosomal DNA sequences of the organismsindicated that they all belonged to the alpha, beta, or gammasubclass of the Proteobacteria. Several were closely related tomembers of previously described genera that are not recognizedfor the ability to reduce (per)chlorate, such as the genera Pseudomonasand Azospirllum. However, many were not closely related to anypreviously described organism and represented new genera withinthe Proteobacteria. The results of this study significantly increasethe limited number of microbial isolates that are known to becapable of dissimilatory (per)chlorate reduction and demonstratethe hitherto unrecognized phylogenetic diversity and ubiquityof the microorganisms that exhibit this type ofmetabolism.

^* Corresponding author. Mailing address: Department of Microbiology and Center for Systematic Biology, Southern Illinois University,Carbondale, IL 62901. Phone: (618) 453-6132. Fax: (618) 453-8036.E-mail: jcoates{at}micro.siu.edu.

Applied and Environmental Microbiology, December 1999, p. 5234-5241, Vol. 65, No. 12
0099-2240/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.

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