Although metals are thought to inhibit the ability of microorganisms to degrade organic pollutants, several microbial mechanisms of resistance to metal are known to exist. This study examined the potential of cadmium-resistant microorganisms to reduce soluble cadmium levels to enhance degradation of 2,4-dichlorophenoxyacetic acid (2,4-D) under conditions of cocontamination. Four cadmium-resistant soil microorganisms were examined in this study. Resistant up to a cadmium concentration of 275 g ml ؊1 , these isolates represented the common soil genera Arthrobacter, Bacillus, and Pseudomonas. Isolates Pseudomonas sp. strain H1 and Bacillus sp. strain H9 had a plasmid-dependent intracellular mechanism of cadmium detoxification, reducing soluble cadmium levels by 36%. Isolates Arthrobacter strain D9 and Pseudomonas strain I1a both produced an extracellular polymer layer that bound and reduced soluble cadmium levels by 22 and 11%, respectively. Although none of the cadmium-resistant isolates could degrade 2,4-D, results of dual-bioaugmentation studies conducted with both pure culture and laboratory soil microcosms showed that each of four cadmium-resistant isolates supported the degradation of 500-g ml Cocontaminated soils, soils contaminated with both metals and organics, are considered difficult to remediate because of the mixed nature of the contaminants. A treatment alternative to expensive excavation and incineration (9) of metal-contaminated soils is bioaugmentation with metal-detoxifying and/or organic-degrading microorganisms (1,3,4,6,18). Many microorganisms are known to degrade a variety of organics, and likewise, a number of metal-resistant microorganisms are known to detoxify metals, such as selenium, mercury, and cadmium (23,27). In cocontaminated sites, metal toxicity inhibits the activity of organic-degrading microorganisms (24). Consequently, bioremediation efforts focus on reducing metal toxicity in sites with mixed contaminants. Until recently, bioaugmentation studies focused on the introduction of a microorganism that was both metal resistant and capable of organic degradation. Under field conditions, such an approach is often unsuccessful. One reason may be that the energy requirements to maintain concurrent metal resistance and organic degradation are too high, and the introduced organism cannot perform both activities under environmental conditions. The issue of cocontamination is a serious one, since approximately 37% of all contaminated sites in the United States alone contain both metal and organic contaminants (20; W. W. Kovalich, Jr., keynote lecture, 4th World Congr. Chem. Eng., p. 281-295, 1991).The approach used in this study was to coinoculate with a metal-detoxifying population and an organic-degrading population that cooperatively functioned to remediate both metal and organic pollutants in a cocontaminated system. We hypothesized that the metal-resistant population could protect the metal-sensitive organic-degrading population from metal toxicity. Stephen et al. (27) used metal-resis...
