Unculturable polycyclic aromatic hydrocarbon (PAH)-degrading bacteria are a significant reservoir of the microbial potential to catabolize low-molecular-weight PAHs. The population of these bacteria is larger than the population of nah-like bacteria that are the dominant organisms in culture-based studies. We used the recently described phn genes of Burkholderia sp. strain RP007, which feature only rarely in culture-based studies, as an alternative genotype for naphthalene and phenanthrene degradation and compared this genotype with the genotypically distinct but ubiquitous nah-like class in different soils. Competitive PCR quantification of phnAc and nahAc, which encode the iron sulfur protein large (␣) subunits of PAH dioxygenases in nah-like and phn catabolic operons, revealed that the phn genotype can have a greater ecological significance than the nah-like genotype.It could mistakenly be inferred from available nucleotide sequence data that highly conserved nah-like gene clusters, which are isolated from polycyclic aromatic hydrocarbon (PAH)-degrading pseudomonads obtained from diverse geographic areas, are the dominant gene clusters involved in degradation of the low-molecular-weight PAHs naphthalene and phenanthrene. The results of probing and PCR amplification of nah sequences from contaminated soils and sediments also indicate that these sequences are ubiquitous (7,17). Although PAH degraders with nah genotypes are easily isolated, it has been acknowledged that the nah catabolic cluster and closely related homologues may be present in only a small part of the PAH-degrading bacterial population (1,4,12,20). Recently, the phn genes of Burkholderia sp. strain RP007 provided evidence that there is a different genotype that exhibits a low level of sequence homology with nah and has a different gene order yet encodes enzymes for an identical PAH degradation pathway (9, 10).As increasingly diverse genes that encode enzymes for PAH catabolism are characterized (4-6, 14, 20), it is important not only to understand the function of these genes but also to determine their ecological significance in the context of environmental pollution. The objective of this study was, therefore, to compare the prevalence in aromatic hydrocarbon-contaminated soils of two distinct PAH catabolic genotypes. These genotypes were the divergent phn genes (9, 10), which are difficult to isolate by conventional microbiological methods (12), and the easily isolated nah-like genes (1,7,17). It has been shown that culture-based methods overemphasize nahlike genes and fail to detect bacteria with phn genotypes in contaminated soils in which both nahAc and phnAc are detected by PCR amplification and DNA hybridization (12). A molecular biological approach was required to overcome the disparity in the ease of culturing of host bacteria harboring these two genotypes. Highly specific primer combinations, which targeted genes that encode the iron sulfur protein large (␣) subunits of the nah-like and phn PAH initial dioxygenases, allowed us to deter...
