Abstract
BackgroundAnaerobic polycyclic hydrocarbon (PAH) degradation coupled to sulfate reduction may be an important mechanism for in situ remediation of contaminated sediments. Steps involved in the anaerobic degradation of 2-methylnaphthalene have been described in the sulfate reducing strains NaphS3, NaphS6 and N47. Evidence from N47 suggests that naphthalene degradation involves 2-methylnaphthalene as an intermediate, whereas evidence in NaphS2, NaphS3 and NaphS6 suggests a mechanism for naphthalene degradation that does not involve 2-methylnaphthalene. To further characterize pathways involved in naphthalene degradation in NaphS2, the draft genome was sequenced, and gene and protein expression examined.ResultsDraft genome sequencing, gene expression analysis, and proteomic analysis revealed that NaphS2 degrades naphthoyl-CoA in a manner analogous to benzoyl-CoA degradation. Genes including the previously characterized NmsA, thought to encode an enzyme necessary for 2-methylnaphthalene metabolism, were not upregulated during growth of NaphS2 on naphthalene, nor were the corresponding protein products. NaphS2 may possess a non-classical dearomatizing enzyme for benzoate degradation, similar to one previously characterized in Geobacter metallireducens. Identification of genes involved in toluene degradation in NaphS2 led us to determine that NaphS2 degrades toluene, a previously unreported capacity. The genome sequence also suggests that NaphS2 may degrade other monoaromatic compounds.ConclusionThis study demonstrates that steps leading to the degradation of 2-naphthoyl-CoA are conserved between NaphS2 and N47, however while NaphS2 possesses the capacity to degrade 2-methylnaphthalene, naphthalene degradation likely does not proceed via 2-methylnaphthalene. Instead, carboxylation or another form of activation may serve as the first step in naphthalene degradation. Degradation of toluene and 2-methylnaphthalene, and the presence of at least one bss-like and bbs-like gene cluster in this organism, suggests that NaphS2 degrades both compounds via parallel mechanisms. Elucidation of the key genes necessary for anaerobic naphthalene degradation may provide the ability to track naphthalene degradation through in situ transcript monitoring.
Highlights
Anaerobic microbial oxidation of polycyclic aromatic hydrocarbons (PAHs) coupled to the reduction of sulfate can be an important mechanism for the removal of PAHs from contaminated marine sediments [1,2]
Documenting the activity of anaerobic PAH-degrading microorganisms in contaminated marine sediments can be problematic For example, anaerobic oxidation of PAHs in sediments can be documented as the production of 14CO2 from [14C]-labeled PAHs [1,4,5,6]
Our results suggest that while NaphS2 has the capacity to degrade 2-methylnaphthalene, consistent with previous studies and the presence of nmsABC and bnsA-H in the NaphS2 genome, the pathway for 2-methylnaphthalene degradation does not appear to be active during NaphS2 growth on naphthalene
Summary
Anaerobic microbial oxidation of polycyclic aromatic hydrocarbons (PAHs) coupled to the reduction of sulfate can be an important mechanism for the removal of PAHs from contaminated marine sediments [1,2]. It is possible to estimate rates of PAH degradation in long-term sediment incubations in which the loss of the PAHs from the sediments is documented over time[2]. Does this approach require a high level of analytical precision, but it may take years to accurately determine whether PAHs are being degraded. Anaerobic polycyclic hydrocarbon (PAH) degradation coupled to sulfate reduction may be an important mechanism for in situ remediation of contaminated sediments. To further characterize pathways involved in naphthalene degradation in NaphS2, the draft genome was sequenced, and gene and protein expression examined
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