TY - JOUR
T1 - Molecular diagnostics of polycyclic aromatic hydrocarbon biodegradation in manufactured gas plant soils
AU - Sanseverino, J.
AU - Werner, C.
AU - Fleming, J.
AU - Applegate, B.
AU - King, J. M.H.
AU - Sayler, G. S.
PY - 1993/12
Y1 - 1993/12
N2 - Traditional methods for quantifying specific catabolic bacterial populations underestimate the true population count due to the limitations of the necessary laboratory cultivation methods. Likewise, in situ activity is also difficult to assess in the laboratory without altering the sample environment. To circumvent these problems and achieve a true in situ bacterial population count and activity measurement, new methods based on molecular biological analysis of bacterial nucleic acids were applied to soils heavily contaminated with polycyclic aromatic hydrocarbons (PAH). In addition, a naphthalene-lux reporter system was used to determine bioavailability of naphthalene within these soils. DNA extracted from seven PAH-contaminated soils and hybridized with the nahA gene probe indicated that the naphthalene degradative genes were present in all samples in the range of 0.06 to 0.95 ng/100 μl DNA extract which was calculated to represent 3.2×106 to 1.1×1010 cells/g soil (assuming one copy of these genes per cell).14C-naphthalene mineralization was observed in all contaminated soils with14CO2 mineralization rates ranging from 3.2×10-5 to 304,920.0×10-5 μg g soil-1h-1. Phenanthrene, anthracene, and benzo(a)pyrene were mineralized also in several soils. Messenger RNA transcripts of nahA were isolated and quantified from 4 soils. Only one soil tested, soil B, was inducible with salicylate above the in situ nahA gene transcript level. Two of the soils, C and G, were already fully induced in situ. The naphthalene mineralization rate correlated positively with the amount of nahA gene transcripts present (r=0.99). Naphthalene was bioavailable in soils A, D, E, G, and N as determined by a bioluminescent response from the naphthalene-lux reporter system. Taken together, these data provided information on what the naphthalene-degrading bacterial population was experiencing in situ and what approaches would be necessary to increase activity.
AB - Traditional methods for quantifying specific catabolic bacterial populations underestimate the true population count due to the limitations of the necessary laboratory cultivation methods. Likewise, in situ activity is also difficult to assess in the laboratory without altering the sample environment. To circumvent these problems and achieve a true in situ bacterial population count and activity measurement, new methods based on molecular biological analysis of bacterial nucleic acids were applied to soils heavily contaminated with polycyclic aromatic hydrocarbons (PAH). In addition, a naphthalene-lux reporter system was used to determine bioavailability of naphthalene within these soils. DNA extracted from seven PAH-contaminated soils and hybridized with the nahA gene probe indicated that the naphthalene degradative genes were present in all samples in the range of 0.06 to 0.95 ng/100 μl DNA extract which was calculated to represent 3.2×106 to 1.1×1010 cells/g soil (assuming one copy of these genes per cell).14C-naphthalene mineralization was observed in all contaminated soils with14CO2 mineralization rates ranging from 3.2×10-5 to 304,920.0×10-5 μg g soil-1h-1. Phenanthrene, anthracene, and benzo(a)pyrene were mineralized also in several soils. Messenger RNA transcripts of nahA were isolated and quantified from 4 soils. Only one soil tested, soil B, was inducible with salicylate above the in situ nahA gene transcript level. Two of the soils, C and G, were already fully induced in situ. The naphthalene mineralization rate correlated positively with the amount of nahA gene transcripts present (r=0.99). Naphthalene was bioavailable in soils A, D, E, G, and N as determined by a bioluminescent response from the naphthalene-lux reporter system. Taken together, these data provided information on what the naphthalene-degrading bacterial population was experiencing in situ and what approaches would be necessary to increase activity.
KW - bioavailability
KW - bioluminescence
KW - gene probe
KW - in situ microbial analysis
KW - mRNA
KW - polynuclear aromatic hydrocarbons
UR - http://www.scopus.com/inward/record.url?scp=0027133938&partnerID=8YFLogxK
U2 - 10.1007/BF00695976
DO - 10.1007/BF00695976
M3 - Article
C2 - 7516749
AN - SCOPUS:0027133938
SN - 0923-9820
VL - 4
SP - 303
EP - 321
JO - Biodegradation
JF - Biodegradation
IS - 4
ER -