Transformations of chloroguaiacols, chloroveratroles, and chlorocatechols by stable consortia of anaerobic bacteria

Neilson, Alasdair H.; Allard, Ann‐Sofie; Lindgren, Carin; Remberger, Mikael

doi:10.1128/aem.53.10.2511-2519.1987

Cited by 56 publications

(43 citation statements)

References 53 publications

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“…(b) The more highly chlorinated congeners appear generally to be more readily dechlorinatcd which is consistent with the hypothesis that dechlorination is an energy-producing reaction coupled to metabolism of the substrate (Dolfing 1990;Mohn & Tiedje 1990). The corresponding reactions with the bromo analogues have not been systematically investigated, although debromination was one of a series of reactions observed during the metabolism of Sbromovanillin-but not 5-chlorovanillin-by stable anaerobic consortia (Neilson et a/.…”

Section: Deblogenation Of Aromatic Compounds Under Anaerobic Conditionssupporting

confidence: 73%

The biodegradation of halogenated organic compounds

Neilson¹

1990

Journal of Applied Bacteriology

105

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Section: Deblogenation Of Aromatic Compounds Under Anaerobic Conditionssupporting

confidence: 73%

The biodegradation of halogenated organic compounds

Neilson¹

1990

Journal of Applied Bacteriology

105

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“…The significant difference between estimates of recoverability based on short-term laboratory spike experiments and those based on work with naturally aged contaminated samples is readily illustrated by data from our own experiments. Previous studies using spiked sediment samples incubated in the laboratory under anaerobic conditions [21] and experiments using stable consortia have shown that, under anaerobic conditions, chloroguaiacols are rapidly de-0-methylated to chlorocatechols before dechlorination [29]. These results are in apparent conflict with the data presented here, which unequivocally show that substantial amounts of chloroguaiacols can, in fact, be recovered from natural samples of contaminated sediments.…”

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confidence: 99%

“…Reference samples of the chloroguaiacols, chlorocatechols and chlorovanillins were synthesized in this laboratory [28,29]. Quantitative analysis of all of the chloro compounds was carried out using GC analysis of the 0-acetates, as described previously [30].…”

Section: Procedures For Analysis a N D Identificationmentioning

confidence: 99%

Comparison of Procedures for Recovering Chloroguaiacols and Chlorocatechols From Contaminated Sediments

Remberger¹,

Hynning²,

Neilson³

1988

Environ Toxicol Chem

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Procedures for the extraction of chloroguaiacols and chlorocatechols from contaminated sediment samples were examined. Using one sample, a comparison was made of the following procedures: solvent extraction with water-miscible solvents, steam distillation, Soxhlet extraction with t-butyl methyl ether, and several more aggressive methods employing BF3/methanol, HBr/water and KOH/methanol. The recoveries of the chlorinated compounds were highly variable. Recovery of the chloroguaiacols by the nonaggressive procedures was generally low, but it was significantly greater using methanolic alkali. The efficacy of the latter procedure was confirmed by the data obtained with three other sediment samples. Qualitatively similar differences in recoverability were also observed when a high molecular weight alkali-stage chlorolignin was examined. Therefore it was not possible to determine whether the monomeric chlorinated compounds were bound to natural organic compounds in the sediment or to the chlorolignin, which is produced during the bleaching process. In an experiment using one sediment sample incubated under anaerobic conditions for nine months, no change occurred in the amount of extractable chloroguaiacols and there was an approximate 40% reduction in the corresponding chlorocatechols. It is therefore postulated that the binding mechanisms of the chloroguaiacols and chlorocatechols in the sediment phase are significantly different, and that an indeterminate fraction is not accessible to microbial transformation. There are, it is noted, inherent limitations to interpreting the results of experiments on binding and desorption in which xenobiotics are exposed to the sediment phase for only a short time.

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“…In the absence of molecular oxygen, the aryl halogens of homocyclic *To whom correspondence may be addressed. aromatic compounds are biologically removed by reduction [12,18].…”

Section: Introductionmentioning

confidence: 96%

Reductive dechlorination of aroclor 1242 in anaerobic sediments: Pattern, rate and concentration dependence

Rhee

Bush

Sokol

et al. 1993

Enviro Toxic and Chemistry

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Anaerobic biotransformation of polychlorinated biphenyls of Hudson River sediment microorganisms was investigated using the commercial mixture Aroclor 1242 in the laboratory at six different concentrations: 120, 300, 500, 800, 1,000, and 1,500 μg/g (on a sediment dry‐weight basis). Dechlorination was concentration dependent. No change in congener composition was found at 1,000 and 1,500 μg/g during seven months of incubation, but significant shifts were observed in sediments with concentrations below 800 μg/g. A mass balance of the transformation indicated that, despite the shifts, the total molar concentration remained the same. An optimum concentration, based on the decrease of Cl per biphenyl, was 500 μg/g, but based on Cl removed per gram sediment it had a range from 500 to 800 μg/g. Dechlorination (total Cl removed per biphenyl) at 300 and 500 μg/g appeared to be first order, with rate constants of —0.039 and —0.059 per month, respectively. The rate also varied with the substitution position; it was faster for m‐Cl, followed by p‐Cl, but no o‐Cl was removed. However, the faster rate of m‐dechlorination in Aroclor 1242 was probably due to a high concentration of congeners in the Aroclor with Cl substitution patterns favoring its removal, rather than the meta‐position itself.

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Transformations of chloroguaiacols, chloroveratroles, and chlorocatechols by stable consortia of anaerobic bacteria

Cited by 56 publications

References 53 publications

The biodegradation of halogenated organic compounds

The biodegradation of halogenated organic compounds

Comparison of Procedures for Recovering Chloroguaiacols and Chlorocatechols From Contaminated Sediments

Reductive dechlorination of aroclor 1242 in anaerobic sediments: Pattern, rate and concentration dependence

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