Bioremediation Strategies Aimed at Stimulating ... - ACS Publications

Jul 25, 2018 - Bioremediation Strategies Aimed at Stimulating Chlorinated Solvent Dehalogenation Can Lead to Microbially-Mediated Toluene Biogenesis...
0 downloads 0 Views 733KB Size
Subscriber access provided by University of South Dakota

Remediation and Control Technologies

Bioremediation Strategies Aimed at Stimulating Chlorinated Solvent Dehalogenation can Lead to Microbially-Mediated Toluene Biogenesis William M Moe, Samuel J Reynolds, M Aaron Griffin, and J Bryan McReynolds Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.8b02081 • Publication Date (Web): 25 Jul 2018 Downloaded from http://pubs.acs.org on July 26, 2018

Just Accepted “Just Accepted” manuscripts have been peer-reviewed and accepted for publication. They are posted online prior to technical editing, formatting for publication and author proofing. The American Chemical Society provides “Just Accepted” as a service to the research community to expedite the dissemination of scientific material as soon as possible after acceptance. “Just Accepted” manuscripts appear in full in PDF format accompanied by an HTML abstract. “Just Accepted” manuscripts have been fully peer reviewed, but should not be considered the official version of record. They are citable by the Digital Object Identifier (DOI®). “Just Accepted” is an optional service offered to authors. Therefore, the “Just Accepted” Web site may not include all articles that will be published in the journal. After a manuscript is technically edited and formatted, it will be removed from the “Just Accepted” Web site and published as an ASAP article. Note that technical editing may introduce minor changes to the manuscript text and/or graphics which could affect content, and all legal disclaimers and ethical guidelines that apply to the journal pertain. ACS cannot be held responsible for errors or consequences arising from the use of information contained in these “Just Accepted” manuscripts.

is published by the American Chemical Society. 1155 Sixteenth Street N.W., Washington, DC 20036 Published by American Chemical Society. Copyright © American Chemical Society. However, no copyright claim is made to original U.S. Government works, or works produced by employees of any Commonwealth realm Crown government in the course of their duties.

Page 1 of 35

Environmental Science & Technology

1

Bioremediation Strategies Aimed at Stimulating

2

Chlorinated Solvent Dehalogenation can Lead to

3

Microbially-Mediated Toluene Biogenesis

4

William M. Moe*,†, Samuel J. Reynolds†, M. Aaron Griffin†, J. Bryan McReynolds‡

5



Louisiana State University, Department of Civil and Environmental Engineering, Baton Rouge, LA 70803, USA

6

7

8 9



Dayspring Group, LLC, Baton Rouge, LA 70808, USA

AUTHOR INFORMATION *Corresponding Author

10 11

Address: Department of Civil and Environmental Engineering, Louisiana State University, 3255 Patrick F. Taylor Hall, Baton Rouge, LA 70803

12

E-mail: [email protected]; Telephone: +1-225-578-9174

1 ACS Paragon Plus Environment

Environmental Science & Technology

Page 2 of 35

13

ABSTRACT

14

In situ bioremediation practices that include subsurface addition of fermentable electron donors

15

to stimulate reductive dechlorination by anaerobic bacteria have become widely employed to

16

combat chlorinated solvent contamination in groundwater. At a contaminated site located near

17

Baton Rouge, Louisiana (USA), toluene was transiently observed in groundwater at

18

concentrations that sometimes far exceeded the US drinking water maximum contaminant level

19

(MCL) of 1 mg/L after a fermentable substrate (agricultural feed grade cane molasses) was

20

injected into the subsurface with the intent of providing electron donors for reductive

21

dechlorination. Here, we present data that demonstrate that indigenous microorganisms can

22

biologically produce toluene by converting phenylacetic acid, phenylalanine, phenyllactate, and

23

phenylpyruvate to toluene. When grown in defined medium with phenylacetic acid at

24

concentrations ≤350 mg/L, the molar ratio between toluene accumulated and phenylacetic acid

25

supplied was highly correlated (R2>0.96) with a toluene yield exceeding 0.9:1. Experiments

26

conducted using

27

resulted in production of toluene-α-13C, confirming that toluene was synthesized from these

28

precursors by two independently developed enrichment cultures. Results presented here suggest

29

that monitoring of aromatic hydrocarbons in warranted during enhanced bioremediation

30

activities where electron donors are introduced to stimulate anaerobic biotransformation of

31

chlorinated solvents.

13

C labelled compounds (phenylacetic acid-2-13C and L-phenylalanine-3-13C)

2 ACS Paragon Plus Environment

Page 3 of 35

32

Environmental Science & Technology

GRAPHIC FOR TABLE OF CONTENTS/ABSTRACT ART

13

Phenylacetic acid-2- C

13

L-Phenylalanine-3- C

13

Toluene-α- C

3 ACS Paragon Plus Environment

Environmental Science & Technology

Page 4 of 35

33

INTRODUCTION

34

Chlorinated alkanes (e.g., 1,2-dichloroethane and 1,2-dichloropropane) and alkenes (e.g.,

35

trichloroethene and vinyl chloride) are widespread soil and groundwater pollutants that pose a

36

risk to human health on account of their toxicity and/or carcinogenicity.1 Fortunately, some

37

bacterial genera possess the metabolic capacity to reductively dehalogenate chlorinated aliphatic

38

hydrocarbons into environmentally benign final products. For example, Dehalococcoides

39

mccartyi strains are able to transform the carcinogen vinyl chloride into ethene.2,3 Similarly,

40

representatives from the genus Dehalogenimonas are able to dehalogenate 1,2-dichloroethane to

41

ethene and 1,2-dichloropropane to propene.4-6 Because the chlorinated compounds serve as

42

electron acceptors for organohalide respiring bacteria, a suitable electron donor must be available

43

for both Dehalococcoides and Dehalogenimonas to transform the chlorinated substrates. The

44

number of electron donors that may be utilized by some dechlorinating genera are quite limited,

45

with H2 the only known electron donor for Dehalococcoides3 and H2 or formate the only known

46

electron donors utilized by Dehalogenimonas.6

47

A technique that has become widely implemented in recent years to enhance in-situ

48

biotransformation of chlorinated compounds is to inject a fermentable substrate (e.g., sugars,

49

lactate, molasses, emulsified vegetable oil, or poly-lactate esters) into the subsurface so that

50

indigenous microbial populations can produce electron donors (e.g., H2) that can be utilized by

51

dechlorinating bacteria.7-10 Fermentative bacteria able to produce H2 from various substrates

52

include a variety of Clostridium species11 and other taxa12 that appear to be ubiquitous in the

53

environment.13

54

While bioremediation strategies involving electron donor additions have proven

55

successful for chlorinated solvent remediation at many sites around the world, here we report on

56

a potential unintended consequence of electron donor addition, the biologically mediated in-situ 4 ACS Paragon Plus Environment

Page 5 of 35

Environmental Science & Technology

57

production of the aromatic hydrocarbon toluene, a pollutant conventionally thought to be

58

associated with anthropogenic pollution sources. Data reported include a combination of field

59

observations of toluene concentrations over a four year period as well as laboratory studies

60

conducted to identify precursors that have the potential to form toluene.

61

MATERIALS AND METHODS

62

Field site and microcosm studies. Field monitoring was conducted at a Superfund Site located

63

in southeast Louisiana (USA) where groundwater is contaminated with a variety of chlorinated

64

alkanes (e.g., 1,2-dichloroethane and 1,2-dichloropropane) and alkenes (e.g., tetrachloroethene,

65

vinyl chloride). In 2012, a series of groundwater wells (selected well locations provided in

66

Supporting Information Table S1) was installed to allow the subsurface injection of amendments

67

intended to facilitate establishment of anaerobic conditions and stimulate the biologically

68

mediated reductive dechlorination of halogenated aliphatic compounds near the leading edge of

69

the site’s contaminated groundwater plume. The subsurface injection of molasses in the study

70

area was accomplished by pumping groundwater from adjacent wells, metering in agricultural

71

feed grade cane molasses and in some cases bicarbonate buffer (injection quantities for selected

72

wells shown in Supporting Information Table S2), and then re-injecting the amended

73

groundwater. In the area reported on here, molasses amended groundwater was injected into each

74

well on four separate occasions spaced at roughly one year intervals.

75

Groundwater sampling was conducted prior to and after molasses addition to quantify

76

groundwater concentrations of both contaminants and geochemical parameters. Concentrations

77

of volatile organic compounds were measured via gas chromatography mass spectrometry (GC-

78

MS) using EPA method 8260B. Dissolved ethene, ethane and methane were measured using

79

method RSK 175. Nitrate and nitrite were measured using US EPA method 353.2. Chloride was 5 ACS Paragon Plus Environment

Environmental Science & Technology

Page 6 of 35

80

measured using US EPA method 325.2. Sulfate was measured by ion chromatography using US

81

EPA method 300.0. Sulfide was measured using US EPA method 376.2. Ferrous iron was

82

measured using US EPA method 3500-Fe D. Total organic carbon (TOC) was measured using

83

US EPA method 5310B. Detailed descriptions of the US EPA analytical methods referenced

84

above are available elsewhere (National Environmental Index, http://www.nemi.gov/).

85

Groundwater temperature, conductivity, turbidity, pH, and ORP were measured at the time of

86

collection using probes and flow cell (In-Situ).

87

A groundwater microcosm study was conducted using groundwater sampled from well

88

ID SP024 70 days after the third subsurface injection of molasses in that well. For microcosms,

89

groundwater was collected in sterile glass bottles filled leaving little or no gas headspace. After

90

transport to the laboratory (approximately one hour), groundwater samples were transferred into

91

an anaerobic chamber (Coy Laboratory Products), and 100 mL aliquots of groundwater were

92

aseptically dispensed into sterile 160 mL glass serum bottles (Wheaton) that were capped with

93

butyl rubber stoppers and aluminum crimp caps with no additional media supplements. Bottles

94

were incubated in the dark, without mixing, at ambient laboratory temperature (21±2˚C),

95

comparable to the 20.9°C site groundwater temperature on the day of collection (Table S4). At

96

weekly intervals, samples from duplicate bottles were analyzed by gas chromatography to

97

quantify toluene. Following analysis, microcosm replicates were stored at 4°C.

98

Enrichment cultures. Two separate enrichment cultures were developed from groundwater

99

collected from different wells on different dates. Groundwater sample locations (Supporting

100

Information Table S1), contaminant concentrations (Supporting Information Table S3), and

101

various geochemical concentrations at the time of initial groundwater sample collection

102

(Supporting Information Table S4) are provided in Supporting Information. The enrichment

6 ACS Paragon Plus Environment

Page 7 of 35

Environmental Science & Technology

103

cultures were prepared using strictly anaerobic protocols and aseptic techniques. All cultures

104

were incubated at ambient laboratory temperature (21±2 °C) in the dark without mixing.

105

The first enrichment culture, designated as AG, was established by propagating the

106

microbial population from microcosms described above that were established using groundwater

107

sampled from well ID SP024. Following storage at 4°C, the culture grown with only

108

groundwater was subsequently inoculated (5% v/v) into anoxic TP medium14 but without

109

Na2S·9H2O, phenylalanine added to a final concentration of 132 mg/L, and glucose added to a

110

final concentration of 2.0 g/L. After incubation at ambient laboratory temperature for 6 weeks,

111

the culture was subsequently transferred into anoxic modified TP medium prepared as described

112

by Zargar et al.15 but with phenylacetic acid omitted and phenylalanine added to a concentration

113

of 220 mg/L. The culture was serially transferred (0.1-5%, v/v) using sterile, disposable syringes

114

and needles at 3-8 week intervals in the same medium but with either phenylalanine or

115

phenylacetic acid supplied at concentrations in the range of 27 to 800 mg/L.

116

A second enrichment culture, designated as SR, was established by inoculating

117

groundwater (4% v/v) sampled from well ID SP022 at a time 222 days after the fourth injection

118

of molasses-amended groundwater into anoxic modified TP medium as described previously15

119

but with phenylacetic acid added to a final concentration of 350 mg/L, pH 7.6. The culture was

120

serially transferred (0.1-10%, v/v) a total of 11 times at 2-8 week intervals in the same medium.

121

Toluene production by enrichment cultures. To investigate the relationship between toluene

122

production and the amount of phenylacetic acid supplied to the enrichment cultures as a potential

123

precursor, we tested cultures supplied with phenylacetic acid (Aldrich P16621, 99% purity) over

124

the concentration range of 0 to 800 mg/L. 25 mL glass serum bottles containing 15 mL liquid

125

medium, sealed with PTFE-lined butyl rubber stoppers and aluminum crimp caps, were

7 ACS Paragon Plus Environment

Environmental Science & Technology

Page 8 of 35

126

inoculated (0.1% v/v) with one of the two enrichment cultures (AG or SR). Serum bottles

127

prepared with identical medium but without microbial inoculation served as abiotic negative

128

controls. Bottles without phenylacetic acid addition but with microbial inoculation served as

129

additional controls. For serum bottles containing 350 and 700 mg/L phenylacetic acid, triplicate

130

bottles were sacrificed at regular (~3 day) intervals over an incubation period lasting 30 days.

131

For other concentrations, triplicate bottles were sacrificed at a single time step after 30 days

132

incubation.

133

To further assess whether the enrichment cultures were able to transform phenylacetic 13

134

acid to toluene, modified TP medium was prepared as described above but with

C-labelled

135

phenylacetic acid (phenylacetic acid-2-13C, Aldrich 293849, 99 atom% 13C) replacing the regular

136

(i.e., unlabeled) phenylacetic acid. The phenylacetic acid-2-13C was added to a final

137

concentration of 250 mg/L. Replicate glass serum bottles sealed with PTFE-lined butyl rubber

138

stoppers and aluminum crimp caps were inoculated 0.1% v/v with culture SR or AG. Abiotic

139

negative controls were prepared in exactly the same manner but without inoculation. Triplicate

140

bottles were sacrificed after 45 days incubation for analysis via GC-MS. Toluene-α-13C (Aldrich

141

487082, 99 atom % 13C) dissolved in deionized water was included as a standard.

142

Experiments conducted to investigate whether additional phenyl-containing compounds

143

could serve as precursors for toluene production were conducted in 25 mL glass serum bottles

144

containing 15 mL liquid medium, sealed with PTFE-lined butyl rubber stoppers and aluminum

145

crimp caps. Bottles were inoculated (0.1% v/v) with one of the two enrichment cultures (AG or

146

SR). L-Phenylalanine (Sigma P5482, assay 98.5-101.0%) was added to reach final aqueous-

147

phase concentrations of 350 mg/L while sodium phenylpyruvate (≥95%, Aldrich P8001),

148

phenylacetaldehyde (≥95%, Aldrich W287407), and L-(−)-3-phenyllactic acid (98%, Aldrich

8 ACS Paragon Plus Environment

Page 9 of 35

Environmental Science & Technology

149

113069) were added to reach final aqueous-phase concentrations of 250 mg/L. Serum bottles

150

prepared with identical medium but without microbial inoculation served as abiotic negative

151

controls. Triplicate bottles were analyzed for toluene after incubation for 35-37 days. Bottles not

152

exhibiting appreciable toluene accumulation were further incubated and reanalyzed at t=70 days.

153

To fully confirm whether the enrichment cultures were able to transform phenylalanine to

154

toluene, experiments described above were repeated but with 13C labelled L-phenylalanine -β-13C

155

(Aldrich 490121, 99 atom%

156

ambient laboratory temperature for 35 days prior to analysis by GC-MS.

13

C) added to a concentration of 250 mg/L. Incubation was at

157

For routine analyses, aqueous-phase toluene concentrations in laboratory enrichment

158

cultures were measured using an Agilent Model 7820A Gas Chromatograph (GC) equipped with

159

a flame ionization detector (FID) and a DB-624 capillary column (60 m × 0.32 mm × 1.80 µm).

160

The GC thermal program included a five minute hold at 40°C, a 20°C/minute ramp to 260°C,

161

and a 3-minute hold at 260°C. Aqueous-phase samples were introduced to the GC utilizing a

162

Teledyne Tekmar AQUATek 100 autosampler in conjunction with a Teledyne Tekmar Purge and

163

Trap. A subset of laboratory enrichment culture samples (n=13) were additionally analyzed via

164

gas chromatography (GC) with mass spectrometry (MS) detection following EPA Method

165

8260B using an Agilent model 6890N GC equipped with an Agilent 5975B detector and an Rtx-

166

VMS fused silica column (30 m × 0.25 mm, Restek). Triplicate bottles from both cultures

167

amended with

168

temperatures were monitored using Traceable digital thermometers (Fisher Scientific).

13

C-labelled precursors were analyzed by GC-MS. Laboratory incubation

169

To facilitate mass balance calculations, the amount of toluene per serum bottle was

170

calculated using experimentally measured aqueous-phase toluene concentrations in conjunction

9 ACS Paragon Plus Environment

Environmental Science & Technology

Page 10 of 35

171

with an assumed toluene dimensionless Henry’s Law Constant of 0.209 [=0.00506

172

atm·m3/mol].16

173

Molasses analysis. Molasses from two bulk distributors of agricultural feed grade molasses

174

(Table S6) were analyzed to determine total phenylalanine content (free amino acid +

175

phenylalanine incorporated into proteins). Molasses aliquots were hydrolyzed in 6 N HCl for 24

176

hours at 110 °C with N2 as the gas headspace, dried under vacuum, reconstituted in ultrapure

177

water, and amino acids were quantified by reversed-phase HPLC with fluorescence detection

178

after pre-column derivatization of with 6-aminoquinolyl-N-hydroxysuccinimidyl carbamate

179

(AQC) as described previously.17 Analysis employed AccQ-Tag chemistry (Waters) in

180

conjunction with a Breeze 2 HPLC System equipped with a binary HPLC pump, a model 2475

181

multi-λ fluorescence detector and a model 717plus autosampler injector (Waters). To determine

182

the concentrations of phenyl-containing organic acids, aliquots of molasses were added to

183

deionized water at a final concentration of 10 g/L, mixed on a magnetic stir plate for two hours,

184

centrifuged (10 min, 10,000×g), and supernatants were analyzed via ion chromatography (IC) as

185

described previously18 but with phenylacetic acid (Aldrich P16621, 99% purity), L-(−)-3-

186

phenyllactic acid (98%, Aldrich 113069), and sodium phenylpyruvate (≥95%, Aldrich P8001)

187

dissolved in deionized water as standards.

188

RESULTS AND DISCUSSION

189

Field-scale Observations and Microcosms. Prior to the first injection of molasses and

190

bicarbonate buffer at the field site, groundwater collected from the two groundwater wells

191

reported on here (SP022 and SP024) was moderately acidic (pH 5.5-6.0), aerobic (dissolved

192

oxygen approximately 3 mg/L), contained low alkalinity (61-73 mg/L as CaCO3), moderate

193

levels of sulfate (25.9 to 30.3 mg/L), and low TOC (