Page 1 of 46 ACS Paragon Plus Environment ... - ACS Publications

Information Box 1. Soil Factors Influencing the Residual Impact of Land Application. • Minimal ARBs added relative to what is already in soil (as pe...
0 downloads 9 Views 479KB Size
Subscriber access provided by UNIV OF NEW ENGLAND ARMIDALE

Characterization of Natural and Affected Environments

Antibiotic resistant bacteria in municipal wastes: Is there reason for concern? Ian Pepper, John P. Brooks, and Charles P. Gerba Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.7b04360 • Publication Date (Web): 05 Mar 2018 Downloaded from http://pubs.acs.org on March 6, 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 46

Environmental Science & Technology

338x190mm (96 x 96 DPI)

ACS Paragon Plus Environment

Environmental Science & Technology

1

Antibiotic resistant bacteria in municipal wastes: Is there reason for concern?

2

Ian L. Peppera*, John P. Brooksb, and Charles P. Gerbaa

3 4

a

5

W. Calle Agua Nueva, Tucson, AZ 85745;

6

b

Water and Energy Sustainable Technology Center (WEST), The University of Arizona, 2959

Genetics and Sustainable Agriculture Research Unit, USDA ARS, Mississippi State, MS, 39762

7 8

Corresponding author: *Ian L. Pepper

9

Water and Energy Sustainable Technology Center (WEST, The University of Arizona, 2959 W.

10

Calle Agua Nueva, Tucson, AZ 85745. E-Mail: [email protected]. Ph: (520) 626-

11

3328; Fax: 520-621-1032.

12

13

14

15

16

17

18

19

20

21 1 ACS Paragon Plus Environment

Page 2 of 46

Page 3 of 46

Environmental Science & Technology

22

Abstract

23

Recently, there has been increased concern about the presence of antibiotic resistant bacteria

24

(ARB) and antibiotic resistant genes (ARG), in treated domestic wastewaters, animal manures

25

and municipal biosolids. The concern is whether these additional sources of ARB contribute to

26

antibiotic resistance levels in the environment, i.e. “environmental antibiotic resistance.” ARB

27

and ARG occur naturally in soil and water, and it remains unclear whether the introduction of

28

ARB in liquid and solid municipal and animal wastes via land application have any significant

29

impact on the background levels of antibiotic resistance in the environment, and whether they

30

affect human exposure to ARB. In this current review, we examine and re-evaluate the incidence

31

of ARB and ARG resulting from land application activities, and offer a new perspective on the

32

threat of antibiotic resistance to public health via exposure from non-clinical environmental

33

sources. Based on inputs of ARBs and ARGs from land application, their fate in soil due to soil

34

microbial ecology principles, and background indigenous levels of ARBs and ARGs already

35

present in soil, we conclude that while antibiotic resistance levels in soil are increased temporally

36

by land application of wastes, their persistence is not guaranteed and is in fact variable, and often

37

contradictory based on application site. Furthermore, the application of wastes may not produce

38

the most direct impact of ARGs and ARB on public health. Further investigation is still

39

warranted in agriculture and public health, including continued scrutiny of antibiotic use in both

40

sectors.

41 42 43 44

2 ACS Paragon Plus Environment

Environmental Science & Technology

45

I.

46

Microorganisms naturally produce and secrete antibiotic compounds, which can inhibit the

47

growth of competing microbes in the environment.1 Due in part to their germicidal effects,

48

antibiotics are useful as therapeutic agents for the control of infectious disease in humans and

49

animals. The first and perhaps most effective antibiotic discovered was penicillin,

50

serendipitously isolated from the soil fungus Penicillium by Sir Alexander Fleming in 1929. A

51

second major antibiotic, streptomycin, was later isolated from the soil actinomycete

52

Streptomyces griseus, by the soil microbiologist Selman Waksman in 1943. Waksman received

53

the Nobel Prize for this discovery in 1952 - the only soil scientist to ever achieve such an honor.

54

These powerful antibiotics revolutionized our ability to treat infectious diseases, but not without

55

a concomitant cost.

56

RECENT CONCERNS ON ARB AND ARG

Bacteria are simple prokaryotic microbes that can metabolize and replicate very quickly,

57

resulting in remarkable genetic plasticity and adaptability. The existence of only one bacterial

58

cell with a genetic or mutational change that confers resistance to an antibiotic agent encountered

59

in the environment is sufficient for the subsequent proliferation of antibiotic resistant bacteria

60

(ARB) that contain antibiotic resistant genes (ARG). ARGs are now considered to be a class of

61

emerging contaminants.2 Thus, the more that antibiotics are used for the treatment or prevention

62

of disease, the greater the likelihood that resistant strains will occur due to the selective

63

advantages conferred by ARG. More specifically, the potential for the transfer of antibiotic

64

resistance to human pathogenic microbes that subsequently can no longer be controlled by the

65

prescribed antibiotics is of paramount concern. The conundrum then, is the more an antibiotic is

66

utilized to prevent infectious disease, the less effective it will become over time. In addition,

67

public health risks increase significantly when bacteria accumulate resistance to multiple

3 ACS Paragon Plus Environment

Page 4 of 46

Page 5 of 46

Environmental Science & Technology

68

antibiotics, making them particularly difficult to control as in the case of methicillin-resistant

69

Staphylococcus aureus (MRSA). CDC estimates of antibiotic resistant infections are a minimum

70

of 2 million3 people in the United States annually resulting in 23,000 deaths.

71

ARB and ARG are commonly detected in domestic wastewater, agricultural waste releases

72

from concentrated animal feedlot operations (CAFOs), biosolids and animal manures, hospital

73

waste discharged into sewers, and soil and water.4 The role of anthropogenic activity on the

74

incidence of ARB and ARG led to the introduction of the term “environmental antibiotic

75

resistance,”5 as well as several review articles including “The Scourge of Antibiotic Resistance;

76

The Important Role of the Environment,”6 and “Urban Wastewater Treatment Plants as Hotspots

77

for Antibiotic Resistant Bacteria and Genes Spread into the Environment: A Review”.7 In this

78

current review, we examine and re-evaluate the incidence of ARB and ARG resulting from land

79

application activities, and offer a new perspective on the threat of antibiotic resistance to public

80

health via exposure from non-clinical environmental sources.

81

Specifically we discuss the relative incidence of ARBs in different anthropogenic-impacted

82

environments relative to the naturally occurring level of incidence found in soils. Based on these

83

data, we evaluate the impact of land application of biosolids, municipal effluents and animal

84

manures on these natural levels found in soils. We also identify data gaps on pathogenic ARB

85

characteristics that need to be identified before a formal risk assessment for antibiotic resistant

86

pathogens can be performed. Overall, this review is meant to demonstrate the relative impact of

87

anthropogenic activities versus “naturally” occurring soil-borne ARBs and ARGs.

88 89

4 ACS Paragon Plus Environment

Environmental Science & Technology

90

II.

INCIDENCE OF ARBs IN THE ENVIRONMENT, FOODSTUFFS, AND CLINICAL SETTINGS

91 92

The discovery and implementation of antibiotics to aid in the fight against infectious diseases

93

was a landmark event of great significance to public health. Yet, it also marked the rise of

94

antibiotic-resistant microorganisms in health care settings, raising serious concerns as to the

95

appropriate use of antibiotics in the treatment of infectious disease. Humans are exposed to

96

millions of microbes with antibiotic resistant traits every day via natural and necessary activities

97

such as the ingestion of water and food.8,9 However, the widespread use of antibiotics in the

98

medical and agricultural industries has created an artificial selective pressure for the survival of

99

ARB in some environments. This is especially true in health care environments, where

100

antibiotics are routinely used to control the proliferation of human pathogens.10 In the clinical

101

environment, the survival and transmission of ARB and ARG is a major concern due to the

102

potential impacts on therapeutic outcomes. The importance of ARB and ARG outside of the

103

clinical environment could be determined by employing a risk assessment approach that

104

considers exposure, the nature of the pathogen, dose response, persistence in the environment,

105

and the potential for genetic exchange.11 However for many of these parameters, data are

106

lacking such that formal risk assessments do not exist. It is also important to consider the risk

107

from exposure due to the environment relative to exposure to ARB and ARG originating from

108

clinical environments.

109

A.

ARBs and ARGs in Soil, Water and Residual Waste Materials

110

In order to evaluate whether the occurrence of antibiotic resistance in the environment is actually

111

a public health risk, multiple data sets are needed. These include the background or incidence

112

concentrations of naturally-occurring ARB in the external environment where anthropogenic

5 ACS Paragon Plus Environment

Page 6 of 46

Page 7 of 46

Environmental Science & Technology

113

inputs of antibiotics are minimal or non-existent (e.g. undisturbed pristine soils), and also the

114

levels of ARB introduced into soils due to anthropogenic activities including land application of

115

biosolids, municipal effluents or animal manures. Here, antibiotic presence and ARB

116

concentrations in different environments are considered.

117

a) Soils

118

The vast majority of antibiotics are natural products synthesized by soil microorganisms.12

119

These include antibiotics effective against Gram-positive bacteria (e.g. penicillin), Gram-

120

negative bacteria (e.g. polymixin), and the broad-spectrum antibiotics that are effective against

121

both Gram-positive and -negative bacteria (e.g. chloramphenicol). These antibiotics are produced

122

by diverse populations of soil microorganisms including bacteria, fungi and actinomycetes.13

123

These natural products can be utilized by indigenous soil microbes as a form of self-defense

124

against neighboring soil microorganisms. Interestingly, the gene clusters that result in antibiotic

125

production are always present in the soil environment, but are only expressed under very specific

126

conditions, such as interactions with other microbes.14

127

Two perspectives on antibiotic resistance in soils are now well documented in the

128

literature. The first is that antibiotic resistance is an ancient microbial attribute that existed on

129

earth thousands or even billions of years before Fleming discovered the first antibiotic in 1929.

130

Adu-Oppong et al.15 state that antimicrobials have likely been naturally produced by

131

environmental microbes as a means of communication and defense for billions of years. For

132

example, daptomycin, a clinically useful lipopeptide antibiotic produced by Streptomyces

133

roseosporus may have evolved over 1 billion years ago16 Relatively more recently, D’Costa et

134

al.17 concluded that analysis of Beringian permafrost sediments document that antibiotic

6 ACS Paragon Plus Environment

Environmental Science & Technology

135

resistance genes existed 30,000 years ago, showing conclusively “that antibiotic resistance is a

136

natural phenomenon that predates the modern selective pressure of clinical antibiotic use.”

137

The second documented perspective is that antibiotic resistance can be found in pristine areas

138

unimpacted by anthropogenic activities. Recently, Durso et al.18 surveyed ungrazed, native

139

prairie soil throughout Nebraska and showed ARG copy numbers ranging from ~103 to 105

140

copies/g for tetracycline and sulfonamide resistance. Rahman et al.19 documented the occurrence

141

of natural tetracycline resistance within bacteria located in marine sediments offshore of Japan.

142

Diaz et al.20 identified antibiotic resistance genes in three different habitats across a permafrost

143

thaw gradient within a pristine Arctic wetland. Taylor et al.21 found amphotericin B resistance in

144

fungal Aspergilus spp. isolated from pristine caves in Brazil. Tetracylcine-resistant bacteria and

145

resistance gene tet(M) were identified in fecal material from penguins in Antarctica.22 The

146

concept of soil as a natural source of ARBs and ARGs was endorsed by Cytryn23 who eloquently

147

stated that: “Although some evidence correlates between anthropogenic factors and elevated

148

levels of antibiotic resistance in soil, it is becoming increasingly clear that unimpacted and

149

pristine soils contain highly diverse and abundant levels of antibiotic resistant bacteria which

150

harbor a wide array of clinically associated and novel antibiotic resistant genes.”

151

The most prevalent biological entity on Earth (other than viruses) are bacteria, with recent

152

estimates of total numbers on the order of 5 x 1030, the vast majority of which are non-

153

pathogenic to humans.6 In soils, typical numbers of bacteria range from 108-1010 cells per gram.

154

If one considers a homeowner on an acre lot, then the homeowner is surrounded by ~1018 native

155

soil bacteria per acre furrow slice.

156 157

One acre furrow slice (1 acre to a depth of 6”) ≃ 2 x 106 lbs soil ≃ 9 x 108 g soil

7 ACS Paragon Plus Environment

Page 8 of 46

Page 9 of 46

Environmental Science & Technology

158

Assuming 109 bacterial cells per g soil, it follows that there are

159

109 x 9 x 108 cells per acre furrow slice

160

≃ 1018 cells per acre furrow slice

161

The numbers of intrinsic ARB within soils are also large. Such antibiotic resistance has been

162

documented in pristine natural soils even when unimpacted by anthropogenic activities.24 Studies

163

have shown that even pristine, undisturbed soils contain ARB,18 and that “environmental

164

antibiotic resistance” has been a naturally-occurring factor in nature for more than 3 billion

165

years.25,5 Culture-based estimates of ARB extracted from soils that were resistant to

166

tetracycline, ciprofloxacin, cephalothin and ampicillin ranged from 106 to 107 colony forming

167

units (CFU) per gram of soil.26 Likewise, Demaneche et al.27 demonstrated approximately 50-

168

70% of cultured bacteria (tryptic soy agar) were ampicillin resistant (~104 CFU/g) from an

169

undisturbed prairie soil. Durso et al.18 documented tetracycline- or cefotaxime-resistant

170

heterotrophic counts ranging from 104 to 105 CFU/g in undisturbed prairie soil. Bacterial human

171

pathogens have also been reported to enter a viable but non-culturable (VBNC) state.28 If the

172

culture-based estimate of 106 to 107 resistant CFU per gram of soil is assumed, then a

173

homeowner on an acre lot is surrounded by 1015 to 1016 antibiotic resistant bacteria that are

174

resistant to one or more antibiotics. Many of the culturable bacteria are resistant to multiple

175

antibiotics leading to the term: “The Soil Antibiotic Resistome.”29 Interestingly soil bacteria

176

typically contain universal mechanisms of resistance to both natural and synthetic antibiotics.30

177

In summary, every human is surrounded by extraordinarily large numbers of bacteria including

178

vast numbers that can be resistant to any known antibiotic. Bacterial communities in natural

179

environments unimpacted by anthropogenic activities also tend to be relatively stable with

180

regards to taxonomic diversity and population density,31 but the influence of antibiotic inputs on

8 ACS Paragon Plus Environment

Environmental Science & Technology

181

the indigenous soil microbial community and the ARB community has shown variable effects.

182

For example, a recent study in which streptomycin was applied to soil, demonstrated that the

183

antibiotic did not influence the abundance nor diversity of the indigenous bacterial taxa.32 In

184

contrast, others have reported localized or temporal shifts (