Combined Deterministic and Stochastic Processes Control Microbial

Apr 10, 2019 - Granular sludge is an efficient and compact biofilm process for wastewater treatment. However, the ecological factors involved in micro...
0 downloads 0 Views 2MB Size
Subscriber access provided by UNIV OF LOUISIANA

Environmental Processes

Combined deterministic and stochastic processes control microbial succession in replicate granular biofilm reactors Raquel Liébana, Oskar Modin, Frank Persson, Enikö Szabó, Malte Hermansson, and Britt-Marie Wilen Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.8b06669 • Publication Date (Web): 10 Apr 2019 Downloaded from http://pubs.acs.org on April 10, 2019

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 39

Environmental Science & Technology

1

Combined deterministic and stochastic processes control microbial succession in replicate

2

granular biofilm reactors

3

Raquel Liébana a*, Oskar Modin a, Frank Persson a, Enikö Szabó a, Malte Hermansson b and Britt-

4

Marie Wilén a

5 6

a

7

Chalmers University of Technology, Gothenburg, Sweden

8

b

9

Sweden

Division of Water Environment Technology, Department of Architecture and Civil Engineering,

Department of Chemistry and Molecular Biology, University of Gothenburg, Gothenburg,

10

*Corresponding author: Raquel Liébana; Postal address: Division of Water Environment

11

Technology, Department of Architecture and Civil Engineering, Chalmers University of

12

Technology, Sven Hultins gata 8, SE- 412 96 Gothenburg, Sweden; Telephone number: +46 031-

13

772-1912, Email address: [email protected]

14 15 16 17 1

ACS Paragon Plus Environment

Environmental Science & Technology

Page 2 of 39

18 19

ABSTRACT

20

Granular sludge is an efficient and compact biofilm process for wastewater treatment. However,

21

the ecological factors involved in microbial community assembly during the granular biofilm

22

formation are poorly understood and little is known about the reproducibility of the process.

23

Here, three replicate bioreactors were used to investigate microbial succession during the

24

formation of granular biofilms. We identified three successional phases. During the initial phase,

25

the successional turnover was high and α-diversity decreased as a result of the selection of taxa

26

adapted to grow on acetate and form aggregates. Despite these dynamic changes, the microbial

27

communities in the replicate reactors were similar. The second successional phase occurred when

28

the settling time was rapidly decreased to selectively retain granules in the reactors. The influence

29

of stochasticity on succession increased and new niches were created as granules emerged,

30

resulting in temporarily increased α-diversity. The third successional phase occurred when the

31

settling time was kept stable and granules dominated the biomass. Turnover was low and

32

selection resulted in the same abundant taxa in the reactors, but drift, which mostly affected low-

33

abundant community members, caused the community in one reactor to diverge from the other

34

two. Even so, performance was stable and similar between reactors.

35 36

2

ACS Paragon Plus Environment

Page 3 of 39

Environmental Science & Technology

37 38

TABLE OF CONTENTS (TOC)/ABSTRACT ART

39 40 41

INTRODUCTION

42

The structure of microbial communities results from complex and dynamic ecological

43

mechanisms 1, which traditionally have been grouped into deterministic and stochastic factors 2.

44

Environmental conditions, species interactions and species traits are considered deterministic 3,

45

4,

46

deterministic and stochastic factors can be framed into four fundamental processes: selection,

47

dispersal, diversification and drift

48

community structure according to the environmental conditions, differences in fitness between

49

individuals and microbial interactions. Dispersal refers to the movement and establishment of

50

microorganisms among communities, which can be both deterministic and stochastic.

51

Diversification refers mainly to stochastic factors, which generate genetic variation. Drift refers

whereas random events, such as birth and death, are considered stochastic 5. These

6, 7.

Selection refers to deterministic factors that modify the

3

ACS Paragon Plus Environment

Environmental Science & Technology

Page 4 of 39

6, 7.

52

to stochastic changes as a result of birth, death and reproduction

53

simultaneously in natural ecosystems and their influences vary in time and space 2, 7, therefore it

54

is challenging to determine their contribution to microbial community assembly. The study of the

55

biodiversity within and between microbial communities can help us to understand the underlying

56

ecological processes 7. Studying the compositional differences (turnover) between two different

57

communities (β-diversity) provides a link between biodiversity at the local scale or at

58

instantaneous sampling (within-sample or α-diversity) and at the regional scale or long time scale

59

(overall diversity or γ-diversity) 8.

60

The importance ascribed to deterministic and stochastic factors during microbial community

61

assembly in wastewater bioreactors vary. Some studies report similar microbial communities in

62

replicate reactors, such as membrane bioreactors 9, anaerobic digesters 10-12, microbial fuel cells

63

13,

64

environmental conditions. On the contrary, diverging communities and functions have been

65

reported in replicate microbial electrolysis cell reactors

66

anaerobic digesters 20, 21, due to the roles of stochastic factors.

67

Wastewater treatment bioreactors are engineered to select for functional groups needed for

68

water purification, e.g. nitrifiers, denitrifiers, and phosphate accumulating organisms. Moreover,

69

the reactor operational conditions are adjusted to cultivate the microorganisms in the desired

70

aggregate modes, either as flocs in activated sludge or as biofilms on different substrata

71

Free-floating spherical biofilms, so called granules, combine many of the properties of these two

biofilters

14, 15

and sequencing batch reactors

16, 17,

These four processes act

due to selection caused by the reactor

18,

sequencing batch reactors

19

and

22, 23.

4

ACS Paragon Plus Environment

Page 5 of 39

Environmental Science & Technology

72

growth modes. The granules are compact and spherical suspended biofilms with a diameter of

73

approximately 1-3 mm obtained at defined reactor conditions of large shear forces created by a

74

high up-flow air velocity, typically higher than 1 cm s−1, large temporal variation of electron donors

75

and -acceptors causing feast-famine operation, and short settling time to select for well settling

76

biomass 24. Granules are stratified in an aerobic outer layer and an anoxic substrate-rich interior

77

as a consequence of oxygen and substrate gradients inside the granule where heterotrophic-,

78

nitrifying-, denitrifying-, phosphorous-accumulating- and glycogen-accumulating bacteria can

79

coexist

80

simultaneously, which renders highly compact and energy efficient wastewater treatment

81

Despite the well-established methods for granule cultivation, the ecological processes

82

underpinning the microbial community assembly during granulation are poorly understood

83

Granulation is believed to occur as a response to specific selection pressures created in the

84

reactor, which causes the bacteria to switch from a planktonic to an aggregate growth mode 28.

85

High shear forces and feast-famine alternation stimulate the bacteria to increase the production

86

of extracellular polymeric substances (EPS) and increases the bacterial cell surface

87

hydrophobicity, accelerating the microbial aggregation 29. High wash out dynamics would act as

88

an accelerant of granulation by the physical selection of bigger particles 25.

89

Over the last decade, many studies have been conducted in granular sludge analysing the

90

microbial dynamics descriptively. However, there is a need to understand the factors shaping the

91

granular microbial community. For this, laboratory scale studies that enable controlled

92

environmental conditions and tests of reproducibility are valuable test-benches 1. Laboratory

25.

This permits granular sludge to remove carbon, nitrogen and phosphorus 26.

27.

5

ACS Paragon Plus Environment

Environmental Science & Technology

Page 6 of 39

93

experiments in granular sludge reactors, and generally in the field of wastewater treatment, are

94

typically performed in one reactor because of practical reasons. Hence, conclusions regarding

95

reactor performance and microbial community structure are drawn from single reactors operated

96

at different conditions 30-33. For example, in a previous study we showed considerable divergence

97

of microbial communities in three sequencing batch reactors, each fed with different carbon

98

concentrations, during granulation 30. It is, however, unclear how reliable such conclusions are,

99

especially for the complex processes underlying microbial community assembly. It is therefore

100

necessary to assess the reproducibility of these systems.

101

Here, to better understand the microbial community assembly of granule formation, we have

102

investigated the succession during the transition from floccular to granular sludge in replicate

103

reactors. Reactor functions, granule development, successional patterns of taxa, microbial

104

diversity and reproducibility were assessed. We used null models to determine the ecological

105

factors behind taxonomic- and phylogenetic turnover to assess community assembly. We

106

hypothesized that similar communities would develop in the three replicate reactors if

107

deterministic factors were dominating, whereas the opposite would support the importance of

108

stochastic factors.

109

MATERIAL AND METHODS

110

Reactors and analytical methods

6

ACS Paragon Plus Environment

Page 7 of 39

Environmental Science & Technology

111

Three replicate sequencing batch reactors (R1, R2 and R3) with a working volume of 3 L,

112

previously described in detail

113

inoculated with fresh activated sludge for a total addition of 9 g of biomass to each reactor. A

114

mineral medium with acetate as the single source of organic carbon was used with a chemical

115

oxygen demand (COD) of 3 kg COD m-3d-1 and a nitrogen load of 0.75 kg NH4-N m-3d-1 (see Text S1

116

and Figure S1 for detailed information). Concentrations in the effluent of total organic carbon and

117

total nitrogen were measured with a TOC-TN analyser (TOC-V, Shimadzu, Japan). Total and

118

volatile suspended solids in the reactor and in the effluent were measured according to standard

119

methods

120

microscope (Olympus Sverige AB, Solna, Sweden), using the CellSens (Olympus) software to

121

measure the diameter of 10 random flocs/granules.

122

DNA extraction, amplification and sequencing

123

The V4 region of the 16S rRNA gene was amplified using indexed 515'F and 806R primers 35 and

124

sequenced using the MiSeq platform (Illumina). For detailed information, see Text S1. To increase

125

the confidence in the obtained results, a second MiSeq sequencing run was performed on the

126

same DNA pool.

127

Sequence processing and data analysis

128

Raw sequence reads were processed following the UNOISE pipeline 36, 37 with USEARCH v.10 38,

129

taxonomically classified with the SINTAX algorithm 39 based on the MiDAS database v.2.1 40 and

34.

30,

were operated identically for 35 days. The reactors were

Sludge particle size assessments were performed with an Olympus BX60 light

7

ACS Paragon Plus Environment

Environmental Science & Technology

Page 8 of 39

130

analysed in R version 3.4.1 (http://www.r-project.org). For comparison, raw sequence reads were

131

also processed following the DADA2 pipeline 41. An approximately maximum-likelihood tree was

132

generated using the R package DECIPHER 42 and the FastTree 2 software 43. Raw sequence reads

133

from both MiSeq sequencing runs were processed following the same procedure. The dataset

134

was rarefied, subsampling each sample to 17395 sequences. Basic R functions were used to

135

perform Wilcoxon signed-rank tests and to calculate Pearson correlation coefficients. NMDS

136

ordination and heatmaps were created using the R package ampvis

137

permutations) and Procrustes tests using the protest function (999 permutations) were

138

performed using the R package vegan 45. Analysis of pairwise multivariate permutational analysis

139

of variances (PERMANOVA) was conducted using adonis from the package pairwiseAdonis 46. The

140

ANCOM method 47 was implemented in scikit-bio 0.5.5. Time-decay rates were calculated as in

141

Shade, et al. 48. For detailed information on sequence processing and data analysis, see Text S1.

142

Taxonomic Hill numbers were used to calculate α-diversity, qTD 49. Phylogenetic diversity, qPD,

143

which take the sequence dissimilarity into account, was also calculated 50. The same calculation

144

framework was used to calculate β-diversity and was converted into dissimilarity indices (qβdis)

145

constrained between 0 (two identical samples) and 1 (two samples with no shared OTUs) 50, 51.

146

The parameters qβdisTD and qβdisPD are based on the taxonomic and the phylogenetic β-diversity

147

values, respectively (see TextS1 for detailed information). Correlations between series of α-

148

diversity data were investigated using Kendall’s rank correlation coefficient (tau), which was

149

calculated with the Scipy package in Python 52 (see Text S1).

44.

CAP, Mantel tests (999

8

ACS Paragon Plus Environment

Page 9 of 39

Environmental Science & Technology

150

Raw sequences were deposited in the NCBI Sequence Read Archive (SRA), BioProjectID

151

PRJNA472243, accession number SRP148672. Python scripts used to calculate diversity indices

152

based on Hill numbers are freely available at https://github.com/omvatten/qDiv.

153

Null model analysis

154

Taxonomic turnover was estimated with Raup-Crick measures based on Bray-Curtis dissimilarities

155

(RCbray) as by Stegen, et al. 53. The RCbray index values range between -1 and 1. A negative value

156

means that the two communities are more similar than expected by chance whereas a positive

157

value means that they are more dissimilar. Values > |0.95| were considered statistically

158

significant. Values < |0.95| indicates that the taxonomic turnover between the community pair

159

are not different from the null expectation and therefore, influenced by stochastic factors 2.

160

Phylogenetic turnover was estimated with β nearest-taxon index (βNTI), as previously described

161

53. A negative βNTI value means that the samples are more phylogenetically similar than expected

162

by chance and a positive value means that they are more phylogenetically distant from each

163

other. Pairwise comparisons with βNTI > |2| were considered statistically significant. Values < |2|

164

were not significantly different from the null expectation, which indicate that stochastic factors

165

influenced the phylogenetic turnover 2. For detailed information see Text S1.

166

RESULTS

167

Granulation of the sludge and reactor performance

9

ACS Paragon Plus Environment

Environmental Science & Technology

Page 10 of 39

168

Around day 7, granules started to emerge (Figure S2) and the mean particle sizes of the reactor

169

biomass increased similarly in the three reactors (Figure S3). On day 25, the granulated biomass

170

dominated and at the end of the experiment (day 35), the granules had an average diameter of

171

approximately 1.5 mm. The three reactors were reproducible in terms of effluent concentrations

172

of suspended solids (total and volatile), organic carbon and nitrogen (Figure 1) as indicated by

173

paired sample Wilcoxon signed-rank tests (Table S1), but the reactor concentrations of volatile

174

and total suspended solids were significantly lower (p