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Linking microbial community, environmental variables and methanogenesis in anaerobic biogas digesters of chemically enhanced primary treatment sludge Feng Ju, Frankie Lau, and Tong Zhang Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.6b06344 • Publication Date (Web): 27 Feb 2017 Downloaded from http://pubs.acs.org on February 28, 2017

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Environmental Science & Technology

Linking microbial community, environmental variables and methanogenesis in anaerobic biogas digesters of chemically enhanced primary treatment sludge Authors: Feng Ju 1, Frankie Lau 2, Tong Zhang 1* Author affiliation:

1

Environmental Biotechnology Lab, The University of Hong

Kong SAR,China; 2Drainage Services Department, The Government of the Hong Kong Special Administrative Region, Hong Kong, China. *Corresponding author: Dr. Tong Zhang (Professor) Address: Environmental Biotechnology Lab, The University of Hong Kong, Pokfulam Road, Hong Kong Tel: 852-28591968 (lab), 28578551 (office) Fax: 852-25595337 E-mail: [email protected]

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Abstract

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Understanding the influences of biotic and abiotic factors on microbial community structure

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and methanogenesis are important for its engineering and ecological significance. In this study,

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four biogas digesters were supplied with the same inoculum and feeding sludge, but operated

5

at different sludge retention time (7 to 16 days) and organic loading rates for 90 days to

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determine the relative influence of biotic and environmental factors on the microbial

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community assembly and methanogenic performance. Despite different operational

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parameters, all digester communities were dominated by Bacteroidales, Clostridiales and

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Thermotogales, and followed the same trend of population dynamics over time. Network and

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multivariate analyses suggest that deterministic factors, including microbial competition

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(involving Bacteroidales spp.), niche differentiation (e.g., within Clostridiales spp.), and

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periodic microbial immigration (from feed sludge), are the key drivers of microbial

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community assembly and dynamics. A yet-to-be-cultured phylotype of Bacteroidales

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(GenBank ID: GU389558.1) is implicated as a strong competitor for carbohydrates. Moreover,

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biogas-producing rate and methane content were significantly related with the abundances of

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functional populations rather than any operational or physicochemical parameter, revealing

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microbiological mediation of methanogenesis. Combined, this study enriches our

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understandings of biological and environmental drivers of microbial community assembly and

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performance in anaerobic digesters.

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Keywords: Anaerobic digesters; Methanogenesis; Microbial community; Population 2

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dynamics; Network analysis

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Introduction

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Anaerobic digestion (AD) is a microbially mediated biotechnology widely used for renewable

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energy production and waste management 1, 2. Environmental variables, including operational

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parameters (e.g., sludge retention time) and physicochemical conditions (e.g., volatile fatty

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acids (VFAs), ammonium nitrogen (NH4-N)), are known to affect AD process, including

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formation of intermediates, process stability, biogas yield, biodegradation efficiency, and 3, 4, 5.

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However, because of the lack of dense monitoring of coupled environmental and

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microbiological data from the same anaerobic digesters, biotic and abiotic factors that govern

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microbial community structure and their linkage with methane production are poorly

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understood3, 6, 7.

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Recent application of high-throughput sequencing technologies provides a comprehensive,

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qualitative and quantitative measurement of diverse environmental microbiomes, facilitating

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the exploration of the driving forces that structure microbial communities in marine water 8,

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lake 9, soil

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interpret patterns and processes of microbial community assembly

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highlights an importance of deterministic processes, such as microbial interactions (e.g.,

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syntrophy and competition), niche differentiation, substrate availability and operational

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conditions 6, 11. On the contrary, neutral theory, as a null hypothesis, disregards the differences

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among species in response to ecological conditions and only considers stochastic processes,

10-12

, and bioreactors

6, 13-15

. Both niche-based and neutral theories are used to 16

. Niche-based theory

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15, 17

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such as birth, death, dispersal, and colonization and immigration

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the relative role of niche and neutral forces in structuring microbiome are controversial. Some

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researchers argue that microbiome assembly in lake water, soil, and activated sludge is driven

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by deterministic niche-based processes based on co-occurrence analysis

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reactor experiments 6; others that neutral models support stochastic processes for interpreting

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microbiome assembly in marine water 8, activated sludge

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that niche-based and stochastic-neutral processes are both important for structuring

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microbiomes of soil and bioreactor 10.

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Bioreactors are ideal systems to study patterns of microbial community assembly and link

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them with system performance, because microorganisms are cultivated in elaborately

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controlled and regularly monitored systems

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previously reported in quintuplicate denitrifying bioreactors

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membrane reactors

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suggests that these highly predictable microbial systems are not guided by stochastic

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processes. However, replicate operational conditions, such as sludge retention time (SRT) and

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organic loading rate (OLR), and highly similar profiles of chemicals (e.g., VFAs and NH4-N)

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in these replicated bioreactors make it impossible to resolve the influence of different

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operational parameters on the microbial community assembly and performance. In fact,

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operational parameters including SRT and NH4-N have long been implicated to affect

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microbial community structure and methane production

15

. Recent viewpoints on

9, 13

or replicated

and bioreactors 18; and yet more

6, 13, 14

. The reproducible community dynamics

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19

, quadruplicate nitrifying

, and triplicate anaerobic cellulose-degrading reactors

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congruously

3, 4

. Therefore, the examination of

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anaerobic digesters under different operational conditions is essential for checking the

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robustness of deterministic community assembly and dynamics observed in previous replicate

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bioreactors, examining whether different operational conditions lead to stochastic or random

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community assemblages, and determining the influences of biotic and abiotic (environmental)

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factors in shaping community structure and performance.

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Here, four anaerobic digesters were supplied with the same seeding and feeding sludge and

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operated at different SRTs and OLRs. Temporal dynamics in the microbial communities and

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environmental conditions was closely followed over 90 days and linked to methane

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production. This work was conducted to show the relationships among microbial community,

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environmental variables and methane production, to check whether microbial community

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assembly and dynamics were deterministic or stochastic, and to compare the relative

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influence of environmental variables (operational and physicochemical) and biotic factors

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(e.g., microbial interactions) in shaping microbial community assembly and performance.

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Materials and Methods

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Digester operation and sample collection

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Four 1-liter continuously stirring anaerobic digesters of chemically enhanced primary

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treatment (CEPT) sludge, designated as R1, R2, R3 and R4, were operated at 35°C (heated in

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water bath) but under different SRTs of 7, 9, 12 and 16 days, corresponding to levels of OLR

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between 2.40 and 3.78, 1.86 and 2.93, 1.40 and 2.21, and 1.05 and 1.66 kg-VS/m3/d, 5

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respectively (Table S1). The setup of retention time below and above 10 days, which is

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deemed as the minimum retention time needed to prevent washout of slow-growing

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methanogens by some researchers

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recommended minimum SRT on the methanogenic performance and microbial structure.

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More details on digester operation are available in the Supporting Method S1. For

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microbiological analysis, the seed sludge (in triplicates), feed sludge (Day 1), and 48 digester

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samples (collected at 12 time points; Figure 1a) were fixed in 50% ethanol and stored at

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-20°C until further processing.

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Digester performance monitoring

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Biogas, liquid, and sludge samples were collected for chemical analysis every 2 or 4 days

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from the four anaerobic digesters, as described in Supporting Method S2. The digesters

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showed reproducible performance in biogas production and volatile solid reduction over 90

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days (Figure S1).

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DNA extraction, sequencing and bioinformatics analysis

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16S rRNA genes were amplified with the universal primer set F515/R806 11, 21 from genomic

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DNAs extracted using FastDNA SPIN Kit for Soil. The pooled PCR products were purified

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and prepared for paired-end sequencing (2×250 bp) on Illumina Miseq. The generated data

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were pretreated following mothur Miseq SOP

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QIIME (v 1.8.0) for open-reference operational taxonomic units (OTUs) picking and core

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diversity analyses 23. The molecular and bioinformatics procedures are described in details in

4, 6

, allows us to test the effects of a span around the

22

, and the clean data were imported into

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Supporting Method S3. The sequence data are deposited into the NCBI’s Sequence Read

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Archive Database with accession numbers of SRR3104406, SRR3104407, SRR3104408,

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SRR3104410 and SRR3104411.

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Statistical and network analyses

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The statistical analyses including principal coordinates analysis (PCoA), procrustes analysis,

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canonical correspondence analysis (CCA), correlation analysis, student’s t-test, Wilcoxon

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signed-rank test, Kruskal-Wallis tests and BIOENV analysis were performed using R

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packages: stats

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and co-exclusion species-species associations (SSA) were explored by calculating all pairwise

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Spearman’s rank coefficients (ρ) among 0.97-OTUs that occurred in at least 50% of samples

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and represented by at least five sequences on average across all samples. Details on the

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statistical and network analyses were described in the Supporting Method S4.

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Results

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Digester performance and operational parameter

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Four anaerobic digesters were operated to investigate the effects of different SRTs (7-16 days)

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and OLRs (1.05-3.78 kg-VS/m3/d) on the biogas production and microbial community

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structure over 90 days. To facilitate comparison of temporal succession of microbial

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community, three operational stages with similar time lengths were defined: Stage I—day

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10-38, Stage II—day 39-66, and Stage III—day 67-90 (Figure 1).

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, vegan

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, MASS

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and nortest 27, unless stated otherwise. Co-occurrence

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The four anaerobic digesters achieved good methane-producing rate (RM) (0.49-0.66 L/L/d;

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Figure 1b) and methane content (CH4%; 64-67%, Table S1) at Day 12, indicating rapid

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adaptation of the inoculated microorganisms to the feedings of sewage sludge. From day 10 to

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18, R1 and R2 (shorter SRTs of 7 and 9 days) had higher RM than R3 and R4 (higher SRTs of

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12 and 16 days), probably because of the higher OLRs to the former over the latter digesters

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(Figure 1a, inset). However, accumulation of VFAs (mainly acetate and propionate) were

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observed in R1 during stage I (Figure 1c and Table S2) and RM dramatically decreased on Day

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34 (Figure 1b), closely followed by the peak of VFAs at Day 38 (Table S2). Stage II was

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characterized by OLR decrease from day 42 to 50 and OLR increase from day 54 to 66. This

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accompanied with the decrease of VFA concentrations in R1 (33-128 mg/L), as well as

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fluctuations of RM and pH in all digesters (Figure 1b and 1d). During Stage III, the digester

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OLRs were markedly increased on Day 66 (by 38%), followed by dramatic increases of RM in

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all digesters expect for R1. Two-sample statistical tests show that RM from day 10 to 90 were

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significantly (P-values < 2.3×10-4) different between R2 (0.95±0.14 L/L/d) and R3

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(0.73±0.20), between R3 and R4 (0.59±0.10), and between R2 and R1 (0.54±0.14). In

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contrast, there was no significant (P-values > 0.07) difference in CH4% between any two

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digesters.

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Associations among environmental parameters, microbial alpha-diversity and biogas

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parameters

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Pearson’s linear correlations and/or Spearman’s rank correlations (Table S4) show that RM 8

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was negatively correlated with the concentration of organic parameters, including acetic acid

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(HAc), propionic acid (HPr) and VFAs (-(0.39-0.48), Table S4-1), as well as microbial

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alpha-diversity metrics, such as Shannon’s and Simpson’s diversity indexes (-(0.38-0.40),

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Table S4-2). Moreover, all alpha-diversity metrics were negatively correlated with operating

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time (i.e., Day; -(0.61-0.84)), inorganic carbon (IC, -(0.37-0.65)), and NH4-N (-(0.41-0.64)

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(Table S4-1). This is in agreement with the results of two-sample statistical tests that the

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richness, evenness and diversity metrics of 0.97-OTUs significantly decreased (P-values ≤

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0.05) with operating time from Stage I to III (Table 1).

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Microbial population dynamics in SRT-differentiated digesters

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The seed sludge was mainly composed of Bacteroidia (20.9%), Gammaproteobacteria

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(12.7%) and Betaproteobacteria (8.5%). All the digester microbial communities rapidly

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shifted away from the seed community (Figure 2, 0.97-OTU level; Figure S2, class level) and

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markedly decreased in richness (i.e., observed species) and Shannon’s H diversity of OTUs

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after startup (Figure 2, diversity heatmap). PCoA biplots based on UniFrac distances (Figure 3)

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and Bray Curtis dissimilarities between 0.97-OTUs (Figure S3a) show that both microbiome

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membership (i.e., presence or absence of rare phylotypes) and abundance were much more

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different between operating stages (Figure 3c & 3d) than between digesters (Figure 3a & 3b).

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Procrustes analysis on the principal coordinates of unweighted UniFrac and weighted UniFrac

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distances between samples over 90 days shows a significant and high correlation (0.85,

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P-value = 0.001) between microbial community structure with and without considering 9

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membership, and highly similar community dynamics among the four digesters (Figure S3b).

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BIOENV analysis supports that operating time best explained the variations of microbial

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community abundance and membership (rho = 0.518-0.520, weighted UniFrac distance,

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Table 2). However, compared with only considering operating time, the incorporation of SRT

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slightly improved interpretation of the unweighted (but not weighted) UniFrac distances

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between the samples (rho from 0.369-0.413 to 0.442-0.481, Table 2), revealing that SRT

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slightly determines microbial community membership. PCoA bi-plots highlighted the

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influence of SRT on the community membership at Stage I. For example, the community

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membership (Figure 3d) changed more apparently than abundance (Figure 3c) for all

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digesters.

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Despite the differences in SRT and operating time, the microbial communities in all digester

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samples (n = 48) were composed of Bacteroidia (42.8±13.1%), Clostridia (23.0±6.2%),

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Thermotogae (8.7±7.0%), Bacilli (3.0±1.3%), Anaerolineae (2.7±1.2%), Actinobacteria

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(2.1±1.0%) and other populations (17.8±5.2%) (Figure S2, clusters a and c1). Moreover, the

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overall profiles of microbial abundance and diversity metrics in the four digesters were

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similar over time (Figure S2) and the microbiome succession followed deterministic trends

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over 90 days (Figure 3 and Figure S3b). The 50 most abundant 0.97-OTUs in the four

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digesters over 90 days (i.e., labeled from s1 to s50; Table S5) accounted for total relative

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abundance of 71.1(±6.8)%. Among them, 38 OTUs had significant different (P-values ≤ 0.05)

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relative abundances between the seed sludge and different operating stages (29 OTUs, taxon

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names in red) or SRTs (10 OTUs, taxa names in green), as shown by Kruskal-Wallis tests

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(Figure 2, P-value heatmap).

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Environment-species and species-performance associations

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The relationships among environmental (i.e., operational and physicochemical) parameters,

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abundance of 0.97-OTUs, and methanogenic performance were explored by CCA based on

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data from all 48 digester samples. Overall, the associations between environmental and

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performance parameters, as shown by CCA plot, were in agreement with the results of

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correlation analysis (Table S4). CCA additionally shows that Bacteroidales OTUs including

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s1, s13 and s49 (red nodes, Figure 4) were positively correlated with both methane-producing

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rate (RM) and biogas-producing rate (RG) whereas negatively with CH4%. The most abundant

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OTU, s1 (GenBank ID: GU389558.1, Greengenes ID: 837605, Figure S6), was significantly

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enriched (P-value ≤ 0.01) in all digesters, from 1.1% in the seed sludge to average relative

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abundances of 15.1% 28.0% and 45.6% at Stages I (n=16), II (n=16) and III (n=16),

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respectively (Figure 2, cluster a). In contrast, the organic parameters, including OLR, DOC,

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VFAs, HPr and HAc, were positively correlated a group of OTUs (blue nodes, Figure 4),

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including four Clostridium OTUs (s3, s4, s19 and s36), four Syntrophomonas OTUs (s5, s12,

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s18 and s29), three Bacteroidales OTUs (s10, s15 and s46), three Verruco-5 OTUs (of

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Verrucomicrobia; s28, s38 and s48), two T78 clade OTUs (of Chloroflexi, s9 and s23) and one

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Fibrobacter succinogenes OTU (s17). The most abundant methanogen, s30, (Greengenes

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taxonomy ID: 103247) was correlated positively with HAc, whereas negatively with SRT 11

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(Figure 4). This Methanosaeta species had significantly different relative abundances at

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different SRTs (Kruskal-Wallis test P-value ≤ 0.001; Figure 2, P-value heatmap). Likewise,

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methanogenic populations of class Methanomicrobia and genus Methanosaeta were the most

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enriched at the SRT of 7 days, followed by SRTs of 9, 12 and 16 days, respectively (Figure

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S4).

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Species-species associations

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The co-occurrence (i.e., positive) and co-exclusion (i.e., negative) associations between

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species (i.e., 0.97-OTUs) over time were explored using network analysis of 48 digester

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samples collected from Day 10 to 90. The resulting positive SSA network consisted of 101

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nodes (i.e., 0.97-OTUs) and 317 edges (i.e., correlation; Figure 5a), while the negative SSA

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network included 60 nodes and 131 edges (Figure 5b). Overall, 52% and 48% of OTUs in the

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positive and negative SSA networks belonged to Bacteroidetes and Firmicutes, respectively.

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Furthermore, 20% and 40% of all the 131 negative SSA involved the most abundant,

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Bacteroidales s1 and other 15 Bacteroidales OTUs, respectively. Notably, the average

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correlation coefficients of negative SSA between s1 and other OTUs (-0.71; see Figure 5d for

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examples) were significant higher (P-values < 0.0003, Figure 5c) than those between other 15

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Bacteroidales OTUs and between 44 non-Bacteroidales OTUs.

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Topological analysis shows that the positive SSA network had a clustering coefficient of 0.47

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and a modularity index of 0.49. Network partitioning divided the network into seven modules

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(Figure S5a). Module I was aggregated by 25 densely connected OTUs with peak abundances

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at Stage I (see green nodes in Figure S5a against Figure S5b). However, these OTUs had

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sharply decreasing abundance with operating time. This was accompanied with peak

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abundance of many other OTUs (mainly in Modules II and V, Figure S5a) at Stage II (39

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OTUs; red nodes) or Stage III (14 OTUs, purple nodes; Figure S5b). Different from Module I

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where OTUs of Actinobacteria, Tenericutes and WWE1 were prevalent (see Figure S5a

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against 5a), Module II mainly harbored OTUs of Bacteroidetes (10 OTUs), Proteobacteria (7

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OTUs), Verrucomicrobia (3 OTUs), and Firmicutes (3 OTUs).

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Further statistical analysis reveals non-random (deterministic) co-exclusion patterns between

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OTUs from different orders (i.e., inter-orders) or from the same order (i.e., intra-order). Firstly,

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OTUs from order Bacteroidales tended to co-exclude with OTUs of other bacterial orders (i.e.,

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Actinomycetales, Cloacamonales, Mollicutes, Anaerolineales and Synergistales) much more

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(23%) than expected when considering observed order frequencies and random association

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(6%, Table S6). Moreover, the observed incidence of intra-order co-exclusion for

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Bacteroidales (10.7%) was slightly higher than expected by chance (6.8%), whereas the

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observed incidence of intra-order co-exclusion for Clostridiales (0.8%) was much lower than

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expected by random associations (4.4%).

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Discussion

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Environmental parameters linked to methanogenic performance

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In this study, four anaerobic digesters were operated for 90 days under different SRTs and

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OLRs with the same inoculum and primary sewage sludge as biogas feedstock. Shortening

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SRT to 9 days, which is below the putative minimum SRT, i.e., 10 days, to prevent washout of

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slow-growing methanogens

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abundance of HAc-utilizing methanogens, nor in the deterioration of biogas/methane

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production. For example, relative abundances of Methanomicrobia and Methanosaeta (Figure

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S4) and methane-producing rate (RM, Figure 1b) markedly increased with the decrease of SRT

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from 16 or 12 days to 9 days. However, a further decrease of SRT from 9 to 7 days led to a

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dramatic decrease of RM from 0.95 (±0.14) to 0.54 (±0.14) L/L/d (Table S1), despite a

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further increase of the relative abundance of methanogens (Figure S4). This non-monotonic

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relationship between SRT/OLR and methanogen abundance suggest that they are not the sole

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influential factors of methanogens and RM. For example, the positive/negative correlations

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between abundance of Bacteroidales populations (i.e., s1, s3 and s49, Figure 4) and RM/CH4%

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suggest their important roles in mediating both methane-producing rate (as further discussed

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below) and methane content in biogas. In line with this relationship, the increasing order of

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the relative abundance of Bacteroidales populations by SRT during stage III (i.e., 7 < 16 < 12

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< 9 days, Figure 6) well agrees with that of the biogas-producing rate between the digesters

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(RM, Table S3). However, results obtained in this study are inadequate to suggest that all

6, 30

, may not necessarily result in the reduction of relative

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digesters could reduce their SRT to below 10 days, considering the narrow range of possible

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conditions and specific source of the seed and feed sludge. Therefore, the effects of SRT

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should be assessed on a case-by-case basis.

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The positive correlations between OLR and VFAs/HPr/HAc, as shown both by correlation

259

analysis (0.37-0.47, Table S4-1) and CCA (Figure 4), reflect increased hydrolysis and

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conversion of organic macromolecules including carbohydrates, lipids and proteins to soluble

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organic molecules with increasing OLR. In contrast, the negative correlations between RM and

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VFAs/HPr/HAc (-0.39 to -0.48, Table S4-1) indicate that elevated levels of these soluble

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intermediates may signify incomplete methanogenesis. The buildup of VFAs in R1 during

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Stage I was probably an indicator of unbalanced growth between acidogenic bacteria and

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methanogens. In contrast, no clear accumulation of VFAs in R2, R3 and R4 suggests

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relatively stable conversion of VFAs to methane.

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Community composition and dynamics linked to methanogenic performance

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Microbial communities in the four digesters rapidly shifted away from the inoculated

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community, followed the same trends in succession (along PC1, Figure 3), and converged into

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highly similar community compositions (mainly Bacteroidia, Clostridia and Thermotogae)

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under the selective pressures imposed by SRT, OLR and feed sludge (Figure S2 and Figure 2).

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Both the nature of substrate (primary sludge) and SRT (7-16 days) were different from those

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of the source digester of seed sludge that treats combined primary and secondary sludge at a

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SRT of 6 days. Primary sludge has much higher biodegradability than secondary sludge since

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it consists of more easily biodegradable organics, while SRT selects microorganisms by

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growth rate and tends to wash out slowly growing organisms. Both our and other studies show

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a positive relation between digester SRT and microbial richness 3, 4. Therefore, these selective

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pressures may create specific niches that differentiate the community composition and

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diversity from those of the inoculum.

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First, both the microbial richness and evenness of 0.97-OTUs decreased over 90 days in all

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digesters (Table 1). The decrease in diversity was mainly driven by the differences in the

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nature of feeding sludge and SRT between this study and the source digester of the seed

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sludge, reflecting the adaption of inoculated microorganisms to the regular feedings of CEPT

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sludge. Moreover, many OTUs undetected or detected at low relative abundance in the seed

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sludge (Figure 2) became the major trophic groups (Figure 6). Multiple populations capable

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of the same metabolic functions, including hydrolyzing and fermenting organic molecules

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(e.g., s1, s2, s3, s4, s7, s8, s13, s14, s15, s17, s22), and generating acetate (e.g., s5, s6, s12,

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s16, s18 and s21) and methane (e.g., s30) were shared by the four digesters (Figure 2 and

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Table S5), regardless of their different SRTs and OLRs, indicating high levels of functional

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redundancy to maintain the process stability.

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Hydrolysis and fermentation

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Bacterial populations of orders Bacteroidales, Clostridiales and Thermotogales dominated

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microbial communities in all digesters (Figure 6). Members of Clostridiales and 16

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Thermotogales are well implicated in the hydrolysis and fermentation of carbohydrates in

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anaerobic digesters

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mammalian gut and anaerobic digesters as hydrolyzing/fermentative bacteria of carbohydrates

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6, 32, 33

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bacteria in anaerobic digesters (e.g., Clostridiales).

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The rapid enrichment and continuous dominance of Bacteroidales populations (Figure 6) and

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their significant (P-values < 0.01) negative Spearman’s correlations with cellulolytic

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Clostridiales (-0.44) and Thermotogales (-0.64) populations reveals Bacteroidales spp. are

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much stronger competitors of organic molecules in the anaerobic digesters than other bacteria.

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Likewise, Bacteroidales populations are probably substrate competitors of Cloacamonales

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(WWE1) and Saprospirales populations, considering the strong and significant negative

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correlations (-0.88 and -0.80; P-values < 1×10-11) between them. The functions of WWE1 and

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Saprospirales in methanogenic environments are poorly understood 34, 35. Our results suggest

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that in anaerobic digesters they may share overlapped niches with Bacteroidales populations.

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As operational conditions and resource availability in the anaerobic digesters favor the

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prosperity and dominance of Bacteroidales, WWE1, Saprospirales and Thermotogales

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populations are outcompeted and gradually washed out from the digesters (Figure 6).

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On the contrary, Clostridiales spp. were dramatically enriched, secondary dominant

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populations (Figure 6). The opposite intra-order species-spices co-exclusion (i.e., negative

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associations between species of the same order) for Bacteroidales and Clostridiales

6, 31

. In contrast, Bacteroidales populations commonly occur in the

. However, we know little about their biological interactions with other cosmopolitan

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implicates different ecological traits and rules guiding their co-dominance. Specifically,

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Clostridiales populations have diverse metabolic capabilities of diverse organic molecules,

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including cellulose and protein hydrolysis

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and homoacetogenesis

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niche differentiation may drive functionally versatile Clostridiales spp. into diverse patterns

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of resource use to avoid exclusive competition. The metabolic versatility and phenotypic

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plasticity with regard to the use of a broad range of organic micro- and macro-molecules in

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Clostridiales populations should allow them to fulfill multiple functions and occupy broad

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niches in anaerobic digesters. Based on these arguments, it is suggested that Clostridiales spp.

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should be more ecologically divergent (or dissimilar) than Bacteroidales spp., thus

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intra-species competition is stronger between members of Bacteroidales than Clostridiales.

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Therefore, non-overlapped niches between Clostridiales and Bacteroidales populations could

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make their co-dominance in the anaerobic digesters possible.

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Acetogenesis and methanogenesis

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Syntrophomonas, Syntrophobacterales and Clostridium can convert fatty acids to

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methanogenic substrates (i.e., HAc and H2) 40, 41. These populations were the main acetogens

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during anaerobic digestion (Figure 6), as also implicated by the positive correlations between

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relative abundance of Syntrophomonas (s5, s12, s18 and s29) and Clostridium (e.g., s3, s4,

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s19) OTUs and HAc concentration (Figure 4 and Table S5). The archaeal methanogens

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mainly included acetoclastic Methanosarcinales and hydrogenotrophic Methanomicrobiales

36, 37

, polysaccharide fermentation 6, acetogenesis

38

, and syntrophic oxidation of fatty acids and acetate

39

. Therefore,

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and Methanobacteriale, which are widely found together or individually as the core

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methanogens in anaerobic digesters

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between H2-producing Syntrophomonas populations and H2-scavenging Methanomicrobiales

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and Methanobacteriales (0.45 and 0.60, P-values