Metabolic potential of uncultured bacteria and archaea associated with petroleum seepage in deep-sea sediments

Hydrocarbon migration in seabed sediments

This study tested three petroleum-associated near-surface sediments (referred to as Sites E26, E29 and E44; see map in Supplementary Figure 1) sampled from the Eastern Gulf of Mexico ²⁰. Migrated thermogenic hydrocarbon content in the piston cores was analyzed for each of the three sites (Table 1). All three sediments contained high concentrations of aromatic compounds and liquid alkanes; aromatic compounds were most abundant at Site E26, while liquid alkanes were on average 2.5-fold higher concentration at Sites E26 and E29 than Site E44. Alkane gases were only abundant at Site E29 and were almost exclusively methane (CH₄). CH₄ sources can be inferred from stable isotopic compositions of CH₄ and molar ratios of CH₄ to higher hydrocarbons ¹⁵. Ratios of C₁/(C₂+C₃) were greater than 1,000 and δ¹³C values of methane were more negative than −60‰, indicating that the CH₄ in these sediments was predominantly biogenic ^{15, 21}. Similar co-occurrence of biogenic methane and complex hydrocarbons have been reported in a nearby seep in the Mississippi Canyon in the Gulf of Mexico ²². GC-MS revealed an unresolved complex mixture (UCM) of saturated hydrocarbons in the C₁₅₊ range in all three sites. Such UCM signals correspond to degraded petroleum hydrocarbons and may indicate the occurrence of oil biodegradation at these sites ²³.

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Figure 1. Relative frequency of metagenomic sequence reads for different marker genes at Sites E26, E29 and E44.

(a) Community composition based on reconstruction of full-length 16S rRNA genes from the metagenomes. Eukaryotes and unassigned reads are not shown. (b) Relative occurrences of hydrogenases with different metal cofactors. (c) Relative abundance of different subtypes of NiFe hydrogenases. (d) Relative abundance of mcrA genes indicative of different types of methanogenesis.

Phylogenetically diverse bacterial and archaeal communities

Illumina NextSeq sequencing of genomic DNA from deep-sea sediment communities produced 85,825,930, 148,908,270, and 138,795,692 quality-filtered reads for Sites E26, E29, and E44, respectively (Supplementary Table 1). The 16S rRNA gene amplicon sequencing results suggest that the sediments harbor diverse bacterial and archaeal communities, with Chao1 richness estimates of 359, 1375 and 360 amplicon sequence variants (ASVs) using bacterial-specific primers, and 195, 180 and 247 ASVs using archaeal-specific primers, for Sites E26, E29 and E44, respectively (Supplementary Table 2 and Supplementary Figure 2). In accordance with amplicon sequencing results, taxonomic profiling of metagenomes using small subunit ribosomal RNA (SSU rRNA) marker genes demonstrated that the most abundant phyla in the metagenomes were, in decreasing order, Chloroflexi (mostly classes Dehalococcoidia and Anaerolineae), Candidatus Atribacteria, Proteobacteria (mostly class Deltaproteobacteria), and Candidatus Bathyarchaeota (Supplementary Table 3 and Figure 1a). While the three sites share a broadly similar community composition, notable differences were Ca. Bathyarchaeota and Proteobacteria being in higher relative abundance at the sites associated with more hydrocarbons (E29 and E26; Table 1), whereas the inverse is true for Actinobacteria, the Patescibacteria group, and Ca. Aerophobetes that are all present in higher relative abundance at Site E44 where associated hydrocarbon levels are lower. Additional sampling is required to determine whether these differences are due to the presence of hydrocarbons or other factors.

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Figure 2. Phylogenetic placement of 82 reconstructed metagenome-assembled genomes.

A maximum-likelihood phylogenomic tree was built based on concatenated amino acid sequences of 43 conserved single copy genes using RAxML with the PROTGAMMALG model. Sequences of Altiarchaeales ex4484_43 were used as an outgroup. The scale bar represents 1 amino acid substitution per sequence position. Bootstrap values > 70% are indicated. Blue for Site E26 (E26_binX), red for Site E29 (E29_binY), and green for Site E44 (E44_binZ). The genome sequences used for inferring Figure 2 are available in Supplementary Data 1.

Assembly and binning for the three metagenomes resulted in a total of 82 MAGs with >50% completeness and <10% contamination based on CheckM analysis ²⁴. Reconstructed MAGs comprise taxonomically diverse members from a total of six archaeal and 15 bacterial phyla (Figure 2 and Supplementary Table 4). Within the domain Bacteria, members of the phylum Chloroflexi are highly represented in each sample, especially from the classes Dehalococcoidia and Anaerolineae. Within the domain Archaea, members of phylum Bathyarchaeota were recovered from all three sites. Most other MAGs belong to poorly understood candidate phyla that lack cultured representatives, including Aminicenantes (formerly OP8), Aerophobetes (formerly CD12), Cloacimonas (formerly WWE1), Stahlbacteria (formerly WOR-3), Atribacteria (formerly JS1 and OP9), TA06 (Supplementary Note 1 and Supplementary Table 5), and the Asgard superphylum, including Lokiarchaeota, Thorarchaeota, and Heimdallarchaeota.

In summary, while there are considerable community-level differences between the three sample locations, the recovered MAGs share common taxonomic affiliations at the phylum and class levels. Guided by associated geochemistry from the three sediment cores (Table 1 and Supplementary Note 2), we subsequently analyzed the metabolic potential of these MAGs to understand how bacterial and archaeal community members generate energy and biomass in these natural petroleum-associated deep-sea environments. Hidden Markov models (HMMs) and homology-based models were used to search for the presence of different metabolic genes in both the recovered MAGs and unbinned metagenomes. Where appropriate, findings were further validated through metabolomic analyses, phylogenetic visualization, and analysis of gene context.

Detrital biomass and hydrocarbon degradation

In deep-sea marine sediments, organic carbon is supplied either as detrital matter from the overlying water column or as aliphatic and aromatic petroleum compounds that migrate upwards from underlying petroleum-bearing sediments ¹¹. With respect to detrital matter, genes involved in carbon acquisition and breakdown were prevalent across both archaeal and bacterial MAGs. These include genes encoding intracellular and extracellular carbohydrate-active enzymes and peptidases, as well as relevant transporters and glycolysis enzymes (Figure 3 and Supplementary Table 6). The ability to break down fatty acids and other organic acids via the beta-oxidation pathway was identified in 13 MAGs, including members of Chloroflexi, Deltaproteobacteria, Aerophobetes and Lokiarchaeota (Figure 3 and Supplementary Table 6). Metabolomics data supported these genomic predictions and showed a surprising degree of consistency between the geographically distinct sampling sites (Figure 4). Over 50 metabolites from eight pathways were detected in all the samples, including carbohydrate metabolism (e.g. glucose), amino acid metabolism (e.g. glutamate), and beta oxidation (e.g. 10-hydroxydecanoate). Together, the metagenomic and metabolomic data suggest that seabed microorganisms are involved in recycling of residual organic matter, including complex carbohydrates, proteins and lipids.

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Figure 3. Identification of functional genes or pathways present in MAGs.

The presence of genes or pathways are indicated by orange shaded boxes. Gene names: Aor, aldehyde:ferredoxin oxidoreductase; Kor, 2-oxoglutarate/2-oxoacid ferredoxin oxidoreductase; Por, pyruvate:ferredoxin oxidoreductase; Ior, indolepyruvate ferredoxin oxidoreductase; GHs, glycoside hydrolases; AssA, catalytic subunit of alkylsuccinate synthase. CmdA, catalytic subunit of p-cymene dehydrogenase; AhyA, catalytic subunit of alkane C2-methylene hydroxylase; H2ase, hydrogenase; DsrAB, dissimilatory sulfite reductase. Pathways were indicated as being present if at least five genes in the Embden-Meyerhof-Parnas pathway, three genes in the beta-oxidation pathway, four genes in the Wood-Ljungdahl pathway, and six genes in the TCA cycle were detected. Additional details for the central benzoyl-CoA degradation pathway can be found in Supplementary Figure 5. Lactate and ethanol fermentation are indicated if genes encoding respective dehydrogenases were detected. More details about these functional genes and pathways can be found in the text and in Supplementary Table 6.

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Figure 4. Heatmap of metabolites identified in sediment pore water at Sites E26, E29 and E44 calculated using log fractional abundance.

Metabolite levels were measured by LC-MS and observed intensities are expressed as the log fractional abundance. Technical replicate numbers (n = 5) from each site are given on the bottom axis. Compound names are listed on the right axis and pathway assignments on the left. Compounds denoted with an asterisk can be intermediates in both anaerobic and aerobic metabolic pathways.

To identify the potential for microbial degradation of hydrocarbons, we focused on functional marker genes encoding enzymes that initiate anaerobic hydrocarbon biodegradation by activating mechanistically stable C-H bonds ²⁵. We obtained evidence that two of the four known pathways for oxygen-independent C-H activation ^25-28 were present: hydrocarbon addition to fumarate by glycyl-radical enzymes ²⁸ and hydroxylation with water by molybdenum cofactor-containing enzymes ²⁵. Glycyl-radical enzymes proposed to mediate hydrocarbon addition to fumarate were found in 13 MAGs (Chloroflexi, Aminicenantes, Aerophobetes, Actinobacteria, Bathyarchaeota, Thorarchaeota and Lokiarchaeota) (Figure 3). The sequences identified are phylogenetically distant from canonical akyl-/arylalkylsuccinate synthases, but form a common clade with the glycyl-radical enzymes proposed to mediate alkane activation in anaerobic alkane degraders Vallitalea guaymasensis L81 and Archaeoglobus fulgidus VC-16 ^29-31 (Supplementary Figure 3). Based on quality-filtered reads, canonical AssA (n-alkane succinate synthase) and BssA (benzyl succinate synthase) enzymes are also encoded at these sites and were most abundant in Site E29 (Supplementary Table 7). In agreement with this, metabolomics analysis detected six succinic acid conjugates involved in hydrocarbon activation, including conjugates of xylene, toluene, cyclohexane, and isopropane (Figure 4). For the hydroxylation pathway, a Dehalococcoidia MAG in Site E29 encoded proteins sharing over 40% sequence identities to the catalytic subunits of p-cymene dehydrogenase (Cmd) and alkane C₂-methylene hydroxylase (Ahy) (Figure 3 and Supplementary Figure 4) ³². Genes encoding enzymes catalyzing hydrocarbon carboxylation (ubiD-like), reverse methanogenesis (mcrA-like), and aerobic hydrocarbon degradation (e.g. alkB) were not detected (Supplementary Table 7). The latter result is expected due to the low concentrations of oxygen in the top 20 cm of organic rich seabed sediments ¹¹.

Our results also provide evidence that aromatic compounds can be anaerobically degraded via channeling into the central benzoyl-CoA degradation pathway. Through metabolomic analysis, we detected multiple intermediates (Figure 4) involved in both the production and degradation of benzoyl-CoA, a universal intermediate formed during the degradation of aromatic compounds ³³. Various compounds that can be activated to form benzoyl-CoA were detected, including benzoate, benzylsuccinate, 4-hydroxybenzoate, phenylacetate, acetophenone, and phenol. The downstream metabolite glutarate was also highly abundant (Figure 4). Benzoyl-CoA can be reduced to cyclohex-1,5-diene-1-carboxyl-CoA by either the Class I ATP-dependent benzoyl-CoA reductase pathway (bcr genes, e.g. Thauera aromatica) or Class II ATP-independent reductase (bam genes, e.g. sulfate reducers) ³⁴. We identified bcr genes for the Class I pathways in 12 MAGs from both bacteria (i.e., Dehalococcoidia, Anaerolineae, Deltaproteobacteria, Aminicenantes and TA06) and archaea (i.e., Thermoplasmata and Bathyarchaeota) (Figure 3 and Supplementary Figure 5). Genes for further transformation of dienoyl-CoA to 3-hydroxypimelyl-CoA were also identified, i.e. those encoding 6-oxo-cyclohex-1-ene-carbonyl-CoA hydrolase (oah), cyclohex-1,5-diencarbonyl-CoA hydratase (dch) and 6-hydroxycyclohex-1-ene-1-carbonyl-CoA dehydrogenases (had) ³⁵ (Supplementary Figure 5). In combination, these results strongly suggest that the organisms represented by these MAGs mediate the typical downstream degradation of aromatic compounds through the central benzoyl-CoA Bcr-Dch-Had-Oah pathway. However, sources of benzoate other than via anaerobic degradation of the above compounds, cannot be ruled out based on current data.

Production and consumption of acetate and hydrogen

Analysis of MAGs from these deep-sea hydrocarbon-associated sediments suggests that fermentation, rather than respiration, is the primary mode of organic carbon turnover in these environments. Most recovered MAGs with capacity for heterotrophic carbon degradation lacked respiratory primary dehydrogenases and terminal reductases, with exception of several Proteobacteria and one Chloroflexi (Supplementary Table 6). In contrast, various MAGs contained genes indicating the capability for fermentative production of acetate (69 MAGs), lactate (14 MAGs), and ethanol (6 MAGs) (Figure 3 and Supplementary Table 6). These findings therefore provide genomic evidence supporting other studies emphasizing the importance of fermentation, including acetate production, in deep-sea sediments ^{12, 36}. Acetate can also be produced by acetogenic CO₂ reduction through the Wood-Ljungdahl pathway using a range of inorganic and organic substrates ¹⁵. Partial or complete sets of genes for the Wood-Ljungdahl pathway were found in 50 MAGs (Figure 3 and Supplementary Figure 6), including those affiliated with phyla previously inferred to mediate acetogenesis in deep-sea sediments through either the tetrahydrofolate-dependent bacterial pathway (e.g. Chloroflexi and Aerophobetes) ^{7, 37} or the tetrahydromethanopterin-dependent archaeal variant (e.g. Bathyarchaeota and Asgard group) ^{38, 39}. In addition, the signature diagnostic gene for the Wood-Ljungdahl pathway (acsB; acetyl-CoA synthase) is in high relative abundance in the quality-filtered metagenome reads at all three sites (Supplementary Table 7). The most abundant MAG at each site were all putative acetogenic heterotrophs, i.e. Dehalococcoidia E26_bin16, Actinobacteria E44_bin5, and Aminicenantes E29_bin47 for Sites E26, E44 and E29 respectively (∼3.3-4.5% relative abundance, Supplementary Table 4). These observations are in agreement with mounting evidence that homoacetogens play a quantitatively important role in organic carbon cycling in the marine deep biosphere ^{38, 40, 41}.

The potential for H₂ metabolism was also found in MAGs from all three sites. We screened putative hydrogenase genes from various subgroups in MAGs as well as unbinned metagenomic sequences (Figures 1, 3 and Supplementary Tables 6-7). Surprisingly few H₂ evolving-only hydrogenases were observed, with only five Group A [FeFe]-hydrogenases and five Group 4 [NiFe]-hydrogenases detected across the bacterial and archaeal MAGs. Instead, the most abundant hydrogenases within the MAGs and quality-filtered unassembled reads were the Group 3b, 3c, and 3d [NiFe]-hydrogenases. Group 3b and 3d hydrogenases are physiologically reversible, but generally support fermentation in anoxic environments by coupling NAD(P)H reoxidation to fermentative H₂ evolution ⁴²-⁴⁴. Group 3c hydrogenases mediate a central step in hydrogenotrophic methanogenesis, bifurcating electrons from H₂ to heterodisulfides and ferredoxin ⁴⁵; their functional role in bacteria and non-methanogenic archaea remains unresolved ⁴⁴ yet corresponding genes frequently co-occur with heterodisulfide reductases across multiple archaeal and bacterial MAGs (Figure 3). Various Group 1 [NiFe]-hydrogenases were also detected, which are known to support hydrogenotrophic respiration in conjunction with a wide range of terminal reductases. This is consistent with previous studies in the Gulf of Mexico that experimentally measured the potential for hydrogen oxidation catalyzed by hydrogenase enzymes ⁴⁶.

Given the genomic evidence for hydrogen and acetate production in these sediments, we investigated whether any of the MAGs encoded terminal reductases to respire these compounds. In agreement with porewater sulfate concentrations (16-27 mM; see Supplementary Note 2), the key genes for dissimilatory sulfate reduction (dsrAB) were widespread across the metagenome reads, particularly at Site E29 (Supplementary Table 7); however, probably due to incompleteness of genomes or insufficient binning, these genes were identified only in two MAGs affiliated with Deltaproteobacteria and Dehalococcoidia (Supplementary Table 6). We also identified 31 putative reductive dehalogenase genes (rdhA) across 22 MAGs, mainly from Aminicenantes and Bathyarchaeota (Figure 3 and Supplementary Table 6); this suggests that organohalides, which can be produced through abiotic and biotic processes in marine ecosystems ⁴⁷, may be electron acceptors in these deep-sea sediments. At least two thirds of the MAGs corresponding to putative sulfate reducers and dehalorespirers encoded the capacity to completely oxidize acetate and other organic acids to CO₂ using either the reverse Wood-Ljungdahl pathway or TCA cycle (Figure 3 and Supplementary Table 6). Several of these MAGs also harbored the capacity for hydrogenotrophic dehalorespiration via Group 1a and 1b [NiFe]-hydrogenases (Figure 3). In addition to these dominant uptake pathways, one MAG belonging to the epsilonproteobacterial genus Sulfurovum (E29_bin29) included genes for the enzymes needed to oxidize either H₂ (group 1b [NiFe]-hydrogenase), elemental sulfur (soxABXYZ), and sulfide (sqr), using nitrate as an electron acceptor (napAGH); this MAG also has a complete set of genes for autotrophic CO₂ fixation via the reductive TCA cycle (Figure 3 and Supplementary Table 6).

The capacity for methanogenesis appears to be relatively low. The genes for methanogenesis were detected in quality-filtered unassembled reads in all three sediments and were mainly affiliated with acetoclastic methanogens at Site E29, and hydrogenotrophic methanogens at the other two sites (Figure 1d). However, none of the MAGs contained mcrA genes. Overall, the collectively weak mcrA signal in the metagenomes suggests that the high levels of biogenic methane detected by geochemical analysis (Table 1) is due to methanogenesis in deeper sediment layers. Similar phenomena have been observed in other sites, where mcrA genes are in low abundance despite clear geochemical evidence for biogenic methane ⁴⁸. Sequencing additional sediment depths at greater resolution would likely result in detection of mcrA-related methanogens and ANME lineages.

Thermodynamic modelling

Together, the geochemical, metabolomic, and metagenomic data strongly indicate that anaerobic degradation of aliphatic and aromatic compounds occurs in these deep-sea sediments (Table 1 and Figures 3-4). Recreating the environmental conditions for cultivating the organisms represented by the retrieved MAGs is a challenging process, preventing further validation of the degradation capabilities of these compounds (and other metabolisms) among the majority of the lineages represented by the MAGs retrieved here ⁴¹. Instead, we provide theoretical evidence that anaerobic degradation of aliphatic and aromatic compounds is feasible in this environment by modelling whether these processes are thermodynamically favorable in the conditions typical of deep-sea sediments, namely high pressure and low temperature.

As concluded from the genome analysis and supported by metabolomics (Figures 3-4), it is likely that anaerobic degradation occurs through an incomplete oxidation pathway. However, due to incompleteness of the reconstructed genomes, we cannot exclude the possibility that complete oxidation of aliphatic and aromatic compounds to CO₂ occurs through, for example, coupling with sulfate reduction (Figure 3). Additionally, several recent studies indicate that some aliphatic and aromatic compounds can be incompletely oxidized to acetate via the Wood-Ljungdahl pathway ^{37, 40, 49}. Therefore, we compared the thermodynamic constraints on anaerobic biodegradation for three plausible scenarios (Table 2): (i) incomplete oxidation with production of hydrogen and acetate, (ii) acetogenic oxidation with production of acetate alone, and (iii) complete oxidation coupled with sulfate reduction. Hexadecane and benzoate are used as representative aliphatic and aromatic compounds, respectively, based on the results of geochemistry and metabolomics results (e.g. C₂₊ alkane and benzoate detection) and genomic analysis (e.g. genes encoding for glycyl-radical enzymes and bcr genes). Under deep-sea conditions, without taking the in situ concentrations of hydrogen and acetate into consideration, the calculations show that sulfate-dependent complete oxidation of hexadecane and benzoate, as well as acetogenic oxidation of benzoate, would be energetically favorable. The three other reactions would be endergonic under most conditions, but based on the measured concentrations for both acetate and H₂ in these sediments being low (Supplementary Note 2) these reactions could also take place in theory (Table 2 and Figure 5). This suggests that acetate- and H₂-scavengers, by making acetogenic and hydrogenogenic degradation more thermodynamically favorable, may support activity of anaerobic degraders in the community.

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Figure 5. Thermodynamic constraints on anaerobic benzoate and hexadecane degradation in deep sea sediments.

Three reactions (Reactions 1, 2 and 4) are illustrated as taken from Table 2 where ΔG°_{4, 300}> 0. Thermodynamics for each reaction are indicated by a line in its corresponding color. If ΔG° < 0, the reaction is energetically favorable (indicated by arrow), and if ΔG° > 0 the reaction is assumed not to occur. In the studied environment (outlined in the shaded area), hydrogen concentrations fall below 1 µM while acetate concentrations are below 2.5 µM. The graph shows that ΔG° for three reactions are all negative when both actual concentrations of acetate and hydrogen are taken into consideration.

Sample selection based on geochemical characterization

The three marine sediment samples used in this study were chosen from among several sites sampled as part of a piston coring seafloor survey in the Eastern Gulf of Mexico, as described previously ²⁰. Piston cores penetrating 5 to 6 meters below sea floor (mbsf) were sectioned in 20 cm intervals on board the research vessel immediately following their retrieval. Three intervals from the bottom half of the core were chosen for geochemical analysis, and were either frozen immediately (for liquid hydrocarbon analyses), or flushed with N₂ and sealed in hydrocarbon-free gas tight metal canisters then frozen until analysis (for gaseous hydrocarbon analysis). Interstitial gas analysis was later performed on the headspace in the canisters using GC with Flame Ionization Detector (GC-FID). Sediment samples for gas/liquid chromatography and stable isotope analysis were frozen, freeze-dried and homogenized then extracted using accelerated solvent extraction (ACE 200). Extracts were subsequently analyzed using GC/FID, GC/MS, a Perkin-Elmer Model LS 50B fluorometer, and Finnigan MAT 252 isotope mass spectrometry as detailed elsewhere ⁵⁴. On the basis of TSF and UCM concentration thresholds described previously ²⁰, core segments from E26 and E29 were qualified and core segments from E44 were disqualified for unambiguous occurrence of thermogenic liquid hydrocarbons. Additionally, interstitial hydrocarbon gases were observed in the core segments of E29. Samples from the surface 0-20 cm interval from these three cores were further analyzed as described below.

Porewater geochemistry

Porewater sulfate and chloride concentrations were measured in a Dionex ICS-5000 reagent-free ion chromatography system (Thermo Scientific, CA, USA) equipped with an anion-exchange column (Dionex IonPac AS22; 4 × 250 mm; Thermo Scientific), an EGC-500 K₂CO₃ eluent generator cartridge and a conductivity detector. Organic acids were analysed in the 0.2 µm filtered sediment porewater using a Thermo RS3000 HPLC fitted with an Ultimate 3000 UV detector. Separation was achieved over an Aminex HPX-87H organic acid column (BioRad, USA) under isocratic conditions (0.05 mM H₂SO₄) at 60°C with a run time of 20 minutes. Organic acids were compared to the retention time of known standards and the limit of detection for acetate was determined to be 2.5 µM.

Metabolomic analysis

For the analysis of metabolites, sediment was centrifuged at 21,100 × g for 10 minutes at room temperature, the supernatant was collected, diluted 1:1 in pure methanol, and filtered through 0.2µm Teflon syringe filters. Each sediment was subsampled five times to assess technical variability across the sample. Metabolites present in the extracts were separated using ultra high-performance liquid chromatography (UHPLC) performed using a gradient of 20 mM ammonium formate at pH 3.0 in water (solvent A) and 0.1% formic acid (% v/v) in acetonitrile (solvent B) in conjunction with a Syncronis™ HILIC LC column (100mm × 2.1mm x 2.1µm; Thermo Scientific). High-resolution mass spectral data were acquired on a Thermo Scientific Q-Exactive™ HF Hybrid Quadrupole-Orbitrap mass spectrometer coupled to an electrospray ionization source. Data were acquired in negative ion full-scan mode from 50-750 m/z at 240,000 resolution with an automatic gain control (AGC) target of 3e6 and a maximum injection time of 200 ms. For MS/MS fragmentation experiments, an isolation window of 1 m/z and an AGC target of 1e6 was used with a maximum injection time of 100 ms. Data were analyzed in MAVEN ⁵⁵. Metabolites were assigned based on accurate mass and retention times of observed signals relative to standards (where available). Metabolites classified as being involved in the anaerobic degradation of aliphatic and aromatic compound pathways ⁵⁶, for which metabolites standards are not readily available, were assigned using accurate mass alone. The key benzoate and succinate metabolites were assigning using accurate mass, co-elution and MS/MS fragmentation patterns. To control for variability in total organic content across the sediment samples, metabolite data are presented based on their fractional abundance relative to all observed metabolites (i.e. constant sum normalization) and were visualized based on their log fractional abundance ⁵⁷.

DNA extraction and sequencing

For the three sediment samples, DNA was extracted from 10 g of sediment using the PowerMax Soil DNA Isolation Kit (12988-10, QIAGEN) according to the manufacturer’s protocol with minor modifications for the step of homogenization and cell lysis i.e., cells were lysed in PowerMax Bead Solution tubes for 45 s at 5.5 m s⁻¹ using a Bead Ruptor 24 (OMNI International). DNA concentrations were assessed using a Qubit 2.0 fluorometer (Thermo Fisher Scientific, Canada). Metagenomic library preparation and DNA sequencing was conducted at the Center for Health Genomics and Informatics in the Cumming School of Medicine, University of Calgary. DNA fragment libraries were prepared by shearing genomic DNA using a Covaris sonicator and the NEBNext Ultra II DNA library preparation kit (New England BioLabs). DNA was sequenced on a ∼40 Gb (i.e. 130 M reads) mid-output NextSeq 500 System (Illumina Inc.) 300 cycle (2 × 150 bp) sequencing run.

To provide a high-resolution microbial community profile, as well as quantitative insights into microbial community diversity, the three samples were also subjected to 16S rRNA gene amplicon sequencing on a MiSeq benchtop sequencer (Illumina Inc.). DNA was extracted from separate aliquots of the same sediment samples using the DNeasy PowerLyzer PowerSoil kit (MO BIO Laboratories, a Qiagen Company, Carlsbad, CA, USA) and used as the template for different PCR reactions. The v3-4 region of the bacterial 16S rRNA gene and the v4-5 region of the archaeal 16S rRNA gene were amplified using the primer pairs SD-Bact-0341-bS17/SD-Bact-0785-aA21 and SD-Arch-0519-aS15/SD-Arch-0911-aA20, respectively ⁵⁸ as described previously ²⁰ on a ∼15 Gb 600-cycle (2 × 300 bp) sequencing run.

Metagenomic assembly and binning

Raw reads were quality-controlled by (1) clipping off primers and adapters and (2) filtering out artifacts and low-quality reads as described previously ⁵⁹. Filtered reads were assembled using metaSPAdes version 3.11.0 ⁶⁰ and short contigs (<500 bp) were removed. Sequence coverage was determined by mapping filtered reads onto assembled contigs using BBmap version 36 (https://sourceforge.net/projects/bbmap/). Binning of metagenome contigs was performed using MetaBAT version 2.12.1 (--minContig 1500) ⁶¹. Contaminated contigs in the produced bins were further removed based on genomic properties (GC, tetranucleotide signatures, and coverage) and taxonomic assignments using RefineM version 0.0.22 ⁶². Resulting bins were further examined for contamination and completeness using CheckM version 1.0.8 with the lineage-specific workflow ²⁴.

Annotation

For MAGs, genes were called by Prodigal (-p meta) ⁶³. Metabolic pathways were predicted against the KEGG GENES database using the GhostKOALA tool ⁶⁴ and against the Pfam, TIGRfam and custom HMM databases (https://github.com/banfieldlab/metabolic-hmms)using MetaErg (https://sourceforge.net/projects/metaerg/). The dbCAN web server was used for carbohydrate-active gene identification (cutoffs: coverage fraction: 0.40; e-value: 1e-18) ⁶⁵. Genes encoding proteases and peptidases were identified using BLASTp against the MEROPS database release 12.0 (cutoffs: e-value, 1e-20; sequence identity, 30%) ⁶⁶. Genes involved in anaerobic hydrocarbon degradation were identified using BLASTp against a custom database (Supplementary Table 8) (cutoffs: e-value, 1e-20; sequence identity, 30%). Hydrogenases were identified and classified using a web-based search using the hydrogenase classifier HydDB ⁶⁷.

Full-length 16S rRNA genes were reconstructed from metagenomic reads using phyloFlash version 3.1 (https://hrgv.github.io/phyloFlash/) together with the SILVA SSU 132 rRNA database ⁶⁸. Diversity calculations were based on separate 16S rRNA gene amplicon library results ²⁰. Functional and taxonomic McrA gpkgs were used to assess the diversity of methanogens against the metagenomic reads using GraftM with default parameters ⁶⁹. Genes encoding the catalytic subunits of hydrogenases, dsrA, acsB, assA, nmsA and bssA were retrieved from metagenomic reads through diamond BLASTx ⁷⁰ queries against comprehensive custom databases ^{39, 67, 71} (cutoffs: e-value, 1e-10; sequence identity, 70%).

Phylogenetic analyses

For taxonomic classification of each MAG, two methods were used to produce genome trees that were then used to validate each other. In the first method the tree was constructed using concatenated proteins of up to 16 syntenic ribosomal protein genes following procedures reported elsewhere ⁷²; the second tree was constructed using concatenated amino acid sequences of up to 43 conserved single-copy genes following procedures described previously ⁷³. Both trees were calculated using FastTree version 2.1.9 (-lg -gamma) ⁷⁴ and resulting phylogenies were congruent. Reference genomes for relatives were accessed from NCBI GenBank, including genomes selected from several recent studies representing the majority of candidate bacterial and archaeal phylogenetic groups ^{4, 62, 75-78}. The tree in Figure 2 was inferred based on concatenation of 43 conserved single-copy genes (Supplementary Data 1). Specifically, it was built using RAxML version 8 ⁷⁹ implemented by the CIPRES Science Gateway ⁸⁰ and it was called as follows: raxmlHPC-HYBRID -f a -n result -s input -c 25 -N 100 -p 12345 -m PROTCATLG -x 12345. The phylogeny resulting from RAxML is consistent with the taxonomic classification of MAGs that resulted from FastTree. Interactive tree of life (iTOL) version 3 ⁸¹ was used for tree visualization and modification.

For phylogenetic placements of functional genes, sequences were aligned using the ClustalW algorithm included in MEGA7 ⁸². All positions with less than 95% site coverage were eliminated. Maximum-likelihood phylogenetic trees were constructed in MEGA7 and evolutionary distances were computed using the Poisson correction method. These trees were bootstrapped with 50 replicates.

Thermodynamic calculations

The values of Gibbs free energy of formation for substances were taken from Madigan et al. ⁸³ and Dolfing et al. ⁵³. The pH used in all calculations was 8.0 as reported in a previous thermodynamic study of deep buried sediments ⁴⁰, partial pressure was 300 atm based on water depths at the three sites (http://docs.bluerobotics.com/calc/pressure-depth/), and temperature was set as 4°C to represent deep sea conditions ⁸⁴. Calculations and corrections based on actual temperatures, pressure, and concentrations followed accepted protocols for determining reaction kinetics and thermodynamics ⁸⁵.