Introduction

Methanogenesis is the terminal step of organic matter mineralization in marine sediments [1]. There are three main pathways producing methane, i.e., hydrogenotrophic (H2/CO2), acetoclastic (acetate), and methylotrophic (e.g., methanol, methylamine, methoxylated benzoate) methanogenesis [2,3,4], with the former two pathways considered dominant. However, the importance of methylated compounds for methanogenesis in marine sediments has been acknowledged in recent years. Geochemical profiles and molecular analysis have shown that methylotrophic methanogenesis is the most significant pathway for methane formation in hypersaline sediments [5, 6] and in the sulfate reduction zone (SRZ) in marine environments [7, 8], where methanol concentration of up to 69 µM had been measured [9, 10]. Especially in the SRZ, methylated compounds are regarded as non-competitive substrates for methanogenesis, since sulfate reducing microorganisms apparently do not compete with methanogens for these compounds [11, 12]; in addition, methylated compounds can be used by marine homoacetogens [13]; however, in marine sediments, evidence for this activity in competition with methanogens has not been obtained so far [14]. In sediments of the Helgoland mud area, specifically, high relative abundances of potential methylotrophic methanogens were observed [15] of which many are unknown. The potential for methylotrophic methanogenesis was recently even predicted from two metagenome-assembled genomes of uncultivated Bathyarchaeota, assembled from a shotgun metagenome [16].

The formation of methane via the three main pathways in methanogenic archaea has been studied intensively [17,18,19]. Much less is known regarding assimilation of carbon into biomass under in situ conditions and to which extent different carbon sources in the environment are utilized. Discrepancies between the predicted pathways known and the actual carbon metabolism measured appear to be based on (1) different cellular functions of carbon dissimilation and assimilation originated from reaction equilibria operative, (2) intermediate carbon cross utilization, and (3) interplay between different microbial communities [18, 20,21,22,23]. For example, mixotrophically growing cultures of Methanosarcina barkeri form their biomass equally from methanol and CO2; however, almost all the methane is formed from methanol rather than from CO2 since methanol is disproportionated to methane and CO2 according to the following reaction:

$$4\;{\mathrm{CH}}_3{\mathrm{OH}} \to 3\;{\mathrm{CH}}_4 + {\mathrm{CO}}_2 + 2\;{\mathrm{H}}_2{\mathrm{O}}$$
(1)

But apart from such culture studies using the nutritionally versatile M. barkeri, the respective contribution of CO2 and methylated carbon substrates to biomass formation during methylotrophic methanogenesis, especially for “obligate” methylotrophic methanogens, in natural sediments has not been studied to date.

Nucleic acids (RNA ~20%, DNA ~3%, of dry biomass, respectively), lipids (7–9%) and proteins (50–55%) are crucial cell components in living microorganisms [24], and thus, suitable markers of carbon assimilation. In order to characterize carbon assimilation capabilities, stable isotope probing (SIP) techniques exist, among which RNA-SIP is very powerful for identifying active microorganisms based on separating 13C-labeled from unlabeled RNA using isopycnic centrifugation [25, 26]. In combination with downstream sequencing analysis, RNA-SIP provides high phylogenetic resolution in detecting transcriptionally active microbes [27, 28] but is limited in its sensitivity by requiring more than 10% of 13C incorporation into RNA molecules for separating 13C-labeled from unlabeled RNA [29]. To date, a number of SIP studies successfully detected methylotrophic bacteria [30,31,32] but the detection of methylotrophic methanogens by RNA-SIP with 13C labeled methyl compounds might be hampered by mixotrophic growth [33].

In contrast to RNA-SIP, lipid-SIP has a lower phylogenetic resolution, but can detect very sensitively δ13C-values in lipid derivatives by gas chromatography combustion isotope ratio mass spectrometry (GC-c-IRMS), thereby facilitating quantitative determination of small amounts of assimilated carbon [34, 35].

In this study, we aimed to identify methylotrophic methanogens by RNA-SIP and elucidate carbon assimilation patterns in marine sediments. We hypothesized that the large pool of ambient dissolved inorganic carbon (DIC) in sediments [7] alters carbon utilization patterns in methylotrophic methanogens compared to pure cultures. To address this hypothesis, we tracked carbon dissimilation into methane and quantified assimilation into lipids by lipid-SIP in slurry incubations and pure cultures. In contrast to known pathways, we found a high degree of methane generation from DIC during methylotrophic methanogenesis by obligate methylotrophic methanogens, i.e., using only methyl groups for methane formation. This mixotrophic methanogenesis from both, methanol and DIC, might be the basis for our observation that more inorganic carbon was assimilated into biomass than could be expected from known pathways.

Materials and methods

Sediment incubation setup for SIP

Sediment was collected from the Helgoland mud area (54°05.23′N, 007°58.04′E) by gravity coring in 2015 during the RV HEINCKE cruise HE443. The geochemical profiles were previously described [15]. Sediments of the SRZ (16–41 cm) and MZ (238–263 cm) from gravity core HE443/077-1 were selected for incubations; typically, sulfate concentration for SRZ sediment is in the range of ~3–25 mM and for MZ sediment is below the detection threshold (~50 µM) as reported in Oni et al. [15]. Anoxic slurries (1:4; w/v) were prepared by mixing sediments with sterilized artificial sea water without sulfate [36]. Slurries of 50 mL were dispensed into sterile 120-mL serum bottles and sealed with butyl rubber stoppers. Residual oxygen was removed by exchanging bottle headspace three times with N2 gas. A 10-day pre-incubation was performed, followed by applying vacuum (3 min at 100 mbar) to remove most of the headspace CO2. Triplicate incubations were conducted by supplementing 1 mM 13C-labeled methanol (~33 mg L−1 slurry) and unlabeled 10 mM sodium bicarbonate (~610 mg L−1 slurry), or 1 mM unlabeled methanol and 10 mM 13C-labeled sodium bicarbonate (13C-labeled substrates provided by Cambridge Isotope Laboratories, Tewksbury, MA, USA) at 10 °C. The proportion of 13C DIC was determined by GC-c-IRMS.

Pure culture setup

The carbon assimilation patterns were compared between SIP sediment incubations and the obligate methylotrophic methanogen, Methanococcoides methylutens. M. methylutens strain MM1 (DSM 16625) was obtained from the German Collection of Microorganisms and Cell Cultures (DSMZ, Braunschweig, Germany). Initial cultivation was performed using medium 280 according to DSMZ protocols. After several transfers of the culture in anoxic marine Widdel medium [37], 5% of the culture were inoculated into fresh Widdel medium supplemented with 30 mM methanol, trace element solution SL 10 [38], and 50 mM sodium bicarbonate (i.e., DIC) with carbon sources containing 5% of 13C-label. Pure cultures were grown at 30 °C in triplicates.

Slurry incubations inoculated with M. methylutens

To test methanogenesis from CO2, incubations were performed with M. methylutens in autoclaved (n = 3) slurry from the SRZ with different amendments of electron donor (H2), electron shuttles (humic acid; anthraquinone-2,6-disulfonic acid—AQDS), and electron acceptors/electron conductors (hematite, α-Fe2O3; magnetite, Fe3O4; Lanxess, Germany). Incubations were separately prepared with 50% H2 in headspace, 100 µM AQDS, 30 mM magnetite, 30 mM hematite and 500 mg L−1 humic acid (Sigma-Aldrich, Steinheim, Germany). The pure culture (5%) was inoculated into these setups, and amended with 20 mM unlabeled methanol and ~10% of 13C-labeled DIC (1 mM) for measuring carbon partitioning into methane. The control incubation comprised autoclaved slurry, 50% H2 and 20 mM methanol without addition of M. methylutens. All experiments were set up with a total volume of 50 mL in 120-mL serum bottles sealed with butyl rubber stoppers, and incubated at 30 °C in triplicates.

Gas analysis

The concentration of methane in the headspace was measured by gas chromatography as previously described [39]. Headspace H2 was determined with a reduction gas detector (Trace Analytical, Menlo Park, CA, USA). Gas samples of 100 µL and 1 mL from triplicate bottles were used for measuring methane and H2, respectively. The parameters for H2 measurement were as follows: carrier gas (nitrogen) 50 mL min−1, injector temperature 110 °C, detector 230 °C, column (Porapak Q 80/100) 40 °C.

The δ13C values of methane and CO2 in the headspace, DIC as well as total inorganic carbon (TIC) in slurries were determined using a Thermo Finnigan Trace GC connected to a DELTA Plus XP IRMS (Thermo Scientific, Bremen, Germany) as described previously [40]. Prior to analyses of δ13C-DIC and -TIC, 1 mL of supernatant or slurry was converted to CO2 by adding 1 mL phosphoric acid (85%, H3PO4) overnight at room temperature.

Nucleic acids extraction, quantification, and DNase treatment

The nucleic acids were extracted according to Lueders et al. [41]. Briefly, 2 mL of wet sediment without supernatant from biological triplicates was used for cell lysis by bead beating, nucleic acid purification by phenol-chloroform-isoamyl alcohol extraction and precipitation with polyethylene glycol. For the RNA extract, DNA was removed by using the RQ1 DNase kit (Promega, Madison, WI, USA). DNA and RNA were quantified fluorimetrically using Quant-iT PicoGreen and Quant-iT RiboGreen (both Invitrogen, Eugene, OR, USA), respectively.

Isopycnic centrifugation, gradient fractionation, and reverse transcription

Isopycnic centrifugation and gradient fractionation were performed according to the previously described method with modifications [41]. In brief, 600–800 ng RNA from biological replicates (n = 3) was combined and loaded with 240 µL formamide, 6 mL cesium trifluoroacetate solution (CsTFA, GE Healthcare, Buckinghamshire, UK) and gradient buffer solution. RNA was density separated by centrifugation at 124,000 × g at 20 °C for 65 h using an Optima L-90 XP ultracentrifuge (Beckman Coulter, Brea, CA, USA). As standard, a mixture of equivalent amounts of fully 13C-labeled and unlabeled E. coli RNA was used in density separation for defining heavy and light gradient fraction density ranges. RNA was quantified and reverse transcription was conducted using the high-capacity cDNA reverse transcription kit (Applied Biosystems, Foster City, CA, USA).

Quantitative PCR (qPCR)

Archaeal 16S rRNA and mcrA genes were quantified from each biological replicate (n = 3) using primer sets 806F/912R and ME2 mod/ME3′Fs 1011 (Table S1), respectively; mcrA encodes the alpha subunit of methyl coenzyme M reductase, a key enzyme of methanogenic and methanotrophic archaea [42]. Standard curves were based on the 16S rRNA gene of M. barkeri and the mcrA gene clone A4-67 for archaea and methanogens, respectively. The setup of PCR reaction was described previously [36]. The qPCR protocol comprised an initial denaturation for 5 min at 95 °C and 40 cycles amplification (95 °C for 30 s, 58 °C for 30 s, and 72 °C for 40 s). The detection thresholds were 100–1000 gene copies with an efficiency of 90–110%.

Sequencing and bioinformatics analysis

Based on the RNA-SIP profiles of E.coli standard RNA (Fig. S1) and previously reported density shifts in SIP fractions [41], “heavy” (1.803–1.823 g mL−1, combination of fraction 3, 4, and 5) and “light” (1.777–1.780 g mL−1, fraction 11) fractions of RNA-SIP samples were selected. Library construction and sequence read processing were as described previously [39].

Lipid analysis

Total lipids were extracted from ~4 g of freeze-dried sediment samples from single-labeling incubations (one substrate labeled, the other unlabeled) using a modified Bligh–Dyer protocol [43]. Intact polar archaeal ether lipids were purified by preparative high-performance liquid chromatography with fraction collection according to the method by Zhu et al. [44]. Considering the origin and complexity of sediment samples and similar proportion of carbon atoms in lipid molecules (archaeol (AR) and hydroxyarchaeol (OH-AR)), phytenes, biphytane, and biphytanes containing cycloalkyl rings (Figs. 3c and S2) were obtained from the intact archaeal lipid fraction [45]. The detailed chromatographic and mass spectrometric parameters were described by Kellermann et al. [46].

δ13C calculation

The proportion of methane from DIC (\({f_{\mathrm{DIC}/\mathrm{CH}_4}}\)) was calculated based on the fractional abundance of 13C (13F) of methane, methanol (MeOH) and DIC in the incubation with 13C-DIC and MeOH. According to a two-end member model, DIC, and MeOH are two main carbon sources for methane production expressed as follows:

$${f_{{\mathrm{DIC}}{/}{\mathrm{CH}}_{4}}}^{13}F_{\mathrm{DIC}} + \left( {1 - f_{{\mathrm{DIC}}/{\mathrm{CH}}_{4}}} \right)^{13}F_{{\mathrm{MeOH}}} = {}^{13}F_{{\mathrm{CH}}_{4}}$$
(2)
$$f_{{\mathrm{DIC}}{/}{\mathrm{CH}}_{4}} = \frac{{\,}^{13}F_{{\mathrm{CH}}_{4}} - {\,}^{13}F_{{\mathrm{MeOH}}}}{{\,}^{13}F_{{\mathrm{DIC}}} - {\,}^{13}F_{{\mathrm{MeOH}}}} \times 100\%$$
(3)

where 13F is obtained from the δ notation according to F = R/(1 + R) and R = (δ/1000 + 1) * 0.011180 [47]. \(^{13}F_{\mathrm{CH}_4}\) and \(^{13}F_{\mathrm{DIC}}\) were the fractional 13C abundance of methane and DIC at harvest time, and \(^{13}F_{\mathrm{MeOH}}\) that of MeOH in the medium at the start.

13C label incorporation ratios from MeOH or DIC in single-labeling experiments were calculated from the 13C abundance increase relative to the 13C label strength via Eqs. (4) and (5). XMeOH and XDIC signify the 13C incorporation ratio from MeOH and DIC, respectively. \(\,{}^{13}F_{t_{\mathrm{end}}}\) and \(^{13}F_{t_0}\) are the 13C fractional abundance of lipids harvested at tend and t0.

$$X_{\mathrm{MeOH}} = \frac{{{\,}^{13}F_{t_{\mathrm{end}}} - {\,}^{13}F_{t_0}}}{{{\,}^{13}F_{\mathrm{MeOH}}}}$$
(4)
$$X_{\mathrm{DIC}} = \frac{{{\,}^{13}F_{t_{\mathrm{end}}} - {\,}^{13}F_{t_0}}}{{{\,}^{13}F_{\mathrm{DIC}}}}$$
(5)

Given that the single-labeling incubations were conducted with the same treatment, i.e., 1 mM methanol and 10 mM DIC, the relative proportion of DIC for lipids biosynthesis (fDIC/lipid) was estimated from the 13C incorporation ratios (XMeOH and XDIC) in these single-labeling incubations as follow:

$$f_{\mathrm{DIC}/\mathrm{lipid}} = \frac{{X_{\mathrm{DIC}}}}{{X_{\mathrm{DIC}} + X_{\mathrm{Me}}}}$$
(6)

Results

Methylotrophic methanogenesis and increase in methanogenic archaea

In order to examine carbon labeling into RNA and lipids of methylotrophic methanogens in anoxic marine environments, sediment slurries amended with or without 13C-methanol (1 mM) and 13C-DIC (10 mM) were incubated at 10 °C. Sediment incubations from the zones of sulfate reduction (SRZ) and methanogenesis (MZ) showed a divergent methane production rate, i.e., methanogenesis finished after 40 and 20 days, respectively (Fig. 1a). In incubations amended with DIC and 13C-methanol, carbon recovery from methanol of ~80% was measured from both sediment incubations (Table S2). Amended 13C-DIC was diluted into the sediment endogenous DIC pool to about 70–84%, which was more obvious in samples from MZ than SRZ (Table 1). In SRZ sediment incubations with 13C-DIC and unlabeled methanol, up to 10.3% of methane originated from 13C-DIC (Table 1).

Fig. 1
figure 1

Dynamics of methane formation and archaeal populations in stable isotope probing (SIP) incubations with SRZ and MZ sediment samples. a Methane concentrations in SIP incubations. Methane data are presented as average values (n = 3, error bar = SD). b Gene copy numbers of archaea (16S rRNA genes) and methanogens (mcrA gene). Gene copies were quantified based on DNA extracts at harvest. Fold increase of gene copies was indicated above each histogram by comparing gene copies on day 0 after pre-incubation (n = 3, error bar = SD). DIC dissolved inorganic carbon, i.e. bicarbonate; MeOH methanol

Table 1 13C fractional abundance and H2 partial pressures in SIP incubations

The dynamics of the archaeal communities in all incubations was tracked by qPCR of archaeal 16S rRNA genes and mcrA genes after methanogenesis ceased (Fig. 1b). Archaeal and mcrA gene copy numbers increased strongly by 10–14 and 19–30 times for all treatment incubations, respectively, while gene copies in control incubations were not elevated (Fig. 1b).

Carbon assimilation into RNA and identification of metabolically active archaea

In preliminary sediment incubations, SIP experiments with 13C-methanol had shown that RNA could not be labeled to a sufficiently high extent to become detectable in heavy gradient fractions (e.g., >1.803 g mL−1) after isopycnic separation of RNA. Contrastingly, methanol dissimilation was strong and archaeal and mcrA gene copies increased compared to that on day 0 and 13C-DIC control, likewise indicating that methylotrophic methanogens were active (Fig. 1a, b and Table S2). Because of mixotrophic assimilation capabilities in methylotrophic methanogens, i.e., utilizing methylated compounds and DIC, a series of SIP slurry experiments were conducted with combinations of methanol and DIC in order to improve the sensitivity of RNA-SIP: double 13C-label (methanol+DIC), single 13C-label (one of the substrates labeled), both substrates unlabeled, and a 13C-DIC control (Figs. 2 and S3). After density separation of RNA, different degrees of RNA labeling were detected in isotopically heavy gradient fractions, e.g., >1.803 g mL−1 (Fig. 2). The strongest 13C-labeling, as indicated by largest amounts of RNA found in gradient fractions >1.803 g mL−1, was detected in RNA from incubations with double 13C-labeling (Fig. 2a), followed by single-label incubations with 13C-DIC. For single-label 13C-methanol incubations, however, RNA fraction shifts according to density were minor compared to unlabeled incubations.

Fig. 2
figure 2

Density distribution of RNA, gene copy numbers, and community composition from SIP incubations with SRZ and MZ sediment after isopycnic separation. a RNA profiles from different RNA-SIP experiments. b Gene copy numbers of archaeal cDNA in heavy fractions (1.803–1.823 g mL−1) from RNA-SIP experiments. Archaeal gene copy numbers refer to the absolute abundance of 16S rRNA gene copies in cDNA from gradient fractions. c Relative abundances of density separated archaeal 16S rRNA from single-labeling incubations in light (1.771–1.800 g mL−1) and heavy (1.803–1.835 g mL−1) gradient fractions

In order to estimate 13C-labeling levels of methanogens in single SIP experiments (13C-methanol or 13C-DIC), a series of molecular techniques were applied including qPCR of cDNA in heavy fractions of RNA-SIP samples, archaeal 16S rRNA sequencing from RNA-SIP fractions and δ13C value determination of methanogen lipids, e.g., phytanes derived from intact polar AR-based molecules. In incubations amended with 13C-DIC and unlabeled methanol, archaeal gene copies were substantially higher than that of 13C-DIC control and 13C-methanol incubations (Fig. 2b). Up to 49,000-fold more RNA molecules were present in the heavy fraction (i.e., 1.803–1.823 g mL−1) compared to the incubation amended with unlabeled DIC and 13C-methanol (Table S3). Correspondingly, Illumina sequencing of RNA revealed that sequences identified as related to the genera Methanococcoides were dominant in SRZ sediment incubations, and the methylotrophic methanogens Methanococcoides and Methanolobus spp. were more dominant in MZ sediment incubations. In contrast to heavy fractions, the abundance of methanogens in the light fractions from double labeling incubations, i.e., 13C-(DIC + methanol), was lowest (~30–60%) (Fig. S3), followed by the incubations amended with methanol and 13C-DIC (~50–70%) (Fig. 2c). SIP incubations amended with DIC and 13C-methanol harbored the highest relative abundance of methanogens in the light fraction, which ranged in abundance from 80 to 90% of total archaea (Fig. 2c). Light fractions were overall mainly composed of anaerobic methanotrophic archaea, Bathyarchaeota, and Lokiarchaeota, except for methylotrophic methanogens (Fig. 2c). For 13C-DIC control incubations, abundances of methanogens were low in SIP samples (Fig. S3). For unlabeled methanol and DIC incubations, given the low amount of labeled RNA in heavy fractions, no amplicons were obtained, but light fractions showed a high abundance of methylotrophic methanogens (Fig. S3). Classifications were confirmed by phylogenetic clustering of cloned 16S rRNA gene fragments (about 800 base pairs) with OTU sequences representing Methanococcoides and Methanolobus spp. (Fig. S4). Sequences of these methanogens accounted for more than 97% of total archaea in heavy gradient fractions. However, known hydrogenotrophic methanogens were undetectable (Fig. 2c), although 3 and 10% of methane was formed from DIC in incubations with MZ and SRZ sediments, respectively (Table 1).

In parallel to RNA-SIP, lipid-SIP incubations with SRZ sediment slurries demonstrated δ13C values of phytane and phytenes being more positive in 13C-DIC and unlabeled methanol treatment than that in 13C-methanol amendments, while the opposite was found in MZ sediment incubations (Fig. 3a). After elimination of 13C-DIC dilution effects by ambient inorganic carbon, DIC contributions to lipids ranged from 59.3 to 86.1% in SRZ sediment incubations, which was constantly higher than that of MZ sediment incubations (52.7–56.4%).

Fig. 3
figure 3

Lipid-SIP experiments from sediment incubations (natural community) and pure cultures in Widdel medium. Lipid δ13C values were measured in homogenized samples after methanogenesis had ceased. a δ13C values of phytanes in sediment incubations with 70% 13C-DIC. Phytane originates from intact polar archaeol lipids, phytenes (phytene I and phytene II) derive from intact polar hydroxyarchaeol lipids. fDIC/lipid are indicated on the top of bars from single-labeling incubations based on Eq. (6). b δ13C values of archaeol (AR) and hydroxyarchaeol (AR-OH) in pure culture of M. methylutens treated with 5% 13C-labeled substrates (methanol or DIC). c Structures of archaeal lipids. Enclosed structures of phytenes in (c) were tentatively assigned according to GC-MS mass spectra (Fig. S6) [80]. Data are expressed as average values (n = 3, error bar = SD)

To understand how carbon is assimilated into lipids by methylotrophic methanogens, pure culture incubations of M. methylutens were performed with 5% of the 13C-labeled substrates (i.e., DIC or MeOH) and the dominating archaeal lipids AR and OH-AR were directly analyzed without cleavage. In contrast to sediment incubations, lipids showed lower fDIC/lipid (~49%) based on the carbon incorporation in single-labeling incubations (Fig. 3b).

Methane formation from DIC during methylotrophic methanogenesis

The high proportion of methane formed from DIC in methanol amended sediment slurry incubations (Table 1) prompted us to investigate the underlying mechanism in more detail. Thus, autoclaved sediment slurries were used as a surrogate of natural sediment, but with all microorganisms killed, and inoculated with the obligate methylotroph M. methylutens. Hematite and magnetite known to serve as electron acceptors or conductors [48, 49] were added along with humic acid, and AQDS as electron shuttles, as well as an additional electron donor (H2), which are all known to stimulate methanogenesis [48,49,50,51]; certain methylotrophic methanogens, e.g., Methanomassiliicoccales spp., require hydrogen for methanogenesis [52, 53].

Methane concentrations in incubations with hematite and humic acid were higher than that of the other incubations after 7 days (Fig. 4a). Although methane production rates were low, methane proportions from DIC in treatments with M. methylutens alone, H2, AQDS and magnetite were much higher (fDIC/CH4, ~10%) than that in incubations with hematite and humic acid (~2%) (Fig. 4b). Linear regression showed a strong correlation between methane production rate and CO2-dependent methanogenesis by methylotrophic methanogens on day 3 and 5 of the incubations, indicating that lower methanogenesis rates triggered higher levels of methane formation derived from 13C-DIC (Fig. 4c).

Fig. 4
figure 4

Methane production from DIC during methylotrophic methanogenesis in autoclaved slurry supplemented with pure culture of M. methylutens. a Total methane concentrations in headspace. b Proportion of methane derived from DIC. Methane proportion from DIC (\(f_{{\mathrm{DIC}}{/}{\mathrm{CH}}_{4}}\)) was calculated according to Eq. (3). Data are expressed as average values (n = 3, error bar = SD). c Linear correlation between methanogenesis rate and methane proportion from DIC after 3 and 5 days. Day 3: Pearson’s r = −0.92, P < 0.001, CI (0.95) = −0.79 > r > −0.97; Day 5: Pearson’s r = −0.85, P < 0.001, CI (0.95) = −0.62 > r > −0.94

Discussion

In this study, we utilized RNA-SIP employing 13C-DIC and methanol and successfully identified methylotrophic methanogens in both, SRZ and MZ sediments of the Helgoland mud area in the North Sea. We demonstrated that the addition of 13C-DIC is necessary to detect label in RNA of methylotrophic methanogens rather than using 13C-methanol as energy substrate alone. We further evaluated carbon utilization patterns of the methylotrophic methanogens by lipid-SIP and identified a high DIC assimilation into characteristic lipids within the SRZ sediment. Isotope probing experiments revealed that up to 12% of methane was formed from DIC by the “obligate” methylotrophic methanogen, M. methylutens, thereby suggesting an explanation for the elevated DIC incorporation into biomass.

Carbon assimilation by methylotrophic methanogens in sediment incubations

Nucleic acids-SIP techniques depend on 13C-labeling levels of DNA or RNA molecules, from which carbon assimilation can be reconstructed and compared to the known pathway of nucleic acid biosynthesis from methyl groups in methanogens [54,55,56,57,58,59]. The current pathways show that only one carbon atom stems from methanol in ribose-5-phosphate while 25–40% of carbon in nucleobases originates from the methyl carbon of the substrate (Fig. 5). This is corroborated by our RNA-SIP experiments using 13C-labeled methanol alone, but RNA was not found to be labeled effectively enough for density separation and further sequence analysis. However, by additionally using 13C-DIC, we found high 16S rRNA copy numbers (Fig. 2b) and a high representation of known methylotrophic methanogens (Fig. 2c) in the heavy RNA gradient fractions, successfully recovering 13C-labeled RNA of methylotrophic methanogens in the SRZ and MZ sediments of the Helgoland mud area. Combined with downstream analysis including qPCR, 16S rRNA sequencing and cloning, we directly show that members of the genus Methanococcoides were the predominantly active methylotrophic methanogens in SRZ incubations, while Methanococcoides together with Methanolobus were dominant in MZ incubations. In addition, archaea with an abundance less than 0.01% showed a higher proportion in light fractions than in heavy fractions (Table S4), excluding the populations under high-sensitivity SIP conditions [60]. A small peak at 1.808 g mL−1 was detected in RNA-SIP profiles from the SRZ incubations amended with 13C-methanol and unlabeled DIC, which originated most likely from methylotrophic methanogens as shown by relative abundances of methanogens in the heavy fractions (Fig. 2c). However, at this density, RNA was partially labeled only because of the lower contribution of methanol carbon to nucleic acid biosynthesis, which resulted in lower RNA amounts in heavy fractions than that of 13C-DIC and unlabeled methanol treatment. Consequently, RNA labeling will be more effective in methylotrophic methanogenic archaea by using DIC than by methanol.

Fig. 5
figure 5

Biosynthesis of nucleotide moieties, the pyrimidine and purine bases, as well as the C5-carbon from 13C-labeled methanol in methylotrophic methanogens based on previous studies [54,55,56,57,58,59] with final carbon contribution from methanol added besides the compounds. Black arrows indicate ribose synthesis and the blue arrows represent synthesis of base moieties in nucleosides. The reverse gluconeogenesis pathway is displayed in green and the reverse ribulose monophosphate pathway in pink

The main reactions of inorganic carbon assimilation are the generation of acetyl-CoA and pyruvate, respectively (Fig. 5). In principle, the generated CO2 from methanol (Reaction 1) can be utilized for biomass synthesis but is in exchange with the large pool of ambient CO2 (at least 10 mM in our experiments, up to 40 mM in marine sediment [7]. Thus, the methane formed by reduction of CO2 will be largely recruited from ambient, unlabeled CO2 molecules [61]. Hence, addition of 13C-labeled DIC or a combination of both substrates labeled enables tracking of methylotrophic methanogens via RNA-SIP techniques. For carbon assimilation into nucleic acids of these methanogens, both proposed biosynthesis pathway of nucleic acid and labeling strategy of RNA-SIP confirmed inorganic carbon as the main carbon source for nucleic acids.

Because of its proven accuracy, lipid-SIP was used for the relative quantification of carbon assimilation into biomass. In lipid-SIP analysis, we evaluated 13C-incorporation into intact polar AR- and OH-AR diether molecules, which are the dominant lipids produced by moderately thermophilic methanogenic archaea [62,63,64], via phytane and phytene side-chain analysis (Fig. 3). These moieties were the only ones being 13C-labeled while tetraether-derived biphytane and cycloalkylated biphytanes as indicators of archaea such as Thaumarchaeota [65], anaerobic methanotrophs [66, 67] or Bathyarchaeota [68] did not show a 13C incorporation (Fig. S5). This was corroborated by our sequencing results demonstrating that methylotrophic methanogens were the dominant archaea in the heavy fractions and that the relative abundances of other archaea were very low or even below detection (Fig. 2c).

By evaluating 13C incorporation into methanogen-derived phytane and phytenes, lipid-SIP provides insight into methanogen activities and carbon utilization. As the main precursors of ether lipids in archaea, biosynthesis of isopentenyl diphosphate (IPP) and dimethylallyl diphosphate (DMAPP) proceeds via the modified mevalonate pathway [69,70,71]. In this pathway, mevalonate-5-phosphate is decarboxylated to IPP, in which three out of five carbon atoms are derived from methanol (Fig. 6). DMAPP is further converted to geranylgeranyl diphosphate, which receives 60% of its carbon from methanol, suggestive of a lower DIC contribution to isoprenoid chains than methanol. This was supported by the fact that AR and OH-AR contained more methanol-derived than DIC-derived carbon using a pure culture of M. methylutens (Fig. 3b). However, unlike the proposed lipid biosynthesis pathway and the pure culture, clearly more DIC was assimilated into lipids than methanol in both sediment incubations, which was most prominent in the sediment from the SRZ (Fig. 3a). We, moreover, detected that ~10% of methane produced was derived from DIC during the SIP experiments and using M. methylutens in autoclaved sediment slurry incubations (Table 1 and Fig. 4). Because of the reversibility of all reactions from CO2 to methyl-tetrahydrosarcinapterin (CH3-H4SPT) [23], it is very likely that part of the DIC is converted to CH3-H4SPT. Thus, CH3-H4SPT generated from CO2 will be available for lipid biosynthesis (Fig. 6) leading to the 13C-enrichment of the lipid pool observed (Fig. 3).

Fig. 6
figure 6

Methylotrophic methanogenesis pathway from methanol (yellow) and carbon assimilation pattern into isoprenoid chains of archaeal lipids (blue) with carbon contribution from 13C-methanol added besides the compounds. The pathway of archaeal lipid biosynthesis is based on previous studies [69, 81, 82]

CO2 reduction to methane by obligate methylotrophic methanogens

There are two types of CO2-dependent methanogenesis: (1) Hydrogenotrophic methanogenesis [2, 4]. These methanogens contain F420-reducing [NiFe]-hydrogenase to catalyze F420 reduction by H2 [72]. (2) Mediation by interspecies electron transfer between bacteria and some members of the Methanosarcinales. CO2 reduction to methane was observed in Methanosaeta and Methanosarcina during syntrophic growth with Geobacter species on alcohols (ethanol, propanol, and butanol), as electrons generated from Geobacter are directly transferred to methanogens to reduce CO2 [73,74,75,76].

Based on our SIP incubations with SRZ sediment showing 10% of methane generation from DIC at low H2 partial pressure (<0.3 Pa) (Table 1) and the overall lack of hydrogenotrophic methanogens in RNA-SIP fractions (Fig. 2c), we argue that H2-dependent methanogenesis does not play a role [2]. Similarly, in autoclaved sediment slurry (Fig. 4b), the “obligate” methylotroph M. methylutens generated methane from CO2 without a hydrogen (or electron) supplying partner microorganism.

Members of the genus Methanococcoides are considered as obligate methylotrophic methanogens since no F420-reducing [NiFe]-hydrogenase was detected in their genomes [69, 77] ruling out hydrogenotrophic methanogenesis in sediment incubations. Nevertheless, part of the methane formed during methylotrophic methanogenesis by M. methylutens was from CO2, especially when methane production rates were low (Fig. 4c). Apparently, at high rates of methanol dissimilation to CO2, the reverse pathway of CO2 reduction to methane was outcompeted. Higher rates of methylotrophic methanogenesis can be achieved potentially by amendments in autoclaved slurries using hydrogen as electron donor, electron conductors (hematite, magnetite) and electron shuttles (humic acid, AQDS); in our incubations, we found humic acid and hematite most strongly stimulating methylotrophic methanogenesis. Although the underlying mechanism is beyond the scope of the current study, methylotrophic methanogens in our incubations could take advantage of hematite as potential electron conductor [48, 49] or humic acid as electron shuttle [51] as indicated by a higher rate of methanogenesis compared to the other treatments (Fig. 4a).

It has been shown that 3% of methane was produced from CO2 during methylotrophic methanogenesis of M. barkeri (i.e., a facultative methylotroph) without the addition of H2 [33], which is similar to about 2.5% of methane generated from CO2 by M. methylutens (i.e., “obligate” methylotroph) in our study (Table S5). However, in SRZ sediment incubations the rate of methane production was lower than in MZ incubations, which resulted in a high proportion of methane generated from CO2 (10%) (Table 1 and Fig. 1). Furthermore, CO2 conversion to methane linked inorganic carbon assimilation into lipids, highlighting the importance of the activity of concomitant CO2 reduction during methylotrophic methanogenesis in marine sediments. In contrast, we found that in pure cultures, under optimal growth conditions, a substantially higher methanogenesis rate decreases the amount of methane produced from CO2. In marine sediment methylotrophic methanogenesis rates are likely lower than those in pure cultures because of the limitation in methylated substrates [7, 18], strongly suggesting that methane generation from CO2 by obligate methylotrophic methanogens is underestimated under in situ conditions. Thus, CO2 conversion to methane has to be considered when estimates of in situ methylotrophic methanogenesis in marine sediments are performed.

In summary, we have shown that 13C-DIC is required as cosubstrate for successful identification of methylotrophic methanogens by RNA-SIP in marine sediments. DIC is the main carbon source for biosynthesis of nucleic acids in these methanogens and thus using 13C-methanol as energy and carbon substrate alone is insufficient in SIP experiments (Fig. 5). Given the intricacies of known assimilatory pathways in methanogenic archaea as a functional group, it might be necessary to at least check for the possibility of DIC as a main assimilatory carbon component in all methanogens for successful SIP experiments. In general, it seems that archaea have a propensity for using DIC as a carbon source for assimilation [68, 78], possibly as an evolutionary adaptation to environments with limited availability of organic carbon [79].

But beyond known pathways, we detected an unexpectedly high amount of methane (>10%) formed from DIC. Especially in SRZ incubations, the lower methane production rates resulted in increased CO2 conversion to methane (~10%), which is linked to CO2 assimilation. This finding strongly suggests that the alleged obligate methylotroph studied here was rather mixotrophically converting both available substrates (DIC, methanol) to methane. Our detailed labeling studies showed that the kinetics of substrate utilization apparently is a decisive factor in channeling more or less CO2 into the pathway of methanogenesis: more methane formed from CO2 when the overall kinetics were slow, and vice versa. From an ecological perspective, DIC is a much more pertinent substrate than methanol (or other methyl compounds) in marine sediments [5, 7], and thus we speculate that more DIC reduction by obligate methylotrophic methanogens occurs in situ than is currently known. A larger proportion of methane formed from DIC in methylotrophic methanogens should also impact interpretation of δ13CH4 values and associated carbon isotope fractionations, which might be overprinted by such mixotrophic methanogenesis. Thus, the CO2 reduction to methane and assimilation into biomass by obligate methylotrophic methanogens plays a much more important role in the environment than was previously known.