Sousa, Diana Z.

An anaerobic, thermophilic methanogen, designated strain LWZ-6T, was isolated from the Shengli oil field, China. The cells of strain LWZ-6T were non-motile cocci, with a diameter of 0.5–1.0 µm, and formed aggregates. They reduced methanol and monomethylamine into methane, using H2 as an electron donor. Dimethylamine, trimethylamine and methanethiol, H2/CO2, formate, acetate, pyruvate, lactate and glucose were not used as energy sources. Strain LWZ-6T required yeast extract, acetate or CO2 as carbon sources. Strain LWZ-6T grew at 35–65 °C (optimum 55 °C), pH 5.0–8.0 (optimum 6.0–6.5) and 0–60 g l−1 NaCl (optimum 9 g l−1). The genome was 1.54 Mbp with a G+C content of 54.42 mol%. Strain LWZ-6T shared 83.54% 16S rRNA gene sequence identity with Infirmifilum lucidum strain 3507LTT in the class Thermoprotei. Phylogenetic analysis based on the 16S rRNA gene, along with phylogenomic analysis, indicated that strain LWZ-6T belonged to the candidate class ‘Candidatus Methanomethylicia’, which lacks cultivated representatives. Based on these findings, a new species within a new genus, Methanosuratincola petrocarbonis gen. nov., sp. nov., is proposed for LWZ-6T (=CCAM 1872T=JCM 39528T). In addition, we propose the Methanosuratincolia class. nov. for candidate class ‘Ca. Methanomethylicia’ represented by Methanosuratincolaceae fam. nov. and Methanosuratincolales ord. nov. within the phylum Thermoproteota.

Summary An anaerobic enrichment with CO from sediments of hypersaline soda lakes resulted in a methane‐forming binary culture, whereby CO was utilized by a bacterium and not the methanogenic partner. The bacterial isolate ANCO1 forms a deep‐branching phylogenetic lineage at the level of a new family within the class ‘ Natranaerobiia ’. It is an extreme haloalkaliphilic and moderate thermophilic acetogen utilizing CO, formate, pyruvate and lactate as electron donors and thiosulfate, nitrate (reduced to ammonia) and fumarate as electron acceptors. The genome of ANCO1 encodes a full Wood–Ljungdahl pathway allowing for CO oxidation and acetogenic conversion of pyruvate. A locus encoding Nap nitrate reductase/NrfA ammonifying nitrite reductase is also present. Thiosulfate respiration is encoded by a Phs/Psr‐like operon. The organism obviously relies on Na‐based bioenergetics, since the genome encodes for the Na + ‐Rnf complex, Na + ‐F1F0 ATPase and Na + ‐translocating decarboxylase. Glycine betaine serves as a compatible solute. ANCO1 has an unusual membrane polar lipid composition dominated by diethers, more common among archaea, probably a result of adaptation to multiple extremophilic conditions. Overall, ANCO1 represents a unique example of a triple extremophilic CO‐oxidizing anaerobe and is classified as a novel genus and species Natranaerofaba carboxydovora in a novel family Natranaerofabacea .

Microbial communities with the ability to convert long-chain fatty acids (LCFA) coupled to sulfate reduction can be important in the removal of these compounds from wastewater. In this work, an enrichment culture, able to oxidize the long-chain fatty acid palmitate (C16:0) coupled to sulfate reduction, was obtained from anaerobic granular sludge. Microscopic analysis of this culture, designated HP culture, revealed that it was mainly composed of one morphotype with a typical collar-like cell wall invagination, a distinct morphological feature of theDesulfomonilegenus. 16S rRNA gene amplicon and metagenome-assembled genome (MAG) indeed confirmed that the abundant phylotype in HP culture belong toDesulfomonilegenus [ca.92% 16S rRNA gene sequences closely related toDesulfomonilespp.; andca. 82% whole genome shotgun (WGS)]. Based on similar cell morphology and average nucleotide identity (ANI) (77%) between theDesulfomonilesp. in HP culture and the type strainDesulfomonile tiedjeistrain DCB-1T, we propose a novel species designated as “CandidatusDesulfomonile palmitatoxidans.” This bacterium shares 94.3 and 93.6% 16S rRNA gene identity withDesulfomonile limimarisstrain DCB-MTandD. tiedjeistrain DCB-1T, respectively. Based on sequence abundance ofDesulfomonile-morphotype in HP culture, its predominance in the microscopic observations, and presence of several genes coding for enzymes involved in LCFA degradation, the proposed species “Ca.Desulfomonile palmitatoxidans” most probably plays an important role in palmitate degradation in HP culture. Analysis of the growth of HP culture andD. tiedjeistrain DCB-1Twith short- (butyrate), medium- (caprylate) and long-chain fatty acids (palmitate, stearate, and oleate) showed that both cultures degraded all fatty acids coupled to sulfate reduction, except oleate that was only utilized by HP culture. In the absence of sulfate, neither HP culture, norD. tiedjeistrain DCB-1Tdegraded palmitate when incubated withMethanobacterium formicicumas a possible methanogenic syntrophic partner. UnlikeD. tiedjeistrain DCB-1T, “Ca.Desulfomonile palmitatoxidans” lacks reductive dehalogenase genes in its genome, and HP culture was not able to grow by organohalide respiration. An emended description of the genusDesulfomonileis proposed. Our study reveals an unrecognized LCFA degradation feature of theDesulfomonilegenus.