Bacterial insect endosymbionts that occupy tissues of their hosts are widespread in multiple insect taxa (reviewed in Perlmutter and Bordenstein, 2020). The nature of such symbiosis may take the form of parasitism, mutualism or commensalism depending on the ecology of the bacterial symbiont. Parasitic bacteria may manipulate reproduction of their hosts, while mutualistic bacteria may provide essential vitamins or participate in nitrogen (N) cycling (Akman et al., 2002; Behar et al., 2005; Sabree et al., 2009). Commensal bacteria can use insects at some part of their life cycle as vectors for transmission to their target host organism, e.g., plants for which they are parasitic (Nadarasah and Stavrinides, 2011). The life strategy of the symbiont depends on the evolutionary history with the host and is driven by the length of its coexistence with the host (Toh et al., 2006). Different bacterial symbionts with distinct evolutionary histories have been described, e.g., in tsetse flies (Glossina sp.). Wigglesworthia glossinidia (Enterobacterales) provides vitamins to the tsetse fly and to other symbionts (Hall et al., 2019) and represents an obligate mutualist with a long coevolutionary history (Chen et al., 1999). Another tsetse fly enterobacterium, Sodalis glossinidius, shows a more recent association with its host as suggested by its relatively large genome that contains a high number of pseudogenes, which remain actively transcribed in a cell-free culture (Toh et al., 2006; Goodhead et al., 2020; Hall et al., 2020). Further hinting at the recent establishment of the Sodalis-tsetse symbiosis was the successful establishment and vertical transmission of the non-native Sodalis population in tsetse flies cleared from their native symbionts. It indicates lack of host-symbiont extensive coevolution (Weiss et al., 2006).

Sodalis endosymbionts are present in other insects with nutritionally restricted diets, such as bloodsucking Diptera (Nováková and Hypša, 2007; Chrudimský et al., 2012), Phthiraptera (Fukatsu et al., 2007; Boyd et al., 2016), sapsucking Hemiptera (Kaiwa et al., 2010) and Coleoptera (Heddi et al., 1999). Multiple Sodalis species have thus been identified within their hosts and shown to supply essential vitamins to the host (Heddi et al., 1999; Boyd et al., 2016). In contrast, only one free-living member of this genus has been described despite the apparent recent establishment of the host-dependent life strategy of the endosymbionts. Sodalis sp. strain HS, later described as S. praecaptivus was isolated from a hand wound of a human impaled with a tree branch (Clayton et al., 2012; Chari et al., 2015). Incidental isolation of Sodalis-related strain from such source was unexpected and as a consequence Sodalis became a textbook example of microbial specialization processes (Yong, 2016).

The genome-wide sequence comparison of Sodalis species shows S. glossinidius and the cereal weevil symbiont S. pierantonius strain SOPE to be closely related to S. praecaptivus. In particular, the S. pierantonius strain SOPE shares high genome similarity with free-living S. praecaptivus, and its symbiosis with the weevil shows evidence of recent origin (Clayton et al., 2012). Despite the presence of numerous pseudogenes, genes of both symbionts represent a subset of the genes in the S. praecaptivus genome, showing that the S. praecaptivus-like ancestor might be the ancestor for symbionts as well (Clayton et al., 2012). The genome characteristics of S. praecaptivus correspond to host-independent life and stabilizing gene selection pressure; in comparison with symbiotic relatives, it has a larger genome, fewer pseudogenes and fewer IS elements (Oakeson et al., 2014). Consequently, due to its wide spectrum of genes and high coding density, S. praecaptivus is able to utilize several carbon (C) sources, including chitin and plant sugars (cellobiose, xylose, rhamnose) and N sources, such as ammonia and nitrate (Chari et al., 2015). While S. praecaptivus is host-independent, it is able to colonize weevils and tsetse flies through quorum sensing suppression of its virulence, which suggests a mechanism of insect symbiosis development in the Sodalis group (Enomoto et al., 2017; Munoz et al., 2020). Despite the well-characterized phylogeny and genome properties of the Sodalis group, a systematic approach to assess the environmental distribution of free-living Sodalis strains has not been performed. It remains to be determined whether there are different levels of relatedness of non-symbiotic strains with symbionts in distinct insect taxa hosts.

Here, we present a Sodalis pangenome analysis that allowed us to characterize different guilds within this genus. Guilds differ in their gene composition as well as in their life strategy. Our results show that the Sodalis genus is functionally versatile with multiple ecological roles. We report novel free-living Sodalis species-level taxon associated in high abundances with decomposing wood, for which we propose the name Sodalis ligni sp. nov. This taxon is represented by the strain dw23^T and can utilize C-rich labile wood-derived compounds and fix atmospheric nitrogen. Sodalis ligni is a globally distributed species that is directly related to symbiotic Sodalis members with characterized genomes while maintaining a non-symbiotic lifestyle and preferring deadwood habitats.

S. ligni was able to grow on laboratory media in which beech wood was the only source of C, reaching a cell density up to 1.3 × 10⁸ mL^–1 within 4 weeks of incubation. This growth excluded the possibility that it is an obligate symbiont of deadwood-associated insects. Hybrid assembly of the Sodalis ligni dw23^T provided 32 contigs (>200 bp, N50: 3.8 Mbp), a total genome size of 6.4 Mbp, GC content 54.96% and a mean coverage of 99×. Assembly of the Sodalis sp. strain dw96 provided 85 contigs (>200 bp, max 0.72 Mbp, N50: 0.25 Mbp), a total genome size of 5.9 Mbp, GC content 54.04% and a mean coverage of 52×. Genome completeness was 98.8 and 99.9% for the Sodalis ligni dw23^T and strain dw96, respectively. Contamination was not detected in the assembled genomes. Sodalis ligni dw23^T was placed within the genus Sodalis (P = 0.211) and belongs to a species not represented in the NCBI database of prokaryotic genomes (P = 0.0025).

We retrieved 11 Sodalis genomes from NCBI together with the strain metadata (Supplementary Table 1). Pangenome analysis divided the available Sodalis genomes into three distinct guilds based on gene frequency (Figure 1). One group consisted of two genomes of Sodalis glossinidius morsitans (strains Sg and ASM), which are tsetse fly endosymbionts. The two Sodalis ligni dw23^T and strain dw96 isolated in this study from deadwood formed the second group together with the free-living Sodalis sp. strain 159R retrieved from NCBI as an anaerobic lignin degrader. The third group consisted of endosymbionts of hymenopteran, hemipteran, dipteran and coleopteran insects. The gene frequency, gene count and genome length of S. praecaptivus have high similarity with the third group of endosymbionts, thus placing this free-living strain distant from deadwood-associated Sodalis sp. strains dw23^T and dw96 despite their relatively high 16S rRNA gene similarity (97.2 and 97.8%, respectively). The ANI between strain dw23^T or strain dw96 and the rest of the analyzed genomes ranged from 76 to 78%, except for strain 159R (98 and 88%, respectively, Figure 1 and Supplementary Table 2). The ANI between strains dw23^T and dw96 was 88%. The genome size of all Sodalis strains and their gene count were closely correlated (ρ = 0.82, P = 0.004), while the genome size and gene counts per Kbp were negatively correlated (ρ = -0.63, P = 0.04). Free-living strains exhibited the lowest coding density (0.87–0.90 genes per kbp) and longer genes than symbionts (947 ± 7 bp and 732 ± 39 bp, respectively, P < 0.01, Supplementary Table 1).

Pangenome analysis allowed us to identify clusters of orthologous genes (COGs) that were shared among strain guilds. Genes shared by all the genomes represent the core Sodalis pangenome (in average 1,747 genes per genome from 1,561 core gene clusters, 35.6% of genes from the average Sodalis genome, Figure 1). The core gene set shared with the Sodalis-like symbionts with extremely reduced genomes is represented by in average 130 genes from only 125 gene clusters. The COG categories with the highest share of classified core genes were translation, amino acid and carbohydrate metabolism, cell wall/membrane biosynthesis and replication categories (Figures 1, 2). Genes shared only among free-living strains were less frequent (in average 109 genes from 106 gene clusters; 2.0% per average free-living Sodalis genome) and were dominated by genes related to carbohydrate metabolism. Gene sharing among wood-associated strains was relatively common (in average 1,596 genes from 1,519 gene clusters, 28.4% per average wood-associated Sodalis genome), these genes were mostly classified in carbohydrate and amino acid utilization and transcription regulation COG categories. The nitrogenase gene nifH and genes encoding an ABC-type molybdate transport system were significantly enriched in the accessory genes of the wood-associated guild (adj. q-value = 0.01). Sodalis ligni dw23^T, Sodalis sp. strain dw96 and Sodalis sp. strain 159R each contained nifHDK operons, while nitrogen fixation genes were absent in other Sodalis genomes. Similar to symbionts, wood-associated strains contained type III secretion system components.

In total, 833 genes encoding carbohydrate-active enzymes from 66 CAZy families were identified across all the genomes. Free-living strains together with the symbiotic Sodalis sp. strain SAL2 contained the highest per-genome share of CAZy, with >1.62% of the total genes being identified as CAZymes (Supplementary Tables 3, 4). Wood-associated strains showed the highest diversity of CAZy, possessing >80% of the detected CAZy families each. The lowest diversity of CAZy (43.9% of detected families) was recorded in tsetse fly-associated strains. CAZy richness in individual genomes was correlated with CAZy abundance (ρ = 0.7, P = 0.02). The distribution of detected CAZymes followed Sodalis guild differentiation, with distinct CAZy patterns for wood-associated strains, tsetse fly symbionts and other symbionts (Figure 3A). Additionally, the functional annotation of CAZy families showed to some extent their conservation within Sodalis guilds (Figure 3B and Supplementary Table 4). In comparison to symbionts, wood-associated strains had more genes for α-glucan, cellobiose, xylobiose and chitin utilization. Genes for cellulose, pectin and hemicelluloses degradation were also detected; however, the counts of these CAZymes were comparable with those in the genomes of symbionts. Glycoconjugate utilization CAZymes were enriched in wood dwellers as well as free-living S. praecaptivus. Lytic polysaccharide monooxygenases (LPMOs) were not detected in the genomes of wood-associated strains.

16S rRNA genes assigned to Sodalis were present in other published community studies from deadwood (see the “Data Availability” section) and typically exhibited high relative abundance. The mean abundance of one Sodalis OTU related to strains dw23^T and strain dw96 at 98.8% similarity was 2.79 ± 0.86% (n = 155, spruce deadwood in Finland, Schigel et al., unpublished data). Another Sodalis OTU (98% similarity to the presented genomes) was found on beech and spruce wood at 0.57–0.70% (Hoppe et al., 2015). When comparing deadwood of 13 tree species after 6 years of decomposition, the broadleaved species Betula sp., Populus spp., Carpinus sp. showed the highest abundance of Sodalis OTU (Supplementary Table 5; Moll et al., 2018). The abundance of other Sodalis OTU (99.6% similarity to the presented genomes) also differed in samples of spruce wood cubes (0.23 ± 0.16%, n = 26) and surrounding soil (0.004 ± 0.002%, n = 30, P < 0.001, Probst et al., 2018). Similarly, sequences assigned to Sodalis (100% similarity) were enriched in decomposing beech trees in Žofínský prales Nature Reserve (0.93 ± 0.48%, n = 24, P < 0.001), when compared to underlying soil (0.0004 ± 0.0002%, n = 48, Šamonil et al., 2020).

The exact mapping of the deadwood metagenomic data to the Sodalis genomes confirmed the higher abundances of the S. ligni, Sodalis sp. strain dw96 and Sodalis sp. strain 159R guild in a deadwood habitat than S. praecaptivus and S. pierantonius strain SOPE (P < 0.001, Figure 4A). For the three wood-associated strains, the average number of exactly mapped reads was 808 ± 220 reads per million reads (812 ± 397 reads per million for S. ligni only). S. ligni showed an even distribution throughout the gradient of deadwood decomposition stages when considering the proportion of mapped reads from the total reads available (Figure 4B). The rate of SNVs per one mapped read was 0.03 ± 0.01 (n = 23), and the density of SNVs against the S. ligni genome showed homogenous Sodalis populations in the deadwood metagenomes, with mean SNVs of 0.17 ± 0.07% except for the outlier population in one young deadwood metagenome (1.7% SNVs, Figure 4B). Most SNVs occurred in the third codon wobbling position (Supplementary Figure 1). Three distinct nifHDK operons were identified in the genome of Sodalis ligni. Two of these operons successfully called reads from two deadwood metatranscriptome samples (SRA accessions SRR10968245, SRR10968250). Notably, the same decomposing tree (BioSample SAMN13762420) served as the source of RNA for the latter metatranscriptome, as well as for the cultivation of S. ligni. Phylogenetic analysis of the nifH gene across the phylum Proteobacteria showed placement of Sodalis nitrogenase genes into distinct clades common to other Enterobacterales, with the exception of one Sodalis ligni nifH placed on a distant branch (Figure 5).

The genus Sodalis represents the model for the development of insect-associated lifestyle and host-symbiont interactions due to its evolutionarily young transition from a free-living to a symbiotic bacterium (Hall et al., 2020; Maire et al., 2020). Moreover, the tsetse fly symbiont Sodalis glossinidius is able to grow independently on its host under laboratory conditions, further pointing to the recent development of its non-facultative symbiosis (Goodhead et al., 2020). Until now, S. praecaptivus was the only free-living species described, which hints that there is a more diversified spectrum of life strategies than only association with insects (Clayton et al., 2012; Chari et al., 2015). Here, we describe two other free-living isolates from the Sodalis genus, one of which, strain dw23^T, is suggested to represent the type strain for Sodalis ligni sp. nov. within the family Enterobacterales. The genome-to-genome alignment of the available Sodalis genomes shows ∼77% ANI with our strain, thus supporting the establishment of a new species within the Sodalis genus (Konstantinidis et al., 2006; Richter and Rosselló-Móra, 2009; Barco et al., 2020). This is supported also by comparison with NCBI database of prokaryotic genomes (Rodriguez-R et al., 2018). In contrast to Sodalis insect endosymbionts, S. ligni occupies deadwood and possesses genome characteristics connected with non-symbiotic life: a larger genome, a higher number of longer genes and a lower coding density (Toh et al., 2006; Oakeson et al., 2014). It refers to independent nutrient provisioning from more complex resources, the necessity for more sophisticated regulatory systems in fluctuating environments and a large effective population of free-living taxa in contrast to their symbiotic relatives (Giovannoni et al., 2014; Bobay and Ochman, 2018). We identified three ecological guilds within the genus Sodalis: tsetse endosymbionts, endosymbionts of other insect taxa and the wood-associated guild presented here. This differentiation is consistent based on ANI and on the functional genome content when considering either all genes or their subset CAZymes.

S. ligni appears in multiple 16S rRNA-based deadwood studies and is usually ranked among the most abundant taxa. Due to the multi-copy character of the 16S rRNA gene (Větrovský and Baldrian, 2013), amplicon studies might provide imperfect abundance estimates. This is true especially for the family Enterobacterales, as the mean number of 16S rRNA genes is 7 ± 0.5 (n = 3,130, Stoddard et al., 2015), which overestimates their abundance when comparing relative counts of 16S rRNA. Seven copies of 16S rRNA were also confirmed in the genome of S. ligni. Hybrid assembly using short and long reads helped to identify their individual copies, which are otherwise usually merged into one consensus copy by the assembler when assembling short reads only (Waters et al., 2018).

Despite the limitations of abundance estimates, amplicon studies showed clear habitat selection of S. ligni, which preferentially colonizes deadwood rather than the underlying soil (Probst et al., 2018; Šamonil et al., 2020). Moreover, Sodalis-related metagenome-assembled genomes are also absent in the recent large-scale cultivation-independent genome catalog, suggesting a low abundance of S. ligni in global soils (Nayfach et al., 2020). We therefore propose that S. ligni is a member of a wood-associated Sodalis guild. The independence of S. ligni from insect hosts is supported by its ability to grow solely on wood. The wood-associated guild further contains the other two isolates, Sodalis strain dw96 and Sodalis strain 159R, the former of which was identified in the present study and the latter was identified in an unpublished study. Other related Sodalis members, the previously described free-living S. praecaptivus and symbiont Sodalis pierantonius strain SOPE, do not show a deadwood preference (Oakeson et al., 2014). While for the symbiont this is not surprising, the main habitat and ecological functions of S. praecaptivus remain to be identified, considering its genome composition (which is closer to symbionts than to wood-associated strains), wood cultivation source and ability to grow in human and insect tissues (Clayton et al., 2012; Enomoto et al., 2017; Munoz et al., 2020). Based on the presence of virulence factors, S. praecaptivus may represent a plant pathogen transmitted by insects (Clayton et al., 2012) and thus may prefer living plants rather than decomposing wood.

Preferential colonization of wood of particular tree species by S. ligni might occur, as was observed in the data from conifers and broadleaved trees (Hoppe et al., 2015; Moll et al., 2018). However, further research across more deadwood types is needed to disentangle potential tree species selection. The abundance of S. ligni in decomposing wood does not seem to vary over tens of years, which is a typical lifetime for decomposing trees in temperate forests (Přívětivý et al., 2016), and the S. ligni population is homogenous with regard to SNVs density.

The core genes shared by all Sodalis strains contain genes for crucial cell functions, mainly translation, replication, transcription, amino acid and carbohydrate metabolism and cell wall/membrane biosynthesis. Furthermore, pangenome analysis unveiled a relatively low number of genes specific for non-symbiotic life, while accessory genes specific for wood-associated guild represent a significant portion of the total identified genes and are involved in, e.g., amino acid and carbohydrate metabolism. Such gene-specific enrichment is connected with a more diverse set of nutrient resources in deadwood habitats. The presence of type III secretion system genes in wood-associated strains might serve as an evolutionary predisposition for host infection by related symbiotic Sodalis members (Maire et al., 2020). The composition of CAZymes of wood-associated strains differentiates them from symbionts as well. Substrates targeted by CAZymes show that wood-associated Sodalis members utilize rather labile plant polymers or chitin to obtain C and do not serve as important cellulose degraders. The broader degradation capabilities were described for other deadwood-associated bacterial taxa such as those from the phyla Acidobacteria and Bacteroidetes (Tláskal and Baldrian, 2021). The ecological function of free-living Sodalis strains might be resolved based on the multiplied presence of nifHDK operons expressing nitrogenase, a key enzyme for nitrogen fixation which is dependent on the metal cofactors (e.g., molybdenum). The sequence difference between nitrogenase variants shows the importance of these genes for the bacterium. To reduce atmospheric nitrogen is energetically costly, and thus, there is probably a selection pressure in the Sodalis deadwood guild to not combine nitrogen fixation with resource-intensive degradation of recalcitrant plant polymers. Nitrogen fixation within the family Enterobacterales is known from taxa living in association with plants (Rosenblueth et al., 2004), with leaf-cutter ant fungus gardens (Pinto-Tomás et al., 2009) and with Diptera (Behar et al., 2005). Deadwood was previously described as a hotspot of nitrogen fixation by which bacteria enrich material with a low nitrogen content and relieve the nitrogen limitation on microbial colonization (Tláskal et al., 2021). Deadwood-associated S. ligni thus represents a candidate for nitrogen fixation and one of the rarely described free-living nitrogen fixing Enterobacterales members.

To conclude, we identified S. ligni as a member of the wood-associated Sodalis guild, and we provide a comprehensive analysis of its genome potential, substrate utilization and ecological function in the context of other known isolated Sodalis sensu stricto strains. Members of the Sodalis genus show broad life strategies with distinct specialization, indicating all-rounder character of this genus, including free-living deadwood inhabitants, non-symbiotic strains with the ability to colonize internal insect and human tissues and recently established symbionts in several insect orders. Such an extensive niche differentiation is known from another enterobacterial species, Escherichia coli (Tenaillon et al., 2010; Luo et al., 2011), but has not been described for Sodalis-related taxa. There is not enough evidence and more isolates from related sources are needed to determine whether deadwood served as a reservoir pool for symbiotic bacteria diversification via genome reduction or whether there was another common ancestor for both wood-associated and insect-associated guilds.

The above methods indicate the programs used for analysis within the relevant sections. The code for reproducing all sequence processing is provided at https://github.com/TlaskalV/Deadwood-Sodalis.

Data described in this manuscript, including raw sequences from short-read sequencing and genome assembly files, have been deposited in the NCBI under BioProject accession numbers PRJNA599932 (Sodalis ligni dw23^T) and PRJNA613885 (Sodalis sp. strain dw96). We further deposited MinION long-read sequencing data in ENA nucleotide archive (PRJEB43208), 16S rRNA sequences of Sodalis clustered in other deadwood studies (10.6084/m9.figshare.13227464), anvi’o pangenome databases (10.6084/m9.figshare.13221065), anvi’o deadwood metagenome mapping databases (10.6084/m9.figshare.13221074) and nifH tree in Newick format (10.6084/m9.figshare.14562279).

VT conceived the study with input from PB. VT performed the strain isolation, pangenome analysis, metagenomic mapping, and strain characterization. LŽ and VP performed the library preparation and sequencing, genome assembly, and annotation. VT and PB wrote the original version of the manuscript. All authors contributed to the final version of the manuscript.

The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.