Introduction

Extracellular polymeric substances (EPS), including polysaccharides, proteins and nucleic acids, aid the adhesion and aggregation of bacteria, and form extracellular scaffolds that promote biofilm formation [1,2,3]. Biofilms have unique three-dimensional structures, with the scaffold providing stratification of physicochemical properties, and enabling different ecological niches to form in response to, for example, oxygen and nutrient availability [4]. Microorganisms embedded within biofilm matrices display emergent properties, such as enhanced stress tolerance, and form synergistic relationships with other microbial populations [5, 6]. Such synergies and micro-domains contribute to microcolony development and allow microbial growth also under bulk conditions of nutrient limitation [1, 7]. Hence, there is a strong need to resolve molecular, structural and functional aspects of microbial EPS and their role in biofilm assembly and function [8]. For example, biofilm community spatial organisation is central to industrial biotechnologies, such as activated sludge in wastewater purification, and the increased virulence of pathogenic biofilms, as exemplified by periodontitis [9,10,11]. Despite their importance for community biofilms, most studies into the roles of EPS in biofilm architecture and function have focused on laboratory cultures of single or defined mixed species rather than naturally occurring biofilms [6, 10, 12,13,14,15,16], which may not realistically represent bioprocesses occurring in environmental or industrial systems.

The biofilm-based multispecies anaerobic ammonium oxidation (anammox) process accounts for up to 80% of oceanic nitrogen losses [17]. It is also employed extensively in industry as a side stream in wastewater treatment processes, where it outperforms conventional nitrogen removal by allowing direct transformation of ammonium to nitrogen using nitrite as an electron acceptor, with minimum requirement for organic substrates [18]. Members of the Planctomycetes perform the anammox process in such communities, with members of Chlorobi, Bacteroidetes, Chloroflexi or Proteobacteria commonly present as co-occurring species [19, 20]. A symbiotic relationship has been described for anammox bacteria and Chloroflexi, which utilise organic matter secreted by anammox bacteria. While Chloroflexi has been suggested to form filamentous scaffolding to facilitate biofilm formation, this is yet to be demonstrated for anammox biofilms [21, 22].

Regardless of habitat, whether natural or engineered, anammox bacteria always express EPS and form biofilms, either floccular, granular or surface-attached, that enable syntrophic relationships with other microorganisms [23]. Residing as microbial consortia enhances nitrogen removal efficiency, increases tolerance to stress, and, crucially for wastewater treatment, improves biomass retention and hydraulic throughput [21, 24]. Hence, anammox biofilms are ideal model systems for understanding the role of EPS in microbial communities. Anammox EPS have accordingly been studied extensively, with the classes of biopolymers present and their impact on biofilm biophysical and mechanical properties, such as attachment, self-aggregation and settleability, being described [25,26,27]. β-sheet proteins, which have been identified as putative surface (S-) layer proteins, are consistently detected in the EPS of anammox biofilms [9, 28]. While S-layer proteins are present extracellularly as a paracrystalline lattice on the outer side of the cell envelope layer of microorganisms, they are not generally recognised as biofilm matrix components per se (i.e., beyond contributing to surface attachment) [29]. However, S-layer protein expression has been shown to correlate with biofilm formation in several species, including Clostridium difficile and Tannerella forsythia [30, 31].

In this study, we resolve the contribution of an EPS to polymicrobial community organisation within an anammox biofilm, and describe the structural and functional roles of the S-layer protein in the extracellular matrix. We analysed the spatial distribution of anammox extracellular protein, BROSI_A1236, within the biofilm, specifically relative to Candidatus Brocadia sinica and Chloroflexi using an antibody raised against it. These bacteria generally predominate in synthetic wastewater-enriched anammox granular sludge [19, 21, 32, 33]. We could thus infer that, in addition to its role as an S-layer protein, the extracellular protein accumulates in the matrix at the biofilm edges as well as at the borders of anammox cell clusters and fortifies junctions in the Chloroflexi network. The S-layer protein-Chloroflexi association builds an EPS-mediated scaffold for the anammox bacteria [22, 34]. These findings inform on the spatial organisation of a key environmental and engineered community biofilm, as mediated by its biopolymers in the biofilm matrix.

Materials and methods

Anammox granules cryosection

Anammox granules collected freshly from a bioreactor [35] were washed twice with 1x phosphate buffer saline (PBS, 137 mM NaCl, 2.7 mM KCl, 10 mM Na2HPO4, and 1.8 mM KH2PO4, pH7.4) followed by fixation with 4% paraformaldehyde (PFA) overnight. The granules were then washed with 1x PBS and placed in 15% sucrose followed by 3:1, 1:1 and 1:3 15% sucrose: OCT (v/v) and finally 100% OCT sequentially overnight. OCT-treated anammox granules were transferred to a square mould and stored at −20 °C overnight. The sample was sliced on Leica CM 1950 cryostat instrument to obtain 2–10 µm thin slices of anammox biofilm on a poly-L-lysine coated slide (Sigma-Aldrich). The slide was then dehydrated for 3 min sequentially in 50%, 70%, and 98% (v/v) ethanol solutions. The slides were air-dried and kept at room temperature for fluorescent labelling.

Fluorescence microscopy

Microscopic imaging was conducted on a Zeiss LSM 780 confocal microscope with a 63x/1.4 oil objective. Briefly, cryosectioned anammox granules were stained with Concanavalin A, Alexa Fluor 594 conjugate (0.2 mg/mL (w/v)), SYTO 9 from BacLight Live/Dead viability stain and SYPRO Ruby stain according to manufacturers’ manuals. All dyes were obtained from Thermo Fischer Scientific.

Microbial community profiling and data analysis

Microbial community profiling of the reactors was conducted weekly [36]. The average abundance of the microbial community at the family level from reactors over two months (k = 6) was used to construct a Krona plot [37]. Metagenomic analysis was carried out on DNA extracted from granules according to a previously described method [38]. Metagenome assembled genomes (MAGs) associated to Chloroflexi were selected and inserted into a species tree [39] in Kbase [40]. The quality of the MAGs was assessed using CheckM for completeness, contamination and strain heterogeneity (SI Table 1) [41].

Protein sequence aligner

Translated protein sequences of BROSI_A1236 were obtained from NCBI (Locus: GAN32721, accession BAFN01000001), and utilised as database for diamond blastx search on Chloroflexi MAGs 1–5, with default settings [42, 43].

Scanning electron microscopy (SEM) and variable pressure SEM (VP-SEM)

Freeze-dried fresh anammox granules were sputtered with 6 nm platinum using Leica ACE200 Sputter coater (Leica Microsystems, Wetzlar, Germany). SEM imaging was performed with Hitachi FlexSEM 1000 II (Hitachi, Tokyo, Japan) at 5 kV at high vacuum image mode using SE detector. For samples without platinum coating, variable pressure SEM (VP-SEM) imaging was performed at 10 kV at 30 Pa using BSE detector.

Antibody generation

Two rabbits were inoculated with purified BROSI_A1236 isolate [35] in a three-month immunisation protocol consisting of three injections on days 0, 7, and 14 (iDNA Biotechnology Pte Ltd). The serum was collected from rabbit antiserum. Crude serum of one rabbit was used as anti-BROSI_A1236 primary antibody.

Binding specificity of the antibody was validated by western blot, a primary antibody concentration-dependent decrease in fluorescence signal, as well as the absence of the fluorescence signal when the primary antibody was omitted (SI Fig. 1).

Immunofluorescence-fluorescence in situ hybridisation (FISH) staining

A slide with cryosectioned anammox biofilm, as described above, was blocked overnight with PBS-T (137 mM NaCl, 12 mM PO43-, 2.7 mM KCl, 0.05% Tween 20, pH 7.4) and 5% (w/v) bovine serum albumin (BSA) at 4 °C. The primary antibody was diluted 200 or 250 times in blocking buffer with RNase inhibitor (0.4 U/µL, Thermo Fisher Scientific) and incubated for 1.5 h at 22 °C. The slide was then washed three times with PBS-T for 5 min followed by incubation with 500 times diluted goat anti-rabbit IgG (H + L)-AF488 or AF405 secondary antibody (Thermo Fisher Scientific) in blocking buffer for 1 h at 22 °C in the dark. The slide was washed three times for 5 min with PBS-T followed by fixing with 4% PFA for 30 min. Next, the fixed slide was washed two times with 1x PBS followed by sequential dehydration using 50%, 70% and 98% (v/v) ethanol solutions for 3 min. FISH was then performed on a dried slide with the probes listed in SI Table 2 [44]. The slide was then viewed using Zeiss LSM 780 confocal laser scanning microscopy. The biovolume of SYPRO Ruby and BROSI_A1236 signal on four biofilms cross-section was quantified using Imaris software.

Image processing using ImageJ

Fluorescence intensity line profiles were obtained by drawing a line across the region of interest with a line pixel width of 18. The colocalisation profile of any two fluorescent channels of interest from the same image acquired was processed by applying Coloc 2 to perform the pixel intensity correlation over the space methods of Pearson. Pearson’s R-value without threshold was used in the data analysis and comparison.

Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of the soluble EPS

Twenty microliters of the crude ionic liquid anammox biofilm extract was denatured in NuPAGE LDS sample buffer (Thermo Fischer Scientific) (1:1 (v/v)) for 10 min at 70 °C and were loaded onto a 12% (w/v) hand-cast polyacrylamide gel, according to the protocol provided by Bio-Rad. The electrophoresis was carried out at 165 V in tris-glycine running buffer (25 mM Tris, 0.192 M glycine, 0.1% (w/v) SDS, pH 8.3) for 60 min. Lane L was loaded with PageRuler Plus Prestained Protein Ladder, 10 to 250 kDa (Thermo Fischer Scientific, 22619).

Immunoblot analysis

After electrophoresis, proteins were transferred from the SDS-PAGE gel to a membrane using an iBlot transfer system (Invitrogen). The polyvinylidene difluoride (PVDF) membrane was blocked with PBS-T and 5% (w/v) bovine serum albumin (BSA) and kept overnight at 4 °C. The primary antibody was then diluted 6000 times in blocking buffer and incubated for 2 h at 22 °C. The PVDF membrane was washed three times with PBS-T for 5 min before incubating with goat anti-rabbit IgG (H + L) secondary antibody, HRP (Thermo Fisher Scientific) diluted 10,000x in blocking buffer for 1 h at 22 °C in the dark. After incubation, the membrane was washed five times for 5 min with PBS-T. For immune detection, the blot was developed in 1:1 (v/v) dilution of SuperSignal West Femto Trial Kit (Thermo Fisher Scientific) to achieve the desired signal intensity. The blot was imaged using Amersham ImageQuant 800 Fluor Biomolecular Imager (cytiva).

Results

Extracellular biopolymers localise in distinct regions of Ca. B. sinica-enriched anammox biofilms

Thin anammox biofilm sections were prepared and stained separately with three selected EPS-specific dyes in combination with a fluorescence in situ hybridisation (FISH) probe specific for the dominant population of Ca. B. sinica, Bsi630 (Fig. 1A–C) [45]. The three EPS dyes used, Concanavalin A (Con A), SYPRO Ruby and SYTO 9, are specific for polysaccharides, proteins and DNA, respectively. The staining patterns demonstrated three compositionally distinct regions within the biofilm section (Fig. 1). The first region encompassed the periphery of the biofilm, which was stained most intensely by Con A and SYPRO Ruby (Fig. 1A, D and Fig. 1B, E respectively with regions identified by white arrowheads). The second region consists of the internal channels between Ca. B. sinica cells, which stained positively to Con A and SYTO 9 (Fig. 1A, D and Fig. 1C, F with regions identified by yellow arrowheads). The final region displayed Ca. B. sinica-cell clusters which were stained by both SYPRO Ruby and SYTO 9 (Fig. 1B, C, E, F).

Fig. 1
figure 1

AC Confocal laser scanning microscopy (CLSM) images of 5 μm anammox biofilm sections stained with Ca. B. sinica-specific FISH probe, Bsi630 (red) and EPS-specific dyes (green) targeting (A) polysaccharides (Con A), (B) proteins (SYPRO Ruby) and (C) nucleic acids (SYTO 9). Three compositionally distinct regions were identified where: (i) the periphery of the biofilm was enriched with polysaccharides and protein-specific stains (identified by white arrowheads); (ii) the internal Ca. B. sinica cell cluster borders were detected by the polysaccharides and nucleic acid-specific stains (indicated by yellow arrowheads); and (iii) SYPRO Ruby and SYTO 9 stained Ca. B. sinica bacterial cells, showing overlapping orange signals in 1B and 1C. DF Single channel extracellular polymer stains of anammox biofilms. Scale bar indicates 20 μm.

Ca. B. sinica cell clusters are demarcated by a filamentous polysaccharide-rich Chloroflexi

Metagenomic sequencing showed a high co-enrichment of Ca. B. sinica (45%) and Chloroflexi (26%) in the laboratory-enriched anammox granules (Fig. 2A). The phylogenetic tree of five metagenome assembled genomes (MAGs) recovered within the Chloroflexi phylum in the biofilm is presented in Fig. 2B. The coexistence of Chloroflexi with anammox bacteria in the biofilm is consistent with a previously described organic-free synthetic nutrient-fed bioreactor [21].

Fig. 2
figure 2

A Krona chart showing taxonomic classification of the laboratory enriched anammox granular biofilm based microbial communities at the phylum level according to 16S amplicon sequencing. B Phylogenetic tree generated using FastTree based on MAGs retrieved from anammox bioreactor metagenomic sequencing data. Only the closest identified sequences were selected. The scale indicates 0.1 nucleotide change per nucleotide position.

FISH microscopy using probes targeting the Chloroflexi phylum (i.e., CFX1223 and GNSB941), along with Ca. B. sinica, confirmed the presence of Chloroflexi in the anammox biofilms (Fig. 3A). The results demonstrated that Ca. B. sinica exists in tightly packed, mono-species clusters, and the Chloroflexi are located predominantly in the channels between and around Ca. B. sinica cell cluster borders as well as at the edge of the biofilm surface, where metabolically active Ca. B. sinica was absent (Fig. 3B, C, colocalisation Pearson’s R value, r = 0).

Fig. 3
figure 3

Confocal laser scanning microscopy (CLSM) images show 10 µm anammox biofilm sections stained with the general Chloroflexi phylum probes CFX1223 and GNSB941 (red) (A, D, and G). These are coupled separately with either (B) the Ca. B. sinica FISH probe, Bsi630 (green), (E) SYPRO Ruby (green) or (H) Concanavalin A (blue). C, F, I are the superimposed images of A and B, D and E, and G and H, respectively, where the white arrows denote the assembly of Chloroflexi filaments at the borders of anammox bacterial cell clusters. Scale bars indicate 20 μm. Scanning electron microscopy (SEM) images showing (J) a highly filamentous and networked structure at the surface of anammox biofilm and (K) an enlarged selected area of anammox biofilm edge in J that is likely made up predominately of filamentous Chloroflexi cells. Scale bars indicate 10 μm.

Localisation of Chloroflexi relative to anammox cells and EPS was assessed using combined extracellular polysaccharide and protein staining. The Chloroflexi, occupying the regions between Ca. B. sinica cell clusters, were only lightly stained, or not at all, by SYPRO Ruby (Fig. 3D–F, r = 0.26). In contrast, a strong Con A signal was observed only at the boundaries of anammox cell clusters and at the outer biofilm edge. The Con A signal overlapped almost entirely with the Chloroflexi FISH probe signal (Fig. 3G–I, r = 0.88).

Scanning electron microscopy (SEM) images of the freeze-dried anammox biofilm revealed the presence of a highly cross-linked network of filamentous bacteria at the edge of the biofilm (Fig. 3J, K and SI Fig. 2). The filamentous network at the biofilm edge is comprised of Chloroflexi, along with EPS matrix material (Fig. 3).

Anammox S-layer protein coats Ca. B. sinica cells and occupies the space surrounding Chloroflexi cells at the edge of the biofilm

The spatial distribution of the dominant extracellular S-layer protein, BROSI_A1236 in the biofilm, relative to Chloroflexi and Ca. B. sinica is illustrated by the thin sliced anammox biofilm sectioned following FISH and immunostaining (Fig. 4). The specificity of the BROSI_A1236 antibody is indicated from western blot analysis of the crude EPS extract (SI Fig. 1) by an intense interaction between the antibody and the 170/200 kDa protein doublet that was previously attributed to BROSI_A1236 of Ca. B. sinica [35].

Fig. 4
figure 4

A Confocal laser scanning microscopy (CLSM) images of a thin anammox biofilm section (3 µm) stained with Ca. B. sinica FISH probe Bsi630 (red), S-layer protein antibody (250x dilution) visualised with Alexa Fluor 488-labelled goat anti-rabbit IgG (green) and general Chloroflexi-phylum probes CFX1223 and GNSB941 (blue). The Ca. B. sinica cell cluster borders are outlined by Chloroflexi bacteria, with (B) Ca. B. sinica S-layer enveloping the anammox bacterial cells and (C) presenting at the edge of the biofilm. D Normalised fluorescence intensity line profile along the dashed line in A (line width = 18) showing the change in interaction between S-layer protein (green), Chloroflexi (blue) and anammox bacteria (red) from the edge (location 1) to the interior (location 6) of the biofilm. E 3-D reconstructed image of A. F 3-D reconstructed anammox biofilm topology in which S-layer protein binds only to the border of the anammox cell clusters as indicated by white arrows. Scale bars indicate 10 µm.

Three distinct S-layer protein binding regions (green) relative to Ca. B. sinica cells (red) were visible across the anammox biofilm section (Fig. 4A–E, SI Figs. 3,  4). The antibody was bound to the envelope of Ca. B. sinica cells within the biofilm (dashed box B, Fig. 4AB). This is further demonstrated by overlapping fluorescent signals for the S-layer antibody and Ca. B. sinica FISH probes in the fluorescence intensity line profile in this region (Fig. 4D, region 3, red and green lines respectively). This observation provides further evidence that the anammox extracellular protein is an S-layer protein [35].

The S-layer protein also appeared at the edge of the biofilm, along with Chloroflexi and where Ca. B. sinica is largely absent (Fig. 4A, dashed box C and Fig. 4C). In this region, the S-layer protein occupied the space around the Chloroflexi (Fig. 4A, regions 1 and 4 of line 4D; SI Fig. 5), which is in contrast to the polysaccharides that only coat the surface of the Chloroflexi (Fig. 3H, I). The Diamond sequence aligner run against all Chloroflexi returned no match for BROSI_A1236 to any Chloroflexi MAGs. Furthermore, no other major microbial population was observed at the edge of the biofilm (SI Fig. 6).

Additionally, in another region close to the surface of the biofilm (dashed box F of Fig. 4E), some Ca. B. sinica cells were not labelled by the S-layer protein antibody. There is, however, an intense S-layer protein antibody signal at the border of this cluster (indicated by white arrows in Fig. 4F). This demonstrates that the antibody is selective and that the S-layer proteins may not necessarily be present on the surface of all anammox cells in the community.

Anammox S-layer protein coincides with Chloroflexi at the junctions of Chloroflexi structural networks

The association between Chloroflexi and the S-layer protein also depends on the proximity to the biofilm surface. Chloroflexi and S-layer proteins coexist towards the outer edge of the biofilm (Fig. 4C), as indicated by the elevated fluorescent signals at the biofilm surface (Fig. 4D, region 1, green and blue lines). The S-layer protein antibody signal also coincides with the Chloroflexi at junctions in the Chloroflexi network (Fig. 5A–C), particularly towards the outer edge (Fig. 5C) rather than the interior of the biofilm (Fig. 5B and SI Fig. 7).

Fig. 5
figure 5

Confocal laser scanning micrographs (A, B, C) and scanning electron micrographs (D, E, F, G) showing (A) filamentous Chloroflexi cell (labelled by Chloroflexi-phylum probes CFX1223 and GNSB941, blue) demarcating anammox bacterial cell clusters (labelled by Ca. B. sinica FISH probe Bsi630, red) in cross-linked network with (B, D) weak and (C, E) strong S-layer protein (labelled by S-layer protein antibody and visualised with Alexa Fluor 488-labelled goat anti-rabbit IgG, green) associations. Regions marked by white dotted lines in E are likely S-layer proteins that assemble Chloroflexi cells in the structural lattice. F, G show filamentous Chloroflexi cells forming a cross-linked framework with junctions (i.e., intersections formed by two or more filamentous Chloroflexi cells) that are coated and non-coated with extracellular matrix biopolymer. Blue solid lines in G trace Chloroflexi filaments in the biofilm. Scale bars indicate 10 μm in A, B, C and 5 μm in D, E, F, G. Yellow lines in images B, C indicate regions where fluorescence intensity line profiles of interactions between S-layer protein and Chloroflexi cells were plotted in SI Fig. 7 Figure 5A was imaged at the layer distal from the surface of the anammox biofilm cross-section. Therefore, most of the antibody staining was observed at the edge of the biofilm.

The EPS that overlapped with Chloroflexi cells, as shown in SEM images (Fig. 3J, K), is proposed to be S-layer protein, as demonstrated by immunofluorescence staining (Fig. 5B–E). The SEM images showed filamentous bacteria embedded by an extracellular matrix and forming a 3-D scaffold (Figs. 3K5). The extracellular matrix coating the Chloroflexi at the nodes of the filamentous framework is denoted by white dotted lines in Fig. 5E. This was observed across multiple regions in SEM images (SI Fig. 8). More than 80% of the Chloroflexi junctions were coated by the extracellular matrix biopolymer, as determined by tracing the filamentous network and identifying junctions as either matrix-associated or non-matrix-associated (see Fig. 5F, G for the representative images; i.e., 105 out of 119 junctions were matrix-associated, as determined by several images. Refer to SI Fig. 8 for remaining images).

Potential pathways for succession of BROSI_A1236 from surface protein to EPS

The anammox biofilm cross-section in Fig. 6A highlights the various forms in which BROSI_A1236 exists in the biofilm, relative to the Chloroflexi. The S-layer protein initially forms well-defined closed or partially closed surface protein rings (Fig. 6B) that coalesce to form extended chains (Fig. 6C). These subsequently develop into aggregates of larger assemblages within anammox clusters (Fig. 6D) and finally form assemblages that coat the Chloroflexi cells (Fig. 6E). In the larger BROSI_A1236 assemblages surrounding Chloroflexi cells, traces of the original BROSI_A1236 ring structure can still be discerned (Fig. 6D, E). The same image including a Ca. B. sinica signal indicates that Ca. B. sinica co-occurs with BROSI_A1236 aggregates in the internal regions of the biofilm as the latter begins to coat the Chloroflexi cells (SI Fig. 9). Moreover, the same traces of the surface protein rings coating the Chloroflexi in the absence of Ca. B. sinica, are also visible in the border regions of the biofilm (Fig. 4C).

Fig. 6
figure 6

Different morphologies of S-layer protein (250x dilution, identified using S-layer protein antibody and visualised with Alexa Fluor 488-labelled goat anti-rabbit IgG, green) relative to Chloroflexi (identified using Chloroflexi-phylum probes CFX1223 and GNSB941), suggesting (A) S-layer protein transitions from enveloping cell surface to an EPS and matrix stabilising agent. B S-layer protein expressed as surface layer protein by anammox bacteria, covering the cells as a complete (white arrowhead 1), partially (white arrowhead 2) or fully opened (white arrowhead 3) ring structure. C These closed and partially closed rings then start to coalesce, D Consolidate further into an aggregate of S-layer proteins, and (E) finally start aggregating around Chloroflexi cells (the Chloroflexi FISH probes labelled cells are highlighted with white dotted lines). Scale bar indicates 10 μm.

Discussion

This study reveals a strong association of the S-layer protein BROSI_A1236 with the envelope of Ca. B. sinica cells. The S-layer protein also contributes to a thick extracellular matrix layer at the edge of the biofilm surface and in close proximity to Chloroflexi. The filamentous Chloroflexi assemble into a cross-linked network throughout and at the surface of the anammox biofilm, and the Ca. B. sinica S-layer protein is present at network junctions. The intensity of the western blot signal for antibody binding to the high molecular weight protein doublet in the crude EPS that was previously identified as the surface protein, BROSI_A1236 of Ca. B. sinica, was high relative to other proteins [35]. Low level binding of the antibody to lower molecular weight proteins is visible in the western blot, and it is possible that some of the signals in the immunofluorescence microscopy images result from non-specific binding (SI Fig. 1). Nonetheless, overlaying the general protein stain (i.e., SYPRO Ruby) with the BROSI_A1236 immunofluorescence (SI Fig. 10) shows that, while BROSI_A1236 is abundant, it represents only a small fraction of the protein signal on the biofilm cross-section, further indicating antibody specificity (approximately 20% biovolume). This, along with the inability of any Chloroflexi to express BROSI_A1236 and the absence of any other major microbial populations within the regions where Chloroflexi and the surface protein co-localise at the biofilm borders (SI Fig. 6), suggest that Chloroflexi has acquired the S-layer protein that is secreted by Ca. B. sinica. Hence, the surface layer protein likely facilitates another species to form a structural scaffold and act as an adhesive as well as EPS. The Chloroflexi network in turn accommodates clusters of anammox cells. Thus, Ca. B. sinica secretion of the S-layer protein enables the organisation of a cooperating community into a biofilm structural matrix for the benefit of the whole community.

We have demonstrated that the S-layer protein is secreted by the Ca. B. sinica and transported to the biofilm edge; however, the means by which this is achieved is not clear. No paracrystalline structures were observed in the matrix at the edge of biofilm, although this could possibly be due to insufficient resolution of the SEM used here (Fig. 5E–G). Nonetheless, the transport of the S-layer protein from the cell surface to the biofilm surface likely involves the S-layer protein transitioning between different phases or states, as illustrated in Fig. 6. Several mechanisms exist by which the S-layer protein could achieve this. The anammox biofilm S-layer protein possesses intrinsically disordered repeat domains (IDRs) at the C-terminus, which could facilitate phase transitions and the passaging of the S-layer protein through the matrix [45, 46]. Alternatively, the glycosylated S-layer protein could adopt different proteoforms throughout the biofilm (e.g., glycosylated or unglycosylated forms) to facilitate the transition of S-layer protein to cells in the biofilm and its transformation into EPS [47,48,49].

The heterotrophic Chloroflexi metabolise anammox EPS [21]. The close association between Chloroflexi cells and the S-layer protein described in this study suggests that the EPS metabolised by Chloroflexi could be the anammox S-layer protein (Fig. 5). Con A staining showed a strong overlap of polysaccharides with Chloroflexi cells within internal anammox cell cluster channels, and at the biofilm surface (Fig. 3). This indicates that the polysaccharide is located on the cellular surface of the Chloroflexi (i.e., as capsular), as opposed to the extracellular biopolymer, which encompasses the Chloroflexi cells, as illustrated in the SEM images (Fig. 5E–G). Based on the experimental spatial localisation of the S-layer protein, the anammox exoprotein is proposed to enable anaerobic growth, gluconeogenesis and subsequent expression of the polysaccharide capsule of Chloroflexi [50, 51]. In addition to benefitting Ca. B. sinica by establishing a biofilm scaffold that accommodates necessary synergistic relationships, the carbon dioxide produced from fermentation of the S-layer protein by Chloroflexi would also be available to the anammox bacteria for carbon fixation via the Wood-Ljungdahl pathway for subsequent biomass precursor production [52]. The S-layer protein could therefore function as a “public-good” exopolymer and coordinate the organisation of key populations in a polymicrobial biofilm (Fig. 7) [53, 54].

Fig. 7
figure 7

A proposed model of Ca. B. sinica coordinated assembly of filamentous Chloroflexi cells into anammox biofilm structural scaffold through excretion of S-layer protein, BROSI_A1236 as an EPS.

Mixed species biofilms are the dominant microbial life form in environmental and industrial settings [14, 55]. However, there are few examples where the distribution of specific EPS has been described relative to key microbial populations. To the authors’ best knowledge, the anammox biofilm results provided here constitute the first report of such a structure-function relationship for industrial or environmental biofilms. The S-layer protein was, however, previously observed on anammox bacterial cell surfaces, and it has been detected in the extracellular extracts from anammox biofilms enriched in different anammox bacterial species [56]. The inability to confirm its function as an EPS arose from a lack of means to visualise the protein (Figs. 1B, 3E, and SI Fig. 10).

This study describes how EPS may mediate structure, composition and function in a model mixed-species biofilm [57]. We propose that anammox cells use the S-layer protein to promote cellular adhesion and microcolony formation within a structural scaffold established by the second most abundant population (i.e., Chloroflexi) in the biofilm community. The spatial location and succession of the S-layer suggests it has a moonlighting role as a Chloroflexi cross-linking network and stabilising material as well as a driver for biofilm community assembly (Fig. 7). High co-enrichments of Chloroflexi and Ca. Brocadia in anammox bioprocesses, and a scaffold-building function for Chloroflexi in providing a network for cells and microcolonies to adhere and aggregate have been described in activated sludge and anammox biofilms [23, 58,59,60,61,62]. These findings may have direct implications in activated sludge microbiology [22]. Following the first description of an anammox S-layer glycoprotein [56], BROSI_A1236 and its homologues have been identified as a common feature of anammox biofilms and, more recently, as an EPS [35, 45, 63]. There is increasing interest in all aspects of this glycoprotein, including understanding how it is glycosylated [64], and its function as an EPS. While our work provides additional insight into its function in enabling community assembly, it also suggests a key role for S-layer proteins in the formation of biofilms. Overall, this work highlights the importance of the spatial organisation for syntrophic relationships within mixed species microbial biofilms [55, 65] and may underpin strategies for optimising anammox bioprocesses, such as increasing biofilm stability or reducing bioprocess start-up times [45, 66].