Abstract
Biofilm formation has been shown to be critical to the success of uropathogens. Although Staphylococcus saprophyticus is a common cause of urinary tract infections, its biofilm production capacity, composition, genetic basis, and origin are poorly understood. We investigated biofilm formation in a large and diverse collection of S. saprophyticus (n = 422). Biofilm matrix composition was assessed in representative strains (n = 63) belonging to two main S. saprophyticus lineages (G and S) recovered from human infection, colonization, and food-related environment using biofilm detachment approach. To identify factors that could be associated with biofilm formation and structure variation, we used a pangenome-wide association study approach. Almost all the isolates (91%; n = 384/422) produced biofilm. Among the 63 representative strains, we identified eight biofilm matrix phenotypes, but the most common were composed of protein or protein–extracellular DNA (eDNA)–polysaccharides (38%, 24/63 each). Biofilms containing protein–eDNA–polysaccharides were linked to lineage G and environmental isolates, whereas protein-based biofilms were produced by lineage S and infection isolates (p < 0.05). Putative biofilm-associated genes, namely, aas, atl, ebpS, uafA, sasF, sasD, sdrH, splE, sdrE, sdrC, sraP, and ica genes, were found with different frequencies (3–100%), but there was no correlation between their presence and biofilm production or matrix types. Notably, icaC_1 was ubiquitous in the collection, while icaR was lineage G-associated, and only four strains carried a complete ica gene cluster (icaADBCR) except one that was without icaR. We provided evidence, using a comparative genomic approach, that the complete icaADBCR cluster was acquired multiple times by S. saprophyticus and originated from other coagulase-negative staphylococci. Overall, the composition of S. saprophyticus biofilms was distinct in environmental and clinical isolates, suggesting that modulation of biofilm structure could be a key step in the pathogenicity of these bacteria. Moreover, biofilm production in S. saprophyticus is ica-independent, and the complete icaADBCR was acquired from other staphylococci.
Keywords: Staphylococcus saprophyticus, evolution, pan-GWAS, WGS, biofilm structure, ica cluster, urinary tract infection
Introduction
Staphylococcus saprophyticus is a uropathogen associated with 10–20% of urinary tract infection (UTI) in sexually active young women worldwide (Raz et al., 2005; Kline and Lewis, 2016). Possible complications such as acute pyelonephritis, urethritis (Hovelius et al., 1984), and endocarditis (Garduño et al., 2005; Choi et al., 2006), especially in immunocompromised individuals, have been documented. S. saprophyticus is a frequent colonizer of the human gastrointestinal tract, cervix, urethra, vagina, perineum, and rectum (Latham et al., 1983; Rupp et al., 1992). Also, it colonizes the gut and skin of food-producing animals (Hedman et al., 1993), which could serve as a source of contamination of food-related environments.
The success of S. saprophyticus as a uropathogen is due to its ability to survive in harsh and toxic conditions, which is provided by the accumulation of genetic determinants encoding high resistance to heavy metals (Lawal et al., 2021b) and detoxification of uric acid and D-serine (Gatermann and Marre, 1989; Korte-Berwanger et al., 2013). Moreover, S. saprophyticus pathogenicity has been described to be associated with its capacity to adhere to uroepithelial cells promoted by adhesins, surface proteins, and biofilm production (Kuroda et al., 2005; Martins et al., 2019).
Previous studies mainly done on uropathogenic Escherichia coli have shown that biofilm is an important pathogenicity factor in either medical device-associated UTI (Jacobsen et al., 2008) or cystitis (Anderson et al., 2003; Rosen et al., 2007; Blango and Mulvey, 2010). In particular, it was demonstrated in a mouse model of cystitis that E. coli and Klebsiella pneumoniae can exist in biofilm-like large aggregates of bacteria (pods or intracellular bacterial communities) in the bladder epithelial cells, a phenomenon that was suggested to be responsible for recurrent cystitis (Anderson et al., 2003; Rosen et al., 2007; Blango and Mulvey, 2010). The importance of biofilm for UTI was additionally shown during occurrence of urinary stones/calculi by urease-producing bacteria (Norman and Stamey, 1971; McLean and Nickel, 1994). Regarding S. saprophyticus, the role of biofilm on pathogenesis was mainly evidenced by the occurrence of medical device-associated UTI (Hovelius et al., 1984; Choi et al., 2006; Magarifuchi et al., 2015), but it remains to be demonstrated whether biofilms formed by these bacteria are also implicated in cystitis or urinary stones.
Biofilms are organized bacterial cell communities contained in an extracellular matrix that mediate adherence to abiotic and biotic surfaces (Heilmann et al., 2003; Izano et al., 2008; Tojo et al., 2009; Fagerlund et al., 2016). Biofilms play a significant role in an array of infections, namely, medical device associated, valve endocarditis, and UTI (O’Gara, 2007; Becker et al., 2014). Bacterial cells within the biofilm matrix exhibit phenotypic characteristics different from those of planktonic or free-living cells (Martins et al., 2019). For instance, free-living bacteria cells that are susceptible to antibiotics sometimes become resistant or tolerant to such antibiotics or other antimicrobial agents in the matrix (Martins et al., 2019). In fact, S. saprophyticus biofilms were reported to be resistant to antibiotics used in the empirical treatment of UTI and to biocides used for decontamination because of the protective function of the biofilm against the action of these agents (Fagerlund et al., 2016; Martins et al., 2019). Additionally, biofilms constitute effective barriers against host-immune evasion and low urine pH (Becker et al., 2014; Heilmann et al., 2019). Biofilm could also be a hotspot for horizontal gene transfer and a risk for development and dissemination of multidrug-resistant strains (Baker-Austin et al., 2006; Fagerlund et al., 2016; Martins et al., 2019).
The composition of the biofilm matrix could be different between species and from strain to strain (Fagerlund et al., 2016), but the biofilm matrix is essentially composed of bacterial cells embedded in polysaccharides, extracellular DNA (eDNA), and proteins. In staphylococcal biofilms, polysaccharide intercellular adhesin (PIA) is one of the main components. PIA is a homoglycan with beta-1,6-linked N-acetylglucosamine residues and de-N-acetylated amino groups in its composition (Mack et al., 2016). The synthesis of PIA in biofilm formation is mediated by an operon (icaADBCR). This comprises the N-acetylglucosamine transferase icaA that synthetizes PIA oligomers from UDP-N-acetylglucosamine and the product of icaD, which gives optimal efficiency to icaA (Arciola et al., 2015). The icaB encodes N-deacetylase and is involved in the partial deacetylation of PIA. The product of icaC is involved in the export of the polysaccharide, while icaR is the negative transcriptional regulator of the operon (Rohde et al., 2010; Arciola et al., 2015).
Extracellular DNA has been described in staphylococcal biofilms from Staphylococcus aureus (Eckhart et al., 2007; Izano et al., 2008) and Staphylococcus epidermidis (Qin et al., 2007; Izano et al., 2008) and was described to be part of the biofilm of two clinical strains of S. saprophyticus (Soumya et al., 2017). Staphylococcal biofilms are often additionally composed of surface-associated and cell wall-anchored proteins such as microbial surface components recognizing adhesive matrix molecules, which are essential for different stages of attachment to surfaces and biofilm accumulation (Jönsson et al., 1991; Patti et al., 1994). Other commonly found proteins associated with proteinaceous biofilm in staphylococci are autolysins/adhesins such as AtlE, Aap in S. epidermidis, and Bap in S. aureus (Heilmann et al., 1997; Cucarella et al., 2001; Hirschhausen et al., 2012). In spite of the clinical relevance of S. saprophyticus biofilms, its composition remains unclear.
A recent study showed that S. saprophyticus causing UTI in humans belonged to two major clonal lineages (G and S) that originated in food/production animals and humans, respectively, (Lawal et al., 2021a). However, it is still unknown if the mechanisms of disease caused by the two lineages are related.
In this study, we aimed to explore the heterogeneity in matrix composition of biofilms produced by S. saprophyticus and to explore how biofilm phenotypes are distributed in the population and how they correlate with genetic content.
Materials and Methods
Ethical Considerations
The human isolates were recovered as part of the routine clinical diagnostic testing; ethical approval and informed consent were not required. All data were handled anonymously. Sample collection was in accordance with the European Parliament and Council decision for the epidemiological surveillance and control of communicable disease in the European community1. Slaughterhouse samples were part of the routine control practices for evaluation of good hygiene practices and programs to assure meat safety (CE No. 853/2004).
Bacterial Collection
We assembled a large collection of 422 Staphylococcus saprophyticus isolates recovered in seven countries from human infection and colonization as well as food-related environment between 1997 and 2017 (Supplementary Table 1). Out of a total number of biofilm producers (n = 384), we selected 63 strains with high biofilm production representing the different phylogenetic clusters identified when isolates were studied by single-nucleotide polymorphism (SNP) analysis (Lawal et al., 2021a). The selected isolates comprised isolates from both clonal lineages G (n = 42) and S (n = 21; Supplementary Figure 1). Selected strains were recovered from human infection and colonization (n = 47) and food-related environment (n = 16; Supplementary Table 2).
Biofilm Formation Assay
We assessed the biofilm formation capacity in 422 S. saprophyticus using the modified polystyrene microtiter plates in a static condition as previously described (Stepanović et al., 2000; Stephanovic et al., 2007). Briefly, a colony from an overnight culture was suspended in tryptic soy broth (TSB) and grown overnight at 37°C with aeration. The culture was adjusted to 0.5 McFarland standards with TSB supplemented with 1% glucose (w/v; BDH, England; TSBsG); and each suspension was inoculated onto 96-well microtiter plates (Corning Inc., United States) and incubated at 37°C for 18 h. The free-floating planktonic bacteria from each well were removed and washed (4×) with sterile distilled water. Attached cells were heat fixed at 60°C for 60 min and stained with 0.06% crystal violet; and excess dye was removed by washing (4×) with sterile deionized water. The plates were air-dried at room temperature. Biofilm produced by each isolate was quantified by adding 30% acetic acid to each well, measured for absorbance at OD595 nm, and classified as described below (Stephanovic et al., 2007). The assay was done in triplicates. S. epidermidis RP62A and TSB were used as positive and negative controls, respectively.
Classification of Biofilm Production
The method of Stephanovic et al. (2007) was employed to classify the biofilm production. Briefly, the average OD595 nm of the four blank wells (TSB only) was calculated, and the ODc was obtained by applying the following formula: ODc = AverageOD595 nmblank + 4 ∗ Standard Deviationblank. The final optical density (OD) value of an isolate was expressed as average OD value of the strain less ODc. Biofilm formation for each test strain was classified as follows: OD ≤ ODc = no biofilm produced; ODc < OD ≤ 2 × ODc = weak biofilm producer; 2 × ODc < OD ≤ 4 × ODc = moderate biofilm producer; and 4 × ODc < OD = strong biofilm producer.
Biofilm Detachment Assay
We used three biofilm-detaching agents previously described (Fagerlund et al., 2016; Sugimoto et al., 2018; Tasse et al., 2018), namely, Proteinase K (100 μg/ml, Sigma-Aldrich, St. Louis, United States), DNAse I (100 μg/ml, Sigma-Aldrich, St. Louis, United States), and sodium periodate (50 mM, Sigma-Aldrich, St. Louis, United States; prepared in sodium acetate buffer), which disperse biofilm matrix composed of protein, eDNA and polysaccharide, respectively. Biofilms were grown in microtiter plates in TSBsG for 18 h, as described above. The planktonic cells were removed, and the plates were washed with distilled water (4×). The disruptor was added to each well and incubated for 2 h at 37°C. For the control wells, only buffer was added instead. The suspensions were removed; the plates were washed, heat fixed, and stained with crystal violet as described above. Biofilm remaining after treatment with disruptors was determined by comparing the test assays with their respective control. The main component of the biofilms produced by each representative isolate was assessed and classified as described below. All assays were done in triplicates.
Biofilm Composition and Definition of Biofilm Types
To determine the relative biofilm composition, we compared the biofilm biomass of each strain after disruption with its corresponding control (without disruptors) expressed in percentage (%), as previously described (Kogan et al., 2006; Fagerlund et al., 2016). Isolates with >70% reduction in biofilm after treatment with specific biofilm detaching agents were interpreted to be composed of the component targeted by the disruptor (Fagerlund et al., 2016); isolates with 30–70% reduction in biofilm after disruption were classified as partially composed of these components; and isolates with <30% biofilm reduction after disruption were considered as not containing the component (Kogan et al., 2006; Fagerlund et al., 2016).
Whole-Genome Sequencing and Assembly
Paired-end sequence reads produced on an Illumina MiSeq with an average coverage of 103 per genome reported in Lawal et al. (2021a) with the accession number PRJNA604222 were retrieved from sequence read archives. Low Q-score ends (Q < 20) were trimmed of the Illumina reads using Trimmomatic v0.36 (Bolger et al., 2014). Reads were assembled using SPAdes v3.11.1 (Bankevich et al., 2012). QUAST v5.1 (Gurevich et al., 2013) was used to evaluate the quality of assemblies. All contigs with <200-bp size were removed.
Phylogeny Reconstruction and Comparison
Single-nucleotide polymorphism-based phylogeny of all S. saprophyticus isolates in the collection and the representative strains was done separately using CSIPhylogeny v1.4 (Kaas et al., 2014) with the default parameters. Maximum likelihood trees were reconstructed using RAxML v8.2.12 (Stamatakis, 2014). The general time reversible model was performed with 100 bootstrap resampling for node support. Phylogenetic trees were re-rooted midpoint and visualized using web-based tool microreact (Argimón et al., 2016).
Genome Annotation and Pangenome Construction
Genomes were annotated using Prokka v1.14.6 (Seemann, 2014). The pangenomes of the representative strains (n = 63) and those of the entire collection (n = 422) were defined using Roary v3.13.0 (Page et al., 2015) with 85% BLASTp homologues clustering with split paralogues. The accessory genomes were defined as the pan minus the core genome. Pangenome-wide association study (pan-GWAS) approach was used to determine the association between genomic, demographic, and phenotypic data using Scoary v1.6.16 (Brynildsrud et al., 2016). Genes with a Benjamini–Hochberg p value < 0.05 and odds ratio > 1, with no duplicated function in the pangenome, were considered.
Comparative Genomic Analysis
The nucleotide sequences of genes of interest found in the collection were compared using blast (blastn) analysis (Altschul et al., 1997, 2005). Contigs were reordered with MAUVE (Darling et al., 2004) using S. saprophyticus American Type Culture Collection (ATCC) 15305 (AP008934.1) as reference. Gene environment and synteny of specific loci were compared and visualized using Artemis v17.0.1 (Carver et al., 2012) and Easyfig (Sullivan et al., 2011).
Statistical Analysis
The mean and standard error values of technical and biological replicates of each strain were calculated. The statistical significance of differences between the control and the respective disruption assay for each strain was done through unpaired Student’s t-test. Chi square was used to test the significance of the link between S. saprophyticus biofilm phenotypes of strains from different lineages and origin. Statistical analyses were performed with GraphPad Prism v6.0 (GraphPad Software, Inc., San Diego, CA, United States).
Results
The Great Majority of Staphylococcus saprophyticus Isolates Produced Biofilm
All S. saprophyticus isolates (n = 422) recovered from human colonization and infection including UTI and food-related environment were assessed for their ability to produce biofilm. A great majority (91%; 384/422, OD595 nm > 0.2) produced biofilm, among which 91% (n = 349/384) were strong biofilm producers, and 5% each (n = 18/384) were moderate and weak biofilm producers. Among the weak (n = 18) and non-biofilm producers (n = 36) in this collection, 83% (n = 15/18) and 64% (23/36), respectively, were recovered from human infection and dispersed in clonal lineage G.
Biofilm Composition Is Highly Diverse in Staphylococcus saprophyticus
Biofilm matrix phenotype in 63 representative S. saprophyticus isolates (Supplementary Figure 1) was determined using biofilm detachment assay. Our results showed that proteinase K, when compared with the controls, detached > 75% of the biofilm matrix formed in almost all the isolates (98%; 62/63) in this collection. The treatment of isolates’ biofilm matrix with DNAse and sodium periodate showed that in 54% (34/63) and 46% (29/63) of the isolates, respectively, >70% of the matrix was detached (Supplementary Figure 2), while a partial detachment (30–70% biofilm detached) was observed in 35% (22/63) and 41% (26/63), respectively, (Supplementary Figure 2). Considering that the amount of biofilm detached is directly correlated to the amount of the targeted biofilm component, almost all the S. saprophyticus tested produced biofilms composed of similar amounts of proteins, while the content in eDNA and polysaccharide varied from strain to strain.
We classified the observed phenotypes into groups based on the % of reduction in biofilm biomass after detachment in comparison with the respective control. Based on this classification, we found five major different biofilm matrix types in S. saprophyticus population. The great majority (81%; 51/63) of the isolates produced biofilm composed of protein–eDNA–polysaccharide (PDS). The remaining isolates (<20%) produced biofilms composed of protein–eDNA (PD), protein–polysaccharide (PS), protein only (P), and polysaccharides only (S; Figure 1A). Within the PDS-based biofilm, the quantity of eDNA and polysaccharides varied within the biofilm (PDS1–PDS4; Figure 1A), providing an additional layer of heterogeneity.
Next, we categorized the biofilm matrix phenotypes based on the major component such that components that were partially present (30–70% biofilm detached) in the biofilm produced by isolates were excluded. Based on this qualitative classification, 38% (24/63, each) of the isolates produced biofilm mainly composed of protein or PDSs, 13% (8/63) of PD, 10% (6/63) of PSs, and 2% (1/63) of S (Figure 1B).
Biofilm Matrix Types in Staphylococcus saprophyticus Are Associated With the Genetic Background and the Source of Isolates
Staphylococcus saprophyticus belonging to different genetic lineages and recovered from different sources were hypothesized to produce homogeneous biofilm types. We tested this hypothesis using chi-square test. There was a significant difference between biofilm matrix phenotype in the two S. saprophyticus genetic lineages. In particular, biofilm composed of mainly PDS was strongly associated with lineage G (lineage G, 44%; 18/41; lineage S, 27%; 6/22, p < 0.0436), whereas protein-based biofilm was linked to isolates belonging to lineage S (lineage S, 50%; 11/22, lineage G, 32%; 13/41, p < 0.0468; Figure 2A).
Similarly, the protein-based phenotype that was lineage-linked was almost exclusive in human infection isolates (infection, 55%; 23/42, environmental sources, 5%; 1/21, p < 0.0001). Conversely, PDS-based biofilm was strongly associated with isolates from environmental sources including colonization and those of food origin (environmental sources, 71%; 15/21, infection, 21%; 9/42, p < 0.0001; Figure 2B). These results suggest that biofilm matrix phenotypes in S. saprophyticus vary not only according to the genetic background but also with the source of the isolates.
Biofilm Phenotypes Are Not Associated With a Specific Genetic Content
To investigate the frequency and distribution of biofilm-associated genes among the different biofilm matrix phenotypes produced by S. saprophyticus, we constructed a pangenome of the 63 isolates in the representative collection and assessed the prevalence of these genes (Jefferson, 2004; Rohde et al., 2007; Speziale et al., 2014; Barros et al., 2015; Fagerlund et al., 2016; Harris et al., 2016) in the accessory genome. Genes encoding autolysin (atl), fibronectin binding protein (aas), lipase (ssp), and elastin binding protein (ebpS) were present in all the isolates, while other genes encoding surface proteins, namely, sasF, uafA, and sasD, were present in 85, 56, and 3%, respectively. Serine protease-encoding genes sdrH, sdrE, splE, and sdrC were present in 66, 44, 39, and 5%, respectively. Additionally, icaC was present in 100% and icaR in 59% of the population tested. Complete ica gene cluster (icaADBCR) was only present in three infection isolates, while one other isolate recovered from a food-related environment carried icaADBC without icaR (Figure 3).
To better understand if any biofilm-associated genes or other genes in the genome were associated with specific biofilm phenotypes, we used pan-GWAS approach with Scoary where the five phenotypes based on the major matrix components were used as the predefined traits and mapped against the accessory genome containing 4,657 genes. However, we could not find a direct association between any gene and the matrix phenotypes produced by S. saprophyticus strains in this collection or the presence of specific components, such polysaccharide, protein, or eDNA. In spite of the fact that the great majority of strains produced biofilms containing polysaccharides, the complete ica cluster was only found in four isolates except one without icaR, suggesting that polysaccharide biofilms produced by S. saprophyticus are ica cluster independent.
The Complete icaADBCR Cluster Was Acquired Multiple Times in Staphylococcus saprophyticus
In this study, we did not detect definite candidate genes associated with the biofilm formation ability or matrix heterogeneity observed in isolates analyzed. However, the observation that some ica genes were present in the 63 representative S. saprophyticus strains prompted a further assessment of the frequency and diversity of this gene cluster in the entire collection of 422 S. saprophyticus for which the genomic data were available. The draft genomes were annotated, the pangenome was constructed, and the prevalence of ica genes was assessed.
The icaR gene encoding a negative transcriptional regulator of the ica operon (Conlon et al., 2002) was exclusively found in isolates belonging to clonal lineage G, whereas an allele of icaC (icaC_1), a gene encoding an acetyltransferase that exports polysaccharide (Arciola et al., 2015), was ubiquitous in S. saprophyticus. The remaining ica genes, which are part of the cluster, namely, icaA, icaD, and icaB, were found in a very small fraction of the population (4/422; <2%). Three of the isolates containing the complete ica cluster belonged to clonal lineage G, while a single isolate belonged to clonal lineage S (see Figure 3).
To understand the relative position of the five ica genes and to estimate their location in the chromosome, we aligned and reordered the contigs against the reference genome S. saprophyticus 15305 and annotated the contigs containing ica genes. The ubiquitous icaC (icaC_1) and icaR genes were in different chromosomal regions; however, both were located in the first quarter of the genome (ATCC 15305 AP008934.1; icaC_1: 336965…338035; icaR: 134063…134569; Kuroda et al., 2005).
The icaADB was located in three different chromosomal regions, always accompanied by an additional copy of icaC (icaC_2, icaC_3) different from the ubiquitous allele (icaC_1). In isolates belonging to lineage G, they were either located immediately downstream icaR or downstream fmhA nearby a tRNA-Asn (Figure 4 and Supplementary Figure 4).
The single isolate from lineage S that contained an entire ica cluster carried these genes immediately downstream from the mec complex and within a genomic fragment bracketed by two different insertion sequences (IS256 and IS1181). Although this ica-containing genomic region in S. saprophyticus resembles a SCCmec-like structure, due to the presence of the two central structural elements of SCCmec (mec complex A and ccrB gene; Figure 5), we could not find the inverted repeat regions and ISs defining the boundaries of the element. These elements appear to be inserted in a location far apart from the characteristic orfX chromosomal integration site (>1.5 Mb apart; see Figure 5; Rolo et al., 2017). Our results suggest that the complete ica cluster was acquired multiple times by S. saprophyticus in diverse chromosomal locations.
The ica Cluster From Staphylococcus saprophyticus Originated From Other Coagulase-Negative Staphylococci
The diverse ica cluster genetic environment in S. saprophyticus suggests a complex evolutionary history for this group of genes. To better understand the origin and evolution of the cluster in S. saprophyticus, we used blast analysis (Altschul et al., 1997, 2005) to find homologs of these genes and compared the gene environment with those of related species.
The ubiquitous icaC_1 and icaR from lineage G in S. saprophyticus was closely related homologous to the one found in Staphylococcus xylosus and Staphylococcus equorum (nt id: icaC_1—87% and 84%; icaR—72% and 62%, respectively). Furthermore, the genetic environment of ubiquitous icaC_1 in both lineages (G and S) was very similar in terms of nucleotide sequence (nt id ∼ 80%) and gene synteny to the icaC region of S. xylosus and S. equorum, although it was inverted in these species (Supplementary Figure 3 and Table 1). The fact that S. xylosus and S. equorum are close phylogenetic relatives of S. saprophyticus and icaC genes are within a similar chromosomal region implies that they could have been inherited via vertical evolution during speciation. Actually, the average nucleotide identity between these species was identical (∼80%) to the homology observed for the genes understudy, which further supports the hypothesis of vertical inheritance.
TABLE 1.
Gene allele | Strains (lineage) | % Nucleotide identity |
|||||
Staphylococcus aureus | Staphylococcus xylosus | Staphylococcus cohnii | Staphylococcus fleurettii | Staphylococcus sciuri | Staphylococcus epidermidis | ||
icaC_1 | G (326); S (n = 95) | 56.0 | 87.0 | 55.0 | 53.0 | 54.0 | 56.0 |
icaR | All (G) | 61.0 | 75.0 | – | 56.0 | 56.0 | 61.0 |
icaA (group_4834) | KS11, KS98 (G) | 71.0 | 78.0 | 41.0 | 46.0 | 70.0 | 71.0 |
icaD | 61.0 | 74.0 | – | 60.0 | 59.0 | 61.0 | |
icaB (group_4832) | 64.0 | 73.0 | 68.0 | 63.0 | 48.0 | 64.0 | |
icaC_2 (group_3085) | 69.0 | 73.0 | 63.0 | 54.0 | 56.0 | 50.0 | |
icaA_1 | KS313 (G) | 71.0 | 78.0 | 99.6 | 67.0 | 70.0 | 71.0 |
icaD_1(group_4346) | 60.0 | 64.0 | 98.0 | 59.0 | 58.0 | 59.0 | |
icaB_1 | 70.0 | 73.0 | 99.0 | 63.0 | 62.0 | 66.0 | |
icaC_3 (group_2023) | 67.0 | 71.0 | 99.0 | 63.0 | 61.0 | 68.0 | |
icaR_1 | KS295 (S) | 75.0 | 56.0 | – | 99.8 | 73.0 | 56.0 |
icaA_2 | 83.0 | 70.0 | 65.0 | 99.8 | 83.0 | 65.0 | |
icaD_2 | 80.0 | 60.0 | – | 99.7 | 77.0 | 56.0 | |
icaB_2 | 77.0 | 65.0 | 64.0 | 100.0 | 78.0 | 64.0 | |
icaC_4 | 79.0 | 59.0 | 58.0 | 99.8 | 73.0 | 52.0 |
depicts genes that either were completely absent or had ≤60% coverage. Values highlighted in bold had the highest identities for each gene.
Staphylococcus xylosus is one of the species most closely related to S. saprophyticus in the Staphylococcus phylogenetic tree (Naushad et al., 2019) and also contains icaC_1 ubiquitously and icaR in low frequency (n = 16/57) in their genome, suggesting that these genes could have been transmitted during vertical evolution through speciation. However, the extremely low GC content observed in these two genes in both S. saprophyticus and S. xylosus (icaC: 28.85, 30.81%; icaR: 25.9, 27.84%) when compared with the remaining genome implies that they were acquired from other genus into Staphylococcus.
Among the four ica-positive strains from lineage G, two carried icaADBC (icaA, icaD, icaB, and icaC_2; KS11 and KS98, Figure 3) located downstream the ubiquitous icaR (Figure 4). Like with ubiquitous icaR, the remaining ica genes (icaADBC) had the closest homology with those of S. xylosus (nt id = 73–78%; Table 1). The gene organization within the clusters was similar to the ica cluster from Staphylococcus aureus or S. epidermidis (Lerch et al., 2019). The only exception was that the icaR had the same transcriptional direction as the remaining ica genes (Figure 4).
The other two ica-positive strains from lineage G that carried icaADBC downstream fmhA gene appear to have a completely different origin. They contained no icaR (icaADBCΔR); and all the other ica genes (icaA_1, icaB_1, icaD_1, and icaC_3) were highly similar (nt id ≥ 98%) to those in Staphylococcus cohnii BKAW01 (Table 1 and Supplementary Figure 4). The high similarity of ica genes detected in these strains with those of S. cohnii suggests a probable recent acquisition from this species. In fact, genes encoding a tRNA [tRNA-Asn (att)], a putative recombinase (bin), and a plasmid replication protein (rep), all genes associated with mobilization and recombination, were located downstream of the ica cluster, suggesting that these genes might have been exogenously acquired.
In the single isolate from lineage S that contained an entire ica cluster (icaA_2, icaD_2, icaB_2, icaC_4, and icaR_1) in a SCCmec-like structure (KS295; Figures 3, 5), the ica cluster genes were almost identical (nt. Id ≥ 99.7%) to those found in Staphylococcus fleurettii having a much lower identity with ica genes than other staphylococcal species (S. aureus, 75–83%; S. epidermidis, ≤67%; Staphylococcus sciuri, 73–83%; and S. xylosus, ≤70%; Table 1). This is the only case in which direction of transcription of icaR is opposite to the remaining ica genes, as it is described for S. aureus and S. epidermidis (Lerch et al., 2019). Interestingly, in addition to ica cluster, the entire region spanning from brnQ to xylR, including the mec complex, was highly identical to the mecA region in S. fleurettii NCTC13829 (99–100% nt id; Table 2 and Figure 5). Furthermore, the gene synteny of this region in both S. saprophyticus and S. fleurettii NCTC13829 was similar. The only exception was the position of ica gene cluster that was found upstream of the mec complex and SCCmec elements in S. saprophyticus and downstream these elements in S. fleurettii (Figure 5). The chromosomal location of the mec complex in S. fleurettii, so-called the native location (approximately 200 kb apart from orfX; Rolo et al., 2017), differed with the location of mec complex and ica genes in this S. saprophyticus strain. Overall, our data suggest that ica genes in S. saprophyticus were probably acquired from different CoNS species and were inserted in different chromosomal locations.
TABLE 2.
Genes | % Nucleotide identity |
|||
Staphylococcus aureus | Staphylococcus fleurettii | Staphylococcus sciuri | Staphylococcus vitulinus | |
ccrB (ccrB3) | 86.0 | – | 91.0 | – |
brnQ | 74.0 | 99.9 | 83.0 | 86.0 |
mvaA | 70.0 | 100.0 | 83.0 | 87.0 |
paaJ | – | 99.9 | 85.0 | 85.0 |
mvaS | 99.7 | 99.9 | 88.0 | 91.0 |
IS256 | – | 99.7 | 79.0 | – |
ugpQ | 100.0 | – | – | – |
maoC | 100.0 | – | – | – |
mecA | 99.9 | 100 | 99.9 | 99.9 |
mecR1 | 99.5 | 99.7 | 99.5 | – |
mecI | 100.0 | 100.0 | – | – |
xylR | 99.0 | 99.8 | 99.0 | – |
depicts genes that either were completely absent or had ≤60% coverage. Values highlighted in bold had the highest identities for each gene.
Discussion
In this study, we confirmed that almost all (91%) the 422 included S. saprophyticus isolates produced biofilm irrespective of the source or genetic lineage of the isolates. This rate was higher than that found in a previous study wherein 70% (119/169) of the S. saprophyticus recovered from infection and food-produced biofilm (Martins et al., 2019). These high rates of biofilm formation in the population suggest that biofilm is probably the main mode of living of these bacteria. Biofilm formation is an important step in bacterial colonization and adaptation in a variety of environments and contributes to disease development in the host (Speziale et al., 2014; Jeong et al., 2016). Biofilm formation in this study was assessed using the in vitro microtiter plate assay in rich standard medium. This does not completely mimic the in vivo scenario; and, hence there is the possibility for false negatives. Studies on comparison of different techniques would be essential to complement the results obtained here.
The structure and composition of biofilms produced by bacteria are generally maintained by various macromolecules, which can vary in type and quantity among species and strains (Arciola et al., 2015; Sugimoto et al., 2018). The S. saprophyticus biofilm matrix composition determined by detachment assays in this study was highly heterogeneous, showing at least five different phenotypes. However, the most common biofilm types found in this study were composed of only protein or PDSs. Noteworthy, we found significant differences in biofilm matrix composition in S. saprophyticus of the two genetic lineages as well as between strains of infection and colonization/environmental origin (lineage S/infection: protein; lineage G/colonization: PDS). The heterogeneity in the biofilm matrix phenotypes found in S. saprophyticus population was previously described for Staphylococcus aureus (Sugimoto et al., 2018) and S. epidermidis (Rohde et al., 2007), among others. Moreover, Tasse and colleagues have previously described the association between biofilm matrix phenotypes and clonal lineages in S. aureus. In particular, they reported that S. aureus CC5, CC15, and CC30 strains produced highly eDNA-dependent biofilm, whereas that S. aureus CC45 was protein-dependent (Tasse et al., 2018). This observation might be a long-term adaptive response to different environmental signals that may vary between different settings, such as the presence of antibiotics, immune system, acidity, humidity, changes in temperature, and other imbalances in the environment that may induce stress (Rachid et al., 2000; López et al., 2010; Di Ciccio et al., 2015). Results suggest that eradication of biofilms in infection and colonization should be done with different approaches. More knowledge on the composition and genetic basis of biofilm formation is important to help develop anti-biofilm strategies against this pathogen.
Genes that encode cell wall-anchored proteins, surface proteins, autolysins, and ica operon that are linked to biofilm formation and matrix phenotypes were found in our collection. Adhesin-encoding genes such as aas (Hell et al., 1998), ebpS (Downer et al., 2002), and uafA (Kuroda et al., 2005) had been speculatively linked to biofilm formation in S. saprophyticus with scarce experimental proof (Fagerlund et al., 2016). In this study, the presence of these genes alone was not correlated with biofilm formation ability or composition, suggesting that mutations with impact in gene expression level might have an important role on biofilm phenotype produced, as previously described (Harris et al., 2016; Tasse et al., 2018). Further studies would be required to confirm this hypothesis. Another possibility is that the low number of isolates included in the GWAS analysis could have hindered the identification of statistically significant associations.
Among the genes associated with biofilm formation in staphylococci, the ica operon, responsible for the production of polysaccharide, is the most important (Rohde et al., 2010). However, in our S. saprophyticus collection, this operon was rarely found (∼1%), suggesting that biofilm in this species is ica-independent. Although the complete cluster was scarce, an allele of icaC gene, involved in polysaccharide export, was found to be ubiquitous (Arciola et al., 2015), and icaR, a ica negative transcriptional regulator (Conlon et al., 2002), was present in all isolates of lineage G. In spite of their high homology with genes within the ica cluster, these two genes, when together in the same strain, were located far apart in the chromosome. These genes had high similarity (nt id ∼ 80%) with those found in S. xylosus, a close phylogenetic relative of S. saprophyticus, within a similar chromosomal region, implying that they could have been inherited via vertical evolution during speciation.
Besides the ubiquitous icaC/icaR genes, we additionally found in the genome of a few strains the complete ica cluster located in three different regions of the chromosome: downstream, the ubiquitous icaR or nearby genes usually associated with mobile genetic elements like SCCmec or plasmids. While ica cluster genes located nearby the ubiquitous icaR had a low identity with ica genes from the closely related species S. xylosus (∼70% nt id), ica cluster genes inserted nearby mobile genetic elements showed a high identity (>98%) with ica genes from other coagulase-negative staphylococci such as S. cohnii and S. fleurettii. These results suggest that the ica cluster located downstream icaR was either acquired exogenously, a long time ago, or inherited via vertical evolution during speciation and further lost from the majority of the population to avoid the “fitness cost” associated with polysaccharide production. On the other hand, the other ica clusters identified appear to have been acquired by horizontal gene transfer from staphylococcal species.
Conclusion
In this study, we showed that there was a high variability in the composition of the biofilm formed by S. saprophyticus. The most common type of biofilm produced by this bacterium contained protein or PDSs. The biofilm components appear to differ between food-related and human infection isolates and between clones, suggesting that modulation of biofilm composition could be a key step in S. saprophyticus virulence and niche adaptation. Our data further showed the possible origin and multiple acquisition of the ica gene cluster in S. saprophyticus.
Data Availability Statement
The datasets presented in this study can be found in online repositories that can be found in the article/Supplementary Material. Sequence data generated from this study had earlier been deposited to the Sequence Reads Archives under the project accession number PRJNA604222.
Ethics Statement
The studies involving human participants were reviewed and approved by Comissão de Ética para a Investigação e Ensino (CEIE) da Faculdade de Medicina Veterinária, Universidade de Lisboa. Written informed consent for participation was not required for this study in accordance with the national legislation and the institutional requirements. The animal study was reviewed and approved by Comissão de Ética para a Investigação e Ensino (CEIE) da Faculdade de Medicina Veterinária, Universidade de Lisboa. Written informed consent for participation was not obtained from the owners because Oral informed consent was obained for animal participation. Slaughterhouse samples were part of the routine control practices for evaluation of good hygiene practices and programs to assure meat safety (CE No. 853/2004). The sampling was done as part of the routine infection control program and no additional sampling was perfomed. The samples were non-invasive or minimal invasive and were the animal commensal bacteria and not animals that were studied.
Author Contributions
OL and MB performed the phenotypic experiments. OL performed the bioinformatics analysis. OL and MM carried out the data analysis and interpretation and wrote the manuscript. MF, LG, PP, EG, CT, JE, MU, HL, HW, and MDB provided the isolates. MF, LG, PP, EG, CT, JE, MU, HL, HW, PW, and MDB were involved in manuscript revision. All authors read and approved the final manuscript.
Conflict of Interest
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.
Funding. OL was supported by Ph.D. grant PD/BD/113992/2015 from the Fundação para a Ciência e Tecnologia (FCT). This work was partially supported by project PTDC/FIS-NAN/0117/2014, project PTDC/CVT-CVT/29510/2017, and project PTDC/BIAMIC/31645/2017; Projects LISBOA-01-0145-FEDER-007660 (Microbiologia Molecular, Estrutural e Celular) and UID/Multi/04378/2019 funded by FEDER funds through COMPETE2020—Programa Operacional Competitividade e Internacionalização (POCI); ONEIDA project (LISBOA-01-0145-FEDER-016417) co-funded by FEEI—“Fundos Europeus Estruturais e de Investimento” from “Programa Operacional Regional Lisboa2020”; and national funds through FCT; Operacional Competitividade e Internacionalização, Programa Operacional Regional de Lisboa (FEDER) and Fundação para a Ciência e a Tecnologia.
Supplementary Material
The Supplementary Material for this article can be found online at: https://www.frontiersin.org/articles/10.3389/fmicb.2021.663768/full#supplementary-material
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Associated Data
This section collects any data citations, data availability statements, or supplementary materials included in this article.
Supplementary Materials
Data Availability Statement
The datasets presented in this study can be found in online repositories that can be found in the article/Supplementary Material. Sequence data generated from this study had earlier been deposited to the Sequence Reads Archives under the project accession number PRJNA604222.