Background

Viridans streptococci are the most important pathogens responsible for native valve infective endocarditis (IE) in non-drug-addicted patients [1]. However, Streptococcus gallolyticus subsp. gallolyticus, formerly referred to as Streptococcus bovis biotype I, a member of group D streptococci, was estimated to be the causative agent in 24% of streptococcal endocarditis [2]. S. gallolyticus subsp. gallolyticus belongs to the S. bovis-complex including different species frequently isolated from humans and animals (S. bovis, S. gallolyticus, S. infantarius, S. equinus, S. alactolyticus). The taxonomic classification of this group of streptococci was often revised. However, at the beginning of this decade, Schlegel et al. proposed the reclassification of S. bovis biotype I as S. gallolyticus subsp. gallolyticus based on genetic, physiologic and phylogenetic perceptions [3], which was recently confirmed in a large comprehensive study [4]. Therefore, the highest priority regarding the clinical significance must refer to S. gallolyticus subsp. gallolyticus instead of S. bovis. Particularly in Southern Europe, the proportion of endocarditis caused by group D streptococci increased over the recent years [5, 6]. Hoen et al. documented that 58% (France), 9.4% (other European countries) and 16.7% (USA) of streptococcal IE cases were caused by S. bovis [6]. S. gallolyticus subsp. gallolyticus is a normal inhabitant of the human gastrointestinal tract and numerous reports, referring to S. bovis, demonstrated an association between IE and gastrointestinal neoplasia, which were in most cases colonic adenoma or carcinoma [79] as well as liver disease [10, 11]. Either the underlying colonic disease or an altered hepatic function may promote the bacterial translocation during the initial phase of infection [10].

Pathogenesis and several virulence factors have been examined for viridans streptococci, yet the knowledge of similar mechanisms for S. gallolyticus subsp. gallolyticus is limited. Studies examined the adhesion of animal isolates from pigeons to immobilized matrix proteins [12], and characterized virulence-associated surface proteins [1315]. Recently, Sillanpää et al. observed a difference in adherence to distinct host extracellular matrix (ECM) proteins of endocarditis-derived S. gallolyticus subsp. gallolyticus isolates [2]. Until now, analogue mechanisms of human isolates regarding the adhesion to or invasion of endothelial cells, as well as defined virulence genes are unknown. Viridans streptococci have been shown to adhere to human endothelial cells in vitro [16, 17] and numerous host cell factors and bacterial components have been identified as possible virulence factor candidates in other streptococci [18]. For example, a group of streptococcal genes encoding several adhesins (fimA, fimB, ssaB, scaA, psaA) play important roles in the development of IE [1921]. It has also been shown that pilB contributes to adherence to endothelial cells in groupB streptococci and over-expression leads to increased virulence in rats [22, 23].

Glycosyltransferases (gtf), which are responsible for the synthesis of glucans, are known to be major cell surface proteins involved in adherence of Streptococcus gordonii to human umbilical vein endothelial cells (HUVECs) in vitro [24]. Glycosyltransferases are further involved in the adhesion to human endothelial cells [24] and modulate cellular cytokine induction in IE [25, 26]. Biofilm formation in vitro is also strongly influenced by the amount of Gtf produced by S. mutans [27, 28]. The role of biofilm formation in IE remains open, with some studies reporting a lack of association [29, 30] and other studies proposing a considerable importance [31]. Endothelial matrix proteins, such as collagen, fibronectin, vitronectin, fibrinogen and laminin, have also been shown to serve as receptors for bacterial surface proteins which promote bacterial adherence to host cells [3237].

In the present study, an in vitro cell culture model was established to analyze the capability of human S. gallolyticus subsp. gallolyticus endocarditis isolates to adhere to and invade endothelial cells in comparison to non-endocarditis associated strains. Furthermore, adherence to immobilized ECM proteins and the ability to form biofilms in vitro was examined to determine a possible association with endocarditis virulence. Isolates were further analyzed for the presence of the virulence associated genes fimB, gtf and pilB.

Methods

Bacterial strains and growth conditions

Bacterial strains listed in Table 1 were obtained from the American Type Culture Collection (ATCC, LGC Promochem GmbH, Wesel, Germany), the Deutsche Sammlung von Mikroorganismen und Zellkulturen GmbH (DSMZ, Braunschweig, Germany) or were previously isolated from patients' specimens at our hospital. All clinical isolates used in this study were characterized in our microbiological laboratory by standard methods. In addition, molecular genetic strain identification was performed by sequencing analysis of the superoxide-dismutase gene (sodA) as described previously [38]. Bacteria were grown on tryptone soya (TS) or brain heart infusion (BHI) agar plates (Oxoid Ltd., Cambridge, UK) and isolated colonies were used as inocula in TS or BHI medium. Determination of the bacterial titer was performed by plating on TS agar. For simplification of readability, S. gallolyticus subsp. gallolyticus is consecutively abbreviated to S. gallolyticus.

Table 1 List of strains analyzed in this study with source, sodA GenBank accession numbers, distribution of virulence gene sequences detected by PCR and occurrence of intestinal abnormalities.

Cell culture

EA.hy926 cells were derived from the ATCC (Manassas, USA) and cultured in Dulbecco's modified essential medium (DMEM, Gibco, Invitrogen, Karlsruhe, Germany) containing 1% L-glutamine (200 mM), supplemented with 10% fetal calve serum (Biowest, Nuaillé, France) and 1% antibiotic/antimycotic solution (100×, Biowest). Cells were grown at 5% CO2 and 37°C in a humidified atmosphere and were used before passage 10 for all experiments. Cryopreserved pooled HUVECs were purchased from Lonza (Basel, Switzerland) and grown routinely in EGM-2 medium (EGM-2 BulletKit, Lonza) at 5% CO2 and 37°C in a humified atmosphere. Cell culture dishes were previously coated with collagen I (Sigma, Steinheim, Germany). Cells were utilized before passage five for all experiments. EA.hy926 and HUVEC cells were detached using 10% trypsin-EDTA (Lonza). For the adherence and invasion assays, cells were transferred after trypsination to 6-well culture plates and cultivated to confluence. Before infection with bacteria, cells were washed three times with Dulbecco's phosphate buffered saline (DPBS, Gibco).

Cell adherence and invasion assay

The assay was performed as described previously with some modifications [39, 40]. Briefly, bacterial cultures were harvested at late-log phase, washed once with DPBS and diluted in fresh cell culture medium without antibiotics. To analyze dose-dependent effects on adhesion and invasion, two millilitres of bacterial suspensions with inocula between 102 and 107 CFU/mL were added to each well containing a monolayer of EA.hy926 or HUVEC cells, respectively. For the comparison of adhesion and invasion efficacy of different S. gallolyticus strains, cells were infected with 1 - 9 × 105 CFU/mL. The 6-well plates were incubated for 2 h at 37°C and 5% CO2 to facilitate cell infection. For the adherence assay, the cell monolayer was washed five times with DPBS, and endothelial cells were trypsinized and lysed with 1 mL 10% Trypsin-EDTA in distilled water. Trypsin-reaction was stopped with an equal volume of cell culture medium without antibiotics. 100 μL from each well were plated onto TS agar and incubated overnight at 37°C. For the invasion assay, the monolayer was washed three times with DPBS. Two millilitres of cell culture medium supplemented with 1% antibiotic/antimycotic solution and 100 μg/mL gentamicin (Gibco) were added to each well. The 6-well plates were incubated for another 2 h at 37°C and 5% CO2 to kill extracellular and surface-adherent bacteria. Afterwards, the monolayers were washed three times with DPBS and bacteria were quantified as described for the adherence assay. Assays were performed in duplicate and repeated twice. For comparative reasons, isolate 21702 was used as an internal assay control in every assay. Antibiotic efficacy of the invasion assay was tested for all strains with concentrations of 107 CFU/mL in pure cell culture medium, confirming that no viable bacteria were present after 2 h incubation (data not shown).

Mechanical stretch

Cultures of EA.hy926 were subjected to cyclic tension using a FlexCell vacuum system (FlexCell, Dunn Laboratories, Hillsborough, USA). Cells were cultured on BioFlex culture plates (FlexCell) coated with collagen I in a humidified atmosphere with 5% CO2 at 37°C for 72 h. Afterwards cultures were stretched by 10% with a frequency of 1 Hz in a square wave pattern for another 24 h. EA.hy926 from the same preparation and cultured without mechanical stretch were used as controls. Stretched cells and controls were infected immediately after completion of mechanical stretch as described above.

Biofilm assay

The biofilm assay used in this study was performed as described previously [30] with the following modifications: absorbance was measured using the GENios Plate Reader (Tecan Deutschland GmbH, Crailsheim, Germany) at 450 nm (total bacterial growth) and 550 nm (crystal violet (CV), biofilm formation). Each strain was assayed in quintuplicate.

ECM assay

96 well microtiter plates were coated with 10 μg/mL fibrinogen (human plasma, Sigma). Microtiter plates precoated with collagen I, collagen II, collagen IV, fibronectin, laminin, tenascin and vitronectin were purchased from Chemicon (Millipore, Schwalbach, Germany). Wells coated with BSA were used as negative controls and values were subtracted. Late-log-phase cultures of bacteria were inoculated into 100 μL BHI medium (Oxoid) and incubated on pre-coated wells without agitation for 2 h at 37°C. Subsequently, wells were washed twice with DPBS and dried for 20 min at 60°C. In parallel, bacteria were plated onto BHI agar and incubated overnight at 37°C. Attached bacteria were stained with 100 μL of 0.4% CV at room temperature for 45 min. Wells were rinsed five times with PBS and air dried. CV was solubilized in 100 μL ethanol (99%), and the absorbance was measured at 550 nm. Each strain was assayed in quadruplicate for the different ECM proteins.

PCR analysis

Bacteria were harvested from overnight grown cultures and bacterial DNA was extracted using the QIAamp DNA Blood Kit (protocol D, Qiagen, Hilden, Germany) according to the manufacturer's instructions. PCR primers were designed to amplify the known virulence factors of S. gallolyticus fimB and gtf and to amplify a homolog of the pilB gene identified in S. suis (Table 2). DNA amplification was carried out in 0.2 mL tubes containing 45 μL reaction mix and 5 μL DNA extract. The reaction mix consisted of 1× HotMaster Taq buffer including 2.5 mM MgCl2, 200 μM of each dNTP, 100 nM of each primer and 1.25 U of HotMaster Taq DNA polymerase (5 Prime, Inc., Gaithersburg, USA). The PCR conditions were as follows: initial denaturation at 94°C for 5 min, followed by 30 cycles of denaturation at 95°C for 30 s, PCR-product specific annealing temperature (Table 2) for 60 s and extension at 72°C for 60 s, followed by a final elongation for 10 min at 72°C. PCR products were sequenced for identification as described previously [41].

Table 2 Primer sequences and PCR conditions.

Statistical analysis

Statistical analysis was performed using One-way-ANOVA, the Mann-Whitney-U-test and the student's t-test where appropriate. Multiple testing correction was performed using the Bonferroni method. Normality testing of all data sets for Gaussian distribution was performed using the Kolmogorov-Smirnov test. We used Spearman correlation coefficients to assess correlations between variables. P values < 0.01 were considered significant. All values are given as mean values (± SD). Statistical analysis was performed using GraphPad Prism 4.0 software (GraphPad Software, San Diego, CA, USA).

Results

Identification of virulence genes and occurrence of intestinal abnormalities

All strains analyzed in this study were identified as S. gallolyticus by sequencing analysis of the sodA gene (GenBank accession no. Table 1). Table 1 displays the distribution of the analyzed S. gallolyticus virulence genes fimB, gtf and pilB among 23 different strains. The known virulence gene fimB was detected in all analyzed strains, whereas four strains showed no positive PCR signal for gtf. The occurrence of a partial sequence homolog of the pilB gene, originally identified in S. suis, was proven in 9 strains of S. gallolyticus (GenBank accession no. for S. gallolyticus partial pilB sequence: FJ555059). Sequencing analysis confirmed the gene as pilB with a high similarity of 98% to S. suis pilB. PCR screening results were confirmed by Southern-Blot analysis with total genomic DNA and Digoxigenin-labeled PCR products (data not shown).

Analysis of the corresponding patient information of eight isolates revealed two patients exhibiting colonic malignancies, three patients with intestinal abnormalities and three patients without evidence of intestinal abnormalities (Table 1). For the other eleven human clinical isolates, patient data was not available because isolates were obtained from other institutes and repeatedly characterized in our microbiological laboratory.

Adhesion to and invasion of EA.hy926 cells

All strains started to grow after 3 h of incubation in DMEM at 37°C and 5% CO2 at the earliest (data not shown). Therefore, incubation time for adhesion was determined to 2 h to avoid false-high titers as a result of bacterial growth kinetics. Three strains representing different adherence and invasion potentials, namely strain DSM 16831 (low adhesion, no invasion), isolate 21702 (intermediate adhesion and invasion) and isolate 05950 (high adhesion and invasion), were chosen to exemplify the dose-dependent effects on adhesion and invasion to EA.hy926 cells (Fig. 1). The proportion of adhesive and invasive bacteria did not increase using higher bacterial concentrations, with both, the adhesiveness and the invasiveness of the different bacteria showing a linear progress. Remarkably, strain DSM 16831 did not have the potential to invade cells, even when higher bacterial concentrations were used for infection. Subsequently, all S. gallolyticus strains were compared regarding their adhesion and invasion characteristics to EA.hy926 cells (Fig. 2). As a result of the observed linear progress and for strain comparability the initial inocula were calculated to 1 × 105 CFU/mL, and consequently adhesion and invasion values were factorized. Generally, all the S. gallolyticus strains analyzed were able to adhere to EA.hy926 endothelial cells (range 103-104 recovered CFU/mL) and significant differences were observed among the investigated strains (repeated measures anova, P < 0.0001). Consideration of the individual strains revealed that isolates 13366, K6236 and AC1016 presented the most frequently significances (Fig. 2). With the exception of strain DSM 16831, which was excluded in further statistical analysis regarding invasion characteristics, all S. gallolyticus strains also had the capacity to invade EA.hy926 cells (range 101 - 103 recovered CFU/mL) with significant differences (repeated measures anova, P < 0.0001). A closer look on variation between individual strains disclosed, that the potential of invasion of the two strains DSM 13808 and isolate 05950 demonstrated numerous significances overall (DSM 13808: 17 strains, P < 0.001; isolate 05950: five strains, P < 0.001 and seven strains P < 0.01, Fig. 2). Correlation analysis of adherence and invasion showed a strong correlation for all strains (Spearman rank correlation coefficient r = 0.673, P = 0.0003). A considerable difference in the adherence or invasion potential of endocarditis isolates and reference strains was not observed. However, five strains illustrate noticeable characteristics (Fig. 2). Strain DSM 16831 has a considerably low ability of adherence and no ability of invasion. In comparison to isolates characterized as common, isolate AC6827 has a low adherence and invasion, whereas isolate 134257 exposed only a low adherence. Strain DSM 13808 and isolate 05950 revealed standard adhesive characteristics but the invasion capacity was considerably higher compared to the other isolates. Correlation analysis of adherence to or invasion of endothelial cells and the number of present virulence genes revealed no correlation: (a) three virulence genes versus two virulence genes: Padhesion = 0.35, Pinvasion = 0.12, (b) three virulence genes versus one virulence gene: Padhesion = 0.08, Pinvasion = 0.19 and (c) two virulence genes versus one virulence gene: Padhesion = 0.27, Pinvasion = 0.81.

Figure 1
figure 1

Dose response analysis of S. gallolyticus adhesion to and invasion of EA.hy926 cells. (A) Adhesion, (B) Invasion. Cells were incubated with decreasing concentrations of three different S. gallolyticus strains (white triangle: isolate 05950, black dot: isolate 21702, white square: DSM 16831), as described in Material and Methods. Error bars indicate standard deviations, n.d.: not detectable.

Figure 2
figure 2

Adhesion and invasion characteristics of different S. gallolyticus strains to EA.hy926 cells. Displayed are the factorized adhesion to and invasion characteristics of 23 different S. gallolyticus strains (calculated to 1 × 105 CFU/mL) after 2 h infection of EA.hy926 cells. The dashed vertical line indicates the separation of "common" and "noticeable" relations between adhesion and invasion. Error bars indicate standard deviations. Results of statistical analysis of individual strains are arranged in tabular form.

Influence of cell type and cell condition on the adherence and invasion characteristics

Fig. 3 shows the adherence to and invasion of EA.hy926 and HUVECs for six bacterial strains with different adhesion and invasion potentials. The comparison of the two different cell types revealed no discrepancy between adhesion and invasion (P > 0.01). Therefore, the cell line EA.hy926 was chosen for further studies of S. gallolyticus infection of endothelial cells. As shown in Fig. 3, the adherence and invasion characteristics of S. gallolyticus to EA.hy926 are likewise comparable between mechanical stretched and untreated cells. However, isolates 13366, 05950, 49147 and 06718 show the tendency of a marginally decreased invasion to mechanical stretched cells.

Figure 3
figure 3

Influence of cell type (EA.hy926/HUVEC) and cell condition (stressed/non-stressed) on the adherence and invasion characteristics of S. gallolyticus. (A) Adhesion to and invasion of endothelial cell lines EA.hy926 and HUVECs after infection with 1 - 9 × 105 CFU/mL of different S. gallolyticus strains. (B) S. gallolyticus strain's adhesion to and invasion of EA.hy926 with and without mechanical stretch 24 h prior to infection with 1 - 9 × 105 CFU/mL bacteria. Results were determined after a 2 h exposure followed by additional 2 h incubation in the presence of antibiotics. n.d.: not detectable.

Binding to ECM proteins and biofilm formation

For evaluation of the ability of S. gallolyticus strains to adhere to host ECM proteins, we analyzed adherence to collagen types I, II, IV, fibronectin, laminin, tenascin, vitronectin and fibrinogen (Fig. 4). Adherent bacteria were stained with CV, and parallel plating onto BHI agar confirmed the initial bacterial titer to 108 CFU/mL for all 23 strains tested. After correction with BSA negative control values, values of OD550 > 0.1 were considered adherent. Mean values of the three different collagen types did not differ significantly. Adherence to collagen I showed the highest values (mean 0.53 (± 0.28)), followed by collagen II (mean 0.45 (± 0.27)), collagen IV (mean 0.38 (± 0.24)), fibrinogen (mean 0.37 (± 0.52)), tenascin (mean 0.25 (± 0.21)) and laminin (mean 0.20 (± 0.19)). Accordingly, the proportion of non-adherent strains increased almost in this order. One strain was unable to adhere to collagen II and IV, whereas five strains did not adhere to fibrinogen, and seven strains did not adhere to laminin or tenascin. Binding to fibronectin and vitronectin revealed the highest proportion of non-adherent strains (fibronectin: n = 16, vitronectin: n = 18) and the observed adherence was relatively low. Individual strain correlation analysis between adherence to endothelial cells and ECM proteins showed no correlation. In contrast, analysis of the adherence of different ECM proteins showed a strong correlation (P < 0.0001) for the following nine protein combinations: (a) collagen I versus collagen II, IV, laminin and tenascin, respectively; (b) collagen II versus collagen IV, laminin and tenascin, respectively; (c) collagen IV versus tenascin and (d) laminin versus tenascin (Fig. 4). A correlation of moderate strength was found for the protein combination collagen IV and laminin (P < 0.001). No correlation was observed for protein combinations including fibronectin, vitronectin or fibrinogen. The ability of adherence to ECM proteins showed a tendency to cluster in certain isolates, e.g. strains with high efficiency of binding to the three different collagen types also showed a strong adherence to laminin and tenascin. Two strains exhibited a considerably higher adherence; isolate AC1181 had a high adherence to collagen I/II/IV, laminin and tenascin, whereas isolate AC7070 had a high adherence to fibrinogen, vitronectin and fibronectin.

Figure 4
figure 4

Biofilm formation and adherence of S. gallolyticus strains to immobilized ECM proteins. Scatter plots show the distribution of the eight ECM proteins and biofilm formation for the different strains/isolates. Individual dots represent the mean values for each strain (quadruplicate determination), the solid horizontal line represents the mean values of the different strains for each ECM protein tested. The dotted horizontal line represents the cut-off value for adherence. The dashed vertical line indicates the separation of the biofilm formation assay. vs: versus, ***P < 0.0001, **P < 0.001, black dot: isolate AC 7070, black triangle: isolate AC 1181.

The analysis of biofilm formation demonstrated that all strains have the capability to adhere to polystyrene surfaces and form biofilms (Fig. 4). Isolates 10672, AC1135 and strain DSM 16831 revealed the highest biofilm formation; remarkably, strain DSM 16831 had no capacity to invade cells. Correlation analysis of adherence to or invasion of endothelial cells and biofilm formation revealed no correlation. Additionally, no correlation was found between adherence to different ECM proteins and biofilm formation.

Discussion and Conclusions

S. gallolyticus is an important pathogen with an underestimated relevance causing IE. The frequent changes in the taxonomy resulted in an inadequate or incorrect identification of the causative pathogens, because non-experts were often not aware of the new nomenclature (e.g. [42]). In contrast to other streptococci, little is known about virulence factors and pathogenesis. The adherence of circulating bacteria to damaged heart tissues and subsequent colonization and persistence of bacteria are the crucial factors in streptococcal IE. The prevention of tissue colonization, with special attention to targeting therapy against ECM-binding, potentially provides a promising alternative in human medicine [43]. Therefore, we analyzed the factors which contribute to S. gallolyticus adhesion and invasion in IE using an experimental in vitro cell culture model. Investigation of the adhesion to ECM proteins identified or confirmed putative adhesive sites on the endothelial cell surface. Additionally, virulence factors were detected and biofilm formation was analyzed in order to identify different strain characteristics.

Most S. gallolyticus strains tested in this study adhere to and invade endothelial cells. The diversity in adhesion and invasion characteristics appears considerably higher for invasion. Strain DSM 16831 exclusively demonstrated no invasive capability. Invasion was also not induced using higher concentrations of bacteria, usage of primary endothelial cells or mechanical stretched cells. In contrast, strain DSM 13808 present a considerably high invasion. The distinct behaviour of these two strains may be due to the fact that they were the only strains tested that were isolated from non-human sources. In general, the observed differences may reflect distinctions in the bacterial equipment with virulence factors or gene expression of virulence factors. We have shown that isolate represent a different distribution of the virulence-associated genes gtf, fimB and pilB. However, the presence of a putative virulence gene does not necessarily indicate expression. For example, Stipp et al. observed variability at different phases of planktonic growth in gtfB and gtfC gene expression [44]. Furthermore, the gene integrity has to be proven. To correlate virulence with the expression of gtf, fimB and pilB, these factors have to be deleted by the construction of knock-out mutants to determine difference in the ability to form biofilms, the adherence to and invasion of host cells and the adherence to ECM proteins. This will show the impact of these factors on binding to host cells and most likely correlate with the bacterial potential to cause IE. In addition, the determined virulence factors reflected only a small proportion of the presumably high quantity of possible virulence factors in S. gallolyticus. Accordingly, the absence of a correlation between the potential to adhere to as well as to invade cells and the number of the existing putative virulence genes most likely could also be explained by these reasons.

The role of biofilm formation in IE remains ambiguous. Several studies demonstrated an association between biofilm formation and streptococcal IE [4547], whereas another study indicated that the ability to form biofilms in vitro is not associated with endocarditis virulence [30]. The results of our study support the lack of association between biofilm formation and adherence to or invasion of endothelial cells and adherence to ECM proteins.

Most IE patients have valve abnormalities, resulting in the exposure of ECM proteins, the production of tissue factor and the deposition of fibrin and platelets promoting bacterial colonization. Streptococcal adherence to endothelial matrix proteins has previously been shown to be an important factor for the infection of host tissues [3237, 48]. Recently, Sillanpää et al. analyzed endocarditis-derived human isolates of S. gallolyticus and, according to the results obtained in our study, binding to collagen I was found to be the most common phenotype, followed by collagen type IV, fibrinogen and fibronectin [2]. In contrast, both studies revealed a weak binding to fibronectin, which is contradictory to studies observing a direct connection between adherence to fibronectin and the applicability of S. sanguis to induce IE [49]. This observation possibly indicates a different pathogenesis of S. gallolyticus IE. Interestingly, a study of animal isolates of S. gallolyticus revealed no adherence to collagen I [12]. Further analysis of the draft genome sequence of an ECM protein-adherent S. gallolyticus strain by Sillanpää et al. revealed 11 predicted LPXTG-type cell-wall-anchored proteins with characteristics of MSCRAMMs (microbial surface components recognizing adhesive matrix molecules), including the "adhesin to collagen of the S. bovis group" (acb) gene [50]. Remarkably, a recombinant Acb protein showed high affinity binding to immobilized collagen. Cell surface expression of Acb correlated with the presence of acb and collagen adherence of different isolates. Therefore, the authors concluded that the high prevalence of this collagen-binding MSCRAMM among S. gallolyticus may play an important role in the predominance of this subspecies in S. bovis complex endocarditis.

The endothelial cell line EA.hy926 displays highly differentiated characteristics of human vascular endothelial [51] whereas primary endothelial cells such as HUVECs presumably provide the most accurate cell type based reflection of the in vivo situation. However, we observed no difference in the adhesion and invasion characteristics of S. gallolyticus using these two cell lines. Consequently, the usage of endothelial cell lines seems to be an equivalent experimental in vitro model, with the major advantage of easier handling compared to primary cells. Nonetheless, it has to be noted that cell monolayers of either cell lines or primary cells only provide a two-dimensional model, whereas the in vivo situation in tissue is three-dimensional.

The intact endothelium is usually resistant to colonization by streptococci [18]. In the present study, mechanical stress of endothelial monolayer does not increase the proportion of adherent or invasive bacteria. This data is an indication for active colonization of valve tissue by S. gallolyticus. However, the results have to be interpreted with caution. We cannot exclude the possibility that mechanical stretch does not significantly increase the degree of stress on the potentially damaged cell monolayer. In addition, monolayers probably do not exhibit a physically intact endothelium since two-dimensional cultivation or contact-inhibition perhaps affected the endothelial cells. Therefore, further studies are warranted to figure out the degree of monolayer integrity and the dimension of cell damage before and after mechanical stretch.

The data of our study demonstrates that there is no evidence for the correlation between adherence to or invasion of endothelial cells, the adherence of bacteria to ECM proteins and biofilm formation. Therefore several other factors have to be investigated to determine their role in the infection of endothelial cells by S. gallolyticus isolates. These factors might include the capsule structure [52], interaction with cell surface glycosaminoglycans [53], presence of fimbriae or production of toxins [15]. It has been shown that S. gallolyticus is capable to produce capsular material [15] and the amount of capsule produced most likely influence the capacity to adhere to the cells. Hence, analysis of further pathomechanisms beneath adhesion, invasion and biofilm formation characteristics as well as the identification of further putative virulence genes is crucial for a better understanding of the mechanisms of S. gallolyticus infection. Our future investigations will address the transcriptional analysis of known virulence factors, the identification and characterization of further putative virulence genes by sequencing the whole genome of S. gallolyticus and knock-out mutation experiments to determine the influence of individual gene function in the pathogenesis of IE. As a result of the distinct behaviour of the isolates from non-human sources, we will also focus on the comparison of human and animal isolates to further elaborate potential differences in infection mechanisms. The specific clinical association with gastrointestinal neoplasia due to S. bovis biotype I or S. gallolyticus, respectively [79] strongly imply that S. gallolyticus enter the human body via the gastrointestinal tract through sites with decreased intestinal barrier function such as colonic malignancies. Unfortunately, a correlation between the number of existing virulence genes, biofilm formation, invasion and adhesion characteristics with the presence or absence of colonic malignancies can barely be created with the small number of available patient data at present. Indeed, the bacterial translocation is the first important step in the development of IE before colonizing the endothelium, and mechanisms of adherence to and invasion of epithelial cells play an important role during this initial phase of infection. Therefore, our future investigations will also address this important mechanism to potentially disclose clues on specific features of individual S. gallolyticus strains.

In conclusion, this is the first description of S. gallolyticus adhesion to and invasion of human endothelial cells. The established in vitro model provides a convenient system to evaluate differences in the virulence characteristics of different strains. Binding to ECM proteins and biofilm formation provide additional information for strain characterization. The first identification of a possible pilus-associated gene in S. gallolyticus supplemented the so far limited availability of possible virulence factors. This study provides important initial characterization of variability and behaviour of the as yet barely analyzed endocarditis pathogen S. gallolyticus.