Abstract
Bacterial resistance to serum is a key virulence factor for the development of systemic infections. The amount of lipopolysaccharide (LPS) and the O-antigen chain length distribution on the outer membrane, predispose Salmonella to escape complement-mediated killing. In Salmonella enterica serovar Enteritidis (S. Enteritidis) a modal distribution of the LPS O-antigen length can be observed. It is characterized by the presence of distinct fractions: low molecular weight LPS, long LPS and very long LPS. In the present work, we investigated the effect of the O-antigen modal length composition of LPS molecules on the surface of S. Enteritidis cells on its ability to evade host complement responses. Therefore, we examined systematically, by using specific deletion mutants, roles of different O-antigen fractions in complement evasion. We developed a method to analyze the average LPS lengths and investigated the interaction of the bacteria and isolated LPS molecules with complement components. Additionally, we assessed the aspect of LPS O-antigen chain length distribution in S. Enteritidis virulence in vivo in the Galleria mellonella infection model. The obtained results of the measurements of the average LPS length confirmed that the method is suitable for measuring the average LPS length in bacterial cells as well as isolated LPS molecules and allows the comparison between strains. In contrast to earlier studies we have used much more precise methodology to assess the LPS molecules average length and modal distribution, also conducted more subtle analysis of complement system activation by lipopolysaccharides of various molecular mass. Data obtained in the complement activation assays clearly demonstrated that S. Enteritidis bacteria require LPS with long O-antigen to resist the complement system and to survive in the G. mellonella infection model.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
Introduction
Salmonella bacteria are facultative intracellular pathogens of worldwide epidemiological importance with a wide range of hosts [1]. In the genus Salmonella, according to 16S rRNA sequence analysis, two species can be distinguished: Salmonella enterica (S. enterica) and Salmonella bongori (S. bongori) [2, 3]. S. enterica species is further divided into six subspecies: enterica, salamae, arizonae, diarizonae, houtenae and indica on the basis of biochemical and phylogenetic relationship. Based on the presence of antigenic determinants (somatic antigen O, ciliary antigen H) S. enterica is further subdivided into serovars. According to the World Health Organization, more than 2600 Salmonella serovars are distinguished using the Kauffmann-White classification, and new serovars are still being discovered [2, 3].
Salmonella bacteria are among the most commonly isolated gastrointestinal pathogens and the second leading cause of gastrointestinal infection in the European Union (EU). They are mainly transmitted through the fecal–oral route [4]. Salmonella bacteria can be classified into typhoidal and non-typhoidal Salmonella strains (NTS). Salmonella Typhi (S. Typhi) strains are the agents that cause typhoid fever, whereas Salmonella Paratyphi (S. Paratyphi) bacteria of groups A, B and C cause paratyphoid fever. Unlike NTS, infections caused by typhoidal strains occur only in humans. They have high mortality rates mainly in underdeveloped regions [5, 6]. NTS include strains other than S. Typhi and S. Paratyphi. NTS are the etiological agent of salmonellosis of various clinical forms, of which the gastrointestinal form is the most common. Globally, NTS predominantly cause a self-limiting disease characterized by abdominal cramps, diarrhea and vomiting [7]. In immunocompetent individuals, secondary bacteremia is thought to be uncommon. However, in Sub-Saharan Africa NTS strains can cause invasive infections (bloodstream infections, meningitis) in immunocompromised individuals [8, 9]. Serovars Salmonella enterica Enteritidis (S. Enteritidis) and Salmonella enterica Typhimurium (S. Typhimurium) are among the most common NTS isolated from humans in the EU. However, their global distribution is not uniform [10, 11].
Lipopolysaccharide (LPS) is the main component of the outer membrane of Gram-negative bacteria and a key virulence factor of NTS strains [12]. LPS forms a barrier between the cell and the external environment, providing the bacteria resistance to antibiotics and detergents. LPS also enables the survival of bacteria in the host organism during colonization, protecting the cell from complement-dependent cytotoxicity (CDC) and opsonophagocytosis [13]. The inflammatory potential of LPS triggers a strong innate immune response in the host, leading to cell lysis or even septic shock [14]. LPS consists of three main structural parts: lipid A, oligosaccharide core and O-antigen (O-Ag). Lipid A is the most conserved LPS domain, while O-Ag has a very high structural diversity among bacterial strains. The O-Ag chain is built up of oligosaccharide repeating units (RUs), with its saccharide structure differing among various strains of a bacterial species. The structural diversity of O-Ag as the distal part of LPS, contribute to its immunogenic properties [15]. The O-antigen has a variable number of RUs, varying from one to even a hundred in a single strain and in a single bacterial cell [16]. It has been shown that in one LPS preparation there may be molecules with high range of molecular weight, due to a varying number of RUs [17, 18].
In S. Enteritidis and S. Typhimurium a modal distribution of the O-antigen length can be observed. It is characterized by the presence of distinct fractions: (i) low molecular weight O-Ag LPS (LMW-OAg LPS)—an O-Ag composed of fewer than 15 RUs, (ii) long O-Ag LPS (L-OAg LPS) with 16–35 RUs and (iii) LPS with very long O-Ag LPS (VL-OAg LPS) with more than 100 RUs [19, 20]. The number of RUs attached to the lipid A-core region is regulated by wzz genes. The gene wzzST is responsible for the synthesis of L-OAg LPS, while wzzfepE controls the VL-OAg LPS synthesis [19, 21,22,23]. It has been shown that such a modal distribution of LPS length can be found among various Enterobacteriaceae [19, 23,24,25,26], but VL-OAg LPS often remains unrecognized due to difficulties in its detection.
Numerous studies have shown that the proportions of individual fractions of LPS molecules on the bacterial cell surface are important in the protection from complement killing [19, 27,28,29,30,31,32,33]. However, the literature data about that influence is incoherent. Studies on S. Typhimurium initially indicated greater importance of the wzzfepE gene, and thereby the VL-OAg LPS fraction, in protecting the bacteria from complement killing [29]. However, results obtained in later experiments indicated that the L-OAg LPS (wzzST gene) fraction is essential for bacterial survival in human serum [30, 34]. It should be emphasized that most of the data regarding the involvement of different LPS O-Ag fractions contributing to Salmonella complement evasion were collected based on experiments carried out on S. Typhimurium serovars. Therefore, the role of VL-OAg and L-OAg LPS in other serovars in bacterial serum resistance is still unclear. Grossman et al. showed that even minor differences in the orientation of –OH groups in the RUs in S. Typhimurium and S. Enteritidis could lead to differences in the activation levels of complement C3 via the alternative pathway [31]. Furthermore, the studied bacterial strains often lack an in-depth characterization of their LPS O-antigen fractions. Most experiments describing Salmonella serum resistance are based on simple serum susceptibility assays, lacking clear evidence of the various modes of bacterial evasion mechanisms to prevent complement killing. In the present work, we investigated the effect of the O-antigen modal length composition of LPS molecules on the surface of S. Enteritidis cells on its ability to evade host complement responses. In order to determine the roles of different LPS types in complement evasion we constructed a panel of chromosomal mutants with different O-antigen fractions, developed a method allowing the analysis of the average LPS lengths and investigated the interaction of the bacteria and isolated lipopolysaccharides with complement components. Additionally, we assessed the aspect of LPS O-antigen chain length in S. Enteritidis virulence in vivo in the Galleria mellonella infection model.
Materials and methods
Bacterial strains and culture conditions
Bacterial strains and plasmids used in this study are presented in Table 1. Bacteria were grown in lysogeny broth medium (LB) (Biocorp). Solid medium contained 1.5% (w/v) agar (Biocorp). Ampicillin (100 µg/ml) or kanamycin (50 µg/ml) (Sigma-Aldrich) were added when appropriate.
Mutagenesis of S. Enteritidis LPS biosynthesis genes
Mutagenesis was performed according to the phage λ Red-mediated homologous recombination method described by Datsenko and Wanner [35]. In brief, wild-type S. Enteritidis PCM 2817 was first transformed with the Red helper plasmid pKD46 and subsequently transformed with PCR products that were generated using pKD4 as a template plasmid, which contains FRT-flanked kanamycin (kan) resistance gene. Linear DNA fragments and competent cells were prepared according to the method described by Czerniak and Hensel [36]. The sequences of the oligonucleotide primers used in this study are available on request. To obtain nonpolar deletion mutants, kan resistance genes were removed by transforming the mutants with plasmid pCP20, which encodes the FLP recombinase system [37]. The lack of appropriate genes was verified by PCR analysis after transformation with the Red helper plasmid pKD46, with PCR-products, with the pCP20 plasmid and to confirm the removal of the kan resistance genes, and sequencing. Additionally corresponding changes in the modal distribution pattern of LPS were verified by SDS-PAGE and GC–MS analysis of LPS monosaccharide components.
LPS isolation and analysis by SDS-PAGE
LPS was isolated by the hot phenol–water method [38]. Briefly, freeze-dried bacteria were suspended in 45% phenol solution (2 g/50 ml) and incubated at 65 °C with intermittent stirring for 15 min. The suspension was cooled to 5 °C, centrifuged (3500 g, 30 min), and the aqueous phase was collected. Water was added to compensate for the collected aqueous phase volume, and the cycle was repeated. The aqueous phases were combined and dialyzed against deionized water to remove residual phenol, then filtered and freeze-dried. The obtained crude LPS was dissolved in MiliQ water and purified by ultracentrifugation (105,000 g, 6 h, 4 °C) [39]. LPS extracts were analyzed by SDS-PAGE using the Laemmli buffer system [40]. Electrophoresis was performed using 6% polyacrylamide stacking gels and 15% separating gels. Samples were loaded into the gels after mixing with Laemmli buffer and heating at 98 °C for 4 min. The SDS-PAGE separation of LPS was performed at constant voltage (120 V), for 90 min using a Mini-Protean Tetra Cell apparatus (Bio-Rad). The separated LPS was visualized using silver staining according to Tsai and Frasch [41] with the modification of Fomsgaard [42] and imaged under white light using a GelDoc XR system (Bio-Rad).
GC–MS analysis of monosaccharides
The following three-letter abbreviations of monosaccharides are used throughout the publication: Gal—d-galactose; Hep—heptose, d-glycero-d-manno-heptose; Kdo—3-deoxy-d-manno-oct-2-ulosonic acid; Man—d-mannose; MuAc—N—acetylmuramic acid; Rha—l-rhamnose, 6-deoxy-l-mannose; Tyv—tyvelose, 3,6-dideoxy-d-arabino-hexose.
Preparation of alditol acetate derivatives of monosaccharides from bacterial mass samples for the analysis of O-antigen monosaccharide composition
To determine the monosaccharide composition of LPS O-antigen, sugar analysis using alditol acetate derivatives was performed. Briefly, bacterial mass (10 mg) was hydrolyzed in 1 ml of 1% CH3COOH (Sigma–Aldrich) in water at 100 °C for 30 min, followed by centrifugation (15 min, 12,000g). HCl (Sigma-Aldrich) was added to the supernatant to a final concentration of 1 M and hydrolysis was carried out at 80 °C for 2 h. After hydrolysis, the sample was neutralized with NaOH (Merck Millipore). After drying under a stream of N2 (Air Products) and rinsing twice with methanol (POCH), the sample was reduced with 1 M NaBH4 (Sigma–Aldrich) solution in water at 4 °C for 24 h. After the reduction, NaBH4 was decomposed with acetic acid, the sample was dried under a stream of N2. After washing twice with methanol the sample was subjected to acetylation: 50 µl of pyridine (Merck Millipore) and 250 µl of acetic anhydride (POCH) were added and incubated at 100 °C for 30 min. Then, the sample was dried under a stream of N2, washed twice with methanol and extracted in a chloroform: water system (POCH). The chloroform phase was collected, dried under a stream of N2 and dissolved in 100 µl of ethyl acetate (Sigma–Aldrich) for gas chromatography coupled with mass spectrometry (GC–MS) analysis.
Preparation of acetylated methylglycosides and acetylated methylglycoside methyl esters from LPS and bacterial mass samples
Bacterial mass (10 mg) was hydrolyzed in 4 M HCl in methanol at 80 °C for 17 h. After incubation, the supernatant was evaporated under a stream of N2 and washed twice with methanol. The sample was acetylated: 20 µl of pyridine and 100 µl of acetic anhydride were added and the sample was heated at 100 °C for 30 min, dried under a stream of N2, washed twice with methanol and extracted in a chloroform: water system. The chloroform phase was collected, dried under a stream of N2 and dissolved in 100 µl of ethyl acetate for GC–MS analysis. LPS (1 mg) was hydrolyzed in 0.75 M HCl in methanol at 80 °C for 1 h, followed by neutralization with NaOH in methanol to a slightly alkaline pH. The sample was centrifuged (5 min, 12,000 g), and the supernatant was evaporated under a stream of N2 and washed twice with methanol. Acetylation and extraction in the chloroform: water system were carried out analogously to the bacterial mass. The resulting acetylated methylglycosides of Tyv and Hep and acetylated methylglycoside methyl esters of Kdo and MuAc were analyzed by GC–MS technique. The experiment was performed in four biological replicates.
GC–MS analysis
Analysis of the monosaccharide derivatives: acetylated methylglycosides and acetylated methylglycoside methyl esters, was carried out using a FOCUS gas chromatograph (Thermo-Scientific) equipped with Zebron ZB-5HT 30 m × 0.25 mm × 0.25 μm w/5 m guard column (Phenomenex) coupled to ITQ 700 ion trap type mass detector (Thermo-Scientific). The analyzed derivatives were acetylated methylglycosides of Tyv, Rha and Hep or methylglycoside acetylated methyl esters of MuAc and Kdo. For Tyv four derivatives of each monosaccharide (α or β anomers with pyranose or furanose ring) were obtained, for Kdo: two derivatives (α and β anomers) and one derivative for Hep or MuAc. The measured amount of each form was added for each sugar. The amounts of Rha or Tyv, as components of the O-specific polysaccharide, were compared to the amounts of Kdo or Hep, as components of the LPS core. The resulting proportions between the O-specific chain and core oligosaccharide components corresponded to the average lengths of the lipopolysaccharide molecules of a given mutant.
Serum
Normal human serum (NHS) was pooled from blood samples from a group of 15 healthy adults (7 males; 8 females). All donors provided a written informed consent. The blood was drawn into Vacutainer serum tubes with a clot activator (SKU 367820, BD). The blood was allowed to clot, and the sera were subsequently harvested by centrifugation (10 min, 1200 g), pooled in even contribution from each donor, aliquoted and stored at − 70 °C until used. The required volume of serum was thawed on ice immediately before use and each portion was used only once. Heat-inactivated serum (HIS) was generated by incubating NHS for 1 h at 56 °C.
Serum susceptibility assays
NHS and HIS were distributed onto a Honeycomb 2 plate (Growth Curves AB Ltd) and incubated with or without Ravulizumab (100 µg/ml; Alexion), a humanized monoclonal complement inhibitor (anti-C5) at ambient temperature for 35 min. The investigated S. Enteritidis PCM 2817 strains were cultured overnight at 37 °C in 3 ml LB medium. After overnight incubation, bacterial cells were transferred into 5 ml of fresh LB medium and incubated at 37 ℃ with rotation to achieve an OD600 value of 0.3 (early exponential phase). Next, bacterial cells were further diluted in 10 mM Tris-HCl buffer (pH = 7.3) supplemented with 150 mM NaCl, 2 mM CaCl2 and 0.5 mM MgCl2 (Sigma-Aldrich). Bacterial cells were added to the plate (CFU = 106/well). The final serum concentration after addition of bacterial cells was 25%. The plate was incubated for 15 h in a BioScreen C (Growth Curves AB Ltd) incubator at 37 °C with continuous shaking. The OD600 of each well was measured every 20 min. The experiment was performed twice with three biological replicates.
C3 cleavage in serum
The investigated S. Enteritidis PCM 2817 strains were cultured overnight at 37 °C in 3 ml LB medium. After overnight incubation, bacterial cells in the early exponential phase were transferred into 5 ml of fresh LB medium and incubated at 37 °C with rotation to achieve an OD600 value of 0.3. Next, bacterial cells were collected by centrifugation (10 min, 5000 g, 4 °C) and washed three times in phosphate-buffered saline (PBS; 137 mM NaCl, 2.7 mM KCl, 8 mM Na2HPO4, and 2 mM KH2PO4 (Sigma–Aldrich), pH 7.4). Bacterial cells (2 × 108 CFU/ml) were incubated in 50% NHS for 10 min at 37 °C with shaking. After incubation the samples were pelleted (10 min, 5000 g, 4 °C) and the supernatants were mixed with Bolt™ LDS buffer and Bolt™ sample reducing agent (Life Technologies), and heated at 95 °C for 5 min. Gel electrophoresis was performed using Bolt™ 4–12% Bis–Tris Plus Mini Gels (Invitrogen) on a Mini Gel Tank in Bolt™ MES buffer (Invitrogen) at 165 V for 45 min. Western blot analysis was performed using the iBlot 2™ system according to the manufacturer’s instructions (Invitrogen). Membrane blocking was carried out with non-fat dried milk in PBS/0.05% Tween 20 (w/v). The products of C3 cleavage by bacteria were detected using primary antibodies: rabbit anti-human C3c (Dako) and secondary antibodies: goat anti-rabbit IgG conjugated with horseradish peroxidase (HRP) (minimal cross-reaction to mouse, human, rat serum proteins, Jackson ImmunoResearch laboratories). After washing, the membrane was incubated in the enhanced chemiluminescence (ECL) substrate containing 1 M Tris HCl, ph 8.5; 250 mM luminol; 90 mM coumaric acid and 30% H2O2. Enhanced chemiluminescence was detected on Super-RX films (Fujifilm Corporation). The experiment was performed in three biological replicates.
Functional complement activation assay
Complement activation via the alternative pathway was measured by an enzyme-linked immunosorbent assay based on Seelen et al. [43]. Briefly, a Nunc MaxiSorp plate (Thermo Scientific) was coated overnight with 1 µg/ml of LPS isolated from the WT and S. Enteritidis PCM 2817 mutants in PBS containing 10 mM MgCl2 (Sigma–Aldrich). The plate was washed three times with PBS containing 0.05% Tween-20 (PBS-T). NHS dilutions were selected on the basis of preliminary tests and prepared in Tris-buffered saline (TBS; 10 mM Tris base and 150 mM NaCl (Sigma–Aldrich), pH 7.4) containing 5 mM MgCl2, 10 mM EGTA (MgEGTA, Sigma–Aldrich), 1% w/v bovine serum albumin (BSA), 0.05% Tween-20 and incubated for 1 h at 37 °C. The plate was washed three times with PBS-T. Next, biotinylated anti-human C5b-9 neoepitope antibody (Hycult, clone aE11) in TBS containing 1% w/v BSA (B-TBS) was added to the wells and the plate was incubated for 1 h at 37 ℃. After washing, streptavidin conjugated with horseradish peroxidase (Pierce™ Streptavidin Poly-HRP, Thermo Scientific) in B-TBS was added and incubated for 1 h at 37 °C. After washing, the reaction was revealed with 3,3′,5,5′-tetramethylbenzidine (TMB) substrate, stopped with 0.5 M sulphuric acid, and absorbance read at 450 nm. Absorbance readings were normalized to a wild-type value of 100%. The experiment was performed in three biological replicates.
Detection of C5b-9 deposition on bacterial surfaces
The deposition of C5b-9 on S. Enteritidis strains was assessed using flow cytometry. Bacterial cells (CFU/ml = 106) were incubated with 50% NHS or HIS for 30 min at 37 °C and washed three times with PBS. Cells were incubated with the monoclonal mouse anti-human C5b-9 antibody (clone aE11) (Hycult) for 45 min at ambient temperature, washed and detected with an anti-mouse Alexa 488 antibody (Abcam) (45 min, ambient temperature). To assess cell permeability, bacterial cells were stained with 7AAD (Invitrogen) according to the manufacturer’s specifications. 7AAD is a fluorescent DNA binding dye, that selectively stains cells with compromised membrane integrity, prior to analysis. Samples were analyzed using the CytoFLEX Flow Cytometry Platform (Beckman Coulter). The experiment was performed in three biological replicates.
Galleria mellonella infection model
G. mellonella larvae were obtained from ZooFaktor (Piastów, Poland). Only larvae characterized by a body length of 20 mm (± 5 mm), body weight of 190 mg (± 30 mg), high mobility and a cream color without dark discoloration were used for the experiment. Tested bacterial strains were grown overnight, and washed three times with PBS and diluted to obtain a bacterial inoculum of 106 and 107 CFU/ml. The survival assay was carried out on an experimental group of 15 larvae. Each larvae was injected with 10 μl of bacterial suspension into the hindmost left proleg using a 50 µl syringe (Hamilton, Bonaduz, Switzerland). After injection, the larvae were placed in a 100 mm Petri dish and incubated at 37 °C. PBS-injected larvae (n = 15) were included in the experiment as control. Larval survival was followed for 120 h. The larvae were considered dead when they did not move in response to physical contact, had lost turgor and melanization was visible. The results are expressed as percent of survival. The experiment was performed in four biological replicates.
Statistical analysis
Calculations were performed using GraphPad Prism (Version 9.2.0). The Shapiro–Wilk test assessed the normality distribution. Ordinary one-way ANOVA with post hoc Dunnett’s or Šídák's analysis were applied to compare groups. The differences with a significance level of p < 0.05 were considered significant.
Results
Mutagenesis of Salmonella Enteritidis LPS O-antigen length mutants
To investigate the role of LPS O-antigen types in complement evasion mechanisms of Salmonella Enteritidis a panel of chromosomal mutants of S. Enteritidis PCM 2817 differing in the LPS O-antigen modal pattern distribution was constructed. LPS preparations isolated from the WT strain and mutants (ΔwzzfepE, ΔwzzST, ΔwzzSTΔwzzfepE, Δwzy) were analyzed by SDS-PAGE and silver staining (Fig. 1). In comparison with the WT strain, LPS isolated from the ΔwzzfepE mutant lacked VL-OAg (Fig. 1) and the ΔwzzST mutant lacked L-OAg (Fig. 1). The LPS of ΔwzzSTΔwzzfepE lacked VL-OAg and L-OAg while the Δwzy null mutant showed only one O-antigen RU in the LPS molecule (Fig. 1). Interestingly, deletion of the wzzfepE gene resulted in a distinct difference in the average L-OAg LPS molecular weight in that strain in comparison to the WT strain (Fig. 1). Additionally, an increased intensity of the VL-OAg LPS bands was observed in the ΔwzzST mutant in comparison to the WT strain (Fig. 1).
Analysis of the average LPS O-antigen chain length
The O-antigen subunit of S. Enteritidis is a tetrasaccharide containing: Rha, Man, Gal and Tyv (Fig. 2) [44]. The analysis of the average length of O-Ag polysaccharide chain was based on the analysis of the ratio between the components of the O-specific part (Rha or Tyv) and the core part (Kdo or Hep), which allows for the determination of the average LPS length. In addition, the content of MuAc in bacterial cells was measured. The Hep/MuAc ratio (LPS core and peptidoglycan markers respectively) provides the information on relative amounts of LPS molecules on the surface assuming that the amount of mureine in the cell wall is comparatively stable between tested strains. The sugar composition of the LPS molecule was confirmed by alditol acetate sugar analysis using GC–MS. We confirmed the presence of monosaccharides in the sample: Rha and Tyv (components of the LPS O-antigen), and Hep (a component of the LPS core oligosaccharide), which were used as chemical markers for estimation of the average lengths of the LPS O-antigens. Analysis of the average lengths of the O-specific parts of LPS was performed on entire bacterial cells and on LPS preparations isolated from the tested S. Enteritidis PCM 2817 strains. Results were expressed as percentage (%), taking the value of 100% for the Δwzy mutant. An example chromatogram, structures of derivatives and mass spectra are presented in the supplementary data, Figs. S1, S2. Analysis of the proportions of Tyv and Rha in the bacterial mass and in the isolated LPS preparations, as well as the proportions of Hep and Kdo in the bacterial mass, showed that there were no significant differences in the ratios obtained from the analysis of the O-antigen and the LPS core markers for the tested S. Enteritidis PCM 2817 strains (supplementary data, Fig. S3). The results confirmed that the selected chemical markers of the O-antigen and core parts of the LPS are constant, and that the markers can be used to analyze the average lengths of LPS in the studied strains.
The average length of LPS O-antigen differs between mutants but the number of LPS molecules is constant
By the analysis of the Tyv/Hep ratio, the average number of repetitive O-antigen subunits per LPS core, i.e. average lengths of the O-specific parts of LPS molecules of the particular S. Enteritidis PCM 2817 mutants were determined. The analysis of bacterial mass showed that the LPS of the WT strain had the highest number of O-specific subunits (Tyv/Hep value of 657%), followed by the decrease of the Tyv/Hep ratios for the tested mutants (Fig. 3A). However, the results obtained for isolated LPS preparations were different: the ΔwzzfepE mutant had the highest Tyv/Hep ratio (821%), while 726% was obtained for the WT strain, 543% for the ΔwzzST strain and 389% for the ΔwzzST ΔwzzfepE strain when compared to Δwzy (100%) (Fig. 3B). Additionally, a comparison of the proportions of the obtained levels of Hep compared to MuAc, found in the bacterial cell wall, indicated a similar number of LPS molecules in the tested strains, as the Hep/MuAc ratio values were similar among strains and ranging from 97 to 104% (Fig. 3C).
Long O-antigen protects S. Enteritidis from complement killing
O-antigen length regulation by wzz genes is required for serum resistance in S. Typhimurium [19, 29]. To determine the effect of O-antigen length on the survival of S. Enteritidis in serum, the tested strains were incubated for 15 h in 25% NHS and OD600 values were measured every 20 min. The strains differed in the levels of susceptibility to the bactericidal effect of 25% NHS (Fig. 4). The WT strain and the ΔwzzfepE mutant survived in serum after 15 h of incubation (Fig. 4A, B). In comparison, the ΔwzzST mutant, lacking L-OAg in the LPS was killed by serum complement (Fig. 4C). The same pattern of serum sensitivity was observed for the mutants, characterized by the shortest O-antigens: ΔwzzSTΔwzzfepE and Δwzy (Fig. 4D, E). None of the tested strains were sensitive in the tested conditions to human serum after adding Ravulizumab, a humanized monoclonal complement inhibitor, which inhibits C5 activation and the downstream formation of lytic C5b-9 complex on the cell surface. This indicates a direct involvement of the complement system in killing of the tested S. Enteritidis PCM 2817 mutants. These data indicates that L-OAg LPS plays a major role for S. Enteritidis in the evasion of the complement system.
O-antigen length influences complement activation
In order to test the effect of O-Ag LPS length on C3 activation in serum, the tested S. Enteritidis PCM 2817 strains were incubated with 50% NHS and the supernatants were analyzed with a Western blotting technique to detect C3 cleavage. All tested strains activated C3 in serum (Fig. 5A). Upon activation of the complement system, the C3α chain was cleaved into two fragments of approximately 68 (α′) and 39 kDa (α′2). They are the results of C3 activation to C3b and subsequently to inactive iC3b. Comparing to the WT strain the highest amount of the α′2 product was observed for the ΔwzzfepE and ΔwzzST mutants, while for ΔwzzSTΔwzzfepE and Δwzy that amount was much lower. Additionally, the level of complement activation via the alternative pathway by the O-antigen LPS types, isolated from the tested S. Enteritidis PCM 2817 strains, was tested by ELISA, where the deposition of C5b-9 on the plate was measured. The level of alternative pathway activation by different LPS types is shown in Fig. 5B. While LPS isolated from the WT strain and the ∆wzzST mutant had similar activation potential, LPS from ∆wzzfepE mutant activated the alternative complement system twice as effectively as the wild-type strain (220% for ∆wzzfepE versus WT). Upon shortening of the average LPS length, the level of complement activation decreased: ∆wzzfepE∆wzzST mutant activated complement by 24%, while the ∆wzy mutant only by 9% (Fig. 5B). The obtained data suggests that VL-OAg LPS modulates activity of the alternative pathway, as the activation potential of LPS from ∆wzzfepE mutant differs distinctly from that of the ∆wzzST and WT strains.
Long O-antigen is required for protection from serum complement
After the experiment with isolated LPS we next analyzed C5b-9 binding to whole cells of the S. Enteritidis PCM 2817 strains and the effect of complement on outer membrane permeability by flow cytometry. Wild-type and mutant strains were incubated in 50% NHS for 30 min. After washing the deposition of C5b-9 was detected with an antibody recognizing a neo-epitope in the C5b-9 complex. Cell permeability was monitored with the fluorescent DNA binding dye 7AAD, which selectively stains cells with compromised membrane integrity. We observed C5b-9 deposition on all tested strains, but its levels were not equal. The strongest binding was observed for the ΔwzzST mutant followed by the ΔwzzSTΔwzzfepE and Δwzy mutants. The level of C5b-9 deposition for the WT strain and ΔwzzfepE mutant was only about one third of that of the ΔwzzST mutant (Fig. 6A). No C5b-9 was detected on bacteria incubated with HIS (data not shown). Cells with permeabilized outer membranes were detected for all tested strains. However, their amounts were more abundant for the strain lacking L-OAg (ΔwzzST) in comparison to the WT strain and ΔwzzfepE mutant (Fig. 6A, B).
Long O-antigen is required for full virulence of S. Enteritidis in the G. mellonella infection model
In order to determine the influence of the O-antigen chain length on the pathogenic potential of S. Enteritidis, we studied the susceptibility of G. mellonella larvae to infection with the wild-type strain and LPS O-antigen mutants. G. melonella larvae were challenged with 106 and 107 CFU/ml bacteria, incubated at 37 °C and monitored for signs of melanization for 120 h. Melanization is a part of the insects’ immune response and is used as a measure to determine the insects’ health status after a challenge with pathogens. The survival rate of larvae after 120 h challenge is shown in Fig. 7A. Infection with WT S. Enteritidis PCM 2817 strain resulted in a high level of pathogenicity in vivo. After 120 h of incubation, the survival rates of larvae were 13% and 53%, respectively for 107 and 106 CFU/ml infection inoculum. The elimination of VL-OAg LPS (∆wzzfepE mutant) reduced the survival of G. mellonella larvae to 7% and 47%, respectively, for both amounts of bacteria after 120 h. However, the survival rate of G. mellonella increased after challenge with the ∆wzzST mutant (27% and 73% for 107 and 106 CFU/ml infection inocula, respectively). This showed that an intact LPS with L-OAg is required to resist the innate immune response of G. mellonella larvae. Infection of larvae with the double knock-out mutant ∆wzzST∆wzzfepE resulted in a similar survival level of G. mellonella as in the two tested conditions. Infection with the ∆wzy mutant resulted in an increase of G. mellonella survival to 73% after injection of 107 CFU/ml bacteria (Fig. 7A). The survival of G. mellonella over time is presented in Fig. 7B. In the experiment, a group of 15 larvae injected with PBS buffer served as a control. After 120 h of incubation, larval survival in the control group was 100% (Fig. 7B).
Discussion
Salmonella bacteria are zoonotic pathogens of major importance to human and animal health worldwide. According to the European Food Safety Authority and the European Center for Disease Prevention and Control, salmonellosis remains the second most frequently reported gastrointestinal infection in humans after campylobacteriosis. In 2018, Salmonella bacteria were responsible for nearly a third of foodborne disease outbreaks in the EU. Slovakia, Spain and Poland were responsible for 67% of all salmonellosis outbreaks in the EU [45]. Salmonella bacteria are characterized by several virulence factors. An infection can lead, apart from diarrhea, to extraintestinal infections and sepsis.
One of the main features that allows S. Enteritidis bacteria to survive in an extremely unfavorable environment is LPS. Literature data about the involvement of different LPS O-antigen types in complement evasion by S. Typhimurium is ambiguous [29, 30, 34]. Therefore, we examined systematically, using specific deletion mutants, roles of VL-OAg, L-OAg and LMW-OAg LPS in complement evasion by S. Enteritidis. First, we characterized the structural properties of the LPS molecules. The measurement of LPS length and its density on the bacterial surface is difficult due to various reasons. Lipopolysaccharides have high structural variability, several LPS length types exist simultaneously in one bacterial cell, and LPS molecules have a tendency to form aggregates of different sizes and experimentally obtained LPS preparations are heterogeneous.
In order to characterize the average LPS O-antigen length of S. Enteritidis PCM 2817 WT strain and mutants (Fig. 1) a method measuring the average length of LPS molecules present in a given bacterial strain was used (Figs. 3 and S3). The essence of the used method is the analysis of the ratio between the amount of sugar components present in the RUs of the O-specific part (length-dependent component) and in one of the LPS core components (length-independent component). This approach was previously used for E. coli O111 LPS, where the colitose to Kdo ratio was measured colorimetrically [17]. To measure the NeuAc(sialic acid) to Kdo ratio in LPS of Salmonella O48 bacteria GC–MS technique was used [33, 46]. In this study, we determined the amount of the chemical markers of the O-specific part of LPS: rhamnose and tyvelose (Fig. S3A, B), as well as of the components of the LPS core: Kdo and heptose (Fig. S3C) using the peracetylated methylglycoside derivatives for the analysis [47]. Rhamnose is a common component of the O antigen [48, 49] and fimbriae [50, 51]. In turn, tyvelose occurs only in some serovars of Yersinia pseudotuberculosis [52], Y. entomophaga [53], S. Enteritidis and S. Typhi [48]. Tyvelose is also a component of the immunogenic glycoprotein TSL-1 from Trichinella spiralis [54]. The low prevalence of tyvelose as a structural component in bacteria and nematodes makes it an interesting chemical marker for the rapid detection of S. Enteritidis. The method used for the average LPS O-Ag chain length analysis is based on the simultaneous analysis of five sugar markers in one sample: Rha, Tyv, Hep, Kdo and MuAc. This method represents a significant advance over the previously used and described method engaging sialic acid as a marker of LPS length, due to the fact that when Salmonella does not produce NeuAc in the O-antigen, such a method cannot be used [55].
The obtained results of the measurements of the average LPS length (Fig. 3A, B) confirmed that they can be used for comparison between strains. Differences in the results obtained from the measurement of the proportions of sugar markers in the whole bacterial mass (Fig. 3A) and in the isolated LPS preparations (Fig. 3B) for the WT strain and the ΔwzzfepE mutant may be due to the used LPS isolation method. The LPS preparations used for the measurements were isolated using the hot phenol–water method, which is recommended for the isolation of very long and long LPS types [38, 56]. The inclusion in the analysis of muraminic acid also allows to compare the proportion of the total numbers of LPS molecules in the cells between individual strains, assuming that the amount of muramine in the cell is constant (Fig. 3C). The analyzed markers differ significantly in their chemical properties: sensitivity to degradation and susceptibility to disruption of the bonds formed in the LPS molecule. Tyv and Kdo are readily released during the methanolysis reaction. However, their methyl glycosides are sensitive to acid degradation, while efficient release of MuAc from peptidoglycan requires longer methanolysis at a higher concentration of HCl. In addition, ester groups in MuAc and Kdo derivatives are sensitive to elevated pH, which hampers the repetitive neutralization of the mixture after the reaction. The method developed may in the future be the basis for a more detailed analysis of the proportions of different types of LPS (VL-OAg, L-OAg, LMW-OAg) on the bacterial cell surface.
In our previous publication we analyzed 21 Salmonella O48 clinical isolates and showed a high variability in the average length of the O-antigen part of LPS molecules ranging up to two orders of magnitude between extreme values [46]. Subsequent experiments on selected strains have shown that even in the same strain the average length can be gradually increased by the bacteria after stimulation with human serum [33]. The mechanisms for the regulation of O-specific chain length during LPS synthesis are still unclear and there are several hypotheses regarding this phenomenon, involving the regulation by synthesis time (the “molecular clock”) [22], or by the length of emerging O-polysaccharide chain (“molecular ruler”) [57]. Recent studies indicate, that the regulation is effected by the expression ratio between the enzymes: WbdA responsible for the elongation of polysaccharide and WbdD responsible for the termination of the synthesis process [58]. A more detailed description of length control of the O-antigen by Wzz proteins was described previously [20]. Additionally, the effect of environmental factors on length regulation is so far very poorly understood and limited to studies on the effect of bactericidal components of the complement system, composition of medium, temperature and also growth phase [31, 34, 59, 60].
Current knowledge in this area is ambiguous. Palva and Mäkäla showed that the LPS on the surface of S. Typhimurium has a low content of molecules with 2–18 repeating O-specific subunits (LMW-OAg) and a more predominant LPS containing 19–34 repeating subunits (L-OAg) (77%) [61]. It is worth noting that, at the time of publication of the study, the form of VL-OAg LPS and the wzzfepE gene responsible for its formation were not yet known. Despite the presence of bands in the electropherograms indicating very long O-specific chains, the authors do not mention the possibility of the occurrence of LPS with more than 100 repeating O-specific subunits [61]. Numerous studies have shown that the proportions of individual length forms of LPS molecules on the surface of the bacterial cell have a significant impact on the protection of Salmonella against the complement system [19, 29, 30, 34, 62]. Previous studies on this phenomenon were performed using mostly S. Typhimurium. That serotype, although closely related to S. Enteritidis, differ in the composition of its O-antigen structure: in S. Typhimurium the monosaccharide tyvelose, present in S. Enteritidis in the repeating unit, is replaced by abequose. It has been shown previously that seemingly such a small difference as the orientation of the −OH groups in the positions C2 and C4 in one monosaccharide of the O-antigen repeating unit has such a distinct impact on the opsonization capacity of those serovars [63].
Therefore, in this the study, the influence of different S. Enteritidis O-antigen LPS types (Figs. 1, 3) on complement evasion was determined. The analysis of survival in 25% NHS showed that the wild-type strain and ΔwzzfepE mutant were serum resistant (Fig. 4A, B), while ΔwzzST,ΔwzzfepE ΔwzzST and Δwzy were serum sensitive (Fig. 4C–E). The obtained results for the WT strain are in accordance with a previously published study, where the strain showed resistance to 50% NHS [62]. The addition of Ravulizumab (anti-C5 antibody blocking the terminal pathway of complement) in the serum challenge resulted in the survival of the serum sensitive strains (Fig. 4A–E). This proved the involvement of the complement membrane attack complex in the killing of the tested bacteria. The obtained results indicate a small contribution of VL-OAg in the protection of S. Enteritidis bacteria against the lytic effect of the complement system. In contrast, L-OAg clearly protects the bacterial cells from complement mediated lysis.
Literature data initially indicated a greater involvement of the wzzfepE gene, and thus VL-OAg, in protection of S. Typhimurium against complement lysis [29]. However, the results obtained in later experiments showed that it is the wzzST gene, which is essential for S. Typhimurium resistance to human serum [29, 34]. Bravo et al. showed that the survival of S. Enteritidis LPS length mutants in 40% NHS is directly linked with the growth phase. Mutation in the wzzfepE gene was found to lead to serum resistance in the logarithmic growth phase but had no influence on the survival in the stationary phase [34].
C3 activation by the tested S. Enteritidis PCM 2817 strains in 50% NHS showed that mutants with a repertoire of longer O-specific chains on the bacterial cell surface (WT, ΔwzzfepE, ΔwzzST) more effectively activated the C3 protein of the complement system (Fig. 5A). However, we observed differences in complement activation between the entire bacterial cells and isolated LPS molecules. The analysis of that activation by isolated LPS preparations showed that the ΔwzzfepE LPS mutant activated the complement system to a higher degree than the LPS isolated from the WT strain (Fig. 5B). In contrast, C5b-9 deposition on entire bacterial cells was more abundant for the ΔwzzST strain than for the WT strain. This discrepancy might be related to the previously discussed method of LPS isolation (Fig. 6A) [56] or to the difference between the physical state of the LPS molecules on the intact bacterial surface vs. isolated LPS preparation immobilized on polystyrene. The observed discrepancy in the level of activation of the complement system for bacterial cells and isolated LPS molecules could mean that with a shorter O-antigen, there is lowered activation of the complement system. Based on flow cytometry experiments (Fig. 6) it can be concluded that the WT strain and ΔwzzfepE mutant deposit the end products of the complement cascade on their surfaces, but the C5b-9 complex is released from the cell surface without lysing the bacterial cell (Fig. 6B). Similar conclusions were reached by Joiner et al. studying the mechanism of resistance of S. Minnesota smooth and rough strains exposed to human serum. The authors showed that in serum-resistant strains, complement components are deposited on the polysaccharide portion of LPS, which forms a physical barrier separating them from the lipid portion of the cell membrane [28, 64]. It would be useful to know the exact proportions between the individual O-antigen types (VL-OAg, L-OAg, LMW-OAg) of LPS in individual S. Enteritidis PCM 2817 mutants. If mutation in the ΔwzzST gene affects the activation of the complement system to a greater extent (Fig. 6A) than the mutation in the ΔwzzfepE gene, it can be postulated that the appropriate density of LPS with long O-specific chains on the surface of the outer membrane is of key importance in protecting S. Enteritidis against complement lysis. Most likely, the higher density of L-OAg LPS on the ΔwzzfepE mutant is protective against the incorporation of the C5b-9 complex into the bacterial cell membrane, while in the case of the ΔwzzST mutant, the density of VL-OAg LPS is probably not high enough to protect the bacteria from depositing C5b-9 on the outer membrane (Fig. 6). VL-OAg LPS, as shown in the experiments with monosaccharide markers of O-Ag and LPS core (Fig. 3A, B), constitute only a tiny molar part of the total LPS. This implies that VL-OAg molecules are very sparsely distributed on the bacterial surface. In that mutant the L-OAg LPS molecules are most probably replaced by LMW-OAg or LPS with one repeating unit, as the overall number of LPS molecules is constant (Fig. 3C). As it turns out from the SDS PAGE analysis, the molar content of VL-OAg LPS is low, and the lack of L-OAg in wzzST mutant is probably not compensated by VL-OAg LPS. The polysaccharide layer on the outer membrane is thus much more susceptible to the action of serum proteins. Therefore, despite prominent C5b-9 deposition, permeability data suggests that the forming MAC cannot penetrate the membrane (Fig. 6). L-OAg LPS in turn strongly activates the complement alternative pathway (Fig. 5B), which is apparently somehow attenuated by the presence of VL-OAg. In the presence of short and very short LPS molecules this activation capability is very low, although the perforation of the membrane built up of such short molecules is the strongest (Fig. 6B).
In vivo experiments, using laboratory animals is an essential element in determining the degree of pathogenicity of bacterial strains and in understanding interactions between the host and the pathogen. Although the use of rodent models is widely used in the study concerning the pathogenesis of Salmonella infections, mammalian studies are often time-consuming, require an expensive experimental set up and are associated with significant ethical issues. The introduction of invertebrate models allows for a substantial reduction of research costs and minimizing the ethical concerns. Numerous studies have confirmed that the Wax moth G. mellonella is a convenient model to test some aspects of the pathogenicity of bacterial strains [65,66,67,68,69,70,71]. Bender et al. showed that the structure of LPS affects the virulence of S. Typhimurium NCTC 12023. G. mellonella survival after injection with mutant strains lacking the synthesis of VL-OAg or L-OAg was greater, than the survival of larvae after injection with the wild-type strain. In addition, the authors showed that removal of the entire O-specific antigen was associated with the loss of virulence of S. Typhimurium NCTC 12023 in the G. mellonella infection model [70]. Our investigations are in accordance with those observations, showing that the elimination of a particular fraction of O-antigen had an effect of the survival rate of G. mellonella larvae. After challenge with S. Enteritidis PCM 2817 WT and the ΔwzzfepE most of the larval population did not survived (survival 13% and 7%, respectively) (Fig. 7A, CFU/ml 107). The elimination of the L-OAg LPS reduced the pathogenicity to 27% of survival, indicating the importance of long O-antigens as a virulence factor of S. Enteritidis (Fig. 7A, CFU/ml 107). The obtained results confirm the observations of Bender et al. [70] that the structure of LPS may affect the pathogenicity of strains in the infection model of G. mellonella larvae. An interesting observation is that the lack of VL-OAg increases bacterial virulence (increased larval mortality, Fig. 7A). Perhaps the bacteria produce other structures on the surface of the outer membrane that compensate for the lack of VL-OAg. Surprisingly, the survival rate of wax moth larvae subjected to infection with ΔwzzfepE was lower than larvae infected with WT or double mutants. This suggests that VL-LPS can have a moderating role at least in invertebrates (Fig. 7A).
Previous research of other groups concentrated on immunological aspects of LPS length diversity, but the molecular characterization of the O-antigen length was limited to SDS-PAGE analysis with various types of LPS pattern visualization. In our work we have analyzed the length of LPS O-specific polysaccharide using mass spectrometry, therefore we could precisely compare the LPS modal distribution in particular mutants. The elaborated method utilizes tyvelose as an LPS length marker, which has advantages over the previously used method using sialic acid, which could not be used in strains lacking NeuAc [55]. Our method can be also used for quick S. Enteritidis strain identification by detection of Tyv. Previous publications by other groups have mainly studied the S. Typhimurium serotype, which is an predominant serovar in the United States. S. Enteritidis, which is prevalent in Europe and used in the present work, have not yet been studied in this regard. Several publication compare the immunological aspects of reactivity of different strains [28, 64] and different serotypes, where the O-antigen polysaccharide structure is not identical [63]. That approach may introduce variables into the experiment that will not be taken into account. In our publication, we use different mutants of the same Salmonella strain, differing only in the pattern of LPS modal distribution, which allows us to analyze the impact of just that single factor. We also analyze multiple aspects of complement activation, using not only survival in serum but also the more subtle aspects of complement system activation, like C3 activation, specific blocking of C5, C5b9 deposition, bacterial cell permeability and finally preliminary in vivo study on larvae model.
Although the phenomenon of modulation of the length of the lipopolysaccharide molecule probably cannot be used for vaccine construction, the different modal distribution of lipopolysaccharide and the absence of some LPS fractions, especially VL-OAg and L-OAg LPS, may lead to better exposure of some immunogenic structures, such as fimbriae or outer membrane proteins, on the bacterial surface. This in turn may make such bacteria more susceptible to attack by complement or specific antibodies, and vaccines based on the aforementioned structures may be more effective against these bacteria.
To summarize, the obtained data clearly demonstrate that S. Enteritidis bacteria require LPS with a specific modal length to resist complement-mediated lysis and to survive in the G. mellonella infection model. The results indicate a particular contribution of L-OAg in bacterial virulence. The observed inconsistency of the activation potential between isolated LPS and entire bacterial cells is intriguing and requires further study in future.
Data availability
No datasets were generated or analysed during the current study.
References
CDC (2022) Salmonella and Food. In: Cent Dis Control Prev. https://www.cdc.gov/foodsafety/communication/salmonella-food.html. Accessed 23 Nov 2022
Antigenic Formulae of the Salmonella Serovars 2007 9th edition.pdf
Issenhuth-Jeanjean S, Roggentin P, Mikoleit M et al (2014) Supplement 2008–2010 (no. 48) to the White-Kauffmann-Le Minor scheme. Res Microbiol 165:526–530. https://doi.org/10.1016/j.resmic.2014.07.004
Salmonellosis (2020) - annual epidemiological report for 2017. In: Eur Cent Dis Prev Control. https://www.ecdc.europa.eu/en/publications-data/salmonellosis-annual-epidemiological-report-2017. Accessed 20 Sep 2022
Eng S-K, Pusparajah P, Ab Mutalib N-S et al (2015) Salmonella: a review on pathogenesis, epidemiology and antibiotic resistance. Front Life Sci 8:284–293. https://doi.org/10.1080/21553769.2015.1051243
Hardy A (2004) Salmonella: a continuing problem. Postgrad Med J 80:541–545. https://doi.org/10.1136/pgmj.2003.016584
Lokken KL, Walker GT, Tsolis RM (2016) Disseminated infections with antibiotic-resistant non-typhoidal Salmonella strains: contributions of host and pathogen factors. Pathog Dis 74:ftw103. https://doi.org/10.1093/femspd/ftw103
Stanaway JD, Parisi A, Sarkar K et al (2019) The global burden of non-typhoidal salmonella invasive disease: a systematic analysis for the Global burden of disease study 2017. Lancet Infect Dis 19:1312–1324. https://doi.org/10.1016/S1473-3099(19)30418-9
Gilchrist JJ, MacLennan CA (2019) Invasive nontyphoidal Salmonella disease in Africa. EcoSal Plus 8(2):10–1128. https://doi.org/10.1128/ecosalplus.ESP-0007-2018
Hendriksen RS, Vieira AR, Karlsmose S et al (2011) Global monitoring of Salmonella Serovar distribution from the World Health Organization Global Foodborne Infections Network country data bank: results of quality assured laboratories from 2001 to 2007. Foodborne Pathog Dis 8:887–900. https://doi.org/10.1089/fpd.2010.0787
Ferrari RG, Rosario DKA, Cunha-Neto A et al (2019) Worldwide epidemiology of Salmonella Serovars in animal-based foods: a meta-analysis. Appl Environ Microbiol 85:e00591-e619. https://doi.org/10.1128/AEM.00591-19
Dos Santos AMP, Ferrari RG, Conte-Junior CA (2019) Virulence factors in Salmonella Typhimurium: the sagacity of a bacterium. Curr Microbiol 76:762–773. https://doi.org/10.1007/s00284-018-1510-4
Gunn JS (2000) Mechanisms of bacterial resistance and response to bile. Microbes Infect 2:907–913. https://doi.org/10.1016/S1286-4579(00)00392-0
Ramachandran G (2014) Gram-positive and gram-negative bacterial toxins in sepsis. Virulence 5:213–218. https://doi.org/10.4161/viru.27024
Lerouge I, Vanderleyden J (2002) O-antigen structural variation: mechanisms and possible roles in animal/plant–microbe interactions. FEMS Microbiol Rev 26:17–47. https://doi.org/10.1111/j.1574-6976.2002.tb00597.x
Rhee SH (2014) Lipopolysaccharide: basic biochemistry, intracellular signaling, and physiological impacts in the gut. Intest Res 12:90–95. https://doi.org/10.5217/ir.2014.12.2.90
Goldman RC, Joiner K, Leive L (1984) Serum-resistant mutants of Escherichia coli O111 contain increased lipopolysaccharide, lack an O antigen-containing capsule, and cover more of their lipid A core with O antigen. J Bacteriol 159:877–882. https://doi.org/10.1128/jb.159.3.877-882.1984
Jann B, Reske K, Jann K (1975) Heterogeneity of lipopolysaccharides. Analysis of polysaccharide chain lengths by sodium dodecylsulfate-polyacrylamide gel electrophoresis. Eur J Biochem 60:239–246. https://doi.org/10.1111/j.1432-1033.1975.tb20996.x
Murray GL, Attridge SR, Morona R (2003) Regulation of Salmonella typhimurium lipopolysaccharide O antigen chain length is required for virulence; identification of FepE as a second Wzz. Mol Microbiol 47:1395–1406. https://doi.org/10.1046/j.1365-2958.2003.03383.x
Krzyżewska-Dudek E, Kotimaa J, Kapczyńska K et al (2022) Lipopolysaccharides and outer membrane proteins as main structures involved in complement evasion strategies of non-typhoidal Salmonella strains. Mol Immunol 150:67–77. https://doi.org/10.1016/j.molimm.2022.08.009
Stevenson G, Kessler A, Reeves PR (1995) A plasmid-borne O-antigen chain length determinant and its relationship to other chain length determinants. FEMS Microbiol Lett 125:23–30. https://doi.org/10.1111/j.1574-6968.1995.tb07330.x
Bastin DA, Stevenson G, Brown PK et al (1993) Repeat unit polysaccharides of bacteria: a model for polymerization resembling that of ribosomes and fatty acid synthetase, with a novel mechanism for determining chain length. Mol Microbiol 7:725–734. https://doi.org/10.1111/j.1365-2958.1993.tb01163.x
Batchelor RA, Haraguchi GE, Hull RA, Hull SI (1991) Regulation by a novel protein of the bimodal distribution of lipopolysaccharide in the outer membrane of Escherichia coli. J Bacteriol 173:5699–5704. https://doi.org/10.1128/jb.173.18.5699-5704.1991
Ozenberger BA, Nahlik MS, McIntosh MA (1987) Genetic organization of multiple fep genes encoding ferric enterobactin transport functions in Escherichia coli. J Bacteriol 169:3638–3646. https://doi.org/10.1128/jb.169.8.3638-3646.1987
Schmitt MP, Payne SM (1988) Genetics and regulation of enterobactin genes in Shigella flexneri. J Bacteriol 170:5579–5587. https://doi.org/10.1128/jb.170.12.5579-5587.1988
Morona R, Van Den Bosch L, Daniels CY (2000) Evaluation of Wzz/MPA1/MPA2 proteins based on the presence of coiled-coil regions. Microbiology 146:1–4. https://doi.org/10.1099/00221287-146-1-1
Liang-Takasaki CJ, Grossman N, Leive L (1983) Salmonellae activate complement differentially via the alternative pathway depending on the structure of their lipopolysaccharide O-antigen. J Immunol Baltim Md 130:1867–1870
Joiner KA, Hammer CH, Brown EJ, Frank MM (1982) Studies on the mechanism of bacterial resistance to complement-mediated killing. II. C8 and C9 release C5b67 from the surface of Salmonella minnesota S218 because the terminal complex does not insert into the bacterial outer membrane. J Exp Med 155:809–819. https://doi.org/10.1084/jem.155.3.809
Murray GL, Attridge SR, Morona R (2005) Inducible serum resistance in Salmonella typhimurium is dependent on wzzfepE-regulated very long O antigen chains. Microbes Infect 7:1296–1304. https://doi.org/10.1016/j.micinf.2005.04.015
Murray GL, Attridge SR, Morona R (2006) Altering the length of the lipopolysaccharide O antigen has an impact on the interaction of Salmonella enterica Serovar Typhimurium with macrophages and complement. J Bacteriol 188:2735–2739. https://doi.org/10.1128/JB.188.7.2735-2739.2006
Grossman N, Schmetz MA, Foulds J et al (1987) Lipopolysaccharide size and distribution determine serum resistance in Salmonella montevideo. J Bacteriol 169:856–863. https://doi.org/10.1128/jb.169.2.856-863.1987
Tomás JM, Ciurana B, Benedí VJ, Juarez A (1988) Role of Lipopolysaccharide and complement in susceptibility of Escherichia coli and Salmonella typhimurium to non-immune Serum. Microbiology 134:1009–1016. https://doi.org/10.1099/00221287-134-4-1009
Pawlak A, Rybka J, Dudek B et al (2017) Salmonella O48 serum resistance is connected with the elongation of the lipopolysaccharide O-Antigen containing sialic acid. Int J Mol Sci 18:2022. https://doi.org/10.3390/ijms18102022
Bravo D, Silva C, Carter JA et al (2008) Growth-phase regulation of lipopolysaccharide O-antigen chain length influences serum resistance in serovars of Salmonella. J Med Microbiol 57(8):938–946. https://doi.org/10.1099/jmm.0.47848-0
Datsenko KA, Wanner BL (2000) One-step inactivation of chromosomal genes in Escherichia coli K-12 using PCR products. Proc Natl Acad Sci USA 97:6640–6645. https://doi.org/10.1073/pnas.120163297
Czarniak F, Hensel M (2015) Red-mediated recombineering of Salmonella enterica genomes. Methods Mol Biol Clifton NJ 1225:63–79. https://doi.org/10.1007/978-1-4939-1625-2_4
Cherepanov PP, Wackernagel W (1995) Gene disruption in Escherichia coli: TcR and KmR cassettes with the option of Flp-catalyzed excision of the antibiotic-resistance determinant. Gene 158:9–14
Westphal O, Westphal O, Jann K (1965) Bacterial lipopolysaccharide-extraction with phenol water and further application of procedure. Methods Carbohydr Chem 5:83–97
Petersson C, Niedziela T, Jachymek W et al (1997) Structural studies of the O-specific polysaccharide of Hafnia alvei strain PCM 1206 lipopolysaccharide containing D-allothreonine. Eur J Biochem 244:580–586
Laemmli UK (1970) Cleavage of structural proteins during the assembly of the head of bacteriophage T4. Nature 227:680–685
Tsai CM, Frasch CE (1982) A sensitive silver stain for detecting lipopolysaccharides in polyacrylamide gels. Anal Biochem 119:115–119
Fomsgaard A, Freudenberg MA, Galanos C (1990) Modification of the silver staining technique to detect lipopolysaccharide in polyacrylamide gels. J Clin Microbiol 28:2627–2631
Ma S, A R, J W, et al (2005) Functional analysis of the classical, alternative, and MBL pathways of the complement system: standardization and validation of a simple ELISA. J Immunol Methods 296:187–198. https://doi.org/10.1016/j.jim.2004.11.016
Hellerqvist CG, Lindberg B, Svensson S et al (1969) Structural studies on the O-specific side chains of the cell wall lipopolysaccharides from Salmonella typhi and S. enteritidis. Acta Chem Scand 23:1588–1596. https://doi.org/10.3891/acta.chem.scand.23-1588
European Food Safety Authority, European Centre or Disease Prevention and Control (2019) The European Union summary report on antimicrobial resistance in zoonotic and indicator bacteria from humans, animals and food in 2017. EFSA J Eur Food Saf Auth 17:e05598. https://doi.org/10.2903/j.efsa.2019.5598
Bugla-Płoskońska G, Rybka J, Futoma-Kołoch B et al (2010) Sialic acid-containing lipopolysaccharides of Salmonella O48 strains–potential role in camouflage and susceptibility to the bactericidal effect of normal human serum. Microb Ecol 59:601–613. https://doi.org/10.1007/s00248-009-9600-2
Rybka J, Gamian A (2006) Determination of endotoxin by the measurement of the acetylated methyl glycoside derivative of Kdo with gas-liquid chromatography-mass spectrometry. J Microbiol Methods 64:171–184. https://doi.org/10.1016/j.mimet.2005.04.029
Liu B, Knirel YA, Feng L et al (2014) Structural diversity in Salmonella O antigens and its genetic basis. FEMS Microbiol Rev 38:56–89. https://doi.org/10.1111/1574-6976.12034
Liu B, Knirel YA, Feng L et al (2008) Structure and genetics of Shigella O antigens. FEMS Microbiol Rev 32:627–653. https://doi.org/10.1111/j.1574-6976.2008.00114.x
Guerry P, Ewing CP, Schirm M et al (2006) Changes in flagellin glycosylation affect Campylobacter autoagglutination and virulence. Mol Microbiol 60:299–311. https://doi.org/10.1111/j.1365-2958.2006.05100.x
Takeuchi K, Taguchi F, Inagaki Y et al (2003) Flagellin glycosylation island in Pseudomonas syringae pv. glycinea and its role in host specificity. J Bacteriol 185:6658–6665. https://doi.org/10.1128/JB.185.22.6658-6665.2003
Kondakova AN, Bystrova OV, Shaikhutdinova RZ et al (2009) Structure of the O-antigen of yersinia pseudotuberculosis O: 4a revised. Carbohydr Res 344:531–534. https://doi.org/10.1016/j.carres.2008.12.010
Sizova OV, Kondakova AN, Shashkov AS et al (2017) Structure and gene cluster of a tyvelose-containing O-polysaccharide of an entomopathogenic bacterium Yersinia entomophaga MH96T related to Yersinia pseudotuberculosis. Carbohydr Res 445:93–97. https://doi.org/10.1016/j.carres.2017.04.013
Goyal PK, Wheatcroft J, Wakelin D (2002) Tyvelose and protective responses to the intestinal stages of Trichinella spiralis. Parasitol Int 51:91–98. https://doi.org/10.1016/s1383-5769(02)00002-8
Dudek B, Książczyk M, Krzyżewska E et al (2019) Comparison of the phylogenetic analysis of PFGE profiles and the characteristic of virulence genes in clinical and reptile associated Salmonella strains. BMC Vet Res 15:312. https://doi.org/10.1186/s12917-019-2019-1
Darveau RP, Hancock RE (1983) Procedure for isolation of bacterial lipopolysaccharides from both smooth and rough Pseudomonas aeruginosa and Salmonella typhimurium strains. J Bacteriol 155:831–838. https://doi.org/10.1128/jb.155.2.831-838.1983
Tocilj A, Munger C, Proteau A et al (2008) Bacterial polysaccharide co-polymerases share a common framework for control of polymer length. Nat Struct Mol Biol 15:130–138. https://doi.org/10.1038/nsmb.1374
King JD, Berry S, Clarke BR et al (2014) Lipopolysaccharide O antigen size distribution is determined by a chain extension complex of variable stoichiometry in Escherichia coli O9a. Proc Natl Acad Sci 111:6407–6412. https://doi.org/10.1073/pnas.1400814111
Delgado MA, Mouslim C, Groisman EA (2006) The PmrA/PmrB and RcsC/YojN/RcsB systems control expression of the Salmonella O-antigen chain length determinant. Mol Microbiol 60:39–50. https://doi.org/10.1111/j.1365-2958.2006.05069.x
McConnell M, Wright A (1979) Variation in the structure and bacteriophage-inactivating capacity of Salmonella anatum lipopolysaccharide as a function of growth temperature. J Bacteriol 137:746–751. https://doi.org/10.1128/jb.137.2.746-751.1979
Palva ET, Mäkelä PH (1980) Lipopolysaccharide heterogeneity in Salmonella typhimurium analyzed by sodium dodecyl sulfate polyacrylamide gel electrophoresis. Eur J Biochem 107:137–143. https://doi.org/10.1111/j.1432-1033.1980.tb04634.x
Dudek B, Krzyżewska E, Kapczyńska K et al (2016) Proteomic analysis of outer membrane proteins from Salmonella Enteritidis strains with different sensitivity to human serum. PLoS ONE 11:e0164069. https://doi.org/10.1371/journal.pone.0164069
Grossman N, Svenson SB, Leive L, Lindberg AA (1990) Salmonella O antigen-specific oligosaccharide-octyl conjugates activate complement via the alternative pathway at different rates depending on the structure of the O antigen. Mol Immunol 27:859–865. https://doi.org/10.1016/0161-5890(90)90152-p
Joiner KA, Hammer CH, Brown EJ et al (1982) Studies on the mechanism of bacterial resistance to complement-mediated killing. I. Terminal complement components are deposited and released from Salmonella minnesota S218 without causing bacterial death. J Exp Med 155:797–808. https://doi.org/10.1084/jem.155.3.797
Jl I, E L, D M, et al (2013) Modeling Klebsiella pneumoniae pathogenesis by infection of the wax moth Galleria mellonella. Infect Immun 81:3552–3565. https://doi.org/10.1128/IAI.00391-13
Andrejko M, Zdybicka-Barabas A, Cytryńska M (2014) Diverse effects of Galleria mellonella infection with entomopathogenic and clinical strains of Pseudomonas aeruginosa. J Invertebr Pathol 115:14–25. https://doi.org/10.1016/j.jip.2013.10.006
Koch G, Nadal-Jimenez P, Cool RH, Quax WJ (2014) Assessing Pseudomonas virulence with nonmammalian host: Galleria mellonella. Methods Mol Biol Clifton NJ 1149:681–688. https://doi.org/10.1007/978-1-4939-0473-0_52
Jønsson R, Struve C, Jenssen H, Krogfelt KA (2017) The wax moth Galleria mellonella as a novel model system to study Enteroaggregative Escherichia coli pathogenesis. Virulence 8:1894–1899. https://doi.org/10.1080/21505594.2016.1256537
Viegas SC, Mil-Homens D, Fialho AM, Arraiano CM (2013) The virulence of Salmonella enterica Serovar Typhimurium in the insect model galleria mellonella is impaired by mutations in RNase E and RNase III. Appl Environ Microbiol 79:6124–6133. https://doi.org/10.1128/AEM.02044-13
Bender JK, Wille T, Blank K et al (2013) LPS structure and PhoQ activity are important for Salmonella Typhimurium virulence in the Galleria mellonella infection model [corrected]. PLoS ONE 8:e73287. https://doi.org/10.1371/journal.pone.0073287
Luiz de Freitas L, Pereira da Silva F, Fernandes KM et al (2021) The virulence of Salmonella enteritidis in galleria mellonella is improved by N-dodecanoyl-homoserine lactone. Microb Pathog 152:104730. https://doi.org/10.1016/j.micpath.2021.104730
Acknowledgements
This work was supported by the National Science Center Poland (2017/25/N/NZ6/02295), The Polish National Agency for Academic Exchange (PPN/IWA/2018/1/00034/U/00001), The Sigrid Juselius Foundation (4708373), Helsinki University Hospital (TYH2022315, TYH2023322) grants and The Academy of Finland. Graphical abstract and Figure 1 were created with BioRender.com.
Author information
Authors and Affiliations
Contributions
Eva Krzyżewska-Dudek, Juha Kotimaa, Krzysztof Pawlik, Seppo Meri and Jacek Rybka contributed to the study conception and design. Material preparation and data collection were performed by Eva Krzyżewska-Dudek, Vinaya Dulipati, Katarzyna Kapczyńska, Mateusz Noszka, Carmen Chen, Marta Książczyk and Bartłomiej Dudek. Data analysis and interpretation of the data were performed by Eva Krzyżewska-Dudek, Vinaya Dulipati, Katarzyna Kapczyńska, Juha Kotimaa, Krzysztof Pawlik, Jacek Rybka and Seppo Meri. The first draft of the manuscript was written by Eva Krzyżewska-Dudek, Juha Kotimaa, Seppo Meri and Jacek Rybka and all authors commented on previous versions of the manuscript. All authors read and approved the final manuscript.
Corresponding author
Ethics declarations
Conflict of interest
The authors have no conflicts of interest to declare.
Additional information
Edited by: I. Bekeredjian-Ding.
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Supplementary Information
Below is the link to the electronic supplementary material.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article's Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article's Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Krzyżewska-Dudek, E., Dulipati, V., Kapczyńska, K. et al. Lipopolysaccharide with long O-antigen is crucial for Salmonella Enteritidis to evade complement activity and to facilitate bacterial survival in vivo in the Galleria mellonella infection model. Med Microbiol Immunol 213, 8 (2024). https://doi.org/10.1007/s00430-024-00790-3
Received:
Accepted:
Published:
DOI: https://doi.org/10.1007/s00430-024-00790-3