Bordetella holmesii Lipopolysaccharide Hide and Seek Game with Pertussis: Structural Analysis of the O-Specific Polysaccharide and the Core Oligosaccharide of the Type Strain ATCC 51541

Abstract Whooping cough is a highly contagious disease caused predominantly by Bordetella pertussis, but it also comprises of a pertussis-like illness caused by B. holmesii. The virulence factors of B. holmesii and their role in the pathogenesis remain unknown. Lipopolysaccharide is the main surface antigen of all Bordetellae. Data on the structural features of the lipopolysaccharide (LPS) of B. holmesii are scarce. The poly- and oligosaccharide components released by mild acidic hydrolysis of the LPS were separated and investigated by 1H and 13C NMR spectroscopy, mass spectrometry, and chemical methods. The structures of the O-specific polysaccharide and the core oligosaccharide of B. holmesii ATCC 51541 have been identified for the first time. The novel pentasaccharide repeating unit of the B. holmesii O-specific polysaccharide has the following structure: {→2)-α-l-Rhap-(1→6)-α-d-Glcp-(1→4)-[β-d-GlcpNAc-(1→3]-α-d-Galp-(1→3)-α-d-GlcpNAc-(1→}n. The SDS-PAGE and serological cross-reactivities of the B. holmesii LPS suggested the similarity between the core oligosaccharides of B. holmesii ATCC 51541 and B. pertussis strain 606. The main oligosaccharide fraction contained a nonasaccharide. The comparative analysis of the NMR spectra of B. holmesii core oligosaccharide fraction with this of the B. pertussis strain 606 indicated that the investigated core oligosaccharides were identical.


Introduction
Bacterial genus Bordetella belongs to the Alcaligenceae family. Bordetellae are Gram-negative, aerobic, and typically small coccobacilli [1]. Extensive molecular analysis of the ribosomal 16S RNA extended the list of known Bordetella species. Currently the Genus comprises sixteen species: B. pertussis, B. parapertussis, B. bronchiseptica, B. holmesii, B. petrii, B. hinzii, B. pseudohinzii, B. trematum, B. avium, B. ansorpii, B. flabillis, B. bronchialis, B. sputigena, B. muralis, B. tumulicola, B. tumbae [2]. The most prominent for the genus Bordetella is Bordetella pertussis-exclusively human pathogen, responsible for whooping cough-a highly contagious disease of respiratory tract, especially dangerous for infants and young children. Some milder form of pertussis may be also caused by Bordetella holmesii, another Bordetella-a human pathogen predominantly isolated from immunocompromised patients [3,4]. B. pertussis, B. parapertussis, B. bronchiseptica, that is the classical Bordetellae, are closely related pathogenic bacteria and termed the "Bordetella bronchiseptica cluster" [5]. The initial 16 rRNA analysis of B. holmesii indicated that this bacterium was closely related to B. pertussis [1,3], but recent genomic data has suggested that there are substantial differences and thus B. holmesii does not composition of the medium was modified. Recently published research has shown that the addition of riboflavin (10 µg/mL) in case of low B. pertussis density stimulated its growth [21], and likewise, we also observed a better growth of B. holmesii. When compared to the standard SS medium the yield of B. holmesii growth on SS medium with riboflavin under the same conditions was doubled (In 250 mL of medium an increase from 0.1 g to 0.2 g of dried bacterial mass was observed).
The LPS of Bordetella species were extracted from dried bacterial mass by the modified hot phenol/water method [22] and purified by ultracentrifugation [23]. The SDS-PAGE analysis of the LPS preparation of different Bordetella species showed the smooth-type LPS of B. holmesii ATCC 51541 and B. parapertussis 529. The rough-type LOS were detected for B. pertussis strains 186 and 606 as well as for B. bronchiseptica strains 530 and 1943 ( Figure 1A). The electrophoretic separation of complete lipooligosaccharide (LOS) of B. pertussis yields two bands described as the "A-band" (slow-migrating) and the "B-band" (fast-migrating). The A-band is a complete LOS structure consisting of lipid A, core oligosaccharide, and the distal trisaccharide [α-d-GlcpNAc-(1→4)β-d-Manp2NAc3NAcA-(1→3)-β-l-Fucp2NAc4NMe-(1→]. B-band is an incomplete LOS that lacks the terminal trisaccharide. The intact oligosaccharide molecule is a dodecasaccharide, and OS that lacks distal trisaccharide is a nonasaccharide. In the SDS-PAGE of B. pertussis 186 LOS both bands are observed. In the SDS-PAGE of LOS of B. pertussis 606 only B-band is present, which confirms that B. pertussis 606 is a rough strain, producing LOS that lacks the distal trisaccharide. B. holmesii ATCC 51541 showed a smooth-type LPS in the SDS-PAGE analysis. We observed a band in the region of lipid A linked to the core and a set of bands in the O-antigen region. In the immunoblotting analysis, the fast migrating core-lipid A band of B. holmesii LPS cross-reacted with rabbit sera containing antibodies directed against complete bacterial cells of a mixture of B. pertussis strains 186/576/606/629 ( Figure 1C) as well as with rabbit sera containing polyclonal antibodies directed against B. pertussis 186 OS-PT glycoconjugate ( Figure 1B). Electrophoretic and serological analyses have indicated that the OS structure of B. holmesii core may be similar to the structure of B. pertussis 606 OS. B. holmesii on the standard SS medium was weak, with very low efficiency, therefore the composition of the medium was modified. Recently published research has shown that the addition of riboflavin (10 µg/mL) in case of low B. pertussis density stimulated its growth [21], and likewise, we also observed a better growth of B. holmesii. When compared to the standard SS medium the yield of B. holmesii growth on SS medium with riboflavin under the same conditions was doubled (In 250 mL of medium an increase from 0.1 g to 0.2 g of dried bacterial mass was observed). The LPS of Bordetella species were extracted from dried bacterial mass by the modified hot phenol/water method [22] and purified by ultracentrifugation [23]. The SDS-PAGE analysis of the LPS preparation of different Bordetella species showed the smooth-type LPS of B. holmesii ATCC 51541 and B. parapertussis 529. The rough-type LOS were detected for B. pertussis strains 186 and 606 as well as for B. bronchiseptica strains 530 and 1943 ( Figure 1A). The electrophoretic separation of complete lipooligosaccharide (LOS) of B. pertussis yields two bands described as the "A-band" (slow-migrating) and the "B-band" (fast-migrating). The A-band is a complete LOS structure consisting of lipid A, core oligosaccharide, and the distal trisaccharide [α-D-GlcpNAc-(1→4)-β-D-Manp2NAc3NAcA-(1→3)-β-L-Fucp2NAc4NMe-(1→]. B-band is an incomplete LOS that lacks the terminal trisaccharide. The intact oligosaccharide molecule is a dodecasaccharide, and OS that lacks distal trisaccharide is a nonasaccharide. In the SDS-PAGE of B. pertussis 186 LOS both bands are observed. In the SDS-PAGE of LOS of B. pertussis 606 only B-band is present, which confirms that B. pertussis 606 is a rough strain, producing LOS that lacks the distal trisaccharide. B. holmesii ATCC 51541 showed a smooth-type LPS in the SDS-PAGE analysis. We observed a band in the region of lipid A linked to the core and a set of bands in the O-antigen region. In the immunoblotting analysis, the fast migrating core-lipid A band of B. holmesii LPS cross-reacted with rabbit sera containing antibodies directed against complete bacterial cells of a mixture of B. pertussis strains 186/576/606/629 ( Figure 1C) as well as with rabbit sera containing polyclonal antibodies directed against B. pertussis 186 OS-PT glycoconjugate ( Figure 1B). Electrophoretic and serological analyses have indicated that the OS structure of B. holmesii core may be similar to the structure of B. pertussis 606 OS.  The heteropolysaccharide components of the LPS were released by mild acid hydrolysis and isolated by gel filtration on HiLoad 16/600 Superdex 30 prep grade column in 0.05 M acetic acid ( Figure 2). All fractions were analyzed by matrix-assisted laser desorption ionization time-of-flight (MALDI-TOF) mass spectrometry and NMR spectroscopy. The fraction with the shortest retention time (Rt 40-48 min) was identified as O-specific polysaccharide (O-PS I, yield 8.3%) with the highest degree of polymerization. The largest fraction with the longest retention time (OS VIII, yield 23.3%) was recognized as the core OS. The core oligosaccharides were compared with the known Bordetella cores. The comparative OS analyses were performed with fraction OS VIII (Rt 110-130 min). Fractions O-PS  II and O-PS III were identified as the shorter O-specific polysaccharide and fractions OS-IV-OS-VII contained complex mixtures of O-PS and OS components.
( Figure 2). All fractions were analyzed by matrix-assisted laser desorption ionization time-of-flight (MALDI-TOF) mass spectrometry and NMR spectroscopy. The fraction with the shortest retention time (Rt 40-48 min) was identified as O-specific polysaccharide (O-PS I, yield 8.3%) with the highest degree of polymerization. The largest fraction with the longest retention time (OS VIII, yield 23.3%) was recognized as the core OS. The core oligosaccharides were compared with the known Bordetella cores. The comparative OS analyses were performed with fraction OS VIII (Rt 110-130 min).

NMR Spectroscopy and Chemical Analysis of the O-PS I
The 1 H NMR spectrum of the isolated O-PSI indicated five anomeric signals, two acetyl resonances, and a methyl group. As the 1 H NMR spectrum was complex, the spin systems were identified and assigned by several two-dimensional experiments, including 1 Figure 3) five sugar residues were identified based on the number of anomeric proton and carbon signals. The sugar residues are denoted with the uppercase letters through the manuscript.

NMR Spectroscopy and Chemical Analysis of the O-PS I
The 1 H NMR spectrum of the isolated O-PSI indicated five anomeric signals, two acetyl resonances, and a methyl group. As the 1 H NMR spectrum was complex, the spin systems were identified and assigned by several two-dimensional experiments, including 1 Figure 3) five sugar residues were identified based on the number of anomeric proton and carbon signals. The sugar residues are denoted with the uppercase letters through the manuscript.     Figure 4). Table 2. Selected inter-residue NOE and 3 J H , C -connectivities from the anomeric atoms of the O-antigen repeating unit of PS B. holmesii ATCC 51541.

Atom H-1/C-1
Connectivities to Inter-Residue  Sugar analysis of the O-PS I confirmed the presence of rhamnose, glucose, galactose, and N-acetylglucosamine. The absolute configuration of the monosaccharide components of PS B. holmesii was confirmed by the method described by York et al. [24]. This method allows us to define the absolute configuration of sugar residues in the PS using only NMR spectroscopy. The O-(S)-2-methyl butyrate (SMB) derivatives of D-and L-monosaccharides are diastereomeric and can be differentiated by comparing their chemical shift and coupling patterns. The polysaccharides were hydrolyzed with 2 M TFA and the resulting monosaccharides were converted into (SMB) Sugar analysis of the O-PS I confirmed the presence of rhamnose, glucose, galactose, and N-acetylglucosamine. The absolute configuration of the monosaccharide components of PS B. holmesii was confirmed by the method described by York et al. [24]. This method allows us to define the absolute configuration of sugar residues in the PS using only NMR spectroscopy. The O-(S)-2-methyl butyrate (SMB) derivatives of d-and l-monosaccharides are diastereomeric and can be differentiated by comparing their chemical shift and coupling patterns. The polysaccharides were hydrolyzed with 2 M TFA and the resulting monosaccharides were converted into (SMB) derivatives, and then their absolute configurations were analyzed by 1 H NMR spectroscopy ( Figure 5). The samples were dissolved in deuterated acetone (acetone-d6) and all the spectra were calibrated to the internal reference of acetone-d5 (δ 2.05 ppm). Comparison of 1

Structural Analysis of the O-PS I by Mass Spectrometry
As the attempts to obtain MALDI-TOF spectra of the intact O-PS I failed, the mass of the repeating unit of B. holmesii strain ATCC 51541 has been deduced from the analysis of the partially

Structural Analysis of the OS Core
An initial SDS-PAGE analysis of the intact LPS of B. holmesii and the observed cross-reactivities of the anti-B. pertussis 186 OS-PT antibodies with the fast migrating bands suggested some structural similarity with the core oligosaccharides of B. pertussis strains 186 and 606 (Figure 1), thus we compared the 1 H NMR profiles of the corresponding oligosaccharides. 1 H NMR spectra of the B. pertussis strains 186 and 606 OS (Figure 8) provide information on the reporter groups in the 1 H NMR spectra of these oligosaccharide structures. As mentioned before, B. pertussis produces two types of LOS. The complete OS molecule is a dodecasaccharide that includes the distal trisaccharide and the incomplete OS molecule is devoid of it. Chemical shift values for B. pertussis 186 have been reported [14,19] and are in line with the data published for the B. pertussis 1414 strain [17]. The B. pertussis 606 strain produces only one type of LOS, comprising lipid A linked to a nonasaccharide (Tables S1 and S2). The nonasaccharide is easily identifiable as it lacks the main reporter groups of the distal trisaccharide of B. pertussis LOS-the signals of the N-methyl resonance and the deoxy-group of β-l-Fucp2NAc4NMe.    (Table 3) and B. pertussis 606 for the first time (Table S1).    (Table 3) and B. pertussis 606 for the first time (Table S1) Figure S1 and Table S1 of the supplementary data.
The J C1, H1 coupling values obtained from the non-decoupled HSQC experiment indicated the α-pyranosyl configuration of residues A (175 Hz), B (178 Hz), C (170 Hz), D (171 Hz), E (173 Hz) and H/I (170 Hz) and the β-pyranosyl configuration for residue J (161 Hz). The sequence of sugar residues was confirmed using inter-residue cross-peaks between the transglycosidic protons observed by 1  The results from all NMR experiments indicated that the structure of the core isolated in the main OS VIII fraction of B. holmesii ATCC 51541 was identical to the OS of B. pertussis 606 (Figure 10).

Discussion
We present here the structures of an O-specific polysaccharide, including the structure of the biological repeating unit and a core oligosaccharide of Bordetella holmesii ATCC 51541 lipopolysaccharide in relation to the classical Bordetellae. Current understanding of the whooping-cough etiology has changed, since it is not restricted to infections exclusively caused by B. pertussis, but embraces also pertussis-like illnesses caused by B. holmesii and B. parapertussis. B. pertussis is still a primary causative agent of whooping-cough, with B. holmesii, emerging as the second, and followed by B. parapertussis [10,12,13,28]. The relation between B. pertussis and B. holmesii infections remains unknown, but cases of the co-infection have been reported recently. More importantly, there is no effective vaccine against B. holmesii, and the existing pertussis DTwP and DTaP vaccines do not provide cross-protection in animal models of B. holmesii infection [15,29]. Thus, it is vital to distinguish B. pertussis and B. holmesii infections efficiently as failing to do so may substantially underestimate the efficiency of anti-pertussis vaccination. B. holmesii does not produce the main protein antigens typical for B. pertussis and implicated in the pathogenesis of whooping-cough [8,15]. At the moment further studies are required to identify and isolate virulence factors of B. holmesii that could become possible antigenic components of new pertussis vaccine compositions and could protect against both B. pertussis and B. holmesii.
One of the common virulence factors and the essential constituent of the bacterial membrane of all Bordetellae is lipopolysaccharide [16]. The lipopolysaccharides (LPS) of Bordetellae differ structurally between species and strains. Lipid A and core oligosaccharide moieties constitute the most conservative part of LPS across the genus. The basic structure of O-specific polysaccharides of the B. bronchiseptica and B. parapertussis were defined as homopolymers of the 1,4-linked 2,3-diacetamido-2,3-dideoxy-α-galacturonic acid, additionally modified at the non-reducing end terminal sugar by non-carbohydrate residues (e.g., formylation, substitution with aminoacids) [14]. These variable modifications define the antigenic properties of the O-antigens at the strain level. Interestingly, B. pertussis does not express O-antigen. Instead, it can be replaced with a single

Discussion
We present here the structures of an O-specific polysaccharide, including the structure of the biological repeating unit and a core oligosaccharide of Bordetella holmesii ATCC 51541 lipopolysaccharide in relation to the classical Bordetellae. Current understanding of the whooping-cough etiology has changed, since it is not restricted to infections exclusively caused by B. pertussis, but embraces also pertussis-like illnesses caused by B. holmesii and B. parapertussis. B. pertussis is still a primary causative agent of whooping-cough, with B. holmesii, emerging as the second, and followed by B. parapertussis [10,12,13,28]. The relation between B. pertussis and B. holmesii infections remains unknown, but cases of the co-infection have been reported recently. More importantly, there is no effective vaccine against B. holmesii, and the existing pertussis DTwP and DTaP vaccines do not provide cross-protection in animal models of B. holmesii infection [15,29]. Thus, it is vital to distinguish B. pertussis and B. holmesii infections efficiently as failing to do so may substantially underestimate the efficiency of anti-pertussis vaccination. B. holmesii does not produce the main protein antigens typical for B. pertussis and implicated in the pathogenesis of whooping-cough [8,15]. At the moment further studies are required to identify and isolate virulence factors of B. holmesii that could become possible antigenic components of new pertussis vaccine compositions and could protect against both B. pertussis and B. holmesii.
One of the common virulence factors and the essential constituent of the bacterial membrane of all Bordetellae is lipopolysaccharide [16]. The lipopolysaccharides (LPS) of Bordetellae differ structurally between species and strains. Lipid A and core oligosaccharide moieties constitute the most conservative part of LPS across the genus. The basic structure of O-specific polysaccharides of the B. bronchiseptica and B. parapertussis were defined as homopolymers of the 1,4-linked 2,3-diacetamido-2,3-dideoxy-α-galacturonic acid, additionally modified at the non-reducing end terminal sugar by non-carbohydrate residues (e.g., formylation, substitution with aminoacids) [14].  [18]. The results obtained from the comparative analysis of the NMR spectra of B. holmesii core oligosaccharide fraction with this of the B. pertussis strain 606 indicated clearly that the investigated core oligosaccharides were identical. Thus the core OS of B. holmesii conforms to the core nonasaccharide-type that prevails among Bordetellae LPS. The NMR analysis of O-PSI was further supported by mass spectrometry on the partially depolymerized preparations and indicated a unique structure of the pentasaccharide O-repeats, containing one deoxy sugar (Rhap), one galactose (Galp), one glucose (Glcp), and two N-acetylglucosamine (GlcpNAc) residues. Although the isolation of a fraction comprising a single O-repeat linked to the core OS failed, the presence of an un-substituted variant of residue C at the non-reducing end of the O-PS allowed to define the biological repeating unit. The herein reported O-polysaccharide and core oligosaccharide are the first ones described for the B. holmesii type strain ATCC 51541.

Bacteria
Bordetella holmesii strain ATCC 51541 (DSM 13416) was obtained from DSMZ collection (Leibniz-Institut, Berlin, Germany). B. pertussis strains 186 and 606, used in the current wP vaccine manufactured in Poland, were acquired from the National Medicines Institute (Warsaw, Poland) [30]. Bordetella parapertussis PCM 529 (ATCC 15311), Bordetella bronchiseptica PCM 530 (ATCC 19395), and Bordetella bronchiseptica PCM 1943 (ATCC 4617) came from the PCM collection (Hirszfeld Institute of Immunology and Experimental Therapy, Polish Academy of Sciences, Wrocław, Poland). The strains were stored as bacterial suspensions in PBS containing 20% glycerol, at −70 • C. Bacteria were grown on charcoal agar medium supplemented with 10% defibrinated sheep blood (GRASO Biotech, Owidz, Poland) and then transferred to the liquid medium. B. pertussis strains were cultured using Stainer-Scholte medium at 37 • C for 72 h and B. holmesii was cultured in the modified Stainer-Scholte medium with the addition of riboflavin. Bacteria were killed with 1% phenol, harvested by centrifugation (4000× g, 30 min, 4 • C) (Sorvall Lynx 6000), suspended in water and freeze-dried.

Lipopolysaccharides and O-Specific Polysaccharide Fractions
LPS was extracted from lyophilized bacterial cells by the modified hot phenol/water extraction method [22] and purified by ultracentrifugation [23]. The modified extraction included an extra step prior to the addition of phenol. Briefly, killed and lyophilized bacteria were suspended in 0.05 M phosphate buffer at pH 7.4 and lysozyme (EC 3.2.1.17, specific activity ≥ 40,000 U/mg) was added in portions (10 mg per one g of dry bacterial mass) and the suspension was incubated for 18 h at 25 • C with stirring [31]. LPS (45 mg) was hydrolyzed with 1.5% acetic acid at 100 • C for 15 min and subsequently, 12 mg of water-soluble heteropolysaccharide was isolated. The supernatant was fractionated using the semi-preparative HPLC UltiMate 3000 chromatographic system ( 1 mg), the core substituted with phosphates (OS V-OS VII, <0.1 mg) and main OS fraction containing unsubstituted core oligosaccharides (OS VIII, 2.8 mg). Eluates were monitored with a Shodex RI-102 detector (Showa-Denko, Tokyo, Japan). All fractions were checked by NMR spectroscopy and matrix-assisted laser desorption/ionization time-of-flight (MALDI-TOF) mass spectrometry (MS).

Analytical Procedures
Monosaccharides were analyzed as their alditol acetates by GC-MS using a Thermo ITQ™ 1100 GC-Ion Trap mass spectrometer coupled with a Trace™ 1310 gas chromatograph (Thermo Scientific™) equipped with HP-5M S column (30 m, ID = 0.25 mm, dF = 0.25 µm) (Agilent Technologies, Lexington, MA, USA) and a temperature gradient 150-270 • C at 8 • C·min −1 . The absolute configurations of the sugars were determined using 1 H NMR spectroscopy by converting the polysaccharide hydrolysate components and relevant monosaccharide standards into O-(S)-2-methyl butyrate derivatives as described by York et al. [24]. For NMR analyzes, the samples were dissolved in acetone-d6 (~160 µL) and transferred to 3 mm diameter NMR tubes.

Partial HF Hydrolysis
The polysaccharide O-PS I fraction (0.2 mg, 200 µL) was hydrolyzed with 48% hydrofluoric acid at −20 • C. The O-PS I was dissolved in HF solution portioned and stored at −20 • C. Everyday a sample (10 µL) was taken and the progress of hydrolysis was checked by MALDI-TOF MS. The hydrolysis was ended after 30 days when no polymerized material was detected.

SDS-PAGE and Serological Analysis
The LPS was analyzed by SDS-PAGE according to the method of Laemmli [32]. The LPS bands were visualized by the silver staining method [33] and by immunoblotting using polyclonal rabbit antisera specific for the whole cell of B. pertussis (The serum was obtained by immunization with a mixture of B. pertussis strains 186/576/606/629) and for the core oligosaccharide of B. pertussis 186 (OS-PT) and the LOS-derived pentasaccharide (penta-PT) in separate experiments. OS-PT and penta-PT conjugates and the corresponding sera were described in the US (US 9878051 B2) patent [34]. All polyclonal rabbit sera were from our Laboratory collection. Immunoblotting was done as previously described [23]. The detection systems consisted of a goat anti-rabbit IgG conjugated with alkaline phosphatase (Bio-Rad, Hercules, CA, USA) as a second antibody and 5-bromo-4-chloro-3-indolyl phosphate-nitroblue tetrazolium.

Mass Spectrometry
MALDI-TOF MS spectra of polysaccharides, oligosaccharides, and lipid A were acquired using UltrafleXtreme (Bruker Daltonik GmbH, Bremen, Germany) with a time-of-flight detector. Spectra were recorded in positive and negative modes. 2,5-Dihydroxybenzoic acid was used as a matrix.

NMR Spectroscopy
NMR spectra of the isolated polysaccharide and oligosaccharides were recorded for 2 H 2 O solutions at 25 • C on Bruker Avance III 600 MHz spectrometer (Bruker Biospin GmbH, Rheinstetten, Germany) using 5 mm QCI cryprobe. 3 mm tubes (~160 µL) were used for the measurements. Polysaccharide and oligosaccharide fractions were repeatedly exchanged with 2 H 2 O with intermediate lyophilization.
Acetone (δ H /δ C 2.225/31.05 ppm) was used as an internal reference. The data were acquired and processed using TopSpin software (Bruker BioSpin GmbH, Rheinstetten, Germany). The processed spectra were assigned with the help of the NMRFAM-SPARKY program [35]. The signals were assigned by one-and two-dimensional experiments (COSY, TOCSY, NOESY, HMBC, HSQC-DEPT, and HSQC-TOCSY). In the TOCSY experiments, the mixing times used were 30, 60, and 100 ms. The coupling patterns within the identified spin-systems in the 2D TOCSY experiments facilitated the identification of individual monosaccharide residues. The delay time in the HMBC experiment was 60 ms and the mixing time in the NOESY experiment was 100 ms.

Conclusions
The relation between B. pertussis and B. holmesii infections remains unknown. To date there is no effective vaccine against B. holmesii, and the existing pertussis DTwP and DTaP vaccines do not provide cross-protection in animal models of B. holmesii infection [15,29]. Lipopolysaccharide is one of the common virulence factors and the essential constituent of the bacterial membrane of all Bordetellae [16]. In the current research we have elucidated the structures of the O-specific polysaccharide and the core oligosaccharide of B. holmesii ATCC 51541: (1) The B. holmesii O-specific polysaccharide has been identified as the novel pentasaccharide biological repeating unit ( Figure 7). (2) The comparative analysis of the NMR spectra of B. holmesii core oligosaccharide fraction with this of the B. pertussis strain 606 indicated their structural identity. These observations were in agreement with SDS-PAGE analysis and the detected cross-reactions of the B. holmesii ATCC 51541 LPS with the polyclonal antibodies directed against the LOS-derived antigens of B. pertussis. Therefore, the core nonasaccharide-type, prevailing among Bordetellae LPS could facilitate a design of a cross-protective neoglycoconjugate as a potential vaccine component.

Conflicts of Interest:
The authors declare no conflict of interest.