New Structure of Aeromonas salmonicida O-Polysaccharide Isolated from Ill Farmed Fish
by
, , and
Karolina Ucieklak
1,†
,
Sylwia Wojtys-Tekiel
1,†,
Garance Leroy
2,
Laëtitia Le Devendec
3,
Sandrine Baron
3 and
Marta Kaszowska
1,* 1
Laboratory of Microbial Immunochemistry and Vaccines, Ludwik Hirszfeld Institute of Immunology and Experimental Therapy, Polish Academy of Sciences, 53-114 Wroclaw, Poland
2
Laboratory of Marine Biotechnology and Chemistry, University of Western Brittany, EMR CNRS 6076, IUEM, 29000 Quimper, France
3
Mycoplasmology-Bacteriology and Antimicrobial Resistance Unit Ploufragan Plouzane-Niort Laboratory (ANSES), 22440 Ploufragan, France
*
Author to whom correspondence should be addressed.
†
These authors contributed equally to this work.
Microorganisms 2024, 12(8), 1575; https://doi.org/10.3390/microorganisms12081575
Submission received: 12 June 2024
/
Revised: 8 July 2024
/
Accepted: 26 July 2024
/
Published: 1 August 2024
(This article belongs to the Section Molecular Microbiology and Immunology)
Abstract
The diversity of O-polysaccharides (O-antigens) among 28 Aeromonas salmonicida strains isolated from ill fish has been determined by using high-resolution magic angle spinning (HR MAS) NMR spectroscopy. The new O-polysaccharide has been identified in two isolates. This new structure was investigated by 1H and 13C NMR spectroscopy and matrix-assisted laser-desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS). The following structure of the linear hexasaccharide repeating unit of A. salmonicida O-antigen has been established: →3)-α-L-Rhap-(1→3)-α-D-ManpNAc-(1→2)-β-D-Glcp-(1→3)-α-L-Rhap2OAc4OAc-(1→3)-β-D-ManpNAc-(1→3)-α-D-Glcp-(1→. This new A. salmonicida O-polysaccharide was detected among two isolates collected from trout and turbot fish in 2010 and 2011, respectively. Further investigations should be conducted to evaluate the distribution of this new O-polysaccharide among a larger collection of isolates, depending on their geographic origin, the species of fish, and the health status of the fish.
1. Introduction
Aeromonas salmonicida is an important fish pathogen, causing the systemic disease furunculosis in a great variety of fish (e.g., salmon, trout, and turbot). Since the annual worldwide losses of farmed fish due to diseases involve millions of dollars, this pathogen has been subjected to considerable investigation [1]. One of the principal virulence factors of this pathogen is an S-layer (named the A-layer) that consists principally of a 2-dimensional crystalline tetragonal protein (A-protein, with a molecular mass of 49 kDa) array, which is tethered to the cell by lipopolysaccharide (LPS) molecules. Labeling studies have shown that the A-layer appears to cover most of the surface of virulent A. salmonicida, although some parts of LPS (O-polysaccharide) may also be exposed. This structure has been shown to protect this bacterium from killing by serum in a manner that somehow requires both LPS and the A-layer [2].
LPS is an amphiphilic molecule which is a well-characterized pathogen-associated molecular pattern (PAMP). It is a powerful activator of innate immune responses. The characteristics of endotoxin are important, since the physiological and pathophysiological effects depend strongly on their chemical structure. It consists of three domains: lipid A, core oligosaccharide, and O-specific polysaccharide (O-antigen, O-serotype). By now, only one structure of A. salmonicida lipid A, one core oligosaccharide, and three O-polysaccharides have been identified and published [3,4,5,6,7,8].
Antibiotherapy is still used against furonculosis and has led to resistance [9]. Several studies have reported the detection of resistant A. salmonicida strains in trout fish farms in Denmark [10], France [11], Turkey [12], and Canada [13]. Colistin is a positively charged peptide that exhibits activity against Gram-negative bacteria by interacting with its lipopolysaccharide (LPS) molecules. These interactions involve the electrostatic attraction between the positively charged diaminobutyric acid (Dab) residue of colistin and the negatively charged phosphate groups present in the lipid A part of the bacterial membrane. As a result of this interaction, the LPS becomes destabilized, leading to an increase in the permeability of the bacterial membrane inducing cell lysis and death. This mode of action is common to all polymyxins, including polymyxin B [14].
Herein, a structural study of O-polysaccharide diversity among a collection of 28 A. salmonicida strains collected from diseased farmed fish, including trout and turbot, in France has been established.
2. Materials and Methods
2.1. Bacterial Strains
2.1.1. Origin and Identification
The bacterial collection is composed of 28 strains of A. salmonicida isolated from diseased fish between 1994 and 2014. The isolates were collected from rainbow trout (n = 9) and turbot (n = 19) bred in 13 fish farms. All isolates were provided by French laboratories located in western France, the Mycoplasmology-Bacteriology and Antimicrobial resistance unit (MBA) and Virology, Immunology and Ecotoxicology of Fish unit (VIMEP) of the Ploufragan-Plouzané-Niort Laboratory of the French Agency for Food, Environmental and Occupational Health & Safety (Anses, Ploufragan, France), and Labocéa (site of Quimper). Strains had been preserved by freezing at −70 °C. All strains were purified on tryptic soy agar and identified at genus level by MALDI-TOF Biotyper platform (Bruker, Bremen, Germany) in Labocéa laboratory. In MBA unit, the identification at species level was confirmed by sequencing the housekeeping gene gyrB [15,16], and the determination of the subspecies A. salmonicida subsp salmonicida, using PCR, targeted the phage PSal 3, which is specific to the subspecies salmonicida [15].
2.1.2. Genetic Diversity
Strain genotyping was performed using the enterobacterial repetitive intergenic consensus PCR (ERIC-PCR) typing method. The amplification conditions were as follows: initial denaturation at 95 °C for 5 min, followed by 35 amplification cycles that successively comprised denaturation at 92 °C for 45 s, annealing at 52 °C for 1 min, and extension at 65 °C for 4 min, before a final extension step at 70 °C for 20 min [17].
2.1.3. Antimicrobial Susceptibility Testing
The minimal inhibitory concentration (MIC) was determined using the broth microdilution method. Five antibiotics are included in the custom-made microdilution plate “FRANV” (Thermofischer, Dardilly, France): colistin (COL) (0.5–32.0 µg/L), florfenicol (FLO) (0.12–16.0 µg/L), oxolinic acid (OXO) (0.004–8.0 µg/L), oxytetracycline (OXY) (0.03–16.0 µg/L), and trimethoprim-sulfamethoxazole (SXT) (0.015/0.3–8.0/152.0 µg/L). Excluding colistin, the four other antibiotics are labelled for aquaculture in France. The colistin was tested because it belongs to the polymyxin class, which is known to interact with LPS molecules. Results were recorded after a 48 h incubation at 22 °C using the testing protocols recommended for non-fastidious microorganisms in the guidelines proposed by the Clinical Laboratory Standard Institute guideline (CLSI. Methods for antimicrobial broth dilution and disk diffusion susceptibility testing of bacteria isolated from aquatic animals, 2nd ed. CLSI Guideline Vet 03. Wayne, PA: Clinical and Laboratory Standards Institute, 2020).
Interpretation criteria are epidemiological cut-off values (Ecoff). The Ecoff values allow categorizing an isolate as wild-type (WT) or non-wild-type (NWT). A microorganism is defined as WT for a species by the absence of acquired and mutational resistance mechanisms to the drug in question. A microorganism is categorized as WT for a species by applying the appropriate cut-off value in a defined phenotypic test system [18].
The Ecoff proposed by CLSL VET 04 (CLSI. Performance Standards for Antimicrobial Susceptibility Testing of Bacteria Isolated From Aquatic Animals 3rd ed. CLSI Supplement VET 04 Wayne, PA: Clinical and Laboratory Standards Institute, 2020) was used for oxolinic acid (WT ≤ 0.12, NWT ≥ 0.25), oxytetracycline (WT ≤ 1.0, NWT ≥ 2.0), florfenicol (WT ≤ 4.0, NWT ≥ 8.0). For colistin (WT ≤ 4.0, NWT ≥ 8.0) and trimethoprim-sulfamethoxazole (WT ≤ 0.25/4.75, NWT ≥ 0.5/9.5), Ecoff was not available in CLSI, so the one previously proposed by Baron et al., 2017 [19] was used (Table 1).
2.2. Isolation of the Lipopolysaccharide and O-Polysaccharide
Bacteria were cultivated aerobically with aeration at 22 °C for 24 h, in peptone water, then harvested and freeze-dried. The LPS was extracted from bacterial cells by the hot phenol/water method [20], purified from nucleic acids by ultracentrifugation (105,000× g, 4 °C, 3 × 6 h) with a yield of 1.4%. A. salmonicida 11/A/658 LPS (200 mg) was degraded by 1.0% acetic acid at 100 °C for 100 min. The supernatant was fractionated using the semi-preparative HPLC UltiMate 3000 chromatographic system (Dionex Corporation, Sunnyvale, CA, USA) on a HiLoad 16/600 Superdex 30 prep grade column (30 mm × 124 cm, grain size 34 μm, GE Healthcare, Chicago, IL, USA) equilibrated with 0.05 M acetic acid. Eluates were monitored with a Shodex RI-102 detector (Showa-Denko, Tokio, Japan). All fractions were checked by MALDI-TOF MS. The polysaccharide fraction was subjected to further structural analysis by NMR spectroscopy.
Instrumental Methods
NMR Spectroscopy. NMR spectra were recorded using a Bruker Avance III 600 MHz spectrometer (Bruker Biospin GmbH, Rheinstetten, Germany) using a 5 mm QCI 1H/13C/15N/31P probe equipped with a z-gradient. The measurements were performed at 298 K. The O-specific polysaccharide was dissolved in 2H2O and the acetone (δH/δC 2.225/31.05 ppm) was used as an internal reference. The data were acquired and processed using Bruker Topspin software (version 3.1) and with the help of the NMRFAM-SPARKY program [21]. The signals were assigned by one-dimensional (1H, 13C, 31P) and two-dimensional (2D) experiments: correlation spectroscopy (COSY), total correlation spectroscopy (TOCSY, with mixing times: 30, 60, and 100 ms), nuclear Overhauser effect spectroscopy (NOESY, with mixing time of 100 ms), 1H-detected heteronuclear single quantum coherence spectroscopy (HSQC) with and without carbon decoupling, HSQC-TOCSY, and 1H-13C heteronuclear multiple-bond correlation spectroscopy (HMBC, with mixing time of 60 ms) [22,23].
HR MAS NMR Spectroscopy. The HR MAS NMR was used to create a database of A. salmonicida O-serotypes (O-polysaccharides). NMR spectra were obtained using a 1H, 13C high-resolution magic angle spinning (HR MAS) probe with z-gradients at the magic angle. LPS (3–4 mg) were suspended in 2H2O and placed into the ZrO2 rotor. HR MAS NMR experiments were carried out at a spin rate of 4 kHz at 30 °C (the measured temperature of the bearing air used for sample spinning) [24].
Mass Spectrometry. O-polysaccharide (1 mg/mL in mQ) fraction was analyzed using a MALDI-TOF Ultraflextreme III instrument (Bruker Daltonic GmbH, Bremen, Germany). The MALDI-TOF MS spectra were obtained in a positive ion mode. For analyses, 2,5-Dihydroxybenzoic acid (10 mg/mL in 1:1 AcN/0.2 M citric acid (v/v)) was used as a matrix.
3. Results
3.1. A. salmonicida O-Polysaccharides Database
Up to this time three different structures of A. salmonicida O-polysaccharides have been identified (chart in Figure 1) [6].
Herein, by using 1H and 1H-13C HR MAS NMR, a database of 28 A. salmonicida O-polysaccharide structures has been created. The trisaccharide structure A was identified in 23 A. salmonicida strains based on the presence of a characteristic signal from a CH3 group (→4)-α-L-Rhap residue), and signals belonging to NAc (of →3-β-D-ManpNAc residue) and OAc groups. The spin systems of these residue/groups with the addition of terminal α-D-Glcp residue have been proven. The disaccharide structure B has been determined in three strains by the presence of signals of →3-β-D-ManpNAc and→4)-α-L-Rhap residue only. No strain with a known C structure has been isolated. Additionally, in two A. salmonicida strains 11/A/658 (Figure 1) and 10/A/646, a new O-polysaccharide structure has been identified based on characteristic signals belonging to two Rhap residues (CH3), and two NAc and two OAc groups (Table 2). The strain 11/A/658 has been selected for further structural analysis.
3.1.1. Isolation of the O-Polysaccharide
LPS of A. salmonicida 11/A/658 was isolated from bacterial mass. The mild acid hydrolysis of the LPS yielded five polysaccharide (PS) and oligosaccharide (OS) fractions: PSI-III consisting of a core oligosaccharide substituted by several repeating units, and OSIV-V—the unsubstituted core oligosaccharide fractions. The high yield of PSI-III suggested the smooth (S-LPS) type of A. salmonicida 11/A/658 LPS. The data presented herein concern the PSI fraction.
3.1.2. Structural Analysis
The initial 1H NMR investigation of the A. salmonicida 11/A/658 O-polysaccharide indicated the presence of two N-acetyl (NAc), two O-acetyl (OAc) groups, and two deoxy sugar residues (the presence of CH3 groups). The 1H NMR spectrum of the A. salmonicida 11/A/658 contained the six signals of anomeric protons. The 1H-1H COSY and 1H-1H TOCSY (using different mixing times) allowed for the assignment of the H-1 to H-6,6′ signals for each residue, whereas the 1H-13C HSQC-DEPT spectrum also contained signals for carbons (Table 2, Figure 2).
Residue A, with H-1/C-1 signals at δH/δC 5.14/96.2 ppm (1JC-1,H-1 = 173 Hz), was recognized as the 3-substituted α-D-ManpNAc residue based on the chemical shift of the C-2 (δC 53.6 ppm) and C-3 (δC 74.1 ppm). The chemical shift was inferred by comparison with published data [24]. Residue B, with H-1/C-1 signals at δH/δC 4.90/98.9 ppm (1JC-1,H-1 = 173 Hz), was recognized as 3-substituted α-L-Rhap2OAc4OAc on the basis of the signals of exocyclic CH3 groups (δH/δC 1.02/14.9 ppm) and the small vicinal coupling constants between H-1 and H-2. Relative downfield chemical shifts of the C-3 at δC 74.0 ppm indicated a substitution position. Characteristic chemical shift values of H-2/C-2 (δH/δC 5.00/68.9 ppm) and H-4/C-4 (δH/δC 5.00/69.9 ppm) indicated substitution by two OAc groups (δH/δC 2.08/20.6, δC 173.2 ppm and δH/δC 2.11/20.2, δC 173.3 ppm, respectively). Residue C, with H-1/C-1 signals at δH/δC 4.83/99.7 ppm (1JC-1,H-1 = 176 Hz), was recognized as 3-substituted α-d-Glcp based on the characteristic five-proton spin systems. Significant downfield shift was observed for C-3 of this residue (δC 74.3 ppm) as compared with the chemical shift of the corresponding non-substituted monosaccharide, indicating the linkage position for this residue. Residue D, with H-1/C-1 signals at δH/δC 4.70/103.6 ppm (1JC-1,H-1 = 162 Hz), was recognized as 2-substituted β-d-Glcp based on the characteristic chemical shift of the C-2 (δC 76.4 ppm), the similarity of the 1H and 13C chemical shifts with those of β-d-Glcp, and the large vicinal couplings between all protons in the sugar ring. Residue E, with H-1/C-1 signals at δH/δC 4.61/102.1 ppm (1JC-1,H-1 = 163 Hz), was recognized as 3-substituted β-d-ManpNAc based on the characteristic five-proton spin systems, chemical shift value of the C-2 (δC 55.6 ppm), and high 13C chemical shift of the C-3 (δC 82.0 ppm). Residue F, with H-1/C-1 signals at δH/δC 4.43/102.3 ppm (1JC-1,H-1 = 162 Hz), was recognized as terminal β-L-Rhap based on the characteristic spin system and the signals of the CH3 group (δH/δC 1.20/16.5 ppm). Additionally, also the signals for 3-substituted β-L-Rhap (described as F’ residue) have been identified based on the characteristic chemical shift of the C-3 (δC 79.5 ppm) and for the CH3 group (δH/δC 1.17/16.4 ppm). The presence of terminal and 3-substituted residue points for fraction heterogeneity related to the presence mixture of different lengths of linear A. salmonicida O-polysaccharides.
The monosaccharide sequence was established using 1H-1H NOESY experiment. The 1H-1H NOESY spectrum showed strong inter-residue cross-peaks between the following transglycosidic protons: H-1 of B/H-3 of E, H-1 of D/H-3 of B, H-1 of E/H-3 of C, H-1 of F/F’/H-3 of A, H-1 of C/H-3 of F’, and H-1 of A/H-2 of D (Figure 3). The results suggest the following structure of the repeating unit of the A. salmonicida 11/A/658 O-polysaccharide.
The structure of the repeating unit of A. salmonicida O-polysaccharide 11/A/658 was analyzed by MALDI-TOF MS (Figure 4). The six sugar residues, two ManpNAc, two Glcp, and two Rhap residues, give together a monoisotopic mass of 1106.401 Da (MRU). The ions at m/z 1129.42 Da [MRU + H-H2O + Na]+, at m/z 2235.84 [M2RU + H-H2O + Na]+, at m/z 3342.26 [M3RU + H-H2O + Na]+, and at m/z 4448.63 [M4RU + H-H2O + Na]+ represent the masses of one, two, three, and four complete repeating units, respectively.
3.1.3. Origin, Genetic Diversity, and Antimicrobial Susceptibility of Bacterial Strains and A. salmonicida O-Polysaccharide Structures
The 28 isolates included in this study were collected from turbot (n = 18) and from trout (n = 10), bred in five and nine farms, respectively. Twenty-six out of the twenty-eight A. salmonicida isolates had O-polysaccharide structures, which have been previously described (Figure 2), structure A (n = 18) or structure B (n = 8). The two isolates, which have the new O-polysaccharide structure (new A. salmonicida O-serotype), were collected in 2010 from a trout and in 2011 from a turbot (Table 1).
The three O-polysaccharide structures were found in both species of fish. Out of the 18 isolates with structure A, 7 were collected from trout and 11 were collected from turbot. Structure A was the dominant in both species of fish. No link between LPS structure and the origin of the strain (fish species) was observed.
Among the thirteen isolates collected in turbot farm 7, three LPS structures, eight A-type structures, four B-type structures, and one new structure were observed.
The genetic diversity of these 28 A. salmonicida strains was investigated by ERIC-PCR. The strains are distributed into fifteen genetic profiles (called ERIC-profiles). The eighteen strains with structure A are distributed among eleven ERIC-profiles and the eight strains with structure B into seven ERIC-profiles. Six ERIC-profiles are composed of 2 or more strains. Five of them are composed of strains with structure A and structure B. No link between the ERIC-profiles and the LPS (O-polysaccharide structures) was observed, meaning that these three structures could be detected in a large diversity of A. salmonicida strains.
The antimicrobial susceptibility was tested using a microbroth dilution for five antibiotics, colistin and the four others labelled for use in aquaculture.
No strain was wild-type for the four antibiotics labeled for use in aquaculture in France (oxolinic acid (OXO), oxytetracylcine (OXY), florfenicol (FLO), and trimethoprim-sulfamethoxazole (SXT)). In contrast, two strains were non-wild-type for the four antibiotics. They both have an O-polysaccharide A structure. Thirteen strains (eight structure A, four structure B, and one new structure) were non-wild-type for three agents, “oxy-oxo-sxt”. Multidrug resistant isolates are defined as isolates that are not susceptible to at least one agent in at least three antimicrobial classes [25,26]. By extension of this definition, fifteen strains of this study (53.6%) are multi-drug “non wild type”. Strains with structure A and strains with structure B are both present in all different antimicrobial profiles, except the non-wild-type profile for the four antibiotics.
One of the strains with the new structure is a non-wild-type only for oxolonic acid and a second one is a multi-drug non-wild-type. Based on the Ecoff proposed by Baron et al. [19], all the isolates were wild-type to colistin independently of the O-polysaccharide structures.
4. Discussion
A. salmonicida is an important pathogen for fish, especially salmonidae, which is the causative agent of furonculosis. Antibiotic treatment is not always efficient due to the acquisition of resistance by the strain. Moreover, a reduction in the usage of antibiotics is encouraged by most international organizations. One of the alternatives is phagotherapy. The lipid A of the LPS and A-layer have been identified as a receptor for Aeromonas subsp salmonicida myophages [27,28]. The determination of an LPS with new O-polysaccharide structures (new O-serotypes) could impact the efficiency of phagotherapy.
Moreover, the A-layer is known as one of the A. salmonicida major virulence factors [29]; the O-polysaccharide (as a part of LPS) may modulate this virulence by direct presence between tetragonal A-protein arrays.
In this study, a new A. salmonicida O-polysaccharide has been identified in two clinical isolates collected from trout and turbot. Despite the different O-polysaccharide structures being currently dominant among the tested isolates (structure A in Figure 2), this may change in the future.
The HR MAS NMR is dedicated for fast LPS profile determination. The creation of a useful A. salmonicida O-polysaccharide database will be useful in the future for the rapid identification of different O-serotypes in new isolates (available for European veterinarian laboratories). Collaboration with many different fish farms (European veterinarian laboratories) gives the possibility of structural identification, which is also important for the control of diversity among A. salmonicida isolates.
The investigation of the O-polysaccharide structures presented on A. salmonicida isolates could bring information about or could be linked with other traits of Aeromonas, including geographical diversity (by using strains isolated from many different European fish farms). Such data could be used to improve the identification at species level, and the understanding of A. salmonicida pathogenicity. The results related to the O-polysaccharide structure presented in isolates can be used as one of the necessary steps to propose alternative methods of control of A. salmonicida infections and can be used to develop a rapid, accurate detection system in fish farming. Moreover, Hofer et al. recently explored the ability of non-A-layer and A-layer A. salmonicida strains to incorporate polyunsaturated fatty acids (PUFAs) into their lipid profiles and tested the phenotypic effects thereof. Temperature-dependent effects on biofilm formation were observed [30]. This study compared strains with and without the A-layer, but not between the A-layer strain and different O-polysaccharide structures. Further investigations are needed to understand the impact of the diversity on the O-polysaccharide structure and thus on biofilm formation.
However, studying the structure of LPS in pathogenic bacteria is crucial to assist in the search for effective compounds in combating antibiotic resistance. Indeed, antibiotics under development, such as antimicrobial peptides, interact with the LPS of Gram-negative bacteria. For example, alterins or ogipeptins are cationic antimicrobial peptides which are produced by Pseudoalteromonas strains and exert their antimicrobial action by interacting with the LPS. Enhancing our comprehension of the LPS structure could provide insights into a more accurate mode of action, facilitating the targeting of Gram-negative pathogens [14,31,32,33].
Based on these preliminary observations, the LPS structure seems to not be linked to a particular species. The new structure has been found in trout farms and turbot farms; this could mean that this new structure, as with the structures A and B, is not specific to fish species. Concerning the antimicrobial profile and ERIC-profile, they are not associated with a specific O-polysaccharide structure. All the isolates included in this study were wild-type for colistin and differences were observed even in MIC concentration. Nevertheless, the number of strains with the new O-polysaccharide structure are too few to allowed definitive conclusion. Several questions are pending. (I) What is the proportion of the new structure inside A. salmonicida subs salmonicida, and in other subspecies of A. salmonicida? (II) Does this new structure impact the bacteria–phage interaction? (III) Does the A. salmonicida O-polysaccharide structure confer a protection against macrophage?
5. Conclusions
Identification of A. salmonicida O-polysaccharides (different O-serotypes) presented in ill fish could be very useful for a veterinarian either in confirming the etiologic agent of disease or in improving biosecurity of fish farms, by providing a quick tool to detect the presence of pathogenic A. salmonicida O-polysaccharides before the level of the pathogen reaches density and causes disease. The structural identification of A. salmonicida O-polysaccharides could contribute to reducing and improving the usage of antibiotics in fish farms, which are considered a potential hotspot for antimicrobial resistance dissemination.
Author Contributions
Conceptualization, M.K.; methodology, K.U., S.W.-T., M.K., S.B. and G.L.; formal analysis, K.U., S.W.-T., L.L.D. and G.L.; investigation, M.K. and S.B.; writing—original draft preparation, M.K. and S.B. writing—review and editing, M.K. and S.B.; supervision, M.K.; funding acquisition, M.K. and S.B. All authors have read and agreed to the published version of the manuscript.
Funding
This study was financed through the «ANTIBIOFISH» research project supported by both French ministries in charge of environment and agriculture. This project is part of the national effort to reduce antimicrobial resistance in veterinary medicine called “EcoAntibio2017”. This work was supported by the Polish National Agency for Academic Exchange (NAWA), mobility grant number PPN/BFR/2020/1/00031 and 46907VD-PHC Polonium 2021. This work was supported by the statutory funds of the Laboratory of Microbial Immunochemistry and Vaccines of the Hirszfeld Institute of Immunology & Experimental Therapy, Polish Academy of Sciences.
Data Availability Statement
All data that support the findings of this study are available on request from the corresponding author.
Acknowledgments
Thierry Morin (French Agency for Food, Environmental and Occupational Health and Safety, Ploufragan-Plouzané-Niort Laboratory, Viral Fish Diseases Unit) and Benoit Thuillier (Labocéa, Veterinerian microbobiology, Quimper, France), who provided strains included in this study.
Conflicts of Interest
The authors declare no conflicts of interest.
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Figure 1.
1H HR MAS NMR spectra of A. salmonicida O-polysaccharides: (A) strain 11/A/658 with the new O-polysaccharide structure, (B) strain 9/A/632 with the structure B, and (C) strain 8/A/626 with the structure A. Chart represents A, B, C structures of A. salmonicida O-polysaccharides which have been identified [6]. * impurities from the microextraction step.
Figure 1.
1H HR MAS NMR spectra of A. salmonicida O-polysaccharides: (A) strain 11/A/658 with the new O-polysaccharide structure, (B) strain 9/A/632 with the structure B, and (C) strain 8/A/626 with the structure A. Chart represents A, B, C structures of A. salmonicida O-polysaccharides which have been identified [6]. * impurities from the microextraction step.
Figure 2.
(A–C) Selected regions of 1JH,C- and 3JH,C-connectivities in 1H-13C HSQC-DEPT spectrum of the A. salmonicida 11/A/658 O-polysaccharide. The cross-peaks are marked as uppercase letters indicated in the text.
Figure 2.
(A–C) Selected regions of 1JH,C- and 3JH,C-connectivities in 1H-13C HSQC-DEPT spectrum of the A. salmonicida 11/A/658 O-polysaccharide. The cross-peaks are marked as uppercase letters indicated in the text.
Figure 3.
Selected region of the 1H-1H NOESY spectrum of the A. salmonicida 11/A/658 O-polysaccharide (PSI fraction).
Figure 3.
Selected region of the 1H-1H NOESY spectrum of the A. salmonicida 11/A/658 O-polysaccharide (PSI fraction).
Figure 4.
MALDI-TOF MS spectrum of the A. salmonicida 11/A/658 O-polysaccharide (PSI fraction).
Table 1.
Repartition of the 28 structures of A. salmonicida O-polysaccharides depends on the origin of the strain (date of isolation and fish species) and the antimicrobial profile.
Table 1.
Repartition of the 28 structures of A. salmonicida O-polysaccharides depends on the origin of the strain (date of isolation and fish species) and the antimicrobial profile.
| STRAIN | YEAR | SPECIES | FISH-FARM | ERIC-PCR PROFILE | OXY | OXO | SXT | FLO | COL | AMR PROFILE | O-Polysaccharide Type |
|---|---|---|---|---|---|---|---|---|---|---|---|
| 13/A/730 | 2013 | trout | farm 32 | P9 | WT | NWT | WT | WT | WT | oxo | A |
| 10/A/646 | 2010 | trout | farm 34 | P9 | WT | NWT | WT | WT | WT | oxo | NEW |
| A/94/20 | 1994 | turbot | farm 18 | P4 | WT | NWT | NWT | WT | WT | oxo-sxt | A |
| A/96/205 | 1996 | trout | farm 0 | P25 | NWT | WT | NWT | WT | WT | oxy-sxt | A |
| A/96/21 | 1996 | turbot | farm 7 | P17 | NWT | WT | NWT | WT | WT | oxy-sxt | A |
| 9/A/635 | 2009 | trout | farm 27 | P9 | WT | NWT | NWT | WT | WT | oxo-sxt | A |
| 11/A/652 | 2011 | turbot | farm 11 | P21 | WT | NWT | NWT | WT | WT | oxo-sxt | A |
| 13/A/734 | 2013 | turbot | farm 7 | P17 | WT | NWT | NWT | WT | WT | oxo-sxt | A |
| A/96/22 | 1996 | turbot | farm 7 | P16 | NWT | WT | NWT | WT | WT | oxy-sxt | B |
| 9/A/640 | 2009 | trout | farm 25 | P4 | WT | NWT | NWT | WT | WT | oxo-sxt | B |
| 9/A/629 | 2009 | turbot | farm 7 | P14 | NWT | NWT | NWT | WT | WT | oxy-sxt | B |
| 9/A/632 | 2009 | turbot | Farm 13 | P21 | WT | NWT | NWT | WT | WT | oxo-sxt | B |
| 9/A/638 * | 2009 | turbot | farm 13 | P24 | WT | NWT | NWT | WT | WT | oxo-sxt | B |
| A/94/18 | 1994 | trout | farm 6 | P2 | NWT | NWT | NWT | WT | WT | oxo-oxy-sxt | A |
| A/98/43 | 1998 | trout | farm 8 | P2 | NWT | NWT | NWT | WT | WT | oxo-oxy-sxt | A |
| 7/A/621 | 2007 | turbot | farm 7 | P12 | NWT | NWT | NWT | WT | WT | oxo-oxy-sxt | A |
| 8/A/626 | 2008 | trout | farm 9 | P6 | WT | NWT | WT | WT | WT | oxo | A |
| 10/A/641 | 2010 | turbot | farm 7 | P15 | NWT | NWT | NWT | WT | WT | oxo-oxy-sxt | A |
| 10/A/644 | 2010 | turbot | farm 7 | P16 | NWT | NWT | NWT | WT | WT | oxo-oxy-sxt | A |
| 11/A/666 | 2011 | turbot | farm 7 | P16 | NWT | NWT | NWT | WT | WT | oxo-oxy-sxt | A |
| 11/A/667 | 2011 | turbot | farm 7 | P19 | NWT | NWT | NWT | WT | WT | oxo-oxy-sxt | A |
| 12/A/688 | 2012 | trout | farm 19 | P4 | NWT | NWT | NWT | WT | WT | oxo-oxy-sxt | A |
| 10/A/651 | 2010 | turbot | farm 7 | P16 | NWT | NWT | NWT | WT | WT | oxo-oxy-sxt | B |
| 11/A/656 | 2011 | trout | farm 25 | P5 | NWT | NWT | NWT | WT | WT | oxo-oxy-sxt | B |
| 11/A/657 | 2011 | turbot | farm 7 | P17 | NWT | NWT | NWT | WT | WT | oxo-oxy-sxt | B |
| 11/A/658 | 2011 | turbot | farm 7 | P18 | NWT | NWT | NWT | WT | WT | oxo-oxy-sxt | NEW |
| 10/A/649 | 2010 | turbot | farm 7 | P17 | NWT | NWT | NWT | NWT | WT | oxo-oxy-sxt-flo | A |
| 14/A/756 | 2014 | turbot | farm 12 | P21 | NWT | NWT | NWT | NWT | WT | oxo-oxy-sxt-flo | A |
* One strain did not belong to the subspecies salmonicida; it was collected from turbot in 2009.
Table 2.
1H and 13C NMR chemical shifts of A. salmonicida 11/A/658 O-polysaccharide.
| Chemical Shifts (ppm) | |||||||
|---|---|---|---|---|---|---|---|
| Sugar Residue | H1/C1 | H2/C2 | H3/C3 | H4/C4 | H5/C5 | H6, H6′/C6 | NAc/OAc |
| A →3)-α-D-ManpNAc-(1→ | 5.14 96.2 | 4.16 53.6 | 3.93 74.1 | 3.90 72.9 | 4.08 71.6 | 3.79, 3.81 59.1 | 1.98 175.1 |
| B →3-α-L-Rhap2OAc4OAc-(1→ | 4.90 98.9 | 5.00 68.9 | 4.17 74.0 | 5.00 69.9 | 4.42 65.7 | 1.02 14.9 | 2.08/2.11 173.2/173.3 |
| C →3)-α-D-Glcp-(1→ | 4.83 99.7 | 3.89 70.3 | 3.89 74.3 | 3.39 68.7 | 3.62 75.2 | 3.67, 3.79 60.3 | |
| D →2)-β-D-Glcp-(1→ | 4.70 103.6 | 3.26 76.4 | 3.47 74.3 | 3.39 68.7 | 3.37 75.6 | 3.72, 3.86 60.2 | |
| E →3)-β-D-ManpNAc-(1→ | 4.61 102.1 | 3.78 55.6 | 3.57 82.0 | 3.47 68.3 | 3.33 75.5 | 3.68, 3.75 61.3 | 1.99 175.1 |
| F β-L-Rhap-(1→ | 4.43 102.3 | 3.33 71.3 | 3.55 72.7 | 3.81 68.9 | 4.48 68.0 | 1.20 16.5 | |
| F’ →3)-β-L-Rhap-(1→ | - | 3.34 71.3 | 3.70 79.5 | 3.91 72.8 | 4.50 68.1 | 1.17 16.4 | |
Spectra were obtained for 2H2O solutions at 25 °C, and acetone (δH/δC 2.225/31.05 ppm) was used as an internal reference.
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Ucieklak, K.; Wojtys-Tekiel, S.; Leroy, G.; Le Devendec, L.; Baron, S.; Kaszowska, M. New Structure of Aeromonas salmonicida O-Polysaccharide Isolated from Ill Farmed Fish. Microorganisms 2024, 12, 1575. https://doi.org/10.3390/microorganisms12081575
AMA Style
Ucieklak K, Wojtys-Tekiel S, Leroy G, Le Devendec L, Baron S, Kaszowska M. New Structure of Aeromonas salmonicida O-Polysaccharide Isolated from Ill Farmed Fish. Microorganisms. 2024; 12(8):1575. https://doi.org/10.3390/microorganisms12081575
Chicago/Turabian StyleUcieklak, Karolina, Sylwia Wojtys-Tekiel, Garance Leroy, Laëtitia Le Devendec, Sandrine Baron, and Marta Kaszowska. 2024. "New Structure of Aeromonas salmonicida O-Polysaccharide Isolated from Ill Farmed Fish" Microorganisms 12, no. 8: 1575. https://doi.org/10.3390/microorganisms12081575
APA StyleUcieklak, K., Wojtys-Tekiel, S., Leroy, G., Le Devendec, L., Baron, S., & Kaszowska, M. (2024). New Structure of Aeromonas salmonicida O-Polysaccharide Isolated from Ill Farmed Fish. Microorganisms, 12(8), 1575. https://doi.org/10.3390/microorganisms12081575
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