The antimicrobial role of itaconic acid (ITA) has been recently discovered in mammalian cells. In our previous studies, we discovered that marine molluscs biosynthesise substantial quantities of ITA when exposed to marine pathogens, but its antimicrobial function to Vibrio bacteria is currently unknown. Thus, in this study, we used an untargeted gas chromatography–mass spectrometry (GC-MS) platform to identify metabolic changes of Vibrio sp. DO1 (V. corallyliticus/neptunius-like isolate) caused by ITA exposure. Vibrio sp. DO1 was cultured in Luria-Bertani broth supplemented with 3 mM sodium acetate and with different concentrations of ITA (0, 3 and 6 mM) for 24 h. The results showed that ITA completely inhibited Vibrio sp. growth at 6 mM and partially inhibited the bacterial growth at 3 mM. A principal component analysis (PCA) revealed a clear separation between metabolite profiles of Vibrio sp. DO1 in the 3 mM ITA treatment and the control, which were different in 25 metabolites. Among the altered metabolites, the accumulation of glyoxylic acid and other metabolites in glyoxylate cycle (cis-aconitic acid, isocitric acid and fumaric acid) together with the increase of isocitrate lyase (ICL) activity in the 3 mM ITA treatment compared to the control suggest that ITA inhibited Vibrio sp. growth via disruption of central carbon metabolism.
Itaconic acid (ITA), or 2-methylenesuccinic acid, is an unsaturated dicarboxylic acid that is a well-known precursor for polymer synthesis in the industrial production of polymers. In addition, ITA is known to have antimicrobial function which was first described in Gram-negative bacterium Vogesella indigofera1. The inhibitory effect of ITA was subsequently reported in other bacteria, including Pseudomonas indigofera1,2, Yersinia pestis3, Mycobacterium tuberculosis and Salmonella enterica4.
Recently, ITA was surprisingly discovered in mammalian immune cells. Shin, et al.5 reported the presence of ITA in lung tissue of mice infected with M. tuberculosis, and it was hypothesized that ITA was originated from the bacteria in this association. However, Sugimoto, et al.6 subsequently detected ITA in mouse macrophage-like cell lines stimulated with lipopolysaccharide (LPS), which demonstrated an intracellular source. The biological function of ITA as a novel mammalian metabolite was then highlighted by Strelko, et al.7 who suggested its roles in macrophage-based immune functions after observing increased ITA production and secretion in mouse peritoneal macrophages activated by LPS and IFN-γ. Similarly, the highly increased levels of ITA in human primary macrophages under LPS-induced inflammatory conditions4. Taken together, these findings indicate the role of ITA as mammalian antimicrobial metabolite.
In addition to mammalian macrophages, increased biosynthesis of ITA was recently reported in marine bivalves during pathogen challenges8,9,10. The first detection of ITA in bivalves was reported by Young, et al.10 in Pacific oyster larvae challenged with a marine herpesvirus (OsHV-1 µVar). Accumulation of ITA was then detected in mussel haemolymph following an in vivo experimental challenge with a pathogenic strain of Vibrio sp.8,9,11. Interestingly, ITA increased during initial stages of infection in mussels then decreased in those individuals which survived and recovered from the infection after a week9. These results suggest that ITA could be a potential biomarker for pathogen infections and health status of molluscan hosts9. Taken together, these studies demonstrate that marine bivalves have the capacity to synthesize ITA, with potential immune functions during pathogen infections. However, it is currently unknown whether ITA can inhibit growth of specific pathogenic marine bacteria, as it does in some terrestrial strains.
Vibrio is a genus of Gram-negative bacteria, possessing a number of pathogenic strains that associated with infectious diseases in marine bivalves12. To test the potential inhibitory role of ITA on growth of a virulent Vibrio strain, we cultured Vibrio sp. DO1 in different concentrations of ITA. This Vibrio strain (Vibrio coralliilyticus/neptunius-like isolate, Genbank: EU358784) was isolated from Perna canaliculus larvae13 have been showed to be pathogenic to both P. canaliculus larvae14 and adults8,9,11. GC-MS-based metabolomics was performed to compare metabolite profiles of the Vibrio sp. cultures and evaluate mechanistic effects of ITA on bacterial metabolism.
Effect of ITA on the growth of Vibrio sp. DO1
To test the antimicrobial effect of ITA on bacterial growth, we cultured Vibrio sp. in a Luria-Bertani (LB) broth with different concentrations of ITA (0, 3 and 6 mM). Luria-Bertani broth was chosen since growth in this medium is carbon limited15. Growth of Vibrio sp. was measured via spectroscopy every 6 h for 24 h (Fig. 1a). The results show that the growth of Vibrio sp. was completely inhibited in the 6 mM ITA treatment. Growth in the 3 mM ITA treatment was significantly slower than the growth in the control at all recorded times (p < 0.05). Furthermore, to test whether ITA has the capacity to inhibit isocitrate lyase (ICL) of the glyoxylate shunt, we measured the concentrations of isocitrate and activity of ICL at 24-hour post-incubation (hpi). The results show the significantly higher levels of isocitrate (t10 = −5.878, p < 0.001) and ICL activity (t8 = −12.52, p < 0.001) in the ITA treatment compared to the control (Fig. 1b,c).
Effect of ITA on metabolite profiles of Vibrio sp. DO1
Untargeted GC-MS-based metabolomics was performed to compare metabolite differences between the 3 mM ITA treatment and the control. A total of 565 features were detected by GC-MS in Vibrio sp. samples and 63 metabolites were successfully annotated using an in-house library. The majority of these metabolites were amino acids (43%), followed by organic acids (30%), fatty acids (19%) and others (8%) (Fig. 2a).
Principal component analysis (PCA) was used to identify natural groupings of all bacterial samples based on the underlying structure of the metabolite data. A PCA score plot shows a clear separation between the ITA treatment and the control (Fig. 2b). Partial least-squares discriminant analysis (PLS-DA) was revealed a very robust model for discrimination between sample classes with an accuracy of 1.0, a multiple correlation coefficient (R2) of 0.99 and a cross-validated predictive ability (Q2) of 0.90. T-tests identified 25 metabolites that were significantly altered by ITA treatment, compared to control cultures (Table S1). A heatmap was generated to visualise the relative abundance of these metabolites in each group (Fig. 2c). Overall, clear differences were observed between the treatment and the control, where most of the metabolites in the ITA treatment were elevated with exception of trans-4-hydroxyproline.
Effect of ITA on the glyoxylate shunt
Eight metabolites related to the glyoxylate shunt and TCA cycle were identified in metabolite profiles of Vibrio sp., including citric acid, cis-aconitic acid, isocitric acid, succinic acid, fumaric acid, malic acid, glyoxylic acid, pyruvic acid, 2-oxoglutaric acid and 2-phosphoenolpyruvic acid. The addition of ITA led to alterations of 4 metabolites which were elevated in the ITA treatment, including cis-aconitic acid, fumaric acid, glyoxylic acid and 2-oxoglutaric acid (Fig. 3a).
Classical univariate ROC curve analyses were performed to assess the biomarker specificity and sensitivity of these significantly altered metabolites based on the area under the ROC curve (AUC). The results revealed that all these metabolites had AUC higher than 0.8, and cis-aconitic acid had AUC equal to 1 (Fig. 3b). In addition, ROC curve analyses identified isocitric acid as significantly different between the treatment and the control with t-test p-value < 0.05 and AUC = 0.81. The multivariate ROC curve-based model evaluation, which combined potential biomarkers, showed a very high AUC of 0.972.
Pathway analysis was used to identify potentially altered metabolic pathways induced by ITA. This analysis identified 28 pathways with p < 0.05, which contained at least two identified metabolites (Table 1). Among these, 15 pathways with impacts >0.1 were considered as pathways of interest relating to ITA effects (Table 1), while those with an impact <0.01 may have slight effects. These pathways are involved in carbohydrate metabolism (e.g., TCA cycle, pyruvate metabolism), energy metabolism (e.g., nitrogen metabolism, sulfur metabolism), amino acid metabolism (e.g., valine, leucine and isoleucine biosynthesis; arginine and proline metabolism), lipid metabolism (e.g., biosynthesis of unsaturated fatty acids), oxidative stress (e.g., glutathione metabolism), metabolism of cofactors and vitamins (e.g., pantothenate and CoA biosynthesis), among others.
The glyoxylate cycle is an anabolic variation of the TCA cycle used during carbon limitation in plants, bacteria, protist and fungi16. This mechanism differs from the TCA cycle in which the two decarboxylation reactions (isocitrate → α-ketoglutarate → succinyl-CoA) are bypassed via the glyoxylate shunt pathway (Fig. 4). In this pathway, isocitric acid is converted into glyoxylic acid and succinic acid by isocitrate lyase (ICL). Glyoxylic acid is further combined with acetyl-CoA to form malic acid by malate synthase (MLS)17,18. When initiated during glycolytic sugar (C5-6) starvation, bypassing the CO2-producing steps of the TCA cycle helps the glyoxylate shunt preserve carbon atoms of acetyl-CoA for gluconeogenesis, which is critical for biomass production19. The glyoxylate cycle thus allows microorganisms to utilize carbon compounds other than glucose, such as acetate and fatty acids, as carbon sources for growth under different nutrient conditions3,20. During host infection, pathogenic bacteria are known to up-regulate the glyoxylate cycle3.
The glyoxylate bypass is a potential drug target, which could be inhibited by natural or synthetic compounds, such as ITA21. ITA strongly inhibits the glyoxylate shunt by acting as a potent competitive inhibitor of ICL1,2,22. Inhibition of bacterial growth by ITA exposure has been demonstrated in several bacteria, such as Pseudomonas indigofera1,2, Yersinia pestis3, M. tuberculosis and S.enterica4. For example, Michelucci, et al.4 reported that supplementation of 25–50 nmol L−1 ITA significantly inhibited the growth of M. tuberculosis and S. enterica. In our study, the growth of Vibrio sp. was completely inhibited in culture media supplemented with 6 mM ITA and reduced growth in the 3 mM ITA treatment compared to the control. Furthermore, glyoxylic acid and other intermediates of the glyoxylate cycle (cis-aconitic acid, isocitric acid and fumaric acid) were significantly higher in the ITA treatment compared to the control. However, most surprisingly, the activity of ICL was not inhibited by ITA in our experiment, which indicates that a different toxic mechanism may be responsible for the antimicrobial effect.
In addition, we observed elevated levels of many amino acids (e.g., alanine, glutamic acid, glycine) in ITA-exposed Vibrio sp. Increases in many amino acids have previously been reported in bacteria exposed to environmental stress23,24,25. For example, glutamic acid, which is involved in many metabolic pathways was reported to be synthesized by Escherichia coli26 and Vibrio costicola27 to balance the K+ uptake from the media. The up-regulation of glutamic acid with increasing temperature was observed in Vibrio coralliilyticus24. Accumulation of alanine is a common phenomenon in response to various stresses in both plants and animals28. Therefore, the level of alanine has been proposed to be a universal stress signal28. The increases in alanine were demonstrated in V. parahaemolyticus exposed to various concentrations of ferric iron23. Hence, the accumulation of many amino acids and an activated amino acid metabolism (indicated via the pathway analysis) in ITA exposed Vibrio sp. may indicate stress responses and disturbance of amino acid metabolism of ITA on Vibrio sp.
We observed the accumulation of fatty acids, including pimelic acid, stearic acid, capric acid, and a secondary pathway analysis revealed biosynthesis of unsaturated fatty acids as an altered pathway due to the ITA effect. This may suggest the change of lipid metabolism of Vibrio sp. exposed to ITA. However, the mechanisms underlying the increases in these fatty acids is currently unknown. In addition, the accumulation of other organic acids (e.g., lactic acid, adipic acid, malonic acid, maleic acid) remains uncertain.
Among the altered metabolites, trans-4-hydroxyproline (Hyp) was the only down-regulated metabolite in the metabolite profiles of ITA exposed Vibrio sp. Hyp is a non-essential amino acid that is a major component of collagen in animals29 and glycoproteins in plant cell walls30. Hyp is synthesized in plants and animals by hydroxylation of proline by prolyl hydroxylase following protein synthesis (as a post-translational modification). Bacteria are able to metabolize Hyp released by protein degradation of animals and plants31. The accumulation of Hyp has been reported in Thermococcus spp32, Brevibacterium sp.33 and Halobacillus halophilus25 under high salt conditions, suggesting that Hyp may be a widespread osmoprotectant in halophilic and halotolerant bacteria. However, we observed the decrease of Hyp in ITA exposed Vibrio sp. This may be due to species-specific responses of different bacteria or stressor-specific responses. Nevertheless, these results suggest the important role of Hyp in stress responses of Vibrio bacteria, which should be investigated in future studies.
Overall, the findings from this study strongly indicate antimicrobial activity of ITA to marine bacteria. This points toward the potential use of ITA as an antimicrobial metabolite for bacterial control in aquaculture. However, ITA is known to be unsuitable as drug for mammal due to its toxicity to host cells21. For marine bivalves, we recently identified the increase of ITA in their tissues during the pathogen exposure8,9,11 which indicates ITA is internal metabolite and may not toxic for host at low concentration. However, whether exposure of aquatic organisms to high concentrations of ITA (e.g., 6 mM ITA like in this study) to fight intracellular and drug-resistant bacteria are safe for the host which needs to be investigated prior to application in aquaculture.
To our knowledge, this is the first study to report antibacterial properties of ITA to a marine Vibrio sp. bacterium. After ITA exposure, we observed reduced microbial growth, and higher levels of metabolites in the TCA cycle (glyoxylic acid, cis-aconitic acid, isocitric acid and fumaric acid), amino acids and fatty acids in ITA-exposed bacterial cultures. This indicates that ITA inhibits Vibrio sp. growth and disruption of central carbon metabolism and other metabolic changes. However, ICL activity was higher in the ITA treatment compared to the control, suggesting that ITA did not inhibit ICL in the glyoxylate shunt of this Vibrio isolate and another toxic mechanism may be responsible for the antimicrobial effect of ITA. Hence, there is a need for future investigations to explore the antimicrobial mechanism of ITA in marine Vibrio bacteria and other marine pathogens which may lead to the use of ITA as an antimicrobial compound in aquaculture practices.
Materials and Methods
Most of the chemicals used in this study were of analytical grade and obtained from Sigma-Aldrich (St Louis, MO, USA) with the following exceptions: LB broth (Miller, Code: 244610) and thiosulfate citrate bile salts sucrose (TCBS) agar from Fort Richard Laboratories (Auckland, New Zealand), chloroform from Merck (Darmstadt, Germany).
Bacterial culture and itaconic acid effects
Vibrio sp. DO1 (99.5% 16 S sequence similarity with V. corallyliticus and V. neptunius; Genbank: EU358784) isolated from Greenshell™ mussel larvae13 was kindly provided by Cawthron Institute (Nelson, New Zealand). The bacterial suspension was prepared as previously described8 with modifications. Briefly, the bacterial isolates, which were stored at −80 °C in 25% glycerol, were revived by thawing for 1 h prior to incubation in 10 mL volumes of sterilized LB broth at 25 °C for 12 h. The LB broth was prepared by adding 20 g of LB broth powder in 1 L of 5 μm-filtered artificial seawater (FAS), which was then autoclaved at 121 °C for 15 min. The bacterial suspension was streaked on TCBS agar plates and sub-cultured three times to ensure purity. Bacterial colonies were cultured in 20 mL LB for 24 h prior to using for the ITA study.
The effects of ITA on Vibrio were assessed by adding 100 μL of Vibrio sp. stock (8.7 × 107 cells mL−1) into glass bottles containing 100 mL LB with three different ITA concentrations (0, 3, 6 mM) supplemented with 3 mM sodium acetate. The bacterial cultures were incubated at 25 °C and sampled every 6 h up to 24 hpi for bacterial growth using a spectrophotometer (Ultrospec 2100 pro UV–Vis: Biochrom Ltd., Cambridge, UK) to measure absorbance at 600 nm. For metabolomics analyses, bacteria were harvested at 24 hpi. 1 mL of bacterial culture was centrifuged at 2438 × g for 10 minutes at 4 °C on an Eppendorf Centrifuge 5810 R (Eppendorf AG, Hamburg, Germany). The pelleted cells were washed with FAS and re-suspended with 1 mL of FAS. The final cell pellets were flash frozen in liquid nitrogen and stored at −80 °C until metabolite extraction and enzyme analyses could be performed. For isocitrate and isocitrate lyase assays, 1 mL bacterial culture was sampled and stored at −80 °C.
The concentrations of isocitrate in Vibrio sp. samples were measured by isocitrate assay kit (Sigma-Aldrich, St Louis, MO, USA). The assay was performed according to the manufacturer’s protocol. In summary, isocitrate standards containing 0, 4, 8, 12, 16, 20 nmole per well were prepared in a 96-well plate from 20 μL of 100 mM isocitrate stock. One hundred μL of Vibrio sp. in LB broth was homogenized in 100 μL of isocitrate assay buffer and centrifuged at 13,000 × g for 10 minutes (Centrifuge 5810 R, Eppendorf AG, Hamburg, Germany) to remove insoluble material. Twenty-five μL of each sample were added into each well and mixed with 25 μL of isocitrate assay buffer. A standard mix containing 46 μL isocitrate assay buffer, 2 μL substrate mix and 2 μL substrate mix was added into each of the wells and mixed. Blank samples contained 48 μL isocitrate assay buffer and 2 μL substrate mix only. All samples, blanks and standards were incubated for 30 min in the dark at room temperature prior to measuring at 450 nm with a microplate reader (Multiskan FC, Thermo, Waltham, MA, USA). Concentrations of isocitrate in the samples were calculated based on absorbance and standard curves.
Isocitrate lyase assay
Quantification of isocitrate lyase in Vibrio sp. samples was conducted following a published protocol34. In brief, reagents were prepared and added into suitable cuvettes as follows: 0.50 mL of 50 mM imidazole buffer (pH 6.8 at 30 °C), 0.1 mL of 50 mM magnesium chloride solution (MgCl2), 0.1 mL of 10 mM ethylenediaminetetraacetic acid solution (EDTA), 0.1 mL of 40 mM phenylhydrazine hydrochloride solution and 0.1 mL of 10 mM DL-isocitric acid solution (isocitrate). Cuvettes containing the reagent mixture was equilibrated to 30 °C in a water bath. For each Vibrio sp. sample, 0.1 mL was combined with the reagent mix immediately measured in a spectrophotometer at 324 nm (Ultrospec 2100 pro UV–Vis: Biochrom Ltd., Cambridge, UK). Samples were placed back in the 30 °C water bath re-measured after 5 min. Alternatively, 0.1 mL of imidazole buffer was added to blanks and similarly measured. ICL concentrations in each sample was calculated based on A324 min−1 of samples and blanks.
Metabolite extractions and GC-MS measurements
Metabolites in Vibrio sp. samples were extracted in cold methanol-water solution (MeOH:H2O, 50% and 80%, sequentially), and derivatized via methyl chloroformate alkylation (MCF), as previously described35,36. Derivatized extracts were transferred into 2 mL amber GC glass vials fitted with inserts (Sigma-Aldrich, St. Louis, MO, USA) for GC-MS analyses which were performed on a gas chromatograph GC7890B coupled to a quadrupole mass spectrometer MSD5977A (Agilent Technologies, USA), with a quadrupole mass selective detector (EI) operated at 70 eV. The system was equipped with a ZB-1701 GC capillary column (30 m × 250 μm id × 0.15 μm with 5 m stationary phase) (Phenomenex, Torrance, CA, USA). Helium was used as the carrier gas and was held constant at the flow of 1 mL min−1. The instrumental setup parameters for MCF derivatized samples were conducted according to Smart, et al.35. The injection volume was 1 μL and all samples were injected randomly.
Confirmation of specific metabolites in the TCA cycle/glyoxylate shunt (citric acid, cis-aconitic acid, isocitric acid, succinic acid, fumaric acid, malic acid, glyoxylic acid and pyruvic acid) was conducted by extraction, derivatization and GC-MS measurements of the standards of these compounds (20 μL of 20 mM solutions).
Quality control for GC-MS measurements
Several types of quality control (QC) samples were employed to ensure reproducibility of GC-MS measurements as previously described11. Firstly, 3 blank samples containing 20 μL 10 mM d4 alanine were extracted using the sample protocol. Secondly, three standard amino acid mixtures (20 µL, 20 mM) were similarly derivatized with extracted samples. The third type of QC was a pool of all samples. These QC samples were injected at the beginning and after every six samples. In addition, non-derivatized standard alkane mixtures and chloroform solvent were injected at the beginning and at the end of the measurements for system checking. Together, QC samples made up more than 30% of the total injections.
GC-MS data processing
Raw spectra were processed using Automated Mass Spectral Deconvolution and Identification System (AMDIS) software (version 2.66) integrated with the MassOmics R-based package (The University of Auckland). This process includes baseline correction, peak detection, chromatogram deconvolution and alignment. The target hits were identified using an in-house library (The University of Auckland) with the minimum matching percentage of 70%. Other parameters used to accomplish this analysis were: retention time (RT) window (0.2 min), RT range (6.5–34.0 min), component width (14), m/z range (83–207), and scan sets (3). Annotated metabolites were manually checked with ChemStation software (Agilent Technologies, Inc., US) and AMDIS for the presence of contaminants. Repeats (based on ID number, match factor and retention time) and aberrant records were removed. Data were normalized by the internal standard (d4 alanine) and absorbance of the bacterial cultures to compensate for potential technical variations (e.g. variable metabolite recoveries) and differences in biomass amongst the treatments, respectively.
Statistical and pathway analysis
Metabolite profile data were analysed using MetaboAnalyst 4.037. Data were normalized by generalized logarithm (glog) transforming and mean centring to make individual features more comparable. Multivariate analyses, including unsupervised PCA and supervised PLS-DA were used to assess variability among samples and between sample classes. Validation of the PLS-DA model was performed using leave one out cross validation (LOOCV), which was assessed via accuracy, R2 and Q2 values38. Univariate analysis was performed using t-test to identify differences between metabolite profiles of ITA-treated and control cultures of Vibrio sp. A heatmap of altered metabolites was generated to assess the abundance of these metabolites (low/high) via intuitive visualization. Classical univariate ROC analyses for individually altered metabolites in glyoxylate shunt and multivariate ROC analysis (using linear support vector machines) for all of these features were performed to assess the accuracy of biomarker models.
Quantitative enrichment analysis (QEA) using global test algorithm39 and network topology analysis (NTA) using relative-betweeness centrality40 were performed to investigate functional relationships among the annotated metabolites using the Escherichia coli K-12 MG1655 reference pathway library in the Kyoto Encyclopedia of Genes and Genomes (KEGG) database. Pathways involving two or more annotated metabolites with simultaneous QEA p-values < 0.05, QEA false discovery rates (FDRs) < 0.1, and with NTA pathway impact (PI) scores > 0.1 were considered as primary pathways of interest due to ITA effects.
Williams, J. O., Roche, T. E. & McFadden, B. A. Mechanism of action of isocitrate lyase from Pseudomonas indigofera. Biochemistry 10, 1384–1390 (1971).
McFadden, B. & Purohit, S. Itaconate, an isocitrate lyase-directed inhibitor in Pseudomonas indigofera. Journal of Bacteriology 131, 136–144 (1977).
Hillier, S. & Charnetzky, W. Glyoxylate bypass enzymes in Yersinia species and multiple forms of isocitrate lyase in Yersinia pestis. Journal of Bacteriology 145, 452–458 (1981).
Michelucci, A. et al. Immune-responsive gene 1 protein links metabolism to immunity by catalyzing itaconic acid production. Proceedings of the National Academy of Sciences 110, 7820–7825 (2013).
Shin, J.-H. et al. 1H NMR-based metabolomic profiling in mice infected with Mycobacterium tuberculosis. Journal of Proteome Research 10, 2238–2247 (2011).
Sugimoto, M. et al. Non-targeted metabolite profiling in activated macrophage secretion. Metabolomics 8, 624–633 (2012).
Strelko, C. L. et al. Itaconic acid Is a mammalian metabolite induced during macrophage activation. Journal of the American Chemical Society 133, 16386–16389, https://doi.org/10.1021/ja2070889 (2011).
Nguyen, T. V., Alfaro, A. C., Young, T., Ravi, S. & Merien, F. Metabolomics study of immune responses of New Zealand greenshell™ mussels (Perna canaliculus) infected with pathogenic Vibrio sp. Marine Biotechnology 20, 396–409, https://doi.org/10.1007/s10126-018-9804-x (2018).
Nguyen, T. V., Alfaro, A. C., Merien, F., Young, T. & Grandiosa, R. Metabolic and immunological responses of male and female New Zealand Greenshell™ mussels (Perna canaliculus) during Vibrio sp. infection. Journal of Invertebrate Pathology 157, 80–89, https://doi.org/10.1016/j.jip.2018.08.008 (2018).
Young, T. et al. Differential expression of novel metabolic and immunological biomarkers in oysters challenged with a virulent strain of OsHV-1. Developmental & Comparative Immunology 73, 229–245 (2017).
Nguyen, T. V., Alfaro, A. C., Young, T. & Merien, F. Tissue-specific immune responses to Vibrio sp. infection in mussels (Perna canaliculus): A metabolomics approach. Aquaculture. https://doi.org/10.1016/j.aquaculture.2018.09.061 (2018).
Travers, M.-A., Boettcher Miller, K., Roque, A. & Friedman, C. S. Bacterial diseases in marine bivalves. Journal of Invertebrate Pathology 131, 11–31, https://doi.org/10.1016/j.jip.2015.07.010 (2015).
Kesarcodi‐Watson, A., Lategan, M., Kaspar, H. & Gibson, L. Two pathogens of Greenshell™ mussel larvae, Perna canaliculus: Vibrio splendidus and a V. coralliilyticus/neptunius‐like isolate. Journal of Fish Diseases 32, 499–507 (2009).
Kesarcodi-Watson, A., Kaspar, H., Lategan, M. J. & Gibson, L. F. Challenge of New Zealand Greenshell™ mussel Perna canaliculus larvae using two Vibrio pathogens: a hatchery study. Dis Aquat Organ 86, 15–20 (2009).
Sezonov, G., Joseleau-Petit, D. & D’Ari, R. Escherichia coli physiology in Luria-Bertani broth. Journal of Bacteriology 189, 8746–8749 (2007).
Lorenz, M. C. & Fink, G. R. Life and death in a macrophage: role of the glyoxylate cycle in virulence. Eukaryotic Cell 1, 657–662 (2002).
Sharma, V. et al. Structure of isocitrate lyase, a persistence factor of Mycobacterium tuberculosis. Nature Structural and Molecular Biology 7, 663 (2000).
Kondrashov, F. A., Koonin, E. V., Morgunov, I. G., Finogenova, T. V. & Kondrashova, M. N. Evolution of glyoxylate cycle enzymes in Metazoa: evidence of multiple horizontal transfer events and pseudogene formation. Biology Direct 1, 31–31, https://doi.org/10.1186/1745-6150-1-31 (2006).
White, D., Drummond, J. T. & Fuqua, C. The physiology and biochemistry of prokaryotes. Vol. 4 (Oxford University Press New York, 2007).
Maloy, S. R., Bohlander, M. & Nunn, W. D. Elevated levels of glyoxylate shunt enzymes in Escherichia coli strains constitutive for fatty acid degradation. Journal of bacteriology 143, 720–725 (1980).
Lee, Y.-V., Wahab, H. A. & Choong, Y. S. Potential Inhibitors for Isocitrate Lyase of Mycobacterium tuberculosis and Non-M. tuberculosis: A Summary. BioMed Research International 2015, 895453, https://doi.org/10.1155/2015/895453 (2015).
Patel, T. R. & McFadden, B. A. Caenorhabditis elegans and Ascaris suum: inhibition of isocitrate lyase by itaconate. Experimental parasitology 44, 262–268 (1978).
Zhou, J., Lu, C., Zhang, D., Ma, C. & Su, X. NMR-based metabolomics reveals the metabolite profiles of Vibrio parahaemolyticus under ferric iron stimulation. Journal of Microbiology 55, 628–634 (2017).
Boroujerdi, A. F. et al. NMR-based microbial metabolomics and the temperature-dependent coral pathogen Vibrio coralliilyticus. Environmental science & technology 43, 7658–7664 (2009).
Kim, K. H., Jia, B. & Jeon, C. O. Identification of Trans-4-Hydroxy-L-Proline as a compatible solute and its biosynthesis and molecular characterization in Halobacillus halophilus. Frontiers in microbiology 8, 2054 (2017).
Dinnbier, U., Limpinsel, E., Schmid, R. & Bakker, E. P. Transient accumulation of potassium glutamate and its replacement by trehalose during adaptation of growing cells of Escherichia coli K-12 to elevated sodium chloride concentrations. Archives of Microbiology 150, 348–357 (1988).
Kamekura, M. & Kushner, D. J. Effect of chloride and glutamate ions on in vitro protein synthesis by the moderate halophile Vibrio costicola. Journal of Bacteriology 160, 385–390 (1984).
Ben-Izhak Monselise, E., Parola, A. H. & Kost, D. Low-frequency electromagnetic fields induce a stress effect upon higher plants, as evident by the universal stress signal, alanine. Biochemical and Biophysical Research Communications 302, 427–434, https://doi.org/10.1016/S0006-291X(03)00194-3 (2003).
Szpak, P. Fish bone chemistry and ultrastructure: implications for taphonomy and stable isotope analysis. Journal of Archaeological Science 38, 3358–3372 (2011).
Cassab, G. I. Plant cell wall proteins. Annual review of plant biology 49, 281–309 (1998).
White, C. E., Gavina, J. M., Morton, R., Britz‐McKibbin, P. & Finan, T. M. Control of hydroxyproline catabolism in Sinorhizobium meliloti. Molecular microbiology 85, 1133–1147 (2012).
Lamosa, P., Martins, L. O., Da Costa, M. S. & Santos, H. Effects of Temperature, Salinity, and Medium Composition on Compatible Solute Accumulation by Thermococcus spp. Applied and environmental microbiology 64, 3591–3598 (1998).
Nagata, S., Adachi, K. & Sano, H. NMR analyses of compatible solutes in a halotolerant Brevibacterium sp. Microbiology 142, 3355–3362 (1996).
Chell, R., Sundaram, T. & Wilkinson, A. Isolation and characterization of isocitrate lyase from a thermophilic Bacillus sp. Biochemical Journal 173, 165–177 (1978).
Smart, K. F., Aggio, R. B., Van Houtte, J. R. & Villas-Bôas, S. G. Analytical platform for metabolome analysis of microbial cells using methyl chloroformate derivatization followed by gas chromatography–mass spectrometry. Nature Protocols 5, 1709 (2010).
Alfaro, A. C. & Nguyen, T. V. & Mellow, D. A metabolomics approach to assess the effect of storage conditions on metabolic processes of New Zealand surf clam (Crassula aequilatera). Aquaculture 498, 315–321, https://doi.org/10.1016/j.aquaculture.2018.08.065 (2019).
Chong, J. et al. MetaboAnalyst 4.0: towards more transparent and integrative metabolomics analysis. Nucleic Acids Research 46, W486–W494, https://doi.org/10.1093/nar/gky310 (2018).
Szymańska, E., Saccenti, E., Smilde, A. K. & Westerhuis, J. A. Double-check: validation of diagnostic statistics for PLS-DA models in metabolomics studies. Metabolomics 8, 3–16, https://doi.org/10.1007/s11306-011-0330-3 (2012).
Xia, J. & Wishart, D. S. MetPA: a web-based metabolomics tool for pathway analysis and visualization. Bioinformatics 26, 2342–2344 (2010).
Nikiforova, V. J. & Willmitzer, L. Network visualization and network analysis in Plant Systems Biology (ed. Baginsky, S. & Fernie, A. R.) 245–275 (Springer, 2007).
We would like to thank Aditya Kesarcodi-Watson from Cawthron Institute for providing the pathogenic Vibrio sp., and laboratory technicians in the School of Science at Auckland University of Technology for their help and support during this project. We would like to show appreciation to Shrushti Joshi for her assistance in sampling. This project was supported by the New Zealand Ministry of Business, Innovation and Employment (MBIE) (CAWX1707). Additional financial support was provided by a New Zealand ASEAN Scholarship and an award from the New Zealand Marine Sciences Society (NZMSS) to T. V. Nguyen, under the supervision of A. C. Alfaro and F. Merien.
The authors declare no competing interests.
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Nguyen, T.V., Alfaro, A.C., Young, T. et al. Itaconic acid inhibits growth of a pathogenic marine Vibrio strain: A metabolomics approach. Sci Rep 9, 5937 (2019). https://doi.org/10.1038/s41598-019-42315-6
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