Diverse effects of nitric oxide reductase NorV on Aeromonas hydrophila virulence-associated traits under aerobic and anaerobic conditions

NorV has been known to be an anaerobic nitric oxide reductase associated with nitric oxide (NO) detoxification. Recently, we showed that the norV gene of Aeromonas hydrophila was highly upregulated after co-culturing with Tetrahymena thermophila. Here, we demonstrated that the transcription and expression levels of norV were upregulated in a dose-dependent manner after exposure to NO under aerobic and anaerobic conditions. To investigate the roles of norV in resisting predatory protists and virulence of A. hydrophila, we constructed the norV gene-deletion mutant (ΔnorV). Compared to the wild type, the ΔnorV mutant showed no significant difference in growth at various NO concentrations under aerobic conditions but significantly stronger NO-mediated growth inhibition under anaerobic conditions. The deletion of norV exhibited markedly decreased cytotoxicity, hemolytic and protease activities under aerobic and anaerobic conditions. Also, the hemolysin co-regulated protein (Hcp) in the ΔnorV mutant showed increased secretion under aerobic conditions but decreased secretion under anaerobic conditions as compared to the wild-type. Moreover, the inactivation of norV led to reduced resistance to predation by T. thermophila, decreased survival within macrophages and highly attenuated virulence in zebrafish. Our data indicate a diverse role for norV in the expression of A. hydrophila virulence-associated traits that is not completely dependent on its function as a nitric oxide reductase. This study provides insights into an unexplored area of NorV, which will contribute to our understanding of bacterial pathogenesis and the development of new control strategies for A. hydrophila infection.

Aeromonas hydrophila is a Gram-negative bacterium, commonly found in a variety of natural aquatic environments worldwide including seawater, freshwater, sediments and even drinking water [1]. This bacterium is responsible for a variety of diseases in amphibians, fish and reptiles. As a major pathogen causing hemorrhagic septicemia in fish, A. hydrophila causes severe economic losses to aquaculture worldwide [2, 3]. The pathogenesis of A. hydrophila is complex and multifactorial, probably resulting from the expression of virulence factors such as adhesins, enterotoxins, hemolysin, aerolysin, and proteases, and as well as the secretion systems such as type III (T3SS) and type VI (T6SS) secretion systems [2,3,4,5].

Although many virulence factors have already been identified in A. hydrophila, several remain to be discovered. It is noteworthy that environmental factors, such as protistan predation, have an important impact on the virulence evolution of pathogens [6]. Protists may provide a protective reservoir for pathogens and act as a “training ground” for bacterial virulence [7, 8]. It has been demonstrated that pathogens including Legionella pneumophila [9], Salmonella enteritidis [10, 11], and Mycobacterium avium [12] are able to survive protistan predation, subsequently resulting in resistance to adverse situations such as antibiotics, oxidants and bioacids and increasing virulence. Grazing resistance to protists is an evolutionary precursor of bacterial pathogenicity and promotes bacteria to develop some defensive mechanisms for survival, such as new gene expression patterns or new proteins which may emerge as virulence determinants in animal and human infections [13, 14].

In our previous study, the norV gene of A. hydrophila was screened and identified to be about 15-fold upregulated under predation pressure of Tetrahymena thermophila [15]. The norV encodes a flavorubredoxin, a nitric oxide reductase, which is supposed to be inactivated by oxygen and provides physiological protection against nitric oxide (NO) only at low or zero oxygen concentrations [16]. The transcription of norV gene has been reported to be stimulated via a nitric oxide sensor NorR and sigma factor 54 (σ⁵⁴)-dependent mechanism [17]. The binding of mononuclear iron site to NO activates the ATPase activity of NorR and enables NorR to interact with σ⁵⁴-containing RNA polymerase to regulate the transcription of norV [18]. NorV, functioning as a major defense factor, contributes to bacterial resistance against oxidative and nitrosative killing [19,20,21]. Bacteria engulfed within the phagosomes of protists share similar defensive mechanisms responsible for survival within macrophages [22, 23]. During infection, bacterial cells are typically internalized into macrophages, enclosed in the phagolysosome and exposed to nitrogen radicals that are derived from inducible nitric oxide synthase (iNOS) [24]. NO is toxic to bacteria and usually deployed by macrophages as a potent antimicrobial for inhibition of pathogen proliferation, metabolic blockade, inactivation of virulence factors and dispersion of bacterial biofilm [25]. It has been reported that the norV mRNA expression was upregulated in Salmonella enterica sv. Typhimurium after macrophage internalization [26]. In addition, norV has been identified to limit NO level and contribute to the production of shiga toxin 2 (Stx2) of enterohaemorrhagic Escherichia coli (EHEC) within macrophages [27]. Whether and how norV gene is involved in stress response and pathogenicity of A. hydrophila are still unclear.

In this study, we evaluated the biological functions of the norV gene both in the aerobic and anaerobic environments. We also proposed a possible role of norV in A. hydrophila virulence and its resistance to predation by T. thermophila.

Strains, cell lines and media

Aeromonas hydrophila strain NJ-35 (accession number CP006870) and E. coli SM10 were maintained in Luria–Bertani (LB) media at 28 °C and 37 °C, respectively. When required, media were supplemented with ampicillin (100 μg/mL), chloramphenicol (34 μg/mL) or gentamicin (100 μg/mL).

Tetrahymena thermophila SB210 (accession number GCA_000261185.1) was obtained from Dr. Miao Wei, Institute of Hydrobiology, China Academy of Sciences, and cultured in SPP medium (2% protease peptone, 0.1% yeast extract, 0.2% glucose, 0.003% EDTA-Fe) at 28 °C.

RAW264.7 cells were maintained in Dulbecco’s modified Eagle medium (DMEM; Gibco, New York, USA) supplemented with 10% (vol/vol) heat-inactivated fetal bovine serum (FBS; Gibco). All reagents used in this study were supplied by Sigma (St. Louis, MO, USA) unless otherwise indicated.

Inactivation and complementation of norV gene in A. hydrophila

The norV gene was knocked out on the basis of the suicide plasmid pYAK1 via homologous recombination as previously described [28]. Firstly, the two flanking regions of norV were fused and cloned into pYAK1. The resulting plasmid was conjugated into A. hydrophila NJ-35 (resistance to ampicillin, Amp^r) from E. coli SM10 and transconjugants were selected on LB agar plates with ampicillin and chloramphenicol. The positive colonies were cultured in LB medium without sodium chloride for 12 h and then counter-selected by growing on LB agar plates containing 20% sucrose. The gene-deletion mutant ΔnorV was verified by PCR.

Genetic complementation was carried out by inserting the norV gene with a synonymous point mutation to the genome of ΔnorV mutant. The norV gene and its two flanking regions were amplified from NJ-35 genomic DNA allowing a point mutation (G1236A) in norV. The fused PCR product was cloned into pYAK1 and conjugated into the ΔnorV (Amp^r). Chromosomal integration was achieved via allelic homologous recombination. The complemented strain CΔnorV was screened by antibiotics (ampicillin and chloramphenicol) and 20% sucrose in sequence and further verified by PCR and sequencing. The primers used are listed in Additional file 1.

NO growth inhibition assay

NO growth inhibition assay was performed as previously described [27]. A. hydrophila wild-type, ΔnorV and CΔnorV strains grown overnight were adjusted to OD₆₀₀ of 1.0 with fresh LB media. The bacterial suspensions were diluted 1:100 with LB containing various concentrations of NO donor (sodium nitroprusside, SNP) and grown statically at 28 °C under aerobic or anaerobic conditions. Cultures without any treatment served as control. Then the OD₆₀₀ values were measured every 1 h by a spectrophotometer (Bio-Rad, USA). Each sample was repeated in triplicate.

Measurement of LDH release, hemolytic and protease activity

Aeromonas hydrophila wild-type, ΔnorV and CΔnorV strains were cultured with or without NO donor to OD₆₀₀ of 0.8 both under aerobic and anaerobic conditions. The culture supernatants were collected through centrifugation and filtration.

Cytotoxicity of RAW 264.7 macrophages induced by bacterial extracellular products (ECPs) was evaluated by measuring the release of lactate dehydrogenase (LDH) with a CytoTox 96 nonradioactive cytotoxicity assay (Promega, USA). The assay was performed according to the manufacturer’s instructions. Macrophages grown in 96-well plates were washed and added with 100 μL/well MEM containing 10 μL of the above mentioned culture supernatants. The plate was then incubated for 4 h at 37 °C with 5% CO₂. LDH released by lysis of cells with 1% (vol/vol) Triton X-100 was defined as cell maximum release. LDH released by uninfected cells was designated as cell spontaneous release. The release of LDH was determined by measuring OD₄₉₂ using a micro-plate reader (Tecan, Switzerland). Cytotoxicity was calculated as follows: % cytotoxicity (test LDH release − cell spontaneous release)/(cell maximal release − cell spontaneous release).

The hemolytic activity was measured as previously described [29]. One hundred microliters (100 μL) sterilized saline was added to each well of a 96-well cell plate. A 0.1-mL aliquot of the supernatant from a given strain was added to the first well, followed by a serial twofold dilution, with addition of 100 μL of 2% sheep red blood cells (RBCs). The 2% RBCs added with an equal volume of sterilized saline and water served as negative and positive controls, respectively. The plate was incubated at 37 °C for 1 h and placed at 4 °C overnight. The unlysed cells were precipitated by centrifugation. One hundred microliters of the supernatants were separated and transferred to a new 96-well plate, and the hemoglobin released was measured at OD₅₄₀. The hemolytic activity was expressed as the reciprocal of the highest dilution of the culture filtrates that lead to the lysis of exceeding 50% RBCs.

The protease activity was measured as previously described [30]. Briefly, 250 μL of the supernatants were mixed with an equal volume of 0.5% (wt/vol) casein in 50 mM Tris–HCl (pH 8.0). After incubation at 37 °C for 2 h, the mixture was added to 500 μL pre-cooled 10% (wt/vol) trichloroacetic acid (TCA) and placed on ice for 30 min to precipitate the proteins. Then 500 μL of the supernatant was collected after centrifugation and mixed with an equal volume of 1 M NaOH. The absorbance was measured at OD₄₄₀.

Western blot for hemolysin co-regulated protein (Hcp) and NorV protein

Western blot was performed to determine the levels of Hcp protein expression and secretion in A. hydrophila wild-type, ΔnorV and CΔnorV strains as described previously [31]. Briefly, both the cell pellets and culture supernatants from a given strain were collected and treated with 5× SDS-PAGE buffer. Aliquots of the samples were subjected to SDS-PAGE and electrophoretically transferred to NC membranes. The membranes were incubated with anti-Hcp, or anti-NorV, or anti-GroEL polyclonal antiserum followed by horseradish peroxidase (HRP)-conjugated goat anti-rabbit IgG. Antibody-antigen complexes were detected using an ECL Pico-detect kit (CMCTAG, USA) and ChemiDoc™ Touch imaging system (Bio-Rad, USA).

qRT-PCR analysis for hcp and norV genes

The mRNA levels of hcp and norV genes in A. hydrophila were measured using qRT-PCR. Bacterial RNA was isolated with an E.Z.N.A. bacterial RNA isolation kit (Omega, Beijing, China). Then cDNA was synthesized in triplicate using HiScript qRT SuperMix (Vazyme Biotech). The cDNA amplification was manipulated using AceQ qPCR SYBR Green kit (Vazyme Biotech) in the Applied Biosystems StepOnePlus™ Real-Time PCR System (Thermo Fisher Scientific, USA). All procedures above were performed according to the manufacturer’s instructions. The internal housekeeping gene recA was used as the reference, and the acquired cycle threshold (CT) of each gene was normalized. The fold-change of mRNA levels was calculated using the 2^−ΔΔCT method [32]. The primers used are listed in Additional file 1.

Bacterial resistance to predation by T. thermophila

The anti-predation ability of A. hydrophila was expressed as the relative survival of bacteria after co-cultured with T. thermophila [15]. Briefly, A. hydrophila (1 × 10⁹ CFU/mL) and T. thermophila SB210 (2 × 10⁵ cells/mL) in TBSS (2 mM KCl, 1 mM CaCl₂, 0.5 mM MgCl₂, and 1 mM Tris [pH 6.8–7.2]) were well mixed in equal volume. One hundred microliters of the mixture was transferred to each well of a 96-well plate. Meanwhile, A. hydrophila and SB210 mixed with same volume of TBSS respectively acted as the controls. TBSS alone served as the blank control. The plate was placed at 28 °C without shaking for 12 h, and the bacterial population was measured at OD₄₅₀. The relative survival of bacteria was expressed as the OD₄₅₀ value of the bacteria co-cultured with T. thermophila divided by that of bacteria grown alone at 12 h. The absorbance of T. thermophila cells was negligible [33]. The assay was duplicated in quadruplicate in three independent experiments.

Determination of intracellular growth efficiency

The intracellular growth efficiency was determined using RAW264.7 macrophages as previously described [34]. A. hydrophila wild-type, ΔnorV and CΔnorV strains grown to logarithmic phase were washed and resuspended in fresh serum-free DMEM. The RAW264.7 macrophages cultured in 24-well plate were infected with A. hydrophila at a multiplicity of infection (MOI) of 1:1 for 1 h at 37 °C. Extracellular bacteria were removed by washing and addition of DMEM containing gentamicin. To measure the intracellular bacterial survival rate, cells were sampled 1 h after the interaction with antibiotics (time point 0) and subsequently at a regular intervals of 20 min. Infected macrophages were washed three times with PBS and then treated with 0.1% (vol/vol) Triton X-100 for 10 min to fully lyse the cells and release intracellular bacteria. The CFU of intracellular bacteria was quantified using LB agar plates. The relative survival rate over time was calculated as follows: (average CFU at a specific time point/average CFU at time point 0) × 100.

Determination of the bacterial median lethal dose (LD₅₀)

The LD₅₀ assay was performed using a zebrafish model as described by Pang et al. [33]. Zebrafish were provided by the Pearl River Fishery Research Institute, Chinese Academic of Fishery Science. A. hydrophila grown to logarithmic phase were washed three times and adjusted to 5 × 10⁸ CFU/mL, followed by a serial tenfold dilution with sterilized PBS. The zebrafish were divided into seven groups for each strain and each group consisted of ten zebrafish. The zebrafish were intraperitoneally injected with 20 μL of each dilution (10¹ to 10⁷ CFU). Meanwhile, another ten zebrafish were injected with 20 μL of sterile PBS as the negative control. LD₅₀ studies were carried out in triplicate for all of the strains. The numbers of dead fish showing clinical symptoms were recorded within 7 days. The LD₅₀ values were calculated by the Reed and Muench method [35].

Statistical analyses

The statistical analyses in this study were performed using the GraphPad Prism version 5 software. Student’s t test was used to analyze the difference between the ΔnorV mutant and the wild type strain. Tukey’s multiple comparisons were preformed to analyze the norV mRNA levels of A. hydrophila NJ-35 grown under various conditions using one-way analysis of variance (ANOVA) with 95% confidence intervals. P-value < 0.05 was considered as a significant difference.

NO activates the expression of norV gene

To determine how the norV gene in A. hydrophila responds to NO exposure, qRT-RCR analysis and Western blot were preformed. As shown in Figure 1, the transcription and expression levels of norV were increased when cells were exposed to SNP in a dose-dependent manner under both aerobic and anaerobic conditions, showing that norV could be activated by NO exposure regardless of the presence or absence of oxygen. Notably, the mRNA level of norV was significantly enhanced under anaerobic conditions compared to that under aerobic conditions (P < 0.001), suggesting that norV expression to some extent may be inhibited by oxygen.

The expression of norV in response to NO donor (sodium nitroprusside, SNP) under aerobic and anaerobic conditions. The A. hydrophila strains were cultured to OD₆₀₀ of 0.8 with various concentrations of NO donor under aerobic and anaerobic conditions. A The mRNA level of norV in the wild type strain determined by qRT-PCR. The expression value of norV without SNP treatment in the aerobic condition was normalized to 1.0. Values are means ± SD from three biological replicates. Different uppercase letters (a–g) indicate significant differences (P < 0.05) among different treatments. B The expression levels of NorV protein detected by Western blot. Lines 1, 4, 7, 10 represent the wild type strain NJ-35; Lines 2, 5, 8, 11 represent the ΔnorV mutant; and Lines 3, 6, 9, 12 represent the complemented CΔnorV strain.

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NorV affords protection against NO-mediated growth inhibition

To examine how NorV in A. hydrophila responds to NO, we determined the growth difference between the wild-type and ΔnorV mutant strains exposed to NO donor. As shown in Figures 2A and B, the growth of the wild-type strain and ΔnorV mutant showed no difference both under the aerobic and anaerobic conditions in the absence of NO. In the aerobic cultures containing SNP, the growth rates of ΔnorV were comparable to the wild type strain (Figures 2C and E). However, the ΔnorV mutant displayed a reduction of anaerobic growth in response to SNP in a dose-dependent manner (Figures 2D and F). The growth capacity was restored in the complemented strain CΔnorV.

Growth ability of the wild-type, ΔnorV mutant, and complemented CΔnorV strains exposed to NO donor. Growth curves of A. hydrophila strains were determined under aerobic (A) and anaerobic (B) conditions without SNP treatment. After the addition of 0.5 mM SNP, the growth yields of A. hydrophila strains under aerobic (C) or anaerobic (D) conditions were detected by measuring the OD₆₀₀ values. NO growth inhibition assay was performed in bacteria grown for 8 h at 28 °C in LB broth containing various concentrations of SNP under aerobic (E) or anaerobic (F) conditions. Values are the means ± SD from three biological replicates. ***P < 0.001.

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The norV is involved in cytotoxicity, hemolytic and protease activities

To determine whether NorV is associated with the production of extracellular products, the cytotoxicity, hemolytic and protease activities were determined. As shown in Figures 3A and B, the culture filtrates collected from the ΔnorV, grown both under aerobic and anaerobic conditions, produced significantly lower injury to macrophages than those of the wild-type strain (P < 0.001). In addition, the ΔnorV mutant displayed poorer hemolytic activity than the wild-type strain when cultured both under aerobic and anaerobic conditions (P < 0.001) (Figures 3C and D). Similarly, the protease activity of ΔnorV was also markedly decreased (P < 0.001) (Figures 3E and F). Notably, the cytotoxicity, hemolytic and protease activities of ΔnorV mutant when exposed to NO under anaerobic conditions were decreased in a dose-dependent manner, whereas their activities in the wild-type strain showed no obvious difference. Moreover, the hemolytic activity of the ΔnorV mutant under anaerobic conditions was lower than that under aerobic conditions. High concentrations of NO could exert reduced effect on hemolytic activity of the wild-type. All the activities of extracellular products were restored in the CΔnorV.

Cytotoxicity, hemolytic and protease activities of the wild-type, ΔnorV mutant, and complemented CΔnorV strains grown under various conditions. Cytotoxicity was expressed as LDH release of RAW264.7 macrophages induced by culture supernatants collected from bacteria grown under aerobic (A) and anaerobic (B) conditions after exposure to various concentrations of SNP. The hemolytic activities of each strain grown under aerobic (C) and anaerobic (D) conditions after treating with various concentrations of SNP were expressed as the dilution-fold of the A. hydrophila culture filtrates that led to the lysis of 50% erythrocytes. The protease activities of A. hydrophila strains cultured in LB media containing various concentrations of SNP under aerobic (E) and anaerobic (F) conditions were measured at OD₄₄₀ with azocasein as the substrate. Values are the means ± SD from three biological replicates. ***P < 0.001.

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The norV is diversely involved in production and secretion of Hcp protein

To determine whether the norV gene is involved in regulating the function of T6SS in response to NO, the expression and secretion of Hcp in A. hydrophila wild-type, ΔnorV mutant and CΔnorV strains were examined. When exposed to NO, Hcp expression showed no obvious difference between ΔnorV mutant and wild-type strain under aerobic conditions (Figures 4A and B). However, under anaerobic conditions, Hcp expression displayed a decreased tendency after exposure to NO and that of ΔnorV mutant was significantly lower than the wild-type strain (P < 0.05) with SNP at concentrations of 0.5 mM and 2.5 mM (Figures 4A and C). The mRNA levels of hcp were consistent with protein expression results (Figures 4D and E). However, as shown in Figure 5A, NO exposure led to an increase in Hcp secretion of the wild-type strain but a decrease in ΔnorV mutant both under aerobic and anaerobic conditions. Hcp secretion of ΔnorV mutant was higher in the aerobic environment but poorer under anaerobic conditions than the wild-type strain (Figures 5B and C). The cytoplasmic chaperone protein GroEL was not detectable in the supernatants, demonstrating that the Hcp detected was the result of bacterial secretion but not cell lysis.

Effects of norV on Hcp protein expression. A The Hcp proteins in the whole cells of bacteria grown under aerobic and anaerobic conditions exposing to various concentrations of SNP were determined by Western blot. Polyclonal anti-Hcp antibodies were used to measure the production of Hcp and anti-GroEL antibodies served as internal reference. Lines 1, 4, 7, 10 represent the wild type strain NJ-35; Lines 2, 5, 8, 11 represent the ΔnorV mutant; and Lines 3, 6, 9, 12 represent the complemented CΔnorV strain. The relative changes of Hcp production of bacteria cultured under aerobic (B) and anaerobic (C) conditions are given between the blots. The intensities of the Hcp and GroEL bands were measured and Hcp was equalized to that of GroEL. The relative mRNA levels of hcp gene in A. hydrophila strains grown under aerobic (D) and anaerobic (E) conditions after treated with various concentrations of SNP were determined by qRT-PCR. Values are the means ± SD from three biological replicates. *P < 0.05, **P < 0.01.

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The norV is diversely involved in secretion of Hcp protein. A Hcp proteins in the culture supernatants of bacteria grown under aerobic and anaerobic conditions after exposure with various concentrations of SNP were determined by Western blot. Polyclonal anti-Hcp antibodies were used to measure the secretion of Hcp and anti-GroEL antibodies served as internal reference. Lines 1, 4, 7, 10 represent the wild type strain NJ-35; Lines 2, 5, 8, 11 represent the ΔnorV mutant; and Lines 3, 6, 9, 12 represent the complemented CΔnorV strain. The relative changes of Hcp secretion of bacteria grown under aerobic (B) and anaerobic (C) conditions are given between the blots. Values are the means ± SD from three biological replicates. *P < 0.05, **P < 0.01, ***P < 0.001.

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The norV contributes to resisting predation by T. thermophila

In order to study whether norV inactivation exerts influence on the interaction between A. hydrophila and T. thermophila, the relative survivals of the wild type strain NJ-35 and its norV derivatives were detected after co-culture with T. thermophila for 12 h. The relative survival of ΔnorV mutant (51.83 ± 4.02%) exhibited a significant reduction (P = 0.0054) compared to that of the wild-type strain (68.10 ± 3.20%). The anti-protistan predation level was restored in the complemented strain (63.72 ± 4.73%).

The norV enhances the intracellular survival of A. hydrophila in macrophages

The bacteria within RAW264.7 macrophages were quantified by CFU counts. Compared with the wild-type, more intracellular viable bacteria of the ΔnorV mutant were observed, suggesting that the ΔnorV is more susceptible to phagocytosis by macrophages (Figure 6A). Moreover, the ΔnorV mutant displayed impaired survival rate in macrophages in a time-dependent manner (Figure 6B), indicating that the ΔnorV engulfed was more likely to be cleared by macrophages.

Survival efficiency of the wild-type, ΔnorV mutant, and complemented CΔnorV strains in RAW264.7 macrophages. A CFU of intracellular bacteria at 1 h post-infection (time point 0). B Intracellular survival rate of A. hydrophila in macrophages. Phagocytosis was allowed to proceed for 1 h at a MOI of 1.0. The CFU of intracellular bacteria was estimated every 20 min. The relative survival was calculated by dividing the mean CFU at a specific time point by the CFU at time point 0. The survival rate at time point 0 was arbitrarily set to 100%. Data are presented as the mean ± SD of three independent experiments. *P < 0.05, **P < 0.01.

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The norV is required for the virulence of A. hydrophila in zebrafish

To investigate the effect of norV on the virulence of A. hydrophila, zebrafish were injected intraperitoneally with the wild-type or ΔnorV mutant strain. The mortality of zebrafish was recorded within 7 days after infection. The LD₅₀ value of the ΔnorV mutant (10^4.09 ± 10^3.03 CFU) was 87-fold higher than that of the wild-type strain (10^2.16 ± 10^1.37 CFU), indicating a significant reduction in the virulence of the ΔnorV mutant (P < 0.0001). Virulence was almost restored when the CΔnorV (10^2.75 ± 10^1.89 CFU) was used to infect zebrafish.

Nitric oxide is an important component of host defence against invading pathogenic bacteria [19, 25, 27, 36, 37]. It is likely to be encountered by bacteria in diverse environments. To overcome the deleterious effects of NO, bacteria have evolved multiple mechanisms to protect against NO stress, for example, detoxifying NO via the NorV [38]. In this study, we used SNP as NO donor and investigated the biological functions of NorV in A. hydrophila. Before entering the study, we evaluated the kinetics of NO release by SNP using Griess assay and found NO could be released continuously for more than 10 h (Additional file 2). Based on the releasing dynamic, SNP of 2.5 mM could produce a concentration of NO₂⁻ of about 10 μM in LB medium. Shimizu et al. [27] revealed that the NO₂⁻ concentration in the supernatants of infected RAW264.7 cells by E. coli could be up to nearly 20 μM after 10 h post-infection. Thus, it is possible that bacteria will have an opportunity to encounter relatively high amount of NO during infection. The SNP concentrations used in this study are, therefore, biologically relevant.

NorV has been known for the detoxification of NO under anaerobic, but not aerobic conditions [19, 20]. However, there is evidence that the norV promoter can also be activated by NO exposure during aerobic growth [39]. To determine whether the activation of NorV correlated with the presence or absence of oxygen, we examined its mRNA and protein expression under aerobic and anaerobic conditions. Our data demonstrated that the transcription of norV in A. hydrophila was regulated in a NO-dependent manner in both conditions, and NorV expression would be activated by NO exposure with or without oxygen. Surprisingly, however, NorV could only exert a protective growth effect by eliminating NO under anoxic conditions. Hence, these findings prompt us to explore whether and which physiological role NorV plays in the presence of oxygen in A. hydrophila.

Both environmental oxygen and NO signals are able to reprogram gene expression and to stimulate bacterial secretion systems, effector molecules, or toxins to promote survival and resist injury [36, 37, 40]. Extracellular proteins such as hemolysins, proteases and cytotoxins are belived to exhibit potential pathogenicity in Aeromonas spp. [41, 42]. In this study, we demonstrated for the first time that the norV gene plays important roles in the secretion of bacterial extracellular products. The activities of ECPs from the ΔnorV strain remained aerobically unaffected by NO but anaerobically decreased in a NO dose-dependent manner. This phenomenon leads us to speculate that NO can anaerobically inhibit the production of ECPs and NorV serves as a NO scavenger to minimize the inhibition effect of NO. Notably, however, the activities of ECPs in ΔnorV mutant were significantly lower than those in the wild-type strain even without exposure to NO, indicating that NorV could regulate the production of ECPs beyond depending on its nitric oxide reductase activity. To exclude the potential polar effect of norV disruption on the production of ECPs, we studied the transcriptional levels of both upstream (norR) and downstream (norW) genes of the norV deletion region. The data showed that the inactivation of norV did not affect the transcription of either norR or norW (Additional file 3), indicating no polar mutation had occurred. In A. hydrophila, type II secretion system (T2SS) has been known to be essential for the translocation of ECPs from the periplasm into the extracellular milieu [43, 44]. Thus, it is speculated that NorV might affect the secretion of extracellular proteins through T2SS. In this regard, it may be of interest to further investigate the relationship of norV and T2SS.

In some Gram-negative bacteria, T6SS is often involved in virulence-related mechanisms and environmental competitive fitness [45, 46]. Intriguingly, similar to the impact on ECPs, we found that NorV anaerobically contributed to Hcp production in a NO-dependent fashion. Compared to the wild-type, Hcp secretion in the ΔnorV mutant was higher under oxic conditions but lower under anoxic conditions, indicating that NorV is involved in Hcp secretion and the involvement effect might be strongly related to the presence of oxygen. Oxygen is a constantly changing environmental parameter in bacterial infections [47]. To adapt to the variable oxygen conditions, bacteria have to convert metabolic strategies [40]. A study from Babujee et al. [40] has demonstrated that oxygen limitation was associated to varying degrees with the Hcp production in Dickeya dadantii and Pectobacterium atrosepticum. Also, it should be noted that Hcp secretion in the wild type strain was increased in a NO dose-dependent manner but decreased in the ΔnorV mutant. This indicates that the promotion on Hcp secretion by NO may positively correlate with NorV, and the NO-dependent decrease of Hcp secretion in the ΔnorV mutant probably imply an indirect effect. Some bacteria have been reported to develop other NO defense mechanisms, including flavohemoglobin (Hmp) [48] and cytochrome c nitrite reductase (NrfA) [49] in addition to the NorV. However, we demonstrated that the inactivation of norV gene did not affect the transcription levels of hmp or nrfA (Additional file 4). We can, however, not exclude the possibility that the inactivation of norV may affect other unknown NO defense systems. Also, various classes of regulators sensitive to environmental cues have been demonstrated to specifically modulate the T6SS activity, for example, iron, σ⁵⁴-dependent activator proteins and surface association [50]. We could not determine whether these regulators may be involved in the Hcp secretion in A. hydrophila. Maybe future transcriptomic study will be helpful to explain the molecular basis of the altered Hcp secretion due to NorV.

In the present study, we also determined that norV gene had ability to confer a protective advantage for A. hydrophila in resisting predation by Tetrahymena and improving the bacterial survival within macrophages, and made an important contribution to bacterial virulence in zebrafish. NorV was confirmed to play an important role for the survival of EHEC within macrophages by eliminating NO produced by iNOS [27]. However, we believe the mechanism by which NorV increased A. hydrophila survival in macrophages cannot be due to its NO consumption activity. Some previous studies have indicated that NO could only be produced by macrophages after 8 h post-infection [27, 51], but in our study, A. hydrophila was almost cleared by cells within 3 h. Additional regulatory mechanisms may account for the contribution of norV in bacterial survival within macrophages.

In summary, our results reveal that norV gene has various effects on the virulence-associated traits of A. hydrophila. Regulation of these virulence traits in response to external conditions reflects that this bacterium has the ability to regulate its cellular activity in order to adapt to the environment in which it is growing.

All data generated or analysed during this study are included in this published article and its Additional files.

NorV:

nitric oxide reductase

NO:

nitric oxide

iNOS:

inducible nitric oxide synthase

SNP:

sodium nitroprusside

OD:

optical density

LB:

Luria–Bertani

Amp^r :

ampicillin resistance

Cm^r :

chloramphenicol resistance

PCR:

polymerase chain reaction

CFU:

colony forming unit

DMEM:

Dulbecco’s Modified Eagle’s Medium

FBS:

fetal bovine serum

LDH:

lactate dehydrogenase

MOI:

multiplicity of infection

PBS:

phosphate buffered saline

ECPs:

extracellular products

RBCs:

red blood cells

Hcp:

hemolysin co-regulated protein

TCA:

trichloroacetic acid

GroEL:

heat shock protein Hsp60

LD₅₀ :

median lethal dose

T2SS:

type II secretion system

T6SS:

type VI secretion system

The authors thank Dr Furqan Awan for editing the manuscript.

This study was funded by the Three New Aquatic Projects in Jiangsu Province (D2017-3-1), Independent Innovation Fund of Agricultural Science and Technology in Jiangsu Province (CX(17)2027, CX(18)2011), the National Nature Science Foundation of China (31372454) and Priority Academic Program Development of Jiangsu Higher Education Institutions (PAPD).

Authors and Affiliations

1. Joint International Research Laboratory of Animal Health and Food Safety, College of Veterinary Medicine, Nanjing Agricultural University, Nanjing, 210095, China

   Jin Liu, Yuhao Dong, Shuiyan Ma, Chengping Lu & Yongjie Liu

2. College of Animal Science and Technology, Jinling Institute of Technology, Nanjing, 211169, China

   Nannan Wang

Contributions

JL carried out most of the experiments described in the manuscript and wrote the article; YD, NW, SM and CL participated in the design of the study and performed the statistical analysis. YL provided expertise and conceived the study. All authors read and approved the final manuscript.

Corresponding author

Correspondence to Yongjie Liu.

Ethics approval and consent to participate

The animal experiment was performed in accordance with the animal welfare standards, complied with the guidelines of the Animal Welfare Council of China, and was approved by the Ethical Committee for Animal Experiments of Nanjing Agricultural University, China (approval number: SYXK(Su) 2017-0007).

Competing interests

The authors declare that they have no competing interests.

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