Histamine Produced by Gram-Negative Bacteria Impairs Neutrophil’s Antimicrobial Response by Engaging the Histamine 2 Receptor

We found that histamine (10−9 M) did not have any effect on the in vitro capture of Escherichia coli by neutrophils but accelerated its intracellular killing. In contrast, histamine (10−6 M) delayed the capture of Escherichia coli by neutrophils and reduced the amounts of pHrodo zymosan particles inside acidic mature phagosomes. Histamine acted through the H4R and the H2R, which are coupled to the Src family tyrosine kinases or the cAMP/protein kinase A pathway, respectively. The protein kinase A inhibitor H-89 abrogated the delay in bacterial capture induced by histamine (10−6 M) and the Src family tyrosine kinase inhibitor PP2 blocked histamine (10−9 M) induced acceleration of bacterial intracellular killing and tyrosine phosphorylation of proteins. To investigate the role of histamine in pathogenicity, we designed an Acinetobacter baumannii strain deficient in histamine production (hdc::TOPO). Galleria mellonella larvae inoculated with the wild-type Acinetobacter baumannii ATCC 17978 strain (1.1 × 105 CFU) died rapidly (100% death within 40 h) but not when inoculated with the Acinetobacter baumannii hdc::TOPO mutant (10% mortality). The concentration of histamine rose in the larval haemolymph upon inoculation of the wild type but not the Acinetobacter baumannii hdc::TOPO mutant, such concentration of histamine blocks the ability of hemocytes from Galleria mellonella to capture Candida albicans in vitro. Thus, bacteria-producing histamine, by maintaining high levels of histamine, may impair neutrophil phagocytosis by hijacking the H2R.

© 2022 The Author(s). Published by S. Karger AG, Basel

Introduction

Neutrophils are the most abundant white blood cells and constitute the first line of defense against bacterial and fungal pathogens [1]. These cells have developed a broad range of weapons to kill microorganisms, which include production of reactive oxygen species (ROS) and release of microbicidal granule constituents (degranulation) at the site of inflammation, in response to chemoattractants, proinflammatory cytokines, or bacterial motifs. Production of ROS and degranulation are also integral parts of phagocytosis, a complex process by which neutrophils (and other phagocytic cells) capture, engulf, and kill pathogens inside intracellular phagosomes. The capture of pathogens is facilitated by opsonization, a process by which microorganisms are coated with complement proteins or antibodies. In neutrophils, the main receptor binding complement-opsonized microorganisms is the β2 integrin Mac-1 [2].

Histamine is a major regulator of the immune response because most, if not all, immune cells respond to histamine through engagement of histamine receptors (H1R-H4R). Histamine is produced by the decarboxylation of histidine by histidine decarboxylases (HDCs) [3].

There is evidence in the literature which supports the view that neutrophils produce histamine at the site of inflammation. This is best exemplified in a study [3] showing that the mature 74 kDa form of HDC is not present in peripheral blood murine neutrophils, and the post-translational processing of the 53 kDa precursor form is only observed in neutrophils infiltrated into the mouse peritoneal cavity. Another study found that tracheobronchitis and pneumonia, caused by mycoplasma infection in mice, lead to biosynthesis of histamine by airways neutrophils, thereby contributing to lung inflammation [4]. Production of histamine by neutrophils is triggered by interaction with pathogens. Thus, neutrophils produce histamine in vitro when exposed to the Gram-negative bacterium Pseudomonas aeruginosa PAO1 strain [5] or the TLR4 ligand LPS [6, 7]. Similarly to human neutrophils, hemocytes (a population of innate immune cells in invertebrates that include phagocytic cells) from the tunicate Styela plicata produce histamine when exposed to different pathogen-associated molecular patterns [8]. This implies that histamine biosynthesis by phagocytic cells has been preserved through evolution from invertebrates to mammals thus demonstrating the fundamental role that the diamine plays in the regulation of the innate immune response of the host.

Production of histamine by neutrophils is intriguing and may imply autoregulation of neutrophil functions. This scenario is plausible as neutrophils express two histamine receptors, the H2R and the H4R [9]. The H4R and the H2R have a high and low affinity for histamine, respectively. Thus, the H4R and the H2R receptors are activated by nanomolar or micromolar concentrations of histamine, respectively [10]. The fact that neutrophils express two pharmacological distinct histamine receptors, with different affinities for histamine, may indicate that histamine has a dual role. Thus, depending on its concentration, histamine could either activate inflammatory functions of neutrophils (by engaging the H4R) to facilitate the killing of microorganisms or impair inflammatory functions (by engaging the H2R) to reverse and resolve the inflammatory process.

Neutrophils are not the only source of histamine during periods of infection. Indeed, it was shown that acute exacerbations of chronic bronchitis, cystic fibrosis, and pneumonia are associated with Gram-negative bacteria synthesizing histamine. Thus, Pseudomonas aeruginosa, a Gram-negative bacterium that is also a significant cystic fibrosis pathogen, as well as Branhamella catarrhalis and Haemophilus parainfluenzae synthesize clinically important concentrations of histamine [11].

It is not known why some Gram-negative bacteria produce histamine. Bacteria-derived histamine could represent a previously unappreciated evolutionarily conserved molecular dialog between host and pathogen, whereby production of histamine would regulate neutrophil phagocytosis and inflammatory functions to the advantage of the bacteria. In this study, we aimed to evaluate the role of both the H4R and H2R receptors in the capture and killing of bacteria by neutrophils. We also investigated the contribution of histamine produced by the Gram-negative bacteria Acinetobacter baumannii (A. baumannii) for pathogenicity in the Galleria mellonella (G. mellonella) larvae model of infection. We propose a model in which the H4R and H2R have opposite effects in terms of regulation of bacterial capture and killing by neutrophils and how histamine produced by bacteria could hijack the neutrophil response.

Materials

Histamine and famotidine (ref: F6889) were purchased from Sigma-Aldrich/Merck. Ficoll-Hypaque was from GE Healthcare/Cytiva and Dextran 500 from Pharmacosmos (Denmark). The H4R antagonist JNJ 7777120 (ref: ab144405) was purchased from Abcam (UK). The PCR purification kit and the MiniPrep kit for plasmid isolation were from QiAgen (Germany). Zero BluntTM TOPOTM PCR cloning Kit, with pCRTM-Blunt II-TOPOTM Vector, One shotTM TOP10 chemically competent E. coli, and pHrodo Red Zymosan A particles were purchased from ThermoFischer (UK).

The following antibodies were from cell signaling: the secondary HRP-conjugated anti-mouse or anti-rabbit antibodies (7074S and 7076S) and the anti-MMP-9 Ab (Ref: 3852S). The rabbit anti-VASP Ab (Ref: ab 229624) was from Abcam (Cambridge, UK); the anti-phosphotyrosine (Ref: 05-321X, clone 4G10) was from Millipore (UK). Forskolin (Ref: F 6886), IBMX (Ref: 15879), gentamicin, PP2, and SU6656 were purchased from Merck. The histamine ELISA kit was from IBL International GMBH (Hamburg, Germany). Histamine (Ref: H7125), N-formyl-methionyl-leucyl-phenylalanine (fMLP) (Ref: F3506), human lactoferrin (Ref: L0520), and anti-lactoferrin Abs (ref: L3262) were from Sigma/Aldrich/Merck. The protease inhibitor tablets were from Roche (Germany). The MACSxpress whole blood neutrophil isolation kit (Ref: 130-104-434) was from Miltenyi Biotec (Bergisch Gladbach, Germany). Protein assays were performed using the Bio-Rad (CA, USA) solutions and protocol (Ref: 500-0114).

MethodsIsolation of Human Neutrophils

Venous blood was collected from healthy donors by venous puncture in vacutainer EDTA blood collecting tubes. For the phagocytosis studies, neutrophils were isolated from the blood using the Dextran sedimentation and centrifugation through Ficoll-Hypaque [12]. For killing and capture assays, the cells (97% purity) were resuspended in RPMI medium supplemented with 20 mM HEPES; pH 7.4 (modified RPMI) at a concentration of 107 cells/mL.

For the signaling studies, neutrophils were purified using the MACSxpress whole blood neutrophil isolation kit by following the instructions of the manufacturer. The cells were resuspended in HBSS medium supplemented with 1 mM MgCl2, 1 mM CaCl2, and 20 mM Hepes, pH 7.4 (modified HBSS). Cells were either pretreated with the H4R antagonist JNJ 7777120 or the H2R antagonist famotidine prior to stimulation with histamine.

Cell Culture

Undifferentiated PLB-985 cells were grown at 37°C in an atmosphere of 5% CO2 in RPMI medium supplemented with 10% FCS to a density of 5 × 105 cells/mL. Differentiation into neutrophil-like cells was carried out by culturing undifferentiated PLB-985 cells for 5 days in the RPMI medium supplemented with 5% FCS and 1.25% DMSO [13]. Cells were then collected by centrifugation (190 g, 10 min), washed in HBSS medium, and finally resuspended at a density of ∼1 × 106 cells/mL in modified HBSS medium.

Neutrophil Capture and Killing Assays

These assays were adapted from[14]. E. coli was inoculated in Luria Bertani (LB) broth and incubated overnight at 37°C in a flask placed in an orbital shaker. Bacteria were then diluted 1/10 and grown further for 1.5 h to reach the exponential phase. Bacterial concentrations were adjusted to 107 CFU/mL. Bacteria in LB medium were spun down (2,500 g, 10 min), washed once with modified RPMI medium (RPMI medium supplemented with 20 mM Hepes pH 7.4), and then resuspended in modified RPMI medium containing 10% human serum (a mixture of five different serum samples). After 15 min, bacteria were spun down, washed with modified RPMI medium, and resuspended in the same buffer at a density of 107 CFU/mL.

An equal volume of neutrophils (107 cells/mL) and bacteria (107 cells/mL) (1 mL of each) were mixed together in 15 mL conical tubes. After 10 or 30 min incubation at 37°C under shaking condition, 6 mL of cold-modified RPMI medium was added and the tubes were placed on ice. The tubes were spun (190 g, 10 min) in a cold centrifuge to pellet the neutrophils. The supernatant was collected and the number of E. coli remaining in the supernatant was estimated by serially diluting and colony counting on LB-agar plates. To this end, 20 μL of the serial diluted supernatants (in phosphate buffered saline, PBS) were spread onto LB agar plates (each plate is divided in four equal sections) and the plates were put in an incubator for 18 h at 30°C. The number of colonies formed on the plates was then counted and concentrations of bacteria were calculated by taking into account the dilution factors. The number of bacteria at time 0 (before addition of neutrophils) and time 30 min were also determined. Final concentrations of bacteria (CFU/mL) are corrected for bacterial growth. To test the effect of histamine on E. coli capture, the neutrophils (107 cells/mL) were preincubated for 5 min at 37°C with histamine (10−9 M or 10−6 M) before addition of the bacterial suspension. When the protein kinase A (PKA) inhibitor H-89 (10 μM) was used, it was added 20 min prior to the addition of histamine (see above).

For intracellular killing assays, equal volumes of neutrophils (107 cells/mL) and bacteria (107 cells/mL) (1 mL of each) were mixed together in 15 mL conical tubes, which were placed on a shaker at 37°C. After 10 min or 30 min incubation, 6 mL of cold-modified RPMI medium was added. The tubes were spun (190 g, 10 min) in a cold centrifuge to pellet the neutrophils. The supernatants were discarded and the pellet washed three times with ice-cold-modified RPMI. The pellets were then resuspended in 1 mL of ice-cold-modified RPMI and saponin (0.1%) was added. After vortexing to disrupt neutrophils, the supernatants were diluted in PBS and the number of colonies were then measured as described above. The Src family tyrosine kinase inhibitors PP2 (5 μM) or SU6656 (5 μM) were added 20 min prior to the addition of histamine (see above).

For the gentamicin protection assay [15], neutrophils (107 cells/mL) and bacteria (107 cells/mL) (1 mL of each) were mixed in 15 mL conical tubes which were placed on a shaker at 37°C. After 10 min, 10 mL of cold-modified RPMI medium was added and the tubes were put on ice. The tubes were subjected to centrifugation (190 g, 10 min). The pellets were recovered, washed once with 5 mL cold-modified RPMI, and resuspended in the same medium. Thereafter, gentamicin (5 μg/mL) was added and the samples split into two. One sample received histamine (10−9 M), the other sample only vehicle (H2O). After 10 min or 30 min incubation, the cell suspension was subjected to centrifugation (190 g, 10 min), the pellet washed once with 10 mL PBS, and then resuspended in 1 mL PBS. Saponin was added (0.1%) followed by vortexing, and finally the number of colonies were measured as described above.

For the measurement of pHrodo zymosan particles capture by neutrophils, the following protocol was used: 100 μL of a neutrophil solution (106/mL) in modified HBSS was placed in 96-well plates coated with fibrinogen [12], together with 100 μL of serum-opsonized red pHrodo zymosan A particles (as recommended by the manufacturer). TNF-α (20 ng/mL) and histamine (10−9 M or 10−6 M) were added or not to the wells, after which the plates were subjected to centrifugation (1 min, 190 g) to synchronize phagocytosis. The plates were then placed in the microplate reader at 37°C and the fluorescence was read over time (excitation 560 nm, emission 585 nm). Autofluorescence was substracted from each assay values. All assays were carried out in triplicates.

Western Blot Analysis

Neutrophils, or differentiated PLB-985 cells, resuspended in modified HBSS medium (1 × 106 cells in 1 mL), were pretreated or not with PP2 (5 μM), H-89 (10 μM), JNJ 7777120 (10−8–10−5 M) or famotidine (10−8–10−5 M) for 20 min at 37°C, after which histamine (10−9–10−5 M) was added to the samples. After 1 min, the reaction was stopped by adding 0.5 mL cold-modified HBSS and the tubes were put on ice. Controls cells only received vehicle (0.01% DMSO). The tubes were spun-down in a cold centrifuge (190 g, 10 min), and the supernatants were discarded. The pellets were lysed by adding 400 μL of ice-cold lysis buffer (100 mM Tris-HCl, pH 7.5, 1% Triton X-100, 5 mM EDTA, 5 mM EGTA, 50 mM NaCl, 5 mM NaF, 1 mM Na3VO4, and a protease inhibitor tablet). Cell lysates were clarified by centrifugation (10 min, 15,000 g) at 4°C, and 100 μL of 5X Laemmli buffer containing 1 mM DTT was added to the clarified supernatants. The samples (40 μg) were subjected to 8% SDS-PAGE and transferred to nitrocellulose membranes. The membranes were extensively washed under a running tap of distilled water to remove any traces of acrylamide and were then stained with Ponceau S to verify equal loading in each well prior to immunoblotting. Next, the membranes were blocked for 1 h in TBS buffer, supplemented with 0.2% Tween 20 (TBS-T) and 5% skimmed milk, and then incubated overnight at 4°C with an anti-VASP Ab (1 μg/mL dilution). After three 5 min washes with TBS-T buffer, the membranes were subsequently incubated for 1 h with goat peroxidase-conjugated anti-rabbit IgGs (1:2,500). The blots were again washed with TBS-T and Ab binding was visualized by enhanced chemiluminescence (ECL) using the GBOX ChemiXRQ. The ECL solution was prepared by mixing 6 mL of 0.1 M Tris pH 8.5, with 60 μL of 125 mM luminol (5-amino-2,3-dihydro-1,4-ptalazinedione) and 30 μL of 68 mM p-coumaric acid, and 3 μL of 30% H2O2 solution. Stocks of luminol solution and p-coumaric acid (all in DMSO) were kept at −20°C.

For the detection of tyrosine phosphorylated proteins, the cells were resuspended in HBSS-M medium at a density of 0.2 × 106/mL and then treated as described above. The cells (1 × 106 in 5 mL) were incubated in 15 mL tubes and the reactions stopped by adding 10 mL of cold HBSS-M. The cell pellets recovered after spinning down the tubes at 190 g for 10 min, were lysed with 0.4 mL of ice-cold lysis buffer (100 mM Tris-HCl, pH 7.5, 1% Triton X-100, 0.1% SDS, 5 mM EDTA, 5 mM EGTA, 150 mM NaCl, 5 mM NaF, 2 mM Na3VO4, and a protease inhibitor tablet). Hundred microliter of 5 × Laemmli buffer containing 1 mM DTT was added to the clarified samples. The samples (40 μg) were subjected to 10% SDS-PAGE and transferred to nitrocellulose membranes. The membranes were stained with Ponceau S to verify equal loading in each well prior to immunoblotting. The membranes were blocked for 1 h in TBS-T buffer and 5% BSA (fraction V) and then incubated overnight at 4°C with an anti-phospho-tyrosine Ab (1 μg/mL dilution). After three 5 min washes with TBS-T buffer, the membranes were subsequently incubated for 1 h with goat peroxidase-conjugated anti-mouse IgGs (1:2,500). The blots were again washed and antibody binding was visualized by ECL as described above.

For the detection of MMP-9 and lactoferrin, neutrophils resuspended in modified RPMI at a density of ∼1 × 107/mL, were pretreated or not with histamine (10−6 M) for 5 min at 37°C. Thereafter, opsonized E. coli cells (1 × 107/mL) were added (0.5 mL of neutrophil suspension and 0.5 mL of bacterial suspension) for different time periods. The reaction was stopped by adding 0.5 mL of ice-cold-modified RPMI and putting the tubes on ice. The tubes were then spun (2,500 g, 10 min) in a refrigerated centrifuge, the supernatants (free of bacteria and neutrophils) collected and split into two. In one fraction (0.5 mL), 150 μL of 5 × Laemmli buffer containing 1 mM DTT was added, followed by 5 min boiling of the samples. Detection of MMP-9 was then carried out by Western blot analysis, as described above, using an anti-MMP-9 antibody. The other fraction is used for the determination of lactoferrin concentration using an ELISA [16].

Design of the A. baumannii Hdc-Deficient Strain

The protocol by Aranda et al. [17] was followed to design a mutant deficient in histamine production. A 500-bp internal fragment of the A. baumannii ATCC 17978 hdc gene (homology region) was designed by PCR using the following primers: FW: GAGGATGATCGACAAAAGGTA, REV: TTGTGGTGATTGGAAAGACT. The PCR product was purified by using the QiA quick PCR purification kit (Qiagen). After purification and quantification, the 500 bp PCR product was cloned into the pCR-blunt-TOPO plasmid, by following the protocol provided by the manufacturer (ThermoFischer, UK). Insertion of the plasmid into one Shot Top10 chemically competent E. coli was carried out by using the heat shock method. After transformation, 100 μL of bacterial suspension was placed on LB-agar plates containing kanamycin (50 mg/mL). After 18 h, colonies were picked on plates and grown in LB medium containing kanamycin (50 mg/mL). Glycerol stocks were then prepared and frozen at −80°C. Plasmids preparations were also carried out using the QiAPrep Spin Miniprep Kit (Qiagen). Thereafter, purified plasmids were introduced into competent A. baumannii ATCC 17978 strain by electroporation using the gene Pulser X cell electroporation systems (Bio-rad). Recombinant A. baumannii hdc::TOPO mutants, with a disrupted hdc gene, were selected on plates containing kanamycin (50 mg/mL) and grown overnight in LB medium supplemented with kanamycin (50 mg/mL). Genomic DNA was extracted from these kanamycin-resistant colonies and PCR was carried out to verify that the correct gene insertion had been obtained. To this end, two sets of primers were used for the generation of the amplicons. Set 1: FW: AATACGACTCACTATAGGG (T7 primer), Rev: CCATCATAAGGC­ATACGAC. Set 2: FW: AATACGACTCACTATAGGG (T7 primer), Rev: CATCATAAGGCATACGACAA.

The amplicons obtained by PCR were separated on 1% agarose gel and visualized. Their sizes were estimated in reference to molecular weight standards. The amplicons were further sequenced using the primers provided by the manufacturer in the kit.

Determination of Histamine Concentration

Cultures of overnight grown A. baumannii ATCC 17978 or hdc::TOPO were adjusted to a OD value of 0.2 at 600 nm. An aliquot (10 μL) of the bacterial suspension was added to a 50 mL conical tube containing 10 mL of LB medium (or LB medium and kanamycin for hdc::TOPO) without or with histidine (10−3 M). The 10 mL suspensions are then transferred to a 250 mL conical flask. The flasks are put in an orbital shaker at 37°C. After 18 h, an aliquot (1 mL) of each bacterial suspensions is collected into 1.5 mL Eppendorf tubes and spun at 2,500 g for 10 min. Supernatants, free of bacteria, were collected and used for quantification of histamine using an ELISA kit by following the protocol provided by the manufacturer.

Measurement of Bacterial Growth

A. baumannii wild-type (WT) or hdc::TOPO mutant strains were inoculated in LB medium and grown overnight in a glass flask under rotation at 37°C. Bacterial suspensions were diluted 1/100 in the LB broth (LB broth and kanamycin for hdc::TOPO mutant). The suspension for each strain was then dispatched into two flasks. Histidine (10−3 M final), was added in one flask, and vehicle (H2O) to the control flask. The flasks were shaken at 37°C and, after each hour, an aliquot (1 mL) is collected, transferred to a plastic cuvette, and the optical density at 600 nm is read. LB broth served as a reference. For later time points, aliquots were diluted in LB medium prior to reading OD values.

G. mellonella Larvae Killing Assay

We used G. mellonella larvae with a weight between 250 and 350 mg in all assays. Ten randomly chosen larvae were used for each group. A. baumannii WT or hdc::TOPO mutant strains, in their exponential phase, were collected, washed in PBS, and then diluted to the indicated cell density, as determined by the optical density at 600 nm. Ten microliter of the inoculum was injected into the hemocoel of each larva through the last left proleg [18]. Bacterial colony counts on LB agar plates were used to confirm all inocula. Larvae were considered dead when they displayed no movement in response to puncture with a micro-needle.

Hemocytes Preparation and C. albicans Capture Assays

Insect hemocytes were harvested from ten larvae of G. mellonella. Larval hemolymph was bled into 9 mL of insect physiological saline (IPS) containing 10 mM EDTA and 30 mM sodium citrate as anticoagulants. Hemocytes were pelleted by centrifugation (500 g, 5 min) at room temperature. The cells were washed once with IPS and finally resuspended in PBS containing 5 mM glucose [18].

C. albicans cells were opsonized using cell-free haemolymph diluted 1/10 in IPS. Phagocytosis was measured by incubating 1 × 107 hemocytes with 2 × 106C. albicans cells in a rapidly stirred chamber of a Clark type oxygen electrode at 37°C. Every 10 min, an aliquot was taken and the cell suspension was subjected to centrifugation (500 g, 10 min) to pellet the hemocyte population. An aliquot of the supernatant was diluted in YEPD broth and placed onto YEPD agar plates. After 18 h, the number of colonies was enumerated and the concentration of C. albicans in the supernatant was calculated by taking into account the dilution factor.

Statistical Analysis

In Figure 1, a paired Student’s t test was used to assess statistical difference between control cells and cells stimulated with histamine 10−6 M or histamine 10−9 M (*p < 0.05). In Figure 7, a Mantel-Cox test was used to compare the survival of G. mellonella treated with A. baumannii ATCC 17978 versus hdc::TOPO mutant. The statistical significance is given in Figure 7b.

Fig. 1.

Histamine regulates the capture and killing of E. coli by neutrophils. a (left panel) Neutrophils (1 × 107/mL) were preincubated without (dashed line) or with histamine 10−9 M (solid line) for 5 min. Thereafter, serum-opsonized E. coli cells (1 × 107/mL) were added to the neutrophil preparation (1:1 ratio). After 10–30 min, the neutrophil/E. coli mixture was subjected to low speed centrifugation (190 g, 10 min) to pellet the neutrophils, but not the bacteria, and the supernatants were collected. The number of E. coli cells remaining in the supernatants was determined by colony counting on LB-agar plates. The data represent mean values ± SEM of three experiments using neutrophils from three different blood donors. a (middle panel) Neutrophils (1 × 107/mL) were preincubated without (dashed line) or with histamine 10−6 M (solid line) for 5 min. Thereafter, the number of E. coli cells remaining in the supernatants, after pelleting neutrophils, was determined as described above. The data represent mean values ± SEM of seven experiments using neutrophils from seven different blood donors. a (right panel) Neutrophils (1 × 107/mL) were pretreated with H-89 (10 μM, 20 min, solid square) or not pretreated with the PKA inhibitor (dashed line, and round circle) after which the cells were incubated or not with histamine (10−6 M) for 10–30 min. Thereafter, the number of E. coli remaining in the supernatant, free of neutrophils, was counted as described above. The data represent mean values ± SD of one experiment (out of two). b (left panel) Neutrophils (1 × 107/mL) were preincubated without (dashed line) or with (solid line) histamine (10−9 M) for 5 min. Thereafter, serum-opsonized E. coli cells (1 × 107/mL) were added (1:1 ratio). After 10–30 min, the neutrophil/E. coli mixture was subjected to low speed centrifugation (190 g, 10 min), and the recovered pellet was washed with PBS. The pellet was then resuspended in PBS and the number of E. coli cells was determined by colony counting. The data represent mean values ± SEM of five experiments using neutrophils isolated from five different blood donors. b (middle panel) Neutrophils (1 × 107/mL) were incubated for 10 min with opsonized E. coli (1 × 107/mL) after which the mixture was subjected to low speed centrifugation (190 g, 10 min). The pellets were washed with PBS, and then resuspended in modified RPMI containing gentamicin (5 mg/mL), in the absence (dashed lines), or presence (full line) of histamine (10−9 M). After 10 or 30 min incubation, the mixture was spun down, and the washed pellet resuspended in 1 mL PBS. The amount of E. coli cells associated with the pellet was then measured by colony counting. The data are mean values ± SEM of one representative experiment (out of two). Seven aliquots per assay were counted on LB-agar plates. b (right panel) Neutrophils (1 × 107/mL) were pretreated with either PP2 (5 μM, 20 min, triangle) or SU6656 (5 μM, 20 min, square) after which the cells were incubated or not with histamine (10−9 M) for 5 min. Thereafter, serum-opsonized E. coli cells (1 × 107/mL) were added (1:1 ratio). After 10–30 min, the neutrophil/E. coli mixture was subjected to low speed centrifugation, and the amount of E. coli associated with the pellet was counted as described in b, left panel. One experiment is shown (out of two). c Neutrophils (105) were incubated on 96-well plates coated with fibrinogen in the absence (gray circles) or presence of TNF-α (20 ng/mL) (black square), or in the presence of TNF-α (20 ng/mL) and histamine (10−9 M) (black triangles) or TNF-α (20 ng/mL) and histamine (10−6 M) (black circles). Serum-opsonized pHrodo zymosan A particles were added to each wells. The fluorescence (585 nm) was read over time. The data represent mean values ± SD of triplicates in one representative experiment (out of two). d Neutrophils (1 × 107/mL) were preincubated without or with histamine (10−6 M) for 5 min. Thereafter, serum-opsonized E. coli cells (1 × 107/mL) were added to the neutrophil preparation (1:1 ratio). After 10–30 min, the neutrophil/E. coli mixture was subjected to low speed centrifugation (190 g, 10 min) to pellet the neutrophils, and the supernatants were collected. The level of MMP-9 in the supernatants was measured by Western blot analysis. The top panel depicts a representative Western blot; the position of pro-MMP-9 is indicated by an arrow on the left hand side. The graph represents the accumulation of lactoferrin in the supernatants from neutrophils pretreated (triangle) or not (square) with histamine (10−6 M), and exposed to E. coli cells. As a control, the release of lactoferrin from neutrophils not exposed to E. coli is shown (dotted line). The data represent mean values ± SEM of one representative experiment (out of two) performed in triplicates (for the lactoferrin data).

/WebMaterial/ShowPic/1446170Densitometry Analysis

The densitometric analysis of the bands from Western blots was determined using the software Image J.JS.

Results

To investigate a possible contribution of the H4R and/or the H2R in the capture and/or killing of bacteria by neutrophils, freshly isolated human neutrophils were incubated with serum-opsonized E. coli, either in the absence or presence of histamine. Two concentrations of histamine were used: 10−9 M (to engage the H4R) or histamine 10−6 M (to engage both the H2R and the H4R) [10]. After 10–30 min incubation, the mixture was subjected to centrifugation (190 g, 5 min) to pellet the neutrophils but not the bacteria. Then, the amount of E. coli remaining in the extracellular medium was determined by colony counting on LB-agar plates (extracellular bacteria). We found that the kinetics of E. coli capture by neutrophils were identical between nonstimulated control cells and neutrophils stimulated with histamine (10−9 M) (Fig. 1a, left panel). In contrast, in the presence of a high dose of histamine (10−6 M), we observed a significant delay in the capture of E. coli by neutrophils (Fig. 1a, middle panel). This is illustrated by the fact that the time required by neutrophils to capture half of the amount of bacteria added at time zero (normalized to one unit) was 8 min in the absence of histamine and 18 min in the presence of histamine (10−6 M). Thus, the low affinity H2R receptor, but not the H4R, negatively regulates pathogen capture by neutrophils. We also found that a pretreatment of neutrophils with the PKA inhibitor H-89 (10 μM) totally prevented histamine (10−6 M) to block E. coli capture (Fig. 1a, right panel).

We next investigated the possible role of the H4R in intracellular killing of bacteria. To test this, the neutrophil/E. coli mixture was incubated in the absence or presence of histamine (10−9 M) for 10–30 min. The mixture was then spun down (190 g, 10 min); the neutrophils were disrupted by the addition of saponin, after which the amount of E. coli associated with pelleted neutrophils was measured. A 10 min incubation time is optimum for the loading of neutrophils with E. coli [14]. After 10 min, the amount of E. coli associated with neutrophils declined thus illustrating that the captured pathogens are internalized and killed in phagosomes fused with granules containing antimicrobials. Interestingly, we found that the amount of E. coli associated with neutrophils was significantly (p < 0.05) lower when neutrophils were exposed to histamine (10−9 M) (Fig. 1b, left panel). Since histamine (10−9 M) had no effect on the capture of E. coli by neutrophils, and taking the fact that the H2R is not activated by nanomolar concentrations of histamine, our results indicate that engagement of the H4R leads to augmented intracellular killing of bacteria.

We also carried out gentamicin protection assays [15] to further prove the role of the H4R in the regulation of intracellular killing of microorganisms by neutrophils. The rationale for performing this assay is that gentamicin kills bacteria bound to the membrane surface of neutrophils but not internalized bacteria. To this end, neutrophils were incubated with E. coli for 10 min, after which the neutrophils were spun down, washed, and resuspended in RPMI medium containing gentamicin (5 μg/mL). The cell suspension was then split into two tubes. In one tube, histamine (10−9 M) was added. In the other tube, no histamine was added (control cells). Thereafter, the amount of E. coli associated with pelleted neutrophils was measured over time. We found that addition of histamine (10−9 M) accelerated the speed of E. coli killing by neutrophils. This is evidenced by the fact that control neutrophils kill half of the captured microorganisms in 16 min. In contrast, to accomplish the same task, neutrophils exposed to histamine (10−9 M) require 10 min (Fig. 1b, middle panel). When neutrophils were preincubated with the Src family tyrosine kinase inhibitors PP2 (pyrazolo-pyrimidie structure) or SU6656 (indolinone analog), acceleration of E. coli killing induced by histamine (10−9 M) was abolished (Fig. 1b, right panel).

We also measured the capture of pHrodo zymosan particles by adherent neutrophils. The rationale for using this pHrodo-based system is that it measures phagocytic activity based on acidification of particles as they are ingested. This means that fluorescence is emitted only when the particles are engulfed in mature acidic phagosomes. In neutrophils, after 10 min exposure to particles, the cells exhibit a slow phase of acidification which does not reverse by 1 h [19]. We found that the intensity of fluorescence was augmented with time in control neutrophils (gray circles) and reached a plateau at around 1 h. Stimulation of neutrophils with TNF-α augmented the number of particles inside acidic phagosome (black square) which is an indicative of activation of Mac-1-dependent capture of the particles. Pretreatment of neutrophils with histamine (10−9 M) did not modify the fluorescence intensity over time in cells stimulated with TNF-α. However, a pretreatment of neutrophils with histamine (10−6 M) reduced significantly the number of particles inside acidic phagosomes as evidenced by a decrease in fluorescence emission over time in TNF-α stimulated cells (Fig. 1c). In parallel, we investigated whether histamine (10−6 M) regulated neutrophil degranulation in response to E. coli. To this end, neutrophils and opsonized E. coli were incubated for 10–30 min (as described above) after which the amount of MMP-9 (a marker for specific and gelatinase granules) and lactoferrin (a marker for specific granules) in bacteria- and neutrophil-free supernatants were measured by Western blot analysis, or ELISA, respectively. By Western blot analysis, using an anti-MMP-9 Ab, we detected a protein in the supernatant of Mw ∼105 kDa which corresponds to the monomeric form of pro-MMP-9 [20]. As expected, we found low amounts of granule markers when neutrophils were not exposed to opsonized E. coli (basal conditions) (Fig. 1d). Addition of opsonized E. coli to neutrophils led to a time-dependent increase in the amount of both pro-MMP-9 and lactoferrin in the extracellular medium. However, a pretreatment of the cells with histamine (10−6 M) had no effect on E. coli-induced degranulation (Fig. 1d). This control experiment confirmed that histamine (10−6 M) delayed bacterial capture by neutrophils as histamine did not inhibit the release of microbicidal substances contained in neutrophil granules (which could have explained the augmented level of viable E. coli).

Together, our results demonstrate that in human neutrophils, the H2R and the H4R have two different functions in terms of capture and killing of microorganisms. The H2R negatively regulates the capture of E. coli by neutrophils, whereas activation of the H4R augments intracellular killing of pathogens.

The H2R, but Not the H4R, Is Coupled to the cAMP/PKA Pathway

We next investigated the signaling pathways activated by the H2R and the H4R in human neutrophils, as well as in PLB-985 cells differentiated into neutrophil-like cells. We used differentiated PLB-985 cells because these cells have remarkable similarities to human neutrophils in terms of signaling and functions [13, 21]. We investigated whether the H2R and/or the H4R were coupled to the production of cAMP and activation of PKA. To this end, differentiated PLB-985 cells (Fig. 2a), or human neutrophils (Fig. 2b), were incubated with histamine (10−9–10−5 M). After 1 min, the cells were lysed, cell lysates were separated on 8% SDS-PAGE, and proteins transferred to a nitrocellulose membrane. To assess cAMP production indirectly, we measured by Western blot the phosphorylation of the cytoskeletal protein Vasodilator-stimulated phosphoprotein (VASP) on Ser 157. In human neutrophils, phosphorylation of VASP occurs in response to fMLP, IL-8, or leukotriene B4. Such ligand-induced VASP phosphorylation is blocked by the PKA inhibitor H-89 and the adenyly cyclase inhibitor SQ22536. Thus, VASP phosphorylation on Ser 157 is catalyzed by the cAMP-dependent PKA [22]. Of interest, phosphorylation of VASP on Ser 157 leads to a change in electrophoretic mobility. Thus, it is easy to separate and detect both the Ser 157 phosphorylated and non-phosphorylated forms of VASP by Western blot analysis using an anti-VASP antibody [22]. We found that stimulation of differentiated PLB-985 cells (Fig. 2a), or human neutrophils (Fig. 2b, left panel), with high (10−6–10−5 M), but not low (10−9–10−7 M) doses of histamine, led to a significant increase in basal phosphorylation of VASP. With the highest concentration of histamine (10−5 M), we obtained 3.6- and 5.2-fold increases (over control cells) of the Ser 157 VASP/total VASP ratio in differentiated PLB-985 cells and neutrophils, respectively. Equal amount of proteins (∼30 μg) were loaded in each well of the gels. This was confirmed by quantifying the amount of total VASP (taken as loading controls) in each lane. To further ensure that VASP is phosphorylated in response to histamine, we normalized the densitometry values obtained for the Ser 157 VASP signal to the densitometry values of the corresponding total VASP (see above) [22].

Fig. 2.

Dose-dependent effect of histamine on VASP phosphorylation on Ser 157 in neutrophils and differentiated PLB-985 cells. a PLB-985 cells differentiated into neutrophil-like cells, were stimulated with different concentrations of histamine (10−9–10−5 M), or a combination of FK (10−5 M) plus IBMX (10−5 M). After 1 min, the cells were lysed and solubilized in Laemelli buffer. Equal amounts of proteins (30 μg) were loaded in each well; proteins were separated by 8% SDS-PAGE, transferred to a nitrocellulose membrane and immunoblotted with an anti-VASP pAb. The top panel depicts a representative Western blot; the positions of pS157-VASP and VASP are indicated on the right hand side of the blot by arrows. The densitometry value of total VASP (used as a loading control) for each sample is indicated on the top of the representative blot. The diagram illustrates densitometric analysis of the pS157-VASP/total VASP ratio. The data represent means ± SD of 3 independent experiments. b (left panel) Neutrophils (1 × 106) were stimulated with histamine (10−9–10−5 M) after which the pS157-VASP/total VASP ratio was determined as described in a. The panel depicts a representative Western blot (out of two experiments). The densitometry value of total VASP (used as a loading control) for each sample is indicated on the top of the representative blot. The pS157-VASP/total VASP ratio is also given. The amount of pS157-VASP/total VASP in control cells has been normalized to one. b (right panel) As a control, neutrophils were stimulated with IBMX for 30 s or 60 s after which the ration of pS157-VASP/total VASP was determined as described above. The densitometry value of total VASP (used as a loading control) for each sample is indicated on the top of the representative blot. The pS157-VASP/total VASP ratio is also given. A representative experiment out of two is shown. FK, forskolin.

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As a control, we used IBMX and forskolin, which are commonly used to augment intracellular level of cAMP. We found that stimulation of differentiated PLB-985 cells with forskolin (10−5 M) and IBMX (10−5 M) (Fig. 2a), or human neutrophils with IBMX (10−5 M) (Fig. 2b, right panel), led to phosphorylation of VASP on Ser 157, similarly to what we found with histamine (10−6–10− 5 M).

To confirm further that the H2R, but not the H4R, is coupled to the cAMP/PKA pathway, we made use of famotidine and JNJ 7777120, which are antagonists of the H2R and the H4R, respectively. We found that the phosphorylation of VASP on Ser 157 induced by histamine (10−5 M) was blocked in a dose-dependent manner by a pretreatment of PLB-985 cells (Fig. 3a) or neutrophils (Fig. 3b) with the H2R antagonist famotidine (10−7–10−5 M). In contrast, pretreatment of these cells with the H4R antagonist JNJ 7777120 (10−7–10−5 M) did not. All together, these results demonstrate that the H2R, but not the H4R, is coupled to the cAMP/PKA pathway.

Fig. 3.

The H2R antagonist famotidine, but not the H4R antagonist JNJ777120, blocks histamine-induced phosphorylation of VASP on Ser 157. a PLB-985 cells differentiated into neutrophil-like cells, were pretreated for 20 min with either Fam (10−7–10−5 M, left panel) or JNJ 7777120 (JNJ, 10−7–10−5 M, right panel). Thereafter, the cells were stimulated with histamine (10−5 M) or a combination of FK (10−5 M) plus IBMX (10−5 M). After 1 min, the cells were lysed and the ratio of pS157-VASP/total VASP was determined as described in the legend to Figure 2. The top panels depict a representative Western blot. The diagram illustrates densitometric analysis of the pS157-VASP/total VASP ratio. The data represent means ± SD of 3 independent experiments. The densitometry value of total VASP (used as a loading control) for each sample is indicated on the top of the representative blot. b Neutrophils were pretreated for 20 min with either Fam (10−7–10−5 M, left panel) or JNJ 7777120 (10−7–10−5 M, right panel). Thereafter, the cells were stimulated with histamine (10−5 M) after which the pS157-VASP/total VASP ratio was determined as described above. The Western blot shown is representative of two experiments. The densitometry value of total VASP (used as a loading control) for each sample is indicated on the top of the representative blot. The pS157-VASP/total VASP ratio is also indicated on the top of the blot. The data have also been normalized to the amount of pS157-VASP/total VASP in control cells (taken as one). FK, forskolin; Fam, famotidine.

/WebMaterial/ShowPic/1446166The H4R, but Not the H2R, Is Coupled to the Src Tyrosine Kinase Pathway

N-formulated peptides, such as fMLP, are potent agonists of neutrophil responses implicated in host defense [23]. Stimulation of neutrophils with fMLP triggers a rapid activation of tyrosine kinases of the Src family as well as Syk [23-25], such kinases are indispensable for the activation of inflammatory functions required for the intracellular killing of microorganisms. We next compared the pattern of tyrosine phosphorylated proteins in response to fMLP and histamine. We detected tyrosine phosphorylation of proteins in differentiated PLB-985 cells in response to low doses (10−9–10−8 M), but not high doses (10−7–10−5 M) of histamine (Fig. 4a, left panel). Furthermore, the pattern of tyrosine phosphorylated proteins, obtained in response to histamine (10−9–10−8 M), was similar to the one obtained in response to fMLP (10−7 M). The lack of tyrosine phosphorylation in response to high doses of histamine may be explained in two ways, either homologous desensitization of the H4R by histamine, or heterologous desensitization of the H4R triggered by engagement of the H2R as reported for other G protein-coupled receptors [26].

Fig. 4.

Histamine induces tyrosine phosphorylation of proteins in neutrophils. a PLB-985 cells differentiated into neutrophil-like cells (left panel) or neutrophils (right panel) were stimulated with histamine (10−9–10−5 M) or fMLP (10−7 M). After 1 min, the cells were lysed. Equal amount of protein lysates (40 μg) were loaded in each lane of the gels. Proteins were separated on 10% SDS-PAGE and transferred to a nitrocellulose membrane. The membrane was immunoblotted with an anti-PY mAb. The panel depicts a representative Western blot (out of three); the position of proteins phosphorylated in response to histamine is indicated on the right part of the blots by arrows. b Neutrophils were pretreated for 20 min with JNJ 7777120 (10−5 M) (left panel), or Fam (10−5 M) (right panel) after which the cells were stimulated with histamine (10−9–10−5 M). After 1 min, the cells were lysed and the tyrosine phosphorylation pattern was determined as described above. The panel depicts a representative Western blot (out of three); the position of proteins phosphorylated in response to histamine is indicated on the right part of the blot by arrows. c Differentiated PLB-985 cells (left panel) or neutrophils (right panel) were pretreated for 20 min with PP2 (5 μM) after which the cells were stimulated with histamine (10−8 M) or fMLP (10−7 M). After 1 min, the cells were lysed and the tyrosine phosphorylation pattern was determined as described above. At least 3 independent experiments were performed with human neutrophils and PLB-985 cells.

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We also observed tyrosine phosphorylation of proteins in neutrophils stimulated with histamine (10−9–10−5 M) (Fig. 4a, right panel). Interestingly, a concentration of histamine as low as 10−9 M augmented basal tyrosine phosphorylation of proteins. The highest level of tyrosine phosphorylation was observed with histamine (10−7 M). Furthermore, a pretreatment of neutrophils with JNJ 7777120 (10−5 M) totally blocked tyrosine phosphorylation of proteins induced by histamine (10−9–10−5 M) (Fig. 4b, left panel). In contrast, a pretreatment of the cells with famotidine (10−5 M) did not (Fig. 4b, right panel). These results demonstrate that in human neutrophils and differentiated PLB-985 cells, the H4R, similarly to fMLP receptors, is coupled to Src/Syk family tyrosine kinases, a pathway controlling activation of neutrophil inflammatory functions. We further confirmed this assumption by showing that a pretreatment of differentiated PLB-985 cells (Fig. 4c, left panel) or neutrophils (Fig. 4c, right panel) with the Src family tyrosine kinase inhibitor PP2 totally blocked histamine- or fMLP-induced tyrosine phosphorylation of proteins.

Design of a Hdc-Deficient A. baumannii ATCC 17978 Strain

To evaluate the contribution of histamine produced by Gram-negative bacteria in pathogenicity, we designed a hdc-deficient A. baumannii strain by gene disruption [17]. To confirm that the hdc gene was disrupted by plasmid insertion, regions between the T7 promoter (plasmid sequence) and upstream of the hdc gene were amplified by PCR using genomic DNA of A. baumannii hdc::TOPO mutant as a template. The expected calculated PCR fragment sizes are 843 bp (with P1 rev and T7 forward primers) and 844 bp (with P2 rev and T7 forward primers), respectively (Fig. 5a). The amplicons obtained by PCR were separated on 1% agarose gel and visualized. Their sizes were estimated to be ∼850 bp (Fig. 5b). Thus, the sizes of the PCR products matched the predicted sizes of the amplicons. As a control, we showed that no such amplicons were generated by PCR, using the same sets of primers, with genomic DNA of WT A. baumannii ATCC 17978 (Fig. 5b).

Fig. 5.

Construction of the hdc-deficient A. baumannii ATCC 17978 strain. a A region of the hdc gene (homology region) was amplified by PCR using the genomic DNA of A. baumannii ATCC 17978 as a template. The PCR product was purified, and inserted in to the pCR-Blunt II-TOPO plasmid. Competent A. baumannii ATCC 17978 were electroporated with the pCR-Blunt II-TOPO plasmid containing the homology region of the hdc gene. Recombinants were selected on kanamycin plates. The predicted organization of the genomic DNA of the hdc recombinant hdc::TOPO is shown. To confirm that the hdc gene has been disrupted, the region between the T7 promoter (plasmid sequence) and a region upstream of the hdc gene were amplified by PCR using genomic DNA of the hdc::TOPO recombinant as a template. Two reverse primers (P1 rev or P2 rev) recognizing a gene sequence upstream of the hdc gene were designed. The predicted sizes of the amplicons are 843 and 844 bp with P1 rev and T7 forward primers and P2 rev and T7 forward primers, respectively. b The amplicons obtained by PCR using either genomic DNA from the recombinant hdc::TOPO or the WT strain as templates were separated on 1% agarose gel and visualized. The size of the molecular standards (in bp) is indicated on the left hand side of the gel. c the sequence of the amplicon obtained by PCR using the P1 rev and T7 forward primers and genomic DNA of the hdc mutant hdc::TOPO as a template is indicated. The gray part is the plasmid sequence upstream of the T7 promoter, followed by the sequence of the homology region, then the sequence of the end part of the hdc gene (underlined), and finally the genomic sequence 3′ upstream of the hdc gene (bold).

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To confirm further hdc gene disruption, we sequenced one of the amplicon and its sequence matched the predicted sequence (Fig. 5c). The gray part of the amplicon sequence corresponds to the plasmid sequence upstream of the T7 promoter, followed by the amplicon sequence of the homology region cloned into the TOPO plasmid, then the amplicon sequence of the end part of the hdc gene (underlined), and finally the genomic sequence upstream of the hdc gene (bold).

Functional Activity of the A. baumannii hdc::TOPO Mutant

To verify that hdc gene disruption had functional consequences, we compared histamine production by both the hdc::TOPO mutant and the WT strain. To this end, we incubated the strains in a glass flask containing LB medium, in the absence or presence of histidine (10−3 M). After 18 h under shaking conditions, supernatants, free of bacteria, were collected and histamine concentrations were measured by ELISA. The rationale for adding histidine to the LB medium is that this amino acid is a substrate for hdc and hdc of Gram-negative bacteria are inducible by histidine [27].

We found that addition of histidine (10−3 M) to the LB medium, in which the WT A. baumannii strain was inoculated, led to ∼1.7-fold increase of the histamine concentration (Fig. 6a, left panel). Other Gram-negative bacteria including Branhamella catarrhalis, Haemophilus parainfluenzae, and Pseudomonas aeruginosa have also been shown to produce histamine in histidine-enriched growth medium [11]. In contrast, no such increase in histamine concentration was found following inoculation of the hdc::TOPO mutant (Fig. 6a, right panel). As a control, we showed that both the hdc::TOPO mutant and the WT strain have similar growth rates in LB medium regardless of whether or not histidine was added (Fig. 6b). Thus, the lack of histamine production by the hdc::TOPO mutant cannot be attributed to defective growth but to hdc gene disruption.

Fig. 6.

WT A. baumannii ATCC 17978, but not hdc::TOPO mutant, produces histamine. a A. baumannii WT or hdc::TOPO mutant strains were inoculated in LB medium and grown in a glass flask under orbital rotation at 37°C in the absence or presence of histidine (10−3 M). After 18 h, aliquots of bacteria were collected and spun down (2,500 g, 10 min). The resulting supernatants were transferred to 1.5 mL Eppendorf tubes and aliquots were diluted, and then used for the quantification of histamine by ELISA using the protocol provided by the manufacturer. The data are expressed as mean values ± SD of triplicates. b A culture of overnight grown A. baumannii ATCC 17978 or hdc::TOPO mutant were diluted in LB broth and adjusted to an OD value of 0.2 at 600 nm. The samples were then diluted 1/100 in LB medium and 10 mL of each mixture was transferred to 250 mL flasks. The flasks were put in an orbital shaker at 37°C. After each hour, an aliquot is taken out from the flask, diluted in LB medium, and turbidimetry at 600 nm was read. The OD values versus time are plotted. Wild type, dashed line; hdc::TOPO mutant, solid line.

/WebMaterial/ShowPic/1446160Histamine Produced by Gram-Negative Bacteria Is Essential for Pathogenicity

We next compared the pathogenicity of both the hdc::TOPO mutant and the WT strain in G. mellonella larvae, an in vivomodel which has been validated to study A. baumannii pathogenesis, producing similar results to those obtained from mammalian studies [28]. We found that inoculation of 5.6 × 104 CFU or 1.1 × 105 CFU of the hdc::TOPO mutant in the larvae did not lead to significant death over a 55 h time course. In contrast, inoculation of similar doses of the WT strain led to rapid death of the larvae. After 48 h following inoculation of 1.1 × 105 CFU of the wild strain, all larvae died whereas, in contrast, with the inoculation of a similar dose of hdc::TOPO mutant, the survival rate was about 70% after 55 h (p < 0.0001) (Fig. 7a, b).

Fig. 7.

Histamine produced by A. baumannii ATCC 17978 in G. mellonella larvae contributes to pathogenicity. G. mellonella (10 larvae per group) were inoculated, through the proleg, with 5.6 × 104 CFU or 1.1 × 105 CFU of A. baumannii ATCC 17978 or hdc::TOPO mutant. Larval survival was recorded after 24 h–54 h. a Photograph of larvae 18 h postinfection with A. baumannii ATCC 17978 or hdc::TOPO mutant with 5.6 × 104 CFU (left panel), or 1.1 × 105 CFU (right panel). b Kaplan-Meier survival analysis upon inoculation of G. mellonella larvae with A. baumannii ATCC 17978 or hdc::TOPO mutant at 5.6 × 104 CFU (left panel), or 1.1 × 105 CFU (right panel). c (left panel) G. mellonella larvae were inoculated with PBS (controls), 5.6 × 104 CFU of A. baumannii ATCC 17978, or hdc::TOPO mutant for 18 h after which six surviving larvae were collected. The haemolymph of the six larvae were pooled together. The concentration of histamine in the cell-free haemolymph was determined by ELISA. The data represent mean values ± SD of triplicate values. c (right panel) The haemolymph of ten larvae were pooled and hemocytes (1 × 107) were incubated with C. albicans (2 × 106) in the absence (dashed line) or presence (solid line) of histamine (10−6 M). After 10–20 min, the cell mixture was subjected to low speed centrifugation and the supernatants, free of hemocytes, were collected. The number of C. albicans remaining in the supernatants was determined by colony counting. The data represent the mean ± SD of three experiments performed in triplicates.

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In parallel, we measured the concentration of histamine in the haemolymph of G. mellonella larvae following inoculation of the vehicle (PBS), the WT strain, or the hdc::TOPO mutant (5.6 × 104

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