key: cord-0003582-nlfejnmk
authors: Ciancarella, Valeria; Lembo-Fazio, Luigi; Paciello, Ida; Bruno, Anna-Karin; Jaillon, Sébastien; Berardi, Sara; Barbagallo, Marialuisa; Meron-Sudai, Shiri; Cohen, Dani; Molinaro, Antonio; Rossi, Giacomo; Garlanda, Cecilia; Bernardini, Maria Lina
title: Role of a fluid-phase PRR in fighting an intracellular pathogen: PTX3 in Shigella infection
date: 2018-12-07
journal: PLoS Pathog
DOI: 10.1371/journal.ppat.1007469
sha: c8a84384011fca6e1e24511d1b053eef4650fc04
doc_id: 3582
cord_uid: nlfejnmk

Shigella spp. are pathogenic bacteria that cause bacillary dysentery in humans by invading the colonic and rectal mucosa where they induce dramatic inflammation. Here, we have analyzed the role of the soluble PRR Pentraxin 3 (PTX3), a key component of the humoral arm of innate immunity. Mice that had been intranasally infected with S. flexneri were rescued from death by treatment with recombinant PTX3. In vitro PTX3 exerts the antibacterial activity against Shigella, impairing epithelial cell invasion and contributing to the bactericidal activity of serum. PTX3 is produced upon LPS-TLR4 stimulation in accordance with the lipid A structure of Shigella. In the plasma of infected patients, the level of PTX3 amount only correlates strongly with symptom severity. These results signal PTX3 as a novel player in Shigella pathogenesis and its potential role in fighting shigellosis. Finally, we suggest that the plasma level of PTX3 in shigellosis patients could act as a biomarker for infection severity.

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The first line of immune defense against pathogens is guaranteed by the recognition of Pathogen Associated Molecular Patterns (PAMPs) by Pattern Recognition Receptors (PRRs). The family of PRRs includes secreted, membrane-bound and cytosolic PRRs [1] . Pathogenic organisms use sophisticated strategies to modulate PRR recognition and to control downstream signaling. Accordingly, the human enteropathogen Shigella exploits different mechanisms to hijack the innate immune response. The Shigella genus includes 4 serogroups: S. boydi, S. dysenteriae, S. flexneri and S. sonnei. and S. flexneri are the main serogroups circulating in industrialized and developing countries respectively [2] , but most studies centered on the invasion process of Shigella in vitro and in vivo have been carried out with S. flexneri.

Shigella penetrates epithelial cells through a series of effectors secreted via a Type 3 Secretion System (T3SS) [3] encoded by a large virulence plasmid common to all Shigella serogroups. Once inside the colonic mucosa, shigellae either fuel or dampen the inflammatory response, depending on the step of the invasion process. In epithelial cells, Shigella multiplies freely within the cytoplasm [4] where the cytosolic PRR Nod1 recognizes cell-wall peptidoglycan (PGN) and activates NF-κB [5, 6] . This leads to CXCL8/IL-8 production. IL-8 attracts neutrophils which are required for the clearance of shigellae but which also participate in the destruction of the epithelial barrier [7] . Within epithelial cells, S. flexneri changes its lipopolysaccharide (LPS) structure from a highly inflammatory hexa-acylated lipid A form to a less inflammatory tetra-and tri-acylated lipid A variant [8] . This low-inflammatory LPS is poorly recognized by the PRR Toll-Like-Receptor 4 (TLR4), making macrophages and neutrophils less able to control the infection. Furthermore, in B lymphocytes Shigella induces TLR2-mediated apoptotic death through a mechanism mediated by T3SS, independent of cell invasion [9] . These immune evasion strategies involve TLR2 and TLR4, which are PRRs present on the surface of many cell populations, suggesting that the extracellular step could be critical for successful infection. To gain insight about this poorly explored aspect of Shigella pathogenesis we analyzed the potential role of humoral PRRs, focusing on the possible involvement of Pentraxin 3 (PTX3), which has served as a paradigm of humoral innate immunity [10] .

PTX3 is a key element of the humoral arm of innate immunity, downstream of and complementary to cellular recognition and activation. Pentraxins are an evolutionarily highly conserved superfamily of proteins. PTX3 is the prototypic long pentraxin, while the short pentraxins include C-reactive protein (CRP) and serum amyloid P component (SAP), acutephase proteins in man and mouse respectively. PTX3 is rapidly produced and released by several cell types, e.g. mononuclear phagocytes, dendritic cells (DCs) and neutrophils [11] in response to primary inflammatory signals (e.g. TLR engagement, TNF-α, IL-1β). PTX3 binds selected microorganisms, including Aspergillus fumigatus, Pseudomonas aeruginosa [12, 13] and uropathogenic Escherichia coli (UPEC) [14] . It also promotes complement activation, thereby facilitating pathogen recognition by phagocytes [15] . All these features prompted us to investigate whether PTX3 could play a role in Shigella pathogenesis and how and to what extent this PRR is released upon Shigella infection. Our findings highlight that PTX3 is a new player in the Shigella cross-talk with the infected tissues and provide novel insights into the mechanisms of Shigella to control the production of this humoral PRR.

Firstly, we addressed the question of whether PTX3 could opsonize Shigella as reported with A. fumigatus, Salmonella typhimurium, P. aeruginosa, Neisseria meningiditis [12, 13, 16] and uropathogenic E. coli (UPEC) (14) . We observed that PTX3 (50 μg/mL, 1,1 μM) opsonized the wild type S. flexneri 5 strain M90T (Fig 1A and 1B) and its plasmidless, non-invasive variant BS176 though to a lesser extent compared to P. aeruginosa (strain PAO1), used as a positive control (12, 17) Epithelial cell invasion and macrophage death [18] are hallmarks of Shigella pathogenesis. We investigated whether PTX3 binding could affect epithelial-cell penetration by Shigella. M90T was incubated with different concentrations of recombinant PTX3 (0.05, 0.5, 5 and 50 μg/mL) prior to infection of HeLa cells. M90T treated with bovine serum albumin (BSA) (50 μg/mL) or with a rabbit polyclonal antibody raised against the T3SS-invasin IpaD (50 μg/mL), which is involved in bacterial internalization [19] was used in parallel. As shown in Figs 1C and S1A, PTX3 opsonization with only the concentration of 50 μg/mL significantly decreased the number of intracellular bacteria at 1 h and 2 h post-infection (p.i.) (p< 0.001: PTX3-opsonized M90T vs. M90T plus BSA at 2h) to levels like those induced by the anti-IpaD antibody.

In human peripheral blood monocytes-derived macrophages (MoMs), opsonization with recombinant PTX3 at same concentrations as above only determined a significant improvement of bacterial phagocytosis at the concentration of 50 μg/mL (Fig 1D and 1E, S1B Fig) (p< 0.01: PTX3-opsonized M90T vs. M90T plus BSA). Likewise, the rate of MoMs cell death, measured through lactate dehydrogenase (LDH) release, (Fig 1F and S1C Fig) was improved by PTX3 opsonization, as also shown with the anti-IpaD antibody [19, 20] . However, the cell death rate followed the trend as above since it was only increased with PTX3 at the concentration of 50 μg/mL (p< 0.01: PTX3-opsonized-M90T vs.M90T plus BSA) (S1C Fig) PTX3 is also involved in complement cascade activation and regulation [21] . There is scant and dated literature on Shigella sensitivity to the bactericidal activity of serum [22] , so we set up a bactericidal serum assay against S. flexneri M90T. In preliminary experiments using different serum concentrations (10%; 13%; 17%; 67%) for 30 min at 37˚C, we found that M90T was sensitive to concentrations of > 10% pooled normal human serum (NHS). Exposure to 17% NHS killed around 60% of bacteria (Fig 1G) . Addition of low concentrations of PTX3-5-0.5 μg/mL in the bactericidal serum assay (17% serum) significantly increased bacterial death rate of the bacteria (Fig 1H) .

In conclusion: PTX3-bound bacteria are partially impaired in their ability to invade epithelial cells and are better internalized by macrophages as shown with antibody-bound bacteria [23, 24] . Low doses of PTX3 increase the bactericidal activity of serum/complement.

We therefore passed to analyze a possible contribution of PTX3 in vivo, during infection. Several reports have described the therapeutic effect of recombinant PTX3 in the models of aspergillosis [25, 26, 27] ; of P. aeruginosa acute and chronic lung infections [17, 28, 29] ; of acute respiratory syndrome [30] and of influenza virus lung infection [31] Mice are naturally resistant to Shigella oral infection. Therefore, alternative infection models have been developed and used [32) . Among them, the intranasal route of infection in mice [33] has been extensively used and validated to study Shigella virulence and to analyze vaccine candidates [32, 33] . After intranasal infection (i.n.) with virulent Shigella, mice develop a dramatic pneumonia and die within a few days [32, 33] .

In line with these issues, we investigated whether treating mice with recombinant PTX3 could affect the outcome of intranasal infection with M90T, as shown with the other pathogens as above. Based on previously performed pharmacokinetic analyses and therapeutic approaches in a murine model of lung infection with A. fumigatus [12, 25, 26, 27] and P. aeruginosa [17, 28, 29] , we established a treatment schedule of daily intra-peritoneal (i.p.) injections with recombinant human PTX3 (0.5 mg/Kg, 11 μM) or vehicle, starting from the day of the i.n. inoculum with 3 x 10 8 colony forming units (CFU) of M90T (corresponding to the LD50 dose). The treatment with PTX3 was carried out for 48 hours (three PTX3 injections).

Following this experimental plan, we monitored animal survival/death (in three independent experiments) during 1 week. As expected [6, 34, 35] , during the 72 hours, 55% of mice infected with M90T died (12/22) died. By contrast, the animals infected with M90T and treated with PTX3 survived even when the treatment with PTX3 was stopped (19/19) , (p< 0.0002, two-tailed Mantel-Cox test) (Fig 2A) At 72 h post-challenge, the bacterial load in lungs of M90T-infected animals was~10 6 CFU (per lung), as previously published [6, 34, 35] whereas in PTX3 treated animals the number of CFU (per lung) was~10 4 CFU, which was significantly (p< 0.0001) reduced with respect to that of infected, untreated animals (Fig 2B) .

The local level of pro-inflammatory cytokines and chemokines was measured in BALs (broncho-alveolar lavage) (Fig 2C) and lung homogenates (Fig 2D) . We chose some chemokines/cytokines, which have been previously shown to be influenced by PTX3 treatment [12 and 17, 29] and/or to be involved in Shigella infection [6, 34, 8] . CCL5 (RANTES) and IL-1β values were similar in BALs and lung homogenates for untreated and PTX3-treated infected animals, while those of TNF-α CXCL2/MIP-2 and CXCL1/KC were drastically decreased in both homogenates and BALs of PTX3-treated mice compared to infected-untreated mice (for all, p <0.0001, two-tailed Mann-Whitney test). Furthermore, we quantified the PTX3 levels in sera (Fig 2E) , lung homogenates ( Fig 2F) and BALs (Fig 2G) . In lung homogenates of M90Tonly-infected animals the PTX3 level was lower than that of PTX3-treated infected and uninfected mice (for both, p < 0.0001 two-tailed Mann-Whitney test). Likewise, in BALs and sera the levels of PTX3 were significantly (p < 0.0001, two-tailed Mann-Whitney test) reduced in M90T-only-infected animals with respect to those treated with PTX3. At macroscopic examination (S2 Fig Top) , lungs of infected mice were enlarged, of rubbery consistency, edematous and dusky red in color due to severe hyperemia. The lungs of infected and PTX3-treated animals were macroscopically like the controls, and they appeared aerated, pinkish and spongy.

In lungs of M90T-infected mice, hematoxylin-eosin staining showed acute pneumonia with severe bronchoalveolitis, alveolar edema and many damaged areas in the parenchyma. Pulmonary phlogosis was characterized by a severe and diffuse neutrophil infiltrate in peribronchial, intraluminal and interstitial areas between alveoli (S2A, S2D and S2G Fig). In contrast, in PTX3-treated infected mice, lungs conserved a physiological architecture with a moderate inflammation of the aerated parenchyma and airways and a low and scattered neutrophilic exudate (S2B, S2E and S2H Fig) . Histopatological scores (S1 Table) As oppose to the protective effect of recombinant PTX3 in the models of P. aeruginosa and S. fumigatus lung infection, Ptx3-deficient mice showed increased mortality and lung colonization [12, 17] . Likewise, Ptx3 -/-mice were more susceptible than the wild type to influenza virus and to UPEC infections [31, 14] . Hence, we assessed whether deficiency of PTX3 could affect the virulence of Shigella. With this aim Ptx3-/-mice were infected via intranasal route with M90T as above and the animals were monitored for a week. We found that Ptx3-/-mice challenged with M90T showed an accelerated death with respect to M90T-infected wild type mice (p < 0.046, two-tailed Mantel-Cox test) as the majority (75%: 20/30) of the animals died after 48 hours p.i. (Fig 3A) At a same time point, only 23% (7/30) wild type infected mice died. The bacterial load in lungs of Ptx3-/-of the infected animals was around ten times more (9,3 x10 5 vs 1,54 x10 5 ) (p <0.0001, two-tailed Mann-Whitney test) than that found in infected wild type animals (Fig 3B) . Likewise, the levels of TNF-α, CXCL-1 and CXCL-2 in BALs (Fig 3C) and lung homogenates (Fig 3D) were significantly higher (for all, p <0.0001, two-tailed Mann-Whitney test) than those elicited in infected wild type mice.

Conclusively, these findings suggest that PTX3 is involved in Shigella pathogenesis. Nevertheless, only a genetic rescue with transgene expression or recombinant Ptx3 administration to Ptx3-/-mice could consolidate this result.

We then proceeded to examine whether and to what extent Shigella infection could trigger per se PTX3 release. with recombinant PTX3 (10 μg/mouse i.p.). In (A) n = 22 for M90T-infected-mice, n = 19 for M90T-infected and treated-mice, n = 10 for non-infected PTX3-treated mice in three separate experiments. (p < 0.0002, two-tailed Mantel-Cox test). In (B) The lungs were removed at 72h of infection for the bacterial counts. n = 10 for M90T-infected-mice and n = 11 for M90T-infected and treated-mice, respectively; n = 10 for non-infected PTX3-treated mice Data show total CFU per lung (CFU in one lung). Dots represent CFU in individual mice, horizontal lines represent mean values and the error bars represent the standard error of the mean (SEM) (p <0.0001, two tailed Mann-Whitney test). (C and D): cytokine and chemokine (pg/mL) quantification in BALs (C, left) and lung homogenates (D, right); n = 10 for M90T-infectedmice and n = 11 for M90T-infected and treated-mice, respectively; n = 10 for non-infected PTX3-treated mice. PTX3 quantification (ng/mL) in serum (E), lung homogenates (F) and BAL (G) of C57BL/6 mice infected as above. n = as above. (p <0.0001, for TNF-α; CXCL-2 and CXCL-1 and PTX3 in lung homogenates and BAL; p <0.0001 for PTX3 in sera, two tailed Mann-Whitney test) Data analysis was performed with the GraphPad Prism 7.

https://doi.org/10.1371/journal.ppat.1007469.g002

DCs are a major source of PTX3, released following triggers such as various inflammatory cytokines or bacterial PAMPs [10] . BMDCs from C57BL/6 mice were infected with the invasive strain M90T, or with the non-invasive isogenic strain BS176, lacking the virulence plasmid. BMDCs were infected with shigellae at the Multiplicity of Infection (MOI) of 10. PTX3 and TNF-α production was monitored in parallel at 1, 3, 6 and 18 h. post-infection (p.i) BS176 induced a significantly higher release of PTX3 than M90T (Fig 4A) , while TNF-α release was equivalent with both strains (S4A Fig). To test if invasiveness was correlated to PTX3 release, we introduced another non-invasive strain into our assay. M90T ΔipaB lacks the T3SS-secreted invasin IpaB and is thus non-invasive in epithelial cells even if it can still construct the T3SS machinery [19] . PTX3 release induced by M90T ΔipaB was similar to that of BS176 (Fig 4A) .

To confirm this trend, the infection protocol of BMDCs was modified to abrogate the invasive phenotype of M90T and PTX3 release was measured as above. First, BMDCs were exposed to the invasive and non-invasive strains, previously killed with gentamicin (Fig 4B) . M90Tand BS176-killed bacteria potentially could be phagocytized by DCs; however, the invasive ability of M90T was destroyed. The release of PTX3 did not change in BMDCs infected with killed BS176. In contrast, the PTX3 values induced by killed M90T were significantly higher than those recorded with live M90T. Then, we prevented cell internalization of bacteria by treating the cells with cytochalasin D, which disrupts cytoskeleton organization [36] . In contrast to the previous approach, here invasive and non-invasive bacteria could not be internalized by the cells. Under this condition the PTX3 values induced by M90T were comparable to those of BS176 (Fig 4C) .

The two different experimental approaches are aimed differently at preventing the invasive phenotype of virulent shigellae. However, under both conditions the internalization of live M90T by the cells was inhibited, leading to a significant increase of PTX3 release. Therefore, we analyzed the production of PTX3 and TNF-α in parallel in human peripheral blood MoDCs. The difference in PTX3 release observed with invasive and non-invasive Shigella strains in BMDCs was also recorded in MoDCs (Fig 4D) . The trend of TNF-α release was similar to that observed with PTX3 (S4B Fig) , in contrast to observations in BMDCs where the TNF-α production was equally induced by the two strains.

These results indicate that inhibition of cell invasion-due to either bacteria killing, deficiency of virulence plasmid, or host cell cytoskeleton disruption-leads to higher PTX3 release by human or murine DC.

To evaluate the signaling pathways involved in PTX3 production, we analyzed the putative roles of factors involved in downstream TLR signaling: Myd88, Trif, Cd14 and Irf3 [37] . Infection of Myd88 -/-BMDCs significantly reduced the release of PTX3 with respect to wild-type BMDCs (Fig 4E) . A similar trend was noted for TNF-α production (S4C Fig). The absence of Trif, Irf3 or Cd14 greatly reduced the PTX3 production as shown in Fig 4F and 4G . Likewise,

Animal mortality (n = 30 in three experiments for Ptx3-/-and C57BL/ 6 mice) (p < 0.046, two tailed Mantel-Cox test) and (B) bacterial load (total CFU in one lung) in lungs (n = 10 for Ptx3-/-mice and n = 13 for C57BL/6 mice, respectively) (at 48 h post-challenge) of Ptx3-/-and C57BL/6 mice infected with Shigella M90T strain (1 x 10 8 ) via intranasal route. Dots represent CFU in individual mice, horizontal lines represent mean values and the error bars represent the standard error of the mean (SEM) (p <0.0001, two tailed Mann-Whitney test). (C and D) TNF-α, CXCL-2 and CXCL-1 quantification in BALs (C, left) and lung homogenates (D, right) of Ptx3-/-and C57BL/6 mice infected as above (n = 10 for Ptx3-/-mice and n = 13 for C57BL/6 mice, respectively) (p <0.0001 for all data, two-tailed Mann-Whitney test). Data analysis was performed with the GraphPad Prism 7.

https://doi.org/10.1371/journal.ppat.1007469.g003 TNF-α measures were drastically reduced but not totally abrogated in Trif -/-, Irf3 -/and Cd14 -/-BMDCs (S4C and S4D Fig) .

As LPS is the unique PAMP engaging the Myd88 and Trif pathways, we investigated whether LPS could trigger PTX3 release, as also shown for UPEC [14] .

Shigella modifies LPS composition during intracellular residence in epithelial cells [8] . Intracellular bacteria possess a hypo-acylated lipid A characterized by a blend of lipid A forms; tetra-and tri-acylated variants are more prevalent than the hexa-acylated isoform, which is the main component present in LPS of M90T grown in laboratory media. M90T ΔmsbB1 ΔmsbB2 [38, 8] is a M90T mutant that carries penta-acylated (86%) and tetra-acylated lipid A forms. M90T ΔmsbB1 ΔmsbB2 is fully invasive. Purified LPS from this strain showed a low inflammatory potential, in accordance with the lipid A structure [8] .

We checked whether LPS composition could impact PTX3 production in DCs treated with three Shigella LPS variants: that extracted from bacteria grown in laboratory medium [acellular (a)LPS], that purified from intracellular bacteria [intracellular (i)LPS] and LPS of M90T ΔmsbB1 ΔmsbB2. E. coli LPS was used in parallel. BMDCs stimulated with iLPS and M90T ΔmsbB1 ΔmsbB2 LPS produced a lower level of PTX3 with respect to aLPS and E. coli LPS, consistent with the degree of lipid A acylation (Fig 4H) . TNF-α release reflected the differences between the LPSs (S4E Fig). Then, we examined whether the composition of LPS on live bacteria could affect PTX3 yield using M90T and M90T ΔmsbB1 ΔmsbB2 in an invasion assay as above. However, PTX3 and TNF-α release were similar for M90T and M90T ΔmsbB1 ΔmsbB2, despite different lipid A composition (Fig 4I and S4F Fig) .

MoDCs were stimulated with the three Shigella LPS forms (aLPS, iLPS and M90T ΔmsbB1 ΔmsbB2 LPS) following the scheme described for BMDCs. PTX3 yield drastically decreased with iLPS and LPS of M90T ΔmsbB1 ΔmsbB2 with respect to aLPS (Fig 4J) and TNF-α release followed the same trend (S4G Fig). In contrast with results in BMDCs and in accordance with Lipid A composition, the amount of PTX3 and of TNF-α in infected MoDCs was lower with M90T ΔmsbB1 ΔmsbB2 than with M90T (Fig 4K and S4H Fig) .

Thus, in addition to invasiveness, LPS composition plays a pivotal role in triggering PTX3 release in human DCs. The effect of acylation degree of LPS on live bacteria was not evident in murine DCs (Fig 4I vs Fig 4K) in line with the different TLR4 lipid A-sensitivity, as reported [39, 40] .

As macrophages are a further source of PTX3 during infections, we analyzed whether Shigella could promote PTX3 release in macrophages, as shown in DCs.

In mouse BMDMs infected with M90T or BS176, the difference in PTX3 yield between M90T and BS176 was like that observed in BMDCs (Fig 5A) . TNF-α release did not follow this trend as the release of this cytokine was similar between the two strains ( S5A Fig). However, it has been reported that Shigella-infected macrophages are poorly responsive to Shigella infection in the absence of an adequate pre-stimulation [41] .

We then infected LPS-primed BMDMs as described previously [8] to evaluate the influence of LPS modification on PTX3 release. BMDMs were primed with M90T aLPS (mainly hexaacylated), M90T iLPS (mainly tetra-acylated) and M90T ΔmsbB1 ΔmsbB2 LPS (mainly pentaacylated) and were then infected with M90T at MOI 10. Infected BMDMs primed with iLPS and M90T ΔmsbB1 ΔmsbB2 LPS (both LPSs hypo-acylated) released significantly less PTX3 than those primed with aLPS (Fig 5B) , while the amount of TNF-α was similar for all the LPSs, as already shown [8] (S5B Fig). Then, we stimulated the BMDMs (without infection) with the three Shigella LPS (10 ng/mL) as above for 6 h. PTX3 and TNF-α yields were lower with iLPS and M90T ΔmsbB1 ΔmsbB2 LPS (both LPSs hypoacylated) than with aLPS (Fig 5C  and S5C Fig). To evaluate the relative role of structural LPS on live bacteria and LPS priming, BMDMs were primed with different LPSs and then infected with M90T ΔmsbB1 ΔmsbB2 (carrying a penta-acylated LPS) instead of M90T (carrying a hexa-acylated LPS) as above. PTX3 release followed the trend observed with M90T, which was consistent with the acylation degree of the LPSs used for priming; however, M90T ΔmsbB1 ΔmsbB2 triggered a significantly lower release of PTX3 compared to M90T for each condition, in accordance with the hypo-acylation degree of its LPS (Fig 5D) . For TNF-α, the difference between M90T and M90T ΔmsbB1 ΔmsbB2 was maintained, while no significant difference was induced by priming with the various LPSs as for PTX3 (S5D Fig). We then examined whether MoMs (peripheral blood monocyte-derived macrophages) respond to Shigella infection and LPS stimulation as observed with BMDMs, BMDCs and MoDCs. With this aim, MoMs were infected with either: M90T, BS176, M90T ΔmsbB1 ΔmsbB2 or stimulated with the different LPS and both PTX3 and TNF-α production was evaluated. When infected with M90T, BS176 or M90T ΔmsbB1 ΔmsbB2, PTX3 (Fig 5E) and TNF-α yields (S5E Fig) were significantly higher with BS176 than with M90T. This result was consistent with that seen in BMDMs, BMDC and MoDCs. Likewise, M90T ΔmsbB1 ΔmsbB2 induced the lowest PTX3 and TNF-α production in accordance with its LPS structure and as also observed in BMDMs and MoDCs. In MoMs stimulated with the four forms of LPS (M90T iLPS and aLPS, M90T ΔmsbB1 ΔmsbB2 and E. coli LPS), iLPS and M90T ΔmsbB1 ΔmsbB2 LPS induced the lowest production of PTX3 (Fig 5F) and TNF-α, just as for BMDMs (S5F Fig) .

Together, these experiments suggest that LPS composition is a major trigger of PTX3 production in macrophages and that PTX3 production is influenced by both structural LPS on infecting bacteria and purified LPS used for stimulation or priming.

Finally, we addressed the question about the TLR4 downstream signaling leading to PTX3 release in BMDMs as shown in BMDCs. We then used Myd88 -/-, Trif -/-, Irf3 -/and Cd14 -/-BMDMs (Fig 5G) as described for BMDCs. Surprisingly, PTX3 release was abrogated in all knockout BMDMs, indicating that the MyD88-dependent and MyD88-independent pathways are synergistic in the production of PTX3. In accordance with published results [8] we found that the MyD88 pathway was mainly involved in the release of TNF-α (S5G and S5H Fig) , with some contribution of the Trif pathway. In Cd14 -/-BMDMs, the values of TNF-α were significantly lower than in wild-type cells, while the absence of Irf3 did not impair TNF-α release (S5G Fig). These results highlight some differences in the pathways leading to TNF-α and PTX3 release.

Although S. sonnei is the main serogroup circulating in high-income countries, in recent years S. sonnei has also been observed to prevail over S. flexneri in previously low-income countries where socioeconomic conditions have improved [2] . We evaluated whether S. sonnei could, like S. flexneri M90T, induce PTX3 production. BMDCs, MoDCs and BMDMs and MoMs were infected with S. sonnei as with M90T (S6A, S6B, S6C, S6G and S6I Fig) . The involvement of PTX3 in shigellosis prompted us to investigate PTX3 levels in plasma of shigellosis patients. Plasma samples were collected from 31 patients in the acute stage (0-7 days after onset) of culture-proven S. sonnei shigellosis and from 19 healthy subjects and PTX3 levels were measured. Mean PTX3 levels were significantly higher in the patient group (10.4 ng/mL) compared to the control group (2.3 ng/mL) (p = 0.003). The highest levels of PTX3 in patients and controls were 50 ng/mL and 11.75 ng/mL, respectively (Fig 6) . PTX3 levels were significantly higher within 2 days of disease onset than in samples collected later and were positively associated with signs or symptoms related to the severity of shigellosis such as body temperature, number of watery stools per 24 hours and bloody stools (S2 Table) . Among acute cases of S. sonnei shigellosis whose maximal measured body temperature was above 39˚C, the mean PTX3 level was much higher than among acute patients whose maximal measured temperature was equal or below 39˚C. Similar results were found in regard to presence of blood in stool or when both signs of severity were present, albeit reaching borderline statistical significance (p = 0.05, p = 0.06 respectively).

The role of the humoral arm of the innate immunity has been poorly explored in the context of intracellular bacterial pathogens like Shigella. Here we unveil that phase fluid PRM PTX3 could play a decisive role in resolving Shigella infection as the treatment with recombinant human PTX3 rescues animals from death in the murine model of pulmonary shigellosis. As oppose to the protective effect of recombinant PTX3 Ptx3-/-infected mice showed a defective ability to clear bacteria and an accelerated kinetics of death in the same infection model. This is in line with that observed with P. aeruginosa, A. fumigatus and UPEC (12, 14, 17) .

The therapeutic effect of PTX3 has already been reported for the extracellular pathogens P. aeruginosa and A. fumigatus and Streptococcus suis [13, 17, 25, 26, 27 28, 29, 42] This PRM influences pathogen phagocytosis through opsonization of microorganisms and by reinforcing complement activity [11, 21] .

In lungs of M90T-only infected animals, bacterial load was high as reported [6, 33, 34] while this number was significantly reduced in PTX3-treated animals. In vitro, PTX3 opsonization impairs Shigella internalization in epithelial cells, which are the replicative niche of this pathogen. Likewise, PTX3 binds human cytomegalovirus and inhibits viral-cell fusion and internalization, supposedly by crosslinking of glycoproteins on viral or cellular surface [43] . PTX3 binding to Shigella might inhibit bacteria-host cell contact by interfering sterically with the T3SS machinery thereby affecting bacterial micropinocytosis. Antibodies directed against Shigella surface structures have been shown to prevent epithelial cell internalization [23, 24, 44 and this study] and to promote the opsonophagocytic activity in macrophages [45] . In this light, PTX3 opsonization is reminiscent of some in vitro properties of protective antibodies against Shigella external structures, thus contributing to Shigella eradication before the adaptive immune response is mounted. These features reveal a role of PTX3 as an "ante-antibody" [16, 44] in Shigella infections. At a local level of infection, extracellular Shigella that are no longer protected by the host cell cytoplasm, can be targeted by the complement system and easily internalized by macrophages, thus improving the bacterial clearance by the tissues as we observed in lungs of PTX3-treated mice. Indeed, Shigella is sensitive to the serum bactericidal activity (this study), and low concentrations of PTX3 increase the killing activity of complement. It is unsurprising that PTX3 contributes to complement activity only at low concentrations given that it can play a double role, either by activating the three complement pathways or by negatively regulating them through various mechanisms, thereby limiting complementmediated inflammation [21] .

Moreover, the architecture in lungs of M90T-only infected animals was destroyed by dramatic inflammation mainly characterized by a massive neutrophil infiltration. In these mice, high levels of TNF-α and chemokines such as CXCL1 and CXCL2, which act as potent neutrophil chemoattractants [46] , contribute to lung injury. In Ptx3-/-infected mice the inflammatory response seemed to be exacerbated, as the production of TNF-α, CXCL1 and CXCL2 was significantly higher than in wild type animals. In contrast, in lungs of PTX3-treated infected mice low levels of CXCL1 and CXCL2 were associated with few areas filled by a neutrophilic exudate. PTX3 can also directly contribute to local regulation of the inflammatory reaction based on neutrophil infiltrate as it binds to the adhesion molecule P-selectin and inhibits leukocyte rolling in the endothelium [47] . Although these findings sound very encouraging a definitive result could be achieved through a genetic rescue with transgene expression in Ptx3-/-infected mice or alternatively through administration of recombinant Ptx3 to these animals.

In the M90T-infected wild type mice, the serum level of PTX3 was between 10 to 20 ng/mL after 72 h of infection, which was in the range of that observed in the plasma of shigellosis patients and in patients of aspergillosis (12) . Likewise, the levels of PTX3 in BAL were in the range of that recorded in BAL (2-10 ng/mL) of mice infected with A. fumigatus (25) or with influenza virus (31) as both pathogens are very sensitive to the protective effect of PTX3.

These findings arise the question of whether PTX3 could play a role during natural infection in humans. In clinical trials with a S. dysenteriae 1-attenuated but still invasive vaccine, no PTX3 increase was observed in the plasma of vaccinated individuals, [48] suggesting that only invasion of the epithelial layer by Shigella is not sufficient to rise the amount of PTX3 at the systemic level. In contrast to the attenuated strains, which are likely confined to the epithelial layer, fully virulent shigellae break the integrity of the epithelial barrier and penetrate into the mucosa where they induce severe inflammation characterized by a huge amount of cytokines and inflammatory factors, which can act as signals to promote PTX3 release. In line with this issue, in plasma of patients with shigellosis (infected with S. sonnei) the levels of PTX3 correlate positively with the severity of symptoms, particularly with high temperature and blood in the stools being a reliable parameter of severity of shigellosis, just as in conditions like sepsis [49] and critical infections [50] .

As it seemed that Shigella invasion alone poorly promotes the production of PTX3, we analyzed PTX3 release in vitro upon Shigella infection. Epithelial cells, macrophages, DCs and neutrophils that contribute to Shigella-mediated inflammation have all been described as producers of PTX3.

In vitro intestinal cells such as Caco-2 cells do not release PTX3 and only increase their mRNA expression upon exposure to bacteria and bacterial moieties [51] . Likewise, Shigellainfected Caco-2 cells did not produce detectable levels of PTX3 (S7A Fig). Moreover, bronchial epithelial cells express and produce PTX3 upon TNF-α trigger, but not following bacterial PAMP stimulation (such as LPS) [52] . We could suggest that in natural and experimental shigellosis, epithelial cells cannot or barely produce PTX3 upon initial bacterial contact. PTX3 is likely to be released only when inflammatory signals like TNF-α and especially IL-1β are present. Upon inflammatory activation, neutrophils release about 25% of their pre-formed PTX3 content in lactoferrin granules [53] . In lung sections of infected animals, neutrophils were strongly immunostained for PTX3. Neutrophils recruited by inflammatory mediators could constitute a main source of PTX3 upon Shigella invasion under in vivo conditions.

In contrast to epithelial cells, Shigella-infected macrophages and DCs produce PTX3. However, virulent/invasive shigellae induce lower levels of PTX3 than do non-invasive/avirulent shigellae in these cells, suggesting that phenotypes associated with invasiveness play a major role in controlling PTX3 production.

LPS is a main Shigella trigger in macrophages and DCs, eliciting PTX3 production. In contrast to UPEC-infected cells that secrete PTX3 upon LPS-TLR4/MyD88 activation, both TLR4 mediated pathways, MyD88 and Trif, participate in PTX3 production in Shigella-infected macrophages and DCs. Involvement of the TriF pathway is evident as the absence of Trif or Irf3 abrogates and massively reduces the PTX3 release in BMDMs and BMDCs, respectively. The role of IRF3 in PTX3 production has already been observed in the context of tissue repair and remodeling [54] . In Shigella-infected BMDMs, Irf3 is not involved in TNF-α production, thereby suggesting that the PTX3 and TNF-α downstream signaling pathways diverge upon LPS-TLR4 activation.

The composition of LPS finely modulates PTX3 production, in accordance with the degree of acylation. Hypo-acylated LPS derived from intracellular shigellae stimulates a reduced release of PTX3 with respect to hexa-acylated LPS extracted from bacteria grown under conventional conditions, as also reported for cytokine production [8] . The impact of LPS composition present on live bacteria on PTX3 and TNF-α yield is particularly evident in human cells. Under some experimental conditions, LPS composition tuned PTX3 production more finely than TNF-α production. This result strongly links PTX3 production to LPS composition also in different physiological and pathological contexts.

In conclusion, at a local level of Shigella infection, PTX3 could tip the balance toward bacterial eradication playing a double role: on the bacterial side, it helps to reduce epithelial cell invasion, to implement macrophage phagocytosis and to favor complement activity; on the host tissue side, it contributes to the prevention of the development of the destructive inflammation, which is a main feature of shigellosis. This immune evasion behavior can favor bacterial survival and proliferation, thus allowing tissue colonization during the initial phases of the disease. We suggest that PTX3 could potentially contribute to the eradication of the infection by targeting the poorly explored extracellular phase of the invasion process, which can be considered the "Achille heels" of Shigella invasion process.

M90T: wild type S. flexneri strain (serotype 5a); BS176: plasmidless, non-invasive M90T derivative [55] ; M90T ΔipaB: non-invasive T3SS mutant [19] ; M90T ΔmsbB1 ΔmsbB2: LPS mutant which lacks both copies of the msbB genes (msbB1 and msbB2), each of which encodes the enzyme myristolyl transferase. M90T ΔmsbB1 ΔmsbB2 carries a hypo-acylated lipid A [8, 38] . M90T-GFP was created by transforming wild type strains with TGI pFpV25.1 vector [56] . The Shigella sonnei wild type strain has been described by Rossi [57] . Bacteria were routinely grown in Trypticase soy broth (TSB) (BBL, Becton Dickinson and Co., Cockeysville, MD) or agar (TSA). TSA containing 100 mg of Congo Red dye (Cr) per liter was used to select virulent clones of Shigella. Streptomycin (Sm) and ampicillin (Ap) were added to cultures at 100 μg/mL.

For the PTX3 binding assay a Pseudomonas aeruginosa wild type laboratory strain, PAO1 was used as a positive control.

The procedure was carried out as originally described with minor modifications [12] . A total of 10 7 CFU were incubated in 50 μl HBSS (Hank's Balanced Salt Solution) with 0.5% BSA and biotinylated PTX3 (50 μg/mL) (1.1 μM,) [15] or biotinylated BSA (70 μg/mL). After 1 h at room temperature, samples were extensively washed with HBSS. Samples were incubated in 100 μL HBSS with 0.5% BSA with streptavidin-FITC anti-mouse Ig (1:1000) (BD, Pharmingen). Binding was evaluated by fluorescence-activated cell sorting (FACS).

Normal human serum (NHS) was produced from buffy coats obtained by the blood bank of Sapienza University and was collected from 10 healthy adult volunteers (blood donors) with no history of shigellosis following written informed consent. The blood was allowed to clot, and the serum was subsequently harvested, pooled, and stored at -70˚C until used. Heat-inactivated serum (HIS) was generated by incubating NHS for 1 h at 56˚C. Exponential phase bacteria were suspended in Dulbecco's Phosphate-Buffered Saline (DPBS) with Mg 2+ and Ca 2+ and incubated at 37˚C for 30 min in the presence of NHS or HIS.

Bacterial survival was calculated as CFU in the presence of NHS/CFU in the presence of HIS x 100.

HeLa cells (ATCC Cell Biology Collection) were seeded on 6-well plates (8 x 10 4 cells/mL) and allowed to adhere for 12 h. An amount of 10 8 CFU of wild type M90T in early exponential phase (OD600 0,4-0,6) were incubated in either DMEM (Gibco, Life technologies) only or with PTX3 (50 μg/mL) or anti-IpaD Ab or BSA (50 μg/mL) or with PTX3 and BSA at the same time for 1 h at 37˚C and then used to infect HeLa cells at MOI 50. After 60 min, cells were washed three times with PBS and incubated for an additional 1 or 2 h. Cells were washed three more times with PBS, detached with trypsine, counted and lysed with deoxycholic acid (0,5% in H 2 O). Cell lysate was plated on Congo Red (0,1%) containing TSB agar plates and CFU were counted after 18 h of incubation.

C57BL/6 female mice from Charles River, Calco, Italy, were maintained in a specific pathogen-free animal facility of the University of Camerino and euthanized by cervical dislocation.

Myd88 -/-, Trif -/-, Irf3 -/or Cd14 -/were a kind gift of Maria Rescigno (Myd88 -/-), IFOM-IEO Campus, Milan, Italy and Francesca Granucci (Trif -/-, Irf3 -/or Cd14 -/-), Università degli Studi di Milano-Bicocca, Milan, Italy. Ptx3 -/were generated as described [12] Wild-type and mutant BMDMs and BMDCs were derived from bone marrow cells collected from five-week-old female mice, as already reported [8] and as detailed as follows.

BMDCs (bone barrow derived dendritic cells) were differentiated for 7 days in RPMI 1640 (Lonza, Italy) containing 10% heat inactivated fetal bovine serum (FBS) (Gibco, Life technologies), 100 μM non-essential amino acids, 1000 U/mL penicillin and 1000 U/mL streptomycin (all from Lonza, Italy), supplemented with 30% R1, containing fibroblast produced GM-CSF, as described [58] . After 7 days, BMDCs were characterized by immunostaining with CD11b, CD11c, CD80, CD86, MHCII monoclonal antibodies (all from BD Pharmingen, Italy) through a flow cytometric analysis on a FACSCalibur cytometer (Becton Dickinson,San José, CA, USA). Data acquisition (10 4 events for each sample) was performed using CellQuest software (Becton Dickinson, San José, CA, USA). Analysis was performed with FlowJo software (TreeStar Inc., Ashland, USA).

BMDC infections with S. flexneri strains and S. sonnei were carried out at MOI 10. Infected BMDCs were incubated for 2 h before washing and adding gentamicin (60 μg/mL) (Gibco). Cells were incubated for further 1 h, 3 h, 6 h and 18 h post infection (p.i.) and supernatants were collected and analyzed for PTX3 and TNF-α release. When indicated, cytochalasin D was added 1 h before infection (0,4 μg/mL) (Invivogen). Alternatively, bacteria were killed by gentamicin (60 μg/mL) treatment for 1 h and added to BMDCs at MOI 10. The supernatants were then collected for ELISA at different time points (1 h, 3 h, 6 h and 18 h).

For LPS stimulation BMDCs, cells were seeded on 12-well plates (5 x 10 5 cells/well). LPS stimulation was carried out with: LPS derived from intracellular shigellae (iLPS), shigellae grown in TSB medium (aLPS) and M90T ΔmsbB1msbB2 LPS, as described, [8] and commercial E. coli LPS (LPS ultrapure-EB; InvivoGen) at the concentration of 1 and 10 ng/mL for 18 h. Supernatants were collected for ELISA analysis.

BMDMs (bone barrow derived macrophages) were differentiated for 8 days in RPMI 1640 (Lonza, Italy) containing 10% heat inactivated FBS, 100 μM non-essential amino acids, 1 mM sodium pyruvate, 1000 U/mL penicillin and 1000 U/mL streptomycin (all from Lonza, Italy), supplemented with 30% L929 fibroblast supernatant, containing M-CSF (Macrophage-Colony Stimulating Factor). F4/80 and CD11b double-positive cells were considered as differentiated BMDMs and used in the experiments.

For stimulation assay, differentiated BMDMs were seeded on 24-well plates (5 x 10 5 cells/ well) and exposed to different concentrations (1, 10, or 100 ng/mL) of M90T iLPS, aLPS, and M90T ΔmsbB1msbB2 LPS, as described, [8] and commercial E. coli LPS (LPS ultrapure-EB; InvivoGen). Stimulation was carried out for 6 h and 18 h. Cell supernatants were recovered and stored at -20˚C to be used in the ELISA assay.

BMDM infections assay with S. flexneri and S. sonnei strains were performed as reported [8] with minimal differences. Briefly, bacteria were used at MOI 10 on cells pre-treated or not for 4 h with Shigella iLPS, aLPS, ΔmsbB1 ΔmsbB2 LPS and E. coli LPS at the concentration of 10 ng/mL. Infected BMDMs were incubated at 37˚C for 1 h, washed twice with PBS, and treated with gentamicin (60 μg/mL) for 3 h. At this time, supernatants were analyzed for PTX3 and TNF-α release.

PBMCs (peripheral blood mononuclear cells) were isolated from buffy coats obtained by the blood bank of Sapienza University from healthy adult volunteers (blood donors) following written informed consent.

PBMCs (peripheral blood mononuclear cells) were obtained from blood of healthy adult volunteers (blood donors), through a density gradient. CD14 + monocytes were isolated using the MACS microbead system (Miltenyi Biotec, Bergisch Gladbach, Germany). The monocytes were cultured for 6 days in RPMI 1640 (Lonza) supplemented with 10% heat-inactivated FBS (Euroclone Fetal Bovine Serum, GE Healthcare Life Sciences,U.S.), 100 μM non-essential amino acids, 1 mM sodium pyruvate, 1000 U/ml penicillin and 1000 U/mL streptomycin (all from Lonza, Italy) and 50 ng/mL GM-CSF (Granulocyte-Macrophage Colony-Stimulating Factor) (Miltenyi Biotec) to obtain human macrophages.

Stimulation assays: MoMs (peripheral blood monocyte-derived macrophages) were seeded in 24-well plates (2,5 x 10 5 cells/well), exposed to 1 ng/mL of LPS derived from intracellular shigellae (iLPS), shigellae grown in TSB medium (aLPS), Shigella ΔmsbB1 ΔmsbB2 LPS and commercial E. coli LPS (LPS ultrapure-EB; InvivoGen) and incubated for 12 h. Cell supernatants were recovered and processed for ELISA.

MoM infection assays with Shigella M90T strain, its derivatives BS176 and M90T ΔmsbB1 ΔmsbB2 strains, and S. sonnei strain were performed using MOI 0,1 on cells pretreated or not with Shigella iLPS, aLPS, ΔmsbB1msbB2 LPS and commercial E. coli LPS (LPS ultrapure-EB; InvivoGen) for 4 h (0,1 ng/mL). Infected macrophages were incubated at 37˚C for 1 h, washed twice with PBS solution, and treated with gentamicin (60 μg/mL) for 3 h. Supernatants were recovered and evaluated by ELISA. For infection with PTX3 treated bacteria, shigellae were incubated with PTX3 or BSA (50 μg/mL) or a polyclonal rabbit anti-IpaD antibody (5 μL) (gift of Abdel Allaoui) for 1 h at 37˚C. MOI 5 was used for 2 h. MoDCs were infected with bacteria at MOI of 10.

MoM death evaluation: 10 8 M90T were opsonized with recombinant PTX3 (50 μg/mL), BSA (50 μg/mL) or anti-IpaD Ab or nothing for 1 h at room temperature and then used to infect MoMs at MOI 5 for 2 h before evaluation of lactate dehydrogenase (LDH) release in supernatant. LDH was measured through the CytoTox 96 Non-Radioactive Cytotoxicity Assay kit (Promega, USA), according to manufacurer's instruction. To adjust for spontaneous lysis, % release was calculated as follows: (Release in sample-release from non-infected cells)/(maximum release-release from non-infected cells) � 100.

Phagocytosis Assay: percentage of bacterial internalization by MoMs was evaluated through cytofluorimetric analysis. CD14 was used as MoM marker, and cells positive for both GFP and CD14 were considered infected cells. Data acquisition (10 4 events for each sample) was performed using CellQuest software (Becton Dickinson, San José, CA, USA). Analysis was performed with FlowJo software (TreeStar Inc., Ashland, USA).

Dendritic cells. MoDC (peripheral blood monocyte-derived dendritic cell) culture, stimulation and infection.

PBMCs were obtained from blood of healthy adult volunteers (blood donors), through a density gradient as above. CD14 + monocytes were isolated using the MACS microbead system (Miltenyi Biotec, Bergisch Gladbach, Germany). The monocytes were cultured for 5 days in RPMI 1640 (Lonza) supplemented with 10% heat-inactivated FBS (HyClone Fetal Bovine Serum, GE Healthcare Life Sciences,U.S.), 100 μM non-essential amino acids, 1000 U/mL penicillin and 1000 U/mL streptomycin (all from Lonza, Italy), 20 ng/mL IL-4 and 50 ng/mL GM-CSF (both Miltenyi Biotec) to obtain immature human dendritic cells. MoDCs were characterized by immuno-staining with CD11c, CD14 and CD80 (all from BD Pharmingen, Italy) through a flow cytometric analysis.

For MoDC stimulation, MoDCs were collected, seeded on 12-well plates (5 x 10 5 cells/well) and exposed to 10 ng/mL of iLPS, aLPS, M90T ΔmsbB1 ΔmsbB2 LPS and E. coli LPS for 12 h.

For MoDC infections, cells were seeded at 5 x 10 5 cells/well on the morning of infection. Exponential phase bacteria were added at MOI 10 directly to the wells containing MoDCs. Plates were centrifuged for 5 min at 300 x g and incubated at 37˚C for 2 h. Fresh medium containing gentamycin (60 μg/mL) was added, and cells were incubated for further 1 h, 3 h, 6 h and 18 h.

Five-week-old (18-20 gr) C57BL/6 female wild type (Charles River, Calco, Italy) or Ptx3-/mice were maintained in a specific pathogen-free animal facility of the University of Camerino. For all the infections, mice were anesthetized intramuscularly with 50 μL of a solution containing Zoletil (1 mg) (Virbac, Carros, France) and Xilor (2%) (BIO 985, San Lazzaro, Italy) and inoculated intranasally with 20 μL of 0.9% NaCl suspensions containing 3 x 10 8 CFU of S. flexneri M90T strain [47, 6] .

When required, infected mice (wild type) were treated once per day for 3 days with recombinant PTX3 (10 μg/mouse intraperitoneally, 0,5 mg/Kg, corresponding to 11 μM) or with sterile saline and examined daily to evaluate the survival during 8 days (n = 22 for M90Tinfected-mice, n = 19 for M90T-infected and treated-mice, n = 10 for non-infected PTX3treated mice, in three separate experiments), or euthanized at 3 days post-infection (n = 10 for M90T-infected-mice and n = 11 for M90T-infected and treated-mice, n = 10 for non-infected PTX3-treated mice, in three separate experiments). At this time, bronchoalveolar lavages (BAL) were performed and BALs were used for cytokine analysis. Lungs were removed, homogenized and plated on TSA plates (1 lung per mice) or analyzed for relevant cytokines or alternatively fixed in formalin. Consecutive sections from the middle of the five lung lobes were used for histological and immunohistochemical examination. In the experiments using Ptx3-/-mice survival was analyzed up to 8 days p.i. (n = 30, in three separate experiments) and their lungs were processed to assess the bacterial load and cytokine production at 48 h p.i. (n = 10 Ptx3-/-; mice n = 13 wild type), in three separate experiments).

Lungs samples were fixed in 4% formaldehyde for 18 h at room temperature and treated for histopathological and immunochemistry studies as described [6] . The samples were gradually dehydrated and then embedded in paraffin. The specimens were cut in 3-μm-thick slices and stained with hematoxylin-eosin (Carlo Erba) or immunostained. Immunohistochemistry was performed by using the following antibodies: rabbit polyclonal anti-human PTX3 [14] . and mouse monoclonal anti-PMNs (MA5-12607, clone BM-2, ThermoFisher Scientific, USA). The sections were incubated with the secondary antibodies (1:200) for 45 minutes and then examined blindly and scored by a pathologist.

Cytokine and chemokine concentrations were determined by commercially available ELISA kits (Duo Set R&D systems). The absorbance was measured on a LT-4000 Microplate reader (Labtech) (Hercules, CA, USA).

The LPSs used in this study are the same as those used by Paciello [8] . Refer to this article for relevant information about the experimental procedures for LPS extraction and purification. 31 patients in the acute stage (0-7 days after onset) of culture-proven S. sonnei shigellosis were recruited for the study. They included 31 children aged 0.2-10 years and one adult. The control group included 19 healthy subjects, 11 adults and 8 children aged 0.5-14 years. Signed informed consent was obtained from the parents of all participating children and from all participating adults. Participants or their parents completed a questionnaire with personal data and details regarding symptoms and onset of disease. Blood samples were collected using EDTA tubes (Geiner Bio-One). Plasma was separated and stored at -80 o C until assayed.

Data was presented as mean ± S.D., and the number of independent experiments is indicated in each legend of the figures. Statistics were performed with GraphPad Prism and data analysis was carried out as follow: Mantel-Cox test was used to compare survival curves; non-parametric Mann-Whitney U test for CFU counts and cytokine/chemokines quantification in mice; Student's t-test for PTX3 and TNF-α release in cell cultures and paired t-test for PTX3 quantification in plasma of patients. P < 0.05 was considered significant.

Mice experiments were conducted according to the ethical requirements of the Animal Care Committee of the University of Camerino (study protocol No 17/2012) upon approval of the Ministero della Salute, Direzione Generale della Sanità Animale e dei Farmaci Veterinari, Ufficio VI (Benessere animale), in line with the Guidelines laid down by the European Communities Council (86/ 609/ECC) for the care and use of laboratory animals. The study involving shigellosis patients and controls has been has been approved by the IRBs of Hillel Yaffe Medical Center and the Israel Ministry of Health (Study protocol No. AH-382-11). Written signed informed consent was obtained from the parents of all participating children and from all participating adults. PBMCs (peripheral blood mononuclear cells) were isolated from buffy coats obtained by the blood bank of Sapienza University from healthy adult volunteers (blood donors) following written informed consent. 

Fluid phase recognition molecules in neutrophil-dependent immune responses

Update on molecular epidemiology of Shigella infection

The versatility of Shigella effectors

Multiplication of Shigella flexneri within HeLa cells: lysis of the phagocytic vacuole and plasmid-mediated contact hemolysis

Invasive Shigella flexneri activates NF-kappa B through a lipopolysaccharide-dependent innate intracellular response and leads to IL-8 expression in epithelial cells

Muramylpeptide shedding modulates cell sensing of Shigella flexneri

Interleukin-8 controls bacterial transepithelial translocation at the cost of epithelial destruction in experimental shigellosis

Intracellular Shigella remodels its LPS to dampen the innate immune recognition and evade inflammasome activation

B lymphocytes undergo TLR2-dependent apoptosis upon Shigella infection

An integrated view of humoral innate immunity: pentraxins as a paradigm

PTX3, a humoral pattern recognition molecule at the interface between microbe and matrix recognition

Non-redundant role of the long pentraxin PTX3 in anti-fungal innate immune response

Pathogen recognition by the long pentraxin PTX3

The humoral pattern recognition molecule PTX3 is a key component of innate immunity against urinary tract infection

Role of complement and Fc {gamma} receptors in the protective activity of the long pentraxin PTX3 against Aspergillus fumigatus

Recognition of Neisseria meningitidis by the long pentraxin PTX3 and its role as an endogenous adjuvant

The therapeutic potential of the humoral pattern recognition molecule PTX3 in chronic lung infection caused by Pseudomonas aeruginosa

Shigella flexneri induces apoptosis in infected macrophages

The secretion of the Shigella flexneri Ipa invasins is activated by epithelial cells and controlled by IpaB and IpaD

Functional insights into the Shigella type III needle tip IpaD in secretion control and cell contact

PTX3 as a paradigm for the interaction of pentraxins with the complement system

Differences among Shigella spp. in susceptibility to the bactericidal activity of human serum

Murine splenocyte proliferation by porin of Shigella dysenteriae type 1 and inhibition of bacterial invasion of HeLa cell by anti-porin antibody

IpaD localizes to the tip of the type III secretion system needle of Shigella flexneri

Anti-Aspergillus fumigatus efficacy of pentraxin 3 alone and in combination with antifungals

Exogenous pentraxin 3 restores antifungal resistance and restrains inflammation in Murine Chronic Granulomatous Disease

Efficacy of PTX3 in a rat model of invasive aspergillosis

Prototypic long pentraxin PTX3 is present in breast milk, spreads in tissues, and protects neonate mice from Pseudomonas aeruginosa lung infection

Response of cftr-deficient mice to long-term chronic Pseudomonas aeruginosa infection and PTX3 therapy

Protective effects of long pentraxin PTX3 on lung injury in a severe acute respiratory syndrome model in mice

Antiviral activity of the long chain pentraxin PTX3 against influenza viruses

Shigella vaccine development: prospective animal models and current status

Antibody and cytokine responses in a mouse pulmonary model of Shigella flexneri serotype 2a infection

Analysis of virulence and inflammatory potential of Shigella flexneri purine biosynthesis mutants

Clearance of Shigella flexneri infection occurs through a nitric oxide-independent mechanism

The IpaC carboxyterminal effector domain mediates Src-dependent actin polymerization during Shigella invasion of epithelial cells

Pattern recognition receptors and inflammation

Two msbB genes encoding maximal acylation of lipid A are required for invasive Shigella flexneri to mediate inflammatory rupture and destruction of the intestinal epithelium

TLR4 and infectious disease diversity

Differential activation of human and mouse Toll-like receptor 4 by the adjuvant candidate LpxL1 of Neisseria meningitidis

Interleukin 1 is released by murine macrophages during apoptosis induced by Shigella flexneri

Antibacterial effect of porcine PTX3 against Streptococcus suis type 2 infection

Pentraxin 3 protects from MCMV infection and reactivation through TLR sensing pathways leading to IRF3 activation

O-specific [corrected] polysaccharide conjugate vaccine-induced [corrected] antibodies prevent invasion of Shigella into Caco-2 cells and may be curative

Shigella IpaB and IpaD displayed on L. lactis bacterium-like particles induce protective immunity in adult and infant mice

Neutrophil infiltration and chemokines

Regulation of leukocyte recruitment by the long pentraxin PTX3

Phase 1 clinical trial of live attenuated Shigella dysenteriae type-1 DeltaicsA Deltaent Deltafep DeltastxA:HgR oral vaccine SC599 in healthy human adult volunteers

Persisting high levels of plasma pentraxin 3 over the first days after severe sepsis and septic shock onset are associated with mortality

Circulating levels of the long pentraxin PTX3 correlate with severity of infection in critically ill patients

Immunoregulatory effects on Caco-2 cells and mice of exopolysaccharides isolated from Lactobacillus acidophilus NCFM

TNFα-Induced Long Pentraxin PTX3 Expression in Human Lung Epithelial Cells via JNK

The humoral pattern recognition receptor PTX3 is stored in neutrophil granules and localizes in extracellular traps

An acidic microenvironment sets the humoral pattern recognition molecule PTX3 in a tissue repair mode

Involvement of a plasmid in the invasive ability of Shigella flexneri

Bacterial genetics by flow cytometry: rapid isolation of Salmonella typhimurium acid-inducible promoters by differential fluorescence induction

Draft genomes of Shigella strains used by the STOPENTERICS consortium

A stepwise procedure for isolation of murine bone marrow and generation of dendritic cells

We thank Eleonora Ventola and Giulia Nigro for technical help, Maria Rescigno for helpful discussions, Abdel Allaoui (Universitè Libre de Bruxelles) for the gift of the anti-IpaD antibody, Philippe Sansonetti for the gift of the strain M90T ΔmsbB1 ΔmsbB2, Gabriella Girelli for