Background
Innate immune system plays a primary role in the rapid elimination of invading microorganisms, which occurs via the recognition of microbial pathogen-associated molecular patterns by the cellular pattern recognition receptors [
1,
2]. Intracellular nucleotide binding domain leucine-rich repeat-containing receptor (NLR) can recognize microbial components that are transported to the cytoplasm through the bacterial secretion system, which can then activate inflammasome signalling [
3,
4]. During this process, pro-caspase-1 is synthesized by activated macrophages and enriched in the inflammasome, ultimately being cleaved into the activated caspase-1 [
5]. Activation of caspase-1 subsequently triggers IL-1β/IL-18 maturation and macrophage pyroptotic death. This pathway is important to defend against the colonization of intracellular bacteria in the intestinal tract and systemic circulation [
6‐
8].
After infection,
Salmonella can selectively secret cytoplasmic effectors through its type III secretion system (T3SS) [
9‐
11]. These effectors regulate the host cells’ defense mechanisms to ensure the survival of the invading bacteria [
12,
13]. Infection of
Salmonella can result in both decreased breeding potential and increased fatality in host organism. Therefore, a key defensive step to protect against
Salmonella infection is to reduce bacterial intracellular survival. Currently, there is no effective approach to induce adaptive immunity during the early stages of a
Salmonella infection, thus it is critical to focus on innate immunity.
During the early stage of infection,
Salmonella T3SS1 effectors are expressed to mediate bacterial infection. Once
Salmonella enters host cells, T3SS2 effectors are expressed in order to mediate bacterial intracellular survival [
14]. Though many proteins of
Salmonella can activate intracellular inflammasome response, over the course of evolution,
Salmonella has developed the ability to escape the inflammasome responses. This can occur through the T3SS1 protein PrgJ that can activate the NLRC4 inflammasome in macrophages, but is only expressed during the early stage of infection. When
Salmonella successfully survives intracellularly, it no longer express PrgJ [
15]. This suggests that if
Salmonella strain can persistently express and transport PrgJ to the cytoplasm of host cells, it can enhance the activation of inflammasome and thereby inhibit the intracellular survival of bacteria [
16]. It has also been reported that the immunization of the
Listeria monocytogenesis strain that can enhance caspase-1 activation can confer protective immunity against a subsequent wild-type challenge [
17]. Thus, it has been hypothesized that the
Salmonella strain with the ability to enhance caspase-1 activation can strengthen the cell’s defense against
Salmonella infection [
18].
Previous reports have suggested that inflammasome activation mechanism can be used in the design of recombinant vaccines to limit the colonization of intracellular bacteria in vivo [
19]. As previously reported, the N-terminus signal peptide of the
Salmonella effector SspH2 can be recognized by T3SS2 and transported into the cytoplasm [
20,
21]. The C-terminus of
E. coli EscI protein can activate the NLRC4 (NLR family, CARD domain containing-4) inflammasome in macrophages [
15]. In the present study, a recombinant
Salmonella fusion expressing the N-terminus of
Salmonella SspH2 and the C-terminus of
E. coli EscI was constructed. The recombinant strain was tested for its ability to activate inflammasome and colonize in vivo in mouse.
Methods
Animals, plasmids and bacteria
Six-week-old female C57BL/6 mice were obtained from the Comparative Medicine Center of Yangzhou University (Yangzhou, China). This study was carried out in accordance with the regulations established by the Chinese Ministry of Science and Technology. The animal experiment protocol was approved by the Committee on the Ethics of Animal Experiments of Yangzhou University (Permit Number: 2007–0005). All surgery was performed under sodium pentobarbital anesthesia, and all efforts were made to minimize suffering.
Plasmids pMD20 T (Amp
+) and pYA3334 (asd
+),
E. coli DH5α (RˉMˉ, Ampˉ) and X6212 (asdˉ, NA
+, RˉM
+), attenuated
S. Typhimurium strains X3730 (GalEˉ, Hsdˉ, Asdˉ, NA
+, RˉM
+) and X4550 (△crp-1, △cya-1, asdˉ, NA
+, RˉM
+) were used in this study as previously described [
22,
23].
S. Enteritidis C50041 and
E. coli O:157 were used for the amplification of
sspH2 and
escI genes, respectively. Bacterial strains were grown in Luria broth (LB) medium.
Construction of recombinant plasmid and S. typhimurium expressing SspH2-EscI fusion protein
The genomic DNA of bacteria C50041 and O:157 were extracted using the high pure PCR template preparation kit (Takara, Dalian, China) according to the manufacturer’s instructions. The nucleotide sequences of primers for polymerase chain reaction (PCR) were shown in Table
1, with the underlined segments indicating the restriction sites. The 5’-terminal sequence (1–453 bp) of the
sspH2 gene was amplified from the C50041 strain using the primers SspH2-F1 (forward primer) and SspH2-R1 (reverse primer). The 3’-terminal sequence (205–426 bp) of the
escI gene was amplified from O:157 strain using the primers EscI-F1 (forward primer) and EscI-R1 (reverse primer). The above two purified PCR products were then mixed for the overlap PCR splicing using the primers SspH2-F1 and EscI-R1. All PCR products were subsequently identified via agarose gel electrophoresis. The purified PCR product
sspH2-escI (729 bp) was cloned into the plasmid pMD20 T and the recombinant plasmid was then transformed into
E.coli DH5α for amplification. The recombinant plasmid was verified by restriction digestion and DNA sequencing. After digestion with
Nco I and
Sal I (Takara), the
sspH2-escI gene was cloned into the plasmid pYA3334. The recombinant plasmid was named as pYA3334-SspH2-EscI and transformed into
E.coli X6212. The recombinant plasmid pYA3334-SspH2-EscI was verified by enzyme digestion and DNA sequencing. The plasmid pYA3334-SspH2-EscI was then transformed into
S. typhimurium X3730 for methylation modification. Finally, the modified plasmid pYA3334-SspH2-EscI was transformed into
S. typhimurium X4550. The recombinant bacteria were designated as X4550(pYA3334-SspH2-EscI).
Table 1
The primer sequences used in this study
The purified PCR product sspH2 amplified from the C50041 strain using the primers SspH2-F1 (forward primer) and SspH2-R4 (reverse primer) was cloned into the plasmid pYA3334. The recombinant plasmid was named as pYA3334-SspH2 and the corresponding recombinant bacteria was named as X4550(pYA3334-SspH2).
The plasmid pYA3334 was used as a negative control and the corresponding recombinant bacteria was named as X4550(pYA3334).
Growth curve of recombinant S. typhimurium strains
The growth characteristic of recombinant bacteria was performed as previously described [
23]. Briefly, single colony of recombinant bacteria was inoculated in LB medium. After being cultured with shaking at 37 °C overnight, 50 μl of bacteria was inoculated in 5 ml LB medium and cultured with shaking at 37 °C. OD600 was measured at different time to obtain the growth curve.
In vitro infection of mouse peritoneal macrophages
Peritoneal cells were collected by lavaging the mouse peritoneal cavity using RPMI 1640 culture medium supplemented with 10% fetal bovine serum (FBS) (Gibco, Carlsbad, CA). After washing with phosphate buffer saline (PBS), cells were suspended in RPMI 1640 complete medium (RPMI 1640 containing 10% FBS), seeded on 96-well plates, and cultured at 37 °C in 5% CO2 for 3 h.
Non-adherent cells were removed and cell density was adjusted to 20,000 cells per well. The adherent cells were pre-stimulated with 1 μg/ml
E. coli lipopolysaccharide (LPS) (Sigma-Aldrich) to induce the expression of pro-IL-1β. The freshly cultured X4550(pYA3334-SspH2-EscI), X4550(pYA3334-SspH2) and X4550(pYA3334) were centrifuged at 1500 ×
g for 10 min and washed with PBS. The bacteria were resuspended in RPMI 1640 complete medium and added to the LPS-stimulated cells to the desired multiplicity of infection (MOI = 10, 50 and 100, respectively). The cell plate was centrifuged at 500 ×
g for 10 min to enhance the contact of bacteria with the cells. Infected cells were incubated at 37 °C for 30 min. The supernatants were then removed and washed with RPMI 1640 complete medium. Subsequently, RPMI 1640 complete medium containing 100 U/ml penicillin, 100 μg/ml streptomycin, and 1 μg/ml LPS were added to the cells (100 μl/well) to kill the extracellular bacteria. Cells were remained in culture at 37 °C and 5% CO
2 for four hours [
24,
25]. In all experiments, uninfected cells were used as controls. The cell morphology was observed using TS100-F inverted microscope (Nikon, Japan).
After culturing, the supernatants were collected and centrifuged at 2000 × g for 5 min to remove all dead bacteria and debris. Quantification of IL-1β and IL-18 was performed using cytometric bead array system (CBA) mouse IL-1β Flex Set and enzyme-linked immunosorbent assay kit (Biosciences, PharMingen, San Diego, CA) according to the manufacturer’s instructions. The flow cytometry was performed using FACSAria flow cytometer with FACSDiva software (Becton-Dickinson Immunocytometry Systems, BDIS, San Jose, CA).
The lactate dehydrogenase (LDH) release was measured using the cytotoxicity detection kit (Roche, Switzerland) according to the manufacturer’s instructions. The relative amount of released LDH was calculated as follows: %released LDH (sample) = (sample − medium background)/(total LDH − medium background) × 100% [
26].
Cell plates were washed with PBS and the cells were collected for counting. Then the cells were lysed with lysing solution containing 1 mM phenylmethanesulfonyl fluoride (Westang, Shanghai) according to the manufacturer’s instructions. The intracellular bacteria were counted by coating on the LB agar plate containing NA (20 μg/ml) for culturing.
The intracellular caspase-1 activation were determined by FLICATM caspase-1 detection kit (Immunochemistry Technoligies Inc., Bloomington, MN) using flow cytometry according to the manufacturer’s instructions.
In vivo infection of mice
The freshly cultured bacteria were centrifuged at 1500 × g for 10 min and washed with PBS. Six-week-old C57BL/6 mice were intravenously injected with X4550(pYA3334), X4550(pYA3334-SspH2) and X4550(pYA3334-SspH2-EscI), respectively. Each mouse was infected with 1× 106 cfu using 100 μl PBS as vehicle. The mice intravenously injected with equivalent PBS were used as controls.
At different time points post-infection, the spleen and liver of mice were harvested to determine bacterial colonization. Briefly, the weight and size of the tissues were recorded. After grinding in 5 ml PBS, the suspension of spleen and liver tissues were ten-fold diluted in PBS and 100 μl suspension were then evenly plated on the LB agar containing nalidixic acid (NA, 20 μg/ml) for CFU enumeration.
Three weeks after infection, the pathological section of spleen and liver of mice were examined using hematoxylin-eosin (HE) staining.
Quantification of IL-6 and TNF-α were performed using CBA mouse inflammation kit (Biosciences, PharMingen, San Diego, CA) according to the manufacturer’s instructions.
Statistical analysis
Within each experiment, three to four replicate assays were conducted for each treatment and the average value was calculated for final statistical comparisons. All statistical analyses were performed by t-tests using SPSS software (Version 13.0 for Windows, Chicago, IL). A value of P ≤ 0.05 was considered to be statistically significant.
Discussion
Activation of NLR by microbial components can result in the subsequent activation of inflammasome in macrophages [
1,
2] and is beneficial for the defense against intracellular bacteria [
7,
8,
27,
28]. This is particularly important for the protection of intestinal mucosa and defense against systemic infection [
6,
29]. Currently, the inflammasome mechanism has been predominantly stimulated with peptides in vitro [
15]. However, due to the complex regulation by bacteria in the host cells, the responses of host cells against these peptides may be different from their response against the whole bacterium. Thus, it is more practical to study the inflammasome responses through bacterial infection, rather than peptide treatment. It has been reported that the recombinant
Listeria monocytogenes that can enhance inflammasome response is attenuated and has a protective effect against virulent bacteria challenge [
17]. Based on these previous findings, it has been suggested that an attenuated
Salmonella vaccine candidate that enhances the inflammasome responses can also elevate cellular immunity against subsequent
Salmonella infection [
18]. To test this possibility, we sought to construct a recombinant
Salmonella strain that can enhance inflammasome activation.
Salmonella pathogenicity islands (SPI)-1 and −2 express T3SS1 and T3SS2, respectively [
30]. SPI-1 is mainly expressed in the intestines to promote the invasion of
Salmonella into epithelial cells, while SPI-2 is mainly expressed in host cells to augment the survival of
Salmonella in macrophages [
14]. Reports have shown that NLRC4 can sense
Salmonella proteins PrgJ and flagellin, which both contain a common C-terminal amino acid sequence [
15,
26,
31]. However, over the course of its evolution,
Salmonella has developed many evasion strategies to prevent NLRC4 detection in macrophages. For instance, SPI-1 and SPI-2 encode the rod proteins PrgJ and SsaI respectively, which form the needle in T3SS basal body [
32]. NLRC4 can sense PrgJ, but not SsaI, due to one amino acid difference (V95) in the C-terminus between them [
15]. Moreover, flagellin is repressed in the intracellular environment while SPI-2 T3SS is active [
16,
33]. Taken together, it has been hypothesized that recombinant
Salmonella expressing flagellin or PrgJ from a SPI-2 co-regulated promotor can be persistently detected via NLRC4 and completely cleared in vivo [
16]. As reported,
Salmonella effector SspH2 can be translocated by T3SS2 and colocalize with the polymerizing actin cytoskeleton [
20]. The recombinant
Salmonella expressing fusion protein of SspH2 and exogenous antigen can translocate the latter into the cytoplasm of macrophages [
20,
21,
34,
35]. Furthermore, the SspH2 N-terminal amino acid sequence is conserved among different
Salmonella strains and can be used as an efficient delivery vector [
20]. EscI protein, the inner rod protein of enteropathogenic
E. coli, is secreted in the early stage of infection [
36,
37] and its C-terminal sequence can activate the NLRC4 inflammasome [
15]. In this experiment, the N-terminus of SspH2 and the C-terminus of EscI were selected to construct the recombinant
Salmonella expressing fusion protein SspH2-EscI.
Salmonella lacking
asd gene has an obligatory requirement for DAP because the
asd mutant will undergo lysis in environments deprived of DAP. The
asd + plasmid containing the wild-type
asd gene can complement the mutants to become a stable balanced-lethal system and be used to express exogenous antigens [
38]. The △
crp △
cya Salmonella strain X4550 is avirulent and immunogenic in mice, and introduction of
asd + plasmid pYA3334 into X4550 could completely restore avirulent [
22]. It is reported that X4550 still can survive in mice for a long time [
23]. Therefore, X4550 is usually used to express exogenous antigen to promote immunity without any antibiotic selection. In this experiment, X4550 was selected as the vector to express and transport fusion protein SspH2-EscI.
The intracellular caspase-1 activation and secretion of IL-1β and IL-18 are essential for inflammasome response in macrophages [
7]. The recombinant bacteria expressing SspH2-EscI could significantly promote the secretion of IL-1β and IL-18 and the pyroptotic cell death of macrophages in in vitro infection when compared with bacteria expressing SspH2 only, suggesting that the intracellular recombinant
Salmonella can successfully express fusion protein SspH2-EscI and the SspH2 N-terminus can be used as a signal to deliver EscI C-terminus into the host cells, resulting in activation of the NLRC4 inflammasome. Furthermore, in in vivo infection, the expression of SspH2-EscI, but not SspH2 alone, could inhibit the colonization of recombinant bacteria, suggesting that reduction of bacterial colonization in mice may be due to the activation of NLRC4 inflammasome by EscI in the cytoplasm.
So far, there are different interpretations about how the inflammasome pathway is used during immune defense [
39]. Pyroptosis can lyse the host cells and the pathogen can then be phagocytosed by neutrophils, resulting in bacterial death. As reported, a
sifA gene-mutated
Salmonella can destroy the
Salmonella-containing vacuole due to caspase-11 activation, but not due to the secretion of IL-1β and IL-18. It is also reported that the clearance of
Burkholderia occurs, in part, due to the secretion of IL-1β and IL-18 after nasal infection. This indicates that pyroptosis is a defense mechanism to clear intracellular bacteria [
40]. The anti-infection defense of recombinant
L. monocytogenes that enhanced the inflammasome activation is due to caspase-1-induced pyroptosis, but not due to the secretion of IL-1β and IL-18 [
17]. In this experiment, the inhibition of
Salmonella colonization in mice several days after intravenous infection may be due to the pyroptosis observed in the earlier stages of infection. The definite mechanism should be further studied in the future using NLRC4¯ mice.
The inflammasome pathway was first named and characterized in 2002 [
41] and has since seen great effort to elucidate its mechanism of action. This work can also lead to some applications, especially in the attenuated vaccine design. Because activated inflammasome is not specific to a particular bacteria, this will provide a general platform for the development of vaccine of not only
Salmonella, but also other intracellular pathogens.
Acknowledgements
This work was supported by the National Natural Science Foundation of China (31320103907, 31372414, 31372415) and the Priority Academic Program Development of Jiangsu Higher Education Institutions.