Inflammasomes primarily restrict cytosolic Salmonella replication within human macrophages

Marisa S. Egan; Emily A. O’Rourke; Shrawan Kumar Mageswaran; Biao Zuo; Inna Martynyuk; Tabitha Demissie; Emma N. Hunter; Antonia R. Bass; Yi-Wei Chang; Igor E. Brodsky; Sunny Shin

doi:10.7554/eLife.90107.1

eLife assessment

This important paper provides insights into the role of the inflammasomes in the control of Salmonella replication within human macrophages. Solid evidence is provided that in the absence of inflammasome signaling that Salmonella replicated in the macrophage cytosol. This paper will be of broad interest to cell biologists, immunologists and microbiologists.

https://doi.org/10.7554/eLife.90107.1.sa3

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Abstract

Salmonella enterica serovar Typhimurium is a facultative intracellular pathogen that utilizes its type III secretion systems (T3SSs) to inject virulence factors into the host cell and colonize the host. In turn, a subset of cytosolic immune receptors respond to T3SS ligands by forming multimeric signaling complexes called inflammasomes, which activate caspases that induce interleukin-1 (IL-1) family cytokine release and an inflammatory form of cell death called pyroptosis. Human macrophages mount a multifaceted inflammasome response to Salmonella infection that ultimately restricts intracellular bacterial replication. However, how inflammasomes restrict Salmonella replication remains unknown. We find that caspase-1 is essential for mediating inflammasome responses to Salmonella and subsequent restriction of bacterial replication within human macrophages, with caspase-4 contributing as well. We also demonstrate that the downstream pore-forming protein gasdermin D (GSDMD) and ninjurin-1 (NINJ1), a mediator of terminal cell lysis, play a role in controlling Salmonella replication in human macrophages. Notably, in the absence of inflammasome responses, we observed hyperreplication of Salmonella within the cytosol of infected cells, and we also observed increased bacterial replication within vacuoles, suggesting that inflammasomes control Salmonella replication primarily within the cytosol and also within vacuoles. These findings reveal that inflammatory caspases and pyroptotic factors mediate inflammasome responses that restrict the subcellular localization of intracellular Salmonella replication within human macrophages.

Introduction

Intracellular bacterial pathogens create and maintain replicative niches within host cells. To survive inside the host, these pathogens must remodel the host cellular landscape and overcome immune defenses. Salmonella enterica serovar Typhimurium (Salmonella) is a facultative intracellular pathogen and a major cause of food-borne illness worldwide (Majowicz et al., 2010). Following ingestion, Salmonella colonizes the intestinal tract, where it can invade, replicate, and survive in host cells, including macrophages (Crowley et al., 2016; R. L. Santos & Bäumler, 2004). Salmonella employs type III secretion systems (T3SSs) that act as molecular syringes to inject virulence factors, or effectors, into the host cell cytosol (Agbor & McCormick, 2011; Crowley et al., 2016). Specifically, Salmonella relies on two distinct T3SSs encoded on Salmonella Pathogenicity Islands 1 and 2 (SPI-1 and SPI-2) to invade and replicate within host cells, respectively (Mills et al., 1995; Shea et al., 1996; Hensel et al., 1998; Galan & Zhou, 2000; Galán, 1999; Galán & Collmer, 1999; Galan & Curtiss, 1989; Ochman et al., 1996; Cirillo et al., 1998). The SPI-2 T3SS translocates effectors to facilitate biogenesis and maintenance of the Salmonella-containing vacuole (SCV), wherein Salmonella resides and replicates (Cirillo et al., 1998; Takeuchi, 1967; Takeuchi & Sprinz, 1967; Kihlström & Latkovic, 1978; Garcia-del Portillo et al., 1993; Garcia-del Portillo & Finlay, 1995; Steele-Mortimer et al., 1999; Hansen-Wester et al., 2002; Steele-Mortimer, 2008; Jennings et al., 2017; Brumell, Goosney, et al., 2002; Brumell, Tang, et al., 2002; Beuzón et al., 2000; Hensel et al., 1998). In epithelial cells, Salmonella escapes its vacuolar niche and hyperreplicates in the host cell cytosol (Knodler, Crowley, et al., 2014; Knodler et al., 2010; Knodler, Nair, et al., 2014; Malik-Kale et al., 2012). While T3SSs are essential for Salmonella to infect host cells, they also inject flagellin (Sun et al., 2007) and structural components of the T3SS into the host cell cytosol, which conversely leads to cytosolic immune detection of Salmonella.

The mammalian innate immune system detects violations of cytosolic sanctity, such as the presence of intracellular bacterial pathogens, through cytosolic pattern recognition receptors (PRRs) (Janeway, 1989; Medzhitov & Janeway, 2002). A subset of these PRRs includes the nucleotide-binding domain, leucine-rich repeat (NLR) family proteins. NLRs respond to their cognate stimuli by oligomerizing and inducing the assembly of multiprotein complexes termed inflammasomes, which activate inflammatory caspases (Broz & Dixit, 2016; Lamkanfi & Dixit, 2009, 2014; Martinon et al., 2002). Canonical inflammasomes recruit and activate caspase-1, which cleaves and activates pro-inflammatory interleukin-1 (IL-1) family cytokines and the pore-forming protein gasdermin D (GSDMD) (Kuida et al., 1995; Li et al., 1995; Agard et al., 2010; Thornberry et al., 1992; Shi et al., 2015; Kayagaki et al., 2015). Alternatively, noncanonical inflammasomes are formed by caspase-11 in mice and two orthologs in humans, caspase-4 and caspase-5, in response to cytosolic lipopolysaccharide (LPS) (Casson et al., 2015; Hagar et al., 2013; Kayagaki et al., 2011, 2013; Lagrange et al., 2018; Schmid-Burgk et al., 2015; Shi et al., 2014). These caspases directly process and activate GSDMD (Agard et al., 2010; Kayagaki et al., 2015; Shi et al., 2015). Liberated GSDMD N-terminal fragments oligomerize to create pores in the host plasma membrane, through which IL-1 family cytokines and other alarmins are released to promote a lytic form of inflammatory cell death termed pyroptosis (Agard et al., 2010; Ding et al., 2016; Kayagaki et al., 2015; Shi et al., 2015).

Salmonella activates several inflammasomes in human macrophages. One such inflammasome is the NLR family, apoptosis inhibitory protein (NAIP)/NLR family, CARD domain-containing protein 4 (NLRC4) inflammasome (Bierschenk et al., 2019; Gram et al., 2021; Naseer, Egan, et al., 2022). NAIP detects the cytosolic presence of T3SS structural components and flagellin (Grandjean et al., 2017; Kofoed & Vance, 2011; Kortmann et al., 2015; Miao, Mao, et al., 2010; Molofsky et al., 2006; Rauch et al., 2016; Rayamajhi et al., 2013; Ren et al., 2006; Reyes Ruiz et al., 2017; Sun et al., 2007; Yang et al., 2013; Zhao et al., 2011, 2016). Upon ligand recognition, NAIP recruits NLRC4, which oligomerizes to form the active NAIP/NLRC4 inflammasome (Diebolder et al., 2015; Z. Hu et al., 2015; Zhang et al., 2015). Salmonella also activates the NLR pyrin domain-containing protein 3 (NLRP3) inflammasome and the noncanonical inflammasome in human macrophages (Bierschenk et al., 2019; Casson et al., 2015; Gram et al., 2021; Naseer, Egan, et al., 2022). NLRP3 responds to diverse stimuli, including ionic fluxes as a result of host plasma membrane damage (Franchi et al., 2007; Hornung et al., 2008; Mariathasan et al., 2006; Muñoz-Planillo et al., 2013; Perregaux & Gabel, 1994), and can be secondarily activated by the noncanonical inflammasome (Baker et al., 2015; Casson et al., 2015; Kayagaki et al., 2013; Pilla et al., 2014; Rathinam et al., 2012; Rühl & Broz, 2015; Schmid-Burgk et al., 2015; Shi et al., 2014).

Inflammasome activation is critical for host defense against Salmonella. In mice, the NAIP/NLRC4 inflammasome is required to control Salmonella infection (Carvalho et al., 2012; Franchi et al., 2012; Hausmann et al., 2020; Miao et al., 2006; Miao, Mao, et al., 2010; Rauch et al., 2016, 2017; Sellin et al., 2014; Zhao et al., 2016). In murine intestinal epithelial cells (IECs), NAIP/NLRC4 inflammasome activation triggers pyroptosis and expulsion of infected cells, and is both necessary and sufficient in IECs to restrict Salmonella replication and prevent bacterial dissemination to distal organ sites (Hausmann et al., 2020; Rauch et al., 2017; Sellin et al., 2014). Unlike murine IECs, human epithelial cells do not rely on NAIP/NLRC4 or caspase-1, but instead rely on caspase-4 to control Salmonella replication, in part through pyroptosis and cell extrusion (Holly et al., 2020; Knodler, Crowley, et al., 2014; Knodler et al., 2010; Naseer, Zhang, et al., 2022). Moreover, in murine macrophages, inflammasome activation controls the replication of a mutant strain of Salmonella that aberrantly invades the cytosol, but only slightly limits replication of wild-type (WT) Salmonella (Thurston et al., 2016). In contrast, we found that human macrophages rely on NAIP/NLRC4- and NLRP3-dependent inflammasome responses to control intracellular WT Salmonella replication (Naseer, Egan, et al., 2022). However, how inflammasome signaling restricts Salmonella replication in human macrophages remains unknown.

In this study, we show that caspase-1 is required for inflammasome responses and the restriction of intracellular Salmonella replication early during infection in human macrophages, and that caspase-4 contributes to the restriction of Salmonella later during infection. We find that the cell lysis mediators GSDMD and ninjurin-1 (NINJ1) contribute to bacterial restriction. Importantly, we observed that while human macrophages unable to undergo inflammasome responses showed slightly elevated bacterial replication within SCVs, they became permissive to hyperreplication of Salmonella within the cytosolic compartment. Thus, inflammasome activation appears to preferentially restrict cytosolic Salmonella replication. Our results offer insight into how inflammasomes control Salmonella in human macrophages and restrict the distinct intracellular spatial niches that Salmonella occupy in these cells.

Results

Caspase-1 promotes the control of Salmonella replication within human macrophages

Human macrophages undergo NAIP/NLRC4- and NLRP3-dependent inflammasome activation during Salmonella infection (Bierschenk et al., 2019; Gram et al., 2021; Naseer, Egan, et al., 2022), which restricts intracellular Salmonella replication (Naseer, Egan, et al., 2022). Nonetheless, how inflammasome activation controls Salmonella replication in human macrophages remains unclear. Inflammasomes recruit and activate caspase-1 in both murine and human cells (Franchi et al., 2006; Man, Hopkins, et al., 2014; Mariathasan et al., 2004; Miao et al., 2006; Ross et al., 2022; Zamboni et al., 2006), and caspase-1 promotes the control of Salmonella both in vivo and in vitro (Broz et al., 2010, 2012; Crowley et al., 2020; Hausmann et al., 2020; Holly et al., 2020; Lara-Tejero et al., 2006; Miao, Leaf, et al., 2010; Rauch et al., 2017; Raupach et al., 2006; Sellin et al., 2014; Thurston et al., 2016). Thus, we sought to test whether caspase-1 restricts Salmonella replication in human macrophages.

To first interrogate the impact of caspase activity on Salmonella replication in human macrophages, we pretreated macrophages derived from the human monocytic cell line, THP-1, with Ac-YVAD-cmk (YVAD), a chemical inhibitor of caspase-1 activity, or Z-VAD-FMK (ZVAD), a pan-caspase inhibitor. Upon infection with wild-type (WT) Salmonella, WT THP-1 cells pretreated with either YVAD or ZVAD had significantly reduced levels of IL-1β secretion and cell death compared to infected WT cells pretreated with DMSO, the vehicle control (Figure 1 – figure supplement 1A-B). Since pretreatment with YVAD largely phenocopies ZVAD, these data suggest that caspase-1 is the primary caspase that responds to Salmonella infection in THP-1 cells. We next assessed intracellular Salmonella burdens by determining bacterial colony forming units (CFUs). The increase in bacterial CFUs was significantly higher in WT cells pretreated either YVAD or ZVAD compared to cells pretreated with DMSO (Figure 1 – figure supplement 1C). Microscopic analysis revealed that WT cells treated with either YVAD or ZVAD prior to infection harbored significantly higher intracellular Salmonella burdens compared to cells pretreated with DMSO (Figure 1 – figure supplement 1D). Overall, these results suggest that caspase activity, primarily caspase-1 activity, controls Salmonella burdens in human macrophages.

Next, to genetically test the requirement of caspase-1, we used two independent CASP1^-/- THP-1 single cell clones generated through CRISPR/Cas9-mediated deletion (Okondo et al., 2017). In agreement with previous reports (Bierschenk et al., 2019; Gram et al., 2021; Naseer, Egan, et al., 2022), WT THP-1 cells infected with WT Salmonella exhibited high levels of IL-1β, IL-18, and IL-1α release as well as cell death at 6 hpi (Figure 1A-B; Figure 1 – figure supplement 2A-B). In contrast, CASP1^-/- THP-1 cells released negligible levels of inflammasome-dependent cytokines and did not undergo substantial cell death upon infection (Figure 1A-B; Figure 1 – figure supplement 2A-B). Infected WT and CASP1^-/- THP-1 cells released similar levels of the inflammasome-independent cytokine TNF-α (Figure 1 – figure supplement 2C). These results indicate that caspase-1 is required for inflammasome responses to Salmonella infection in human macrophages.

Caspase-1 promotes the control of *Salmonella* replication within human macrophages.
WT and two independent clones of *CASP1*^-/- THP-1 monocyte-derived macrophages were primed with 100 ng/mL Pam3CSK4 for 16 hours. Cells were then infected with PBS (Mock), WT S. Typhimurium (A, B, C), or WT S. Typhimurium constitutively expressing GFP (D,E) at an MOI = 20. (A) Release of IL-1β into the supernatant was measured by ELISA at 6 hpi. (B) Cell death (percentage cytotoxicity) was measured by lactate dehydrogenase release assay and normalized to mock-infected cells at 6 hpi. (C) Cells were lysed at 1 hpi and 6 hpi, and bacteria were subsequently plated to calculate CFU. Fold-change in CFU/well was calculated. (D, E) Cells were fixed at 6 hpi and stained for DAPI to label DNA (blue). (D) The number of bacteria per cell at 6 hpi was scored by fluorescence microscopy. Each small dot represents one infected cell. 150 infected cells were scored for each genotype. (E) Representative images are shown. Scale bar represents 10 µm. Bars represent the mean for each genotype, and error bars represent the standard deviation of triplicate wells from one experiment (A, B, C, D). ***p < 0.001, ****p < 0.0001 by Dunnett’s multiple comparisons test (A, B, C, D). Data shown are representative of at least three independent experiments.

We next tested whether caspase-1 is required to restrict Salmonella replication in human macrophages. At 1 hour post-infection (hpi), we did not observe any significant differences in bacterial uptake between WT and CASP1^-/- THP-1 cells (Figure 1 – figure supplement 2D). However, at 6 hpi, CASP1^-/- cells harbored significantly higher bacterial burdens and a significant fold-increase in bacterial CFUs compared to WT cells (Figure 1C; Figure 1 – figure supplement 2E). To assess intracellular bacterial burdens on a single-cell level, we quantified the amount of WT Salmonella per cell by microscopy. WT cells contained relatively low numbers of Salmonella on average (∼5 bacteria per cell), while CASP1^-/- cells harbored significantly higher numbers of Salmonella on average (∼30 bacteria per cell) at 6 hpi (Figure 1D-E). Overall, these data indicate that caspase-1 limits intracellular Salmonella replication in human macrophages.

Caspase-4 contributes to the control of Salmonella replication within human macrophages later during infection

Caspase-11 is another member of the inflammatory caspase family, and plays a role in host defense against Salmonella in mice (Aachoui et al., 2013; Crowley et al., 2020; Knodler, Crowley, et al., 2014; Sellin et al., 2014). Humans harbor two orthologs of murine caspase-11: caspase-4 and caspase-5 (Shi et al., 2014). Caspases-11/4/5 recognize cytosolic LPS and form the noncanonical inflammasome to mediate downstream inflammatory responses (Casson et al., 2015; Hagar et al., 2013; Kayagaki et al., 2011, 2013; Lagrange et al., 2018; Schmid-Burgk et al., 2015; Shi et al., 2014). Caspase-4 contributes to inflammasome responses during Salmonella infection of THP-1 macrophages and primary human macrophages (Casson et al., 2015; Naseer, Egan, et al., 2022), and caspases-4/5 are required for inflammasome responses to Salmonella in THP-1 monocytes (Baker et al., 2015). In human intestinal epithelial cells (IECs), caspase-4 drives inflammasome responses during Salmonella infection and limits intracellular bacterial replication (Holly et al., 2020; Knodler, Crowley, et al., 2014; Naseer, Zhang, et al., 2022). However, whether caspase-4 contributes to restriction of intracellular Salmonella replication within human macrophages is unclear.

To genetically test the contribution of caspase-4 during Salmonella infection in THP-1 macrophages, we used CRISPR/Cas9-mediated deletion to disrupt the CASP4 gene. We selected and sequence-validated two independent CASP4^-/- THP-1 single cell clones (Figure 2 – figure supplement 1). We observed a slight decrease in secreted IL-1β levels in CASP4^-/- THP-1 macrophages infected with WT Salmonella compared to infected WT THP-1 macrophages at 6 hpi (Figure 2 – figure supplement 2A). We also observed a slight decrease in cell death at 6 hpi in infected CASP4^-/- clone #2 compared to infected WT cells, whereas cytotoxicity levels were unaffected in infected CASP4^-/- clone #6 (Figure 2 – figure supplement 2B). However, at 24 hpi, we observed a significant decrease in IL-1 release and cell death in both CASP4^-/- clones infected with WT Salmonella compared to infected WT cells (Figure 2A-B; Figure 2 – figure supplement 3A-B). WT and CASP4^-/- cells also released similar levels of the inflammasome-independent cytokine TNF-α upon infection with WT Salmonella at 24 hpi (Figure 2 – figure supplement 3C). Overall, these data indicate that caspase-4 contributes to inflammasome responses in THP-1 macrophages later during Salmonella infection.

Caspase-4 contributes to the control of *Salmonella* replication within human macrophages later during infection.
WT and two independent clones of *CASP4*^-/- THP-1 monocyte-derived macrophages were primed with 100 ng/mL Pam3CSK4 for 16 hours. Cells were then infected with PBS (Mock), WT S. Typhimurium (A, B, C), or WT S. Typhimurium constitutively expressing GFP (D, E) at an MOI = 20. (A) Release of IL-1β into the supernatant was measured by ELISA at 24 hpi. (B) Cell death (percentage cytotoxicity) was measured by lactate dehydrogenase release assay and normalized to mock-infected cells at 24 hpi. (C) Cells were lysed at 1 hpi and 24 hpi, and bacteria were subsequently plated to calculate CFU. Fold-change in CFU/well was calculated. (D, E) Cells were fixed at 24 hpi and stained for DAPI to label DNA (blue). (D) The number of bacteria per cell at 24 hpi was scored by fluorescence microscopy. Each small dot represents one infected cell. 150 infected cells were scored for each genotype. (E) Representative images are shown. Scale bar represents 10 µm. Bars represent the mean for each genotype, and error bars represent the standard deviation of triplicate wells from one experiment (A, B, C, D). ns – not significant, *p < 0.05 by Dunnett’s multiple comparisons test (A, B, C, D). Data shown are representative of at least three independent experiments.

Since caspase-4 restricts Salmonella replication in human epithelial cells (Holly et al., 2020; Knodler, Crowley, et al., 2014; Naseer, Zhang, et al., 2022), we then asked whether caspase-4 contributes to the control of Salmonella replication in human macrophages. Upon examination of the fold-change in bacterial CFUs at 6 hpi, we did not observe any significant differences between WT and CASP4^-/- THP-1 cells (Figure 2 – figure supplement 2C). However, at 24 hpi, CASP4^-/- cells harbored higher bacterial burdens and a significant fold-increase in bacterial CFUs compared to WT cells (Figure 2C; Figure 2 – figure supplement 3D). To confirm these findings, we enumerated the amount of WT Salmonella per cell by microscopy. At 6 hpi, WT and CASP4^-/- THP-1 cells contained comparable numbers of Salmonella per cell (Figure 2 – figure supplement 2D-E). In contrast, at 24 hpi, CASP4^-/- cells harbored significantly higher burdens of Salmonella per cell on average (∼20 bacteria per cell) compared to WT cells (∼10 bacteria per cell) (Figure 2D-E). Altogether, these results suggest that caspase-4 plays a larger role in controlling Salmonella burdens later during infection.

GSDMD promotes the control of Salmonella replication within human macrophages

Inflammasome activation triggers a lytic form of cell death known as pyroptosis (Lamkanfi & Dixit, 2014). Death of the infected host cell eliminates Salmonella’s intracellular replicative niche and thus, may contribute to restricting intracellular bacterial replication. Upon its cleavage by inflammatory caspases, GSDMD forms pores in the host plasma membrane, resulting in pyroptosis (Agard et al., 2010; Ding et al., 2016; Kayagaki et al., 2015; Shi et al., 2015). Whether GSDMD contributes to the control of Salmonella replication in human macrophages is unknown.

First, we asked whether GSDMD pore formation plays a role in controlling Salmonella replication in human macrophages. To do this, we pretreated THP-1 macrophages and primary human monocyte-derived macrophages (hMDMs) with the chemical inhibitor disulfiram. Disulfiram prevents cleaved GSDMD from inserting into the host plasma membrane, thereby limiting GSDMD-mediated pore formation (J. J. Hu et al., 2020). Disulfiram treatment led to the loss of IL-1β release and cytotoxicity in macrophages infected with WT Salmonella, compared to treatment with the vehicle control, DMSO (Figure 3 – figure supplement 1A-B, D-E). Next, we examined the effect of GSDMD-mediated pore formation on intracellular Salmonella burdens. The fold-increase in bacterial CFUs at 6 hpi was significantly higher in cells treated with disulfiram compared to cells treated with DMSO (Figure 3 – figure supplement 1C, F). Collectively, these results suggest that GSDMD-mediated pore formation promotes the restriction of intracellular Salmonella replication.

Consistent with our findings with disulfiram, we observed a significant decrease in IL-1 cytokine release in GSDMD^-/- THP-1 macrophages (Okondo et al., 2017; Taabazuing et al., 2017) infected with WT Salmonella compared to infected WT THP-1 macrophages (Figure 3A; Figure 3 – figure supplement 2A-B). These results suggest that human macrophages undergo GSDMD-dependent IL-1 release during infection. Interestingly, loss of GSDMD did not completely abrogate the release of IL-1, suggesting that there is also GSDMD-independent IL-1 release (Figure 3A; Figure 3 – figure supplement 2A-B). Infected WT and GSDMD^-/- THP-1 cells secreted similar levels of the inflammasome-independent cytokine TNF-α (Figure 3 – figure supplement 2C). Importantly, infected GSDMD^-/- cells failed to undergo substantial cell death, in contrast to infected WT cells, suggesting that GSDMD facilitates cell death during Salmonella infection (Figure 3B). Overall, these results indicate that GSDMD plays an important role in mediating inflammasome responses during Salmonella infection of human macrophages.

GSDMD promotes the control of *Salmonella* replication within human macrophages.
WT and *GSDMD*^-/- THP-1 monocyte-derived macrophages were primed with 100 ng/mL Pam3CSK4 for 16 hours. Cells were then infected with PBS (Mock), WT S. Typhimurium (A, B, C), or WT S. Typhimurium constitutively expressing GFP (D,E) at an MOI = 20. (A) Release of IL-1β into the supernatant was measured by ELISA at 6 hpi. (B) Cell death (percentage cytotoxicity) was measured by lactate dehydrogenase release assay and normalized to mock-infected cells at 6 hpi. (C) Cells were lysed at 1 hpi and 6 hpi, and bacteria were subsequently plated to calculate CFU. Fold-change in CFU/well was calculated. (D, E) Cells were fixed at 6 hpi and stained for DAPI to label DNA (blue). (D) The number of bacteria per cell at 6 hpi was scored by fluorescence microscopy. Each small dot represents one infected cell. 150 infected cells were scored for each genotype. (E) Representative images are shown. Scale bar represents 10 µm. Bars represent the mean for each genotype, and error bars represent the standard deviation of triplicate wells from one experiment (A, B, C, D). **p< 0.01, ***p < 0.001, ****p < 0.0001 by Šídák’s multiple comparisons test (A) or by unpaired t-test (B, C, D). Data shown are representative of at least three independent experiments.

We next examined whether GSDMD controls intracellular Salmonella replication in human macrophages. While we did not observe any differences in bacterial uptake between WT and GSDMD^-/- cells at 1 hpi (Figure 3 – figure supplement 2D), we did observe significantly higher bacterial CFUs in GSDMD^-/- cells compared to WT cells at 6 hpi (Figure 3 – figure supplement 2E). Moreover, the increase in bacterial CFUs at 6 hpi was significantly higher in GSDMD^-/- cells than in WT cells (Figure 3C). Next, we used microscopy to further interrogate intracellular Salmonella burdens. As expected, WT cells contained low numbers of Salmonella per cell (∼5 bacteria per cell) (Figure 3D-E). However, GSDMD^-/- cells harbored significantly higher numbers of Salmonella per cell on average (∼20 bacteria per cell) at 6 hpi (Figure 3D-E), suggesting that GSDMD restricts intracellular Salmonella burdens. Altogether, these data indicate that GSDMD promotes the control of Salmonella replication in human macrophages.

NINJ1 contributes to the control of Salmonella replication within human macrophages

Terminal cell lysis is regulated downstream of GSDMD cleavage and pore formation (Bjanes et al., 2021; Kayagaki et al., 2021). While GSDMD pores release a subset of molecules, including IL-1 family cytokines, the extensive release of cellular contents is mediated by plasma membrane rupture (Ding et al., 2016; Ruan et al., 2018). Recently, NINJ1 was identified as an executioner of terminal cell lysis (Bjanes et al., 2021; Borges et al., 2022; Degen et al., 2023; Kayagaki et al., 2021, 2023). NINJ1 is a transmembrane protein that oligomerizes in the host plasma membrane to induce lytic rupture of the cell after the initiation of pyroptosis and other forms of regulated cell death (Degen et al., 2023; Kayagaki et al., 2021). Cells can be protected from plasma membrane rupture through treatment with the amino acid glycine (Fink & Cookson, 2006; Frank et al., 2000; Heilig et al., 2018; Verhoef et al., 2005), which interferes with the clustering of NINJ1 (Borges et al., 2022). Thus, upon incubation with glycine, cells can still form GSDMD pores but cannot undergo terminal cell lysis (Fink & Cookson, 2006; Heilig et al., 2018; Tsuchiya et al., 2021; Verhoef et al., 2005). Whether NINJ1-dependent cell lysis might contribute to control of Salmonella replication in human macrophages remains unknown.

First, to determine whether glycine exerts a cytoprotective effect on THP-1 macrophages, we pretreated WT and NAIP^-/- THP-1 cells with glycine prior to infection with WT Salmonella and assayed for downstream inflammasome responses. Notably, WT and NAIP^-/- cells pretreated with glycine exhibited significantly decreased cell death and a small defect in IL-1β release following infection compared to infected cells treated with the vehicle control (Figure 4 – figure supplement 1A-B). Release of the inflammasome-independent cytokine TNF-α was unaffected by glycine treatment (Figure 4 – figure supplement 1C). Altogether, these results indicate that glycine prevents cell lysis and limits IL-1 release in THP-1 macrophages upon Salmonella infection.

Given glycine’s cytoprotective effect on infected THP-1 macrophages, we next sought to determine whether glycine impacts intracellular Salmonella burdens in human macrophages. THP-1 macrophages pretreated with glycine retained significantly higher intracellular bacterial burdens at 6 hpi compared to cells given the vehicle control (Figure 4 – figure supplement 1D). We did not detect any significant differences in bacterial uptake (Figure 4 – figure supplement 1E). Moreover, WT and NAIP^-/- THP-1 cells pretreated with glycine exhibited a greater increase in Salmonella CFUs compared to cells treated with the vehicle control (Figure 4 – figure supplement 1F), suggesting that glycine treatment impedes intracellular control of Salmonella. Therefore, cytoprotection by glycine appears to interfere with the restriction of Salmonella burdens in human macrophages.

Next, to genetically test the role of NINJ1, we transfected WT THP-1 macrophages with small interfering RNA (siRNA) targeting NINJ1 or control scrambled siRNA. WT cells treated with control siRNA exhibited robust IL-1β release and cytotoxicity upon infection with WT Salmonella (Figure 4A-B). However, knockdown of NINJ1 resulted in a significant decrease, yet not complete abrogation, of cytotoxicity in infected cells (Figure 4B). Knockdown of NINJ1 also led to defect in IL-1β secretion (Figure 4A). In these experiments, we observed efficient siRNA-mediated knockdown of NINJ1 ranging from 77% to 85%. Collectively, these data suggest a critical role for NINJ1 in contributing to IL-1 release and cell death during Salmonella infection in human macrophages.

NINJ1 contributes to the control of *Salmonella* replication within human macrophages.
WT THP-1 monocyte-derived macrophages were treated with siRNA targeting a control scrambled siRNA or siRNA targeting *NINJ1* for 72 hours prior to infection. Cells were primed with 100 ng/mL Pam3CSK4 for 16 hours. Cells were then infected with PBS (Mock) or WT S. Typhimurium at an MOI = 20. (A) Release of IL-1β into the supernatant was measured by ELISA at 6 hpi. (B) Cell death (percentage cytotoxicity) was measured by lactate dehydrogenase release assay and normalized to mock-infected cells at 6 hpi. (C, D, E) Cells were lysed at 1 hpi and 6 hpi, and bacteria were subsequently plated to calculate CFU. (C) CFU/well at 1 hpi. (D) CFU/well at 6 hpi. (E) Fold-change in CFU/well was calculated. Bars represent the mean for each condition. Error bars represent the standard deviation of triplicate wells from one experiment. ns – not significant, *p< 0.05, **p< 0.01 by unpaired t-test. Data shown are representative of at least three independent experiments.

We then enumerated bacterial CFUs to assess whether NINJ1 impacts intracellular Salmonella replication. At 1 hpi, we did not observe any differences in bacterial uptake between WT THP-1 cells treated with control siRNA or NINJ1 siRNA (Figure 4C). However, at 6 hpi, we found that cells treated with NINJ1 siRNA contained higher intracellular bacterial burdens than cells treated with control siRNA (Figure 4D). Furthermore, there was a greater increase in bacterial CFUs at 6 hpi in NINJ1 siRNA-treated cells compared to control siRNA-treated cells (Figure 4E). Together, these findings suggest that NINJ1 contributes to intracellular bacterial control.

Inflammasome activation primarily controls cytosolic Salmonella replication in human macrophages

In epithelial cells, WT Salmonella can replicate in both vacuolar and cytosolic compartments, specifically hyperreplicating in the cytosol (Knodler, Crowley, et al., 2014; Knodler et al., 2010; Knodler, Nair, et al., 2014; Malik-Kale et al., 2012). However, in murine macrophages, WT Salmonella appears to replicate exclusively in vacuoles (Beuzón et al., 2002; Thurston et al., 2016). Salmonella lacking the SPI-2 effector SifA (ΔsifA), which is required for SCV membrane stability, frequently enter the cytosol and cannot replicate efficiently in murine macrophages (Beuzón et al., 2000, 2002; Thurston et al., 2016). Whether Salmonella replicates within vacuoles or the cytosol of human macrophages remains largely unknown. One study suggested that a small but significant proportion of Salmonella are exposed to the cytosol in THP-1 macrophages (Fisch et al., 2020). Our recently published data and current findings indicate that when human macrophages fail to undergo robust inflammasome responses, Salmonella hyperreplicates to large numbers within these cells (Naseer, Egan, et al., 2022). The hyperreplication that we observed in human macrophages was reminiscent of previous reports describing Salmonella hyperreplication within the cytosol of IECs (Knodler, Crowley, et al., 2014; Knodler et al., 2010; Knodler, Nair, et al., 2014; Malik-Kale et al., 2012). Thus, we hypothesized that inflammasome activation limits Salmonella replication in both SCVs and the host cell cytosol, and that in the absence of inflammasome responses, Salmonella hyperreplicates to large numbers within the host cell cytosol and also exhibits increased replication within SCVs.

First, to test whether inflammasome activation restricts the ability of Salmonella to replicate in vacuolar and cytosolic compartments of human macrophages, we used a chloroquine (CHQ) resistance assay. As a weak base, CHQ accumulates in endosomal compartments, including the SCV, without entering the cytosol of host cells (Klein, Powers, et al., 2017; Knodler, Nair, et al., 2014; Steinberg, 1994). Thus, vacuolar bacteria are CHQ-sensitive, while cytosolic bacteria are CHQ-resistant (Knodler, Nair, et al., 2014). We infected THP-1 macrophages with WT Salmonella and treated the infected cells with CHQ. Then, we determined the bacterial CFUs at 6 hpi, quantifying the numbers of vacuolar bacteria (CHQ-sensitive) and cytosolic bacteria (CHQ-resistant). We found that WT THP-1 cells contained mostly vacuolar Salmonella while also retaining some cytosolic Salmonella (Figure 5A), suggesting that a subset of Salmonella dwells in the cytosol of THP-1 macrophages, in agreement with a previous study (Fisch et al., 2020). In NAIP^-/- and CASP1^-/- THP-1 cells, we observed slightly higher burdens of vacuolar Salmonella compared to WT cells (Figure 5A). Strikingly, we also observed significantly larger numbers of cytosolic Salmonella in NAIP^-/- and CASP1^-/- cells compared to WT cells (Figure 5A). These data indicate that inflammasome signaling restricts Salmonella primarily within the host cell cytosol but also within SCVs in human macrophages.

Inflammasome activation primarily controls cytosolic *Salmonella* replication in human macrophages.
WT, *NAIP*^-/- (A), and *CASP1*^-/- (A, B) THP-1 monocyte-derived macrophages were primed with 100 ng/mL Pam3CSK4 for 16 hours. Cells were then infected with PBS (Mock) or WT S. Typhimurium (A) or Δ*sipB S*. Typhimurium (B) at an MOI = 20. At 5 hpi, cells were left untreated or treated with 500 µM CHQ for 1 hour. Then, at 6 hpi, cells were lysed, and bacteria were subsequently plated to calculate CFU. CFU/well of vacuolar (CHQ-sensitive) and cytosolic (CHQ-resistant) bacteria were calculated from the total bacteria. (C,D) WT, *NAIP*^-/-, and *CASP1*^-/- THP-1 monocyte-derived macrophages were primed with 100 ng/mL Pam3CSK4 for 16 hours. Cells were then infected with PBS (Mock) or WT S. Typhimurium constitutively expressing mCherry and harboring the GFP cytosolic reporter plasmid, pNF101, at an MOI = 20. Cells were fixed at 8 hpi and stained for DAPI to label DNA (blue). (C) The number of GFP-positive, mCherry-positive bacteria (cytosolic) per cell and the number of GFP-negative, mCherry-positive bacteria (vacuolar) per cell were scored by fluorescence microscopy. Each small dot represents one infected cell. 150 total infected cells were scored for each genotype. (D) Representative images from 8 hpi are shown. Scale bar represents 10 µm. White arrows indicate cytosolic bacteria (GFP-positive, mCherry-positive). Bars represent the mean for each genotype (A, B). Error bars represent the standard deviation of triplicate wells from one experiment (A, B). ns – not significant, *p< 0.05, ****p < 0.0001 by Dunnett’s multiple comparisons test (A) or by Tukey’s multiple comparisons test (B). Data shown are representative of at least three independent experiments (A, B, C).

The SPI-1 T3SS can damage the SCV (Roy et al., 2004), and the SPI-1 T3SS and its effectors contribute to Salmonella replication in the cytosol of epithelial cells (Chong et al., 2019; Klein, Grenz, et al., 2017; Knodler, Nair, et al., 2014). So, we next assessed whether the SPI-1 T3SS was required for the cytosolic exposure of Salmonella in human macrophages. We infected WT and CASP1^-/- THP-1 macrophages with Salmonella lacking the SPI-1 T3SS translocon protein SipB (ΔsipB), thus preventing SPI-1 T3SS effector translocation into host cells. While we observed a significant increase in the amount of vacuolar and cytosolic ΔsipB Salmonella in CASP1^-/- cells compared to WT cells at 6 hpi, the numbers of cytosolic ΔsipB were significantly lower than vacuolar ΔsipB in both WT and CASP1^-/- cells (Figure 5B). We also observed lower cytosolic ΔsipB Salmonella burdens compared to WT Salmonella in both WT and CASP1^-/- THP-1 cells (Figure 5A-B). Therefore, these results suggest that there is a partial dependence on the SPI-1 T3SS for Salmonella’s cytosolic access in human macrophages.

Since CFU assays are population-based, we next used single-cell methods to interrogate the subcellular localization of WT Salmonella in human macrophages. We relied on a strain of WT Salmonella that constitutively expresses mCherry and maintains a reporter plasmid, pNF101, that expresses gfp-ova under the control of a promoter responsive to the host cytosolic metabolite glucose-6-phosphate (Lau et al., 2019). We scored the number of GFP-positive/mCherry-positive bacteria (cytosolic) and GFP-negative/mCherry-positive bacteria (vacuolar) in WT, NAIP^-/- and CASP1^-/- THP-1 macrophages at 8 hpi by microscopy. We observed low numbers of both vacuolar and cytosolic populations of Salmonella in WT THP-1 cells (Figure 5C-D). In contrast, NAIP^-/- and CASP1^-/- THP-1 cells maintained significantly larger numbers of vacuolar Salmonella, with a substantial increase in the numbers of cytosolic Salmonella (Figure 5C-D). Taken together, these results suggest that inflammasome responses primarily restrict Salmonella replication within the host cell cytosol and also control bacterial replication within SCVs in human macrophages.

We next asked whether inflammasome responses also restrict the replication of Salmonella within the cytosol and SCV in primary human macrophages. We pretreated hMDMs with either ZVAD, to inhibit inflammasome responses mediated by caspase activity, or the vehicle control DMSO, and then infected the cells with WT Salmonella constitutively expressing mCherry and harboring pNF101. We observed that hMDMs treated with ZVAD contained significantly more cytosolic Salmonella than hMDMs treated with DMSO (Figure 5 – figure supplement 1A-B). We observed no significant differences between the vacuolar burdens of Salmonella in hMDMs pretreated with ZVAD or DMSO (Figure 5 – figure supplement 1A-B). Thus, inflammasome responses appear to primarily control Salmonella replication within the cytosol of primary human macrophages.

Inflammasome activation modulates the cytosolic exposure of Salmonella in human macrophages

Finally, to characterize the effect of inflammasomes on the subcellular niches of Salmonella in human macrophages at higher resolution, we used transmission electron microscopy (TEM). In WT THP-1 cells, TEM analysis revealed that the majority of bacteria resided in a membrane-bound compartment (vacuolar, white arrows) (Figure 6A; Figure 6 – figure supplement 1B). In CASP1^-/- THP-1 cells, we observed a more mixed population of vacuolar bacteria and bacteria that were exposed to the host cell cytosol to varying extents (Figure 6B; Figure 6 – figure supplement 1B). We observed Salmonella free-living in the cytosol without a vacuolar membrane (fully cytosolic, black asterisk) as well as Salmonella exposed to the cytosol within discontinuous vacuolar membranes (partially cytosolic, cyan arrows) (Figure 6B; Figure 6 – figure supplement 1B). We observed a greater proportion of cytosol-exposed Salmonella in CASP1^-/- cells compared to WT cells (Figure 6 – figure supplement 1A). Strikingly, these TEM results revealed distinct intracellular populations of Salmonella in human macrophages, providing further evidence that inflammasome signaling controls the replicative niches that Salmonella occupies in human macrophages.

We next sought to further characterize the cytosolic exposure of Salmonella in CASP1^-/- THP-1 cells using electron tomography (ET), a technique that can reveal three-dimensional (3D) detail about SCV membranes. Indeed, we confirmed the presence of Salmonella in SCVs with varying degrees of vacuolar membrane discontinuities, yielding various extents of cytosolic exposure (Figure 6C; Figure 6 – figure supplement 1C; Video 1). Altogether, our TEM and ET data reveal the full spectrum of cytosolic exposure for Salmonella in CASP1^-/- cells as a result of vacuolar membrane discontinuities. Overall, our findings indicate that inflammasome responses play a role in modulating the subcellular populations of Salmonella, thereby controlling the number of Salmonella able to replicate within the cytosol and SCV in human macrophages.

Discussion

Our data reveal that inflammatory caspases and downstream cell lysis mediators are required to restrict Salmonella replication in human macrophages. Furthermore, our findings indicate that inflammasomes restrict Salmonella hyperreplication within the cytosol of human macrophages. Caspase-1 is required for inflammasome responses and control of intracellular Salmonella replication early during infection. In contrast, caspase-4 contributed minimally early during infection and instead played a larger role in inflammasome responses and restriction of Salmonella replication at later timepoints. We also found that GSDMD and NINJ1 were required for cell death, IL-1 cytokine release, and control of Salmonella replication. Finally, in the absence of these inflammasome components and effectors in human macrophages, we observed a hyperreplicating population of Salmonella within the cytosol, as well as increased bacterial loads within the SCV, suggesting that inflammasome activation prevents hyperreplication of Salmonella within the cytosol and increased replication within SCVs.

There are multiple downstream consequences of inflammasome activation, including pyroptosis, cytokine secretion, phagolysosomal fusion, the formation of pore-induced intracellular traps (PITs), and the generation of reactive oxygen species (ROS), each of which could be responsible for the control of intracellular Salmonella replication in human macrophages. Previous studies have suggested that inflammatory caspases limit the intracellular replication of WT Salmonella in human epithelial cells and murine macrophages through host cell death (Aachoui et al., 2013; Holly et al., 2020; Knodler, Crowley, et al., 2014). Interestingly, in murine macrophages, the restriction of a mutant strain of Salmonella that frequently enters the cytosol is dependent on caspase-1/11 but independent of IL-1 signaling and host cell death (Thurston et al., 2016). Moreover, caspase-1/11-dependent production of mitochondrial ROS and hydrogen peroxide contributes to the control of WT Salmonella replication in SCVs in murine macrophages (Man, Ekpenyong, et al., 2014). Future studies investigating the downstream consequences of inflammasome activation will help elucidate the mechanisms by which inflammatory caspases and cell lysis mediators control intracellular Salmonella replication in human macrophages.

Whereas caspase-1 is the primary caspase that mediates inflammasome responses and control of Salmonella burdens in human macrophages, our data indicate that caspase-4 also plays a role at a later stage of infection. Whether caspase-4 is activated by vacuolar Salmonella or hyperreplicating cytosolic Salmonella in human macrophages remains an open question. Other host immune factors may also contribute to caspase-4-dependent inflammasome responses to Salmonella. Guanylate binding proteins (GBPs) can modulate inflammasome responses to intracellular LPS and impact intracellular bacterial replication (Degrandi et al., 2007; Fisch et al., 2020; Kim et al., 2011; Kutsch et al., 2020; Meunier et al., 2014; Pilla et al., 2014; J. C. Santos et al., 2020; Tietzel et al., 2009; Wandel et al., 2020).

The impact of GSDMD on the restriction of intracellular Salmonella replication may be due to downstream responses, such as IL-1 release and pyroptosis. Moreover, pyroptosis can induce PIT formation, which traps and damages intracellular bacteria, rendering them more susceptible to immune defenses, such as neutrophil-mediated killing (Jorgensen et al., 2016). It is possible that pyroptosis leads to the development of PITs in human macrophages during Salmonella infection, thereby limiting Salmonella’s intracellular replication. In addition, the cleaved N-terminal fragment of GSDMD can directly kill bacteria (Ding et al., 2016; Liu et al., 2016; Wang et al., 2019), so perhaps GSDMD directly targets Salmonella to mediate restriction. It remains unknown whether other cell lysis factors, like NINJ1, together with GSDMD, directly bind the SCV, affecting vacuolar integrity and thus influencing intracellular Salmonella replication.

Our data indicate that inflammasome responses primarily control Salmonella replication within the cytosol of human macrophages and also within SCVs. How inflammasome activation inhibits Salmonella replication in the cytosol of human macrophages remains unknown. Salmonella hyperreplicates in the cytosol of human epithelial cells, which fail to undergo caspase-1-dependent inflammasome responses (Holly et al., 2020; Knodler, Crowley, et al., 2014; Knodler et al., 2010; Knodler, Nair, et al., 2014; Naseer, Zhang, et al., 2022). Our study suggests that CASP1^-/- THP-1 macrophages behave similarly to human IECs, as they support Salmonella hyperreplication in the cytosol in the absence of caspase-1. Inflammasome activation could curtail cytosolic replication of Salmonella through host cell death, direct GSDMD targeting of cytosolic Salmonella, and/or another effector mechanism. Alternatively, inflammasome activation could regulate the cytosolic access of Salmonella through host factors that directly damage the SCV, such as pore-forming proteins like GSDMD.

The bacterial factors that facilitate Salmonella’s cytosolic lifestyle in human macrophages remain largely unknown. Our findings indicate that the SPI-1 T3SS is partially required for Salmonella to access the cytosol in THP-1 macrophages. In epithelial cells, the SPI-1 T3SS SopB and SipA enable Salmonella to efficiently colonize and replicate in the cytosol (Chong et al., 2019; Klein, Grenz, et al., 2017). Future studies are needed to elucidate whether these same effectors play a role in supporting Salmonella’s cytosolic replication in human macrophages.

Of note, our data indicate that there is considerable single-cell heterogeneity in terms of total intracellular bacterial burdens as well as proportions of vacuolar and cytosolic Salmonella in human macrophages using single-cell microscopic analysis. Several factors could account for this phenotypic heterogeneity, including expression levels of inflammasome components, the amount of translocated Salmonella ligands, or the extent of inflammasome activation, all of which might differ at a single cell level and are masked in bulk-population assays. Notably, heterogeneity in Salmonella gene expression, intracellular Salmonella populations, and intracellular Salmonella proliferation and viability has been previously observed in human epithelial cells and murine macrophages (Helaine et al., 2010, 2014; Knodler, Nair, et al., 2014; Malik-Kale et al., 2012; Powers et al., 2021).

Collectively, our results reveal that inflammasome responses restrict intracellular Salmonella replication, particularly within the cytosol of human macrophages. These findings are in contrast to mouse macrophages, where inflammasomes are activated but only marginally restrict the intracellular replication of WT Salmonella. Our findings provide insight into how human macrophages leverage inflammasomes to restrict Salmonella intracellular replication. Moreover, our work offers a basis for future studies to investigate how inflammasome activation modulates the subcellular localization of bacterial replicative niches within host cells.

Materials and Methods

Ethics statement

All experiments on primary human monocyte-derived macrophages (hMDMs) were performed in compliance with the requirements of the US Department of Health and Human Services and the principles expressed in the Declaration of Helsinki. hMDMs were derived from samples obtained from the University of Pennsylvania Human Immunology Core, and they are considered to be a secondary use of deidentified human specimens and are exempt via Title 55 Part 46, Subpart A of 46.101 (b) of the Code of Federal Regulations.

Cell culture of THP-1 cells

THP-1 cells (TIB-202; American Type Culture Collection) were maintained in RPMI supplemented with 10% (vol/vol) heat-inactivated FBS, 0.05 nM β-mercaptoethanol, 100 IU/mL penicillin, and 100 μg/mL streptomycin at 37°C in a humidified incubator. Two days prior to experimentation, the cells were replated in media without antibiotics in a 48-well plate at a concentration of 2 × 10⁵ cells/well or in a 24-well plate at a concentration of 3.5 × 10⁵ cells per well and incubated with phorbol 12-myristate 13-acetate (PMA) for 24 hours to allow differentiation into macrophages. Then, macrophages were primed with 100 ng/mL Pam3CSK4 (Invivogen) for 16 to 20 hours prior to bacterial infections. For fluorescence microscopy experiments, cells were plated on glass coverslips in a 24-well plate.

Cell culture of primary human monocyte-derived macrophages (hMDMs)

Purified human monocytes from deidentified healthy human donors were obtained from the University of Pennsylvania Human Immunology Core. The monocytes were cultured in RPMI supplemented with 10% (vol/vol) heat-inactivated FBS, 2 mM L-glutamine, 100 IU/mL penicillin, 100 μg/ml streptomycin, and 50 ng/ml recombinant human M-CSF (Gemini Bio-Products). Cells were cultured for 4 days in 10 mL of media in at a concentration of 4-5 × 10⁵ cells/mL in 10 cm-dishes. Then, 10 mL of fresh growth media was added for an additional 2 days to promote complete differentiation into macrophages. One day prior to infection, the cells were rinsed with cold PBS, gently detached with trypsin-EDTA (0.05%) and replated in media without antibiotics and with 25 ng/mL human M-CSF in a 48-well plate at a concentration of 1 × 10⁵ cells per well or in a 24-well plate at a concentration of 2 × 10⁵ cells per well. For fluorescence microscopy, cells were replated on glass coverslips in a 24-well plate. For experiments involving LPS, cells were primed with 500 ng/mL LPS (Sigma-Aldrich) for 3 hours prior to bacterial infections.

Inhibitor experiments

Human macrophages were treated 1 hour prior to infection at the indicated concentrations with the following inhibitors: 20 μM of the pan-caspase inhibitor Z-VAD(OMe)-FMK (SM Biochemicals; SMFMK001), 25 μM of the caspase-1 inhibitor Ac-YVAD-cmk (Sigma-Aldrich; SML0429), and 40 μM of the GSDMD inhibitor disulfiram (Sigma). DMSO treatment was used as a vehicle control with these inhibitors. To prevent cell lysis, cells were treated with 20 mM glycine (Fisher Scientific) for 30 minutes prior to infection. Distilled water was used as a vehicle control.

Bacterial strains and growth conditions

Salmonella enterica serovar Typhimurium SL1344 WT was routinely grown shaking overnight at 37°C in Luria-Bertani (LB) broth with streptomycin (100 μg/mL). For infection of cultured cells, the overnight culture was diluted in LB with streptomycin (100 μg/mL) containing 300 mM NaCl and grown standing for 3 hours at 37°C to induce SPI-1 expression (Lee & Falkow, 1990). SL1344 WT glmS::Ptrc-mCherryST::FRT pNF101 (Lau et al., 2019) was kindly provided by Dr. Leigh Knodler. This strain constitutively expresses mCherry that is chromosomally encoded. It also harbors the PuhpT-gfpova plasmid, pNF101, where expression of GFP is under the control of the glucose-6-phosphate responsive uhpT promoter derived from Shigella flexneri. SL1344 WT glmS::Ptrc-mCherryST::FRT pNF101 was grown shaking overnight at 37°C in Luria-Bertani (LB) broth with streptomycin (100 μg/mL) and ampicillin (100 μg/mL). For SPI-1 induction prior to infection, the overnight culture was diluted in LB with streptomycin (100 μg/mL) and ampicillin (100 μg/mL) that also contained 300 mM NaCl and then grown standing for 3 hours at 37°C (Lee & Falkow, 1990).

Bacterial infections

Overnight cultures of Salmonella were diluted into LB broth with streptomycin (100 μg/mL) containing 300 mM NaCl and grown for 3 hours standing at 37°C to induce SPI-1 gene expression (Lee & Falkow, 1990). Bacterial cultures were then pelleted at 6,010 × g for 3 minutes, washed once with PBS, and resuspended in PBS. Human macrophages were infected with Salmonella at a multiplicity of infection (MOI) of 20. Infected cells were centrifuged at 290 × g for 10 minutes and incubated at 37°C. At 30 minutes post-infection, the cells were treated with 100 ng/mL of gentamicin to kill any extracellular Salmonella. Then, the infection proceeded at 37°C for 6 to 8 hours, as indicated. For all experiments, control cells were mock-infected with PBS.

Bacterial intracellular burden assay

Cells were infected with WT Salmonella as described above at an MOI of 20. Then, 30 minutes post-infection, cells were treated with 100 μg/ml of gentamicin to kill any extracellular bacteria. 1 hour post-infection, the media was replaced with fresh media containing 10 μg/ml of gentamicin. At the indicated time points, the infected cells were lysed with PBS containing 0.5% Triton to collect all intracellular Salmonella. Harvested bacteria were serially diluted in PBS and plated on LB agar plates containing streptomycin (100 μg/ml) to enumerate colony forming units (CFUs). Plates were incubated overnight at 37°C and CFUs were subsequently counted.

Chloroquine (CHQ) Resistance Assay

THP-1 macrophages were infected in 48-well plates as described above. For each timepoint, triplicate wells were incubated in the presence of CHQ (500 µM) and gentamicin (100 ng/mL) for 1 hour to quantify the CHQ-resistant bacteria (Bârzu et al., 1997; Fernandez et al., 2001; Klein, Powers, et al., 2017; Knodler, Nair, et al., 2014; Zychlinsky et al., 1994). Another triplicate wells were incubated with gentamicin (100 ng/mL) only to quantify the total intracellular bacteria. At the indicated time points, the infected cells were lysed with PBS containing 0.5% Triton to collect intracellular Salmonella. Harvested bacteria were serially diluted in PBS and plated on LB agar plates containing streptomycin (100 μg/ml) to enumerate colony forming units (CFUs). Plates were incubated overnight at 37°C and CFUs were subsequently counted.

ELISAs

Harvested supernatants from infected human macrophages were assayed for cytokine levels using ELISA kits for human IL-1α (R&D Systems), IL-18 (R&D Systems), IL-1β (BD Biosciences), and TNF-α (R&D Systems).

LDH cytotoxicity assays

Harvested supernatants from infected human macrophages were assayed for cytotoxicity by quantifying the loss of cellular membrane integrity via lactate dehydrogenase (LDH) activity. LDH release was measured using an LDH Cytotoxicity Detection Kit (Clontech) according to the manufacturer’s instructions and normalized to mock-infected cells.

siRNA-mediated knockdown of genes

All Silencer Select siRNA oligos were purchased from Ambion (Life Technologies). Individual siRNA targeting NINJ1 (ID# s9556) was used. The two Silencer Select negative control siRNAs (Silencer Select Negative Control No. 1 siRNA and Silencer Select Negative Control No. 2 siRNA) were used as a control. Three days prior to the infection, 30 nM of siRNA was transfected into the human macrophages using Lipofectamine RNAiMAX transfection reagent (Thermo Fisher Scientific) following the manufacturer’s protocol. Then, 24 hours after transfection, the media was replaced with fresh media containing antibiotics. Finally, 16 hours before infection, the media was replaced with fresh antibiotic-free media containing 100 ng/ml Pam3CSK4.

Quantitative RT-PCR Analysis

RNA was isolated using the RNeasy Plus Mini Kit (Qiagen) following the manufacturer’s protocol. Human macrophages were lysed in 350 μL RLT buffer with β-mercaptoethanol and centrifuged through a QIAshredder spin column (Qiagen). cDNA was synthesized from isolated RNA using SuperScript II Reverse Transcriptase (Invitrogen) following the manufacturer’s protocol. Quantitative PCR was conducted with the CFX96 real-time system from Bio-Rad using the SsoFast EvaGreen Supermix with Low ROX (Bio-Rad). To calculate knockdown efficiency, mRNA levels of siRNA-treated cells were normalized to the housekeeping gene HPRT and control siRNA-treated cells using the 2^−ΔΔCT (cycle threshold) method (Livak & Schmittgen, 2001). The following primers from PrimerBank were used. The PrimerBank identifications are NINJ1 (148922910c1), CASP4 (73622124c2) and HPRT (164518913c1); all primers listed as 5′–3′:

NINJ1 forward: TCAAGTACGACCTTAACAACCCG

NINJ1 reverse: TGAAGATGTTGACTACCACGATG

CASP4 forward: TCTGCGGAACTGTGCATGATG

CASP4 reverse: TGTGTGATGAAGATAGAGCCCAT

HPRT forward: CCTGGCGTCGTGATTAGTGAT

HPRT reverse: AGACGTTCAGTCCTGTCCATAA

Immunoblot analysis

Cell lysates were harvested for immunoblot analysis by adding 1X SDS/PAGE sample buffer to cells. All protein samples (lysates) were boiled for 5 minutes. Samples were separated by SDS/PAGE on a 12% (vol/vol) acrylamide gel and transferred to PVDF Immobilon-P membranes (Millipore). Primary antibodies specific for caspase-4 (4450S; Cell Signaling) and β-actin (4967L; Cell Signaling) and HRP-conjugated secondary antibodies anti-mouse IgG (F00011; Cell Signaling) and anti-rabbit IgG (7074S; Cell Signaling) were used. ECL Western Blotting Substrate (Pierce Thermo Scientific) was used as the HRP substrate for detection.

Fluorescent microscopy of intracellular Salmonella

Primary hMDMs or THP-1 cells were plated on glass coverslips in a 24-well plate as described above. Cells were either infected with WT Salmonella constitutively expressing GFP [Sl1344 harboring pFPV25.1 (Valdivia & Falkow, 1996)], or WT Salmonella constitutively expressing mCherry with a cytosolic GFP reporter [SL1344 glmS::Ptrc-mCherryST::FRT pNF101 (Lau et al., 2019)] at an MOI of 20 as described above. At the indicated timepoints following infection, cells were washed 2 times with PBS and then fixed with 4% paraformaldehyde for 10 minutes. Following fixation, cells were mounted on glass slides with DAPI mounting medium (Sigma Fluoroshield). Coverslips were imaged on an inverted fluorescence microscope (IX81; Olympus), and the images were collected using a high-resolution charge-coupled-device camera (FAST1394; QImaging) at a magnification of 100×. All images were analyzed and presented using SlideBook (version 5.0) software (Intelligent Imaging Innovations, Inc.) and ImageJ software. For experiments with WT Salmonella constitutively expressing GFP, the proportion of infected cells containing GFP-expressing Salmonella (green) were scored by counting 50 infected cells per coverslip. 150 total infected cells were scored for each condition. For experiments with WT Salmonella constitutively expressing mCherry with a cytosolic GFP reporter, the proportion of infected cells containing GFP-positive Salmonella (cytosolic) and GFP-negative, mCherry-positive Salmonella (vacuolar) were scored by counting 50 infected cells per coverslip. 150 total infected cells were scored for each condition.

Transmission electron microscopy

Two days prior to experimentation, 2 × 10⁶ cells THP-1 cells were replated in 10-cm dishes in media without antibiotics and incubated with phorbol 12-myristate 13-acetate (PMA) for 24 hours to allow differentiation into macrophages. Then, macrophages were primed with 100 ng/mL Pam3CSK4 (Invivogen) for 16 hours prior to bacterial infection. Cells were infected with WT Salmonella at an MOI of 20 as described above. At 8 hpi, the media was aspirated, and the cells were fixed with 2.5% glutaraldehyde, 2.0% paraformaldehyde in 0.1M sodium cacodylate buffer, pH 7.4. Then, at the Electron Microscopy Resource Laboratory in the Perelman School of Medicine, after subsequent buffer washes, the samples were post-fixed in 2.0% osmium tetroxide with 1.5% K3Fe(CN)6 for 1 hour at room temperature, and rinsed in dH2O. After dehydration through a graded ethanol series, the tissue was infiltrated and embedded in EMbed-812 (Electron Microscopy Sciences, Fort Washington, PA). Thin sections were stained with uranyl acetate and SATO lead and examined with a JEOL 1010 electron microscope fitted with a Hamamatsu digital camera and AMT Advantage NanoSprint500 software.

Electron tomography

Electron tomography was performed at room temperature on a ThermoFisher Krios G3i TEM equipped with a 300 keV field emission gun. Imaging was performed using the SerialEM software (Mastronarde, 2005) on a K3 direct electron detector (Xuong et al., 2007) (Gatan Inc., Pleasanton, CA, USA) operated in the electron-counted mode. We additionally used the Gatan Imaging Filter (Gatan Inc., Pleasanton, CA, USA) with a slit width of 20 eV to increase contrast by removing inelastically scattered electrons (Krivanek et al., 1995). After initially assessing the infected macrophages at lower magnifications, tilt series were collected at a magnification of 26,000X (with a corresponding pixel size of 3.38 Å) and a defocus of −6 µm. Precooking the target areas with a total dosage of 1000-1500 e/Å² was required to minimize sample shrinking and drifting during tilt series collection. A bi-directional tilt scheme was employed with 2° increments and 120° span (−60° to +60°). The cumulative dose of each tilt-series was in the order of ∼500 e−/Å2. Once acquired, tilt series were aligned (using the patch tracking function) and reconstructed into tomograms, both using the IMOD software package (Kremer et al., 1996). After careful assessment of the 3-dimensional (3-D) tomograms, optimal 2-D slices were chosen for figure presentations. Color overlays provide additional assistance with interpretation.

Statistical analysis

Prism 9.5.0 (GraphPad Software) was utilized for the graphing of data and all statistical analyses. Statistical significance for experiments with THP-1 macrophages and hMDMs was determined using the appropriate test and are indicated in each figure legend. Differences were considered statistically significant if the p value was <0.05.

Acknowledgements

We thank members of Igor Brodsky’s and Sunny Shin’s laboratories for their scientific discussions and continuous support. We thank Leigh Knodler for providing SL1344 glmS::Ptrc-mCherryST::FRT pNF101 and Cornelius Taabazuing for providing CASP1^-/- and GSDMD^-/- THP-1 cells. We thank the Human Immunology Core of the Penn Center for AIDS Research and Abramson Cancer Center for providing purified primary human monocytes. We also thank the Electron Microscopy Resource Lab (EMRL) at the Perelman School of Medicine, University of Pennsylvania for TEM specimen processing, sectioning, and staining along with microscopy training. Additionally, we thank the EMRL for allowing us access and usage of the transmission electron microscope, JEOL JEM-1010. Lastly, we thank Gordon Ruthel at the Penn Vet Imaging Core and Ronit Schwartz for providing helpful insights on fluorescence microscopy.

This work was supported by National Institutes of Health (NIH)/National Institute of Allergy and Infectious Diseases (NIAID) grants: AI151476, AI118861, and AI123243 (S.S.), AI128630, AI163596, and AI139102 (I.E.B). This work was also supported by the Burroughs-Wellcome Fund Investigators in the Pathogenesis of Infectious Disease Award (S.S. and I.E.B.), the National Science Foundation Graduate Fellowships DGE-1321851 (M.S.E.) and DGE-1845298 (A.R.B.), the NIH/NIGMS grant T32GM07229 (E.A.O.), the David and Lucile Packard Fellowship for Science and Engineering 2019– 69645 (Y.-W.C.), and the Pennsylvania Department of Health FY19 Health Research Formula Fund (Y.-W.C.). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

Video 1. Characterization of the cytosolic exposure of Salmonella in CASP1^-/- human macrophages. CASP1^-/- THP-1 monocyte-derived macrophages were primed with 100 ng/mL Pam3CSK4 for 16 hours. Cells were then infected with WT S. Typhimurium at an MOI = 20. At 8 hpi, cells were fixed and collected to be processed for transmission electron microscopy. Representative tomogram shown, depicting Salmonella in an SCV with a discontinuous vacuolar membrane.

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Article and author information

Author information

Marisa S. Egan
Department of Microbiology, Perelman School of Medicine, University of Pennsylvania, Philadelphia, PA
ORCID iD: 0000-0001-6191-5552
Emily A. O’Rourke
Department of Microbiology, Perelman School of Medicine, University of Pennsylvania, Philadelphia, PA
Shrawan Kumar Mageswaran
Department of Biochemistry and Biophysics, Perelman School of Medicine, University of Pennsylvania, Philadelphia, PA
Biao Zuo
Electron Microscopy Resource Laboratory, Department of Biochemistry & Biophysics, Perelman School of Medicine, University of Pennsylvania, Philadelphia, PA
Inna Martynyuk
Electron Microscopy Resource Laboratory, Department of Biochemistry & Biophysics, Perelman School of Medicine, University of Pennsylvania, Philadelphia, PA
Tabitha Demissie
Department of Microbiology, Perelman School of Medicine, University of Pennsylvania, Philadelphia, PA
Emma N. Hunter
Department of Microbiology, Perelman School of Medicine, University of Pennsylvania, Philadelphia, PA
Antonia R. Bass
Department of Microbiology, Perelman School of Medicine, University of Pennsylvania, Philadelphia, PA
- MRL, Merck & Co., Inc., Kenilworth, NJ
Yi-Wei Chang
Department of Biochemistry and Biophysics, Perelman School of Medicine, University of Pennsylvania, Philadelphia, PA
Igor E. Brodsky
Department of Pathobiology, University of Pennsylvania School of Veterinary Medicine, Philadelphia, PA
Sunny Shin
Department of Microbiology, Perelman School of Medicine, University of Pennsylvania, Philadelphia, PA
- Address correspondence to Sunny Shin, sunshin@pennmedicine.upenn.edu.

Version history

Sent for peer review: July 5, 2023
Preprint posted: July 18, 2023
Reviewed Preprint version 1: August 24, 2023

Copyright

This article is distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use and redistribution provided that the original author and source are credited.

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Significance of findings

Strength of evidence

Abstract

Introduction

Results

Caspase-1 promotes the control of Salmonella replication within human macrophages

Caspase-1 promotes the control of Salmonella replication within human macrophages.

Caspase-4 contributes to the control of Salmonella replication within human macrophages later during infection

Caspase-4 contributes to the control of Salmonella replication within human macrophages later during infection.

GSDMD promotes the control of Salmonella replication within human macrophages

GSDMD promotes the control of Salmonella replication within human macrophages.

NINJ1 contributes to the control of Salmonella replication within human macrophages

NINJ1 contributes to the control of Salmonella replication within human macrophages.

Inflammasome activation primarily controls cytosolic Salmonella replication in human macrophages

Inflammasome activation primarily controls cytosolic Salmonella replication in human macrophages.

Inflammasome activation modulates the cytosolic exposure of Salmonella in human macrophages

Inflammasome activation modulates the cytosolic exposure of Salmonella in human macrophages.

Discussion

Materials and Methods

Ethics statement

Cell culture of THP-1 cells

Cell culture of primary human monocyte-derived macrophages (hMDMs)

Inhibitor experiments

Bacterial strains and growth conditions

Bacterial infections

Bacterial intracellular burden assay

Chloroquine (CHQ) Resistance Assay

ELISAs

LDH cytotoxicity assays

siRNA-mediated knockdown of genes

Quantitative RT-PCR Analysis

Immunoblot analysis

Fluorescent microscopy of intracellular Salmonella

Transmission electron microscopy

Electron tomography

Statistical analysis

Acknowledgements

References

Article and author information

Author information

Marisa S. Egan

Emily A. O’Rourke

Shrawan Kumar Mageswaran

Biao Zuo

Inna Martynyuk

Tabitha Demissie

Emma N. Hunter

Antonia R. Bass†

Yi-Wei Chang

Igor E. Brodsky

Sunny Shin

Version history

Copyright

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Antonia R. Bass