Project description:Macrophages mediate key antimicrobial responses against intracellular bacterial pathogens, such as Salmonella enterica. Yet, they can also act as a permissive niche for these pathogens to persist in infected tissues within granulomas, which are immunological structures comprised of macrophages and other immune cells. We apply single-cell transcriptomics to investigate macrophage functional diversity during persistent Salmonella enterica serovar Typhimurium (STm) infection in mice. We identify determinants of macrophage heterogeneity in infected spleens and describe populations of distinct phenotypes, functional programming, and spatial localization. Using a STm mutant with impaired ability to polarize macrophage phenotypes, we find that angiotensin converting enzyme (ACE) defines a granuloma macrophage population that is non-permissive for intracellular bacteria and their abundance anticorrelates with tissue bacterial burden. Disruption of pathogen control by neutralizing TNF is linked to preferential depletion of ACE+ macrophages in infected tissues. Thus ACE+ macrophages have limited capacity to serve as cellular niche for intracellular bacteria to establish persistent infection.

Project description:We present a detailed single cell time course of the macrophage response to Salmonella infection. By combining phenotypic fluorescent labels with single cell expression analysis we are able to identify gene modules associated with bacterial exposure and bacterial infection. We also identify other genetic clusters that are expressed heterogenously, ananlyzing both their regulation and their impact on infection Analysis of 192 single cells across 4 time points after Salmonella exposure (MOI 1:1) with one of three different fluorescent labels indicating whether a given cell contained no intracellular bacteria (non-fluorescent), contained dead intracellular bacteria (only pHrodo positive), or contained live intracellular bacteria (pHrodo and GFP positive)

Project description:Many bacterial infections are hard to treat and tend to relapse, possibly due to the presence of antibiotic-tolerant persisters that are considered dormant cells when bacteria are grown in laboratory medium. Non-growing persisters also form following uptake of Salmonella by macrophages but their nature is little understood. Here we show that Salmonella persisters arising during macrophage infection maintain an active state. Persisters reprogram macrophages by means of effectors secreted by the SPI-2 Type 3 Secretion System (T3SS), thereby dampening pro-inflammatory innate immune responses and inducing anti-inflammatory macrophage polarisation. Reprogramming allows non-growing Salmonella to survive for extended periods in their host. Persisters undermining the host immune defences might confer an advantage to the pathogen during relapse once the antibiotic pressure is relieved.

Project description:Interactions between intracellular bacteria and mononuclear phagocytes give rise to diverse cellular phenotypes that may determine the outcome of infection. Recent advances in single-cell RNA-seq (scRNA-seq) have identified multiple subsets within the mononuclear population, but implications to their function during infection remain unknown. Here, we applied microscopy, flow cytometry and scRNA-seq to survey the mononuclear niche of intracellular Salmonella Typhimurium (S.Tm) during early systemic infection in mice. We describe eclipse-like growth kinetics in the spleen, with a first phase of bacterial control mediated by tissue-resident red-pulp macrophages. A second phase involved extensive bacterial replication within a newly identified macrophage population characterized by CD9 expression. Using Nr4a1e2-/- mice we established that CD9+ macrophages originated from non-classical monocytes (NCM), and NCM-depleted mice were more resistant to S.Tm infection. Our study defines a novel host-pathogen interface, with macrophage subset-specific interactions that determines early infection dynamics and the infection outcome of the entire organism.

Project description:Interactions between intracellular bacteria and mononuclear phagocytes give rise to diverse cellular phenotypes that may determine the outcome of infection. Recent advances in single-cell RNA-seq (scRNA-seq) have identified multiple subsets within the mononuclear population, but implications to their function during infection remain unknown. Here, we applied microscopy, flow cytometry and scRNA-seq to survey the mononuclear niche of intracellular Salmonella Typhimurium (S.Tm) during early systemic infection in mice. We describe eclipse-like growth kinetics in the spleen, with a first phase of bacterial control mediated by tissue-resident red-pulp macrophages. A second phase involved extensive bacterial replication within a newly identified macrophage population characterized by CD9 expression. Using Nr4a1e2-/- mice we established that CD9+ macrophages originated from non-classical monocytes (NCM), and NCM-depleted mice were more resistant to S.Tm infection. Our study defines a novel host-pathogen interface, with macrophage subset-specific interactions that determines early infection dynamics and the infection outcome of the entire organism.

Project description:Interactions between intracellular bacteria and mononuclear phagocytes give rise to diverse cellular phenotypes that may determine the outcome of infection. Recent advances in single-cell RNA-seq (scRNA-seq) have identified multiple subsets within the mononuclear population, but implications to their function during infection remain unknown. Here, we applied microscopy, flow cytometry and scRNA-seq to survey the mononuclear niche of intracellular Salmonella Typhimurium (S.Tm) during early systemic infection in mice. We describe eclipse-like growth kinetics in the spleen, with a first phase of bacterial control mediated by tissue-resident red-pulp macrophages. A second phase involved extensive bacterial replication within a newly identified macrophage population characterized by CD9 expression. Using Nr4a1e2-/- mice we established that CD9+ macrophages originated from non-classical monocytes (NCM), and NCM-depleted mice were more resistant to S.Tm infection. Our study defines a novel host-pathogen interface, with macrophage subset-specific interactions that determines early infection dynamics and the infection outcome of the entire organism.

Project description:MicroRNAs have well-established roles in eukaryotic host responses to viruses and extracellular bacterial pathogens. In contrast, microRNA responses to invasive bacteria have remained unknown. Here, we report cell type-dependent microRNA regulations upon infection of mammalian cells with the enteroinvasive pathogen, Salmonella Typhimurium. Murine macrophages strongly up-regulate NF-κB associated microRNAs; strikingly, these regulations which are induced by the bacterial lipopolysaccharides (LPS) occur and persist regardless of successful host invasion and/or replication, or whether an inflammatory response is mounted, suggesting that microRNAs belong to the first line of anti-bacterial defence. However, a suppression of the global immune regulator miR-155 in endotoxintolerant macrophages revealed that microRNA responses also depend on the status of infected cells. This study identifies the let-7 family as the common denominator of Salmonella regulated microRNAs in macrophages and epithelial cells, and suggests that repression of let-7 relieves cytokine IL-6 and IL-10 mRNAs from negative post-transcriptional control. Our results establish a paradigm of microRNA-mediated feed-forward activation of inflammatory factors when mammalian cells are targeted by bacterial pathogens. The murine macrophage cell-line RAW 264.7 was exposed to wild-type Salmonella typhimurium SL1344 or to the corresponding knockout strain lacking both major genomic loci associated with Salmonella pathogenicity ("SPI1" and "SPI2"). To induce infectivity overnight cultures of Salmonella were dilluted 1:100 and grown to OD2. Host cells at a density of approximately 10e6 per well of a 6-well plate were infected at an MOI of 1. Upon initial incubation for 30 min cells were further incubated for 24 h in RPMI supplemented with gentamicin (10 µg / ml). As determined by a gentamicin protection and plating assay the SPI1/2 double knockout strain is deficient in both invasion and intracellular replication. We compared mouse mRNA abundances between cells infected with wild-type ("24WT") or SPI1/2 knockout Salmonella ("24SPI1/2") and non-infected, mock-treated controls ("24C"). Both strains mounted a similar inflammatory response as judged from the abundance of pro-inflammatory genes compared to the controls. These data indicate, that macrophages can mount a full inflammatory response to extracellular bacteria, that is not further enhanced or attenuated by the sensing of intracellular bacteria. Murine RAW 264.7 cells were rendered endotoxin-tolerant by pre-exposure to heat-killed Salmonella typhimurium SL1344 ("HKS") at an MOI of 10 for 20 h. 5 days upon removal of the HKS stimulus cells were exposed to wild-type Salmonella typhimurium SL1344 or to the corresponding knockout strain lacking both major genomic loci associated with Salmonella pathogenicity ("SPI1" and "SPI2"). To induce infectivity overnight cultures of Salmonella were dilluted 1:100 and grown to OD2. Host cells at a density of approximately 10e6 per well of a 6-well plate were infected at an MOI of 1. Upon initial incubation for 30 min cells were further incubated for 24 h in RPMI supplemented with gentamicin (10 µg / ml). As determined by a gentamicin protection and plating assay the SPI1/2 double knockout strain is deficient in both invasion and intracellular replication. The wild-type Salmonella strain invades and replicates in endotoxin-tolerant RAW 264.7 cells, though the intracellular replication rate is significantly reduced (by roughly 40 %) compared to naive RAW 264.7 cells. We compared mouse mRNA abundances between cells infected with wild-type ("wt") and non-infected, mock-treated controls ("Mock") or between wild-type ("wt") and SPI1/2-knockout ("SPI1/2") infected cells. As apparent from the Microarray data the wild-type Salmonella strain induces a typical inflamatory response in endotoxin-tolerant RAW 264.7 cells (as judged from the fold-induction of NFkB-inducible genes). As expected however, mRNAs corresponding to known inflammatory genes are significantly less abundant in response to the non-invasive SPI1/2 knockout strain, compared to wild-type infection. These data indicate, that endotoxin-tolerance renders macrophages largely insensitive to extracellular, but not to intracellular bacteria. ***This submission represents the mRNA component of the study

Project description:Some intracellular bacteria are known to cause long-term infections for periods of time that last decades without compromising the viability of the host. Although of critical importance, the changes that intracellular bacteria suffer during this long process of residence in a host cell environment remain obscure. Here, we report an experimental approach to study the adaptations of intracellular mycobacteria forced by a long-term intracellular lifestyle. Long-term infection of host macrophages with mycobacteria was maintained for a period of years. Mycobacteria in the long-term infected macrophages underwent an adaptation process leading to impaired phenolic glycolipids (PGL) synthesis, preference for glucose as a carbon source and neutral lipids accumulation. These changes correlated with increased survival of mycobacteria in macrophages and mice during re-infection and specific expression of stress- and survival-related genes. Our findings identify bacterial traits implicated in the establishment of long-term cellular infections and represent a tool for understanding the physiological states of bacteria living in fluctuating intracellular environments.

Project description:Intracellular pathogens, such as Salmonella enterica serovar Typhimurium (S.Tm), are able to sense and respond to a changing host cell environment. Macrophages exposed to microbial products undergo metabolic changes that are increasingly understood to drive a productive inflammatory response. However, the role of macrophage metabolic reprogramming in bacterial adaptation to the intracellular environment has not been explored. Here we show that changes in host metabolic state serve as a signal detected byS.Tm. Using metabolic profiling and dual RNA-seq, we show that succinate accumulates in infected macrophages and is sensed by intracellular S.Tm to promote induction of virulence genes. Succinate uptake by the bacterium drives induction of pmrAB-dependent genes and SPI-2 virulence-associated regulon. S.Tm lacking the DcuB transporter for succinate uptake display impaired intracellular survival. Our work demonstrates that accumulation of metabolic intermediates, necessary for macrophage activation, promote intracellular survival of pathogens, opening a new realm of metabolic host-pathogen crosstalk.

Project description:Intracellular pathogens, such as Salmonella enterica serovar Typhimurium (S.Tm), are able to sense and respond to a changing host cell environment. Macrophages exposed to microbial products undergo metabolic changes that are increasingly understood to drive a productive inflammatory response. However, the role of macrophage metabolic reprogramming in bacterial adaptation to the intracellular environment has not been explored. Here we show that changes in host metabolic state serve as a signal detected byS.Tm. Using metabolic profiling and dual RNA-seq, we show that succinate accumulates in infected macrophages and is sensed by intracellular S.Tm to promote induction of virulence genes. Succinate uptake by the bacterium drives induction of pmrAB-dependent genes and SPI-2 virulence-associated regulon. S.Tm lacking the DcuB transporter for succinate uptake display impaired intracellular survival. Our work demonstrates that accumulation of metabolic intermediates, necessary for macrophage activation, promote intracellular survival of pathogens, opening a new realm of metabolic host-pathogen crosstalk.