Background Klebsiella pneumoniae (KP) is a major cause of hospital-acquired infections, such as pneumonia. Moreover, it is classified as a pathogen of concern due to sprawling anti-microbial resistance. During infection, the gram-negative pathogen is capable of establishing an intracellular niche in macrophages by altering cellular metabolism. One factor critically affecting the host-pathogen interaction is the availability of essential nutrients, like iron, which is required for KP to proliferate but which also modulates anti-microbial immune effector pathways. We hypothesized, that KP manipulates macrophage iron homeostasis to acquire this crucial nutrient for sustained proliferation. Methods We applied an in-vitro infection model, in which human macrophage-like PMA-differentiated THP1 cells were infected with KP (strain ATCC 43816). During a 24-h course of infection, we quantified the number of intracellular bacteria via serial plating of cell lysates and evaluated the effects of different stimuli on intracellular bacterial numbers and iron acquisition. Furthermore, we analyzed host and pathogen specific gene and protein expression of key iron metabolism molecules. Results Viable bacteria are recovered from macrophage cell lysates during the course of infection, indicative of persistence of bacteria within host cells and inefficient pathogen clearing by macrophages. Strikingly, following KP infection macrophages strongly induce the expression of the main cellular iron importer transferrin-receptor-1 (TFR1). Accordingly, intracellular KP proliferation is further augmented by the addition of iron loaded transferrin. The induction of TFR1 is mediated via the STAT-6-IL-10 axis, and pharmacological inhibition of this pathway reduces macrophage iron uptake, elicits bacterial iron starvation, and decreases bacterial survival. Conclusion Our results suggest, that KP manipulates macrophage iron metabolism to acquire iron once confined inside the host cell and enforces intracellular bacterial persistence. This is facilitated by microbial mediated induction of TFR1 via the STAT-6-IL-10 axis. Mechanistic insights into immune metabolism will provide opportunities for the development of novel antimicrobial therapies.
Concentrations of neopterin, which is produced by human monocytes/macrophages when stimulated by gamma-interferon, were measured in urine specimens from 72 patients with lung cancer at diagnosis. Other routine clinical and laboratory variables were concomitantly determined. Neither neopterin nor any other laboratory variable studied showed a significant correlation with clinical indicators of the disease (morphologic type, tumour stage, grading, lymph node status, presence of distant metastases). The cancer patients were followed up for up to 10 years, and the abilities of all variable to predict fatal outcome were assessed. In univariate survival analyses, all clinical indicators except morphologic type (P = 0.86) were significant predictors of survival (P < 0.002), but of all the laboratory variables studies, only neopterin was significantly predictive (P = 0.0013). By multivariate survival analysis, a combination of four variables was found to jointly predict survival: lymph node status (P = 0.003), multivariate model), tumour stage (P = 0.0006), grading (P = 0.0047) and neopterin (P = 0.0047). The data suggest that certain aspects of immune activation may have adverse consequences for the prognosis of patients with lung cancer.
Macrophages are important for host defense against intracellular pathogens like Salmonella and can be differentiated into two major subtypes. M1 macrophages, which are pro-inflammatory and induce antimicrobial immune effector mechanisms, including the expression of inducible nitric oxide synthase (iNOS), and M2 macrophages, which exert anti-inflammatory functions and express arginase 1 (ARG1). Through the process of phagocytosis, macrophages contain, engulf, and eliminate bacteria. Therefore, they are one of the first lines of defense against Salmonella. Infection with Salmonella leads to gastrointestinal disorders and systemic infection, termed typhoid fever. For further characterization of infection pathways, we established an in vitro model where macrophages are infected with the mouse Salmonella typhi correlate Salmonella enterica serovar Typhimurium ( S. tm), which additionally expresses red fluorescent protein (RFP). This allows us to clearly characterize macrophages that phagocytosed the bacteria, using multi-color flow cytometry. In this protocol, we focus on the in vitro characterization of pro- and anti-inflammatory macrophages displaying red fluorescent protein-expressing Salmonella enterica serovar Typhimurium, by multi-color flow cytometry.
Abstract: Anaemia of inflammation (AI) is a frequent complication in patients suffering from chronic inflammatory disorders including infections, autoimmune and malignant disease. Cytokine imbalance with a shift towards T‐helper (Th)1‐type immune response seems to be important in the pathogenesis of this type of anaemia. Interferon‐ γ (IFN‐ γ ) and tumour necrosis factor‐ α may affect the growth and differentiation of erythroid progenitor cells. In macrophages, IFN‐ γ strongly induces indoleamine (2,3)‐dioxygenase, an enzyme which degrades tryptophan (trp) to kynurenine (kyn). Trp availability is rate limiting for protein biosynthesis and thus cell growth, including erythropoiesis. In this study, trp and kyn concentrations and their relationship to haemoglobin concentrations and to immune activation was examined in 22 patients with AI. Patients with AI presented with lower trp concentrations than healthy controls of similar age, and a significantly higher kyn to trp ratio, suggesting enhanced trp degradation and, because of a positive correlation with neopterin, immune activation. The kyn to trp ratio was inversely correlated to haemoglobin levels. Thus, the limitation of trp availability to erythroid progenitors may be a key mechanism in cytokine‐mediated inhibition of erythropoiesis, and the therapeutic modulation of indoleamine (2,3)‐dioxygenase and trp levels may be promising targets for AI therapy.
A dynamic interplay between the host and pathogen determines the course and outcome of infections. A central venue of this interplay is the struggle for iron, a micronutrient essential to both the mammalian host and virtually all microbes. The induction of the ironregulatory hormone hepcidin is an integral part of the acute phase response. Hepcidin switches off cellular iron export via ferroportin-1 and sequesters the metal mainly within macrophages, which limits the transfer of iron to the serum to restrict its availability for extracellular microbes. When intracellular microbes are present within macrophages though, the opposite regulation is initiated because infected cells respond with increased ferroportin-1 expression and enhanced iron export as a strategy of iron withdrawal from engulfed bacteria. Given these opposing regulations, it is not surprising that disturbances of mammalian iron homeostasis, be they attributable to genetic alterations, hematologic conditions, dietary iron deficiency or unconsidered iron supplementation, may affect the risk and course of infections. Therefore, acute, chronic or latent infections need to be adequately controlled by antimicrobial therapy before iron is administered to correct deficiency. Iron deficiency per se may negatively affect growth and development of children as well as cardiovascular performance and quality of life of patients. Of note, mild iron deficiency in regions with a high endemic burden of infections is associated with a reduced prevalence and a milder course of certain infections which may be traced back to effects of iron on innate and adaptive immune function as well as to restriction of iron for pathogens. Finally, absolute and functional causes of iron deficiency need to be differentiated, because in the latter form, oral iron supplementation is inefficient and intravenous application may adversely affect the course of the underlying disease such as a chronic infection. This chapter summarizes our current knowledge on the regulation of iron metabolism and the interactions between iron and the immune response against microbes. Moreover, some of the unanswered questions on the association of iron administration and infections are addressed.
