IL-1R1-Dependent Signals Improve Control of Cytosolic Virulent Mycobacteria In Vivo

ABSTRACT Mycobacterium tuberculosis infections claim more than a million lives each year, and better treatments or vaccines are required. A crucial pathogenicity factor is translocation from phagolysosomes to the cytosol upon phagocytosis by macrophages. Translocation from the phagolysosome to the cytosol is an ESX-1-dependent process, as previously shown in vitro. Here, we show that in vivo, mycobacteria also translocate to the cytosol but mainly when host immunity is compromised. We observed only low numbers of cytosolic bacilli in mice, armadillos, zebrafish, and patient material infected with M. tuberculosis, M. marinum, or M. leprae. In contrast, when innate or adaptive immunity was compromised, as in severe combined immunodeficiency (SCID) or interleukin-1 receptor 1 (IL-1R1)-deficient mice, significant numbers of cytosolic M. tuberculosis bacilli were detected in the lungs of infected mice. Taken together, in vivo, translocation to the cytosol of M. tuberculosis is controlled by adaptive immune responses as well as IL-1R1-mediated signals. IMPORTANCE For decades, Mycobacterium tuberculosis has been one of the deadliest pathogens known. Despite infecting approximately one-third of the human population, no effective treatment or vaccine is available. A crucial pathogenicity factor is subcellular localization, as M. tuberculosis can translocate from phagolysosome to the cytosol in macrophages. The situation in vivo is more complicated. In this study, we establish that high-level cytosolic escape of mycobacteria can indeed occur in vivo but mainly when host resistance is compromised. The IL-1 pathway is crucial for the control of the number of cytosolic mycobacteria. The establishment that immune signals result in the clearance of cells containing cytosolic mycobacteria connects two important fields, cell biology and immunology, which is vital for the understanding of the pathology of M. tuberculosis.

Influence of streptococcal arginine deiminase on the leukocyte infiltration in murine air pouch model

Numerous pathogens express arginine deiminase, an enzyme that catalyzes the hydrolysis of L-arginine in a chain of biochemical reactions aimed at the synthesis of ATP in bacterial cells. L-arginine is a semi-essential, proteinogenic amino acid that plays an important role in regulating the functions of the immune system cells in mammals. Depletion of L-arginine may cause a weakening of the immune reaction. In order to improve the conditions of dissemination, many pathogens use a strategy of L-arginine depletion in the microenvironment of host cells. Bacterial arginine deiminase can be a pathogenicity factor aimed for dysregulating the processes of inflammation and immune response. In general, the effect of arginine deiminase on immune cells may result into disturbed production of regulatory proinflammatory molecules, such as NO, and related substances, inhibition of activation, migration and differentiation of individual leukocyte subsets. The aim of this study was to investigate the effect of arginine deiminase on the formation of inflammatory infiltrate in murine air pouch model of streptococcal infection. Materials and methods: The study was performed using S. pyogenes M49-16 expressing arginine deiminase and its isogenic mutant S. pyogenes M49-16delArcA with inactivated arginine deiminase gene. The flow cytometry analysis of the inflammatory infiltrate leukocytes subpopulation in mice infected with the original strain of S. pyogenes M49-16 and its isogenic mutant S. pyogenes M49-16delArcA at different periods of infection was performed. It was shown that the inflammation reached its peak 6 hours after streptococcal inoculation, being more pronounced in mice infected with the mutant strain. Тhis finding was affirmed by a simultaneous and more pronounced increase in the absolute numbers of all leukocyte subsets in the focus of inflammation in this group of mice when compared to mice infected with original bacterial strain. Despite the decrease in the absolute number of all leukocyte types in the inflammatory infiltrate in both groups of mice for 24 hours, this trend was more pronounced in the group of mice infected with mutant microbial strain. Comparison of the inflammatory infiltrates developing in mice infected with original versus mutant strains showed that arginine deiminase may be a pathogenicity factor leading to dysregulation of protective immune response, due to impaired migration of white blood cells to the site of infection.

Recurrent hemoperitoneum due to aneurysm of the left hepatic artery. Even "Ockham's razor" can fail

The infection of Klebsiella variicola constituted a high morbility and mortality disease in the most of its guest. It is tended to be associated with a septic shock which required an intensive treatment most of the times. The pathological mechanisms are not well-defined. A correlation has been made between this clinical case and one likely pathogenicity factor, which could explain these rates. We present the case of a male patient who presented to the emergency department with a septic shock. The patient eventually developed an hemoperitoneum by the aneurysm of the left hepatic artery which is very unusual.

IL-1R1 dependent signals improve clearance of cytosolic virulent mycobacteria in vivo

Mycobacterium tuberculosis infections claim more than a million lives each year and better treatments or vaccines are required. A crucial pathogenicity factor is translocation from the phago-lysosomes to the cytosol upon phagocytosis by macrophages. The translocation from the phago-lysosome into the cytosol is an ESX-1 dependent process as previously shown in vitro. Here we show that in vivo, mycobacteria also translocate to the cytosol but mainly when host immunity is compromised. We observed only low numbers of cytosolic bacilli in mice, armadillo, zebrafish and patient material infected with M. tuberculosis, M. marinum or M. leprae. In contrast, when innate or adaptive immunity was compromised, as in SCID or IL-1R1 deficient mice, a significant number of cytosolic M. tuberculosis bacilli were detected in lungs of infected mice. Taken together, M. tuberculosis infection is controlled by adaptive immune responses as well as IL-1R1-mediated signals that result in clearance of cells containing cytosolic mycobacteria in vivo.ImportanceFor decades, Mycobacterium tuberculosis is one of the deathliest pathogens known. Despite infecting approximately one third of the human population, no effective treatment or vaccine is available. A crucial pathogenicity factor is the subcellular localization, as M. tuberculosis can translocate from the phago-lysosome to the cytosol in macrophages. The situation in vivo is more complicated. In this study we establish that high level cytosolic escape of mycobacteria can indeed occur in vivo, but mainly when host resistance is compromised. The IL-1 pathway is crucial for the control of the number of cytosolic mycobacteria. The establishment that immune signals result in clearance of cells containing cytosolic mycobacteria, connects two important fields: cell-biology and immunology which is vital for the understanding of the pathology of M. tuberculosis.

Complete Genome Sequence of Enterococcus faecium FS86, Used for Propagation of Bacteriophages with Therapeutic Potential

ABSTRACT The Enterococcus faecium FS86 genome consists of a 2,685,395-bp chromosome and a 9,751-bp plasmid. The plasmid harbors mobilization-related genes. The pathogenicity factor genotype is cylA negative, aggA negative, gelE negative, sprE negative, esp negative, eep positive, and efaA positive. E. faecium FS86 belongs to multilocus sequence type 296, together with the probiotic strain E. faecium SF68.