Your search keyword '"Asulin, Nofar"' showing total 2 results

1. Salmonella manipulates the host to drive pathogenicity via induction of interleukin 1β.

Author

Zigdon, Mor, Sawaed, Jasmin, Zelik, Lilach, Binyamin, Dana, Ben-Simon, Shira, Asulin, Nofar, Levin, Rachel, Modilevsky, Sonia, Naama, Maria, Telpaz, Shahar, Rubin, Elad, Awad, Aya, Sawaed, Wisal, Harshuk-Shabso, Sarina, Nuriel-Ohayon, Meital, Krishnamohan, Mathumathi, Werbner, Michal, Koren, Omry, Winter, Sebastian E, Apte, Ron N, Voronov, Elena, and Bel, Shai

Subjects

Microbiology, Medical Microbiology, Biomedical and Clinical Sciences, Biological Sciences, Emerging Infectious Diseases, Infectious Diseases, Hematology, Foodborne Illness, Digestive Diseases, Biodefense, Sepsis, Microbiome, 2.1 Biological and endogenous factors, Aetiology, Oral and gastrointestinal, Infection, Good Health and Well Being, Animals, Humans, Mice, Interleukin-1beta, Neutrophils, Salmonella Infections, Salmonella typhimurium, Virulence, Agricultural and Veterinary Sciences, Medical and Health Sciences, Developmental Biology, Agricultural, veterinary and food sciences, Biological sciences, Biomedical and clinical sciences

Abstract

Acute gastrointestinal infection with intracellular pathogens like Salmonella Typhimurium triggers the release of the proinflammatory cytokine interleukin 1β (IL-1β). However, the role of IL-1β in intestinal defense against Salmonella remains unclear. Here, we show that IL-1β production is detrimental during Salmonella infection. Mice lacking IL-1β (IL-1β -/-) failed to recruit neutrophils to the gut during infection, which reduced tissue damage and prevented depletion of short-chain fatty acid (SCFA)-producing commensals. Changes in epithelial cell metabolism that typically support pathogen expansion, such as switching energy production from fatty acid oxidation to fermentation, were absent in infected IL-1β -/- mice which inhibited Salmonella expansion. Additionally, we found that IL-1β induces expression of complement anaphylatoxins and suppresses the complement-inactivator carboxypeptidase N (CPN1). Disrupting this process via IL-1β loss prevented mortality in Salmonella-infected IL-1β -/- mice. Finally, we found that IL-1β expression correlates with expression of the complement receptor in patients suffering from sepsis, but not uninfected patients and healthy individuals. Thus, Salmonella exploits IL-1β signaling to outcompete commensal microbes and establish gut colonization. Moreover, our findings identify the intersection of IL-1β signaling and the complement system as key host factors involved in controlling mortality during invasive Salmonellosis.

Published

2024

2. The effect of testosterone on the gut microbiome in mice.

Author

Moadi, Lelyan, Turjeman, Sondra, Asulin, Nofar, and Koren, Omry

Subjects

GUT microbiome, PUBERTY, TESTOSTERONE, SEX hormones, MICE, METABOLOMICS

Abstract

The role of hormones in gut–brain crosstalk is largely elusive, but recent research supports specific changes in hormone levels correlated with the gut microbiota. An interesting but unstudied area in microbial endocrinology is the interplay between the microbiota and sex hormones. The aim of this study is to investigate the effect of testosterone and sex on the mouse gut microbiome. We use in vitro experiments to test direct effects of testosterone on bacteria in fecal samples collected from male and female mice pre- and post-puberty. Sex-specific microbial and metabolic differences surrounding puberty are also examined in vivo. We then explore effects of testosterone supplementation in vivo, characterizing microbiota and metabolomes of male and female mice. We detect sex-specific differences in microbiota and associated metabolites of mice post-puberty, but in vitro experiments reveal that testosterone only affects microbiota of fecal samples collected before puberty. Testosterone supplementation in vivo affects gut microbiota and metabolomes in both male and female mice. Taking our results from in vitro and in vivo experiments, we conclude that the shift in the microbiome after puberty is at least partially caused by the higher levels of sex hormones, mainly testosterone, in the host. A study examining microbiome differences associated with puberty and sex and effects of testosterone on the microbiome in mice, finding shifts in the microbiome after puberty are partially caused by higher levels of sex hormones, mainly testosterone, in hosts. [ABSTRACT FROM AUTHOR]

Published

2024