Your search keyword '"mouse colonization"' showing total 3 results

1. A histone-like protein of Helicobacter pylori protects DNA from stress damage and aids host colonization

Author

Wang, Ge, Lo, Leja F., and Maier, Robert J.

Subjects

*HISTONES, *HELICOBACTER pylori, *BACTERIAL cells, *NUCLEOIDS, *GENOMICS, *ESCHERICHIA coli, *MITOMYCIN C, *DNA

Abstract

Abstract: Genomic DNA in a bacterial cell is folded into a compact structure called a nucleoid, and nucleoid-associated proteins are responsible for proper assembly of active higher-order genome structures. The human gastric pathogen Helicobacter pylori express a nucleoid-associated protein encoded by the hup gene, which is the homolog to the Escherichia coli histone-like protein HU. An H. pylori hup mutant strain (X47 hup:cat) showed a defect in stationary phase survival. The X47 hup:cat mutant was more sensitive to the DNA damaging agent mitomycin C, and displayed a decreased frequency of DNA recombination, indicating Hup plays a significant role in facilitating DNA recombinational repair. The X47 hup:cat mutant was also sensitive to both oxidative and acid stress, conditions that H. pylori commonly encounters in the host. The hup mutant cells survived significantly (7-fold) less upon exposure to macrophages than the wild type strain. In a mouse infection model, the hup mutant strain displayed a greatly reduced ability to colonize host stomachs. The geometric means of colonization number for the wild type and hup mutant were 6×105 and 1.5×104 CFU/g stomachs, respectively. Complementation of the hup strain by chromosomal insertion of a functional hup gene restored oxidative stress resistance, DNA transformation frequency, and mouse colonization ability to the wild type level. We directly demonstrated that the purified His-tagged H. pylori Hup protein can protect (in vitro) an H. pylori-derived DNA fragment from oxidative damage. [Copyright &y& Elsevier]

Published

2012

2. Experimental colonization of mice by fresh clinical isolates of Helicobacter pylori is not influenced by the cagA status and the vacA genotype

Author

Ayraud, Sarah, Janvier, Blandine, and Fauchère, Jean-Louis

Subjects

*COLONIZATION (Ecology), *MICE, *HELICOBACTER pylori

Abstract

Developing murine models of infection by Helicobacter pylori is quite useful but not all the strains are able to colonize the mouse. In order to study the influence of the two main virulence factors, CagA and VacA, on the establishment of H. pylori in mice, we have inoculated C57BL/6 mice with 15 strains randomly chosen among clinical strains freshly isolated from biopsy specimens of infected patients and five reference strains. Only six of the clinical strains and two of the reference strains could infect the animals regardless of the cagA status and the vacA genotype. We concluded that 40% of the H. pylori strains are able to infect mice and that the capacity of colonization is not influenced by the cagA status and the vacA genotype. These factors cannot be used to predict the success of an experimental infection. [Copyright &y& Elsevier]

Published

2002

3. In Vivo Transcriptome of Lactobacillus acidophilus and Colonization Impact on Murine Host Intestinal Gene Expression.

Author

Goh YJ, Barrangou R, and Klaenhammer TR

Subjects

Animals, Bacterial Adhesion, Bacterial Proteins genetics, Host Microbial Interactions genetics, Immunity, Mice, Probiotics administration & dosage, Sequence Analysis, RNA, Signal Transduction, Gene Expression Profiling, Intestines microbiology, Lactobacillus acidophilus genetics, Lactobacillus acidophilus physiology, Transcriptome

Abstract

Lactobacillus acidophilus NCFM is a probiotic strain commonly used in dairy products and dietary supplements. Postgenome in vitro studies of NCFM thus far have linked potential key genotypes to its probiotic-relevant attributes, including gut survival, prebiotic utilization, host interactions, and immunomodulatory activities. To corroborate and extend beyond previous in vivo and in vitro functional studies, we employed a dual RNA sequencing (RNA-seq) transcriptomic approach to identify genes potentially driving the gut fitness and activities of L. acidophilus NCFM in vivo , and in parallel, examine the ileal transcriptional response of its murine hosts during monocolonization. Spatial expression profiling of NCFM from the ileum through the colon revealed a set of 134 core genes that were consistently overexpressed during gut transit. These in vivo core genes are predominantly involved in the metabolism of carbohydrates, amino acids, and nucleotides, along with mucus-binding proteins and adhesion factors, confirming their functionally important roles in nutrient acquisition and gut retention. Functional characterization of the highly expressed major S-layer-encoding gene established its indispensable role as a cell shape determinant and maintenance of cell surface integrity, essential for viability and probiotic attributes. Host colonization by L. acidophilus resulted in significant downregulation of several proinflammatory cytokines and tight junction proteins. Genes related to redox signaling, mucin glycosylation, and circadian rhythm modulation were induced, suggesting impacts on intestinal development and immune functions. Metagenomic analysis of NCFM populations postcolonization demonstrated the genomic stability of L. acidophilus as a gut transient and further established its safety as a probiotic and biotherapeutic delivery platform. IMPORTANCE To date, our basis for comprehending the probiotic mechanisms of Lactobacillus acidophilus , one of the most widely consumed probiotic microbes, was largely limited to in vitro functional genomic studies. Using a germfree murine colonization model, in vivo -based transcriptional studies provided the first view of how L. acidophilus survives in the mammalian gut environment, including gene expression patterns linked to survival, efficient nutrient acquisition, stress adaptation, and host interactions. Examination of the host ileal transcriptional response, the primary effector site of L. acidophilus , has also shed light into the mechanistic roles of this probiotic microbe in promoting anti-inflammatory responses, maintaining intestinal epithelial homeostasis and modulation of the circadian-metabolic axis in its host., (Copyright © 2021 Goh et al.)

Published

2021