Lawsonia intracellularis exploits β-catenin/Wnt and Notch signalling pathways during infection of intestinal crypt to alter cell homeostasis and promote cell proliferation

Lawsonia intracellularis is an obligate intracellular bacterial pathogen that causes proliferative enteropathy (PE) in pigs. L. intracellularis infection causes extensive intestinal crypt cell proliferation and inhibits secretory and absorptive cell differentiation. However, the affected host upstream cellular pathways leading to PE are still unknown. β-catenin/Wnt signalling is essential in maintaining intestinal stem cell (ISC) proliferation and self-renewal capacity, while Notch signalling governs differentiation of secretory and absorptive lineage specification. Therefore, in this report we used immunofluorescence (IF) and quantitative reverse transcriptase PCR (RTqPCR) to examine β-catenin/Wnt and Notch-1 signalling levels in uninfected and L. intracellularis infected pig ileums at 3, 7, 14, 21 and 28 days post challenge (dpc). We found that while the significant increase in Ki67+ nuclei in crypts at the peak of L. intracellularis infection suggested enhanced cell proliferation, the expression of c-MYC and ASCL2, promoters of cell growth and ISC proliferation respectively, was down-regulated. Peak infection also coincided with enhanced cytosolic and membrane-associated β-catenin staining and induction of AXIN2 and SOX9 transcripts, both encoding negative regulators of β-catenin/Wnt signalling and suggesting a potential alteration to β-catenin/Wnt signalling levels, with differential regulation of the expression of its target genes. We found that induction of HES1 and OLFM4 and the down-regulation of ATOH1 transcript levels was consistent with the increased Notch-1 signalling in crypts at the peak of infection. Interestingly, the significant down-regulation of ATOH1 transcript levels coincided with the depletion of MUC2 expression at 14 dpc, consistent with the role of ATOH1 in promoting goblet cell maturation. The lack of significant change to LGR5 transcript levels at the peak of infection suggested that the crypt hyperplasia was not due to the expansion of ISC population. Overall, simultaneous induction of Notch-1 signalling and the attenuation of β-catenin/Wnt pathway appear to be associated with the inhibition of goblet cell maturation and enhanced crypt cell proliferation at the peak of L. intracellularis infection. Moreover, the apparent differential regulation of apoptosis between crypt and lumen cells together with the strong induction of Notch-1 signalling and the enhanced SOX9 expression along crypts 14 dpc suggest an expansion of actively dividing transit amplifying and/or absorptive progenitor cells and provide a potential basis for understanding the development and maintenance of PE

Genetic control of HgCl2-induced IgE and autoimmunity by a 117-kb interval on rat chromosome 9 through CD4 CD45RC(high) T cells

International audienceGold or mercury salts trigger a dramatic IgE response and a CD4 T-cell-dependent nephropathy in Brown-Norway (BN), but not in Lewis (LEW) rats. We previously identified the 1.1-Mb Iresp3 (immunoglobin response QTL3) locus on chromosome 9 that controls these gold salt-triggered immune disorders. In the present work, we investigated the genetic control of HgCl2-induced immunological disorders and assessed the relative contribution of the CD45RC(high) and CD45RC(low) CD4 T-cell subpopulations in this control. By using interval-specific congenic lines, we narrowed down Iresp3 locus to 117-kb and showed that BN rats congenic for the LEW 117-kb were protected from HgCl2-triggered IgE response and nephropathy. This 117-kb interval also controls CD45RC expression by CD4 T cells and the ability of CD45RC(high) CD4 T cells to trigger the autoimmune disorders resulting from HgCl2 administration. This 117-kb region contains four genes, including Vav1, a strong candidate gene according to its cellular function and exclusive expression in hematopoietic cells. Thus, this study highlights the role of the CD45RC(high) CD4 T-cell subpopulation in the opposite susceptibility of BN and LEW rats to HgCl2-triggered immune disorders and identifies a 117-kb interval on chromosome 9 that has a key role in their functions

R-Spondin 2 signalling mediates susceptibility to fatal infectious diarrhoea

Citrobacter rodentium is a natural mouse pathogen widely used as a model for enteropathogenic and enterohemorrhagic Escherichia coli infections in humans. While C. rodentium causes self-limiting colitis in most inbred mouse strains, it induces fatal diarrhoea in susceptible strains. The physiological pathways as well as the genetic determinants leading to susceptibility have remained largely uncharacterized. Here we use a forward genetic approach to identify the R-spondin2 gene as a major determinant of susceptibility to C. rodentium infection. Robust induction of R-spondin2 expression during infection in susceptible mouse strains causes a potent Wnt-mediated proliferative response of colonic crypt cells, leading to the generation of an immature and poorly differentiated colonic epithelium with deficiencies in ion-transport components. Our data demonstrate a previously unknown role of R-spondins and Wnt signalling in susceptibility to infectious diarrhoea and identify R-spondin2 as a key molecular link between infection and intestinal homoeostasis. \ua9 2013 Macmillan Publishers Limited. All rights reserved.Peer reviewed: YesNRC publication: Ye

Topoisomerase 2β mutation impairs early B-cell development

Mutations impairing early B-cell development cause monogenic primary immunodeficiencies that manifest with markedly reduced or absent B cells, hypogammaglobulinemia, and recurrent bacterial infections from childhood. Approximately 85% of such patients have mutations in BTK, the gene responsible for X-linked agammaglobulinemia.1 Current research focuses on patients with unknown genetic defects, because the identification of the causative genes not only will facilitate diagnosis of primary immunodeficiencies but also can reveal new biological roles of the affected proteins in human B-cell development and point at novel drug targets