Role of AE2 for pHi regulation in biliary epithelial cells

The Cl(-)/HCO(-) 3anion exchanger 2 (AE2) is known to be involved in intracellular pH (pHi) regulation and transepithelial acid-base transport. Early studies showed that AE2 gene expression is reduced in liver biopsies and blood mononuclear cells from patients with primary biliary cirrhosis (PBC), a disease characterized by chronic non-suppurative cholangitis associated with antimitochondrial antibodies (AMA) and other autoimmune phenomena. Microfluorimetric analysis of the Cl(-)/HCO(-) 3 anion exchange (AE) in isolated cholangiocytes showed that the cAMP-stimulated AE activity is diminished in PBC compared to both healthy and diseased controls. More recently, it was found that miR-506 is upregulated in cholangiocytes of PBC patients and that AE2 may be a target of miR-506. Additional evidence for a pathogenic role of AE2 dysregulation in PBC was obtained with Ae2 (-/-) a,b mice, which develop biochemical, histological, and immunologic alterations that resemble PBC (including development of serum AMA). Analysis of HCO(-) 3 transport systems and pHi regulation in cholangiocytes from normal and Ae2 (-/-) a,b mice confirmed that AE2 is the transporter responsible for the Cl(-)/HCO(-) 3exchange in these cells. On the other hand, both Ae2 (+/+) a,b and Ae2 (-/-) a,b mouse cholangiocytes exhibited a Cl(-)-independent bicarbonate transport system, essentially a Na(+)-bicarbonate cotransport (NBC) system, which could contribute to pHi regulation in the absence of AE2

Role of AE2 for pHi regulation in biliary epithelial cells

The Cl(-)/HCO(-) 3anion exchanger 2 (AE2) is known to be involved in intracellular pH (pHi) regulation and transepithelial acid-base transport. Early studies showed that AE2 gene expression is reduced in liver biopsies and blood mononuclear cells from patients with primary biliary cirrhosis (PBC), a disease characterized by chronic non-suppurative cholangitis associated with antimitochondrial antibodies (AMA) and other autoimmune phenomena. Microfluorimetric analysis of the Cl(-)/HCO(-) 3 anion exchange (AE) in isolated cholangiocytes showed that the cAMP-stimulated AE activity is diminished in PBC compared to both healthy and diseased controls. More recently, it was found that miR-506 is upregulated in cholangiocytes of PBC patients and that AE2 may be a target of miR-506. Additional evidence for a pathogenic role of AE2 dysregulation in PBC was obtained with Ae2 (-/-) a,b mice, which develop biochemical, histological, and immunologic alterations that resemble PBC (including development of serum AMA). Analysis of HCO(-) 3 transport systems and pHi regulation in cholangiocytes from normal and Ae2 (-/-) a,b mice confirmed that AE2 is the transporter responsible for the Cl(-)/HCO(-) 3exchange in these cells. On the other hand, both Ae2 (+/+) a,b and Ae2 (-/-) a,b mouse cholangiocytes exhibited a Cl(-)-independent bicarbonate transport system, essentially a Na(+)-bicarbonate cotransport (NBC) system, which could contribute to pHi regulation in the absence of AE2

Engrafted parenchymal brain macrophages differ from microglia in transcriptome, chromatin landscape and response to challenge

Irradiation depletes brain microglia cells and induces replenishment of the pool by bone marrow (BM)-derived macrophage. Here the authors show, using mouse BM chimera, that BM-derived macrophages establish long-term residency in the brain, but remain distinct from resident microglia in their transcriptome and gene accessibility landscape

Microglial control of astrocytes in response to microbial metabolites

International audienc

A new fate mapping system reveals context-dependent random or clonal expansion of microglia

Microglia constitute a highly specialized network of tissue-resident immune cells that is important for the control of tissue homeostasis and the resolution of diseases of the CNS. Little is known about how their spatial distribution is established and maintained in vivo. Here we establish a new multicolor fluorescence fate mapping system to monitor microglial dynamics during steady state and disease. Our findings suggest that microglia establish a dense network with regional differences, and the high regional turnover rates found challenge the universal concept of microglial longevity. Microglial self-renewal under steady state conditions constitutes a stochastic process. During pathology this randomness shifts to selected clonal microglial expansion. In the resolution phase, excess disease-associated microglia are removed by a dual mechanism of cell egress and apoptosis to re-establish the stable microglial network. This study unravels the dynamic yet discrete self-organization of mature microglia in the healthy and diseased CNS