Lipid-induced hepatocyte-derived extracellular vesicles regulate hepatic stellate cell via microRNAs targeting PPAR-γ.

Background&aimsHepatic stellate cells (HSCs) play a key role in liver fibrosis in various chronic liver disorders including nonalcoholic fatty liver disease (NAFLD). The development of liver fibrosis requires a phenotypic switch from quiescent to activated HSCs. The triggers for HSCs activation in NAFLD remain poorly understood. We investigated the role and molecular mechanism of extracellular vesicles (EVs) released by hepatocytes during lipotoxicity in modulation of HSC phenotype.MethodsEVs were isolated from fat-laden hepatocytes by differential centrifugation and incubated with HSCs. EV internalization and HSCs activation, migration and proliferation were assessed. Loss- and gain-of-functions studies were performed to explore the potential role of PPAR-γ-targeting miRNAs carried by EVs into HSC.ResultsHepatocyte-derived EVs released during lipotoxicity are efficiently internalized by HSCs resulting in their activation, as shown by marked up-regulation of pro-fibrogenic genes (Collagen-I, α-SMA and TIMP-2), proliferation, chemotaxis and wound healing responses. These changes were associated with miRNAs shuttled by EVs and suppression of PPAR-γ expression in HSC. Hepatocyte-derived EVs miRNA content included various miRNAs that are known inhibitors of PPAR-γ expression with miR-128-3p being the most effectively transferred. Furthermore loss- and gain-of-function studies identified miR-128-3p as a central modulator of the effects of EVs on PPAR-γ inhibition and HSC activation.ConclusionOur findings demonstrate a link between fat-laden hepatocyte-derived EVs and liver fibrosis and have potential implications for the development of novel anti-fibrotic targets for NAFLD and other fibrotic diseases

(Re)-definition of the holo- and apo-Fur direct regulons of Helicobacter pylori

: Iron homeostasis is a critical process for living organisms because this metal is an essential co-factor for fundamental biochemical activities, like energy production and detoxification, albeit its excess quickly leads to cell intoxication. The protein Fur (ferric uptake regulator) controls iron homeostasis in bacteria by switching from its apo- to holo-form as a function of the cytoplasmic level of ferrous ions, thereby modulating gene expression. The Helicobacter pylori HpFur protein has the rare ability to operate as a transcriptional commutator; apo- and holo-HpFur function as two different repressors with distinct DNA binding recognition properties for specific sets of target genes. Although the regulation of apo- and holo-HpFur in this bacterium has been extensively investigated, we propose a genome-wide redefinition of holo-HpFur direct regulon in H. pylori by integration of RNA-seq and ChIP-seq data, and a large extension of the apo-HpFur direct regulon. We show that in response to iron availability, new coding sequences, non-coding RNAs, toxin-antitoxin systems, and transcripts within open reading frames are directly regulated by apo- or holo-HpFur. These new targets and the more thorough validation and deeper characterization of those already known provide a complete and updated picture of the direct regulons of this two-faced transcriptional regulator

Rapid Recapitulation of Nonalcoholic Steatohepatitis upon Loss of Host Cell Factor 1 Function in Mouse Hepatocytes

Host-cell factor 1 (HCF-1), encoded by the ubiquitously expressed X-linked gene Hcfc1, is an epigenetic coregulator important for mouse development and cell proliferation, including during liver regeneration. We used a hepatocyte-specific inducible Hcfc1 knock-out allele (called Hcfc1 <sup>hepKO</sup> ), to induce HCF-1 loss in hepatocytes of hemizygous Hcfc1 <sup>hepKO/Y</sup> males by four days. In heterozygous Hcfc1 <sup>hepKO/+</sup> females, owing to random X-chromosome inactivation, upon Hcfc1 <sup>hepKO</sup> allele induction, a 50/50 mix of HCF-1 positive and negative hepatocyte clusters is engineered. The livers with Hcfc1 <sup>hepKO/Y</sup> hepatocytes displayed a 21-24-day terminal non-alcoholic fatty liver (NAFL) followed by non-alcoholic steatohepatitis (NASH) disease progression typical of severe NAFL disease (NAFLD). In contrast, in livers with heterozygous Hcfc1 <sup>hepKO/+</sup> hepatocytes, HCF-1-positive hepatocytes replaced HCF-1-negative hepatocytes and revealed only mild-NAFL development. Loss of HCF-1 led to loss of PGC1α protein, probably owing to its destabilization, and deregulation of gene expression particularly of genes involved in mitochondrial structure and function, likely explaining the severe Hcfc1 <sup>hepKO/Y</sup> liver pathology. Thus, HCF-1 is essential for hepatocyte function, likely playing both transcriptional and non-transcriptional roles. These genetically-engineered loss-of-HCF-1 mice can be used to study NASH as well as NAFLD resolution

Myiase nasale humaine à

Un cas de myiase nasale humaine due à des larves de stades L2 et L3 d'Œstrus ovis a été diagnostiqué à Lille (Nord de la France). L'œstrose est une myiase naso-sinusale du mouton et de la chèvre causée par les stades larvaires de la mouche O. ovis. Cette zoonose est fréquemment rencontrée dans les pays méditerranéens et tropicaux. Les auteurs comparent la pathogénèse chez le mouton et l'homme et discutent l'épidémiologie, la symptomatologie et le traitement de cette myiase chez l'homme