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    <title>eLife: upcoming articles</title>
    <link>https://elifesciences.org</link>
    <description>The latest eLife POA (publish-on-accept) articles. These articles are in-progress and their final VOR (version-of-record) is still being produced.</description>
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      <title>Pink1-mediated mitophagy in the endothelium releases proteins encoded by mitochondrial DNA and activates neutrophil responses during inflammation</title>
      <link>https://elifesciences.org/articles/82205</link>
      <description>Eukaryotic mitochondria are characterized by several features that represent vestiges of their prokaryotic ancestry. One such feature is the N-terminal formylation of proteins encoded by mitochondrial DNA that undergo translation by mitochondrial ribosomes. N-formylated proteins are also released by bacteria and trigger activation of immune cells such as neutrophils. Growing evidence indicates that circulating levels of mitochondrial formyl proteins are elevated in the serum of patients with excessive inflammatory responses. However, the mechanisms by which they are released into circulation are not known. In this study, we have identified vascular endothelial cells as a source of Pink1-dependent release of mitochondrial formyl proteins in response to inflammatory mediators. Mechanistically, the mitophagy mediator Pink1 is stabilized by inflammatory activation of endothelial cells, promoting mitophagy and mitochondrial formyl peptide release both in mice and primary human endothelial cells. Using nanoparticle delivery of &lt;i&gt;Pink1&lt;/i&gt;-targeting sgRNA in mice expressing endothelial-specific Cas9, we developed a mouse model in which &lt;i&gt;Pink1&lt;/i&gt; is specifically depleted in the endothelium. Deletion of endothelial &lt;i&gt;Pink1&lt;/i&gt; decreased circulating formyl peptide levels, lowered lung neutrophil infiltration and reduced mortality in mice. We thus propose that endothelial cells upregulate pro-inflammatory mitophagy in response to inflammation, leading to the release of mitochondrial formyl peptides and detrimental neutrophil recruitment into the lung.</description>
      <author>jalees@uic.edu (Chinnaswamy Tiruppathi)</author>
      <author>jalees@uic.edu (Dongmei Wang)</author>
      <author>jalees@uic.edu (Jalees Rehman)</author>
      <author>jalees@uic.edu (Koushik Debnath)</author>
      <author>jalees@uic.edu (Li Wang)</author>
      <author>jalees@uic.edu (Peter T Toth)</author>
      <author>jalees@uic.edu (Pierina Danos)</author>
      <author>jalees@uic.edu (Priyanka Gajwani)</author>
      <author>jalees@uic.edu (Sarah Krantz)</author>
      <author>jalees@uic.edu (Shubhi Srivastava)</author>
      <author>jalees@uic.edu (Sriram Ravindran)</author>
      <author>jalees@uic.edu (Young-Mee Kim)</author>
      <author>jalees@uic.edu (Zijing Ye)</author>
      <guid isPermaLink="false">https://dx.doi.org/10.7554/eLife.82205</guid>
      <category>Cell Biology</category>
      <category>Immunology and Inflammation</category>
      <pubDate>Wed, 01 Jul 2026 00:00:00 +0000</pubDate>
      <dc:date>2026-07-01T00:00:00Z</dc:date>
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      <title>Prominin 1 and Tweety Homology 1 both induce extracellular vesicle formation</title>
      <link>https://elifesciences.org/articles/10006</link>
      <description>Prominin-1 (Prom1) is a five-transmembrane-pass integral membrane protein that associates with curved regions of the plasma membrane. Prom1 interacts with membrane cholesterol and actively remodels the plasma membrane. Membrane bending activity is particularly evident in photoreceptors, where Prom1 loss-of-function mutations cause failure of outer segment homeostasis, leading to cone-rod retinal dystrophy (CRRD). The Tweety Homology (Ttyh) protein family has been proposed to be homologous to Prominin, but it is not known whether Ttyh proteins have an analogous membrane-bending function. Here, we characterize the membrane-bending activity of human Prom1 and Ttyh1 in native bilayer membranes. We find that Prom1 and Ttyh1 both induce formation of extracellular vesicles (EVs) in cultured mammalian cells and that the EVs produced are physically similar. Ttyh1 is more abundant in EV membranes than Prom1 and produces EVs with membranes that are more tubulated than Prom1 EVs. We further show that Prom1 interacts more stably with membrane cholesterol than Ttyh1 and that this may contribute to membrane bending inhibition in Prom1 EVs. Intriguingly, a loss-of-function mutation in Prom1 associated with CRRD induces particularly stable cholesterol binding. These experiments provide mechanistic insight into Prominin function in CRRD and suggest that Prom and Ttyh belong to a single family of functionally related membrane-bending, EV-generating proteins.</description>
      <author>bell@molbio.mgh.harvard.edu (Arezu Monshizadeh)</author>
      <author>bell@molbio.mgh.harvard.edu (Bridget E Luce)</author>
      <author>bell@molbio.mgh.harvard.edu (Hiba Dardari)</author>
      <author>bell@molbio.mgh.harvard.edu (Luke H Chao)</author>
      <author>bell@molbio.mgh.harvard.edu (Pusparanee Hakim)</author>
      <author>bell@molbio.mgh.harvard.edu (Tran H Nguyen)</author>
      <author>bell@molbio.mgh.harvard.edu (Tristan A Bell)</author>
      <author>bell@molbio.mgh.harvard.edu (Virly Y Ananda)</author>
      <guid isPermaLink="false">https://dx.doi.org/10.7554/eLife.10006</guid>
      <category>Biochemistry and Chemical Biology</category>
      <pubDate>Tue, 13 Aug 2024 00:00:00 +0000</pubDate>
      <dc:date>2024-08-13T00:00:00Z</dc:date>
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