Intramural Valves of Lymphatic Capillaries of Intestinal Villi in Rats

The article highlights a complex of interendothelial connections of the lymphatic capillary of the rat intestinal villi, and focuses on the path of chylomicron transport through the lymphatic capillary wall after lipid loading.Material and methods. An experimental model was used to exclude a high lipid load; chymus from do- nor rats was injected with a syringe into the initial section of the small intestine in 10 Wistar rats. Chymus was collected from the initial section of the small intestine of donor animals 60 min after oral administration of 1.5 ml of corn oil. The control group consisted of the animals exposed to 12-hour fasting. The material was studied using transmission electron microscopy.Results. It was shown that most often cells are connected by tile-like (66±2.2%) or simple finger-like (27±2.4%) contacts, reinforced with a tight connection and a point adhesive (at the extreme point of contact). An- chor filaments located on the basal surface of endothelial cells at some distance from the extreme contact point “fixed” the lymphatic capillary wall, ensuring its stretching, changing the pressure inside the capillary and opening the valve. Under low lipid load, the main transport pathway of lipids from the interstitium of the intestinal villus to the lumen of the lymphatic capillary was through adhesive intercellular contacts. No chylomicrons were found in the lumen of plasmolemmal vesicles and kidneys. Caveolae in the endothelial cells of the lymphatic capillary, both after lipid loading and in hungry animals, were few. Caveolosomes were rare in both groups. Under low lipid load, no fusion of vesicles with the formation of transendothelial canals was found.Conclusions. The detected structure of contacts of the lymphatic capillary endothelium morphologically substantiates the hypothesis of the regulated resorption of interstitial fluid and macromolecules into the lumen of the lymphatic capillary.

Lipid droplets disrupt mechanosensing in human hepatocytes

This work examines the impact of lipid loading on mechanosensing by human hepatocytes. In cirrhotic livers, the presence of large (although not small) lipid droplets increased nuclear localization of the mechanotransducer YAP. In primary hepatocytes in culture, lipid droplets led to decreased stiffness-induced cell spreading and disrupted focal adhesions and stress fibers; the presence of large lipid droplets resulted in increased YAP nuclear localization. Collectively, the data suggest that lipid droplets induce intracellular mechanical stress.

The lipid transfer protein Saposin B does not directly bind CD1d for lipid antigen loading

Background: Lipid antigens are presented on the surface of cells by the CD1 family of glycoproteins, which have structural and functional similarity to MHC class I molecules. The hydrophobic lipid antigens are embedded in membranes and inaccessible to the lumenal lipid-binding domain of CD1 molecules. Therefore, CD1 molecules require lipid transfer proteins for lipid loading and editing. CD1d is loaded with lipids in late endocytic compartments, and lipid transfer proteins of the saposin family have been shown to play a crucial role in this process. However, the mechanism by which saposins facilitate lipid binding to CD1 molecules is not known and is thought to involve transient interactions between protein components to ensure CD1-lipid complexes can be efficiently trafficked to the plasma membrane for antigen presentation. Of the four saposin proteins, the importance of Saposin B (SapB) for loading of CD1d is the most well-characterised. However, a direct interaction between CD1d and SapB has yet to be described. Methods: In order to determine how SapB might load lipids onto CD1d, we used purified, recombinant CD1d and SapB and carried out a series of highly sensitive binding assays to monitor direct interactions. We performed equilibrium binding analysis, chemical cross-linking and co-crystallisation experiments, under a range of different conditions. Results: We could not demonstrate a direct interaction between SapB and CD1d using any of these binding assays. Conclusions: This work strongly indicates that the role of SapB in lipid loading does not involve direct binding to CD1d. We discuss the implication of this for our understanding of lipid loading of CD1d and propose several factors that may influence this process.

1441LRP5 and PCSK9 in inflammatory cells immunomodulation

Background Atherosclerosis, the leading cause of cardiovascular diseases, is driven by high blood cholesterol levels and chronic inflammation. The disruption of the hepatic interaction between Proprotein Convertase Subtilisin/Kexin 9 (PCSK9) and Low-Density Lipoprotein Receptor (LDLR) downregulates blood cholesterol levels and reduces cardiovascular events. Recent data suggest that other members of the LDLR superfamily may be targets of PCSK9. Purpose The aim of this work is to determine if LDLR-related protein 5 (LRP5) is a PCSK9 target, and to study the role of PCSK9 and LRP5 in foam cell formation and hence, in the mechanism of lipid accumulation and atherosclerotic plaque formation. Methods Intracellular protein and lipid localization, cholesteryl esters (CE) accumulation; quantification of structural and inflammatory proteins expression and immunoprecipitation analyses were performed in primary cultures of human inflammatory cells (monocytes and macrophages) silenced for LRP5 or PCSK9 and challenged with modified LDLs. Results We first show that LRP5 is needed for macrophage lipid uptake since LRP5-silenced macrophages have less intracellular CE accumulation. In LDL treated macrophages internalization of LRP5-bound LDL starts after 30 minutes of incubation and lasts up to 24hours. The SREBP-2 promoter is not involved in LRP5 regulation but it does regulate macrophage PCSK9 expression. Immunoprecipitation experiments show that LRP5 forms a complex with PCSK9 in lipid-loaded macrophages. Finally we studied the role of PCSK9 and LRP5 in the inflammatory response by TLR4/NFkB signaling pathway. We show decreased TLR4 protein expression levels and decreased nuclear translocation of NFκB in PCSK9 silenced-inflammatory cells after lipid loading indicating a downregulation of the proinflammatory pathway TLR4/NFκB. Increased gene expression is observed in TNF-α and IL1β after lipid-loading that is abolished in PCSK9-silenced macrophages. Furthermore release of the proinflammatory cytokines TNF-α and IL1β is decreased in PCSK9-silenced macrophages. LRP5 protein expression is increased in lipid-loaded macrophages independent of the presence or absence of PCSK9. Conclusions These results demonstrate that, in human macrophages, LRP5 is internalized with lipids. Furthermore, PCSK9 and LRP5 can form a complex in the cytoplasm of lipid-loaded macrophages opening the possibility that PCSK9 induces lysosomal LRP5 degradation in a similar manner than it does with LDLR. Finally we also show that PCSK9 gene interference decreases inflammation and supports a role for PCSK9 as an inflammatory mediator in atherosclerosis. Acknowledgement/Funding CN16/11/00411-LB; TERCEL RD16/0011/018-LB; FIS2016-02014 -MBP; SEC2015 to MBP

The lipid transfer protein Saposin B does not directly bind CD1d for lipid antigen loading

Background: Lipid antigens are presented on the surface of cells by the CD1 family of glycoproteins, which have structural and functional similarity to MHC class I molecules. The hydrophobic lipid antigens are embedded in membranes and inaccessible to the lumenal lipid-binding domain of CD1 molecules. Therefore, CD1 molecules require lipid transfer proteins for lipid loading and editing. CD1d is loaded with lipids in late endocytic compartments, and lipid transfer proteins of the saposin family have been shown to play a crucial role in this process. However, the mechanism by which saposins facilitate lipid binding to CD1 molecules is not known and is thought to involve transient interactions between protein components to ensure CD1-lipid complexes can be efficiently trafficked to the plasma membrane for antigen presentation. Of the four saposin proteins, the importance of Saposin B (SapB) for loading of CD1d is the most well-characterised. However, a direct interaction between CD1d and SapB has yet to be described. Methods: In order to determine how SapB might load lipids onto CD1d, we used purified, recombinant CD1d and SapB and carried out a series of highly sensitive binding assays to monitor direct interactions. We performed equilibrium binding analysis, chemical cross-linking and co-crystallisation experiments, under a range of different conditions. Results: We could not demonstrate a direct interaction between SapB and CD1d using any of these binding assays. Conclusions: This work establishes comprehensively that the role of SapB in lipid loading does not involve direct binding to CD1d. We discuss the implication of this for our understanding of lipid loading of CD1d and propose several factors that may influence this process.

The lipid transfer protein Saposin B does not directly bind CD1d for lipid antigen loading

Lipid antigens are presented on the surface of cells by the CD1 family of glycoproteins, which have structural and functional similarity to MHC class I molecules. The hydrophobic lipid antigens are embedded in membranes and inaccessible to the lumenal lipid-binding domain of CD1 molecules. Therefore, CD1 molecules require lipid transfer proteins for lipid loading and editing. CD1d is loaded with lipids in late endocytic compartments, and lipid transfer proteins of the saposin family have been shown to play a crucial role in this process. However, the mechanism by which saposins facilitate lipid binding to CD1 molecules is not known and is thought to involve transient interactions between protein components to ensure CD1-lipid complexes can be efficiently trafficked to the plasma membrane for antigen presentation. Of the four saposin proteins, the importance of Saposin B (SapB) for loading of CD1d is the most well-characterised. However, a direct interaction between CD1d and SapB has yet to be described. In order to determine how SapB might load lipids onto CD1d, we used purified, recombinant CD1d and SapB and carried out a series of highly sensitive binding assays to monitor direct interactions. Using equilibrium binding analysis, chemical cross-linking and co-crystallisation experiments, under a range of different conditions, we could not demonstrate a direct interaction. This work establishes comprehensively that the role of SapB in lipid loading does not involve direct binding to CD1d. We discuss the implication of this for our understanding of lipid loading of CD1d and propose several factors that may influence this process.