Repeat expansions in the C9orf72 gene are a common cause of amyotrophic lateral sclerosis and frontotemporal lobar degeneration, two devastating neurodegenerative disorders. One of the proposed mechanisms of GGGGCC repeat expansion is their translation into non-canonical dipeptide repeats, which can then accumulate as aggregates and contribute to these pathologies. There are five different dipeptide repeat proteins (polyGA, polyGR, polyPR, polyPA and polyGP), some of which are known to be neurotoxic. In the present study, we used BioID2 proximity labelling to identify the interactomes of all five dipeptide repeat proteins consisting of 125 repeats each. We identified 113 interacting partners for polyGR, 90 for polyGA, 106 for polyPR, 25 for polyPA, and 27 for polyGP. Gene Ontology enrichment analysis of the proteomic data revealed that these target interaction partners are involved in a variety of functions, including protein translation, signal transduction pathways, protein catabolic processes, amide metabolic processes, and RNA-binding. Using autopsy brain tissue from patients with C9orf72 expansion complemented with cell culture analysis, we evaluated the interactions between polyGA and valosin-containing protein (VCP). Functional analysis of this interaction revealed sequestration of VCP with polyGA aggregates, altering levels of soluble VCP protein. VCP also functions in autophagy processes, and consistent with this, we observed altered autophagy in cells expressing polyGA. We also observed altered co-localisation of polyGA aggregates and p62 in cells depleted of the VCP protein. Altogether these data suggest that sequestration of VCP with polyGA aggregates contributes to the loss of VCP function, and consequently to alterations in autophagy processes in C9orf72 expansion disorders.
SummaryChemokines are key signals in the immune system and play an important role as proinflammatory mediators in the pathology of inflammatory bowel disease and colorectal cancer, making them an important target for therapy. Recombinant lactic acid bacteria (LAB) were engineered to bind CC and CXC chemokines by displaying chemokine‐binding proteins evasin‐1, evasin‐3 and evasin‐4 on their surface. Evasin genes were cloned into lactococcal surface display vector and overexpressed in L. lactis NZ9000 and NZ9000ΔhtrA in fusion with secretion signal and surface anchor. Evasin‐displaying bacteria removed from 15% to 90% of 11 different chemokines from the solution as determined with ELISA and Luminex multiplexing assays, whereby L. lactis NZ9000ΔhtrA proved more efficient. Lactobacillus salivarius ATCC 11741 was coated with L. . lactis‐expressed evasin fusion protein, and its ability to bind chemokines was also confirmed. Evasin‐3‐displaying L. lactis removed 76.0% of IL‐1β‐induced CXCL8 from the supernatant of Caco‐2 epithelial cells. It also prevented secretion of CXCL8 from Caco‐2 cells in a time‐dependent manner when added before induction with IL‐1β. Evasin‐displaying LAB have the ability to bind multiple chemokines simultaneously and exert synergistic activity. This innovative treatment approach therefore has the potential for mucosal therapy of inflammatory bowel disease or colorectal cancer.
Following the finding that ammodytoxin (Atx), a neurotoxic secreted phospholipase A2 (sPLA2) in snake venom, binds specifically to protein disulfide isomerase (PDI) in vitro we show that these proteins also interact in living rat PC12 cells that are able to internalize this group IIA (GIIA) sPLA2. Atx and PDI co-localize in both differentiated and non-differentiated PC12 cells, as shown by fluorescence microscopy. Based on a model of the complex between Atx and yeast PDI (yPDI), a three-dimensional model of the complex between Atx and human PDI (hPDI) was constructed. The Atx binding site on hPDI is situated between domains b and b’. Atx interacts hPDI with an extensive area on its interfacial binding surface. The mammalian GIB, GIIA, GV and GX sPLA2s have the same fold as Atx. The first three sPLA2s have been detected intracellularly but not the last one. The models of their complexes with hPDI were constructed by replacement of Atx with the respective mammalian sPLA2 in the Atx—hPDI complex and molecular docking of the structures. According to the generated models, mammalian GIB, GIIA and GV sPLA2s form complexes with hPDI very similar to that with Atx. The contact area between GX sPLA2 and hPDI is however different from that of the other sPLA2s. Heterologous competition of Atx binding to hPDI with GV and GX sPLA2s confirmed the model-based expectation that GV sPLA2 was a more effective inhibitor than GX sPLA2, thus validating our model. The results suggest a role of hPDI in the (patho)physiology of some snake venom and mammalian sPLA2s by assisting the retrograde transport of these molecules from the cell surface. The sPLA2–hPDI model constitutes a valuable tool to facilitate further insights into this process and into the (patho)physiology of sPLA2s in relation to their action intracellularly.
Lipid droplets are dynamic organelles with a central role in fatty acid metabolism. They protect cells from lipotoxicity by sequestering excess fatty acids but also provide fatty acids for metabolic reactions and signalling events. Here we show that lipid droplet turnover in cancer cells is required for production of ω-3 and ω-6 polyunsaturated fatty acid (PUFA)-derived inflammatory lipid mediators, including eicosanoids and specialised pro-resolving mediators. We show that incorporation of PUFAs into triglycerides mediated by diacylglycerol acyltransferase 1 (DGAT1), and their release by adipose triglyceride lipase (ATGL), are required for cyclooxygenase- and lipoxygenase-dependent lipid mediator production and cancer cell proliferation. The human group X secreted phospholipase A2 (hGX sPLA2) drives the delivery of membrane-derived PUFAs into lipid droplets, while ATGL promotes the incorporation of lipid droplet-derived PUFAs into phospholipids. The group IVA cytosolic PLA2 (cPLA2α) acts on membrane phospholipids and complements ATGL in the regulation of PUFA trafficking between phospholipids and triglycerides. This study identifies lipid droplets as essential cellular hubs that control PUFA availability for production of lipid mediators involved in inflammation and tumorigenesis.SynopsisThis study shows that lipid droplets in cancer cells control the supply of ω-3 and ω-6 polyunsaturated fatty acids (PUFAs) for the production of lipid mediators, which in turn drive cancer cell proliferation. The esterification of PUFAs into triacylglycerols (TAGs) and their release from lipid droplets are necessary for PUFA entry into lipid mediator production pathways. Lipid mediator production induced by the human group X secreted phospholipase A2 (hGX sPLA2), which releases PUFAs from the plasma membrane and serum lipoproteins, depends on diacylglycerol acyltransferase 1 (DGAT1)-mediated TAG synthesis.Adipose triglyceride lipase (ATGL) liberates ω-3 and ω-6 PUFAs from TAGs and drives lipid mediator production via cyclooxygenase (COX) and lipoxygenase (LOX) pathways.ATGL promotes the incorporation of lipid droplet-derived PUFAs into phospholipids, which are targeted by the group IVA cytosolic PLA2 (cPLA2α), thereby selectively supplying arachidonic acid for lipid mediator production.Lipid droplets are required for cPLA2α-induced lipid mediator production also in cells that do not depend on ATGL for the supply PUFAs into lipid mediator pathways.
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