Expression cloning of the human C3a anaphylatoxin receptor (C3aR) from differentiated U‐937 cells
A cDNA clone encoding the human C3a anaphylatoxin receptor (C3aR) was isolated from a pcDNAI/Amp expression library prepared from U-937 cells which had been differentiated with dibutyryl cAMP to a macrophage-like phenotype. The cDNA clone contained an insert of 4.3 kbp and was able to confer to transfected human HEK-293 cells the capacity to bind specifically iodinated human C3a. Chinese hamster ovary cells co-transfected with this cDNA clone and a G-protein alpha subunit (G alpha-16) became functionally responsive to C3a and a C3a analog synthetic peptide, as measured by increased phosphoinositide hydrolysis. As inferred from the cDNA sequence, the clone encodes a 482-residue polypeptide with seven hydrophobic membrane-spanning helices and a high homology to the human C5a and formyl-Met-Leu-Phe receptors. Uniquely among the family of G-protein coupled receptors, the C3aR contains an exceptionally large second extracellular loop of approximately 175 residues. Northern hybridizations revealed an approximately 2.3-kb transcript as the major and an additional approximately 3.9 kb-transcript as a minor transcription product of the C3aR. The C3aR appears to be widely expressed in different lymphoid tissues, as shown by Northern hybridizations, providing evidence for a central role of the C3a anaphylatoxin in inflammatory processes.
This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits distribution, and reproduction in any medium, provided the original author and source are credited. This license does not permit commercial exploitation without specific permission.Y-box protein (YB)-1 of the cold-shock protein family functions in gene transcription and RNA processing. Extracellular functions have not been reported, but the YB-1 staining pattern in inflammatory glomerular diseases, without adherence to cell boundaries, suggests an extracellular occurrence. Here, we show the secretion of YB-1 by mesangial and monocytic cells after inflammatory challenges. It should be noted that YB-1 was secreted through a non-classical mode resembling that of the macrophage migration inhibitory factor. YB-1 release requires ATP-binding cassette transporters, and microvesicles protect YB-1 from protease degradation. Two lysine residues in the YB-1 carboxy-terminal domain are crucial for its release, probably because of post-translational modifications. The addition of purified recombinant YB-1 protein to different cell types results in increased DNA synthesis, cell proliferation and migration. Thus, the non-classically secreted YB-1 has extracellular functions and exerts mitogenic as well as promigratory effects in inflammation.
Splicing Factor SRp30c Interaction with Y-box Protein-1 Confers Nuclear YB-1 Shuttling and Alternative Splice Site Selection
The multifunctional DNA-and RNA-associated Y-box protein 1 (YB-1) specifically binds to splicing recognition motifs and regulates alternative splice site selection. Here, we identify the arginine/serine-rich SRp30c protein as an interacting protein of YB-1 by performing a two-hybrid screen against a human mesangial cell cDNA library. Co-immunoprecipitation studies confirm a direct interaction of tagged proteins YB-1 and SRp30c in the absence of RNA via two independent protein domains of YB-1. A high affinity interaction is conferred through the N-terminal region. We show that the subcellular YB-1 localization is dependent on the cellular SRp30c content. In proliferating cells, YB-1 localizes to the cytoplasm, whereas FLAG-SRp30c protein is detected in the nucleus. After overexpression of YB-1 and FLAG-SRp30c, both proteins are co-localized in the nucleus, and this requires the N-terminal region of YB-1. Heat shock treatment of cells, a condition under which SRp30c accumulates in stress-induced Sam68 nuclear bodies, abrogates the co-localization and YB-1 shuttles back to the cytoplasm. Finally, the functional relevance of the YB-1/SRp30c interaction for in vivo splicing is demonstrated in the E1A minigene model system. Here, changes in splice site selection are detected, that is, overexpression of YB-1 is accompanied by preferential 5 splicing site selection and formation of the 12 S isoform.The Y-box protein YB-1 is a member of the cold shock protein family, which exhibits pleiotropic functions. YB-1 specifically binds to a sequence motif termed Y-box. This motif is characterized by the presence of a core ATTGG sequence, which represents the inverted CCAAT-box. YB-1 controls the transcription of numerous genes that among others include MHC class II antigen, MDR1, MMP-2, and COL1A1 (1-4). DNA binding specificity is mediated through the evolutionarily conserved cold shock domain in conjunction with the adjacent C-terminal protein residues (5, 6). Interactions of YB-1 with numerous cellular and viral transcription factors including JC virus antigen (7), AP-2 (8), Pur␣ (9), CTCF (10), and p53 (11, 12) have been demonstrated. These interactions may in part explain cell-specific gene regulation, that is, stimulation and repression of transcription, even of the same gene (3). In addition, it has been proposed that YB-1 plays a role as an architectural protein by its propensity to sequence specifically unwind DNA duplexes and stabilize single-stranded templates, thereby altering sequence recognition motifs (1,4,8).In addition to their role in regulating gene transcription, cold shock proteins exhibit a wide spectrum of activities by virtue of sequence-specific and -nonspecific RNA binding. YB-1 has been identified as the major component of messenger ribonucleoprotein particles (mRNPs) in mammalian cells, which constitute templates for the translational machinery (13-15). At higher concentrations Y-box proteins Xenopus FRGY2 and human YB-1 act as repressors of translation in a process called mRNA masking (13, 16 -18), wh...
Notch‐3 receptor activation drives inflammation and fibrosis following tubulointerstitial kidney injury
Kidney diseases impart a vast burden on affected individuals and the overall health care system. Progressive loss of renal parenchymal cells and functional decline following injury are often observed. Notch-1 and -2 receptors are crucially involved in nephron development and contribute to inflammatory kidney diseases. We specifically determined the participation of receptor Notch-3 following tubulointerstitial injury and in inflammatory responses. Here we show by heat map analyses that Notch-3 transcripts are up-regulated in human kidney diseases. A similar response was corroborated with kidney cells following TGF-β exposure in vitro. The murine unilateral ureteral obstruction (UUO) model mirrors hallmarks of tubulointerstitial injury and damage. A subset of tubular and interstitial cells demonstrated up-regulated Notch-3 receptor expression in diseased animals. We hypothesized a relevance of Notch-3 receptors for the chemotactic response. To address this question, animals with genetic ablation of receptor Notch-3 were analysed following UUO. As a result, we found that Notch-3-deficient animals are protected from tubular injury and cell loss with significantly reduced interstitial collagen deposition. Monocytic cell infiltration was significantly reduced and retarded, likely due to abrogated chemokine synthesis. A cell model was set up that mimics enhanced receptor Notch-3 expression and activation. Here a pro-mitogenic response was seen with activated signalling in tubular cells and fibroblasts. In conclusion, Notch-3 receptor fulfils non-redundant roles in the inflamed kidney that may not be replaced by other Notch receptor family members. Thus, specific blockade of this receptor may be suitable as therapeutic option to delay progression of kidney disease.
YB-1 Acts as a Ligand for Notch-3 Receptors and Modulates Receptor Activation
Y-box (YB) protein-1 is secreted by mesangial and immune cells after cytokine challenge, but extracellular functions are unknown. Here, we demonstrate that extracellular YB-1 associates with outer cell membrane components and interacts with extracellular Notch-3 receptor domains. The interaction appears to be specific for Notch-3, as YB-1-green fluorescent protein binds to the extracellular domains and full-length forms of Notch-3 but not to Notch-1. YB-1-green fluorescent protein and Notch-3 proteins co-localize at cell membranes, and extracellular YB-1 activates Notch-3 signaling, resulting in nuclear translocation of the Notch-3 intracellular domain and up-regulation of Notch target genes. The YB-1/Notch-3 interaction may be of particular relevance for inflammatory mesangioproliferative disease, as both proteins co-localize in an experimental nephritis model and receptor activation temporally and spatially correlates with YB-1 expression.
Two Active Molecular Phenotypes of the Tachykinin NK1 Receptor Revealed by G-protein Fusions and Mutagenesis
The NK1 neurokinin receptor presents two non-ideal binding phenomena, two-component binding curves for all agonists and significant differences between agonist affinity determined by homologous versus heterologous competition binding. Whole cell binding with fusion proteins constructed between either G␣ s or G␣ q and the NK1 receptor with a truncated tail, which secured nonpromiscuous G-protein interaction, demonstrated monocomponent agonist binding closely corresponding to either of the two affinity states found in the wild-type receptor. High affinity binding of both substance P and neurokinin A was observed in the tail-truncated G␣ s fusion construct, whereas the lower affinity component was displayed by the tail-truncated G␣ q fusion. The elusive difference between the affinity determined in heterologous versus homologous binding assays for substance P and especially for neurokinin A was eliminated in the G-protein fusions. An NK1 receptor mutant with a single substitution at the extracellular end of TM-III-(F111S), which totally uncoupled the receptor from G␣ s signaling, showed binding properties that were monocomponent and otherwise very similar to those observed in the tail-truncated G␣ q fusion construct. Thus, the heterogenous pharmacological phenotype displayed by the NK1 receptor is a reflection of the occurrence of two active conformations or molecular phenotypes representing complexes with the G␣ s and G␣ q species, respectively. We propose that these molecular forms do not interchange readily, conceivably because of the occurrence of microdomains or "signal-transductosomes" within the cell membrane.Many G-protein-coupled 7TM 1 (transmembrane segment) receptors have the capacity to interact with multiple G-proteins and thus regulate more than one effector pathway. Some receptors preferentially couple to one G-protein, but in the presence of higher, non-physiological concentrations of agonist or in, for example reconstitution assays, these receptors are able to couple to other G-proteins (1, 2). Other more promiscuous receptors couple functionally to more than one G-protein in the physiological range of agonist concentration (3-6). For example, the neurokinin NK1 receptor is coupled to two different signaling pathways: a G␣ q pathway, which activates phospholipase C , thereby initiating inositol phosphate formation and a G␣ s pathway, which induces cAMP formation. Both effector systems are activated by nanomolar physiological concentrations of substance P (6). Other endogenous neurokinin peptides such as NKA and NKB as well as artificial peptide ligands such as septide can act as high affinity agonists on the NK1 receptor (7). Interestingly, in whole cell binding experiments, the NK1 receptor displays certain characteristics that indicate that the receptor in the cell membrane occurs in more than one high affinity active molecular form. First, competition binding experiments using the agonist substance P as a tracer reveal two-component binding curves for all agonists, indicating the occurrence of ...
Y-Box Binding Protein-1 Controls CC Chemokine Ligand-5 (CCL5) Expression in Smooth Muscle Cells and Contributes to Neointima Formation in Atherosclerosis-Prone Mice
Background-The CC chemokine CCL5/Regulated on Activation, Normal T Cell Expressed and Secreted (RANTES) is upregulated in mononuclear cells or deposited by activated platelets during inflammation and has been implicated in atherosclerosis and neointimal hyperplasia. We investigated the influence of the transcriptional regulator Y-box binding protein (YB)-1 on CCL5 expression and wire-induced neointimal hyperplasia. Methods and Results-Analysis of the CCL5 promoter revealed potential binding sites for YB-1, and interaction of YB-1 with a sequence at position Ϫ204/Ϫ173 was confirmed by DNA binding assays. Both YB-1 expression and CC chemokine ligand-5 (CCL5) mRNA expression were increased in neointimal versus medial smooth muscle cells, as analyzed by real-time polymerase chain reaction. Overexpression of YB-1 in smooth muscle cells (but not macrophages) enhanced CCL5 transcriptional activity in reporter assays, mRNA and protein expression, and CCL5-mediated monocyte arrest. Carotid arteries of hyperlipidemic apolipoprotein E-deficient mice were subjected to intraluminal transfection with a lentivirus encoding YB-1 short hairpin RNA or empty vector directly after wire injury. Double immunofluorescence revealed YB-1 expression in neointimal smooth muscle cells but not macrophages and colocalization with neointimal CCL5, which was downregulated by YB-1 short hairpin RNA. Neointima formation was decreased significantly after YB-1 knockdown compared with controls and was associated with a diminished content of lesional macrophages. A reduction of lesion formation by YB-1 knockdown was not observed in apolipoprotein E-deficient mice deficient in the CCL5 receptor CCR5 or after treatment with the CCL5 antagonist Met-RANTES, which indicates that YB-1 effects were dependent on CCL5. Conclusions-The transcriptional regulator YB-1 mediates CCL5 expression in smooth muscle cells and thereby contributes to neointimal hyperplasia, thus representing a novel target with which to limit vascular remodeling.
In vitro studies identified Y-box–binding protein (YB)-1 as a key regulator of inflammatory mediators. In this study, we observed increased levels of secreted YB-1 in sera from sepsis patients. This led us to investigate the in vivo role of YB-1 in murine models of acute peritonitis following LPS injection, in sterile renal inflammation following unilateral ureteral obstruction, and in experimental pyelonephritis. LPS injection enhanced de novo secretion of YB-1 into the urine and the peritoneal fluid of LPS-treated mice. Furthermore, we could demonstrate a significant, transient upregulation and posttranslational modification (phosphorylation at serine 102) of YB-1 in renal and inflammatory cells. Increased renal cytoplasmic YB-1 amounts conferred enhanced expression of proinflammatory chemokines CCL2 and CCL5. Along these lines, heterozygous YB-1 knockout mice (YB-1+/d) that display 50% reduced YB-1 levels developed significantly lower responses to both LPS and sterile inflammation induced by unilateral ureteral obstruction. This included diminished immune cell numbers due to impaired migration propensities and reduced chemokine expression. YB-1+/d mice were protected from LPS-associated mortality (20% mortality on day 3 versus 80% in wild-type controls); however, immunosuppression in YB-1+/d animals resulted in 50% mortality. In conclusion, our findings identify YB-1 as a major, nonredundant mediator in both systemic and local inflammatory responses.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
Contact Info
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Product
Resources
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.
