Objectives Exosomes are 50-90 nm extracellular membrane particles that may mediate trans-cellular communication between cells and tissues. We have reported that human urinary exosomes contain miRNA that are biomarkers for salt sensitivity and inverse salt sensitivity of blood pressure. This study examines exosomal transfer between cultured human renal proximal tubule cells (RPTCs) and from RPTCs to human distal tubule and collecting duct cells. Design and methods For RPTC-to-RPTC exosomal transfer, we utilized 5 RPTC lines producing exosomes that were fluorescently labeled with exosomal-specific markers CD63-EGFP or CD9-RFP. Transfer between RPTCs was demonstrated by co-culturing CD63-EGFP and CD9-RFP stable clones and performing live confocal microscopy. For RPTC-to-distal segment exosomal transfer, we utilized 5 distal tubule and 3 collecting duct immortalized cell lines. Results Time-lapse videos revealed unique proximal tubule cellular uptake patterns for exosomes and eventual accumulation into the multi-vesicular body. Using culture supernatant containing exosomes from 3 CD9-RFP and 2 CD63-EGFP RPTC cell lines, all 5 distal tubule cell lines and all 3 collecting duct cell lines showed exosomal uptake as measured by microplate fluorometry. Furthermore, we found that RPTCs stimulated with fenoldopam (dopamine receptor agonist) had increased production of exosomes, which upon transfer to distal tubule and collecting duct cells, reduced the basal reactive oxygen species (ROS) production rates in those recipient cells. Conclusion Due to the complex diversity of exosomal contents, this proximal-to-distal vesicular inter-nephron transfer may represent a previously unrecognized trans-renal communication system.
Basic residues are known to play a critical role in the attachment of protein domains to membrane interfaces. Many of these domains also contain hydrophobic residues that may alter the binding and the position of the domain on the interface. In the present study, the role of phenylanine in determining the membrane position, dynamics and free energy of a peptide derived from the effector domain of the myristoylated alanine-rich C-kinase substrate (MARCKS) protein was examined. Deuterium NMR in membranes containing phosphatidylcholine (PC) and phosphatidylserine (PS) indicates that this peptide, MARCKS(151-175), partially penetrates the membrane interface when bound and alters the effective charge density on the membrane interface by approximately 2 charges per bound peptide. However, a derivative of this peptide in which the five phenylalanines are replaced by alanine, MARCKS-Ala, does not penetrate the interface when membrane-bound. This result was confirmed by depth measurements by electron paramagnetic resonance spectroscopy on several spin-labeled derivatives of the Phe-less derivative. In contrast to nitroxides on MARCKS(151-175), nitroxides on the derivative lacking Phe do not reside within the bilayer but are in the aqueous phase when the peptide is bound to the membrane. The Phe to Ala substitutions shift the position of the labeled side chains by approximately 10-15 A. The side-chain dynamics of MARCKS-Ala are strongly influenced by membrane charge density and indicate that this peptide is drawn closer to the membrane interface at higher charge densities. As expected, MARCKS-Ala binds more weakly to membranes composed of PS/PC (1:9) than does the native MARCKS peptide; however, each phenylalanine contributes only 0.2 kcal/mol to the binding energy difference, far less than the 1.3 kcal/mol expected for the binding of phenylalanine to the membrane interface. This energetic discrepancy and the differences in membrane position of these peptides can be accounted for by a dehydration energy that is encountered as the peptide approaches the membrane interface. This energy likely includes a Born repulsion acting between the charged peptide and the low dielectric membrane interior. The interplay between the long-range attractive Coulombic force, the short-range repulsive force and the hydrophobic effect controls the position and energetics of protein domains on acidic membrane interfaces.
The attractive interaction between basic protein domains and membranes containing acidic lipids is critical to the membrane attachment of many proteins involved in cell signaling. In this study, a series of charged model peptides containing lysine, phenylalanine, and the spin-labeled amino acid tetramethyl-piperidine-N-oxyl-4-amino-4-carboxylic acid (TOAC) were synthesized, and electron paramagnetic resonance (EPR) spectroscopy was used to determine their position on the membrane interface and free energy of binding. When membrane-bound, peptides containing only lysine and TOAC assume an equilibrium position within the aqueous double layer at a distance of approximately 5 A from the membrane interface, a result that is consistent with recent computational work. Substitution of two or more lysine residues by phenylalanine dramatically slows the backbone diffusion of these peptides and shifts their equilibrium position by 13-15 A so that the backbone lies several angstroms below the level of the lipid phosphate. These results are consistent with the hypothesis that the position and free energy of basic peptides when bound to membranes are determined by a long-range Coulombic attraction, the hydrophobic effect, and a short-range desolvation force. The differences in binding free energy within this set of charged peptides is not well accounted for by the simple addition of free energies based upon accepted side chain partition free energies, a result that appears to be in part due to differences in membrane localization of these peptides.
Hydrophobic and electrostatic interactions between the acylated N-terminal end of Src and lipid bilayers are responsible for the attachment of this nonreceptor tyrosine kinase to the membrane-solution interface. To investigate the structure and dynamics of this domain at the membrane interface, a series of peptides based upon the N-terminal end of pp60src, myr-src(2-16), was synthesized with single-site cysteine substitutions and derivatized with a sulfhydryl-reactive proxyl nitroxide. The EPR line shapes and mobility of these peptides when bound to the membrane interface were consistent with an extended peptide conformation, and no evidence was found for either a helical or sheet structure. Line shapes on the myristoylated N-terminal end indicate that this segment is more restricted in its motion than at the C-terminus. Although the membrane affinity of this peptide is much stronger in the presence of acidic lipid, EPR line shapes were not strongly affected by the presence of acidic lipid. An EPR power saturation technique was used to provide information on the position of nitroxides from the interface for the membrane-bound peptide. When membrane bound, labeled side chains at the N-terminal end of the peptide were found to lie in the aqueous phase near the membrane interface; however, for the C-terminal half of the peptide, residues were further off the membrane and were 10-15 A from the interface. Peptides derived from the membrane and calmodulin binding domains of the myristoylated alanine-rich C kinase substrate and neuromodulin were previously found to be in extended conformations; however, side chains for these peptides penetrated the membrane-solution interface. We speculate that the relatively polar character of the N-terminal segment of Src and a Born repulsion energy prevent this peptide from penetrating into the membrane interface when membrane bound.
Signal transduction pathways that are modulated by thiol oxidation events are beginning to be uncovered, but these discoveries are limited by the availability of relatively few analytical methods to examine protein oxidation compared to other signaling events such as protein phosphorylation. We report here the coupling of PROP, a method to purify reversibly oxidized proteins, with the proteomic identification of the purified mixture using mass spectrometry. A gene ontology (GO), KEGG enrichment and Wikipathways analysis of the identified proteins indicated a significant enrichment in proteins associated with both translation and mRNA splicing. This methodology also enabled the identification of some of the specific cysteine residue targets within identified proteins that are reversibly oxidized by hydrogen peroxide treatment of intact cells. From these identifications, we determined a potential consensus sequence motif associated with oxidized cysteine residues. Furthermore, because we identified proteins and specific sites of oxidation from both abundant proteins and from far less abundant signaling proteins (e.g. hepatoma derived growth factor, prostaglandin E synthase 3), the results suggest that the PROP procedure was efficient. Thus, this PROP-proteomics methodology offers a sensitive means to identify biologically relevant redox signaling events that occur within intact cells.
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