Targeting of the AE2 anion exchanger to the Golgi apparatus is cell type-dependent and correlates with the expression of Ank(195), a Golgi membrane skeletal protein

Sodium-independent anion exchangers (AE1-4) show remarkable variability in their tissue-specific expression and subcellular localization. Currently, isoform-specific targeting mechanisms are considered to be responsible for this variable localization. Here, we report that targeting can also be cell type-specific. We show that the full-length AE2 protein and its green fluorescent protein- or DsRed-tagged variants localize predominantly either to the Golgi apparatus in COS-7 cells, or to the plasma membrane in HeLa cells. This alternative targeting did not seem to result from either translational or post-translational differences, but rather from differential expression of at least one of the Golgi membrane skeletal proteins, ankyrin(195) (Ank(195)), between the two cell types. Comparative studies with several different cell lines revealed that the Golgi localization of the AE2 protein correlated strictly with the expression of Ank(195) in the cells. The two Golgi-associated proteins also co-localized well and similarly resisted detergent extraction in the cold, whereas the plasma membrane-localized AE2 in Ank(195)-deficient cells was mostly detergent-soluble. Collectively, our results suggest that Ank(195) expression is a key determinant for the variable and cell type-dependent localization of the AE2 protein in the Golgi apparatus in mammalian cells.     

OligoDesign: Optimal design of LNA (locked nucleic acid) oligonucleotide capture probes for gene expression profiling

We report the development of new software, OligoDesign, which provides optimal design of LNA (locked nucleic acid) substituted oligonucleotides for functional genomics applications. LNAs constitute a novel class of bicyclic RNA analogs having an exceptionally high affinity and specificity toward their complementary DNA and RNA target molecules. The OligoDesign software features recognition and filtering of the target sequence by genome-wide BLAST analysis in order to minimize cross-hybridization with non-target sequences. Furthermore it includes routines for prediction of melting temperature, self-annealing and secondary structure for LNA substituted oligonucleotides, as well as secondary structure prediction of the target nucleotide sequence. Individual scores for all these properties are calculated for each possible LNA oligonucleotide in the query gene and the OligoDesign program ranks the LNA capture probes according to a combined fuzzy logic score and finally returns the top scoring probes to the user in the output. We have successfully used the OligoDesign tool to design a Caenorhabditis elegans LNA oligonucleotide microarray, which allows monitoring of the expression of a set of 120 potential marker genes for a variety of stress and toxicological processes and toxicologically relevant pathways. The OligoDesign program is freely accessible at http://lnatools.com/.     

Non-thermal activation of the hsp27/p38MAPK stress pathway by mobile phone radiation in human endothelial cells: molecular mechanism for cancer- and blood-brain barrier-related effects

Abstract We have examined whether non-thermal exposures of cultures of the human endothelial cell line EA.hy926 to 900 MHz GSM mobile phone microwave radiation could activate stress response. Results obtained demonstrate that 1-hour non-thermal exposure of EA.hy926 cells changes the phosphorylation status of numerous, yet largely unidentified, proteins. One of the affected proteins was identified as heat shock protein-27 (hsp27). Mobile phone exposure caused a transient increase in phosphorylation of hsp27, an effect which was prevented by SB203580, a specific inhibitor of p38 mitogen-activated protein kinase (p38MAPK). Also, mobile phone exposure caused transient changes in the protein expression levels of hsp27 and p38MAPK. All these changes were non-thermal effects because, as determined using temperature probes, irradiation did not alter the temperature of cell cultures, which remained throughout the irradiation period at 37 ± 0.3 °C. Changes in the overall pattern of protein phosphorylation suggest that mobile phone radiation activates a variety of cellular signal transduction pathways, among them the hsp27/p38MAPK stress response pathway. Based on the known functions of hsp27, we put forward the hypothesis that mobile phone radiation-induced activation of hsp27 may (i) facilitate the development of brain cancer by inhibiting the cytochrome c/caspase-3 apoptotic pathway and (ii) cause an increase in blood-brain barrier permeability through stabilization of endothelial cell stress fibers. We postulate that these events, when occurring repeatedly over a long period of time, might become a health hazard because of the possible accumulation of brain tissue damage. Furthermore, our hypothesis suggests that other brain damaging factors may co-participate in mobile phone radiation-induced effects.     

The complex effects of the invasive polychaetes Marenzelleria spp. on benthic nutrient dynamics

The effects of the polychaetes Marenzelleria sp. (Polychaeta, Spionidae), nonindigenous, rapidly increasing species in the Baltic Sea, on benthic nutrient fluxes, denitrification and sediment pore water nutrient concentration were studied in laboratory experiments using a flow-through setup with muddy sediment from coastal regions of the Gulf of Finland. In addition, different forms of sediment phosphorus (P), separated by chemical fractionation, were studied in three sediment layers. At a population density corresponding to about half the highest measured in the northern Baltic Sea, Marenzelleria sp. increased the fluxes of P and ammonium to the water column. No effect could be recorded for denitrification. Since the previously dominant species of the area, Monoporeia affinis, can enhance denitrification and lower the amount of dissolved P in the pore water, the replacement of M. affinis with Marenzelleria spp. may lead to increased P flux to the water column and decreased denitrification, further increasing the ammonium flux to the water column. However, sediment reworking by Marenzelleria spp. also oxidizes the surface sediment in the long run, improving its ability to retain P and support nitrification. Therefore, the impact of Marenzelleria spp. on sediment nutrient release may not be as drastic as the initial reactions seen in our experiments suggest.     

Detection of microRNAs in frozen tissue sections by fluorescence in situ hybridization using locked nucleic acid probes and tyramide signal amplification

The ability to determine spatial and temporal microRNA (miRNA) accumulation at the tissue, cell and subcellular levels is essential for understanding the biological roles of miRNAs and miRNA-associated gene regulatory networks. This protocol describes a method for fast and effective detection of miRNAs in frozen tissue sections using fluorescence in situ hybridization (FISH). The method combines the unique miRNA recognition properties of locked nucleic acid (LNA)-modified oligonucleotide probes with FISH using the tyramide signal amplification (TSA) technology. Although both approaches have previously been shown to increase detection sensitivity in FISH, combining these techniques into one protocol significantly decreases the time needed for miRNA detection in cryosections, while simultaneously retaining high detection sensitivity. Starting with fixation of the tissue sections, this miRNA FISH protocol can be completed within approximately 6 h and allows miRNA detection in a wide variety of animal tissue cryosections as well as in human tumor biopsies at high cellular resolution.     

The Major Autoantibody Epitope on Factor H in Atypical Hemolytic Uremic Syndrome Is Structurally Different from Its Homologous Site in Factor H-related Protein 1, Supporting a Novel Model for Induction of Autoimmunity in This Disease

Atypical hemolytic uremic syndrome (aHUS) is characterized by complement attack against host cells due to mutations in complement proteins or autoantibodies against complement factor H (CFH). It is unknown why nearly all patients with autoimmune aHUS lack CFHR1 (CFH-related protein-1). These patients have autoantibodies against CFH domains 19 and 20 (CFH_19–20), which are nearly identical to CFHR1 domains 4 and 5 (CFHR1_4–5). Here, binding site mapping of autoantibodies from 17 patients using mutant CFH_19–20 constructs revealed an autoantibody epitope cluster within a loop on domain 20, next to the two buried residues that are different in CFH_19–20 and CFHR1_4–5. The crystal structure of CFHR1_4–5 revealed a difference in conformation of the autoantigenic loop in the C-terminal domains of CFH and CFHR1, explaining the variation in binding of autoantibodies from some aHUS patients to CFH_19–20 and CFHR1_4–5. The autoantigenic loop on CFH seems to be generally flexible, as its conformation in previously published structures of CFH_19–20 bound to the microbial protein OspE and a sialic acid glycan is somewhat altered. Cumulatively, our data suggest that association of CFHR1 deficiency with autoimmune aHUS could be due to the structural difference between CFHR1 and the autoantigenic CFH epitope, suggesting a novel explanation for CFHR1 deficiency in the pathogenesis of autoimmune aHUS.     

N-linked (N-) Glycoproteomics of Urimary Exosomes*

Epithelial cells lining the urinary tract secrete urinary exosomes (40–100 nm) that can be targeted to specific cells modulating their functionality. One potential targeting mechanism is adhesion between vesicle surface glycoproteins and target cells. This makes the glycopeptide analysis of exosomes important. Exosomes reflect the physiological state of the parent cells; therefore, they are a good source of biomarkers for urological and other diseases. Moreover, the urine collection is easy and noninvasive and urinary exosomes give information about renal and systemic organ systems. Accordingly, multiple studies on proteomic characterization of urinary exosomes in health and disease have been published. However, no systematic analysis of their glycoproteomic profile has been carried out to date, whereas a conserved glycan signature has been found for exosomes from urine and other sources including T cell lines and human milk.Here, we have enriched and identified the N-glycopeptides from these vesicles. These enriched N-glycopeptides were solved for their peptide sequence, glycan composition, structure, and glycosylation site using collision-induced dissociation MS/MS (CID-tandem MS) data interpreted by a publicly available software GlycopeptideId. Released glycans from the same sample was also analyzed with MALDI-MS.We have identified the N-glycoproteome of urinary exosomes. In total 126 N-glycopeptides from 51 N-glycosylation sites belonging to 37 glycoproteins were found in our results. The peptide sequences of these N-glycopeptides were identified unambiguously and their glycan composition (for 125 N-glycopeptides) and structures (for 87 N-glycopeptides) were proposed. A corresponding glycomic analysis with released N-glycans was also performed. We identified 66 unique nonmodified N-glycan compositions and in addition 13 sulfated/phosphorylated glycans were also found. This is the first systematic analysis of N-glycoproteome of urinary exosomes.Urine is a combination of plasma filtrate and the secretion profile of cells lining the urino-genital tract. This secretion profile, in addition to proteins and metabolites, also contains exosomes and larger microvesicles that have glycoproteins on their surface. In healthy individuals, ∼70% of the urinary proteome originates from kidneys and the rest represents plasma filtered by glomeruli (1). Proteins present in urine are a collection of proteins secreted by a number of tissues, which changes in disease states (2). Therefore, the urinary proteome may serve as a rich source of biomarkers for urogenital and systemic diseases, which have been reviewed previously (3). Moreover, urine collection is a noninvasive procedure, which makes it an ideal candidate for discovery of novel biomarkers. Only a few large scale studies on urinary proteome and glycoproteome have been published (4, 5). However, most of them have not focused on the glycopeptide characterization.Microvesicles, including exosomes are secreted by many cell types and involved in functions including antigen-presentation, cell-to-cell communication, and immunomodulation (6). These are specialized compartments of cells and they mirror the physiological state of cells secreting them while also providing information about the environment into which they are secreted. For instance, the immunosuppressive and pro-angiogenic environment of cancer may be mediated partially by exosomes (6). Exosomes and other types of microvesicles are abundantly found in urine and thought to be mainly secreted by epithelial cells lining the urinary system (7). These vesicles contain DNA, RNA, and proteins.Glycosylation is an important post-translational modification of proteins and lipids and appears to play many roles, e.g. in cell adhesion, cell-to-cell communication, and immune response (8). Glycosylation is also very important for targeting of proteins to various compartments of the cells. Accordingly, glycans of glycoproteins have important roles in protein sorting to membrane microdomains and furthermore in influencing their intracellular trafficking (9). Microvesicles have a glycan signature that is distinct from the parent cell, suggesting that they originate from specialized membrane microdomains implying a role of glycosylation in microvesicle protein sorting (10, 11). Changes in N-glycans of exosomes from expressed prostatic secretions correlate with disease severity (12). HIV-1 particles were found to have a glycome (the comprehensive glycan profile of a protein, cell, or tissue) largely shared with microvesicles, which is taken to imply that the virus hijacks the glycomachinery of infected cells and uses it systematically to infect additional cells or to deceive the normal immunodefence (13). Thus, the specific glycoproteins of exosomes may be of major impact in targeting exosomes to distinct cells and tissues.Exosome uptake in various cell types has been shown to occur through the mechanisms of clathrin-mediated endocytosis, phagocytosis, and micropinocytosis (14, 15). The uptake of exosomes by dendritic cells and macrophages has been shown to be inhibited by mannose, N-acetylglucosamine, and lactose residues, respectively. This uptake is mediated by a C-type lectin in dendritic cells and galectin-5 in macrophages (14, 15). All this points toward a system in which the exosome glycosylation pattern is kept specific by the cells secreting them to suit the target cell makeup and uptake pathways, and further downstream functions. Taken together, these findings suggest that better understanding of surface glycosylation patterns as well as the glycomics and glycoproteomics of exosomes might help in establishing the specificity of exosome uptake by target cells and activated downstream pathways. This information about exosome uptake might be utilized in therapeutics involving exosomes. Glycome and glycoproteome of urinary microvesicles will provide information not only about the functional state of constituent proteins, but it will also highlight the similarities and differences among proteins that are specifically targeted to exosomes.An N-glycopeptide analysis using collision induced dissociation (CID)-Tandem MS has been reported previously for different sample types (16, 17). This approach provides information about the composition of glycan, partial structure, glycosylation site, and peptide sequence from the same molecule compared with approaches where released glycans or peptides of N-glycopeptides are analyzed separately.We have published an algorithm for an automated analysis of N-glycopeptides (18, 19). A public, web-based software with some changes to the original was developed and named as GlycopeptideId (www.appliednumerics.com, GlycopeptideID version 28–02-28 0.91 beta). The major change was to analyze glycan structures against a database and not with an iterative de novo glycan structure analysis. The proposed structures were further manually validated by the presence of diagnostic ions, when they were available for the given structure.This software was utilized in this study and a comprehensive glycopeptide characterization of urinary exosomal glycoproteins was carried out. We report here the glycan structure determination of urinary exosomal glycoproteins. We have characterized 126 N-glycopeptides representing 51 N-glycosylation sites that belong to 37 glycoproteins. Additionally, glycomic analysis of released N-glycans was also performed and 66 unique modified and 13 sulfated and/or phosphorylated glycans were found. A third of total glycan compositions were common to both the analysis, whereas approximately a third were unique to both the analysis.     

Minor Role of Plasminogen in Complement Activation on Cell Surfaces

Atypical hemolytic uremic syndrome (aHUS) is a rare, but severe thrombotic microangiopathy. In roughly two thirds of the patients, mutations in complement genes lead to uncontrolled activation of the complement system against self cells. Recently, aHUS patients were described with deficiency of the fibrinolytic protein plasminogen. This zymogen and its protease form plasmin have both been shown to interact with complement proteins in the fluid phase. In this work we studied the potential of plasminogen to restrict complement propagation. In hemolytic assays, plasminogen inhibited complement activation, but only when it had been exogenously activated to plasmin and when it was used at disproportionately high concentrations compared to serum. Addition of only the zymogen plasminogen into serum did not hinder complement-mediated lysis of erythrocytes. Plasminogen could not restrict deposition of complement activation products on endothelial cells either, as was shown with flow cytometry. With platelets, a very weak inhibitory effect on deposition of C3 fragments was observed, but it was considered too weak to be significant for disease pathogenesis. Thus it was concluded that plasminogen is not an important regulator of complement on self cells. Instead, addition of plasminogen was shown to clearly hinder platelet aggregation in serum. This was attributed to plasmin causing disintegration of formed platelet aggregates. We propose that reduced proteolytic activity of plasmin on structures of growing thrombi, rather than on complement activation fragments, explains the association of plasminogen deficiency with aHUS. This adds to the emerging view that factors unrelated to the complement system can also be central to aHUS pathogenesis and suggests that future research on the mechanism of the disease should expand beyond complement dysregulation.