The adenosine deaminases that act on RNA (ADARs) catalyze the site-specific conversion of adenosine to inosine (A to I) in primary mRNA transcripts, thereby affecting the splicing pattern or coding potential of mature mRNAs. Although the subnuclear localization of A-to-I editing has not been precisely defined, ADARs have been shown to act before splicing, suggesting that they function near nucleoplasmic sites of transcription. Here we demonstrate that ADAR2, a member of the vertebrate ADAR family, is concentrated in the nucleolus, a subnuclear domain disparate from the sites of mRNA transcription. Selective inhibition of ribosomal RNA synthesis or the introduction of mutations in the double-stranded RNAbinding domains within ADAR2 results in translocation of the protein to the nucleoplasm, suggesting that nucleolar association of ADAR2 depends on its ability to bind to ribosomal RNA. Fluorescence recovery after photobleaching reveals that ADAR2 can shuttle rapidly between subnuclear compartments. Enhanced translocation of endogenous ADAR2 from the nucleolus to the nucleoplasm results in increased editing of endogenous ADAR2 substrates. These observations indicate that the nucleolar localization of ADAR2 represents an important mechanism by which RNA editing can be modulated by the sequestration of enzymatic activity from potential RNA substrates in the nucleoplasm.T he conversion of adenosine to inosine (A to I) by RNA editing was first observed in yeast tRNAs (1) but has since been identified in numerous viral and cellular mRNA transcripts (2-4). A-to-I editing is most often identified as an adenosineto-guanosine (A-to-G) discrepancy between genomic and cDNA sequences due to the similar base-pairing properties of inosine and guanosine during cDNA synthesis. A-to-I conversion is catalyzed via hydrolytic deamination at the C6 position of the adenine ring (5) and requires an extended region of doublestranded RNA (dsRNA) in potential RNA substrates formed by intramolecular base-pairing interactions between exon and intron sequences (2-4). A family of adenosine deaminases that act on RNA (ADARs) have been extensively characterized and are responsible for catalyzing the site-specific A-to-I conversion observed in cellular mRNA transcripts (6-8). ADAR-mediated RNA editing events can change the amino acid coding potential of genomically encoded transcripts to produce protein products with altered functional properties (2, 3). For example, the editing of RNAs encoding mammalian ionotropic glutamate receptor (GluR) subunits can lead to the production of heteromeric glutamate-gated channels with altered ion permeation and agonist-induced desensitization kinetics (9-11), whereas the editing of transcripts encoding the 2C-subtype of serotonin receptor (5-HT 2C R) can generate receptor isoforms that couple to heterotrimeric G proteins with decreased efficiency (12-14). A-to-I editing events have also been described in nontranslated RNA species and noncoding regions of mRNA transcripts (15)(16)(17), suggesting that such modif...
Inflammation associated with CNS demyelination provides an important stimulus for the activation of endogenous oligodendrocyte precursor cells (OPCs) and subsequent remyelination. This view is largely based on "loss-of-function" studies, whereby remyelination is impaired following depletion of inflammatory cells or mediators. However, "gain-of-function" approaches, asking whether inflammation directly enhances remyelination, have received less attention. We have addressed this issue using a model in which OPCs transplanted into the adult rat retina myelinate retinal ganglion cell axons around the point of injection. Inflammation (characterized by increased expression of the macrophage marker ED1 and the astrocyte marker GFAP, and the up-regulation of multiple cytokines) was induced in the retina by the administration of the TLR-2 ligand zymosan. Myelination, revealed by MBP+ myelin sheaths, was substantially increased when OPCs were injected into the inflamed retina compared to that achieved following transplantation into the normal, noninflamed retina. Our results have important implications for the development of immunomodulatory treatments for acute demyelinating disease and for the therapeutic creation of proremyelination environments in chronic demyelinating disease.
The pancreatic islets of Langerhans are highly vascularized micro-organs that play a key role in the regulation of blood glucose homeostasis. The specific arrangement of endocrine cell types in islets suggests a coupling between morphology and function within the islet. Here, we established a line-scanning confocal microscopy approach to examine the relationship between blood flow and islet cell type arrangement by real-time in vivo imaging of intra-islet blood flow in mice. These data were used to reconstruct the in vivo 3D architecture of the islet and time-resolved blood flow patterns throughout the islet vascular bed. The results revealed 2 predominant blood flow patterns in mouse islets: inner-to-outer, in which blood perfuses the core of β cells before the islet perimeter of non-β cells, and top-to-bottom, in which blood perfuses the islet from one side to the other regardless of cell type. Our approach included both millisecond temporal resolution and submicron spatial resolution, allowing for real-time imaging of islet blood flow within the living mouse, which has not to our knowledge been attainable by other methods.
Human small ubiquitin-like modifier (sumo) proteins include sumo-1 and the less studied, nearly identical sumo-2 and sumo-3 proteins. Whereas the structurally related ubiquitin molecule targets proteins for degradation, sumo provides a distinct, yet poorly understood regulatory signal. Protein sumoylation is sensitive to diverse cellular stresses, yet the targets of sumoylation in stress are unknown. We studied protein sumoylation in HEK293 cells exposed to hydrogen peroxide, alkylating agents, and the lipid oxidation-derived electrophile 4-hydroxynonenal, which is an ubiquitous product of lipid oxidation associated with oxidative stress. Confocal immunofluorescence microscopy indicated that in unstressed cells sumo-1 targeted nuclear proteins, whereas sumo-2/3 targeted proteins in both nuclei and cytoplasm. Western blot analyses revealed changes in sumo-1 and sumo-2/3 targeting patterns with stress. We used immunoaffinity chromatography to harvest sumo-associated proteins from HA-sumo-1- and HA-sumo-3-expressing HEK293 cells both before and after treatment with 4-hydroxynonenal. Multidimensional liquid chromatography-tandem mass spectrometry analyses identified 54 HA-sumo-1-associated proteins and 38 HA-sumo-3-associated proteins. Major protein targets included RNA binding and processing proteins, transcription factors, metabolic enzymes, and cytoskeletal regulators. Treatment with 4-hydroxynonenal caused a near-complete redistribution of sumo-1 and sumo-3 to different protein targets, which included chaperones, antioxidant, and DNA damage signaling proteins. A 10-15% overlap of sumo-1 and sumo-3 targets before and after stress suggests that sumo proteins target distinct protein groups. The results suggest that reactive electrophiles not only directly modify proteins but also lead to indirect changes in endogenous protein modifications that regulate protein functions.
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