Angiotensin (Ang) II is present inside vascular smooth muscle cells (VSMCs); however, its intracellular functions, if any, are unknown. We tested the hypothesis that intracellular Ang II exerts effects on cytosolic Ca2+ ([Ca2+]i) in VSMCs. Ang II was administered via microinjection. Intracellular Ang II localization was demonstrated by fluorescein-labeled Ang II and electron microscopy. [Ca2+]i was monitored by confocal microscopy with fluo 3. Ang II was identified in endosomes and in the nucleus by both localizing techniques. Microinjection of Ang II (10(-10) mol/L) led to a rapid increase in [Ca2+]i in the cytosol and in the nucleus. The [Ca2+]i increase was due to the influx of extracellular Ca2+ ions. The intracellular Ang II effect was totally inhibited by the concomitant injection of the Ang II antagonist CV-11947. Desensitization of extracellular Ang II receptors, on the other hand, did not influence the intracellular effects, nor did extracellular CV-11947. The increase in [Ca2+]i was observed not only in the microinjected cell but also in directly adjacent VSMCs. In contrast to the microinjected cells, the [Ca2+]i increase in the adjacent cells was mostly due to release from intracellular stores. Pretreatment with thapsigargin abolished the Ang II response in adjacent cells. Microinjection of inositol tris-phosphate induced a [Ca2+]i response in adjacent cells that was similar to the Ang II-induced effects. Preincubation of VSMCs with the uncoupling substances dimethyl sulfoxide and heptanol did not decrease the Ang II response but instead prevented a [Ca2+]i surge in adjacent cells. We conclude that intracellular Ang II binds to intracellular Ang II receptors and elicits an increased [Ca2+]i in the injected cell and, thereafter, cells in the immediate neighborhood. Cell-cell contact is necessary for the Ang II-mediated effects. The data suggest that intracellular Ang II may stimulate a cluster of VSMCs from a single cell via the release of second messengers.
Dedifferentiation and proliferation of vascular smooth muscle cells (VSMCs) are important features of atherosclerosis. The molecular mechanisms are largely unclear; however, protein kinase C (PKC) is a key enzyme in the intracellular signaling pathways that mediate this process. We studied the activity and immunoreactivity of PKC-alpha in primary cultures of VSMCs from rat aortas under different conditions of growth and differentiation. PKC-alpha was determined under the following conditions: (1) during the growth phase and after confluence of cultured (passages 1 through 3) VSMCs, (2) before and after induction of differentiation in VSMCs by retinoic acid, and (3) in primary cultures of VSMCs from spontaneously hypertensive rats (SHR) and Wistar-Kyoto (WKY) rats during early passages. PKC activity was measured by in vitro substrate phosphorylation. PKC-alpha immunoreactivity was assessed by Western blot using specific polyclonal antibodies and by immunostaining with confocal microscopy. Cell proliferation was measured by direct count. The cell phenotype was characterized by immunostaining and Western blot for alpha-actin and desmin. PKC-alpha expression and PKC activity during VSMC growth showed a decrease during rapid growth and an increase in confluent cells. This pattern was associated with the respective changes in cell differentiation. Retinoic acid induced an increase in PKC-alpha expression together with a more differentiated phenotype. Subcultured, rapidly growing VSMCs from SHR showed a decreased PKC-alpha expression compared with cells from WKY rats. To establish cause and effect, we next microinjected either PKC-alpha or inactivated material directly into dedifferentiated cells. We found that cells injected with active PKC-alpha expressed increased amounts of actin compared with control cells.(ABSTRACT TRUNCATED AT 250 WORDS)
High glucose concentrations and protein kinase C isoforms in vascular smooth muscle cells
High extracellular glucose activates protein kinase C (PKC), a family of kinases vital to intracellular signaling. However, which PKC isoforms are involved and where in the cell they operate is unclear. We tested the hypothesis that only those PKC isoforms binding to diacylglycerol (DAG) are activated by high glucose. We also reasoned that the isoforms would translocate to different parts of the cell, where they presumably serve different functions. The PKC isoforms alpha, beta, delta, epsilon, and zeta were studied. Twenty mM glucose caused an increase in total PKC activity at six hours, which was maintained at 24 hours. High glucose decreased the angiotensin II-induced calcium signal. This effect was reversed by preincubating the cells with the PKC inhibitor staurosporine. Glucose induced a translocation of all PKC isoforms except PKC zeta by Western blot. Confocal microscopy showed that PKC alpha, beta, and epsilon were translocated into the nucleus. PKC delta showed strong association with cytoskeletal structures. The effects were sustained at 24 hours for PKC isoform beta and to a lesser extent for PKC delta and epsilon, but not for PKC alpha. Thus, PKC isoforms differ in their propensity to be activated by high glucose. Those isoforms binding to DAG are activated. Both cytoskeletal and nuclear signaling may be involved.
Protein kinase C is an important second-messenger system that is translocated from the cytosol to the cell membrane on cell stimulation. We used confocal microscopy to study the spatial distribution of protein kinase C isoforms after stimulation of cultured vascular smooth muscle cells with platelet-derived growth factor and angiotensin II (Ang II). Monoclonal antibodies for the isoforms a and p were used. Translocation was also assessed by Western blot. Isoform a was evenly distributed in the cytosol, whereas the £ isoform formed coarse granules in the perinuclear region. Both isoforms shifted from the cytosolic to the membrane fraction after exposure to Ang II (10~7 mol/L) and platelet-derived growth factor (100 ng/mL at 6, 12, and 20 minutes). Confocal microscopy showed a rapid assembly of isoform a along P rotein kinase C (PKC) is a group of calcium-and phospholipid-dependent protein kinases (isoforms) involved in signal transduction responses.1 Activation of PKC has been implicated in vascular smooth muscle cell (VSMC) contraction, 2 DNA synthesis, and cell growth 36 (for review see Reference 7). PKC is located in the cytosol of VSMCs and other cells during the resting state but is "translocated" to the cell membrane after stimulation. 810 However, because the membrane fraction includes not only cell membranes but also nuclear material, earlier studies do not allow a precise definition of subcellular PKC distribution after cell stimulation. Other investigators observed that only a portion of PKC is shifted to the surface membranes and that PKC is associated with nuclear membranes and cytoskeletal proteins, 11 1 5 which raises the possibility that PKC may also perform important tasks elsewhere within the cell.The pattern of isoform distribution may also vary depending on the activation state of the cell or the agonists used. 16 In VSMCs the calcium-sensitive PKC isoforms a and )3 9 as well as the calcium-independent PKC isoforms e and £ have been described. 17 We tested the hypothesis that PKC isoforms have different distributions in VSMCs at rest and during agonist stimulation. We used confocal microscopy to examine the From the UniversitatskJinikum Steglitz and UniversitStsklinikum Rudolf Virchow, Franz Volhard Klinik at the Max-Delbruck Center for Molecular Medicine, Free University of Berlin (Germany).Correspondence to Hermann Haller, MD, Franz Volhard Klinik, Universitatsklinikum Rudolf Virchow, Wiltberg Strasse 50, 13125 Berlin, FRG. cytosolic fibers at 6 minutes followed by a translocation toward the nucleus at 12 minutes with Ang II. Platelet-derived growth factor engendered a similar response; however, a cytoskeletal distribution was not observed. The /3 isoform was rapidly translocated by both inducers to the perinuclear region and the nucleus. Our results show that inducers cause a translocation of protein kinase C isoforms not only into the cell membrane but also into the cell nucleus. We suggest that protein kinase C may also be important for nuclear signaling. (Ang II) and platelet-d...
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