Search

Your search keyword '"Swandulla, D."' showing total 24 results
Start Over Author "Swandulla, D." Database Supplemental Index
24 results on '"Swandulla, D."'

3. Voltage‐dependent and calcium‐dependent inactivation of calcium channel current in identified snail neurones.

Author

Gutnick, M J, Lux, H D, Swandulla, D, and Zucker, H

Abstract

1. The dependence of Ca2+ current inactivation on membrane potential and intracellular Ca2+ concentration ([Ca2+]i) was studied in TEA‐loaded, identified Helix neurones which possess a single population of high‐voltage‐activated Ca2+ channels. During prolonged depolarization, the Ca2+ current declined from its peak with two clearly distinct phases. The time course of its decay was readily fitted by a double‐exponential function. 2. In double‐pulse experiments, the relationship between the magnitude of the Ca2+ current and the amount of Ca2+ inactivation was not linear, and considerable inactivation was present, even when conditioning pulses were to levels of depolarization so great that Ca2+ currents were near zero. Similar results were obtained when external Ca2+ was replaced by Ba2+. 3. In double‐pulse experiments, hyperpolarization during the interpulse interval served to reprime a portion of the inactivated Ca2+ current for subsequent activation. The extent of repriming increased with hyperpolarization, reaching a maximum between ‐130 and ‐150 mV. The effectiveness of repriming hyperpolarizations was considerably increased when Ca2+ was replaced by Ba2+. 4. A significant fraction of inactivated Ca2+ channels can be recovered during hyperpolarizing pulses lasting only milliseconds. If hyperpolarizing pulses were applied before substantial inactivation of Ca2+ current, Ca2+ channels remained available for activation despite considerable Ca2+ entry. 5. The relationship between [Ca2+]i and inactivation was investigated by quantitatively injecting Ca2+‐buffered solutions into the cells. The time course of Ca2+ current inactivation was unchanged at free [Ca2+] between 1 x 10(‐7) and 1 x 10(‐5) M. From 1 x 10(‐7) to 1 x 10(‐9) M, inactivation became progressively slower, mainly due to a decrease of the amplitude ratio (fast/slow) of the two components of inactivation, which fell from about unity to near zero at 1 x 10(‐9) M. In double‐pulse experiments, recovery from inactivation was enhanced in neurones that had been injected with Ca2+ chelator. 6. We conclude that inactivation of Ca2+ channels in these neurones depends on both [Ca2+]i and membrane potential. The voltage‐dependent process may serve as a mechanism to quickly recover inactivated Ca2+ channels during repetitive firing despite considerable Ca2+ influx. 7. The results are discussed in the framework of a model which is based on two states of inactivation, INV and INCA, which represent different conformations of the inactivating substrate, and which are both reached from a lumped state of activation (A). Inactivation leads to high occupancy of INV during depolarization.(ABSTRACT TRUNCATED AT 400 WORDS)

Published
1989
Full Text
View/download PDF

5. Effect of menthol on two types of Ca currents in cultured sensory neurons of vertebrates

Author

Swandulla, D., Carbone, E., Schäfer, K., and Lux, H. D.

Abstract

The effect of menthol on voltage-dependent Ca currents was investigated in cultured dorsal root ganglion cells from chick and rat embryos. Bath application of menthol (0.1–1 mM) had different effects on the various Ca currents present in these neurons. Below -20 mV, the low threshold Ca currents were reduced in amplitude in a dose-dependent manner by menthol with little changes of their activation kinetics. In contrast to this, the time course of inactivation of the high-threshold Ca currents, activated above -20 mV from a holding potential of -80 mV, was drastically accelerated by external menthol. The action of menthol was unchanged with more positive holding potentials (-50 mV). Thus, a proposed third type of Ca current with transient activation and complete deactivation below -50 mV was either not present or not affected by menthol. Menthol exerted its action only when applied from the outside. Its effect was completely reversible within 15–20 min of wash-out. Our findings are consistent with the idea that menthol acts on two types of Ca channels coexisting on the membrane of cultured sensory neurons. Menthol blocks currents through the low voltage-activated Ca channel, and facilitates inactivation gating of the classical high voltage-activated Ca channel.

Published
1987
Full Text
View/download PDF

6. Activation of a nonspecific cation conductance by intracellular Ca2+ elevation in bursting pacemaker neurons of Helix pomatia.

Author

Swandulla, D and Lux, H D

Abstract

The pacemaker current of a bursting neuron of Helix pomatia was investigated using voltage-clamp and pressure-injection techniques. In the steady state the net membrane current was zero near threshold of the action potential at -45 mV. Negative to this potential the membrane current was inward and steady. During burst activity a long-lasting inward current instantaneously appeared with voltage steps to membrane potentials below -20 mV. This inward current was already present when the clamp step fell into the rising phase of the first spike and became larger during the depolarizing phase of the spike. The repolarization phase and the interspike interval did not add much current. As the spike duration became longer in the course of the burst discharge the inward current grew in amplitude, but its increase was not proportional to that of the spike duration. This was observed with clamp steps to the potassium equilibrium potential (EK = -70 mV). The inward current decayed during a hyperpolarizing step with a half time of approximately 400 ms, which was invariant to voltage as measured between -40 and -100 mV. It decreased linearly from -100 to -40 mV with an extrapolated zero potential of about -20 mV. The inward current was not generated by spikes if the Ca2+ conductance was blocked by Ni2+. At membrane potentials positive to EK the development of an outward current, probably carried by K+, could be observed during the burst. It overlasted the inward current and decayed with time constants of 6-7 s. This current grew successively in amplitude in the course of the burst discharge and finally nullified the inward-current component at potentials around spike threshold, thus terminating the burst. An inward current with properties similar to the spike-induced inward current was produced by pressure injecting CaCl2 into the neurons. This current was unselectively carried by cations as shown by both ion-substitution experiments and measurements with ion-selective microelectrodes. Large cations such as choline, TEA, and Tris passed through the channels nearly as well as Na+. Changes in the H+ or Cl- concentration were not seen to affect the inward current. Spike as well as the injection-induced currents were largest in bursting pacemaker cells compared with other cells of similar size. Both currents were found to be small or absent in nonbursting but regularly firing pacemaker cells, albeit these cells reveal a larger Ca2+ current density than the bursting pacemaker cell.(ABSTRACT TRUNCATED AT 400 WORDS)

Published
1985

7. Development and properties of synaptic mechanisms in a network of rat hypothalamic neurons grown in culture.

Author

Swandulla, D and Misgeld, U

Abstract

1. Dissociated neurons from embryonic rat hypothalamus (E14-15) were cultured on a glial background monolayer for up to three months. Dendrites of cells 7-14 days in culture (DIC) intracellularly stained with the fluorescent dye Lucifer yellow were thin and smooth, and multiple growth cones could be observed. The length of the dendrites of older cells did not differ much, but dendrites were thicker and branched more profoundly, forming a complicated network. Growth cones were rare, but few spine-like protrusions could be observed. 2. Randomly occurring depolarizing potentials were recorded in 60% of the cells 7-14 DIC and in 90% of the cells 21 DIC. Activity became phasic when the gamma-aminobutyric acid (GABA) antagonists picrotoxin or bicuculline were applied. After 21 DIC the majority of the cells showed burst discharges, whereas only approximately 10% of the cells 7 DIC exhibited bursting. 3. With low [Cl] in the recording pipette, spontaneous activity consisted of hyperpolarizing and depolarizing potentials at -40-mV membrane potential. Some spontaneous activity persisted with Na channels blocked by tetrodotoxin (TTX, 0.3-1 microM), and when reducing the external [Ca]o from 5 to 0.3 mM. Picrotoxin blocked part of the activity, and the remaining activity was blocked by kynurenic acid. 4. Bursts of action potentials were superimposed on rhythmically occurring clusters of excitatory synaptic potentials (EPSPs), which had a steep rising phase and decayed within hundreds of milliseconds. Bursts of similar appearance could be triggered by brief (10 ms) depolarizing current injections, and a few cells had properties indicative for endogenous pacemakers. 5. From 7 DIC on, all cells responded to GABA and to the GABA agonist muscimol. Under voltage clamp, zero current potential depended on the Cl gradient across the membrane and corresponded to the zero current potential of picrotoxin-sensitive postsynaptic currents. 6. After 21 DIC all cells responded to glutamate and its agonist quisqualate. Under voltage clamp, nanomolar concentrations of quisqualate (100-500 nM) induced long-lasting inward currents, which did not decay substantially during prolonged drug application. Quisqualate concentrations greater than 1 microM induced a diphasic inward-current response consisting of an initial fast current transient followed by a maintained current component. With internal Cs replacing K and Na and external TTX (0.3 microM), both current components reversed sign at approximately 8 mV, as predicted by the Nernst equation for currents through channels that were permeable for monovalent cations. 7. Focal applications of GABA and muscimol elicited larger currents when applied near the soma than when applied to the dendrites.(ABSTRACT TRUNCATED AT 400 WORDS)

Published
1990

8. Ionic currents in cultured rat hypothalamic neurones.

Author

Müller, T H, Misgeld, U, and Swandulla, D

Abstract

1. Dissociated neurones from embryonic rat hypothalamus were grown for several weeks in culture where they formed complex networks. These synaptically coupled networks were capable of generating synchronized bursting activity. Voltage‐activated membrane currents were studied in these neurones using a patch clamp in the whole‐cell configuration. 2. Outward currents were carried by K+ ions and consisted of an inactivating and a non‐inactivating component. These components were similar to the transient K+ current (IA) and the delayed rectifier current (IK) reported in neurones from the postnatal rat hypothalamus. Application of Zn2+ (1 mM) blocked the transient component completely while reducing the non‐inactivating component by only approximately 20%. 3. Inward currents were carried by Na+ and Ca2+ ions. Rapidly activating transient Na+ currents were activated at approximately ‐25 mV. TTX entirely blocked these currents at low concentration (300 nM). Voltage sensitivity of the Na+ conductance was 5.8 mV per e‐fold change with half‐maximal activation occurring at ‐8 mV. Na+ current kinetics could be well described by the Hodgkin‐Huxley model (m3h). 4. With depolarizing pulses from a holding potential of ‐80 mV two Ca2+ current components with different ranges of activation were identified. Low voltage‐activated (LVA, T‐type) Ca2+ currents were activated at approximately ‐50 mV. High voltage‐activated (HVA; also called L‐ or N‐type) Ca2+ currents were observed at membrane potentials more positive to approximately ‐30 mV. LVA Ca2+ currents were observed in hypothalamic neurones that had developed a network of dendritic processes in the course of several weeks in culture. Activation and inactivation time constants of LVA Ca2+ currents were 15‐25 ms and 30‐100 ms (‐30 to ‐45 mV). In contrast to HVA Ca2+ currents, no LVA Ca2+ currents were seen in neuronal somata obtained from the network cultures by mechanical dissociation. This suggests that most of the LVA Ca2+ channels are located on the dendritic tree rather than on the soma membrane. 5. HVA Ca2+ currents were maximal between 0 and +10 mV (external [Ca2+] = 5 mM). The time‐to‐peak was in the range of 1.7‐5.4 ms (+30 to ‐10 mV). Tail currents following repolarization decayed monoexponentially with a time constant of approximately 210 microseconds. During 500 ms depolarizations, 90% of the current inactivated. The time course of inactivation showed two time constants of approximately 40 and approximately 700 ms.(ABSTRACT TRUNCATED AT 400 WORDS)

Published
1992
Full Text
View/download PDF

9. Abstract of the 68th Meeting (Spring Meeting) 6–9 March 1990, Heidelberg

Author

Sakmann, B., Schrader, J., Brenner, B., Murer, H., Boeckh, J., Handwerker, H. O., HonerjÄger, P., Dugas, M., Wang, G., DeLuca, A., Brinkmeier, H., Fakler, B., Pröbstle, T., Rüdel, R., Pohl, J. -A., Meves, H., Kroll, B., Bremer, S., Tümmler, B., Frömter, E., Schwegler, J. S., Steigner, W., Silbernagl, S., Pusch, Michael, Niemann, P., Schmidtmayer, J., Ulbricht, W., Hansen, G., Lönnendonker, U., Neumcke, B., Eickhorn, R., Hornung, D., Antoni, H., Penner, R., Neher, E., Takeshima, H., Nishimura, S., Numa, S., Melzer, W., Feldmeyer, D., Pohl, B., Zöllner, P., Müller, T. H., Swandulla, D., Misgeld, U, Ganitkevich, V. Ya., Isenberg, G., Cavalié, A., Allen, T. J. A., Trautwein, W., Pelzer, Siegried, Shuba, Yaroslav M., Asai, Tatsuya, Trautwein, Wolfgang, Brown, Arthur M., Birnbauner, Lutz, McDonald, Terence F., Pelzer, Dieter, Eckert, R., Hescheler, J., Rosenthal, W., Offermann, S., Krautwurst, D., Schultz, G., Kettenmahn, Helmut, Trotter, J., Verkhratsky, Alexe J N., Savtchenko, Alexej N., Verkhratsky, Alexej N., Schiefer, A., Klöckner, U., Partridge, L. D., SchÄfer, S., Jonas, P., Koh, D. S., Kampe, K., Hermsteiner, M., Vogel, W., Bauer, C. K., Schwarz, J. R., Fink, R. H. A., Wettwer, E., Weik, R., Schlatter, E., Bleich, M., Granitzer, M., Leal, T., Nagel, W., Crabbé, J., Lang, F., Kahn, E., Friedrich, F., Paulmichl, M., Hammerer, M., Maly, K., Grunicke, H., Böhm, T., Nilius, B., Gögelein, H., Dahlem, D., Weiss, H., Waldegger, S., Woell, E., Paulmichl, R., Ruppersberg, J. P., Schröter, K. H., Stocker, M., Pongs, O., Wittka, R., Boheim, G., Lichtinghagen, R, Augustine, C. K., Stühmer, W., Hoppe, Dorothe, Hoppe, D., Zittlau, K. E., Walther, C., Hatt, H., Franke, C., Quasthoff, S., Wischmeyer, E., Jockusch, H., Friedrich, M., Benndorf, K., Bollmann, G., Hirche, Hj., Hollunder-Reese, F., Mohrmann, M., Greger, R., Weber-Schürholz, S., Schürholz, T., Akabas, M., Landry, D., Al-Awqati, Q., Guse, A. H., Gercken, G., Meyerhof, W., Westphale, H. -J., Kerstins, U., Oberleithner, H., Tilmann, M., Kunzelmann, K., Klitsch, T., Siemen, D., Draguhn, A., Verdoorn, T. A., Pritchett, D. B., Seeburg, P. H., Malherbe, P., Möhler, H., Sakmann, B., Hatt, H., Dudel, J., Stern, P., Zufall, F., Rosenheimer, J., Smith, D. O., Dörner, R., Ballanyi, K., Schlue, W. -R., Kalthof, B., Pott, L., Busch, C., Konno, T., Stenql, M., Reinhardt, Ch., Kaiser, H., Baumann, R., Wilimzig, M., Eichenlaub, R., Neumann, E., Lessmann, V., Gottmann, K., Dietzel, I. D., Keller, B. U., Yaari, Y., Konnerth, A., Backus, K. H., Giller, T., Knoflach, F., Pflimlin, P., Trübe, G., von Blankenfeld, G., Ymer, S., Sontheimer, H., Ewert, M., Seeburg, P. H., Kettenmann, H., Schneggenburger, R., Paschke, D., Hülser, D. F., Ubl, J., Kolb, H. A., Ströttchen, J., Boheim, S., Wehner, F., Guth, D., Kinne, R. K. H., Hülser, D. F., Polder, H. R., Bödeker, D., Hoppe, Susanne, Höller, H., Hampe, W., Ruf, H., Schulz, I., Dehlinger-Kremer, M., Ozawa, T., Vasilets, L., Schmalzing, G., MÄdefessel, K., Biel, H., Schwarz, W., Burckhardt, B. C., Stallmach, N., MairbÄurl, H., Hoffman, J. F., Schömig, E., Heuner, A., Göbel, B. O., Siffert, W., Butke, A., Hoffmann, G., zu Brickwedde, M. -K. Meyer, Vetter, H., Düsing, R., Rosskopf, D., Osswald, U., Steffgen, J., Koepsell, H., Martens, H., Rübbelke, M., GÄbel, G., Arens, J., Stabel, J., Fischer, Y., Thomas, J., Rose, H., Kammermeier, H., Munsch, Thomas, Deitmer, Joachim W., Engelmann, B., Duhm, J., Deitmer, Joachim W., Gunzel, D., Galler, S., Fischer, H., Clauss, W., Van Driessche, W., Köckerling, A, Schulzke, JD, Sorgenfrei, D, Fromm, M, Simon, B., Ganapathy, V., Leibach, F. H., Burckhardt, G., Krattenmacher, R., Voigt, Rosita, Dietrich, S., Leyssens, A., Zhang, S. L., Weltens, R., Steels, P., Hoffmann, B., Heinz, M., Habura, B., Dörge, A., Rechkemmer, G., von Engelhardt, W., StrauB, O., Wiederholt, M., Margineanu, D. -G., Van Driessche, W., Kreusel, K. M., Fromm, M., Lempart, U., Sorgenfrei, D., Hegel, U., Augustin, A. J., . Goldstein, R., Purucker, E., Lutz, J., Illek, B., Thiele, K -P., Schwealer, JS., Dittmer, J., Bauer, C., Eckardt, K. -U., Dittmer, J., Neumann, R., Bauer, C., Kurtz, A., Fromm, H., Schulzke, J. D., Clausen, P., Krohn, A., Lüderitz, S., Hierholzer, K., Kersting, U., Woinowski, L., Gro\mann, R., Bin, X. U., Ellendorff, F., Nitschke, R., Fröbe, U., Scholz, H., della Bruna, R., Ehmke, H., Persson, P. B., Seyfarth, M., Kirchheim, H. R., Dietrich, M. S., Parekh, N., Steinhausen, M., Bührle, C. P., Nobiling, R., Ullrich, K. J., Rumrich, G., Klöss, S., Papavassiliou, F., Hoyer, J., Schmitt, C., Jungwirth, A., Ritter, M., Westphale, H. J., Bevan, C., Theiss, C., Denek, Liliana, Schwegler, Johann S., SchÄfer, Roland, Augustin, Albert J., Heidland, August, Nafz, B., Just, A., Steidl, M., Pinggera, G., Gerstberger, R., Schütz, H., Simon, E., Lohrmann, E., Masereel, B., Delarge, J., Lang, H. J., Englert, H. C., Caliebe, D., Mályusz, M., Wrigge, P., Gronow, G., Klause, N., Mályusz, M., Zinnert, H., Fagel, H., Jelkmann, W., Weiss, Ch., Augustin, A. J., Keil, R., Schmidt, W., Kröger, C., Brabant, E. G., Hilgendorf, A., Strauch, S., Lane, F., Prick, A., Golenhofen, N., Mildenberger, S., Schwegler, J. S., Flemming, B., Roloff, D., Wronski, T., Drews, G., Debuyser, A., Henquin, J. C., Jackson, M. B., DeRiemer, S. A., Schmid, A., Schnefel, S., Pröfrock, A., Hinsch, K. -D., Milz, J., Lamprecht, G., Seidler, U., Silen, W., Aziz, O., Reschke, W., Fischer, G., De Decker, N., Hayes, T., Coast, G., Van Kerkhove, E., von zur Mühlen, F., Eckstein, F., Hegel, U, Bentzel, CJ, Riecken, EO, Siemer, C., Rothenpieler, P., Smith, E., Lutnicki, K. R., Wróbel, J. T., Ledwożyw, A., PietraŚ, E., Sender, S., Jürgens, Klaus D., Kleinschmidt, T., Werkmeister, F., Kiwull-Schöne, H., Kiwull, P., Vahle, J., Ott, M., Zimmermann, R. E., Elsing, J. G., Million, D., Zillner, P., Thiel, M., Bardenheuer, H., Peter, K., Fandrey, J., Siegers, C. P., Rupp, H., Elimban, V., Dhalla, N. S., Morano, I., Agostini, B., Mühleisen, M., Mommaerts, W. F. H. M., Ono, K., Wussling, M., Schenk, W., Boldt, W., Lipp, P., Schüttler, K., Szymanski, G., Wendt-Gallitelli, M. F., Herzig, J. W., Depersin, H., Grupp, G., Grupp, I., Glitsch, H. G., Pusch, H., Zylka, Ch., Brāndle, M., Jacob, R., Stein, T., Isselhard, W., Sturz, J., Minor, T., Wingenfeld, P., Siegmund, B., Klietz, T., Schwartz, P., Piper, H. M., Linder, Christa, SchÄfer, Stefan, Heusch, Gerd, Becker, B. F., Reinholz, N., Raschke, P., Leipert, B., Gerlach, E., Dierberger, B., Gülch, R. W., Leverkus, M., Mitsuiye, T., Pohl, U., Wang, S. Y., Meyer, R., Haas, H. G., Christmann, H. Ph, Dörner, Th, Hock, D., Hertel, R., Gagelmann, M., Forssmann, W. G., Leijendekker, W. J., Kissling, G., Michel, H., Goetz, A., Freya, M., Fleckenstein-Grün, G., Schipke, Jochen D., Harasawa, Yasuhiko, Sugiura, Seiryo, Alexander, Joe, Burkhoff, Daniel, Kling, L., Müller-Beckmann, B., Schroth, M., Sponer, G., Böhm, E., Strein, K., Dorszewski, A., Arnold, G., Pike, G. K., Bryant, D. J., Roberts, M. L., Fink, R. H., Ross, Ch., Skyschally, A., Schulz, R., Linder, C., Heusch, G., Schipke, J. D., Burkhoff, D., Alexander, J., Gollnick, F., Peter, Kh., Franken-Weyers, R., Borst, M. M., Deussen, A., Pöpping, S., Hose, H., Strotmann, K. H., Lukascek, B., Karnath, T., Güttier, K., Klaus, W., Haverkampf, K., Guhlmann, M., Schmidt-Ott, S., Heuschen, U., Mall, G., Pfitzer, G., Rösch, J., Arner, A., Rüegg, J. C., Kröger, K., Schipke, J. D., ThÄmer, V., Ehring, Thomas, ThÄmer, Volker, Guth, B. D., Schnabel, Ph A., Schmiedl, A., Gebhard, M. M., Richter, J., Bretschneider, H. J., Guth, B. D., Oudiz, R. J., Schnabel, Ph., Richter, J ., Watanabe, H., Spahr, R., Piper, H. M., Obst, O., Mertens, H., Mülsch, A., Busse, R., Lamontagne, D., Herlan, K., Huang, A., Bassenae, E., Mackert, J. R. L., Schilling, L., Parsons, A. A., Wahl, M., Hock, D., Christmann, M. Ph., Thimm, F., Frey, M., Fleckenstein, a. A., Theilen, H., Göbel, U., Kuschinsky, W., Elbert, Th., Tafil-Klawe, M., Rau, H., Lutzenberger, W., Fleckenstein, A., Forst, H., Haller, M., Santjohanser, C., Lauterjung, L., Smieško, Y., Lang, D. J., Johnson, P. C., Schröck, H., Rau, H., Elbert, T., Geiger, B, Lutzenberger, W., Koch, G., Koralewski, H. E., Perschel, F. H., Wagner, K., Krüger, U., Albrecht, M., Hohlbach, G., Maassen, N., Foerster, M., Mühling, J., Bari, F., Pleschka, K., Schmidt, H. D., Gro\, H., Loock, W., Stick, C., Diefenbacher, U., Gronewold, D., Tobinsky, M., Walther-Behrends, A., Witzleb, E., Brummermann, M., Reinertsen, R. E., Rogausch, H., Rohn, W. M., Acker, H., Delpiano, M., Dufau, E., Hentschel, J., Heller, H., Schuster, K. -D., Siekmeier, R., Kronenberger, H., Lintl, H., Schiller-Scotland, Ch. F., Gebhart, J., Heyder, J., Meier-Sydow, J., Stahlhofen, W., Mottaghy, K., Geisen, C., Richter, W., Beckman, J., Marek, W., Ulmer, W. T., Thiele, A. E., Raschke, F., Peter, J. H., Hildebrandt, G., Kullmer, T., Kozianka-Burghof, G., Thiele, A. E., Schlaefke, M. E., Gnuschke, H., Schaefer, T., Schaefer, D., Schaefer, C., Bradley, Ronald J., Sterz, Raimund, Peper, Klaus, Benterbusch, R., Kraft, Th., Yu, L. C., Kuhn, H. J., Blankenbach, K., Asmussen, G., Kunze, I., Pieper, K. -S., Steinmetz, J., Schmidt, H., Krippeit-Drews, P., Hübschen, U., Nacimiento, A. C., Günzel, D., Rathmayer, W., Gaunitz, U., Költgen, D., Zachar, E., Soltau, B., De Martino, L., Hasselbach, W., Kössler, F., Lange, P., Küchler, G., Zeugner, C., Van Eyk, J., Hodges, R. S., Lorkovic, H., Clemens, N., Scheid, P., Noack, Th., Deitmer, P., Golenhofen, K., Lammel, E., Welling, Andrea, Felbel, Jochen, Hofmann, Franz, Katoch, S., Watanabe, T., Mandrek, K., Milenov, K., Hammer, K., Rössler, W., Sann, H., Pierau, Fr -K., Nguyen-Duong, H., Schneider, P., Stahl, F., Lepple-Wienhues, A., Korbmacher, C., Haller, H., Gebauer, M., Willner, U., Bialojan, C., Lengsfeld, M., Kyrtatas, V., Dartsch, Peter C., Boels, P. J., Fischer, W., Lenz, T., Thei\, U., Kreye, V. A. W., Ohkubo, T., Kupp, H., Vonderlage, M., Schreiner, V., Dorlöchter, M., Brinkers, M., Irintchev, A., Wernig, A., Langenfeld, B., Finger, W., Wolburg, H., Beer, A., Schwejda, Ch., Scheller, D., Heister, U., Tegtmeier, F., Knöpfel, Thomas, Spuler, Andreas, Grafe, Peter, GÄhwiler, Beat, Bijak, M., Misgeld, U., Müller, W., Rausche, G., Leweke, F M., Bingmann, D., Moraidis, I., Speckmann, E. -J., Madeja, M., Mu\hoff, U., Lehmenkühler, A, Kuhlmann, D., Hans, M., Lux, H. D., StrÄub, H., Waiden, J., Baker, R. E., Grantyn, R., Perouansky, M., Kraszewski, K, Lehmenkühler, Chr, Dodt, H. U., ZieglgÄnsberger, W., Pawelzik, H., ZieglgÄngsberger, W., Mann, K., Wiethölter, H., Albrecht, D., Dreier, J., Ficker, E., Beck, H., Corrette, B J., Dreyer, F., Repp, H., Dreessen, J., Augustine, G. J., Lehmenkühler, A., Büsselberg, D., Heimrich, B., Haas, H. L., Birnstiel, S., Haas, H. L., Schönrock, B., Altrup, U., Reith, H., Speckmann, E. -J., Alzheimer, C., Bruagencate, G. ten, Fruhstorfer, B., Mignot, E., Nishino, S., Dement, W. C., Guilleminault, C., Simon-Oppermann, Christa, Günther, Olaf, Stehle, J., Reuss, S., Seidel, A., Riemann, R., Vollrath, L., Reimer, Susanne, HölIt, Volker, Sonnhof, U., Krupp, J., Claus, H, Hinckel, P., Dick, H. B. H., Hiemke, C., Jussofie, A., Dorn, T., Uhlig, S., Witte, O. W., Bother, B., Eiselt, M., Witte, H., Zwiener, ö, Rother, M, Eiseit, H., Taghavy, A., KrÄtzer, A., Clusmann, H., Heinemann, U., Block, F., Sonatg, K. -H., Falkeristein, M., Hohnsbein, J., Hoormann, J., Frieling, A., Tarkka, I. M., Kullmann, W., Bromm, B., Hirsch, M. Chr, Wissing, H., Braun, H. A., Igelmund, P., Klu\mann, F. W., Ehrenstein, W. H., Yakimoff, N., Mateeff, S., Zeise, M. L., Arriagada, J., Teschemacher, A., ZieglgÄnsberger, W., Pöppelmann, T., Köhling, R., Boerrigter, P., Reith, H., Anders, K., Ohndorf, W., Dermietzel, R., Richter, D. W., Tölle, T. R., Castro-Lopes, J. M., Neuropharmakologie, Klinische, Sandkühler, J., Leah, J. D., Herdegen, T., Zimmermann, M., Vaitl, D., Gnippe, H., Herbert, M. K., Mengel, M. K. C., Kniffki, K. -D., Linke, R., Vahle-Hinz, C., Schenda, J., Matsumura, K., Herdegen, T., fu, Q. -G., Forster, C., Hutchison, W. D., Morton, C. R., Aschoff, J., Wilhelm, Z., Schwarzacher, S. W., Wasserschaff, M, Hörner, M., Kümmel, H., Windhorst, U., Feldman, J. L., Schmid, K., Foutz, A. S., Denavit-Saubié, M., Pak, M. A., Wehling, P., Evans, C., Bandara, G., Awiszus, F., Feistner, H., Heinze, H. -J., Illert, M., Wasserschaff, M., Kleinebeckel, D., Böhmer, G., Schauer, W., Abel, H. -H., Klü\endorf, D., Koepchen, H. P., Jarolimek, W, König, St, Czachurski, J., Seller, H., Meckler, R. L., McLachlan, E. M., Boczek-Funcke, A., HÄbler, H. -J., JÄnig, W., Michaelis, M., Dembowsky, K., Königr, S., Rau, Harald, HÄbler, H. -J., Unger, M., Merker, G., Roth, J., Zeisberger, E., Gao, H., Hunold, M., Kirchner, F., Takano, K., Schulze, K., Pokorski, M., Sakakibara, Y., Masuda, A., Morikawa, T., Ahn, B., Takaishi, S., Paulev, P. -E., Honda, Y., Flügge, G., Fuchs, E., König, S., Eysel, U. Th., Schmidt-Kastner, R., Skrandies, W., Geib, T., Baumann, C., Schmidt, K. -F., Knapp, A. G., Dowling, J. E., Kuba, M., Toyonaga, N., Kubová, Z., Ehrenstein, W. H., Jacobi, P., Schmidt, K. -F., Nöll, G. N., Baumann, Ch., Tabata, M., Martin, Ch., Meissl, H., Knottenberg, Th., Scheibner, H., Zenner, Hans P., Zimmennann, Ulrike, Gitter, Alfred H., Ding, D., Smolders, J. W. T., Klinke, R., Boekhoff, I., Raming, K., Krieger, J., Tareilus, E., Strotinann, J., Breer, H., Schild, D., DeSimone, J. A., Hellwig, S., Gitter, A. H., Plinkert, P. K., Zenner, H. P., Koltzenbwg, M., Pinter, E., SchÄfer, K., Braun, H. A., Necker, R., Hanesch, U., Heppelmann, B., Schmidt, R. F., Mense, S., Hoheisel, U., Steen, K. H., Anton, F., Reek, P. W., Handwerker, H. O., Lewin, G. R., McMahon, S. B., Heyer, G., Hornstein, O. P., Klement, W., Arndt, J. O., Maeerl, W., GrÄmer, G., Schepelmann, K., Me\linger, K., Schaible, H. -G., Treede, R. D., Meyer, R. A., Campbell, J. N., Claus, D., Neundörfer, B., Ernst, R., Tick-Waider, A. M., Bretschneider, F., Peters, R. C., Tennis, P. F. M., Teunis, P. F. M., Hoheisel, D., Scherotzke, R., Bub, A., Manzl, G., Forssmann, W. G., Jessen, C., Nuesslein, B., Schmidt, I., Wetzig, J., Reiser, M., Bregenzer, N., von Baumgarten, R. J., Mohr, E., Krzywanek, H., Warncke, G., Schuchmann, K. -L., Linow, H., Klu\mann, F. H., Redlin, U., Heldmaier, G., Bamler, A, Koller, A., Felber, S., Haid, C., Wicke, K., Raas, E., Xuemin, Wang, Kerning, Chen, Ying, Shi, Hanping, Shi, Warncke, Günther, Voisord, R., Dortsch, P. C., Betz, E., Karbach, U., Walenta, S., Gross, M. W., Mueller-Klieser, W., Vaupel, P., Okunieff, P., Mayer, W. -K., Stohrer, M., Krüger, W., Müller-Klieser, W., Strupp, M., Weial, P., Bostock, H., Piwernetz, K., Renner, R., Grafe, P., Lankers, J., Zangemeister, W., Kunze, K., Tries, S., Heinle, H., Beckerath, N. V., Maier-Rudolph, W., Mehrke, G., Günther, K., Goedel-Meinen, L., Daut, J., Piper, H. M., Kopp, A., Noll, T., Goellner, A., Gerlach, S., Teutsch, H. F., Schienger, K., Schwab, R., Höckel, M., Fotev, Z., Nienhaus, M., Kaczmarczyk, Gabriele, Richter, Dinah, Korte, Gabriele, Förther, J., Reinhardt, H. W., Schreiber, R., Rupp, J., Murphy, G., Fingerle, J., Kloiber, O., Miyazawa, T., Höhn-Berlage, M., Hossmann, K. -A., Schad, H., Heimisch, W., Blasini, R., Haas, F., Mendier, M., Spuler, A., Lehmann-Hom, F., Wolfram, U., Fenske, M., Sachser, N., Weis, Ch., Marktl, W., Kopta, B., Klammer, N., Rudas, B., Pohl, H., Nienartowicz, A., Moll, W., Klempt, M., Blum, S., Bühler, H., Lichtenstein, I., Novak, A., Siebe, H., Hierholzer, K., and Peper, K.

Published
1990
Full Text
View/download PDF

11. Calcium channel block by cadmium in chicken sensory neurons.

Author

Swandulla, D and Armstrong, C M

Abstract

Cadmium block of calcium channels was studied in chicken dorsal root ganglion cells by a whole-cell patch clamp that provides high time resolution. Barium ion was the current carrier, and the channel type studied had a high threshold of activation and fast deactivation (type FD). Block of these channels by 20 microM external Cd2+ is voltage dependent. Cd2+ ions can be cleared from blocked channels by stepping the membrane voltage (Vm) to a negative value. Clearing the channels is progressively faster and more complete as Vm is made more negative. Once cleared of Cd2+, the channels conduct transiently on reopening but reequilibrate with Cd2+ and become blocked within a few milliseconds. Cd2+ equilibrates much more slowly with closed channels, but at a holding potential of -80 mV virtually all channels are blocked at equilibrium. Cd2+ does not slow closing of the channels, as would be expected if it were necessary for Cd2+ to leave the channels before closing occurred. Instead, the data show unambiguously that the channel gate can close when the channel is Cd2+ occupied.

Published
1989
Full Text
View/download PDF

12. Single Ca-activated cation channels in bursting neurons ofHelix

Author

Partridge, L. D. and Swandulla, D.

Abstract

The depolarizing drive that maintains bursting inHelix neurons is carried by a long-lasting calcium-activated inward current. This current was studied using cell-attached and inside-out patches from the right parietal fast burster neuron ofHelix pomatia.

Published
1987
Full Text
View/download PDF

13. Activation of Ca2+ signaling in neutrophils by the mast cell-released immunophilin FKBP12.

Author

Bang, H, Müller, W, Hans, M, Brune, K, and Swandulla, D

Abstract

The immunophilins of the FK506-binding protein (FKBP) family are intracellular proteins that bind the immunosuppresants FK506 and rapamycin. In this study we show that HMC-1 mast cells sensitized with IgE release FKBP12 upon stimulation with anti-IgE. The release is rapid and not affected by actinomycin D or cycloheximide, suggesting that it is due to exocytosis from a storage compartment. FKBP12 from HMC-1 mast cells exhibits biological activity. When applied extracellularly to human neutrophils, it induces transient changes in the intracellular Ca2+ concentration ([Ca2+]i) due to Ca2+ release from intracellular stores. Inhibition of [Ca2+]i changes by ruthenium red and ryanodine indicates that ryanodine receptor/Ca2+ release channels are involved in FKBP12-induced Ca2+ signaling. Neutrophil activation by mast cell-derived FKBP12 is prevented by complexing FKBP12 with FK506 or rapamycin. These results demonstrate that extracellular FKBP12 functions as a cytokine in cell-to-cell communication. They further suggest a pathophysiological role for FKBP12 as a mediator in immediate or type I hypersensitivity and may have implications for novel therapeutic strategies in the treatment of allergic disorders with FK506 and rapamycin.

Published
1995
Full Text
View/download PDF

14. Synaptic feedback excitation has hypothalamic neural networks generate quasirhythmic burst activity.

Author

Müller, W and Swandulla, D

Abstract

1. Dissociated neurons from embryonic rat hypothalamus form synaptically coupled networks when cultured for several weeks. When synaptic inhibition is suppressed by the gamma-aminobutyric acid-A (GABAA) antagonist picrotoxin, neurons exhibit "rhythmic" burst activity that is blocked by the glutamate receptor antagonist 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX). 2. We have examined whether this type of activity is generated by pacemaker cells driving follower cells synaptically or whether it is generated by a neuronal network through feedback excitation by Ca2+ imaging of Fura-2/AM-loaded neurons and single-cell recording. 3. IN the presence of the GABAA antagonist picrotoxin (20 microM), a large majority of neurons (> 85%) displayed quasirhythmic increases in intracellular concentration of Ca2+ ([Ca2+]i). Single-cell recording revealed that these increases in [Ca2+]i correspond to burst discharges in individual neurons. When excitatory synaptic transmission was blocked by CNQX (20 microM), none of the imaged neurons exhibited significant oscillations in [Ca2+]i. 4. Investigation of the intervals between bursts from single-cell recording revealed a random distribution over a range of 400% from the minimum interval. Poincaré maps of burst intervals, i.e., graphs of all burst intervals versus their preceding burst interval, revealed that a burst interval is unpredictable from its predecessor. 5. When synaptic coupling was attenuated by low concentrations of CNQX (50-500 nM), the mean burst interval was considerably increased without a change in the random character of burst activity. 4-Aminopyridine (1 mM), known to increase synaptic efficiency, reduced the mean burst interval.(ABSTRACT TRUNCATED AT 250 WORDS)

Published
1995

15. Ca2+ permeability of the sustained proton-induced cation current in adult rat dorsal root ganglion neurons.

Author

Zeilhofer, H U, Swandulla, D, Reeh, P W, and Kress, M

Abstract

1. Microfluorometric Ca2+ measurements using FURA-2 and whole cell patch-clamp recordings were performed to investigate the Ca2+ permeability of ion channels underlying the proton-induced sustained cation current in adult rat dorsal root ganglion neurons. 2. In a subpopulation of these neurons, extracellular application of acidic solutions (pH 5.1) elicited a sustained cation current and a concomitant reversible rise in the intracellular free Ca2+ concentration ([Ca2+]i), which depended on the presence of external Ca2+. Ruthenium red (10 microM) reduced both the current and the rise in [Ca2+]i to about the same extent. 3. In the presence of 2 mM external Ca2+, sustained proton-induced currents reversed sign at -4.6 +/- 1.2 (SE) mV, with external Na+ and internal Cs+ as the major charge carriers. Increasing the external Ca2+ concentration to 30 mM shifted the reversal potential (Erev) by 3.0 +/- 0.9 mV toward more positive values, suggesting a permeability ratio of Ca2+/Cs+ of 0.41. A similar value (0.35) could be obtained from Erev (-21 mV) under bi-ionic conditions with 100 mM external Ca2+ and 154 mM internal Cs+. 4. These results demonstrate that the proton-activated cation channels investigated here are moderately permeable to Ca2+. This may lead to pathophysiologically relevant increases in [Ca2+]i on prolonged exposure of the cells to an acidic environment in inflamed or ischemic tissue.

Published
1996

16. Modulation of calcium‐activated non‐specific cation currents by cyclic AMP‐dependent phosphorylation in neurones of Helix.

Author

Partridge, L D, Swandulla, D, and Müller, T H

Abstract

1. Currents through calcium‐activated non‐specific cation (CAN) channels were studied in the fast burster neurone of Helix aspersa and Helix pomatia. CAN currents were activated by reproducible intracellular injections of small quantities of Ca2+ utilizing a fast, quantitative pressure injection technique. 2. External application of forskolin (10‐25 microM), an activator of adenylate cyclase, caused the endogenous bursting activity of the cells to be replaced by beating activity. These same concentrations of forskolin reduced CAN currents reversibly to about 50%. 3. External application of IBMX (3‐isobutyl‐1‐methylxanthine, 100 microM), an inhibitor of phosphodiesterase, the enzyme which breaks down cyclic AMP, reduced CAN currents reversibly to about 40%. 4. External application of the membrane‐permeable cyclic AMP analogues 8‐bromo‐cyclic AMP and dibutyryl‐cyclic AMP (100 microM) caused almost complete block of the CAN current. A marked reduction in the CAN current was also observed following quantitative injections of cyclic AMP (internal concentrations up to 50 microM) directly into the cells from a second pressure injection pipette. 5. Similar results were obtained with quantitative injections of the catalytic subunit (C‐subunit) of the cyclic AMP‐dependent protein kinase (internal concentrations 10(‐4) units of enzyme) directly into the cells from a second pressure injection pipette. 6. Injection of the non‐hydrolysable GTP analogue, GTP‐gamma‐S (internal concentrations 100 microM), which stimulates G‐proteins, produced a prolonged increase in CAN current amplitude by as much as 300%. 7. External application of serotonin (100‐200 microM) caused a transition from bursting to beating activity of the neurones and mimicked cyclic AMP's effects on CAN currents. Two other neurotransmitters, dopamine and acetylcholine, were not significantly effective in reducing CAN currents. 8. Injection of a peptide inhibitor of cyclic AMP‐dependent protein kinase suppressed serotonin's action on bursting and on CAN current. 9. Our results indicate that CAN currents in Helix burster neurones are modulated by cyclic AMP‐dependent membrane phosphorylation. They suggest that the physiological transmitter that induces this second messenger action is serotonin. The dual control of CAN channels by two second messengers, namely Ca2+ and cyclic AMP, has important functional implications. While Ca2+ activates these channels which generate the pacemaker current in these neurones, cyclic AMP‐dependent phosphorylation down‐regulates them, thereby resulting in modulation of neuronal bursting activity.

Published
1990
Full Text
View/download PDF

17. Synaptic Connectivity in Cultured Hypothalamic Neuronal Networks

Author

Müller, Thomas H., Swandulla, D., and Zeilhofer, H. U.

Abstract

Müller, Thomas H., D. Swandulla, and H. U. Zeilhofer.Synaptic connectivity in cultured hypothalamic neuronal networks. J. Neurophysiol.77: 3218–3225, 1997. We have developed a novel approach to analyze the synaptic connectivity of spontaneously active networks of hypothalamic neurons in culture. Synaptic connections were identified by recording simultaneously from pairs of neurons using the whole cell configuration of the patch-clamp technique and testing for evoked postsynaptic current responses to electrical stimulation of one of the neurons. Excitatory and inhibitory responses were distinguished on the basis of their voltage and time dependence. The distribution of latencies between presynaptic stimulation and postsynaptic response showed multiple peaks at regular intervals, suggesting that responses via both monosynaptic and polysynaptic paths were recorded. The probability that an excitatory event is transmitted to another excitatory neuron and results in an above-threshold stimulation was found to be only one in three to four. This low value indicates that in addition to evoked synaptic responses other sources of excitatory drive must contribute to the spontaneous activity observed in these networks. The various types of synaptic connections (excitatory and inhibitory, monosynaptic, and polysynaptic) were counted, and the observations analyzed using a probabilistic model of the network structure. This analysis provides estimates for the ratio of inhibitory to excitatory neurons in the network (1:1.5) and for the ratio of postsynaptic cells receiving input from a single GABAergic or glutamatergic neuron (3:1). The total number of inhibitory synaptic connections was twice that of excitatory connections. Cell pairs mutually connected by an excitatory and an inhibitory synapse occurred significantly more often than predicted by a random process. These results suggests that the formation of neuronal networks in vitro is controlled by cellular mechanisms that favor inhibitory connections in general and specifically enhance the formation of reciprocal connections between pairs of excitatory and inhibitory neurons. These mechanisms may contribute to network formation and function in vivo.

Published
1997
Full Text
View/download PDF

18. Activation of three types of membrane currents by various divalent cations in identified molluscan pacemaker neurons.

Author

Müller, T H, Swandulla, D, and Lux, H D

Abstract

We investigated membrane currents activated by intracellular divalent cations in two types of molluscan pacemaker neurons. A fast and quantitative pressure injection technique was used to apply Ca2+ and other divalent cations. Ca2+ was most effective in activating a nonspecific cation current and two types of K+ currents found in these cells. One type of outward current was quickly activated following injections with increasing effectiveness for divalent cations of ionic radii that were closer to the radius of Ca2+ (Ca2+ greater than Cd2+ greater than Hg2+ greater than Mn2+ greater than Zn2+ greater than Co2+ greater than Ni2+ greater than Pb2+ greater than Sr2+ greater than Mg2+ greater than Ba2+). The other type of outward current was activated with a delay by Ca2+ greater than Sr2+ greater than Hg2+ greater than Pb2+. Mg2+, Ba2+, Zn2+, Cd2+, Mn2+, Co2+, and Ni2+ were ineffective in concentrations up to 5 mM. Comparison with properties of Ca2(+)-sensitive proteins related to the binding of divalent cations suggests that a Ca2(+)-binding protein of the calmodulin/troponin C type is involved in Ca2(+)-dependent activation of the fast-activated type of K+ current. Th sequence obtained for the slowly activated type is compatible with the effectiveness of different divalent cations in activating protein kinase C. The nonspecific cation current was activated by Ca2+ greater than Hg2+ greater than Ba2+ greater than Pb2+ greater than Sr2+, a sequence unlike sequences for known Ca2(+)-binding proteins.

Published
1989
Full Text
View/download PDF

19. Fast-deactivating calcium channels in chick sensory neurons.

Author

Swandulla, D and Armstrong, C M

Abstract

Whole-cell Ca and Ba currents were studied in chick dorsal root ganglion (DRG) cells kept 6-10 in culture. Voltage steps with a 15-microseconds rise time were imposed on the membrane using an improved patch-clamp circuit. Changes in membrane current could be measured 30 microseconds after the initiation of the test pulse. Currents through Ca channels were recorded under conditions that eliminate Na and K currents. Tail currents, associated with Ca channel closing, decayed in two distinct phases that were very well fitted by the sum of two exponentials. The time constants tau f and tau s were near 160 microseconds and 1.5 ms at -80 mV, 20 degrees C. The tail current components, called FD and SD (fast-deactivating and slowly deactivating), are Ca channel currents. They were greatly reduced when Mg2+ replaced all other divalent cations in the bath. The SD component inactivated almost completely as the test pulse duration was increased to 100 ms. It was suppressed when the cell was held at membrane potentials positive to -50 mV and was blocked by 100-200 microM Ni2+. This behavior indicates that the SD component was due to the closing of the low-voltage-activated (LVA) Ca channels previously described in this preparation. The FD component was fully activated with 10-ms test pulses to +20 mV at 20 degrees C, and inactivated to approximately 30% during 500-ms test pulses. It was reduced in amplitude by holding at -40 mV, but was only slightly reduced by micromolar concentrations of Ni2+. Replacement of Ca2+ with Ba2+ increased the FD tail current amplitudes by a factor of approximately 1.5. The deactivation kinetics did not change (a) as channels inactivated during progressively longer pulses or (b) when the degree of activation was varied. Further, tau f was affected neither by changing the holding potential nor by varying the test pulse amplitude. Lowering the temperature from 20 to 10 degrees C decreased tau f by a factor of 2.5. In all cases, the FD component was very well fitted by a single exponential. There was no indication of an additional tail component of significant size. Our findings indicate that the FD component is due to closing of a single class of Ca channels that coexist with the LVA Ca channel type in chick DRG neurons.

Published
1988
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results