Abstract
Leech blood apparently contains considerably less chloride than generally used in physiological experi ments. Instead of 85–130 mM Cl− used in experimental salines, leech blood contains around 40 mM Cl− and up to 45 mM organic anions, in particular malate. We have reinvestigated the distribution of Cl− across the cell membrane of identified glial cells and neurones in the central nervous system of the leech Hirudo medicinalis L., using double-barrelled Cl−- and pH-selective micro electrodes, in a conventional leech saline, and in a saline with a low Cl− concentration (40 mM), containing 40 mM malate. The interference of anions other than Cl−to the response of the ion-selective microelectrodes was estimated in Cl−-free salines (Cl− replaced by malate and/or gluconate). The results show that the absolute intracellu lar Cl− activities (aCli) in glial cells and neurones, but not the electrochemical gradients of Cl− across the glial and the neuronal cell membranes, are altered in the low Cl−, malate-based saline. In Retzius neurones, aCli is lower than expected from electrochemical equilibrium, while in pressure neurones and in neuropil glial cells, aCli is distributed close to its equilibrium in both salines, re spectively. The steady-state intracellular pH values in the glial cells and Retzius neurones are little affected (≤0.1 pH units) in the low Cl−, malate-based saline.
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References
Angstadt JD, Friesen O (1991) Synchronized oscillatory activity in leech neurons induced by calcium channel blockers. J Neurophysiol 66: 1858–1873
Ballanyi K, Schlue WR (1990) Intracellular chloride activity in glial cells of the leech central nervous system. J Physiol (Lond) 420: 325–336
Ballanyi K, Grafe P, ten Bruggencate G (1987) Ion activities and potassium uptake mechanisms of glial cells in guinea-pig olfactory cortex slices. J Physiol (Lond) 382: 159–174
Boroffka I (1968) Osmo- und Volumenregulation bei Hirudo medicinalis. Z Vergl Physiol 57: 348–375
Borrelli MJ, Carlini WG, Dewey WC, Ransom BR (1985) A simple method for making ion-selective microelectrodes suitable for intracellular recording in vertebrate cells. J Neurosci Meth 15: 141–154
Cline HT (1986) Physiological evidence for GABA as a neurotransmitter in the leech. J Neurosci 6: 2848–2856
Coles JA, Orkand RK, Yamate CL (1989) Chloride enters glial cells and photoreceptors in response to light stimulation in the retina of the honey bee drone. Glia 2: 287–297
Dean JA, Leake LD (1988) Pharmacological control of the pattern of activity in leech Retzius neurones. Comp Biochem Physiol 89C: 31–38
Deitmer JW (1991) Electrogenic sodium-dependent bicarbonate secretion by glial cells of the leech central nervous system. J Gen Physiol 98: 637–655
Deitmer JW (1992) Evidence for glial control of extracellular pH in the leech central nervous system. Glia 5: 43–47
Deitmer JW, Schlue WR (1981) Measurements of the intracellular potassium activity of Retzius cells in the leech central nervous system. J Exp Biol 91: 87–101
Deitmer JW, Schlue WR (1989) An inwardly directed electrogenic sodium-bicarbonate co-transport in leech glial cells. J Physiol (Lond) 411: 179–194
Dixon WJ, Massey FJ (1969) Introduction to statistical analysis. 3rd ed. McGraw Hill, New York
Drapeau P, Sanchez-Armass S (1988) Selection of postsynaptic serotonin receptors during reinnervation of an identified leech neuron in culture. J Neurosci 8: 4718–4727
Frey G, Schlue WR (1993) pH recovery from intracellular alkalinization in Retzius neurones of the leech central nervous system. J Physiol (Lond) 462: 627–643
Hertz L, Yu ACH, Schousboe A (1992a) Uptake and metabolism of malate in neurons and astrocytes in primary cultures. J Neurosci Res 33: 289–296
Hertz L, Code WE, Sykova E (1992b) Ions, water and energy in brain cells: a synapsis of interrelations. Com J Physiol Pharmacol 70: S100-S106
Hoeger U, Wenning A, Greisinger U (1989) Ion homeostasis in the leech: contribution of organic anions. J Exp Biol 147: 43–51
Hoppe D, Kettenmann H (1988) Carrier-mediated Cl− transport in cultured mouse oligodendrocytes. J Neurosci Res 23: 467–475
Inagaki C, Hara M, Inoue M. (1992) Neuronal intracellular chloride ion concentrations and their regulatory mechanisms. Folia Pharmacol Japan 99: 307–315
Kaila K, Panula P, Karhunen T, Heinonen E (1991) Fall in intracellular pH mediated by GABAA receptors in cultured rat astrocytes. Neurosci Lett 126: 9–12
Kenyon JL, Gibbons WR (1977) Effects of low-chloride solutions on action potentials of sheep cardiac Purkinje fibres. J Gen Physiol 70: 635–660
Kimelberg HK, Biddlecome S, Bourke RS (1979) SITS-inhibitable Cl− transport and Na+-dependent H+ production in primary astroglial cultures. Brain Res 173: 111–124
Munsch T, Deitmer JW (1990a) Intracellular Cl− activities in neurones and glial cells of the leech central nervous system after partial Cl− substitution. Pflügers Arch 415: R29
Munsch T, Deitmer JW (1990b) The distribution of Cl− and H+ in the central nervous system of the leech Hirudo medicinalis in a new isotonic saline. Verh Dtsch Zool Ges 83: 638
Munsch T, Schlue WR (1993) Intracellular chloride activity and the effect of 5-hydroxytryptamine on the chloride conductance of leech Retzius neurons. Europ J Neurosci 5: 1551–1557
Nicholls JG, Kuffler SW (1964) Extracellular space as a pathway for exchange between blood and neurons in the central nervous system of the leech: ionic composition of glial cells and neurons. J Neurophysiol 27: 645–671
Nicholls JG, Wallace BG (1978) Modulation of transmission at an inhibitory synapse in the central nervous system of the leech. J Physiol (Lond) 281: 157–170
Sanchez-Armass S, Merz DC, Drapeau P (1991) Distinct receptors, second messengers and conductances underlying the dual response to serotonin in an identified leech neurone. J Exp Biol 155: 531–547
Schmidt J, Calabrese RL (1992) Evidence that acetylcholine is an inhibitory transmitter of heart interneurons in the leech. J Exp Biol 171: 329–347
Szatkowski MS (1989) The effect of extracellular weak acids and bases on the intracellular buffering power of snail neurones. J Physiol (Lond) 409: 103–120
Thomas RC, Coles JA, Deitmer JW (1991) Homeostatic muffling. Nature 350: 564
Vaughan-Jones RD (1979) Regulation of chloride in quiescent sheep heart Purkinje fibres studied using intracellular chloride and pH-sensitive micro-electrodes. J Physiol (Lond) 295: 111–137
Walker RJ, Smith PA (1973) The ionic mechanism for 5-hydroxytryptamine inhibition on Retzius cells of the leech Hirudo medicinalis. Comp Biochem Physiol 45A: 979–993
Wenning A (1989) Properties of a set of internal receptors in the medicinal leech: the nephridial nerve cells monitor extracellular chloride concentration. J Exp Biol 143: 115–132
Wenning A, Calabrese RL (1991) Mechanism of Cl− sensitivity in internal ion receptors of the leech: an inward current gated off by Cl− in the nephridial nerve cells. J Comp Physiol A 168: 53–61
Wuttke WA (1990) Mechanism of potassium uptake in neuropil glial cells in the nervous system of the leech. J Neurophysiol 63: 1089–1097
Zebe E, Salge U, Wiemann C, Wilps H (1981) The energy metabolism of the leech Hirudo medicinalis in anoxia and muscular work. J Exp Zool 218: 157–163
Zerbst-Boroffka I (1970) Organische Säurereste als wichtigste Anionen im Blut von Hirudo medicinalis. Z Vergl Physiol 70: 313–321
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Munsch, T., Reusch, M. & Deitmer, J.W. Intracellular chloride activity of leech neurones and glial cells in physiological, low chloride saline. J Comp Physiol A 176, 273–280 (1995). https://doi.org/10.1007/BF00239929
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DOI: https://doi.org/10.1007/BF00239929