Summary
The effects of brief trains of electrical stimuli applied within the locus coeruleus and subcoeruleus, the Kölliker-Fuse nucleus and the raphe magnus, obscurus and pallidus nuclei were tested on transmission from group I and group II muscle afferent fibres in mid-lumbar spinal segments of chloralose anaesthetized cats. Changes in the effectiveness of transmission from these afferents were assessed from changes in the size of monosynaptic extracellular field potentials evoked by them. The depression of group II field potentials occurred at conditioning-testing intervals of 20–400 ms, and was maximal at intervals of 40–100 ms and 30–60 ms for potentials recorded in the intermediate zone and dorsal horn, respectively. At intervals up to about 30 ms it was combined with the depression of group I components of the intermediate zone field potentials. However, at longer intervals the conditioning stimuli depressed group II components of these potentials as selectively as monoamines applied ionophoretically at the recording site (Bras et al., 1989a, 1990). Thus, only the late depressive actions are considered as being possibly mediated by impulses in descending noradrenergic and/or serotonergic fibres. No major differences were found in the relative degree of depression of transmission from group II afferents by stimulation of the locus coeruleus/subcoeruleus, Kölliker-Fuse or raphe nuclei, either in the dorsal horn or in the intermediate zone. Since field potentials at these locations are preferentially depressed by ionophoretic application of serotonin and noradrenaline (Bras et al., 1990), and since the locus coeruleus/subcoeruleus, Kölliker-Fuse and raphe nuclei are interconnected, the study leads to the conclusion that both noradrenergic and serotonergic descending pathways can be activated by stimuli applied within either of them. Selective depression of field potentials of group II origin was also evoked by stimulation at other sites, e.g. the periaqueductal grey and medullary reticular formation, when conditioning-testing intervals were sufficiently long. Such a depression is considered to be secondary to activation of neurones of the locus coeruleus/subcoeruleus, Kölliker-Fuse or raphe nuclei and attributed to the spread of current or transsynaptic activation of these neurones, or to stimulation of their axon collaterals outside the nuclei rather than to other descending medullo-spinal systems. The non-selective depression of field potentials evoked by group I and group II afferents at shorter conditioning-testing intervals is proposed to be due to actions of reticulo-spinal pathways.
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References
Berman AL (1968) The brain stem of the cat. University of Wisconsin Press, Madison, WI
Bobillier P, Seguin S, Petitjean F, Salvert D, Touret M, Jouvet M (1976) The raphe nuclei of the cat brain stem: a topographical atlas of their efferent projections as revealed by autoradiography. Brain Res 113: 449–486
Bowker RM, Westlund KN, Coulter JD (1981) Serotonergic projections to the spinal cord from the midbrain in the rat: an immunocytochemical and retrograde transport study. Neurosci Lett 24: 221–226
Bras H, Cavallari P, Jankowska E, McCrea D (1989a) Comparison of effects of monoamines on transmission in spinal pathways from group I and II muscle afferents in the cat. Exp Brain Res 76: 27–37
Bras H, Jankowska E, Noga BR (1989b) Depression of transmission from group II muscle afferents to spinal interneurones by descending monoaminergic pathways. Eur J Neurosci Suppl 2: 187
Bras H, Jankowska E, Noga BR, Skoog B (1990) Comparison of effects of various types of NA and 5-HT agonists on transmission from group II muscle afferents in the cat. Eur J Neurosci 2: 1029–1039
Carpenter D, Lundberg A, Norrsell U (1963b) Primary afferent depolarization evoked from the sensorimotor cortex. Acta Physiol Scand 59: 126–142
Cedarbaum JM, Aghajanian GK (1978) Afferent projections to the rat locus coeruleus as determined by a retrograde tracing technique. J Comp Neurol 178: 1–16
Chu N-S, Bloom FE (1974) Activity patterns of catecholamine-containing pontine neurons in the dorsolateral tegmentum of unrestrained cats. J Neurobiol 5: 527–544
Commissiong JW (1981) Evidence that the noradrenergic coeruleospinal projection decussates at the spinal level. Brain Res 212: 145–151
Curtis DR (1963) The pharmacology of central and peripheral inhibition. Pharmacol Rev 15: 333–364
Curtis DR (1976) The use of transmitter antagonists in micro-electrophoretic investigations of central synaptic transmission. In: Bradley PB and Dhawan BN (eds) Drugs and central synaptic transmission. The Macmillan Press, London, pp 7–36
Dahlström A, Fuxe K (1964) Evidence for the extent of monoamine-containing neurons in the central nervous system. I. Demonstration of monoamines in the cell bodies of brain stem neurons. Acta Physiol Scand Suppl 232: 1–55
Eccles JC, Schmidt RG, Willis WD (1963b) Depolarization of central terminals of group Ib afferent fibres of muscle. J Neurophysiol 26: 1–27
Edgley SA, Jankowska E (1987a) Field potentials generated by group I and II muscle afferents in the middle lumbar segments of the cat spinal cord. J Physiol (Lond) 385: 393–413
Edgley SA, Jankowska E (1987b) An interneuronal relay for group I and II muscle afferents in the midlumbar segments of the cat spinal cord. J Physiol (Lond) 389: 647–674
Edgley SA, Jankowska E, Shefchyk S (1988) Evidence that interneurones in reflex pathways from group II afferents are involved in locomotion in the cat. J Physiol (Lond) 403: 57–73
Edwards SB (1975) Autoradiographic studies of the projections of the midbrain reticular formation: descending projections of the nucleus cuneiformis. J Comp Neurol 161: 341–358
Ennis M, Aston-Jones G (1986) A potent excitatory input to the nucleus locus coeruleus from the ventrolateral medulla. Neurosci Lett 71: 299–305
Finlayson PG, Marshall KC (1988) Synchronous bursting of locus coeruleus neurons in tissue culture. Neuroscience 24: 217–225
Fritschy J-M, Lyons WE, Mullen CA, Kosofsky BE, Molliver ME, Grzanna R (1987) Distribution of locus coeruleus axons in the rat spinal cord: a combined anterograde transport and immunohistochemical study. Brain Res 437: 176–180
Fung SJ, Barnes CD (1987) Membrane excitability changes in hindlimb motoneurons induced by stimulation of the locus coeruleus in cats. Brain Res 402: 230–242
Gustafsson B, Jankowska E (1976) Direct and indirect activation of nerve cells by electrical pulses applied extracellularly. J Physiol (Lond) 258: 33–61
Guyenet PG (1980) The coeruleospinal noradrenergic neurons: anatomical and electrophysiological studies in the rat. Brain Res 189: 121–133
Hammond DL, Tyce GM, Yaksh TL (1985) Efflux of 5-hydroxytryptamine and noradrenaline into spinal cord superfusates during stimulation of the rat medulla. J Physiol (Lond) 359: 151–162
Harrison PJ, Jankowska E (1989) Primary afferent depolarization of central terminals of group II muscle afferents in the cat spinal cord. J Physiol (Lond) 411: 71–83
Kuypers HGJM, Maisky VA (1975) Retrograde axonal transport of horseradish peroxidase from spinal cord to brain spinal cord in the cat. Neurosci Lett 1: 9–14
Jordan LM (1986) Initiation of locomotion from the mammalian brainstem. In: Grillner S, Stein PSG, Stuart DG, Forssberg H, Herman RM (eds) Wenner-Gren Centre International Symposium Series, Vol 45. Neurobiology of vertebrate locomotion. MacMillan, London, pp 21–37
Jiménez I, Rudomin P, Solodkin M (1988) PAD patterns of physiologically identified afferent fibres from the medial gastrocnemius muscle. Exp Brain Res 74: 643–657
Lai Y-Y, Barnes CD (1985) A spinal projection of serotonergic neurons in the cat. Neurosci Lett 58: 159–164
Léger L, Wiklund L, Descarries L, Persson M (1979) Description of an indolaminergic cell component in the cat locus coeruleus: a fluorescence histochemical and radioautographic study. Brain Res 168: 43–56
Loughlin SE, Foote SL, Grzanna R (1986) Efferent projections of nucleus locus coeruleus: morphologic subpopulations have different efferent targets. Neuroscience 18: 307–319
Lundberg A (1981) Half-centres revisited. In: Szentágothai J, Palkovits M, Hámori J (eds) Motion and organization principles. Advances in the physiological sciences, Vol 1. Akadémiai Kiado, Budapest, pp 155–167
Martin RF, Cabana T, Ditirro FG, Ho RH, Humberston AO (1982) Raphespinal projections in the North American opossum: evidence for connectional heterogeneity. J Comp Neurol 208: 67–84
Martin RF, Jordan LM, Willis WD (1978) Differential projections of cat medullary raphe neurons demonstrated by retrograde labelling following spinal cord lesions. J Comp Neurol 182: 77–88
Mason P, Fields HL (1988) Axonal trajectories and terminations of physiologically characterized raphe magnus cells in the cat. Soc Neurosci Abstr 14: 174
Nakazato T (1987) Locus coeruleus neurons projecting to the forebrain and the spinal cord in the cat. Neuroscience 23: 529–538
Noga BR, Jankowska E, Skoog B (1991) Depression of transmission from group II muscle afferents by electrical stimulation of the cuneiform nucleus and subcuneiform region in the cat. Soc Neurosci Abstr 17: 1024
Olson L (1977) A new major projection from locus coeruleus: the main source of noradrenergic nerve terminals in the ventral and dorsal columns of the spinal cord. Brain Res 132: 85–93
Olson L, Fuxe K (1972) Further mapping out of central noradrenaline neuron systems: projections of the “subcoeruleus” area. Brain Res 43: 289–295
Proudfit HK, Anderson EG (1974) New long-latency bulbospinal evoked potentials blocked by serotonin antagonists. Brain Res 65: 542–546
Ruda MA, Gobel S (1980) Ultrastructural characterization of axonal endings in the substantia gelatinosa which take up (3H) serotonin. Brain Res 184: 57–83
Sakai K, Touret M, Salvert D, Léger L, Jouvet M (1977) Afferent projections to the cat locus coeruleus as visualized by the horseradish peroxidase technique. Brain Res 119: 21–41
Shah Y, Dostrovsky JO (1980) Electrophysiological evidence for a projection of the periaqueductal gray matter to the nucleus raphe magnus in cat and rat. Brain Res 193: 534–538
Shefchyk S, McCrea D, Kriellaars D, Fortier P, Jordan L (1990) Activity of interneurons within the L4 spinal segment of the cat during brainstem-evoked fictive locomotion. Exp Brain Res 80: 290–295
Skoog B, Noga BR (1991) Do noradrenergic descending tract fibres contribute to the depression of transmission from group II muscle afferents following brainstem stimulation in the cat? Neurosci Lett 134: 5–8
Sotnichenko TS (1985) Differentiation of efferent projections of the medial (cuneiform nucleus) and lateral regions of the reticular formation in cat midbrain. Neurophysiol 17: 466–471
Stevens RT, Hodge CJ, Apkarian AV (1982) Kölliker-Fuse nucleus: the principal source of pontine catecholaminergic cells projecting to the lumbar spinal cord of cat. Brain Res 239: 589–594
Tan J, Holstege G (1986) Anatomical evidence that the pontine lateral tegmental field projects to lamina I of the caudal spinal trigeminal nucleus and spinal cord and to the Edinger-Westphal nucleus in the cat. Neurosci Lett 64: 317–322
Tohyama M, Sakai K, Salvert D, Touret M, Jouvet M (1979) Spinal projections from the lower brain stem in the cat as demonstrated by the horseradish peroxidase technique. II. Projections from the dorsolateral pontine tegmentum and raphe nuclei. Brain Res 176: 215–231
Ugolini G, Kuypers HGJM, Strick PL (1989) Transneuronal transfer of Herpes Virus from peripheral nerves to cortex and brainstem. Science 243: 89–90
Van Dongen P (1980) The noradrenergic locus coeruleus. Behavioral effects of intracerebral injections, and a survey of its structure, function and pathology. Krips Repro BV, Meppel
Watabe K (1980) Mode of neuronal interaction in rat locus coeruleus. Arch Ital Biol 118: 303–329
Wessendorf MW, Proudfit HK, Anderson EG (1981) The identification of serotonergic neurons in the nucleus raphe magnus by conduction velocity. Brain Res 214: 168–173
West DC, Wolstencroft JH (1977) Location and conduction velocity of raphespinal neurones in nucleus raphe magnus and raphe pallidus in the cat. Neurosci Lett 5: 147–151
Wiklund L, Léger L, Persson M (1981) Monoamine cell distribution in the cat brain stem. A fluorescence histochemical study with quantification of indolaminergic and locus coeruleus cell groups. J Comp Neurol 203: 613–647
Willis WD (1984) The raphe-spinal system. In: Barnes CD (eds) Brainstem control of spinal cord function. Academic Press, London, pp 141–214
Zahs KS, Behbehani MM, Basbaum AI (1985) Immunoreactive serotonergic axons in the dorsolateral funiculus of the cat and rat. Soc Neurosci Abstr 11: 125
Zhao ZQ, Duggan AW (1988) Idazoxan blocks the action of noradrenaline but not spinal inhibition from electrical stimulation of the locus coeruleus and nucleus Kölliker-Fuse of the cat. Neuroscience 25: 997–1005
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Noga, B.R., Bras, H. & Jankowska, E. Transmission from group II muscle afferents is depressed by stimulation of locus coeruleus/subcoeruleus, Kölliker-Fuse and raphe nuclei in the cat. Exp Brain Res 88, 502–516 (1992). https://doi.org/10.1007/BF00228180
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DOI: https://doi.org/10.1007/BF00228180