Cerebrospinal fluid-contacting (CSF-c) cells are found in all vertebrates but their function has remained elusive. We recently identified one type of laterally projecting CSF-c cell in lamprey spinal cord with neuronal properties that expresses GABA and somatostatin. We show here that these CSF-c neurons respond to both mechanical stimulation and to lowered pH. These effects are most likely mediated by ASIC3-channels, since APETx2, a specific antagonist of ASIC3, blocks them both. Furthermore, lowering of pH as well as application of somatostatin will reduce the locomotor burst rate. The somatostatin receptor antagonist counteracts the effects of both a decrease in pH and of somatostatin. Lateral bending movement imposed on the spinal cord, as would occur during natural swimming, activates CSF-c neurons. Taken together, we show that CSF-c neurons act both as mechanoreceptors and as chemoreceptors through ASIC3 channels, and their action may protect against pH-changes resulting from excessive neuronal activity.
For survival of the organism, acid-base homeostasis is vital [1, 2]. The respiratory and renal systems are central to this control. Here we describe a novel mechanism, intrinsic to the spinal cord, with sensors that detect pH changes and act to restore pH to physiological levels by reducing motor activity. This pH sensor consists of somatostatin-expressing cerebrospinal fluid-contacting (CSF-c) neurons, which target the locomotor network. They have a low level of activity at pH 7.4. However, at both alkaline and acidic pH, the activity of the individual CSF-c neuron is markedly enhanced through the action of two separate channel subtypes. The alkaline response depends on PKD2L1 channels that have a large conductance and an equilibrium potential around 0 mV, both characteristics of mouse PKD2L1 channels [3-5]. The acidic response is due to an activation of ASIC3 [6]. The discharge pattern of the CSF-c neurons is U-shaped with a minimum frequency around pH 7.4 and a marked increase already at slightly lower and higher pH. During ongoing locomotor activity in the isolated spinal cord, both an increase and as a decrease of pH will reduce the locomotor burst rate. A somatostatin antagonist blocks these effects, suggesting that CSF-c neurons are responsible for the suppression of locomotor activity. CSF-c neurons thus represent a novel innate homeostatic mechanism, designed to sense any deviation from physiological pH and to respond by causing a depression of the motor activity. Because CSF-c neurons are found in all vertebrates, their pH-sensing function is most likely conserved.
CSF-contacting (CSF-c) cells are present in the walls of the brain ventricles and the central canal of the spinal cord and found throughout the vertebrate phylum. We recently identified ciliated somatostatin-/GABA-expressing CSF-c neurons in the lamprey spinal cord that act as pH sensors as well as mechanoreceptors. In the same neuron, acidic and alkaline responses are mediated through ASIC3-like and PKD2L1 channels, respectively. Here, we investigate the functional properties of the ciliated somatostatin-/GABA-positive CSF-c neurons in the hypothalamus by performing whole-cell recordings in hypothalamic slices. Depolarizing current pulses readily evoked action potentials, but hypothalamic CSF-c neurons had no or a very low level of spontaneous activity at pH 7.4. They responded, however, with membrane potential depolarization and trains of action potentials to small deviations in pH in both the acidic and alkaline direction. Like in spinal CSF-c neurons, the acidic response in hypothalamic cells is mediated via ASIC3-like channels. In contrast, the alkaline response appears to depend on connexin hemichannels, not on PKD2L1 channels. We also show that hypothalamic CSF-c neurons respond to mechanical stimulation induced by fluid movements along the wall of the third ventricle, a response mediated via ASIC3-like channels. The hypothalamic CSF-c neurons extend their processes dorsally, ventrally, and laterally, but as yet, the effects exerted on hypothalamic circuits are unknown. With similar neurons being present in rodents, the pH- and mechanosensing ability of hypothalamic CSF-c neurons is most likely conserved throughout vertebrate phylogeny. CSF-contacting neurons are present in all vertebrates and are located mainly in the hypothalamic area and the spinal cord. Here, we report that the somatostatin-/GABA-expressing CSF-c neurons in the lamprey hypothalamus sense bidirectional deviations in the extracellular pH and do so via different molecular mechanisms. They also serve as mechanoreceptors. The hypothalamic CSF-c neurons have extensive axonal ramifications and may decrease the level of motor activity via release of somatostatin. In conclusion, hypothalamic somatostatin-/GABA-expressing CSF-c neurons, as well as their spinal counterpart, represent a novel homeostatic mechanism designed to sense any deviation from physiological pH and thus constitute a feedback regulatory system intrinsic to the CNS, possibly serving a protective role from damage caused by changes in pH.
Cerebrospinal fluid-contacting (CSF-c) cells are found in all vertebrates, but their function remains elusive. In the lamprey spinal cord, they surround the central canal and some have processes passing the gray matter to the lateral edge of the flattened spinal cord. Stimulation of CSF-c cells at the central canal elicits GABAergic inhibitory postsynaptic potentials (IPSPs) in intraspinal stretch receptor neurons (edge cells). Here, we characterize laterally projecting CSF-c cells according to their morphology, phenotype, and neuronal properties by using immunohistochemistry, retrograde tracing, calcium imaging, and whole-cell recordings. We identify two types of CSF-c cells. Type 1 cells have a bulb-like ending that protrudes into the central canal and a lateral process that ramifies ventrolaterally and laterally with a dense plexus surrounding the mechanosensitive dendrites of the edge cells. Most type 1 cells fire spontaneous action potentials that are abolished by tetrodotoxin, and all display spontaneous excitatory postsynaptic potentials and IPSPs that remain in the presence of tetrodotoxin. GABA and somatostatin are colocalized in type 1 cells, and they express both GABA and glutamate receptors. Type 2 cells, on the other hand, have a flat ending protruding into the central canal and a laterally projecting process that ramifies only at the lateral edge. These cells show immunoreactivity to taurine, but they do not express GABA or somatostatin, nor do they have any active neuronal properties. Type 2 cells might be a form of glia. Type 1 CSF-c cells are neurons and may play a modulatory role by influencing edge cells and thus the locomotor-related sensory feedback.
Cerebrospinal fluid‐contacting (CSF‐c) cells are found in all vertebrates, but their function remains elusive. In the lamprey spinal cord, they surround the central canal and some have processes passing the gray matter to the lateral edge of the flattened spinal cord. Stimulation of CSF‐c cells at the central canal elicits GABAergic inhibitory postsynaptic potentials (IPSPs) in intraspinal stretch receptor neurons (edge cells). Here, we characterize laterally projecting CSF‐c cells according to their morphology, phenotype, and neuronal properties by using immunohistochemistry, retrograde tracing, calcium imaging, and whole‐cell recordings. We identify two types of CSF‐c cells. Type 1 cells have a bulb‐like ending that protrudes into the central canal and a lateral process that ramifies ventrolaterally and laterally with a dense plexus surrounding the mechanosensitive dendrites of the edge cells. Most type 1 cells fire spontaneous action potentials that are abolished by tetrodotoxin, and all display spontaneous excitatory postsynaptic potentials and IPSPs that remain in the presence of tetrodotoxin. GABA and somatostatin are colocalized in type 1 cells, and they express both GABA and glutamate receptors. Type 2 cells, on the other hand, have a flat ending protruding into the central canal and a laterally projecting process that ramifies only at the lateral edge. These cells show immunoreactivity to taurine, but they do not express GABA or somatostatin, nor do they have any active neuronal properties. Type 2 cells might be a form of glia. Type 1 CSF‐c cells are neurons and may play a modulatory role by influencing edge cells and thus the locomotor‐related sensory feedback. J. Comp. Neurol. 522:1753–1768, 2014. © 2014 Wiley Periodicals, Inc.
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