Differential Expression of Large-Conductance Ca-Activated K Channels in the Carotid Body between DBA/2J and A/J Strains of Mice.

The carotid body (CB) is a primary chemosensory organ for arterial hypoxia. Inhibition of K channels in chemosensory glomus cells (GCs) are considered to be responsible for hypoxic chemoreception and/or chemotransduction of the CB. Hypoxic sensitivity of large-conductance calcium-activated K (BK) channels has been established in the rat CB. Our previous work has shown the BK channel ß2 subunits are more expressed in the CB of the DBA/2J mouse than that of the A/J mouse. Because the DBA/2J mouse is more sensitive to hypoxia than the A/J mouse, our general hypothesis is that BK channels play a role in the sensitivity of the mouse CB to mild hypoxia. We performed vigorous analysis of the gene expression of α, ß2, and ß4 subunits of BK channels in the CB. We found that α and ß2 subunits were expressed more in the CB of the DBA/2J mice than that of the A/J mice. No differences were found in the ß4 subunit expression. These differences were not seen in the neighboring tissues, the superior cervical ganglion and the carotid artery, suggesting that the differences are CB specific. Further, the sensitivity of BK channels in GCs to mild hypoxia was examined in patch clamp experiments using undissociated CBs. Iberiotoxin significantly inhibited K current of GCs in the DBA/2J mice, but not in the A/J mice. When reducing PO(2) to ∼70 mmHg, K current reversibly decreased in GCs of the DBA/2J, but not of the A/J mice. In the presence of iberiotoxin, mild hypoxia did not inhibit K current in either strains. Thus, the data suggest that BK channels in GCs of the DBA/2J mice are sensitive to mild hypoxia. Differential expression of BK channel ß subunits in the CBs may, at least in part, explain the different hypoxic sensitivity in these mouse strains.

Facilitatory effects of subanesthetic sevoflurane on excitatory synaptic transmission and synaptic plasticity in the mouse hippocampal CA1 area.

Behavioral investigations have shown that general anesthetics at low concentration have enhancing effects on learning and memory in some animal models. In the present experiments, in order to elucidate the cellular mechanisms underlying such memory enhancement, the effects of anesthetics at low doses on synaptic plasticity in the hippocampus were investigated. Tight-seal whole-cell recordings were made from CA1 pyramidal cells in hippocampal slices prepared from adult male mice, and the effects of subanesthetic concentrations of the volatile anesthetic sevoflurane on the glutamatergic excitatory postsynaptic currents (EPSCs) were investigated. In addition, extracellular recordings of field excitatory postsynaptic potential (fEPSP) and population spike (PS) were made, and the effects of subanesthetic sevoflurane on long-term potentiation (LTP) of the fEPSP slope and on LTP of PS amplitude were analyzed. Sevoflurane at anesthetic concentration inhibited the amplitude of EPSCs with an increase in the paired-pulse facilitation (PPF) ratio. In contrast, subanesthetic sevoflurane increased the amplitude of EPSCs without any appreciable changes in the PPF ratio. Subanesthetic sevoflurane also showed facilitatory influences on LTP of PS amplitude but not on LTP of the fEPSP slope. These observations suggest that sevoflurane at anesthetic concentration presynaptically inhibits excitatory synaptic transmission and at subanesthetic concentration postsynaptically enhances excitatory synaptic transmission in the hippocampal CA1 region. Further, subanesthetic sevoflurane seems to exert facilitatory effects on the EPSP-to-spike coupling process in the postsynaptic neurons. These results might provide clues as to the cellular mechanism of light level of sevoflurane anesthesia.

Syntaxin 1A occludes GABA(B) receptor-induced inhibition of exocytosis downstream of Ca(2+) entry in mouse hippocampal neurons.

The mechanisms underlying gamma-amino butyric acid (GABA(B)) receptor-mediated inhibition of exocytosis have been characterized in a variety of synapses. Using patch-clamp recording methods, we attempted to clarify the intracellular mechanisms underlying presynaptic inhibition in autaptic synapses of isolated mouse hippocampal neurons. Baclofen, a selective GABA(B) receptor agonist, decreased the frequency of glutamatergic miniature excitatory postsynaptic currents (mEPSCs) without changing their amplitude in Ca(2+)-free extracellular solution, suggesting that baclofen inhibits exocytosis downstream of Ca(2+) entry. Syntaxin 1A is known to modulate exocytosis and suppress neuronal sprouting. Antisense oligonucleotide-mediated knockdown of syntaxin 1A increased the frequency of mEPSCs under Ca(2+)-free condition. Estimation of the number of functional release sites by staining with FM1-43 indicated that the increased frequency of mEPSCs was induced by facilitation of exocytosis at each site, rather than by an increased number of release sites due to neuronal sprouting. Baclofen reduced mEPSC frequency in syntaxin 1A-knockdown neurons to the same level as that in nonsense oligonucleotide transfected neurons under Ca(2+)-free condition. These results suggest that the GABA(B) receptor- and syntaxin 1A-induced inhibitions of exocytosis occlude one another and that the GABA(B) receptor shares a common intracellular pathway with syntaxin 1A in inhibiting transmitter release downstream of Ca(2+) entry.

Role of acetylcholine in neurotransmission of the carotid body.

Acetylcholine (ACh) has been considered an important excitatory neurotransmitter in the carotid body (CB). Its physiological and pharmacological effects, metabolism, release, and receptors have been well documented in several species. Various nicotinic and muscarinic ACh receptors are present in both afferent nerve endings and glomus cells. Therefore, ACh can depolarize or hyperpolarize the cell membrane depending on the available receptor type in the vicinity. Binding of ACh to its receptor can create a wide variety of cellular responses including opening cation channels (nicotinic ACh receptor activation), releasing Ca(2+) from intracellular storage sites (via muscarinic ACh receptors), and modulating activities of K(+) and Ca(2+) channels. Interactions between ACh and other neurotransmitters (dopamine, adenosine, nitric oxide) have been known, and they may induce complicated responses. Cholinergic biology in the CB differs among species and even within the same species due to different genetic composition. Development and environment influence cholinergic biology. We discuss these issues in light of current knowledge of neuroscience.

Facilitatory action of halothane at subanesthetic concentrations on glutamatergic excitatory synaptic transmission in the CA1 area of adult rat hippocampus.

Whole-cell recordings were made from pyramidal cells visually identified in the CA1 field of adult rat hippocampal slices, and the effects of subanesthetic concentrations of halothane on excitatory postsynaptic currents mediated by non-N-methyl-D-aspartate subtype glutamate receptors were investigated. Halothane concentrations were measured by gas chromatography. At concentrations of 0.2 mM and 0.6 mM, halothane reversibly decreased the amplitude of excitatory postsynaptic currents (EPSCs) evoked by electrical stimulation of Schaffer collateral fibers, and the decrease was accompanied by enhanced paired-pulse facilitation, consistent with the previously reported presynaptic site of halothane's inhibitory action. By contrast, at lower concentrations (0.02 mM and 0.05 mM), halothane increased the amplitude of EPSCs without any appreciable changes in paired-pulse facilitation. Moreover, the frequency of miniature EPSCs arising spontaneously in the presence of tetrodotoxin (mEPSCs) was increased by subanesthetic halothane, but the amplitude of the mEPSCs did not change significantly. These observations suggest that at subanesthetic concentrations halothane postsynaptically enhances glutamatergic excitatory synaptic transmission. This may provide a vital clue to elucidation of the neural mechanisms of the nociceptive reflex enhancement and excitatory state that occur at light levels of anesthesia.