A translational EEG-based approach to assess modulation of long-lasting NMDAR-dependent synaptic plasticity.

BACKGROUND: NYX-2925 is a novel N-methyl-D-aspartate receptor (NMDAR) modulator that has been shown to facilitate both NMDAR-dependent long-term potentiation (LTP) in vitro and learning and memory in vivo. OBJECTIVE: The present studies examine the effects of NYX-2925 on NMDAR-dependent auditory LTP (aLTP) in vivo. METHODS: NMDAR-dependent aLTP and NMDAR-dependent auditory mismatch negativity (MMN) was measured, as well as changes in resting-state qEEG power. RESULTS: NYX-2925 (1, 10 mg/kg PO) increased aLTP 1 h after auditory tetanus measured by the post- minus pre-tetanus difference waveform 140-180 ms post tone onset. NYX-2925 (0.1, 1 mg/kg PO) facilitated MMN measured by the difference waveform (i.e., deviant minus standard tones). NYX-2925 (0.1, 1, 10 mg/kg PO) also enhanced resting-state alpha qEEG power. Conversely, the NMDAR glutamate site antagonist CPP (10 mg/kg IP) reduces alpha power and MMN and produces an opposite effect as NYX-2925 on aLTP. CONCLUSIONS: Together, these data suggest that the activation of the NMDAR by NYX-2925 enhances synaptic plasticity in vivo, which may both reduce symptoms of neurological disorders and serve as a biomarker for drug effects. This is the first demonstration of a long-lasting (1-h post-tetanus) effect of NMDAR modulation on synaptic plasticity processes in vivo using a noninvasive technique in freely behaving animals.

Assessment of NMDA receptor NR1 subunit hypofunction in mice as a model for schizophrenia.

N-methyl-D-aspartate receptors (NMDARs) play a pivotal role in excitatory neurotransmission, synaptic plasticity and brain development. Clinical and experimental evidence suggests a dysregulation of NMDAR function and glutamatergic pathways in the pathophysiology of schizophrenia. We evaluated electrophysiological and behavioral properties of NMDAR deficiency utilizing mice that express only 5-10% of the normal level of NMDAR NR1 subunit. Auditory and visual event related potentials yielded significantly increased amplitudes for the P20 and N40 components in NMDAR deficient (NR1(neo)-/-) mice suggesting decreased inhibitory tone. Compared to wild types, NR1(neo)-/- mice spent less time in social interactions and showed reduced nest building. NR1(neo)-/- mice displayed a preference for open arms of a zero maze and central zone of an open field, possibly reflecting decreased anxiety-related behavioral inhibition. However, locomotor activity did not differ between groups in either home cage environment or during behavioral testing. NR1(neo)-/- mice displayed hyperactivity only when placed in a large unfamiliar environment, suggesting that neither increased anxiety nor non-specific motor activation accounts for differential behavioral patterns. Data suggest that NMDAR NR1 deficiency causes disinhibition in sensory processing as well as reduced behavioral inhibition and impaired social interactions. The behavioral signature in NR1(neo)-/- mice supports the impact of impaired NMDAR function in a mouse model with possible relevance to negative symptoms in schizophrenia.

Insights into alpha-K toxin specificity for K+ channels revealed through mutations in noxiustoxin.

Noxiustoxin (NxTX) displays an extraordinary ability to discriminate between large conductance, calcium-activated potassium (maxi-K) channels and voltage-gated potassium (Kv1.3) channels. To identify features that contribute to this specificity, we constructed several NxTX mutants and examined their effects on whole cell current through Kv1.3 channels and on current through single maxi-K channels. Recombinant NxTX and the site-specific mutants (P10S, S14W, A25R, A25Delta) all inhibited Kv1.3 channels with Kd values of 6, 30, 0.6, 112, and 166 nM, respectively. In contrast, these same NxTX mutants had no effect on maxi-K channel activity with estimated Kd values exceeding 1 mM. To examine the role of the alpha-carbon backbone in binding specificity, we constructed four NxTX chimeras, which altered the backbone length and the alpha/beta turn. For each of these chimeras, six amino acids comprising the alpha/beta turn in iberiotoxin (IbTX) replaced the corresponding seven amino acids in NxTX (NxTX-YGSSAGA21-27-FGVDRG21-26). The chimeras differed in length of N- and C-terminal residues and in critical contact residues. In contrast to NxTX and its site-directed mutants, all of these chimeras inhibited single maxi-K channels. Under low ionic strength conditions, Kd values ranged from 0.4 to 6 microM, association rate constant values from 3 x 10(7) to 3 x 10(8) M(-1) x s(-1), and time constants for block from 5 to 20 ms. The rapid blocked times suggest that key microscopic interactions at the toxin-maxi-K channel interface may be absent. Under physiologic external ionic strength conditions, these chimera inhibited Kv1.3 channels with Kd values from 30 to 10 000 nM. These results suggest that the extraordinary specificity of NxTX for Kv1.3 over maxi-K channels is controlled, in part, by the toxin alpha-carbon backbone. These differences in the alpha-carbon backbone are likely to reflect fundamental structural differences in the external vestibules of these two channels.

Differential expression of kcnq2 splice variants: implications to m current function during neuronal development.

The KCNQ family of K(+) channels has been implicated in several cardiac and neurological disease pathologies. KCNQ2 (Q2) is a brain-derived gene, which in association with KCNQ3 (Q3) has been shown to provide a molecular basis for the neuronal M current. We have cloned a long (Q2L) and a short (Q2S) splice variant of the human KCNQ2 gene; these variants differ in their C-terminal tail. Northern blot analysis reveals that Q2L is preferentially expressed in differentiated neurons, whereas the Q2S transcript is prominent in fetal brain, undifferentiated neuroblastoma cells, and brain tumors. Q2L, transfected into mammalian cells, produces a slowly activating, noninactivating voltage-gated K(+) current that is blocked potently by tetraethylammonium (TEA; IC(50), 0.14 mm). Q2S on the other hand produces no measurable potassium currents. Cotransfection of Q2S with either Q2L, Q3, or Q2L/Q3 heteromultimers results in attenuation of K(+) current, the suppression being most profound for Q3. Inclusion of Q2S in the heteromultimer also positively shifts the voltage dependence of current activation and alters affinity for the TEA block, suggesting that under these conditions, some Q2S subunits incorporate into functional channels on the plasma membrane. In view of the crucial role of M currents in modulating neuronal excitability, our findings provide important insight into the functional consequences of differential expression of KCNQ2 splice variants: dampened potassium conductances in the developing brain could shape firing repertoires to provide cues for proliferation rather than differentiation.

Properties of Ca(2+) release-activated Ca(2+) channel block by 5-nitro-2-(3-phenylpropylamino)-benzoic acid in Jurkat cells.

Ca(2+) release-activated Ca(2+) current (I(crac)) has been previously characterized biophysically in Jurkat lymphocytes and other non-excitable cells, but pharmacology remains poorly developed. The present objective was to delineate with whole cell recording details of the interaction of the chloride channel blocker, 5-nitro-2-(3-phenylpropylamino)-benzoic acid (NPPB), with I(crac) in Jurkat cells. NPPB reversibly inhibited I(crac) in a concentration-dependent manner (IC(50)=5 microM). Kinetics for block and unblock of I(crac) by NPPB indicated a bimolecular interaction. Michaelis-Menten analysis indicated that NPPB interacts competitively with extracellular Ca(2+) permeating the I(crac) pathway. Finally, analysis of the pH dependence of I(crac) block by NPPB revealed a reduction in the apparent affinity during extracellular alkalinization that based on the pK(a) for NPPB, suggested that the neutral form of NPPB blocks the Ca(2+) release-activated Ca(2+) (CRAC) channel. Taken together, our results suggest a direct interaction between NPPB and the CRAC channel, and should help guide insights for developing novel and more selective analogues.

ShK-Dap22, a potent Kv1.3-specific immunosuppressive polypeptide.

The voltage-gated potassium channel in T lymphocytes, Kv1.3, is an important molecular target for immunosuppressive agents. A structurally defined polypeptide, ShK, from the sea anemone Stichodactyla helianthus inhibited Kv1.3 potently and also blocked Kv1.1, Kv1.4, and Kv1.6 at subnanomolar concentrations. Using mutant cycle analysis in conjunction with complementary mutagenesis of ShK and Kv1.3, and utilizing the structure of ShK, we determined a likely docking configuration for this peptide in the channel. Based upon this topological information, we replaced the critical Lys22 in ShK with the positively charged, non-natural amino acid diaminopropionic acid (ShK-Dap22) and generated a highly selective and potent blocker of the T-lymphocyte channel. ShK-Dap22, at subnanomolar concentrations, suppressed anti-CD3 induced human T-lymphocyte [3H]thymidine incorporation in vitro. Toxicity with this mutant peptide was low in a rodent model, with a median paralytic dose of approximately 200 mg/kg body weight following intravenous administration. The overall structure of ShK-Dap22 in solution, as determined from NMR data, is similar to that of native ShK toxin, but there are some differences in the residues involved in potassium channel binding. Based on these results, we propose that ShK-Dap22 or a structural analogue may have use as an immunosuppressant for the prevention of graft rejection and for the treatment of autoimmune diseases.

Oligomycin inhibits store-operated channels by a mechanism independent of its effects on mitochondrial ATP.

Inhibitors of mitochondrial oxidative metabolism have been proposed to interfere with Ca2+ influx mediated by store-operated channels (SOC), secondary to their effects on ATP production. We assessed SOC activity by 45Ca2+ influx and fluorimetric measurements of free Ca2+ or Mn2+ quench in thapsigargin-treated Chinese hamster ovary cells and Jurkat T-cells, and additionally by electrophysiological measurements of the Ca2+-release-activated Ca2+ current (Icrac) in Jurkat T-cells. Various mitochondrial antagonists were confirmed to inhibit SOC. However, the following evidence supported the proposal that oligomycin, in particular, exerts an inhibitory effect on SOC in addition to its known actions on mitochondria and Na+-pump activity: (i) the concentrations of oligomycin required to inhibit SOC-mediated Ca2+ influx or Icrac (half-inhibitory concentration approximately 2 microM) were nearly 50-fold higher than the concentrations that blocked mitochondrial ATP production; (ii) the rank order of potency of oligomycins A, B and C for decreasing SOC-mediated Ca2+ influx or Icrac differed from that known for inhibition of mitochondrial function; (iii) oligomycin blocked Icrac under voltage clamp and with intracellular Na+ and K+ concentrations fixed by dialysis from the patch pipette, arguing that the effect was not secondary to membrane polarization or pump activity; and (iv) fixing the cytosolic ATP concentration by dialysis from the patch pipette attenuated rotenone- but not oligomycin-mediated inhibition of Icrac. Oligomycin also blocked volume-activated Cl- currents, a profile common to some other known blockers of SOC that are not known mitochondrial inhibitors. These findings raise the possibility that oligomycin interacts directly with SOC, and thus may extend the known pharmacological profile for this type of Ca2+-influx pathway.

A novel gene, hKCa4, encodes the calcium-activated potassium channel in human T lymphocytes.

We have isolated a novel gene, hKCa4, encoding an intermediate conductance, calcium-activated potassium channel from a human lymph node library. The translated protein comprises 427 amino acids, has six transmembrane segments, S1-S6, and a pore motif between S5 and S6. hKCa4 shares 41-42% similarity at the amino acid level with three small conductance calcium-activated potassium channels cloned from brain. Northern blot analysis of primary human T lymphocytes reveals a 2.2-kilobase transcript that is highly up-regulated in activated compared with resting cells, concomitant with an increase in KCa current. hKCa4 transcript is also detected by Northern blots or by polymerase chain reaction in placenta, prostate, thymus, spleen, colon, and many cell lines of hematopoietic origin. Patch-clamp recordings of hKCa4-transfected HEK 293 cells reveal a large voltage-independent, inwardly rectifying potassium current that is blocked by externally applied tetraethylammonium (Kd = 30 +/- 7 mM), charybdotoxin (Kd = 10 +/- 1 nM), and clotrimazole (Kd = 387 +/- 34 nM), but is resistant to apamin, iberiotoxin, kaliotoxin, scyllatoxin (Kd > 1 microM), and margatoxin (Kd > 100 nM). Single hKCa4 channels have a conductance of 33 +/- 2 picosiemens in symmetrical potassium solutions. The channel is activated by intracellular calcium (Kd = 270 +/- 8 nM) with a highly cooperative interaction of approximately three calcium ions per channel. These properties of the cloned channel are very similar to those reported for the native KCa channel in activated human T lymphocytes, indicating that hKCa4 encodes this channel type.

Extracellular site for econazole-mediated block of Ca2+ release-activated Ca2+ current (Icrac) in T lymphocytes.

1. Standard whole cell patch clamp recording techniques were used to study the pharmacological characteristics and site of econazole-mediated inhibition of calcium release-activated calcium current (Icrac) in the human leukaemic T cell line, Jurkat. 2. Extracellularly applied econazole blocked Icrac in a concentration-dependent manner (IC50 approximately 14 microM). Block developed over a relatively slow timecourse of 30-60 s (10 microM), and only partially reversed over minutes. 3. Econazole dialysed from the pipette into the cytosol at concentrations ranging from 0.1 to 30 microM did not reduce Icrac, or quantitatively affect Icrac block by extracellularly applied econazole. 4. A less lipophilic quaternary iodide derivative of econazole was synthesized to retard absorption through the cell membrane. When applied extracellularly, this compound blocked Icrac in a concentration-dependent manner with onset kinetics comparable to econazole. 5. Results with intracellularly dialysed econazole and the quaternary econazole derivative provide convergent evidence that econazole blocks Icrac via an extracellular interaction. 6. The inability of intracellularly applied econazole to inhibit Icrac argues against the notion that econazole inhibits capacitative Ca2+ entry pathways secondary to its known inhibitory effects on cytochrome P-450.

Calcium-dependent enhancement of depletion-activated calcium current in Jurkat T lymphocytes.

We have obtained evidence that the Ca(2+)-selective current activated by Ca2+ store depletion (Ca2+ release-activated Ca2+ current; Icrac) in Jurkat T lymphocytes is augmented in a time-dependent manner by Ca2+ itself. Whole cell patch clamp experiments employed high cytosolic Ca(2+)-buffering conditions to passively deplete Ca2+ stores. Rapidly switching to nominally Ca(2+)-free extracellular buffer instantaneously reduced Icrac measured at -100 mV to leak current level. Unexpectedly, readmission of 2 mM Ca2+ instantaneously restored only 38 +/- 5% (mean +/- SEM, n = 9) of the full Icrac amplitude. The remainder reappeared in a monotonic time-dependent manner over 10 to 20 sec. Rapid vs. slow intracellular Ca2+ chelators did not alter this process, and inorganic Icrac blockers did not regenerate it, arguing against an intracellular site of action. The effect was specific to Ca2+: introduction of the permeant ions, Ba2+ or Sr2+, failed to invoke time-dependent Icrac reappearance. Moreover, equimolar substitution of Ba2+ for Ca2+ initially produced Ba2+ current of similar magnitude to the full Ca2+ current, but the Ba2+ current decayed monotonically to < 50% of its initial amplitude in < 20 sec. Conversely, return to Ca2+ produced a time-dependent increase in Icrac to its larger Ca2+ permeation level. Thus Ca2+ appears to selectively promote a reversible transition of Icrac that results in larger current flux, and at least partially explains the selectivity of this current for Ca2+ over other divalent ions.

Excitable properties and underlying Na+ and K+ currents in neurons from the guinea-pig jugular ganglion.

Neurons in the superior vagal (jugular) ganglion relay afferent information from thoracic visceral organs and may be important in inflammatory processes due to the peripheral release of bioactive neuropeptides such as substance P. We characterized the excitable properties and underlying voltage-gated Na+ (INa) and K+ (IKv) currents in acutely dissociated guinea pig jugular ganglion neurons with microelectrode and whole-cell patch-clamp recording techniques. Current clamp recordings revealed a resting potential of approx. -55 mV and input resistance of approx. 100 M ohms. Brief depolarizing steps evoked an overshooting action potential (approx. 2 ms duration), fast (< 20 ms duration) afterhyperpolarization (AHPF) sequence in all neurons, followed by a slow (> 1 s) Cd(2+)-sensitive afterhyperpolarization (AHPS) in 45% of the neurons. The AHPS was implicated in limiting repetitive action potential firing during maintained depolarizing steps. The action potential in 15/17 neurons, and a major component of the whole cell INa in 13/13 neurons were insensitive to TTX (1-10 microM), indicating that jugular neurons express predominantly a TTX-resistant type of INa. Cd2+ (200 microM) did not affect action potential repolarization, while tetraethylammonium (TEA; 10 mM) in the presence of Cd2+ markedly prolonged action potential repolarization, and blocked the AHPF in 11/11 neurons. This suggested that the action potential repolarization and the AHPF are mediated by IKv, with little contribution by Ca(2+)-dependent IK (IK(Ca)). Whole cell IKv activated rapidly (tau < 1.5 ms), and inactivated variably over a time period of seconds. IKv activation and inactivation voltage dependencies and TEA sensitivity were compatible with its availability during the action potential and AHPF. Only 1/26 neurons exhibited current with the rapid inactivation kinetics and voltage-dependencies characteristic of classic IA-type current. These results highlight differences in the properties of jugular neurons (e.g., deficiency of rapid IA, and lack of a TTX-sensitive subpopulation), relative to those known for other visceral and somatic afferents, and thus provide a basis for further functional studies.

Calcium current characterization in dissociated adult guinea-pig jugular ganglion neurons.

Voltage-dependent calcium (Ca2+) channel currents in freshly dissociated adult guinea-pig jugular ganglion neurons were examined and characterized using the whole-cell patch-clamp technique. Electrophysiological analysis demonstrated a high-threshold current, but no low-threshold or T-type current. A fraction of the total Ca2+ current was inhibited by omega (omega)-conotoxin GVIA (Cg (inTX; 10 microM); the dihydropyridine antagonist nifedipine (NIF; 10 microM), inhibited a large fraction of the CgTX-insensitive current. The remaining CgTX/NIF-insensitive current was completely inhibited by omega-agatoxin IVA (AgIVA; 100 nM). These results demonstrated that the whole-cell Ca2+ channel current consisted only of N-, L- P-type components. Of these currents, only the L-type was partially inhibited by both histamine and carbachol (0.01-100 microM).

Guinea pig visceral C-fiber neurons are diverse with respect to the K+ currents involved in action-potential repolarization.

1. Intracellular recordings were made from C-fiber neurons identified by antidromic conduction velocity in intact guinea pig nodose ganglia maintained in vitro, and whole-cell patch clamp recordings were made from dissociated guinea pig nodose neurons to investigate the contribution of various K+ conductances to action-potential repolarization. 2. The repolarizing phase of the intracellularly recorded action potential was prolonged in a concentration-dependent manner by charybdotoxin (Chtx; EC50 = 39 nM) or iberiatoxin (Ibtx; EC50 = 48 nM) in a subpopulation of 16/36 C-fiber neurons. In a subset of these experiments, removal of extracellular Ca2+ reversibly prolonged action-potential duration (APD) in the same 4/9 intracellularly recorded C-fiber neurons affected by Chtx (> or = 100 nM). These convergent results support that a Ca(2+)-activated K+ current (IC) contributes to action-potential repolarization in a restricted subpopulation of C-fiber neurons. 3. Tetraethylammonium (TEA; 1-10 mM) increased APD considerably further in the presence of 100-250 nM Chtx or Ibtx, or in nominally Ca(2+)-free superfusate in 14/14 intracellularly recorded C-fiber neurons. TEA affected APD similarly in subpopulations of neurons with and without IC, suggesting that a voltage-dependent K+ current (IK) contributes significantly to action-potential repolarization in most nodose C-fiber neurons. 4. Substitution of Mn2+ for Ca2+ reduced outward whole-cell currents elicited by voltage command steps positive to -30 mV (2-25 ms) in a subpopulation of 21/36 dissociated nodose neurons, supporting the heterogeneous expression of IC. The kinetics of outward tail current relaxations (tau s of 1.5-2 ms) measured at the return of 2-3 ms depolarizing steps to -40 mV were indistinguishable in neurons with and without IC, precluding a separation of the nodose IC and IK by a difference in deactivation rates. 5. Chtx (10-250 nM) reduced in a subpopulation of 3/8 C-fiber neurons the total outward current elicited by voltage steps depolarized to -30 mV in single microelectrode voltage-clamp recordings. TEA (5-10 mM) further reduced outward current in the presence of 100-250 nM Chtx in all eight experiments. The Chtx-sensitive current was taken to represent IC, and the TEA-sensitive current, the IK component contributing to action-potential repolarization. 6. Rapidly inactivating current (IA) was implicated in action-potential repolarization in a subpopulation of intracellularly recorded C-fiber neurons. In 4/7 neurons, incremented hyperpolarizing prepulses negative to -50 mV progressively shortened APD.(ABSTRACT TRUNCATED AT 400 WORDS)

Protective role for neuropeptides in acute pulmonary response to acrolein in guinea pigs.

To determine the potential role of neuropeptides in acrolein-induced airway responses, capsaicin-treated guinea pigs were exposed to acrolein aerosol in a regimen causing increased airway sensitivity to substance P. Acrolein exposure resulted in 100% mortality after capsaicin pretreatment compared with only 14% mortality in guinea pigs not pretreated with capsaicin. Acrolein exposure by itself caused marked pulmonary inflammation and large airway epithelial necrosis and denudation. Pretreatment with capsaicin exacerbated these responses throughout the lung. Intravenous acrolein caused an acute dose-related bronchoconstriction in naive guinea pigs that was diminished by capsaicin treatment and potentiated by thiorphan pretreatment, which suggests that arolein exposure causes an acute release of capsaicin-sensitive C-fiber neuropeptides. To determine whether acrolein-induced C-fiber release altered neuronal viability, either rhodamine or Fast Blue dye was instilled intratracheally into vehicle- or acrolein-exposed guinea pigs. Acrolein exposure did not reduce the neuronal uptake or retrograde transport of these dyes, as indicated by the number of fluorescent cell bodies in the nodose ganglia. To determine the functional state of airway neurons, the dose response to intravenous capsaicin was measured in vehicle-exposed and acrolein-exposed guinea pigs; no differences were observed. Thus, acrolein appears to activate airway C-fibers, which release neuropeptides that are protective against this insult, with no suggestion of an accompanying reduction in C-fiber function.

A retrograde labeling technique for the functional study of airway-specific visceral afferent neurons.

The development of a method is described whereby primary afferent neurons that specifically innervate the airways in the guinea pig can be retrogradely labeled, acutely dissociated and studied functionally with electrophysiological techniques. Following administration of either dextran-tetramethylrhodamine, Fast Blue, or Fluorogold dye into the tracheal lumen, dye-labeled neurons can be visualized in 100 microns serial nodose ganglion sections. Control experiments show that labeling does not result from the undesirable spread of the dyes to target innervation fields in the gastrointestinal (GI) or cardiovascular (CV) systems. Neuronal somata retain dye label when acutely dissociated. Microelectrode studies provide evidence that the presence of the Rhodamine dye label and its fluorescent excitation neither alter basic electrophysiological membrane parameters nor the chemoreceptive properties of isolated neurons. Thus this new method will allow the isolation of individual airway-specific primary visceral afferent neurons for functional studies with multidisciplinary techniques.

Presynaptic histamine H1 and H3 receptors modulate sympathetic ganglionic synaptic transmission in the guinea-pig.

1. To study the effects of histamine on the efficacy of sympathetic ganglionic synaptic transmission, extracellular recordings of the postganglionic compound action potential (CAP) and intracellular recordings of excitatory postsynaptic potentials (EPSPs) elicited by preganglionic electrical stimulation were obtained from isolated guinea-pig superior cervical ganglia (SCG). 2. In different preparations, superfusion with histamine (0.1-100 microM) either potentiated or depressed the postganglionic CAP elicited by electrical stimulation of the cervical sympathetic trunk (0.2-3.0 Hz). The direction of response produced by histamine did not depend on stimulation frequency or histamine concentration; potentiation and depression both showed concentration dependence over the range of histamine concentrations tested. 3. Experiments employing a variety of histamine receptor agonists or antagonists revealed that histamine-induced potentiation of the postganglionic CAP could be attributed to histamine H1 receptor activation, and depression to H3 receptor activation. 4. Histamine similarly potentiated or depressed the intracellularly recorded EPSP. However, these opposite effects occurred at different synapses. In agreement with the studies on the postganglionic CAP, histamine H1 antagonists prevented histamine-induced potentiation of the EPSP and H3 receptor antagonists prevented histamine-induced depression. 5. Direct quantal analyses of histamine-induced synaptic potentiation and depression were implemented to determine the pre- and postsynaptic components of these effects. Quantal size was estimated by measuring the amplitude of spontaneous miniature EPSP amplitudes. Histamine-induced potentiation and depression of the evoked EPSP were found to be accompanied by increased or decreased quantal content respectively, and unchanged quantal size, providing evidence that presynaptic mechanisms were involved in mediating both effects. 6. Some guinea-pigs were actively sensitized to ovalbumin. Subsequent exposure of the isolated SCG from these animals to the sensitizing antigen produced changes in the EPSP amplitude that correlated significantly to the response produced by exogenously applied histamine at the same synapse. 7. The correspondence between the effects of specific antigen challenge and exogenous histamine on evoked EPSPs at a synapse provides evidence that endogenous histamine released during an immunological response to antigen challenge can activate histamine H1 and H3 receptors to modulate synaptic efficacy in sympathetic ganglia.

Mast cells in the guinea pig superior cervical ganglion: a functional and histological assessment.

We have previously found that antigenic stimulation of mast cells in the guinea pig superior cervical ganglion leads to membrane depolarization of principal neurons and a long-term increase in the efficacy of ganglionic transmission. In this study experiments were conducted to discern the histological, immunological and pharmacological characteristics of the mast cells within the superior cervical ganglion. Mast cells within the superior cervical ganglion could be stained with toluidine blue or berberine sulfate, the latter indicating that heparin-like molecules were present in the granules. Stainable mast cells were distributed throughout the ganglion with no gross evidence of regional localization. The number of mast cells stained with toluidine blue was reduced significantly (P less than 0.01) in contralateral ganglia that had been exposed to the sensitizing antigen (ovalbumin), indicating antigen-induced degranulation. The superior cervical ganglion contained 208 +/- 6 picomole of histamine (mean +/- SEM, n = 66). Ovalbumin evoked the release of histamine from the superior cervical ganglion in a concentration-dependent fashion. At maximally effective concentrations, ovalbumin released 33 +/- 2% of the total histamine stores (mean +/- SEM, n = 61). Similar values were obtained with antigen-challenged stellate ganglia. A temperature of 37 degrees C and an extracellular calcium concentration of 1 mM was required to elicit optimal antigen-induced responses. In addition to releasing histamine, antigenic stimulation of the ganglion resulted in a 3- to 5-fold increase in the synthesis and release of arachidonic acid metabolites including peptidoleukotriene, thromboxane B2, prostaglandins (PG) E2, F2 alpha, D2, the PGD2 metabolite 9 alpha 11 beta-PGF2, and the prostacyclin metabolite 6-keto PGF1 alpha. Various putative mast cell secretagogues were examined for their ability to activate the superior cervical ganglion mast cell, as indicated by evoked histamine release. In contrast to rat peritoneal mast cells, high concentrations of substance P, compound 48/80, and nerve growth factor failed to stimulate the ganglion mast cells. Preganglionic nerve stimulation, electrical field stimulation of axons and cell bodies, or depolarizing concentrations of potassium chloride also failed to activate the superior cervical ganglion mast cells. These results suggest that substances released by membrane depolarization do not influence the function of the resident mast cells. The results demonstrate that the mast cells within sympathetic ganglia can be actively sensitized to respond to specific antigen. These mast cells are similar to lung parenchymal mast cells with respect to histological, immunological and pharmacological characteristics...

Reconstruction of large diaphyseal defects, without free fibular transfer, in Grade-IIIB tibial fractures.

Eight Grade-IIIB tibial fractures that were associated with large soft-tissue and segmental diaphyseal defects, averaging ten centimeters in length, were successfully reconstructed without the use of a free fibular transfer. A free tissue flap was the preferred form of soft-tissue coverage. The osseous reconstruction was accomplished by using a massive amount of autogenous cancellous bone graft. Beads that were made from polymethylmethacrylate and impregnated with two antibiotics at the time of operation were used as soft-tissue spacers to preserve the volume of the diaphyseal defect for later receipt of the cancellous bone graft. The beads prevented the soft-tissue flap from collapsing into and adhering to the site of the tibial defect. The beads also served as vehicles for local delivery of the antibiotics that they contained. When the soft-tissue flap had healed, the beads were replaced with cancellous graft. All of the tibiae healed. The time to healing averaged nine months. The average duration of external fixation was 5.5 months. One deep infection developed, but resolved after debridement and antibiotic therapy. This conservative technique is safe and reliable for patients who have sustained a high-energy tibial fracture and a large segmental diaphyseal defect.

Serotonin increases excitability of rabbit C-fiber neurons by two distinct mechanisms.

Serotonin (5-HT) increases impulse activity in visceral afferent C-fibers in vivo. A 5-HT-induced membrane depolarization may partially account for this effect. Here, we examined the potential contribution of an additional mechanism to the 5-HT-mediated increase in impulse activity. Approximately 40% of rabbit visceral C-fiber neurons exhibit a protracted (greater than 3 s) spike afterhyperpolarization (AHPslow) that is a major determinant of repetitive firing properties in these neurons. Intracellular recording methods were applied to rabbit nodose ganglion neurons in vitro to assess whether 5-HT could increase excitability through effects on the AHPslow. Results revealed a concentration-dependent 5-HT-mediated depression of the AHPslow amplitude and duration that was accompanied by decreased accommodation of action potential firing. Experiments with 5-HT receptor antagonists further showed that this autacoid depressed the AHPslow through a different 5-HT receptor subtype than that subserving the 5-HT-induced depolarization. Thus the AHPslow represents a distinct locus where 5-HT can increase the impulse activity of these visceral C-fiber afferents.

Endogenous histamine excites neurones in the guinea-pig superior cervical ganglion in vitro.

1. Intracellular recordings were obtained from neurones in the guinea-pig superior cervical ganglion (SCG) in vitro to study the electrophysiological effects of endogenously released histamine. 2. Guinea-pigs were actively sensitized to the specific antigen, ovalbumin. SCG removed from these animals rapidly released a significant proportion of their endogenous histamine stores into the extracellular space upon exposure to the sensitizing antigen. Several observations indicated that the released histamine was derived from ganglionic mast cells. 3. The electrophysiological effects produced by antigen challenge in a neurone mimicked qualitatively and quantitatively those effects produced by exogenously applied histamine in the same neurone. Under current clamp the membrane effects of antigen and histamine included a transient depolarization, an increase in input resistance and transient blockade of a long-duration component of the spike after-hyperpolarization. In voltage clamp histamine and antigen produced an inward current and decreased membrane conductance. 4. Histamine H1, but not H2 or H3 receptor antagonists prevented the membrane depolarization to both histamine and antigen treatments. 5. These convergent biochemical, physiological and pharmacological data demonstrate that a sufficient quantity of endogenous histamine is released by an antigenic stimulus in SCG from sensitized guinea-pigs to affect specific electrophysiological characteristics of neurones. Histamine may thus be involved in mediating interactions between the mammalian immune system and the peripheral sympathetic nervous system.