alpha2-Adrenergic receptor-mediated modulation of calcium current in neocortical pyramidal neurons.

Noradrenergic projections to the cortex modulate a variety of cortical activities and calcium channels are one likely target for such modulation. We used the whole-cell patch-clamp technique to study noradrenergic modulation of barium currents in acutely dissociated pyramidal neurons from rat sensorimotor cortex. Extracellular application of specific agonists and antagonists revealed that norepinephrine (NE) reduced Ca2+ current. A major component of this modulation was due to activation of alpha2 receptors. Activation of alpha2-adrenergic receptors resulted in a fast, voltage-dependent pathway involving Gi/Go G-proteins. This pathway targeted N- and P-type calcium channels The alpha2 modulation was partially reversed by repeated action potential waveforms (APWs). N- and P-type channels have been implicated in synaptic transmission and activation of afterhyperpolarizations in these cells. Our findings suggest that NE can regulate these cellular processes by mechanisms sensitive to spike activity.

Structure and targeting of RyR1: implications from fusion of green fluorescent protein at the amino-terminal.

In skeletal muscle, an anterograde signal from the dihydropyridine receptor (DHPR) to the ryanodine receptor (RyR1) is required for excitation-contraction (EC) coupling and a retrograde signal from RyR1 to the DHPR regulates the magnitude of the calcium current carried by the DHPR. As a tool for studying biosynthesis and targeting, we constructed a cDNA encoding green fluorescent protein (GFP) fused to the amino terminal of RyR1 and expressed it in dyspedic myotubes. The GFP-RyR1 was present in a restricted domain near the nucleus injected with cDNA and was fully functional, which places constraints on the location of the amino terminal in the folded structure of RyR1.

A carboxyl-terminal region important for the expression and targeting of the skeletal muscle dihydropyridine receptor.

We have used the yeast two-hybrid technique and expression of truncated/mutated dihydropyridine receptors (DHPRs) to investigate whether the carboxyl tail of the DHPR is involved in targeting to junctions between the sarcolemma and sarcoplasmic reticulum in skeletal muscle. The carboxyl tail was extremely reactive in yeast two-hybrid library screens, with the reactivity residing in amino acids 1621-1647 and abolished by a point mutation (V1642D). Dysgenic myotubes were injected with cDNA encoding green fluorescent protein fused to the amino terminus of DHPRs truncated after either residue 1620 (Delta1621-1873) or residue 1542 (Delta1543-1873) or of full-length DHPRs with the V1642D mutation (V1642D). For either Delta1621-1873 or V1642D, the restoration of excitation-contraction coupling was reduced approximately 40%, and the number of functional DHPRs in the sarcolemma was reduced approximately 30%, compared with the wild-type DHPR. The restoration of excitation-contraction coupling and surface expression was more drastically reduced (by approximately 90 and approximately 55%, respectively) for Delta1543-1873. Fluorescence microscopy revealed that Delta1621-1873 and V1642D were concentrated in a longitudinally restricted region near the injected nucleus, whereas wild-type DHPRs were present relatively uniformly along the length of a myotube. The intensity of fluorescence was greatly reduced for Delta1543-1873, indicating a low level of protein expression. Thus, residues 1543-1647 appear to play a role in the biosynthetic processing, transport, and/or anchoring of DHPRs, with residues 1543-1620 being particularly important for expression.

Calcium channelopathies.

Calcium is an important intracellular signaling molecule, and altered calcium channel function can cause widespread cellular changes. Genetic mutations in calcium channels that cause what appear to be trivial alterations of calcium currents in vitro can result in serious diseases in muscles and the nervous system. This article reviews calcium channelopathies in humans and mice.

Neuromodulation, development and synaptic plasticity.

We discuss parallels in the mechanisms underlying use-dependent synaptic plasticity during development and long-term potentiation (LTP) and long-term depression (LTD) in neocortical synapses. Neuromodulators, such as norepinephrine, serotonin, and acetylcholine have also been implicated in regulating both developmental plasticity and LTP/LTD. There are many potential levels of interaction between neuromodulators and plasticity. Ion channels are substrates for modulation in many cell types. We discuss examples of modulation of voltage-gated Ca2+ channels and Ca(2+)-dependent K+ channels and the consequences for neocortical pyramidal cell firing behaviour. At the time when developmental plasticity is most evident in rat cortex, the substrate for modulation is changing as the densities and relative proportions of various ion channels types are altered during ontogeny. We discuss examples of changes in K+ and Ca2+ channels and the consequence for modulation of neuronal activity.

Altered calcium channel currents in Purkinje cells of the neurological mutant mouse leaner.

Mutations of the alpha1A calcium channel subunit have been shown to cause such human neurological diseases as familial hemiplegic migraine, episodic ataxia-2, and spinocerebellar ataxia 6 and also to cause the murine neurological phenotypes of tottering and leaner. The leaner phenotype is recessive and characterized by ataxia with cortical spike and wave discharges (similar to absence epilepsy in humans) and a gradual degeneration of cerebellar Purkinje and granule cells. The mutation responsible is a single-base substitution that produces truncation of the normal open reading frame beyond repeat IV and expression of a novel C-terminal sequence. Here, we have used whole-cell recordings to determine whether the leaner mutation alters calcium channel currents in cerebellar Purkinje cells, both because these cells are profoundly affected in leaner mice and because they normally express high levels of alpha1A. In Purkinje cells from normal mice, 82% of the whole-cell current was blocked by 100 nM omega-agatoxin-IVA. In Purkinje cells from homozygous leaner mice, this omega-agatoxin-IVA-sensitive current was 65% smaller than in control cells. Although attenuated, the omega-agatoxin-IVA-sensitive current in homozygous leaner cells had properties indistinguishable from that of normal Purkinje neurons. Additionally, the omega-agatoxin-IVA-insensitive current was unaffected in homozygous leaner mice. Thus, the leaner mutation selectively reduces P-type currents in Purkinje cells, and the alpha1A subunit and P-type current appear to be essential for normal cerebellar function.

Characterization of pharmacologically identified voltage-gated calcium channel currents in acutely isolated rat neocortical neurons. I. Adult neurons.

1. Whole cell recordings were obtained from pyramidal neurons acutely dissociated from the sensorimotor cortex of adult rats. 2. Whole cell calcium channel currents were similar in appearance when elicited from holding potentials of -90 or -40 mV. With 5 mM Ba2+ as the charge carrier, currents began to activate at approximately -45 mV, peaked at approximately -10 mV, and had an apparent reversal potential of approximately +45 mV. Current amplitude and voltage dependence varied with the concentration and identity of the charge carrier (Ca2+ vs. Ba2+). Calcium channel currents were blocked completely by > 200 microM Cd2+ (IC50 approximately 3.5 microM). 3. We determined saturating doses for blockade of currents by nifedipine (Nif), omega-conotoxin GVIA (CgTx), and omega-agatoxin IVA (AgTx) in adult cells. We also tested the selectivity of these compounds by applying them in combination and in different orders. We found the three compounds to be highly, but not perfectly, specific. 4. L-type current was operationally defined as that blocked by 5 microM Nif, N-type current as that blocked by 1 microM CgTx, and P-type current as that blocked by 100 nM AgTx. In adult cells, each of these compounds blocked 30-35% of the current. When all three blockers were applied concurrently, approximately 80% of the current was blocked (20% of current was resistant to the 3 blockers). 5. Few biophysical differences were found between the pharmacologically defined current components in adult cells. The resistant current had a more rapid time-to-peak, inactivated more rapidly and completely, and activated at more negative potentials than the other three types.

Characterization of pharmacologically identified voltage-gated calcium channel currents in acutely isolated rat neocortical neurons. II. Postnatal development.

1. Whole cell recordings were obtained from pyramidal neurons acutely dissociated from the sensorimotor cortex of adult (from Lorenzon and Foehring, companion paper) and immature rats postnatal day 1 (P1) to adult. 2. Whole cell calcium channel currents were similar in appearance at all ages. Current amplitudes and estimated densities were initially low (approximately 16 pA/pF at ages < P6) and increased gradually, attaining adult values at approximately 4-5 wk postnatally (approximately 100 pA/pF). 3. L-type current was operationally defined as that blocked by 5 microM nifedipine, N-type current as that blocked by 1 microM omega-conotoxin GVIA, and P-type current as that blocked by 100 nM omega-agatoxin IVA. A resistant current remained in the presence of the combination of these three blockers. The proportions of these four current types did not change during ontogeny. 4. Few biophysical differences were found between the pharmacologically defined current components in adult or 1-wk-old cells. At both ages the resistant current had a more rapid time-to-peak and inactivated more completely and rapidly than the other three types. Resistant currents also activated at more negative potentials. N-, L-, and P-type currents activated at more positive potentials in 1-wk-old cells than in adult cells. For the resistant current, the voltage dependence of activation was not significantly different between the two ages.

Alterations in intracellular calcium chelation reproduce developmental differences in repetitive firing and afterhyperpolarizations in rat neocortical neurons.

Many 1-week-old rat sensorimotor cortical neurons exhibit extreme spike-frequency adaptation (neurons only fire for the first 100-250 ms of a 1 s current injection) accompanied by a large, prolonged afterhyperpolarization (AHP). Relatively greater expression of a Ca-dependent K+ current appears to underlie the extreme adaptation observed in immature cells. In the present study, we examined whether altering intracellular Ca2+ buffering by introducing Ca2+ chelators via the recording electrode could reproduce the age-related differences in firing and AHPs. We studied firing behavior and AHPs in 1-week-old and adult neocortical neurons with sharp microelectrodes, under three recording conditions: no chelator, 2 mM BAPTA, or 100-200 mM BAPTA. Our principal findings in regard to firing behavior and AHPs were that (1) adult-low BAPTA neurons mimicked 1 week-control cells, (2) 1 week-high BAPTA neurons were similar to adult-control cells, (3) a greater percentage of 1 week-low BAPTA neurons showed complete adaptation, and (4) adult neurons impaled with high BAPTA electrodes fired in a burst-spiking mode. These data suggest that Ca2+ regulation is qualitatively different in immature and adult neurons.

The ontogeny of repetitive firing and its modulation by norepinephrine in rat neocortical neurons.

The postnatal ontogeny of electrical properties was studied in rat sensorimotor cortical neurons (P6 to adult) using intracellular recording in an in vitro slice preparation. Many action potential properties and input resistance changed during the first 4 postnatal weeks. Repetitive firing behavior also changed during the first postnatal month. Spike-frequency adaptation was much stronger in immature neurons. At 1 week postnatal, the majority of cortical neurons would only fire for less than 200 ms regardless of the intensity of long depolarizing current injections. These cells were normal in other parameters and could fire throughout a depolarizing current injection in the presence of inorganic calcium channel blockers or norepinephrine (NE), suggesting that the inability to fire was not due to injury. The frequency with which we encountered cells with this extreme adaptation decreased with age. Spike-frequency adaptation in immature neurons appears to be primarily controlled by Ca-dependent K+ conductances as in mature neurons. In mature and immature neurons, three afterhyperpolarizations (AHPs) could be distinguished by their rate of decline. The fast AHP followed repolarization of a single spike and was only partially Ca- and K-dependent. The medium duration AHP was Ca-dependent and apamin-sensitive and the slow AHP was partially Ca-dependent and not blocked by apamin. NE decreased the slow Ca-dependent AHP via beta-adrenergic receptors. This effect of NE on AHPs appeared qualitatively similar throughout postnatal development. NE had a proportionately greater effect in younger neurons, however, due to their relatively larger slow AHP. The quantitative differences of NE's action on the slow AHP (sAHP) led to a qualitative difference in NE's effect on firing behavior. The effects of NE on firing behavior may therefore be greater during times critical for cortical maturation.

Relationship between repetitive firing and afterhyperpolarizations in human neocortical neurons.

1. Human neocortical neurons fire repetitively in response to long depolarizing current injections. The slope of the relationship between average firing frequency and injected current (f-I slope) was linear or bilinear in these cells. The mean steady-state f-I slope (average of the last 500 ms of a 1-s firing episode) was 57.8 Hz/nA. The instantaneous firing rate decreased with time during a 1-s constant-current injection (spike frequency adaptation). Also, human neurons exhibited habituation in response to a 1-s current stimulus repeated every 2 s. 2. Afterhyperpolarizations (AHPs) reflect the active ionic conductances after action potentials. We studied AHPs with the use of intracellular recordings and pharmacological manipulations in the in vitro slice preparation to 1) gain insight into the ionic mechanisms underlying the AHPs and 2) elucidate the role that the underlying currents play in the functional behavior of human cortical neurons. 3. We have classified three AHPs in human neocortical neurons on the basis of their time courses: fast, medium, and slow. The amplitude of the AHPs was dependent on stimulus intensity and duration, number and frequency of spikes, and membrane potential. 4. The fast AHP had a reversal potential of -65 mV and was eliminated in extracellular Co2+, tetraethylammonium (TEA) or 4-aminopyridine, and intracellular TEA or CsCl. These manipulations also caused an increase in spike width. 5. The medium AHP had a reversal potential of -90 to -93 mV (22-24 mV hyperpolarized from mean resting potential). This AHP was reduced by Co2+, apamin, tubocurare, muscarine, norepinephrine (NE), and serotonin (5-HT). Pharmacological manipulations suggest that the medium AHP is produced in part by 1) a Ca-dependent K+ current and 2) a time-dependent anomalous rectifier (IH). 6. The slow AHP reversed at -83 to -87 mV (14-18 mV hyperpolarized from mean resting potential). This AHP was diminished by Co2+, muscarine, NE, and 5-HT. The pharmacology of the slow AHP suggests that a Ca-dependent K+ current with slow kinetics contributes to this AHP. 7. The currents involved in the fast AHP are important in spike repolarization, control of interspike interval during repetitive firing, and prevention of burst firing. Currents underlying the medium and slow AHPs influence the interspike interval during repetitive firing and produce spike frequency adaptation and habituation.

Correlation of physiologically and morphologically identified neuronal types in human association cortex in vitro.

1. We examined whether the three physiologically defined neuron types described for rodent neocortex were also evident in human association cortex studied in an in vitro brain slice preparation. We also examined the relationship between physiological and morphological cell type in human neocortical neurons. In particular, we tested whether burst-firing neurons were numerous in regions of human cortex that are susceptible to seizures. 2. Although we sampled regular-spiking and fast-spiking neurons, we observed no true burst-firing neurons, as defined for rodent cortex. We did find neurons that displayed a voltage-dependent shift in firing behavior. Because this behavior was due, in large part, to a low-threshold calcium conductance, we called these cells low-threshold spike (LTS) neurons. 3. Regular-spiking neurons and LTS neurons only differed in the voltage dependence of firing behavior and the first few interspike intervals (ISIs) of repetitive firing in response to small current injections (from hyperpolarized membrane potentials). Because of the general similarities between the two types, we consider the LTS cells to be a subgroup of regular-spiking cells. 4. All biocytin-filled regular-spiking neurons were spiny and pyramidal and found in layers II-VI. The lone filled fast-spiking cell was aspiny and nonpyramidal (layer V). The LTS neurons were morphologically heterogeneous. We found 80% of LTS neurons to be spiny and pyramidal, but 20% were aspiny nonpyramidal cells. LTS neurons were located in layers II-VI. 5. In conclusion, human association cortex contains two of three physiological cell types described in rodent cortex: regular spiking and fast spiking. These physiological types corresponded to spiny, pyramidal, and aspiny, nonpyramidal cells, respectively. We sampled no intrinsic burst-firing neurons in human association cortex. LTS neurons exhibited voltage-dependent changes in firing behavior and were morphologically heterogeneous: most LTS cells were spiny and pyramidal, but two cells were found to be aspiny and nonpyramidal. It is not clear whether the absence of burst-firing neurons or the morphological heterogeneity of LTS neurons are due to species differences or differences in cortical areas.