Functional comparison of corticostriatal and thalamostriatal postsynaptic responses in striatal neurons of the mouse.

Synaptic inputs from cortex and thalamus were compared in electrophysiologically defined striatal cell classes: direct and indirect pathways' striatal projection neurons (dSPNs and iSPNs), fast-spiking interneurons (FS), cholinergic interneurons (ChINs), and low-threshold spiking-like (LTS-like) interneurons. Our purpose was to observe whether stimulus from cortex or thalamus had equivalent synaptic strength to evoke prolonged suprathreshold synaptic responses in these neuron classes. Subthreshold responses showed that inputs from either source functionally mix up in their dendrites at similar electrotonic distances from their somata. Passive and active properties of striatal neuron classes were consistent with the previous studies. Cre-dependent adeno-associated viruses containing Td-Tomato or eYFP fluorescent proteins were used to identify target cells. Transfections with ChR2-eYFP driven by the promoters CamKII or EF1.DIO in intralaminar thalamic nuclei using Vglut-2-Cre mice, or CAMKII in the motor cortex were used to stimulate cortical or thalamic afferents optogenetically. Both field stimuli in the cortex or photostimulation of ChR2-YFP cortical fibers evoked similar prolonged suprathreshold responses in SPNs. Photostimulation of ChR2-YFP thalamic afferents also evoked suprathreshold responses. Differences previously described between responses of dSPNs and iSPNs were observed in both cases. Prolonged suprathreshold responses could also be evoked from both sources onto all other neuron classes studied. However, to evoke thalamostriatal suprathreshold responses, afferents from more than one thalamic nucleus had to be stimulated. In conclusion, both thalamus and cortex are capable to generate suprathreshold responses converging on diverse striatal cell classes. Postsynaptic properties appear to shape these responses.

Modulation of Ca2+-currents by sequential and simultaneous activation of adenosine A1 and A 2A receptors in striatal projection neurons.

D(1)- and D(2)-types of dopamine receptors are located separately in direct and indirect pathway striatal projection neurons (dSPNs and iSPNs). In comparison, adenosine A(1)-type receptors are located in both neuron classes, and adenosine A(2A)-type receptors show a preferential expression in iSPNs. Due to their importance for neuronal excitability, Ca(2+)-currents have been used as final effectors to see the function of signaling cascades associated with different G protein-coupled receptors. For example, among many other actions, D(1)-type receptors increase, while D(2)-type receptors decrease neuronal excitability by either enhancing or reducing, respectively, CaV1 Ca(2+)-currents. These actions occur separately in dSPNs and iSPNs. In the case of purinergic signaling, the actions of A(1)- and A(2A)-receptors have not been compared observing their actions on Ca(2+)-channels of SPNs as final effectors. Our hypotheses are that modulation of Ca(2+)-currents by A(1)-receptors occurs in both dSPNs and iSPNs. In contrast, iSPNs would exhibit modulation by both A(1)- and A2A-receptors. We demonstrate that A(1)-type receptors reduced Ca(2+)-currents in all SPNs tested. However, A(2A)-type receptors enhanced Ca(2+)-currents only in half tested neurons. Intriguingly, to observe the actions of A(2A)-type receptors, occupation of A(1)-type receptors had to occur first. However, A(1)-receptors decreased Ca(V)2 Ca(2+)-currents, while A(2A)-type receptors enhanced current through Ca(V)1 channels. Because these channels have opposing actions on cell discharge, these differences explain in part why iSPNs may be more excitable than dSPNs. It is demonstrated that intrinsic voltage-gated currents expressed in SPNs are effectors of purinergic signaling that therefore play a role in excitability.

CaV2.1 channels are modulated by muscarinic M1 receptors through phosphoinositide hydrolysis in neostriatal neurons.

In adult neostriatal projection neurons, the intracellular Ca(2+) supplied by Ca(V)2.1 (P/Q) Ca(2+) channels is in charge of both the generation of the afterhyperpolarizing potential (AHP) and the release of GABA from their synaptic terminals, thus being a major target for firing pattern and transmitter release modulations. We have shown that activation of muscarinic M(1)-class receptors modulates Ca(V)2.1 channels in these neurons in rats. This modulation is reversible, is not membrane delimited, is blocked by the specific M(1)-class muscarinic antagonist muscarine toxin 7 (MT-7), and is neither mediated by protein kinase C (PKC) nor by protein phosphatase 2B (PP-2B). Hence, the signaling mechanism of muscarinic Ca(V)2.1 channel modulation has remained elusive. The present paper shows that inactivation of phospholipase C (PLC) abolishes this modulation while inhibition of phosphoinositide kinases, PI-3K and PI-4K, prevents its reversibility, suggesting that the reconstitution of muscarinic modulation depends on phosphoinositide rephosphorylation. In support of this hypothesis, the supply of intracellular phosphatidylinositol (4,5) bisphosphate [PI(4,5)P(2)] blocked all muscarinic modulation of this channel. The results indicate that muscarinic M(1) modulation of Ca(V)2.1 Ca(2+) channels in these neurons involves phosphoinositide hydrolysis.

Dopamine D(2)-class receptor supersensitivity as reflected in Ca2+ current modulation in neostriatal neurons.

The loss of dopaminergic neurons followed by dopamine (DA) depletion in the neostriatum is a hallmark of Parkinson's disease. Among other changes, DA D(2)-receptor class (D(2)R-class) supersensitivity is a result of striatal DA depletion. Pharmacological, biochemical and behavioral data have documented this phenomenon, but clear electrophysiological-functional correlates are still lacking. This work describes an electrophysiological correlate of D(2)R-class supersensitivity in DA-depleted striata after unilateral 6-hydroxydopamine (6-OHDA) lesions in the rat substantia nigra compacta (SNc). Ca2+ current modulation mediated by D(2)R-class activation reflected an altered sensitivity. Thus, while the concentration-response relationship (C-R plot) from control striata was better fit with a two sites model, the C-R plot obtained from DA-depleted striata was better fit by a three sites model, exhibited a considerable leftward shift, and presented an increased maximal response. Because Ca2+ current modulation by D(2)R-class activation is involved in the control of spiny neurons excitability and their synaptic GABA release, the present findings may help to explain several functional changes found in the striatal circuitry after dopaminergic denervation.

Muscarinic M(1) modulation of N and L types of calcium channels is mediated by protein kinase C in neostriatal neurons.

In some neurons, muscarinic M(1)-class receptors control L-type (Ca(V)1) Ca(2+)-channels via protein kinase C (PKC) or calcineurin (phosphatase 2B; PP-2B) signaling pathways. Both PKC and PP-2B pathways start with phospholipase C (PLC) activation. In contrast, P/Q- and N-type (Ca(V)2.1, 2.2, respectively) Ca(2+)-channels are controlled by M(2)-class receptors via G proteins that may act, directly, to modulate these channels. The hypothesis of this work is that this description is not enough to explain muscarinic modulation of Ca(2+) channels in rat neostriatal projection neurons. Thus, we took advantage of the specific muscarinic toxin 3 (MT-3) to block M(4)-type receptors in neostriatal neurons, and leave in isolation the M(1)-type receptors to study them separately. We then asked what Ca(2+) channels are modulated by M(1)-type receptors only. We found that M(1)-receptors do modulate L, N and P/Q-types Ca(2+) channels. This modulation is blocked by the M(1)-class receptor antagonist (muscarinic toxin 7, MT-7) and is voltage-independent. Thereafter, we asked what signaling pathways, activated by M(1)-receptors would control these channels. We found that inactivation of PLC abolishes the modulation of all three channel types. PKC activators (phorbol esters) mimic muscarinic actions, whereas reduction of intracellular calcium virtually abolishes all modulation. As expected, PKC inhibitors prevented the muscarinic reduction of the afterhyperpolarizing potential (AHP), an event known to be dependent on Ca(2+) entry via N- and P/Q-type Ca(2+) channels. However, PKC inhibitors (bisindolylmaleimide I and PKC-1936) only block modulation of currents through N and L types Ca(2+) channels; while the modulation of P/Q-type Ca(2+) channels remains unaffected. These results show that different branches of the same signaling cascade can be used to modulate different Ca(2+) channels. Finally, we found no evidence of calcineurin modulating these Ca(2+) channels during M(1)-receptor activation, although, in the same cells, we demonstrate functional PP-2B by activating dopaminergic D(2)-receptor modulation.

Somatostatinergic modulation of firing pattern and calcium-activated potassium currents in medium spiny neostriatal neurons.

Somatostatin is synthesized and released by aspiny GABAergic interneurons of the neostriatum, some of them identified as low threshold spike generating neurons (LTS-interneurons). These neurons make synaptic contacts with spiny neostriatal projection neurons. However, very few somatostatin actions on projection neurons have been described. The present work reports that somatostatin modulates the Ca(2+) activated K(+) currents (K(Ca) currents) expressed by projection cells. These actions contribute in designing the firing pattern of the spiny projection neuron; which is the output of the neostriatum. Small conductance (SK) and large conductance (BK) K(Ca) currents represent between 30% and 50% of the sustained outward current in spiny cells. Somatostatin reduces SK-type K(+) currents and at the same time enhances BK-type K(+) currents. This dual effect enhances the fast component of the after hyperpolarizing potential while reducing the slow component. Somatostatin then modifies the firing pattern of spiny neurons which changed from a tonic regular pattern to an interrupted "stuttering"-like pattern. Semi-quantitative reverse transcriptase-polymerase chain reaction (RT-PCR) tissue expression analysis of dorsal striatal somatostatinergic receptors (SSTR) mRNA revealed that all five SSTR mRNAs are present. However, single cell RT-PCR profiling suggests that the most probable receptor in charge of this modulation is the SSTR2 receptor. Interestingly, aspiny interneurons may exhibit a "stuttering"-like firing pattern. Therefore, somatostatin actions appear to be the entrainment of projection neurons to the rhythms generated by some interneurons. Somatostatin is then capable of modifying the processing and output of the neostriatum.

Spontaneous voltage oscillations in striatal projection neurons in a rat corticostriatal slice.

In a rat corticostriatal slice, brief, suprathreshold, repetitive cortical stimulation evoked long-lasting plateau potentials in neostriatal neurons. Plateau potentials were often followed by spontaneous voltage transitions between two preferred membrane potentials. While the induction of plateau potentials was disrupted by non-NMDA and NMDA glutamate receptor antagonists, the maintenance of spontaneous voltage transitions was only blocked by NMDA receptor and L-type Ca2+ channel antagonists. The frequency and duration of depolarized events, resembling up-states described in vivo, were increased by NMDA and L-type Ca2+ channel agonists as well as by GABAA receptor and K+ channel antagonists. NMDA created a region of negative slope conductance and a positive slope crossing indicative of membrane bistability in the current-voltage relationship. NMDA-induced bistability was partially blocked by L-type Ca2+ channel antagonists. Although evoked by synaptic stimulation, plateau potentials and voltage oscillations could not be evoked by somatic current injection--suggesting a dendritic origin. These data show that NMDA and L-type Ca2+ conductances of spiny neurons are capable of rendering them bistable. This may help to support prolonged depolarizations and voltage oscillations under certain conditions.

Somatostatin modulates Ca2+ currents in neostriatal neurons.

Somatostatin is synthesized and released by aspiny interneurons of the neostriatum. This work investigates the actions of somatostatin on rat neostriatal neurons of medium size (ca. 6 pF). Somatostatin (1 microM) reduces both calcium action potentials (20 mM tetraethylammonium) by ca. 24% and calcium currents by ca. 35%, in all cells tested. This action was produced in the presence of tetrodotoxin and in dissociated cells and was blocked by cyclo(-7-aminoheptanoyl-phe-d-try-lys-O-benzyl-thr) acetate (CPP-1), a somatostatin receptor antagonist. Except for nitrendipine (5 microM), several calcium channel antagonists, 1 microM omega-conotoxin GVIA, 400 nM omega-agatoxin TK, and 1 microM omega-conotoxin MVIIC, partially occluded somatostatin action. According to the calcium channel types known to be blocked by these antagonists, P/Q-type channels appeared to be the channels mainly modulated by somatostatin, followed by N-type channels. Since these channel types generate the afterhyperpolarizing potential in spiny neurons, we investigated the action of somatostatin on this event. Somatostatin reduces the amplitude of the afterhyperpolarizing potential by ca. 39%. This action is occluded by omega-agatoxin TK and omega-conotoxin MVIIC but not by omega-conotoxin GVIA or nicardipine. Thus, the action of somatostatin on the afterhyperpolarizing potential is mainly mediated by P/Q-type calcium channels. The block of the slow afterhyperpolarizing potential made most neurons exhibit an irregular firing mode, suggesting that ion currents other than calcium may also be affected by somatostatin. We conclude that somatostatin exerts a direct postsynaptic effect on neostriatal neurons via the activation of somatostatin receptors. This action affects non-L-type calcium channels and therefore modifies the afterhyperpolarizing potential and the firing pattern. It is proposed that somatostatin and its analogues may have profound effects on the motor functions controlled by the basal ganglia.

Hippocampal hyperexcitability induced by GABA withdrawal is due to down-regulation of GABA(A) receptors.

The sudden interruption of an intracortical instillation of exogenous gamma-aminobutyric acid (GABA) generates an epileptic focus in mammals. Seizures elicited by GABA withdrawal (GW) last for weeks. A similar withdrawal-induced hyperexcitability is also produced by several GABA(A) receptor agonists. This work reports a quantitative analysis of GW-induced hyperexcitability produced in the hippocampus in vitro. GW produced a left-ward displacement of the input/output (I/O) function, suggesting that the postsynaptic component is predominant to explain the hyperexcitability. A decrease in the inhibitory efficacy of the GABA(A) receptor agonist, muscimol, confirmed that inhibition was impaired. Binding saturation experiments demonstrated a decrease in [(3)H]-muscimol binding after GABA withdrawal showing a close correlation with the development of hyperexcitability. All these modifications coursed without changes in receptor affinity (K(D)) for muscimol or bicuculline as demonstrated by both binding studies and Schild analysis. It is concluded that, in the CA1 region of the hippocampus, it is the number of functional GABA(A) receptors, and not the affinity of the receptor, what is decreased during GW-induced hyperexcitability.

High-affinity inhibition of glutamate release from corticostriatal synapses by omega-agatoxin TK.

To know which Ca(2+) channel type is the most important for neurotransmitter release at corticostriatal synapses of the rat, we tested Ca(2+) channel antagonists on the paired pulse ratio. omega-Agatoxin TK was the most effective Ca(2+) channel antagonist (IC(50)=127 nM; maximal effect=211% (with >1 microM) and Hill coefficient=1.2), suggesting a single site of action and a Q-type channel profile. Corresponding parameters for Cd(2+) were 13 microM, 178% and 1.2. The block of L-type Ca(2+) channels had little impact on transmission, but we also tested facilitation of L-type Ca(2+) channels. The L-type Ca(2+) channel agonist, s-(-)-1,4 dihydro-2,6-dimethyl-5-nitro-4-[2-(trifluoromethyl)phenyl]-3-pyridine carboxylic acid methyl ester (Bay K 8644 (5 microM)), produced a 45% reduction of the paired pulse ratio, suggesting that even if L-type channels do not participate in the release process, they may participate in its modulation.

GABAergic presynaptic inhibition of rat neostriatal afferents is mediated by Q-type Ca(2+) channels.

Population spikes associated with the paired pulse facilitation paradigm have been successfully used to measure presynaptic inhibition in several systems. In the present work, this paradigm was used to evaluate the action of baclofen on neostriatal glutamatergic transmission. Baclofen enhanced synaptic facilitation with an EC(50)=0.57 microM and a maximal effect of 457%. Selective antagonists for N-, P- and Q-type Ca(2+)-channels enhanced paired pulse facilitation; suggesting that these channel types participate in the release of transmitter. Nevertheless, neither 1 microM omega-conotoxin GVIA, nor 20 nM omega-agatoxinTK occluded the action of baclofen. Baclofen's action was occluded only by 400 nM omega-agatoxinTK. These data suggest that Q-type Ca(2+)-channels mediate gamma-aminobutyric acid(B) presynaptic inhibition of neostriatal afferents.

Ca2+ channels that activate Ca2+-dependent K+ currents in neostriatal neurons.

It is demonstrated that not all voltage-gated calcium channel types expressed in neostriatal projection neurons (L, N, P, Q and R) contribute equally to the activation of calcium-dependent potassium currents. Previous work made clear that different calcium channel types contribute with a similar amount of current to whole-cell calcium current in neostriatal neurons. It has also been shown that spiny neurons possess both "big" and "small" types of calcium-dependent potassium currents and that activation of such currents relies on calcium entry through voltage-gated calcium channels. In the present work it was investigated whether all calcium channel types equally activate calcium-dependent potassium currents. Thus, the action of organic calcium channel antagonists was investigated on the calcium-activated outward current. Transient potassium currents were reduced by 4-aminopyridine and sodium currents were blocked by tetrodotoxin. It was found that neither 30 nM omega-Agatoxin-TK, a blocker of P-type channels, nor 200 nM calciseptine or 5 microM nitrendipine, blockers of L-type channels, were able to significantly reduce the outward current. In contrast, 400 nM omega-Agatoxin-TK, which at this concentration is able to block Q-type channels, and 1 microM omega-Conotoxin GVIA, a blocker of N-type channels, both reduced outward current by about 50%. These antagonists given together, or 500 nM omega-Conotoxin MVIIC, a blocker of N- and P/Q-type channels, reduced outward current by 70%. In addition, the N- and P/Q-type channel blockers preferentially reduce the afterhyperpolarization recorded intracellularly. The results show that calcium-dependent potassium channels in neostriatal neurons are preferentially activated by calcium entry through N- and Q-type channels in these conditions.

D2 dopamine receptors in striatal medium spiny neurons reduce L-type Ca2+ currents and excitability via a novel PLC[beta]1-IP3-calcineurin-signaling cascade.

In spite of the recognition that striatal D(2) receptors are critical determinants in a variety of psychomotor disorders, the cellular mechanisms by which these receptors shape neuronal activity have remained a mystery. The studies presented here reveal that D(2) receptor stimulation in enkephalin-expressing medium spiny neurons suppresses transmembrane Ca(2+) currents through L-type Ca(2+) channels, resulting in diminished excitability. This modulation is mediated by G(beta)(gamma) activation of phospholipase C, mobilization of intracellular Ca(2+) stores, and activation of the calcium-dependent phosphatase calcineurin. In addition to providing a unifying mechanism to explain the apparently divergent effects of D(2) receptors in striatal medium spiny neurons, this novel signaling linkage provides a foundation for understanding how this pivotal receptor shapes striatal excitability and gene expression.

Different Ca2+ source for slow AHP in completely adapting and repetitive firing pyramidal neurons.

Intracellular recordings in an in vitro neocortical slice preparation from immature rats were used to investigate the Ca2 source for slow afterhyperpolarization (sAHP) generation in pyramidal neurons that exhibit complete spike frequency adaptation (CA neurons). In pyramidal neurons that maintain repetitive firing for long periods of time (RF neurons), N-, P- and Q-type Ca2+ channels supply Ca2+ for sAHP generation. In CA neurons, the sAHP was reduced by only 50% by the combination of antagonists for these Ca2+ channel types and L-type channels. Ryanodine and dantrolene, blockers of Ca2(+)-induced Ca2+ release, reduced the sAHP by approximately 45% in CA neurons, but caused no reduction of the sAHP in RF neurons. Dantrolene application caused CA neurons to fire throughout a 1s suprathreshold current injection (as do RF neurons).

Muscarinic presynaptic inhibition of neostriatal glutamatergic afferents is mediated by Q-type Ca2+ channels.

Cholinergic presynaptic inhibition was investigated on neostriatal glutamatergic transmission. Paired pulse facilitation (PPF) of orthodromic population spikes (PS) were used to construct a concentration-response relationship for muscarine on presynaptic inhibition. Muscarine had an effect proportional to its extracellular concentration with an EC50 (mean +/- standard estimation error) of: 2.5 +/- 1.5 nM, and a maximal effect (saturation) of 245 +/- 16%. Several peptidic toxins against some voltage-gated Ca2+-channels increased PPF indicating that the Ca2+-channels they block participate in transmitter release. However, neither 1 microM omega-conotoxin GVIA, a specific blocker of N-type Ca2+-channels, nor 10-30 nM omega-agatoxinTK, a selective blocker of P-type Ca2+-channels, were able to occlude muscarine's effect on presynaptic inhibition. Nevertheless, 100-400 nM omega-agatoxinTK occluded muscarine's action on PPF in a dose-dependent manner. These results are consistent with Q-type Ca2+-channels mediating muscarinic presynaptic inhibition of neostriatal afferents.

Action of substance P (neurokinin-1) receptor activation on rat neostriatal projection neurons.

Substance P (SP) acts as a neurotransmitter in the neostriatum through the axon collaterals of spiny projection neurons. However, possible direct or indirect actions of SP on the neostriatal output neurons have not been described. Targets of SP terminals within the neostriatum include interneurons, spiny neurons, afferent fibers and boutons. SP induces the release of both dopamine (DA) and acetylcholine (ACh). Since some postsynaptic actions of both DA and ACh on spiny neurons are known, we asked if activation of neostriatal NK1-class receptors is able to reproduce them. The SP NK1-receptor agonist, GR73632 (1 microM), had both excitatory and inhibitory actions on virtually all spiny neurons tested at resting potential. The excitatory action was blocked by atropine and coursed with an increase in firing rate and input resistance (R(N)). The inhibitory action was blocked by haloperidol and coursed with a reduction in firing rate and R(N). Therefore, the release of both DA and ACh induced by NK1-receptor activation modulates indirectly the excitability of the projection neurons. SP facilitates the actions of these transmitters on the spiny neuron. A residual excitatory response to the NK1-receptor agonist was observed in 30% of a sample of neurons tested in the presence of both haloperidol and atropine. The increase in R(N) that accompanied this response could be observed in the presence of 1 microM TTX or 100 microM Cd2+, suggesting a direct effect. Double labeling showed that only SP-immunoreactive neurons were facilitated by NK1-receptor activation in these conditions.

Ca2+-activated outward currents in neostriatal neurons.

Whole-cell voltage-clamp recordings of outward currents were obtained from acutely dissociated neurons of the rat neostriatum in conditions in which inward Ca2+ current was not blocked and intracellular Ca2+ concentration was lightly buffered. Na+ currents were blocked with tetrodotoxin. In this situation, about 53 +/- 4% (mean +/- S.E.M.; n = 18) of the outward current evoked by a depolarization to 0 mV was sensitive to 400 microM Cd2+. A similar percentage was sensitive to high concentrations of intracellular chelators or to extracellular Ca2+ reduction (<500 microM); 35+/-4% (n=25) of the outward current was sensitive to 3.0 mM 4-aminopyridine. Most of the remaining current was blocked by 10 mM tetraethylammonium. The results suggest that about half of the outward current is activated by Ca2+ entry in the present conditions. The peptidic toxins charybdotoxin, iberotoxin and apamin confirmed these results, since 34 +/- 5% (n = 14), 29 5% (n= 14) and 28 +/- 6% (n=9) of the outward current was blocked by these peptides, respectively. The effects of charybdotoxin and iberotoxin added to that of apamin, but their effects largely occluded each other. There was additional Cd2+ block after the effect of any combination of toxins. Therefore, it is concluded that Ca2+-activated outward currents in neostriatal neurons comprise several components, including small and large conductance types. In addition, the present experiments demonstrate that Ca2+-activated K+ currents are a very important component of the outward current activated by depolarization in neostriatal neurons.

Cholinergic modulation of neostriatal output: a functional antagonism between different types of muscarinic receptors.

It is demonstrated that acetylcholine released from cholinergic interneurons modulates the excitability of neostriatal projection neurons. Physostigmine and neostigmine increase input resistance (RN) and enhance evoked discharge of spiny projection neurons in a manner similar to muscarine. Muscarinic RN increase occurs in the whole subthreshold voltage range (-100 to -45 mV), remains in the presence of TTX and Cd2+, and can be blocked by the relatively selective M1,4 muscarinic receptor antagonist pirenzepine but not by M2 or M3 selective antagonists. Cs+ occludes muscarinic effects at potentials more negative than -80 mV. A Na+ reduction in the bath occludes muscarinic effects at potentials more positive than -70 mV. Thus, muscarinic effects involve different ionic conductances: inward rectifying and cationic. The relatively selective M2 receptor antagonist AF-DX 116 does not block muscarinic effects on the projection neuron but, surprisingly, has the ability to mimic agonistic actions increasing RN and firing. Both effects are blocked by pirenzepine. HPLC measurements of acetylcholine demonstrate that AF-DX 116 but not pirenzepine greatly increases endogenous acetylcholine release in brain slices. Therefore, the effects of the M2 antagonist on the projection neurons were attributable to autoreceptor block on cholinergic interneurons. These experiments show distinct opposite functions of muscarinic M1- and M2-type receptors in neostriatal output, i.e., the firing of projection neurons. The results suggest that the use of more selective antimuscarinics may be more profitable for the treatment of motor deficits.

Passive properties of neostriatal neurons during potassium conductance blockade.

Voltage recordings from neostriatal projection neurons were obtained using in vitro intracellular techniques before and during K+-conductance blockade. Neurons were stained with the biocytin technique. Somatic surface area (AS) was determined by both whole-cell recordings in isolated somata and by measuring stained somata recorded in slices. Dendritic measurements were done in reconstructed neurons. Average determinations of dendritic (AD) and neuronal (AN) surface areas coincided with previously reported anatomical data. Thus: As approximately 6.5 x 10(-6) cm2; AD approximately 1.9 x 10(-4) cm2; AN approximately AD + AS approximately 2 x 10(-4) cm2; AD/AS approximately 30. Measurements were done before and after superfusion with K+-conductance blockers (K+-blockers). Cells whose neuronal morphology was not obviously distorted by K+-blockade were chosen for the present study. Electrotonic transients were matched to a somatic shunt equivalent cylinder model adjusted with the generalized correction factor (Fdga) that constrains the parameters for neuronal anatomy. Neuronal input resistance (RN; mean +/- SEM) increased when it was corrected for somatic shunt, from 49 +/- 2 Momega (n = 80) to 179 +/- 7 Momega (n = 32). A difference was also obtained between the slowest time constant, tau0 = 16 +/- 0.9 ms (n = 49), and the dendritic membrane time constant, taumD = 33 +/- 1.6 ms (n = 36). When these electrophysiological measurements were used to calculate AN, the value obtained was similar to the anatomical measurements. Combining anatomical and electrophysiological data, somatic and dendritic input resistances were determined: RD = 182 +/- 7 Momega; Rs (with shunt) = 74 +/- 4 Momega (n = 32). The generalized correction factor, Fdga = 0.91 +/- 0.007 (n = 10), implied a short effective electrotonic length for dendrites: LD = 0.46 +/- 0.014 (n = 32). Saturating concentrations of the K+-blockers tetraethylammonium, Cs+, and Ba2+ increased RN and induced charging curves well fitted by single exponential functions in 56% of neostriatal neurons. Ba2+ greatly decreased the somatic shunt (n = 5): (RN = 216 +/- 21 Momega, tau0 = 46 +/- 2 ms, RD = 239 +/- 25 Momega, and RS = 3.2 +/- 0.5 Gomega), rendering values similar to those obtained with whole-cell recordings (e.g., RN approximately 198 Momega, RS approximately 2.62 Gomega) (n = 52). Cs+ (n = 5) had less effect on the somatic shunt (RN = 115 +/- 19 Momega, tau0 = 49 +/- 13 ms, RS = 161 +/- 8 Momega), although dendritic conductance was equally blocked (RD = 261 +/- 16 Momega). The Cs+-sensitive conductance exhibited inward rectifying properties not displayed by the Ba2+-sensitive conductance, suggesting that Cs+ preferentially acted upon inward rectifier conductances. In contrast, Ba2+ significantly acted upon linear conductances making up the somatic shunt. This suggests a differential action of different K+-blockers on the somato-dendritic membrane, implying a differential distribution of membrane conductances. Another action of K+-blockers, in about 40% of the cells, was to induce dye and probably electrical coupling between neighboring neurons.

Ca2+-channels involved in neostriatal glutamatergic transmission.

The actions of peptidic toxins that work as Ca2+-channel antagonists were investigated on neostriatal glutamatergic transmission. Both intracellularly recorded excitatory postsynaptic potentials (EPSPs) and extracellularly recorded population spikes (PS) evoked by afferent stimulation were evaluated in the presence of 10 microM bicuculline. Percentage of block (mean +/- SEM; n = 4) for these events (EPSP and PS, respectively) was: omega-AgTxIVA (100-200 nM): 35 +/- 2 and 54 +/- 4%; omega-CgTxGVIA (1 microM): 37 +/- 3 and 63 +/- 6%; omega-CgTxMVIIC (500 nM): 40 +/- 4 and 50 +/- 2%; and calciseptine (500 nM): 5 +/- 4 and 9 +/- 6%. When given together, toxins had additive effects. The calciseptine effects were nonsignificant. The toxins were also tested on Ca2+-dependent random synaptic responses induced by 100 microM 4-AP. Each toxin reduced the frequency of spontaneous EPSPs by more than 60% (n = 2). The summed actions of individual toxins yields more than 100% block (superadditivity); suggesting that several terminals may possess more than one channel type. The reduction in frequency was not accompanied by a reduction in amplitude confirming that toxins' actions were presynaptic. It is concluded that at least three different Ca2+-channel subtypes are involved in glutamate release in neostriatal afferents: N-type, P/Q-type, and a type resistant to the toxins used. The L-type Ca2+-channel had little, if any, participation.