Clinical outcomes of educating nurses about pediatric pain management

This pilot study examined the influence of a mandatory hospital in-service pediatric pain management program on nurses' administration of analgesics. Chart audits were conducted using a convenience sample of all children who had undergone tonsillectomies during a 2-week period before and after the in-service. In contrast to what was expected, after the educational program, there was an increased length of time before the first dose of analgesic was given and between doses of analgesics given to patients.

Synaptic regulation of action potential timing in neostriatal cholinergic interneurons

Action potentials in neostriatal cholinergic interneurons recorded in vivo are triggered by summation of two or three discrete synaptic depolarizations (Wilson et al., 1990). The ability and precision with which EPSPs and IPSPs regulate action potential timing was therefore investigated in vitro. Cholinergic interneurons were identified on the basis of morphological and electrophysiological characteristics in neostriatal slices taken from 2- to 3-week-old postnatal rats recorded at 24-26 degreesC. During periods of induced regular firing, intrastriatal stimuli were used to evoke pharmacologically isolated monosynaptic AMPA receptor-mediated EPSPs or GABAA receptor-mediated IPSPs. EPSPs evoked during the interspike interval (ISI) produced a phase-dependent decrease in the ISI, whereas IPSPs produced a phase-independent prolongation of the ISI. Injection of brief depolarizing currents mimicked the action of EPSPs and revealed an alteration in the input resistance during the ISI. In contrast to IPSPs, the ability of brief hyperpolarizing current injections to delay spike generation was phase-dependent. After blockade of GABAergic and glutamatergic synaptic transmission, stimuli failed to produce a detectable conductance change but could still prolong the subsequent ISI primarily through a D1 dopamine receptor-mediated enhancement of the afterhyperpolarization (AHP). Hence, EPSPs are ideally suited to provide a precise regulation of spike timing in cholinergic cells, whereas IPSPs are more likely to influence the overall level of excitability. The D1-mediated modulation of the AHP may contribute to the prolonged ISI seen in tonically active neurons in vivo in monkeys trained to respond to a sensory cue.

First report of Hürthle cell carcinoma revealed by octreotide scanning

Octreotide is an 8-chain amino acid analog of somatostatin. Somatostatin and its receptors occur naturally in multiple sites within the body and serve a suppressive role in endocrine hormone release. When octreotide, which has a considerably longer half-life than somatostatin, is combined with a radioactive isotope, receptor-based imaging can be performed to visualize tumors with high concentrations of somatostatin receptors. Tumors of neural crest origin -- pituitary adenomas, islet cell tumors, medullary thyroid carcinomas, pheochromocytomas, carcinoids, and paragangliomas -- all express high levels of somatostatin receptors. We present the first reported positive octreotide scan of a Hürthle cell carcinoma of the thyroid and, more important, discuss the role of octreotide scanning in otolaryngology, which has not yet been reviewed by our literature.

Membrane potential synchrony of simultaneously recorded striatal spiny neurons in vivo

The basal ganglia are an interconnected set of subcortical regions whose established role in cognition and motor control remains poorly understood. An important nucleus within the basal ganglia, the striatum, receives cortical afferents that convey sensorimotor, limbic and cognitive information. The activity of medium-sized spiny neurons in the striatum seems to depend on convergent input within these information channels. To determine the degree of correlated input, both below and at threshold for the generation of action potentials, we recorded intracellularly from pairs of spiny neurons in vivo. Here we report that the transitions between depolarized and hyperpolarized states were highly correlated among neurons. Within individual depolarized states, some significant synchronous fluctuations in membrane potential occurred, but action potentials were not synchronized. Therefore, although the mean afferent signal across fibres is highly correlated among striatal neurons, the moment-to-moment variations around the mean, which determine the timing of action potentials, are not. We propose that the precisely timed, synchronous component of the membrane potential signals activation of cell assemblies and enables firing to occur. The asynchronous component, with low redundancy, determines the fine temporal pattern of spikes.

X-linked dominant chondrodysplasia punctata: a peroxisomal disorder?

X-linked dominant chondrodysplasia punctata is characterised by resolving irregular punctate calcifications of epiphyses, variable ichthyosis and atrophoderma, short stature, and cataracts. We report on a patient with this syndrome who had transiently abnormal peroxisomal function tests. We review the literature and propose that X-linked dominant chondrodysplasia punctata is a peroxisomal disorder and that its phenotype can be explained by X chromosome lyonisation and the relative proliferation of cells expressing the normal X allele.

Selective blockade of a slowly inactivating potassium current in striatal neurons by (+/-) 6-chloro-APB hydrobromide (SKF82958)

The ion channels of rat striatal neurons are known to be modulated by stimulation of D1 dopamine receptors. The susceptibility of depolarization-activated K+ currents to be modulated by the D1 agonist, 6-chloro-7,8-dihydroxy-3-allyl-1-phenyl-2,3,4,5-tetra-hydro-1H-3-benzaze pine (APB) was investigated using whole-cell voltage-clamp recording techniques from acutely isolated neurons. APB (0.01-100 microM) produced a concentration-dependent reduction in the total K+ current. At intermediate concentrations (ca. 10 microM), APB selectively depressed the slowly inactivating A-current (I(As)). A similar effect was produced by application of the D1 agonist, 7,8-dihydroxy-1-phenyl-2,3,4,5-tetrahydro-1-H-2-benzazepine (SKF38393, 10 microM). APB reduced I(As) rapidly, having onset and recovery time constants of 1.2 sec and 1.6 sec, respectively. Unexpectedly, the effect of APB could not be mimicked by application of Sp-adenosine 3',5'-cyclic monophosphothioate triethylamine (Sp-cAMPS, 100-200 microM), a membrane-permeable analog of cyclic AMP (cAMP), or by pretreatment with forskolin (25 microM), an activator of adenylyl cyclase. The reduction in I(As) also was not blocked by pretreatment with the D1 receptor antagonist, R(+)-SCH23390 hydrochloride (SCH23390, 10-20 microM). In addition, intracellular dialysis with guanosine-5'-O-(2-thiodiphosphate (GDP-beta-S, 200 microM) did not preclude the APB-induced inhibition of I(As), nor did dialysis with guanosine-5'-O-(3-thiotriphosphate (GTP-gamma-S, 400 microM) prevent reversal of the effect. The effect of APB was produced by a reduction in the maximal conductance of I(As) without changing the voltage-dependence of the current. Collectively, these results argue that APB does not inhibit I(As) through D1 receptors coupled to stimulation of adenylyl cyclase, but rather by allosterically regulating or blocking the channels giving rise to this current.

Temporal regulation of RNA polymerase II by Srb10 and Kin28 cyclin-dependent kinases

Two cyclin-dependent kinases have been identified in yeast and mammalian RNA polymerase II transcription initiation complexes. We find that the two yeast kinases are indistinguishable in their ability to phosphorylate the RNA polymerase II CTD, and yet in living cells one kinase is a positive regulator and the other a negative regulator. This paradox is resolved by the observation that the negative regulator, Srb10, is uniquely capable of phosphorylating the CTD prior to formation of the initiation complex on promoter DNA, with consequent inhibition of transcription. In contrast, the TFIIH kinase phosphorylates the CTD only after the transcription apparatus is associated with promoter DNA. These results reveal that the timing of CTD phosphorylation can account for the positive and negative functions of the two kinases and provide a model for Srb10-dependent repression of genes involved in cell type specificity, meiosis, and sugar utilization.

Connectivity and convergence of single corticostriatal axons

The distribution of synapses formed by corticostriatal neurons was measured to determine the average connectivity and degree of convergence of these neurons and to search for spatial inhomogeneities. Two kinds of axonal fields, focal and extended, and two striatal tissue compartments, the patch (striosome) and matrix, were analyzed separately. Electron microscopic examination revealed that both kinds of corticostriatal axons made synapses at varicosities that could be identified in the light microscope, and each varicosity made a single synapse. Thus, the distribution of varicosities was a good estimate of the spatial distribution of synapses. The distance between axonal varicosities was measured to determine the density of synaptic connections formed by one axon within the volume occupied by a striatal neuron. Intersynaptic distances were distributed exponentially, except that synapses were rarely located <4 microm apart. The mean distance between synapses was approximately 10 microm, so axons made a maximum of 40 synapses within the dendritic volume of a spiny neuron. There are approximately 2840 spiny neurons located within the volume of the dendrites of one spiny cell (Oorschot, 1996), so each axon must contact </=1.4% of all cells in its axonal arborization. Within the same volume there are approximately 30.5 million asymmetric synapses (Ingham et al., 1996), approximately half of which are cortical in origin. Thus, approximately 380,000 cortical axons innervate the volume of the dendritic tree of one spiny cell. Striatal neurons with totally overlapping dendritic volumes have few presynaptic cortical axons in common, and cortical cells with overlapping axons have few striatal target neurons in common. These results explain the absence of redundancy in the responses of neurons located near each other in the striatum.

Regulation of action-potential firing in spiny neurons of the rat neostriatum in vivo

Both silent and spontaneously firing spiny projection neurons have been described in the neostriatum, but the reason for their differences in firing activity are unknown. We compared properties of spontaneously firing and silent spiny neurons in urethan-anesthetized rats. Neurons were identified as spiny projection neurons after labeling by intracellular injection of biocytin. The threshold for action-potential firing was measured under three different conditions: 1) electrical stimulation of the contralateral cerebral cortex, 2) brief directly applied current pulses, and 3) spontaneous action-potentials occurring during spontaneous episodes of depolarization ( state). The average membrane potential and the amplitude of noiselike fluctuations of membrane potential in the state were determined by fitting a Gaussian curve to the membrane-potential distribution. All neurons in the sample exhibited spontaneous membrane potential shifts between a hyperpolarized state and a depolarized state, but not all fired action potentials while in the state. The difference between the spontaneously firing and the silent spiny neurons was in the average membrane potential in the state, which was significantly more depolarized in the spontaneously firing than in the silent spiny neurons. There were no significant differences in the threshold, the amplitude of the noiselike fluctuations of membrane potential in the state, or in the proportion of time that the membrane potential was in the state. In both spontaneously firing and silent neurons, the threshold for action potentials evoked by current pulses was significantly higher than for those evoked by cortical stimulation. Application of more intense current pulses that reproduced the excitatory postsynaptic potential rate of rise produced firing at correspondingly lower thresholds. Because the membrane potential in the state is mainly determined by the balance between the synaptic drive and the outward potassium conductances activated in the subthreshold range of membrane potentials, either or both of these factors may determine whether firing occurs in response to spontaneous afferent activity.

Spectroscopic characterization of arrestin interactions with competitive ligands: study of heparin and phytic acid binding

A combination of intrinsic fluorescence and circular dichroic (CD) spectroscopy has been used to characterize the complexes formed between bovine retinal arrestin and heparin or phytic acid, two ligands that are known to mimic the structural changes in arrestin attending receptor binding. No changes in the CD spectra were observed upon ligand binding, nor did the degree of tryptophan fluorescence quenching change significantly in the complexes. These data argue against any large-scale changes in protein secondary or tertiary structure accompanying ligand binding. The change in tyrosine fluorescence intensity was used to determine the dissociation constants for the heparin and phytic acid complexes of arrestin. The only change observed was a saturable diminution of tyrosine fluorescence signal from the protein. For both ligands, the data suggest two distinct binding interactions with the protein--a high--affinity interaction with Kd between 200 and 300 nM, and a lower affinity interaction with Kd between 2 and 8 microM. Study of collisional quenching of tyrosine fluorescence in free arrestin and the ligand-replete complexes indicates that 10 of the 14 tyrosine residues of the protein are solvent-exposed in the free protein; this value drops to between 5 and 6 solvent-exposed residues in the high-affinity complexes of the two ligands. These data suggest that ligand binding leads to direct occlusion of between 4 and 5 tyrosine residues on the solvent-exposed surface of the protein, but not to any large-scale changes in protein structure. The large activation energy previously reported to be associated with arrestin-receptor interactions may therefore reflect localized movements of the N- and C-termini of arrestin, which are proposed to interact in the free protein through electrostatic interactions. Binding of the anionic ligands heparin, phytic acid, or phosphorylated rhodopsin may compete with the C-terminus of arrestin for these electrostatic interactions, thus allowing the C-terminus to swing out of the binding region.

A strategy for rapid, high-confidence protein identification

A procedure is described for rapid, high-confidence identification of proteins using matrix-assisted laser desorption/ionization tandem ion trap mass spectrometry in conjunction with a genome database searching strategy. The procedure involves excision of copper-stained bands or spots from electrophoretic gels, in-gel trypsin digestion of the proteins, single-stage mass spectrometric analysis of the resultant mixture of tryptic peptides, followed by tandem ion trap mass spectrometric analysis of selected individual peptides, and database searching of the relevant genomic database using the program PepFrag. The scheme provides sensitive, real-time protein identification as well as facile identification of modifications. A single operator can unambiguously identify 5-10 proteins/day from an organism whose genome is known at a level of > 0.5 pmol of protein loaded on a gel. The utility of the technique was demonstrated by the identification and characterization of a band from a human HTLV-I preparation and 11 different proteins from a yeast RNA polymerase II C-terminal repeat domain-affinity preparation. The technology has great potential for postgenome biological science, where it promises to facilitate the dissection and anatomy of macromolecular assemblages, the definition of disease state markers, and the investigation of protein targets in biological processes such as the cell cycle and signal transduction.

p-(4-Hydroxybenzoyl)phenylalanine: a photoreactive amino acid analog amenable to radioiodination for elucidation of peptide-protein interaction. Application to substance P receptor

Benzoylphenylalanine, a photoreactive phenylalanine analog that can be incorporated into a peptide during solid-phase synthesis, is a useful probe for investigating the interactions of bioactive peptides with their receptors. This probe, however, lacks versatility because it is not detectable by Edman sequencing and because it cannot be labeled with radioiodine, requiring radiolabeling of the peptide ligand at a site distal to the photoreactive amino acid. The separation of the radioisotope and photoaffinity labels along the primary sequence limits identification of the photoinsertion site to a peptide fragment rather than a specific amino acid of the receptor protein. We have now synthesized p-(4-hydroxybenzoyl)phenylalanine by a synthetic route involving reaction of 4-(chloromethyl)benzoic anhydride with phenol in polyphosphoric acid to give the 4-(chloromethyl)benzoyl ester of 4-(chloromethyl)-4'-hydroxybenzophenone followed by reaction of the benzophenone derivative with ethyl acetamidocyanoacetate and subsequent hydrolysis of the product to give p-(4-hydroxybenzoyl)phenylalanine. The novel photolabile amino acid was incorporated into substance P (replacing Phe8 or Lys3) to give 11-mer peptides that bind with high (nM) affinity and specificity to the substance P receptor. Radioiodination of the substance P analogs resulted in the incorporation of 125I at the photoreactive amino acid residue, yielding probes of high (approximately 2000 Ci/mmol) specific activity. Subsequent photolysis of the radiolabeled peptides in the presence of substance P receptor caused covalent attachment of the peptide to the receptor with high photoinsertion yield (approximately 30%); photolabeling was abolished in the presence of excess unlabeled SP. p-(4-Hydroxybenzoyl)phenylalanine retains p-benzoylphenylalanine's high insertion yield and low reactivity with water, but in contrast allows placement of radioiodine and the photoactive moieties within the same residue, providing the ability to identify the specific site(s) of interaction, and identification of the residue by Edman sequencing. This novel amino acid may be useful in the elucidation of the interaction of a variety of peptides with their receptors.

Spontaneous subthreshold membrane potential fluctuations and action potential variability of rat corticostriatal and striatal neurons in vivo

We measured the timing of spontaneous membrane potential fluctuations and action potentials of medial and lateral agranular corticostriatal and striatal neurons with the use of in vivo intracellular recordings in urethan-anesthetized rats. All neurons showed spontaneous subthreshold membrane potential shifts from 7 to 32 mV in amplitude, fluctuating between a hyperpolarized down state and depolarized up state. Action potentials arose only during the up state. The membrane potential state transitions showed a weak periodicity with a peak frequency near 1 Hz. The peak of the frequency spectra was broad in all neurons, indicating that the membrane potential fluctuations were not dominated by a single periodic function. At frequencies >1 Hz, the log of magnitude decreased linearly with the log of frequency in all neurons. No serial dependence was found for up and down state durations, or for the time between successive up or down state transitions, showing that the up and down state transitions are not due to superimposition of noisy inputs onto a single frequency. Monte Carlo simulations of stochastic synaptic inputs to a uniform finite cylinder showed that the Fourier spectra obtained for corticostriatal and striatal neurons are inconsistent with a Poisson-like synaptic input, demonstrating that the up state is not due to an increase in the strength of an unpatterned synaptic input. Frequency components arising from state transitions were separated from those arising from the smaller membrane potential fluctuations within each state. A larger proportion of the total signal was represented by the fluctuations within states, especially in the up state, than was predicted by the simulations. The individual state spectra did not correspond to those of random synaptic inputs, but reproduced the spectra of the up and down state transitions. This suggests that the process causing the state transitions and the process responsible for synaptic input may be the same. A high-frequency periodic component in the up states was found in the majority of the corticostriatal cells in the sample. The average size of the component was not different between neurons injected with QX-314 and control neurons. The high-frequency component was not seen in any of our sample of striatal cells. Corticostriatal and striatal neurons' coefficients of variation of interspike intervals ranged from 1.0 to 1.9. When interspike intervals including a down state were subtracted from the calculation, the coefficient of variation ranged from 0.4 to 1.1, indicating that a substantial proportion of spike interval variance was due to the subthreshold membrane potential fluctuations.

Corticostriatal innervation of the patch and matrix in the rat neostriatum

The distribution of rat corticostrial axons in the patch (striosome) and matrix compartments of the neostriatum was studied by using axonal labeling with biotinylated dextran amine (BDA) and identifying patch and matrix in the same section with calbindin immunocytochemistry. Small injections of BDA were made in the anterior cingulate, medial agranular, lateral agranular, or somatosensory cortex. Each area projected to both the patch and matrix compartments, except for the somatosensory cortex, which had only matrix projections. Within the remaining cortical areas, injections in layers Vb and VI preferentially labeled axons in patches whereas injections in layers III-Va preferentially labeled matrix axons. Axons from these injections formed varicosities preferentially, but not exclusively, in one compartment. There was a population of axons that crossed compartmental boundaries and arborized in both patch and matrix. Two distinct patterns of corticostriatal axonal arborizations were observed. Small, discrete foci of innervation were seen in the patch compartment and in some regions of the matrix. The focal arborizations in the matrix were observed through the rostrocaudal extent of the neostriatum but were most obvious in the caudal one-third. They resembled the matrisomes observed in cat and primate corticostriatal projections. The second pattern of innervation consisted of extended axonal arborizations that covered large regions of the rostral neostriatal matrix. These results support the concept of multiple classes of corticostriatal neurons having different targets within the neostriatum, following different topographical rules, and having different but overlapping distributions across cortical areas.

Isolation and characterization of a persistent potassium current in neostriatal neurons

1. Depolarization-activated, calcium-independent potassium (K+) currents were studied with the use of whole cell voltage-clamp recording from neostriatal neurons acutely isolated from adult (> or = 4 wk old) rats. The whole cell K+ current was composed of transient and persistent components. The aims of the experiments were to isolate the persistent component and then to characterize its voltage dependence and kinetics. 2. Application of 10 mM 4-aminopyridine (4-AP) completely blocked the transient currents while reducing the persistent current by approximately 40% [50% inhibitory concentration (IC50), of blockable current = 125 microM]. The persistent K+ current also was reduced by tetraethylammonium (TEA). Two components to the TEA block were present, having IC50s of 125 microM (23% of the blockable current) and 5.9 mM (77% of the blockable current). Collectively, these results suggested that the persistent components of the total K+ current was pharmacologically heterogeneous. The properties of the 4-AP-resistant, persistent K+ current (IKrp) were subsequently studied. 3. The kinetics of activation and deactivation of IKrp were voltage dependent. Examination of the entire activation/deactivation time constant profile showed that it was bell shaped, with time constants being moderately rapid (tau approximately 50 ms) at membrane potentials corresponding to the resting potential of neostriatal cells (approximately -80 mV), becoming considerably longer (tau approximately 100 ms) at potentials near the cells' spike thresholds (approximately -45 mV), and decreasing to a minimum (tau approximately 5 ms) at potentials associated with the peak of the cells' action potentials (approximately +20 mV). The inactivation kinetics of IKrp also were voltage dependent. The time constants of inactivation varied between 1 and 8 s at potentials between -10 and +35 mV. 4. Unlike persistent K+ currents in many other cell types, IKrp activated at relatively hyperpolarized membrane potentials (approximately -70 mV). The Boltzmann function describing activation had a half-activation voltage of -13 mV and a slope factor of 12 mV. In addition, the Boltzmann function describing the voltage dependence of inactivation of IKrp had a relatively depolarized half-inactivation voltage of -55 and a large slope factor of 19 mV, indicating that this current was available over a broad range of membrane potentials (between -100 and -10 mV). 5. Neostriatal neurons recorded in vivo exhibit subthreshold shifts in membrane potential of variable duration (tens of ms to s) from a hyperpolarized resting state to a depolarized state that is limited in amplitude just below spike threshold. The voltage dependence of activation and inactivation of IKrp indicates that it will be available on depolarization from the hyperpolarized state. However, the slow activation rate of this current suggests that it will contribute little either to limiting the amplitude of the initial depolarization associated with entry into the depolarized state or to depolarizing episodes of short duration (e.g., < 50 ms). However, IKrp should limit the amplitude of membrane depolarizations associated with prolonged excursions into the depolarized state.

The origins of two-state spontaneous membrane potential fluctuations of neostriatal spiny neurons

In vivo intracellular recordings of spontaneous activity of neostriatal spiny cells revealed two-state behavior, i.e., characteristic shifts of membrane potential between two preferred levels. The more polarized level, called the Down state, varied among neurons from -61 to -94 mV. The more depolarized level, called the Up state, varied among neurons form -71 to -40 mV. For any one neuron, the membrane potential in the Up and Down states was constant over the period of observation (from 15 min to 4 hr), and the cells spent little time in transition between states. The level of membrane potential noise was higher in the Up state than in the Down state. Spontaneous membrane potential fluctuations were not abolished by experimental alteration of the membrane potential, but the time spent in each state was altered when intracellular current was used to vary the baseline membrane potential. Neither the sodium nor the calcium action potential that could be evoked by depolarization of spiny neurons was required for the occurrence of spontaneous shifts of membrane potential. Blockade of these action potentials using intracellular injection of QX314 and D890, respectively, altered neither the incidence of the membrane potential shifts nor the preferred membrane potential in either state. In contrast, antagonism of voltage-dependent potassium channels with intracellular cesium altered membrane potential shifts. In the presence of QX314 and D890, intracellular injection of cesium caused little or no change in the Down state and a large depolarizing shift in the Up state (to about -20 mV). Under these circumstances, the neuron responded to current in a nearly linear manner, and membrane conductance was found to be increased in the Up state, attributable to a membrane conductance with the same reversal potential as that of the synaptic potential evoked by cortical stimulation. These results indicate that the event underlying the Up state is a maintained barrage of synaptic excitation, but that the membrane potential achieved during the Up state in neostriatal spiny neurons is determined by dendritic potassium channels that clamp the membrane potential at a level determined by their voltage sensitivity. Neostriatal spiny neurons ordinarily receive enormously powerful excitation, which would drive the cells to saturation, and probably destroy them, if it were not for these potassium currents.

RNA polymerase II holoenzyme contains SWI/SNF regulators involved in chromatin remodeling

The RNA polymerase II holoenzyme contains RNA polymerase II, a subset of general transcription factors and SRB regulatory proteins. We report here that SWI and SNF gene products, previously identified as global gene regulators whose functions include remodeling chromatin, are also integral components of the yeast RNA polymerase II holoenzyme. The SWI/SNF proteins are components of the SRB complex, also known as the mediator, which is tightly associated with the RNA polymerase II C-terminal repeat domain. The SWI/SNF components provide the holoenzyme with the capacity to disrupt nucleosomal DNA and thus facilitate stable binding of various components of the transcription initiation complex at promoters.

Striatal interneurones: chemical, physiological and morphological characterization

The neostriatum is the largest component of the basal ganglia, and the main recipient of afferents to the basal ganglia from the cerebral cortex and thalamus. Studies of the cellular organization of the neostriatum have focused upon the spiny projection neurones, which represent the vast majority of neurones, but the identity and functions of interneurones in this structure have remained enigmatic despite decades of study. Recently, the discovery of cytochemical markers that are specific for each of the major classes of striatal interneurones, and the combination of this with intracellular recording and staining, has revealed the identities of interneurones and some of their functional characteristics in a way that could not have been imagined by the classical morphologists. These methods also suggest some possible modes of action of interneurones in the neostriatal circuitry.

Potassium currents responsible for inward and outward rectification in rat neostriatal spiny projection neurons

Many of the nonlinear membrane properties displayed by neostriatal spiny projection neurons are conferred by their voltage-gated potassium (K+) currents, including an inwardly rectifying current (IKir), fast (IAt), and slowly (IAs)-inactivating A-currents, and a slow, noninactivating current. The relative contribution of these K+ currents to the pronounced inward and outward rectification of the current-voltage (I-V) relationship of spiny neurons was investigated in a neostriatal slice preparation. Manipulation of the equilibrium potential for K+ (EK) showed that the voltage dependence of activation of inward rectification was identical to that of IKir. In addition, application of barium (100 microM), which is known to reduce IKir in a time- and voltage-dependent manner, had equivalent effects on inward rectification. Subsequent application of cesium (3 mM) or tetraethylammonium (TEA, 25 mM) blocked inward rectification in a solely voltage-dependent fashion consistent with the action of these blockers on IKir. Administration of 4-aminopyridine (4-AP, 100 microM) at concentrations that selectively depress IAs, reduced outward rectification of spiny neurons at subthreshold membrane potentials. Higher concentrations of 4-AP (2 mM), which block both IAs and IAt, revealed an early transient overshoot in voltage deflections at potentials near spike threshold, but rectification persisted at the end of the responses. The transient overshoot and the residual rectification were eliminated by TEA (25 mM), a blocker of the slow, noninactivating K+ current. Collectively, these results indicate that all three depolarization-activated K+ currents contribute to outward rectification at different times and membrane potentials defined by their voltage dependence of activation and kinetics of inactivation. The spontaneous activity of neostriatal spiny neurons recorded in intact animals is characterized by sustained and limited shifts in membrane potential from relatively hyperpolarized potentials to depolarized potentials near spike threshold. The present data suggest that the hyperpolarized state is determined principally by IKir and the limits on the depolarized state are defined by IAf, IAs, and the noninactivating current. These outward K+ currents also are hypothesized to govern the spike discharge characteristics once the depolarized state has been reached.