A brain slice bath for physiology and compound microscopy, with dual-sided perifusion.

Contemporary in vitro brain slice studies can employ compound microscopes to identify individual neurons or their processes for physiological recording or imaging. This requires that the bath used to maintain the tissue fits within the working distances of a water-dipping objective and microscope condenser. A common means of achieving this is to maintain thin tissue slices on the glass floor of a recording bath, exposing only one surface of the tissue to oxygenated bathing medium. Emerging evidence suggests that physiology can be compromised by this approach. Flowing medium past both sides of submerged brain slices is optimal, but recording baths utilizing this principle are not readily available for use on compound microscopes. This paper describes a tissue bath designed specifically for microscopy and physiological recording, in which temperature-controlled medium flows past both sides of the slices. A particular feature of this design is the use of concentric mesh rings to support and transport the live tissue without mechanical disturbance. The design is also easily adapted for use with thin acute slices, cultured slices, and acutely dispersed or cultured cells maintained either on cover slips or placed directly on the floor of the bath. The low profile of the bath provides a low angle of approach for electrodes, and allows use of standard condensers, nosepieces and water-dipping objective lenses. If visualization of individual neurons is not required, the bath can be mounted on a simple stand and used with a dissecting microscope. Heating is integral to the bath, and any temperature controller capable of driving a resistive load can be used. The bath is robust, readily constructed and requires minimal maintenance. Full construction and operation details are given.

Centre-surround inhibition among olfactory bulb glomeruli.

Centre-surround inhibition--the suppression of activity of neighbouring cells by a central group of neurons--is a fundamental mechanism that increases contrast in patterned sensory processing. The initial stage of neural processing in olfaction occurs in olfactory bulb glomeruli, but evidence for functional interactions between glomeruli is fragmentary. Here we show that the so-called 'short axon' cells, contrary to their name, send interglomerular axons over long distances to form excitatory synapses with inhibitory periglomerular neurons up to 20-30 glomeruli away. Interglomerular excitation of these periglomerular cells potently inhibits mitral cells and forms an on-centre, off-surround circuit. This interglomerular centre-surround inhibitory network, along with the well-established mitral-granule-mitral inhibitory circuit, forms a serial, two-stage inhibitory circuit that could enhance spatiotemporal responses to odours.

Direct excitation of mitral cells via activation of alpha1-noradrenergic receptors in rat olfactory bulb slices.

The main olfactory bulb receives a significant modulatory noradrenergic input from the locus coeruleus. Previous in vivo and in vitro studies showed that norepinephrine (NE) inputs increase the sensitivity of mitral cells to weak olfactory inputs. The cellular basis for this action of NE is not understood. The goal of this study was to investigate the effect of NE and noradrenergic agonists on the excitability of mitral cells, the main output cells of the olfactory bulb, using whole cell patch-clamp recording in vitro. The noradrenergic agonists, phenylephrine (PE, 10 microM), isoproterenol (Isop, 10 microM), and clonidine (3 microM), were used to test for the functional presence of alpha1-, beta-, and alpha2-receptors, respectively, on mitral cells. None of these agonists affected olfactory nerve (ON)-evoked field potentials recorded in the glomerular layer, or ON-evoked postsynaptic currents recorded in mitral cells. In whole cell voltage-clamp recordings, NE (30 microM) induced an inward current (54 +/- 7 pA, n = 16) with an EC(50) of 4.7 microM. Both PE and Isop also produced inward currents (22 +/- 4 pA, n = 19, and 29 +/- 9 pA, n = 8, respectively), while clonidine produced no effect (n = 6). In the presence of TTX (1 microM), and blockers of excitatory and inhibitory fast synaptic transmission [gabazine 5 microM, 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX) 10 microM, and (+/-)-2-amino-5-phosphonopentanoic acid (APV) 50 microM], the inward current induced by PE persisted (EC(50) = 9 microM), whereas that of Isop was absent. The effect of PE was also observed in the presence of the Ca(2+) channel blockers, cadmium (100 microM) and nickel (100 microM). The inward current caused by PE was blocked when the interior of the cell was perfused with the nonhydrolyzable GDP analogue, GDPbetaS, indicating that the alpha1 effect is mediated by G-protein coupling. The current-voltage relationship in the absence and presence of PE indicated that the current induced by PE decreased near the equilibrium potential for potassium ions. In current-clamp recordings from bistable mitral cells, PE shifted the membrane potential from the downstate (-52 mV) toward the upstate (-40 mV), and significantly increased spike generation in response to perithreshold ON input. These findings indicate that NE excites mitral cells directly via alpha1 receptors, an effect that may underlie, at least in part, increased mitral cell responses to weak ON input during locus coeruleus activation in vivo.

A transient effect of estrogen on calcium currents and electrophysiological responses to gonadotropin-releasing hormone in ovine gonadotropes.

Episodic release of luteinizing hormone (LH) by the pituitary gland is controlled by hypothalamic gonadotropin-releasing hormone (GnRH). In the period leading up to the preovulatory surge of LH, estrogen increases the number of pituitary receptors for GnRH and sensitises the gonadotropes to GnRH. The postreceptor events that are responsible for the increase in responsiveness to GnRH are not clearly delineated, but LH release is known to be Ca2+ dependent. The present study addressed the question as to whether or not estrogen may act to modify voltage-dependent Ca2+ entry in normal gonadotropes. Primary cultures enriched in gonadotropes or somatotropes were produced from anestrous female sheep. Conventional whole-cell patch-clamp recording was used to measure inward membrane current in the absence of GnRH treatment, with and without 10 nM estradiol-17beta (E2) treatment for 0 to 36 h. Nystatin-perforated whole-cell patch-clamp recording was used to record membrane voltage responses to GnRH. Ca2+ current density (ICa, pA/pF) began to increase after 2 h exposure to E2, and reached peak values of about 200% of control by 16-20 h (p < 0.005), then declined. If E2 was withdrawn at 24 h, ICa returned towards control values by 36 h. If E2 treatment was continued beyond 24 h, however, ICa fell to about 75% of control by 36 h (p < 0.005). Actinomycin D prevented the enhancement of ICa. E2 was without effect on Na+ current density in gonadotropes, or on ICa in somatotropes. The proportion of ICa carried by L-type and N-type channels in gondadotropes was not changed by E2. Ovine gonadotropes respond to GnRH with membrane potential fluctuations driven by periodic activation of Ca2+-dependent K+ channels, and synchronised action potential generation. This response was found to be sensitive to E2. Responses were categorised according to the pattern of activity evoked by 10 nM GnRH. Without E2 treatment, 11/14 cells responded with oscillations and 3/14 cells responded with spiking (hyperpolarizations following single action potentials). After 20 h 10 nM E2, just 1/14 cells responded with hyperpolarizing oscillations while 13/14 cells showed spiking activity. The predominance of the spiking pattern in E2-treated cells is consistent with the increased Ca2+ flux, and with enhanced LH release. We conclude that E2 has a transient effect on gonadotropes to enhance voltage-gated Ca2+ channel function. The time-course and biphasic nature of the influence of E2 on ICa may be physiologically appropriate to the preovulatory LH surge. Enhanced Ca2+ influx may participate in increased Ca2+-dependent hormone release, while the delayed inhibitory action of E2 on ICa may serve to limit the duration of the surge.

Inward membrane currents and electrophysiological responses to GnRH in ovine gonadotropes.

We have used conventional whole-cell patch-clamp to investigate the membrane currents of ovine anterior pituitary gonadotropes, and nystatin-perforated whole-cell patch-clamp to record the membrane potential changes elicited by the natural hypothalamic secretagogue, gonadotropin-releasing hormone (GnRH). A large basal inward current found by voltage clamp was blocked by tetrodotoxin (TTX) (ED50 < 10 nM), identifying it as a Na+ current. Slowly inactivating inward current, activated at potentials more positive than -30 mV, remained in Na(+)-free medium or in the presence of 1 microM TTX. This current was abolished by ionic Ca2+ channel blockade. In the presence of nifedipine about 70% of this high voltage-activated Ca2+ current was abolished, leaving a slowly inactivating component. No transient Ca2+ current was found. The nifedipine-insensitive slowly inactivating inward current was eliminated by 1 microM omega-conotoxin GVIA (CGTX), consistent with the presence of N-type channels. Outward K+ currents sensitive to membrane voltage and intracellular Ca2+ concentration ([Ca2+]i) were present. The resting membrane potential lay between -20 and -75 mV (mean = -43 +/- 1.5) with spontaneous TTX-sensitive action potentials occurring in 34% of cells. GnRH had concentration-dependent effects on gonadotrope membrane potential. Application of 100 nM GnRH resulted in a rapid hyperpolarization, followed by a gradual depolarization during which action potentials returned briefly. This was followed by protracted electrical quiescence. Application of 1 or 10 nM GnRH led to hyperpolarization, followed by gradual depolarization, upon which rhythmic hyperpolarizations were superimposed, giving membrane potential oscillations. During the depolarising stage of each oscillation, a burst of action potentials occurred. Action potentials, then oscillations, ceased after 5-15 min. Depolarization was then maintained (at -20 to -35 mV) for up to 1 h. Apamin, the SK-type Ca(2+)-dependent K+ channel blocker, prevented the hyperpolarizing oscillations and produced membrane depolarisation, but Ca2+ channel blockade did not. Microfluorimetric detection of [Ca2+]i showed that 10 nM GnRH induced [Ca2+]i oscillations. We conclude that Ca2+ derived from intracellular pools is involved in producing the membrane potential oscillations. The [Ca2+]i fluctuations may activate the apamin-sensitive, Ca(2+)-dependent SK-type K+ channel, and entrain TTX-sensitive action potentials to a bursting pattern of generation following GnRH stimulation. In the absence of T-type currents, the Na+ current spikes may be crucial for activation of the nifedipine- and CGTX-sensitive high-voltage-activated Ca2+ channels.

Gonadotropin-releasing hormone modifies action potential generation in sheep pars distalis gonadotropes.

Cell-intact patch-clamp recording was used to determine the electrophysiological responses of sheep anterior pituitary gonadotropes to stimulation with gonadotropin-releasing hormone (GnRH). Cells were identified prior to recording by reverse haemolytic plaque assay (RHPA), or using morphological criteria in preparations enriched in gonadotropes by Percoll density gradient centrifugation. Most cells identified by RHPA did not generate action potentials, and responses to GnRH were inconsistent. The majority of gonadotropes in enriched preparations however spontaneously generated action potentials requiring the entry of both extracellular Na+ and Ca2+, and involving tetraethylammonium-sensitive K+ channels. Two-minute GnRH application (10(-7) M) evoked a characteristic sequence of changes in action potential generation. The immediate response was an inhibition of action potentials, followed by a recovery of these events, with a progressive decline in amplitude over about 10 min. The cells then remained quiescent for up to 1 h. The results indicate that GnRH may evoke an initial hyperpolarization involving Ca(2+)-dependent K+ channels, followed by a sustained depolarizing response, with consequent inactivation of action potential generation.