Pentobarbital modulatory effect on GABA binding sites in developing chick optic lobe

Acute hypoxia differentially affects the γ-aminobutyric acid type A receptor α1, α2, β2, and γ2 subunit mRNA levels in the developing chick optic tectum: Stage-dependent sensitivity

This investigation analyzes the effect of an acute hypoxic treatment on the level of four (alpha(1), alpha(2), beta(2), and gamma(2)) subunit mRNAs of the GABA(A) receptor in layer "i" of the developing chick optic tectum. Our results show that 1 hr of normobaric acute hypoxia significantly changes the subunit mRNA levels. Different subunit mRNAs display different sensitivity to hypoxia: alpha(1), beta(2), and gamma(2) mRNAs are highly sensitive, whereas alpha(2) mRNA is almost not affected. The sensitivity of the mRNA levels to hypoxia is stage dependent. The mean percentages of variation produced by the hypoxia in the level of expression of the four subunits were 20% at ED12, 5% at ED16, and only 2% at ED18. These changes in the mean percentages of expression modify the probability of coexpression. In the case of double mRNA combinations, the hypoxia produced a mean variation in the probability of coexpression of 37% at ED12, 8% at ED16, and only 4% at ED18. With regard to the triple subunit mRNAs combinations, the variations were 206% at ED12, 11% at ED16, and only 7% at ED18. The quadruple combination values were 1,500% at ED12, 21% at ED16, and only 11% at ED18. This study demonstrates that the subunit mRNA levels are highly sensitive during the early stages, suggesting that GABA(A) receptor composition might undergo environment-dependent plastic changes providing a high degree of plasticity to the GABA neurotransmitter system development.

Development and localisation of GABA(A) receptor alpha1, alpha2, beta2 and gamma2 subunit mRNA in the chick optic tectum

An in situ hybridisation technique was used to analyse the spatial and temporal pattern of expression of the mRNA encoding the four gamma-aminobutyric acid A (GABA(A)) receptor subunits (alpha1, alpha2, beta2, and gamma2) in the developing chick optic tectum. As a rule, layer i, layer h, and transient cell compartment 3 (TCC3) show the highest levels of expression, especially of alpha1, alpha2 and beta2, which undergo striking changes as a function of time. Apart from these common features, the global pattern is highly complex and dynamic. Such complexity derives from the fact that each subunit exhibits a characteristically distinct pattern of expression and the temporal evolution of each differs in the different layers of the tectum. The influence of several developmental cell behaviours such as proliferation, neuronal migration, programmed cell death, and differentiation must be taken into account to understand pattern complexity and dynamics. Our results suggest that differences in the rate of subunit expression, particularly of alpha1, alpha2, and beta2, could have significant consequences on GABA(A) receptor complex subunit composition along development and on the functional properties of the GABA neurotransmitter system.

Hypoxia differentially reduces GABA(A) receptor density during embryonic chick optic lobe development

It has been demonstrated that the CNS is severely affected by hypoxic-ischemic insults during the prenatal-perinatal period, including imbalance in excitatory and inhibitory neurotransmitter release. Using a previously developed model of acute normobaric hypoxic hypoxia on chick embryos, we studied alterations observed both on [3H]GABA binding saturation parameters and on lactate concentration on successive embryonic days (ED). While maximal density of GABA binding sites (Bmax) from the low-affinity site was significantly reduced in an age-dependent manner, earlier stages of development (ED12 and 16) proving more vulnerable (ED12: control = 5.48 +/- 0.20, hypoxia = 3.90 +/- 0.39 pmol/mg prot, P < .05; ED16: control = 3.89 +/- 0.26, hypoxia = 2.80 +/- 0.28 pmol/mg prot, P < .05), ligand affinity (Kd) values and kinetic constants of the high-affinity site remained unaltered. Not unlikely, a physiological hypoxic state prevailing from ED17 up to hatching time rendered the whole embryo less sensitive to an externally induced hypoxic state (ED17: control = 2.93 +/- 0.06, hypoxia = 2.38 +/- 0.04 pmol/mg prot, P < .05; ED18: control = 2.97 +/- 0.12, hypoxia = 2.87 +/- 0.27 pmol/mg prot). Lactate levels in chick optic lobe homogenates were constant during development. The increase observed after hypoxic treatment compared to control value was significant at all stages studied, but increased percentage changes proved similar, indicating that all days of development equally perceive externally induced hypoxia. In conclusion, the present work demonstrates that after normobaric hypoxic hypoxia at different embryonic days, the embryo senses the externally induced hypoxic state as from ED12, but the GABA(A) receptor is differentially affected. It may be speculated that a different subunit composition of GABA(A) receptor is assembled in order to build a more stable receptor capable of resisting the physiological hypoxic state observed during the last few days before hatching.

Differential and irreversible CNS ontogenic reduction in maximal MK-801 binding site number in the NMDA receptor after acute hypoxic hypoxia

CNS exposure to hypoxia impairs excitatory and inhibitory neurotransmission. Our aim was to determine variations induced by normobaric acute hypoxic hypoxia (8% O(2) for 60 min) on the NMDA receptor complex, as well as their potential reversibility after normoxic recovery. To this end, [3H]MK-801 binding assays to a synaptic membrane fraction isolated from chick optic lobes were performed. Previous studies throughout development had disclosed a characteristic age-dependent pattern. Results at embryonic day (ED) 12 and 18 indicated two distinct MK-801 binding sites. Hypoxic treatment failed to alter either the high affinity site dissociation constant (K(d)) or its maximal binding capacity (B(max)), whereas the low affinity site B(max) was significantly decreased (50% and 30% at ED12 and 18, respectively), without alteration in its K(d) values. Hypoxic embryos restored for 48 h at ED12 to normoxic conditions displayed unchanged MK-801 binding reduction, unlike those treated likewise at ED18 whose values fully recovered control levels. To conclude, hypoxic treatment reduces low affinity MK-801 B(max) in the NMDA receptor which proves irreversible up to ED12. Such early neuronal vulnerability may be due to post-transcriptional changes, to endocytosis followed by receptor degradation, or alternatively to cell death.

Acute hypoxic hypoxia alters GABA(A) receptor modulation by allopregnanolone and pentobarbital in embryonic chick optic lobe

Using a previously developed model of acute normobaric hypoxic hypoxia on chick embryos, here we studied at embryonic day 12 the in vitro effect of two positive allosteric modulators of GABA binding, the barbiturate sodium pentobarbital and the neurosteroid allopregnanolone. In both cases an increase in E(max) values in membranes obtained from hypoxic embryos was observed. Studies of GABA-gated chloride influx showed that there were no differences in maximal chloride uptake between hypoxic and control membranes. We have already demonstrated that maximal density of GABA binding sites was decreased after hypoxia, suggesting that each of the remaining GABA(A) receptors display a greater chloride flux than controls. To further characterize GABA(A) receptor alterations, GABA-gated chloride influx modulated by the above barbiturate and neurosteroid was determined, finding that E(max) values were increased 60% and 42%, respectively. The increase in Cl(-) influx per receptor subsequent to hypoxic trauma, and the enhancement in the modulatory properties studied, may mediate neuronal damage by potential changes in subunit interaction at the GABA(A) receptor level.

In ovo chronic neurosteroid treatment affects the function and allosteric interactions of GABAA receptor modulatory sites

We investigated the effects of in ovo chronic administration of the endogenous neurosteroid epipregnanolone (5beta-pregnan-3beta-ol-20-one) on the GABA(A) receptor complex present in chick optic lobe synaptic membranes. Chronic epipregnanolone treatment failed to exert any effect on the chick optic lobe total protein content and wet weight at the different doses tested. [3H]Flunitrazepam control binding remained unaltered after neurosteroid exposure, however, the positive allosteric modulation of this ligand by 4 microM allopregnanolone was reduced in a dose-dependent manner by neurosteroid treatment. Embryo exposure to 30 microM epipregnanolone decreased allopregnanolone EC(50) and E(max) values. Analyses of saturation binding isotherms disclosed that such administration had no effect on K(d) and B(max) values for [3H]flunitrazepam and [3H]GABA binding. [3H]GABA binding modulation disclosed an increase in allopregnanolone EC(50) value with a decrease in its E(max) value. Diazepam EC(50) and E(max) values were enhanced, while low affinity sodium pentobarbital EC(50) value was reduced by epipregnanolone treatment. The investigation of the GABA(A) receptor function revealed that administration of this neurosteroid reduces the efficacy of GABA to induce 36Cl(-) influx into microsacs prepared from chick optic lobe. These results indicate that endogenous neurosteroid epipregnanolone chronically administered in ovo produces homologous uncoupling between steroid modulatory sites, and those corresponding to benzodiazepine and GABA receptors. Thus epipregnanolone is able to induce heterologous changes in the allosteric linkage between benzodiazepine and barbiturate modulatory sites, and the GABA receptor site. Taken jointly with results on epipregnanolone enhancing effects on [3H]flunitrazepam and [3H]GABA binding, in the context of its endogenous synthesis, our present findings support this neurosteroid as the endogenous modulator of GABA(A) receptor sites and function during chick optic lobe development.

Prolonged exposure to hypobaric hypoxia transiently reduces GABA(A) receptor number in mice cerebral cortex

The central nervous system is severely affected by hypoxic conditions, which produce alterations in neural cytoarchitecture and neurotransmission, resulting in a variety of neuropathological conditions such as convulsive states, neurobehavioral impairment and motor CNS alterations. Some of the neuropathologies observed in hypobaric hypoxia, corresponding to high altitude conditions, have been correlated with a loss of balance between excitatory and inhibitory neurotransmission, produced by alterations in glutamatergic and GABAergic receptors. In the present work, we have studied the effect of chronic hypobaric hypoxia (506 hPa, 18 h/day x 21 days) applied to adult male mice on GABA(A) receptors from cerebral cortex, to determine whether hypoxic exposure may irreversibly affect central inhibitory neurotransmission. Saturation curves for [3H]GABA specifically bound to GABA(A) receptors in isolated synaptic membranes showed a 30% decrease in maximal binding capacity after hypoxic exposure (Bmax control, 4.70+/-0.19, hypoxic, 3.33+/-0.10 pmol/mg protein), with no effect on GABA binding sites affinity (Kd control: 159.3+/-13.3 nM, hypoxic: 164.2+/-15.1 nM). Decreased B(max) values were observed up to the 10th post-hypoxic day, returning to control values by the 15th post-hypoxic day. Pharmacological properties of GABA(A) receptor were also affected by hypoxic exposure, with a 45 to 51% increase in the maximal effect by positive allosteric modulators (pentobarbital and 5alpha-pregnan-3alpha-ol-20-one). We conclude that long-term hypoxia produces a significant but reversible reduction on GABA binding to GABA(A) receptor sites in cerebral cortex, which may reflect an adaptive response to this sustained pathophysiological state.

Acute hypoxic hypoxia transiently reduces GABA(A) binding site number in developing chick optic lobe

The Central Nervous System is known to be critically affected in the prenatal-perinatal period by hypoxic-ischemic insults, which produce several disorders such as loss of neural projections, increased susceptibility to seizures, apoptosis and an imbalance in normal activity of glutamatergic and GABAergic neurones, resulting in acute cell excitotoxicity. The aim of the present work was to establish a chick embryo model of normobaric acute hypoxic hypoxia as well as to evaluate modifications in GABA(A) receptor complex from chick optic lobe, that may result from this injury. Fertile chicken (Gallus gallus domesticus) eggs from White Leghorn were incubated and at embryonic days (ED) 12 to 18, subjected to a stream of 8%O(2)/92%N(2) during1 h, and then were either returned to their shelves in the incubator for recovery, or immediately processed for biochemical studies. Hypoxic treatment produced a significant age dependent reduction in GABA binding sites showing the greatest decrease at the earliest stages studied (ED12-ED16). Saturation curves of GABA binding performed at ED12 showed a decrease in B(max), (control, 5.48+/-0.20, hypoxic, 3.90+/-0.39 pmol/mg protein), but no significant change in K(d). Following 48 h in normoxic atmosphere post-hypoxia reduction in [3H]GABA binding was reversed. Pharmacological properties of GABA(A) receptor at ED12 showed that positive allosteric modulation effects of the steroid 3alpha-hydroxy-5alpha-pregnan-20-one and the barbiturate pentobarbital sodium were enhanced by the treatment. This model of acute prenatal hypoxic hypoxia produced marked alterations in inhibitory CNS neurotransmission that proved reversible and age dependent.

Comparative modulation by 3 alpha,5 alpha and 3 beta,5 beta neurosteroids of GABA binding sites during avian central nervous system development

Neurosteroids are endogenous Central Nervous System (CNS) compounds which act mainly by allosteric modulation of the GABAA receptor complex. The presence of a 3 alpha-hydroxyl group and a 5 alpha-hydrogen atom have been found to be essential structural requirements for biological activity in mammals. In the present work we report the enhancing activity on [3H]GABA binding to its receptor sites in chick optic lobe produced by progesterone metabolites 3 alpha-hydroxy,5 alpha-pregnan-20-one (3 alpha,5 alpha-P) and 3 beta-hydroxy,5 beta-pregnan-20-one (3 beta,5 beta-P). Both steroids were found able to enhance [3H]GABA binding along ontogeny, displaying a similar profile at early developmental stages, while in adulthood 3 alpha,5 alpha-P had greater potency (EC50 0.22 microM) and enhancing effect (Emax: 122%). In adult synaptic membranes, the two compounds displayed a complex interaction with the GABAA receptor, disclosed by a Schild plot with slope below one and an incomplete displacement of 3 alpha,5 alpha-P by its 3 beta,5 beta isomer. Such complexity could be related to the steroidogenic profile in avian CNS, with 5 alpha-reduced progesterone metabolites present since early development, while 3 alpha,5 alpha-P is found only in adulthood. Bearing in mind differences between avian and mammalian steroidogenic profiles and the relevance of 5 beta-steroids in early avian development, we propose that 3 beta,5 beta-P, instead of the classical potent 3 alpha,5 alpha-steroids, may be the endogenous modulator of GABAergic activity in developing avian brain.

Epipregnanolone acts as a partial agonist on a common neurosteroid modulatory site of the GABA(A) receptor complex in avian CNS

Neurosteroid modulatory sites present in the GABA(A) receptor complex in chick optic lobe were investigated, in order to evaluate whether allopregnanolone and alphaxalone act through a common site of action. Results showed that either allopregnanolone or alphaxalone present a single-component enhancement of [3H]flunitrazepam binding with EC50 of 1.18 +/- 0.12 and 6.56 +/- 0.86 microM and Emax of 82.18 +/- 5.80 and 62.98 +/- 3.73%, respectively. Epipregnanolone behaved as a partial agonist of these steroid modulatory sites with EC50 of 0.49 +/- 0.15 microM and Emax 12.34 +/- 1.03%. Moreover, the addition of 16 microM epipregnanolone to either allopregnanolone or alphaxalone decreased EC50 values to 0.54 +/- 0.09 and 1.24 +/- 0.25 microM respectively, while Emax values were not significantly affected. On the other hand, additivity experiments disclosed that a maximal concentration (16 microM) of alphaxalone in the presence of allopregnanolone failed to enhance [3H]flunitrazepam binding in excess of that produced by allopregnanolone alone. Results indicate that not only allopregnanolone and alphaxalone act through a common site of action, but such site is highly stereospecific with regard to the neurosteroid spatial configuration.