Modulation of long-term potentiation in CA1 region of mouse hippocampal brain slices by GABAA receptor benzodiazepine site ligands.

Enhancement of GABAA receptor function with benzodiazepine (BZ) site agonists can disrupt memory formation and hippocampal synaptic plasticity. To investigate this further the effects of the agonist, flunitrazepam, were contrasted with that of the inverse agonist, methyl-6,7-dimethoxy-4-ethyl-beta-carboline-3-carboxylate (DMCM), on NMDA-dependent LTP induction in the CA1 region of mouse hippocampus. Under control conditions, a priming stimulus (10 stimuli at 100 Hz) potentiated e.p.s.p. slopes by 198%, and subsequent burst stimuli (4 x 10 events at 100 Hz every 20 sec) by 306%. This potentiation was blocked by the non-competitive NMDA receptor antagonist MK-801 and the glycine site antagonist L-701,324. Flunitrazepam (1 microM) alone caused a slight but significant reduction in e.p.s.p.s to 83% of control, suppressed LTP induced by priming stimuli (133%) and burst stimuli (188%), but not that induced by sustained high-frequency stimulation (2 x 100 events at 100 Hz, 20 sec apart). The suppression of LTP induction by flunitrazepam was blocked by the benzodiazepine site antagonist flumazenil. In contrast, the inverse agonist DMCM (100 nM) potentiated LTP formed by both priming (to 283%) and burst stimuli (to 477%). This was associated with an enhancement of paired pulse facilitation during the induction phase and the subsequent appearance of paroxysmal burst discharges. Therefore, in addition to improvements in learning and memory as a result of improved vigilance, benzodiazepine inverse agonists can have direct effects on synaptic processes thought to contribute to memory formation.

Localization of GABA(B) (R1) receptors in the rat hippocampus by immunocytochemistry and high resolution autoradiography, with specific reference to its localization in identified hippocampal interneuron subpopulations.

Immunocytochemical and autoradiographic methods were used to localize the GABA(B) receptor in the normal rat hippocampus. GABA(B) receptor 1-like immunoreactivity (GBR1-LI) was most intense in presumed GABAergic interneurons of all hippocampal subregions. It was also present throughout the hippocampal neuropil, where it was most intense in the dendritic strata of the dentate gyrus, which are innervated by the perforant pathway and inhibitory dentate hilar cells, and in strata oriens and radiatum of area CA3. The dendritic regions of area CA1 exhibited less GBR1-LI than area CA3. GBR1-LI was detectable in the somata of CA1 pyramidal cells, but was minimal or undetectable within the somata of dentate granule cells and CA3 pyramidal cells. GBR1-LI was similarly minimal in the dentate hilar neuropil, and in stratum lucidum, the two regions that contain granule cell axons and terminals. Nor was GBR1-LI detectable in the inhibitory basket cell fiber systems that surround hippocampal principal cell somata. Fluorescence co-localization studies indicated that significant proportions of interneurons expressing somatostatin, neuropeptide Y, cholecystokinin, calbindin, or calretinin also expressed GBR1-LI constitutively. Conversely, parvalbumin-positive GABAergic basket cells of the dentate gyrus and hippocampus, which form GABA(A) receptor-mediated inhibitory axo-somatic synapses, rarely contained detectable GBR1-LI. High resolution autoradiography with the GABA(B) receptor antagonist CGP 62349 revealed a close correspondence between receptor ligand binding and GBR1-LI, with several notable exceptions. Ligand binding closely matched GBR1-LI throughout the hippocampal, cortical, thalamic, and cerebellar neuropil. However, the hippocampal interneuron somata and dendrites that exhibited the most intense GBR1-LI, and the GBR1-positive somata of CA1 pyramidal cells, did not exhibit a similar density of [3H]-CGP 62349 binding. These data clarify the relationship between immunocytochemically identified receptor protein and potentially functional receptors, indicating that GBR1-LI reflects both non-functional cytoplasmic GBR1 and the ligand-bindable form of the protein, both before dimerization with GBR2 and after translocation to functional sites within cells. The staining and binding patterns further suggest that GBR1 is constitutively expressed in specific neuronal populations, and may exist in higher concentration in the axons of inhibitory hippocampal pathways that innervate dendritic zones, than in axo-somatic inhibitory terminals. Whether GBR1 is inducible in cells that contain GBR1 mRNA, but no detectable constitutive protein, remains to be determined in experimental studies.

Expression of B1 and B2 bradykinin receptor mRNA and their functional roles in sympathetic ganglia and sensory dorsal root ganglia neurones from wild-type and B2 receptor knockout mice.

Bradykinin has been implicated in nociception and inflammation. To examine the relative significance of B1 and B2 bradykinin receptor subtypes in sympathetic and sensory ganglia, the electrophysiological effects of bradykinin analogues and the expression of receptor subtype mRNA were examined in wild-type and "B2 knockout" mice from which the B2 receptor gene had been deleted. In wild-type mice the B2 receptor agonist bradykinin depolarized superior cervical ganglia (SCG) and activated inward currents in dorsal root ganglia (DRG) neurones. Responses to the B1 receptor agonist, [des-Arg10]-kallidin, were seen only in SCG that had been pre-treated with interleukins and the peptidase inhibitor captopril, but not in DRG neurones. The up-regulation of responses to [des-Arg10]-kallidin and substance P were blocked by indomethacin and, thus, were dependent upon cyclo-oxygenase activity. The effects of bradykinin were abolished in SCG and DRG's from B2 knockout mice and this was correlated with the absence of B2 receptor mRNA in ganglia from these animals. However, despite the presence of B1 receptor mRNA in interleukin treated SCG from B2 knockout mice, no depolarizing effects of the B1 receptor agonist [des-Arg10]-kallidin were observed. The successful elimination of bradykinin responses and B2 mRNA in sympathetic and sensory ganglia from B2 knockout mice, confirms that B2 receptors are the predominant functional bradykinin receptor subtype in these tissues and that B1 receptor mRNA is expressed in both sympathetic and sensory ganglia from these animals.

Mechanisms contributing to the deficits in hippocampal synaptic plasticity in mice lacking amyloid precursor protein.

Abnormal processing of amyloid precursor protein (APP), in particular the generation of beta-amyloid (Abeta) peptides, has been implicated in the pathogenesis of Alzheimer's disease. This study examined the consequences of deleting the APP gene on hippocampal synaptic plasticity, and upon the biophysical properties of morphologically identified neurones in APP-null mice. The hippocampus of APP-null mice had a characteristic increase in gliosis throughout the CA1 region and a disruption of staining for the dendritic marker MAP2 and the presynaptic marker synaptophysin. The disruption of MAP2 staining was associated with a significant reduction in overall dendritic length and projection depth of biocytin labeled CA1 neurones. In two groups of APP-null mice that were examined at 8-12 months, and 20-24 months of age, there was an impairment in the formation of long-term potentiation (LTP) in the CA1 region compared to isogenic age matched controls. This LTP deficit was not associated with an alteration in the amplitude of EPSPs at low stimulus frequencies (0.033 Hz) or facilitation during a 100 Hz stimulus train, but was associated with a reduction in post-tetanic potentiation. Paired-pulse depression of GABA-mediated inhibitory post-synaptic currents was also attenuated in APP-null mice. These data demonstrate that the impaired synaptic plasticity in APP deficient mice is associated with abnormal neuronal morphology and synaptic function within the hippocampus.

Age-related cognitive deficits, impaired long-term potentiation and reduction in synaptic marker density in mice lacking the beta-amyloid precursor protein.

Mutations in the beta-amyloid precursor protein are strongly associated with some cases of familial Alzheimer's disease. The normal physiological role of beta-amyloid precursor protein in the brain was evaluated in a cross-sectional analysis of mice deficient in beta-amyloid precursor protein. Compared with wild-type control mice the beta-amyloid precursor protein-null mice developed age-dependent deficits in cognitive function and also had impairments in long-term potentiation. In addition, the brains of the beta-amyloid precursor protein-null mice had marked reactive gliosis in many areas, especially in the cortex and hippocampus. A subpopulation of mice (n = 15) died prematurely (between three and 18 months of age). Analysis of another six mice from the same population that were showing weight loss and hypolocomotor activity exhibited a marked reactive gliosis as detected by immunoreactivity for glial fibrillary acidic protein and a profound loss of immunoreactivities for the presynaptic terminal vesicle marker proteins synaptophysin and synapsin and the dendritic marker microtubule-associated protein-2 in many brain areas, but most predominantly in the cortex and hippocampus. These results suggest that normal beta-amyloid precursor protein may serve an essential role in the maintenance of synaptic function during ageing. A compromise of this function of the beta-amyloid precursor protein may contribute to the progression of the memory decline and the neurodegenerative changes seen in Alzheimer's disease.

Bradykinin receptors in mouse and rat isolated superior cervical ganglia.

1. The ability of bradykinin and its analogues to depolarize rat and mouse superior cervical ganglia was studied by use of in vitro grease-gap recording techniques, and the ability of antagonists selective for bradykinin receptor subtypes to block their effects was examined. 2. Bradykinin (3 microM) depolarized ganglia from both species, although the magnitude of the maximal response was less in mouse (15 +/- 5%, n = 7) than rat tissue (33 +/- 6%, n = 7), relative to muscarine (1 microM). 3. Interleukin 1 beta (30 u ml-1 for 18 h at 37 degrees C) increased the depolarization caused by bradykinin (3 microM) in mouse ganglia from 15% to 54% (P < 0.001, n = 12). Responses to the B1 receptor agonist, [des-Arg10]-kallidin (3 microM) were similarly potentiated but this was only detected after inhibition of peptidase activity with 10 microM captopril (4% to 35%, n = 5). 4. In ganglia from both species the rank order of agonist potency was bradykinin = [Lys0]-bradykinin >> [des-Arg10]-kallidin. However, like responses to [des-Arg10]-kallidin in mouse tissue, both the potency of bradykinin and the maximal depolarization achieved (EC50 = 912 nM; 80%, n = 11) was enhanced following inhibition of angiotensin converting enzyme with 10 microM captopril (EC50 = 50 nM; 135%, n = 4). 5. Responses to bradykinin were selectively antagonized by the B2 receptor antagonist, Hoe 140 but not by the B1 antagonist, [Leu8]-bradykinin1-8. From Schild analysis the pA2 value for Hoe 140 in mouse tissue was 9.65, although the slope of the regression line was significantly greater than unity, indicating non-competitive kinetics (slope = 1.88 +/- 0.18, n = 9). The depolarization caused by [Lys0]-bradykinin was also antagonized by Hoe 140 (3 nM).6. Thus the predominant bradykinin receptor in mouse superior cervical ganglia is compatible with a B2 subtype. Furthermore the depolarizations caused by B1 and B2 agonists in this tissue can be increased following exposure to interleukin l beta, and by blocking peptide degradation with captopril.

Antagonism of the effects of (+)-PD 128907 on midbrain dopamine neurones in rat brain slices by a selective D2 receptor antagonist L-741,626.

1. The ability of PD 128907 to activate dopamine receptors in the ventral tegmental area, substantia nigra pars compacta, and striatum was investigated by use of in vitro electrophysiological recording and fast cyclic voltammetry. The affinity of a novel D2 selective antagonist L-741,626 for receptors activated by this agonist was measured to determine if its effects were mediated by D2 or D3 receptors. 2. The active (+) enantiomer of PD 128907 bound with high affinity and selectivity to rat D3 dopamine receptors. The Ki values for (+)-PD 128907 were 620 nM at D2, 1 nM at D3 and 720 nM at D4 receptors. 3. (+)-PD 128907 inhibited cell firing in both the ventral tegmental area and substantia nigra pars compacta with EC50 values of 33 nM (pEC50 = 7.48 +/- 0.10, n = 10) and 38 nM (pEC50 = 7.42 +/- 0.15, n = 5), respectively. No effects of (+)-PD 128907 (100 nM) were observed on glutamate or GABA-mediated synaptic potentials elicited by focal bipolar stimulation. 4. L-741,626 antagonized these effects of (+)-PD 128907 in a concentration-dependent and surmountable manner with an affinity, determined from Schild analysis, of 20 nM (pKB = 7.71 +/- 0.14) in the ventral tegmental area and 11 nM (pKB = 7.95 +/- 0.18) in the substantia nigra pars compacta. 5. (+)-PD 128907 also inhibited dopamine release in the caudate-putamen with an EC50 of 66 nM (n = 5). The affinity of L-741,626 for these nerve terminal autoreceptors (pKB = 7.71 +/- 0.06; = 20 nM) was identical to that observed on midbrain dopamine neurones. 6. These data demonstrate that the D3 receptor ligand (+)-PD 128907 is a potent agonist on rat midbrain dopamine neurones. However, its lack of regional selectivity, and the high affinity of the selective D2 receptor antagonist L-741,626 for receptors activated by (+)-PD 128907, was more consistent with an action on D2 autoreceptors rather than upon a D3 dopamine receptor subtype.

Pharmacology of tachykinin receptors on neurones in the ventral tegmental area of rat brain slices.

The pharmacology of tachykinin receptors within the ventral tegmental area of rat brain slices was studied using in vitro electrophysiological techniques. The selective tachykinin NK3 receptor agonist senktide (100 nM) increased the action potential firing rate from 1.9 to 3.9 Hz in 70% of spontaneously active cells tested (n = 27). Senktide was the most potent agonist tested with an EC50 of 4 nM. In contrast the NK1 receptor agonists substance P-O-methyl ester (100-300 nM) or GR 73632 (1 microM) were inactive at the concentrations tested. Responses to neurokinin B (EC50 = 32 nM) were not blocked by the tachykinin NK1 receptor antagonist CP 99,994 (1 microM) nor by the tachykinin NK2 receptor antagonist SR 48968 (300 nM). Similarly responses to the tachykinin NK2 receptor agonist beta-[Ala8]neurokinin A-(4-10) (EC50 = 427 nM) were not antagonised by the tachykinin NK2 receptor antagonist SR 48968 (300 nM) and thus were likely to be due to the activation of tachykinin NK3 receptors. These data demonstrate that NK3, and not NK1 or NK2 receptors, mediate the principal excitatory effects of exogenously applied tachykinin receptor agonists on dopamine neurones within the rat ventral tegmental area.