No evidence for role of extracellular choline-acetyltransferase in generation of gamma oscillations in rat hippocampal slices in vitro.

Acetylcholine (ACh) is well known to induce persistent γ-oscillations in the hippocampus when applied together with physostigmine, an inhibitor of the ACh degrading enzyme acetylcholinesterase (AChE). Here we report that physostigmine alone can also dose-dependently induce γ-oscillations in rat hippocampal slices. We hypothesized that this effect was due to the presence of choline in the extracellular space and that this choline is taken up into cholinergic fibers where it is converted to ACh by the enzyme choline-acetyltransferase (ChAT). Release of ACh from cholinergic fibers in turn may then induce γ-oscillations. We therefore tested the effects of the choline uptake inhibitor hemicholinium-3 (HC-3) on persistent γ-oscillations either induced by physostigmine alone or by co-application of ACh and physostigmine. We found that HC-3 itself did not induce γ-oscillations and also did not prevent physostigmine-induced γ-oscillation while washout of physostigmine and ACh-induced γ-oscillations was accelerated. It was recently reported that ChAT might also be present in the extracellular space (Vijayaraghavan et al., 2013). Here we show that the effect of physostigmine was prevented by the ChAT inhibitor (2-benzoylethyl)-trimethylammonium iodide (BETA) which could indicate extracellular synthesis of ACh. However, when we tested for effects of extracellularly applied acetyl-CoA, a substrate of ChAT for synthesis of ACh, physostigmine-induced γ-oscillations were attenuated. Together, these findings do not support the idea that ACh can be synthesized by an extracellularly located ChAT.

Adrenergic modulation of sharp wave-ripple activity in rat hippocampal slices.

Norepinephrine (NE) has been shown to facilitate learning and memory by modulating synaptic plasticity in the hippocampus in vivo. During memory consolidation, transiently stored information is transferred from the hippocampus into the cortical mantle. This process is believed to depend on the generation of sharp wave-ripple complexes (SPW-Rs), during which previously stored information might be replayed. Here, we used rat hippocampal slices to investigate neuromodulatory effects of NE on SPW-Rs, induced by a standard long-term potentiation (LTP) protocol, in the CA3 and CA1. NE (10-50 µM) dose-dependently and reversibly suppressed the generation of SPW-Rs via activation of α1 adrenoreceptors, as indicated by the similar effects of phenylephrine (100 µM). In contrast, the unspecific ß adrenoreceptor agonist isoproterenol (2 µM) significantly increased the incidence of SPW-Rs. Furthermore, ß adrenoreceptor activation significantly facilitated induction of both LTP and SPW-Rs within the CA3 network. Suppression of SPW-Rs by NE was associated with a moderate hyperpolarization in the majority of CA3 pyramidal cells and with a reduction of presynaptic Ca(2+) uptake in the stratum radiatum. This was indicated by activity-dependent changes in [Ca(2+) ](o) and Ca(2+) fluorescence signals, by changes in the paired pulse ratio of evoked EPSPs and by analysis of the coefficient of variance. In the presence of NE, repeated high frequency stimulation (high-frequency stimulation (HFS)) failed to induce SPW-Rs, although SPW-Rs appeared following washout of NE. Together, our data indicate that the NE-mediated suppression of hippocampal SPW-Rs depends on α1 adrenoreceptor activation, while their expression and activity-dependent induction is facilitated via ß1-adrenoreceptors.

Nonspecific effects of the gap junction blocker mefloquine on fast hippocampal network oscillations in the adult rat in vitro.

It has been suggested that gap junctions are involved in the synchronization during high frequency oscillations as observed during sharp wave-ripple complexes (SPW-Rs) and during recurrent epileptiform discharges (REDs). Ripple oscillations during SPW-Rs, possibly involved in memory replay and memory consolidation, reach frequencies of up to 200 Hz while ripple oscillations during REDs display frequencies up to 500 Hz. These fast oscillations may be synchronized by intercellular interactions through gap junctions. In area CA3, connexin 36 (Cx36) proteins are present and potentially sensitive to mefloquine. Here, we used hippocampal slices of adult rats to investigate the effects of mefloquine, which blocks Cx36, Cx43 and Cx50 gap junctions on both SPW-Rs and REDs. SPW-Rs were induced by high frequency stimulation in the CA3 region while REDs were recorded in the presence of the GABA(A) receptor blocker bicuculline (5 µM). Both, SPW-Rs and REDs were blocked by the gap junction blocker carbenoxolone. Mefloquine (50 µM), which did not affect stimulus-induced responses in area CA3, neither changed SPW-Rs nor superimposed ripple oscillations. During REDs, 25 and 50 µM mefloquine exerted only minor effects on the expression of REDs but significantly reduced the amplitude of superimposed ripples by ∼17 and ∼54%, respectively. Intracellular recordings of CA3 pyramidal cells revealed that mefloquine did not change their resting membrane potential and input resistance but significantly increased the afterhyperpolarization following evoked action potentials (APs) resulting in reduced probability of AP firing during depolarizing current injection. Similarly, mefloquine caused a reduction in AP generation during REDs. Together, our data suggest that mefloquine depressed RED-related ripple oscillations by reducing high frequency discharges and not necessarily by blocking electrical coupling.

C-type natriuretic peptide decreases hippocampal network oscillations in adult rats in vitro.

C-type natriuretic peptide (CNP) is an abundant neuropeptide in the human brain and the cerebrospinal fluid. CNP is involved in anxiogenesis and exerts its effects through the natriuretic peptide receptor B (NPR-B), which is expressed in the hippocampus. Hippocampal network oscillations of distinct frequency bands like gamma (gamma)-oscillations and sharp wave-ripple complexes (SPW-Rs) are likely involved in various cognitive functions such as the storage of information and memory consolidation in vivo. Here, we tested the effects of CNP on distinct network oscillations in horizontal slices of rat hippocampus. We found that CNP decreased the power of stimulus- and ACh/physostigmine-induced gamma-oscillations. In contrast to stimulus-induced gamma-oscillations, CNP increased the frequency of ACh-induced, persistent network oscillations. Moreover, the peptide hormone reduced the incidence of LTP-associated SPW-Rs in area CA3 and CA1. Immunohistochemistry indicates that the peptide binds to receptors expressed on a subset of GAD 65-67-immunopositive cells in addition to binding to principal and other presumably non-neuronal cells. CNP caused a hyperpolarization of CA3 neurons increased their input resistance and decreased inhibitory conductance. Together, our data suggest that the effects of CNP on synchronized hippocampal network oscillations might involve effects on hippocampal interneurons.

Modulation of in vitro and in vivo T-cell responses by transferrin-gallium and gallium nitrate.

Gallium is a group IIIa metal that has efficacy in the therapy of malignant disorders such as lymphoma and urothelial tract tumors. Preclinical studies also indicate a role for gallium in autoimmune disorders, suggesting that gallium is able to modulate T-cell immune reactivity. The purpose of this study was to examine the in vitro and in vivo immunomodulatory action of gallium on T-cell function. Since gallium binds to transferrin in vivo, in vitro studies evaluated the effect of transferrin-gallium (Tf-Ga) on human T cells. Tf-Ga inhibited the mitogen-induced proliferative response of peripheral blood mononuclear cells (PBMC) in a dose-dependent fashion. Alloantigen-induced proliferation was also potently suppressed when evaluated in a mixed lymphocyte culture assay. Tf-Ga affected a significant reduction in the density of IL-2 receptors on activated T cells and a slight reduction in the number of CD3+/CD25+ T cells in PHA-stimulated cultures. Neither secretion of interleukin-2 (IL-2) nor the induction of IL-2-stimulated lymphokine-activated killer activity, however, was inhibited by Tf-Ga. Tf-Ga produced significant upregulation of the transferrin receptor (CD71) in T cells as determined by flow cytometric analysis and northern blot assay, but did not affect the percentage of CD3+/ CD71+ T cells after mitogen stimulation. To assess the in vivo effects of gallium on alloreactive T cells, we evaluated the immunosuppressive effect of gallium in a murine model of graft-versus-host disease (GVHD). Administration of gallium significantly prolonged survival in mice undergoing severe GVHD, suggesting that gallium can ameliorate GVH reactivity. Collectively, these data demonstrate that, at clinically achievable concentrations, Tf-Ga potently inhibits T-cell activation and that this immunosuppressive property of gallium may be of adjunctive therapeutic value in the management of disorders characterized by the presence of autoreactive or alloreactive T-cell populations.

Modulation of transferrin receptor mRNA by transferrin-gallium in human myeloid HL60 and lymphoid CCRF-CEM leukaemic cells.

Gallium binds to the iron transport protein transferrin (Tf), is incorporated into cells through transferrin receptors (TfR) and inhibits iron-dependent DNA synthesis. Since cellular TfR expression is tightly regulated by the availability of iron, we investigated the effects of transferrin-gallium (Tf-Ga) on TfR mRNA levels in myeloid HL60 and lymphoid CCRF-CEM cells. In HL60 cells, Tf-Ga increased TfR mRNA levels in a dose-dependent fashion. This increase in TfR mRNA was blocked by Tf-Fe and by cycloheximide. Analysis of the rate of mRNA decay in the presence of actinomycin D revealed that the half-life of TfR mRNA was increased in HL60 cells incubated with Tf-Ga. The rate of transcription of TfR mRNA was not increased by Tf-Ga. In contrast with HL60 cells, CCRF-CEM cells displayed a decrease in the level of TfR mRNA after incubation with Tf-Ga. Tf-Ga inhibited iron uptake in both HL60 and CCRF-CEM cells but increased the level of TfR mRNA only in HL60 cells, suggesting that the Tf-Ga induction of TfR mRNA was not solely due to inhibition of cellular iron uptake. At growth-inhibitory concentrations, Tf-Ga increased the TfR mRNA level in HL60 cells but decreased it in CCRF-CEM cells. Our studies suggest that in HL60 cells, gallium regulates TfR expression at the post-transcriptional level by mechanisms which require de novo protein synthesis and involve interaction with iron. The divergent effects of Tf-Ga on TfR mRNA in myeloid HL60 and lymphoid CCRF-CEM cells suggest that differences exist in the regulation of TfR expression between these two cell types.

Opposing effects of retinoic acid and dexamethasone on cellular retinol-binding protein ribonucleic acid levels in the rat.

Cellular retinol-binding protein (CRBP) is a potential mediator of vitamin A action. To determine whether retinoic acid and dexamethasone administration, alone and in combination, influence CRBP gene expression, adult female vitamin A-sufficient Sprague-Dawley rats randomly received 1) all-trans retinoic acid (100 micrograms) by intragastric intubation, 2) dexamethasone (2 micrograms/g BW) by ip injection, or 3) both all-trans retinoic acid and dexamethasone in the same doses. Control animals received either cottonseed oil by intragastric intubation or saline by ip injection. Six hours after treatment, lung and liver tissue were collected for Northern blot analysis with the radiolabeled cDNA specific for rat CRBP. Retinoic acid administration increased the amount of lung CRBP mRNA only, whereas dexamethasone decreased both lung and liver CRBP mRNA abundance. In animals treated with both retinoic acid and dexamethasone, CRBP mRNA abundance was also reduced. We conclude that CRBP gene expression can be modulated by both retinoic acid and dexamethasone in the vitamin A-sufficient animal. In the whole animal, our findings indicate that dexamethasone not only represses CRBP gene expression, but also opposes the effect of retinoic acid.

Early effects of retinol and retinoic acid on protein synthesis in retinol deficient rat testes.

When an [35S] labeled mixture of methionine and cysteine was injected intratesticularly into retinol-deficient rats, two hours later more than 980 cytosolic proteins were detected by computer aided two dimensional gel electrophoresis. Furthermore, two hours after oral refeeding retinyl acetate as the source of retinol to retinol deficient rats, synthesis of 286 proteins was inhibited and that of 101 proteins was activated. Refeeding with retinoic acid leads in two hours to even higher inhibition of protein synthesis and the labeling patterns of proteins are not identical when compared to retinol refed rats. The results indicate that retinol or retinoic acid quickly influence expression of many proteins and suggest that retinol action in the testes is not identical to that of retinoic acid.