Alcohol Enhances Responses to High Frequency Stimulation in Hippocampus from Transgenic Mice with Increased Astrocyte Expression of IL-6.

Recent studies show that alcohol exposure can induce glial production of neuroimmune factors in the CNS. Of these, IL-6 has gained attention because it is involved in a number of important physiological and pathophysiological processes that could be affected by alcohol-induced CNS production of IL-6, particularly under conditions of excessive alcohol use. For example, IL-6 has been shown to play a role in hippocampal behaviors and synaptic plasticity (long-term potentiation; LTP) associated with memory and learning. Surprisingly, in our in vitro studies of LTP at the Schaffer collateral to CA1 pyramidal neuron synapse in hippocampus from transgenic mice that express elevated levels of astrocyte produced IL-6 (TG), LTP was not altered by the increased levels of IL-6. However, exposure to acute alcohol revealed neuroadaptive changes that served to protect LTP against the alcohol-induced reduction of LTP observed in hippocampus from non-transgenic control mice (WT). Here we examined the induction phase of LTP to assess if presynaptic neuroadaptive changes occurred in the hippocampus of TG mice that contributed to the resistance of LTP to alcohol. Results are consistent with a role for IL-6-induced neuroadaptive effects on presynaptic mechanisms involved in transmitter release in the resistance of LTP to alcohol in hippocampus from the TG mice. These actions are important with respect to a role for IL-6 in physiological and pathophysiological processes in the CNS and in CNS actions of alcohol, especially when excessive alcohol used is comorbid with conditions associated with elevated levels of IL-6 in the CNS.

Transgenic mice with increased astrocyte expression of IL-6 show altered effects of acute ethanol on synaptic function.

A growing body of evidence has revealed that resident cells of the central nervous system (CNS), and particularly the glial cells, comprise a neuroimmune system that serves a number of functions in the normal CNS and during adverse conditions. Cells of the neuroimmune system regulate CNS functions through the production of signaling factors, referred to as neuroimmune factors. Recent studies show that ethanol can activate cells of the neuroimmune system, resulting in the elevated production of neuroimmune factors, including the cytokine interleukin-6 (IL-6). Here we analyzed the consequences of this CNS action of ethanol using transgenic mice that express elevated levels of IL-6 through increased astrocyte expression (IL-6-tg) to model the increased IL-6 expression that occurs with ethanol use. Results show that increased IL-6 expression induces neuroadaptive changes that alter the effects of ethanol. In hippocampal slices from non-transgenic (non-tg) littermate control mice, synaptically evoked dendritic field excitatory postsynaptic potential (fEPSP) and somatic population spike (PS) at the Schaffer collateral to CA1 pyramidal neuron synapse were reduced by acute ethanol (20 or 60 mM). In contrast, acute ethanol enhanced the fEPSP and PS in hippocampal slices from IL-6 tg mice. Long-term synaptic plasticity of the fEPSP (i.e., LTP) showed the expected dose-dependent reduction by acute ethanol in non-tg hippocampal slices, whereas LTP in the IL-6 tg hippocampal slices was resistant to this depressive effect of acute ethanol. Consistent with altered effects of acute ethanol on synaptic function in the IL-6 tg mice, EEG recordings showed a higher level of CNS activity in the IL-6 tg mice than in the non-tg mice during the period of withdrawal from an acute high dose of ethanol. These results suggest a potential role for neuroadaptive effects of ethanol-induced astrocyte production of IL-6 as a mediator or modulator of the actions of ethanol on the CNS, including persistent changes in CNS function that contribute to cognitive dysfunction and the development of alcohol dependence.

Neuronal medium that supports basic synaptic functions and activity of human neurons in vitro.

Human cell reprogramming technologies offer access to live human neurons from patients and provide a new alternative for modeling neurological disorders in vitro. Neural electrical activity is the essence of nervous system function in vivo. Therefore, we examined neuronal activity in media widely used to culture neurons. We found that classic basal media, as well as serum, impair action potential generation and synaptic communication. To overcome this problem, we designed a new neuronal medium (BrainPhys basal + serum-free supplements) in which we adjusted the concentrations of inorganic salts, neuroactive amino acids, and energetic substrates. We then tested that this medium adequately supports neuronal activity and survival of human neurons in culture. Long-term exposure to this physiological medium also improved the proportion of neurons that were synaptically active. The medium was designed to culture human neurons but also proved adequate for rodent neurons. The improvement in BrainPhys basal medium to support neurophysiological activity is an important step toward reducing the gap between brain physiological conditions in vivo and neuronal models in vitro.

Differences in the magnitude of long-term potentiation produced by theta burst and high frequency stimulation protocols matched in stimulus number.

Theta-burst stimulation (TBS: four pulses at 100 Hz repeated with 200 ms inter-burst-intervals) and another commonly used high-frequency stimulation protocol (HFS: 1 s burst of equally spaced pulses at 100 Hz) were compared for the magnitude of LTP produced in rat hippocampal slices. The total number of pulses applied during tetanus (TET) was either 40, 100, 200, or 300. In a conventional analysis of the last 10 min of the post-TET period, a two-way ANOVA revealed no difference either in LTP of the field excitatory post-synaptic potential (fEPSP) between TBS and HFS or differences across pulse number at 40, 100, or 200 pulses. At 300 pulses, there was a significant main effect by pulse number but not by protocol. A linear regression analysis showed that stimulation protocol accounted for only about 10% of the change in magnitude while pulse number contributed to 30% of the change. However, when an extended analysis of the same data was performed across the entire post-TET period with a repeated-measure ANOVA, a small but persistent increase in TBS over HFS at 200 pulses was significant. A difference between TBS and HFS at 300 pulses that occurred only during the early phase of LTP was also significant. These results suggest that, over a range of stimuli, the number of pulses in an induction protocol, rather than the pattern of stimulation, determines the magnitude of late phase LTP, while TBS produces greater potentiation than HFS in the early phase of LTP with higher TET number.

A focal adhesion-like process underlies induction of long-term potentiation in the Schaffer collateral-CA1 region of the hippocampus.

In the series of experiments reported here we provide evidence that a focal adhesion-like process underlies the induction of long-term potentiation (LTP) in the Schaffer Collateral-CA1 projection in the hippocampus. Here we show that an integrin binding peptide (RGD) impairs induction of Schaffer Collateral-CA1 LTP in hippocampal slice preparations in vitro. The heparin-binding peptide that binds heparan sulfate proteoglycan (HSPG) and blocks the formation of focal adhesions also impairs induction of LTP. Either the integrin-binding peptide or heparin-binding peptide reduces LTP partially. However, when the two peptides were administered simultaneously, there was no LTP 1 hour after induction. This indicates that these two molecules might function together and that a focal adhesion-like process might be involved in the induction of LTP. Additionally,we report that the RGD effect on LTP is time dependent and occurs only in the first few minutes following LTP induction, that the binding of the RGD peptide in CA1 stratum radiatum increases after LTP induction and that this increased binding depends on Ca(2+). Using electron microscopy we show that integrins are present in synapses.

An integrin binding peptide reduces rat CA1 hippocampal long-term potentiation during the first few minutes following theta burst stimulation.

The integrin binding peptide GRGDSP was tested on Schaffer to CA1 (Sch-CA1) long-term potentiation (LTP) in the rat hippocampal slice. Experiments in which GRGDSP was bath applied for 50 min, beginning 10 min before theta burst stimulation (TBS), reduced LTP of the field excitatory post synaptic potential in a concentration dependent manner, with 250 microM producing a significant decrease. However, LTP was not affected when 250 microM GRGDSP was applied 30 min post-TBS, nor when applied as soon as 5 min post-TBS. When 250 microM GRGDSP was applied for only 10 min pre- to 5 min post-TBS, this brief application was sufficient in reducing LTP similar to the extended 50 min application. We conclude that RGD-binding integrins involved in LTP are only momentarily responsive to peptide-mediated antagonism in the first few minutes following TBS.