Synaptic transmission is required for initiation of long-term potentiation

Multiple sclerosis (MS) is a progressive inflammatory autoimmune disease that is characterized by demyelination and axonal damage in the nervous system. One obvious consequence is a cumulative loss of muscle control. However, cognitive dysfunction affects roughly half of MS sufferers, sometimes already early in the disease course. Although long-term (remote) memory is typically unaffected, the ability to form new declarative memories becomes compromised. A major structure for the encoding of new declarative memories is the hippocampus. Encoding is believed to be mediated by synaptic plasticity in the form of long-term potentiation (LTP) and long-term depression (LTD) of synaptic strength. Here, in an animal model of MS we explored whether disease symptoms are accompanied by a loss of functional neuronal integrity, synaptic plasticity, or hippocampus-dependent learning ability. In mice that developed MOG_35–55-induced experimental autoimmune encephalomyelitis (EAE), passive properties of CA1 pyramidal neurons were unaffected, although the ability to fire action potentials became reduced in the late phase of EAE. LTP remained normal in the early phase of MOG_35–55-induced EAE. However, in the late phase, LTP was impaired and LTP-related spatial memory was impaired. In contrast, LTD and hippocampus-dependent object recognition memory were unaffected. These data suggest that in an animal model of MS hippocampal function becomes compromised as the disease progresses.

Environmental enrichment (EE), which mimics the wealth of sensory, motor and cognitive stimuli that arise through intense interactions with the ambient environment, results in enhanced hippocampal long-term potentiation (LTP) and spatial learning. A key molecular factor in the mediation of these changes is the brain-derived neurotrophic factor (BDNF). One of the downstream cascades that is activated by BDNF is the cascade linked to the small GTPase, Ras, that triggers mitogen-activated protein kinase (MAPK) activity and is part of the cAMP response element-binding protein (CREB) pathway that can lead to synaptic restructuring to support LTP. Here, we explored whether persistent activation of Ras in neurons further enhances LTP following EE of rodents. Immediately following weaning, transgenic mice that expressed constitutively activated neuronal Ras, or their wildtype (Wt) littermates, underwent 3 weeks of constant EE. In the absence of EE, theta burst stimulation (TBS) evoked LTP in the CA1 region of transgenic mice that was not significantly different from LTP in Wts. After 3 weeks of EE, hippocampal LTP was improved in Wt mice. Enriched transgenic mice showed an equivalent level of LTP to enriched Wts, but it was not significantly different from non-enriched synRas controls. Western blot analysis performed after a pull-down assay showed that non-enriched transgenic mice expressed higher Ras activity compared to non-enriched Wts. Following EE, Ras activity was reduced in transgenics to levels detected in Wts. These results show that constitutive activation of Ras does not mimic the effects of EE on LTP. In addition, EE results in an equivalent enhancement of LTP transgenics and Wts, coupled with a decrease in Ras activity to Wt levels. This suggests that permanent activation of Ras in neurons of synRas animals following EE results in an altered feedback regulation of endogenous Ras activity that is not a key factor in LTP enhancements. The maintenance of Ras within a physiological range may thus be required for the optimization of LTP in the hippocampus.

Insulin is best known for its role in peripheral glucose homeostasis. Less studied, but not less important, is its role in the central nervous system. Insulin and its receptor are located in the central nervous system and are both implicated in neuronal survival and synaptic plasticity. Interestingly, over the past few years it has become evident that the effects of insulin, on neuronal survival and synaptic plasticity, are mediated by a common signal transduction cascade, which has been identified as “the PI3K route”. This route has turned out to be a major integrator of insulin signaling in the brain. A pronounced feature of this insulin-activated route is that it promotes survival by directly inactivating the pro-apoptotic machinery. Interestingly, it is this same route that is required for the induction of long-term potentiation and depression, basic processes underlying learning and memory. This leads to the hypothesis that the PI3K route forms a direct link between learning and memory and neuronal survival. The implications of this hypothesis are far reaching, since it provides an explanation why insulin has beneficial effects on learning and memory and how synaptic activity can prevent cellular degeneration. Applying this knowledge may provide novel therapeutic approaches in the treatment of neurodegenerative diseases such as Alzheimer's disease.

The mechanism of ATP-induced long-term potentiation (LTP) was studied pharmacologically using guinea-pig hippocampal slices. LTP, induced in CA1 neurons by 10 min application of 10 μM ATP, was blocked by co-application of the N-methyl-D-aspartate (NMDA) receptor antagonist, D,L-2-amino-5-phosphonovalerate (5 or 50 μM). In ATP-induced LTP, the delivery of test synaptic inputs (once every 20 s) to CA1 neurons could be replaced by co-application of NMDA (100 nM) during ATP perfusion. These results suggest that, in CA1 neurons, a co-operative effect between extracellular ATP and activation of NMDA receptors is required to trigger the process involved in ATP-induced LTP. In addition, ATP-induced LTP was blocked by co-application of an ecto-protein kinase inhibitor, K-252b (40 or 200 nM), whereas a P2X purinoceptor antagonist, pyridoxal phosphate 6-azophenyl-2′,4′-disulfonic acid 4-sodium (50 μM), or a P2Y purinoceptor antagonist, basilen blue (10 μM), had no effect.

The results of the present study, therefore, indicate that the mechanisms of ATP-induced LTP involve the modulation of NMDA receptors/Ca²⁺ channels and the phosphorylation of extracellular domains of synaptic membrane proteins, one of which could be the NMDA receptor/Ca²⁺ channel.

The capacity to sense changes in the concentrations of extracellular ions is an important function in several cell types. For example, hormone secretion by parathyroid cells and thyroid C-cells is primarily regulated by the level of extracellular ionized calcium (Ca²⁺). The G-protein-coupled receptor that mediates the parathyroid cell response to Ca²⁺ has been cloned and we have used in situ hybridization to map calcium receptor (CaR) mRNA expression in the adult rat brain. Cells expressing CaR mRNA were present in many areas of the brain suggesting that a variety of cell types express the CaR. Particularly high numbers of CaR expressing cells were found in regions associated with the regulation of fluid and mineral homeostasis, most notably the subfornical organ. These data suggest that the capacity to detect changes in extracellular Ca²⁺ concentrations may have important functional consequences in several neural systems.

l-AP4, an agonist at the metabotropic glutamate receptors 4, 6, 7, 8 and 9 produced a selective spatial learning impairment in a water maze as well as in an 8-arm maze task when injected i.c.v. (5 gl of a 80 mM solution), a dose previously reported to block consolidation of long-term potentiation in vivo. Acquisition and recall of the spatial water-maze task, as measured by escape latency and quadrant bias, respectively, were impaired, whereas swim speed was not affected. In contrast, ability to perform a non-spatial control task was not impaired; latency to reach a visible escape platform was not delayed in l-AP4-treated animals. No behavioral difference was visible in the open field. MAP4, an antagonist of mGluRs mediating l-AP4 induced reduction of transmitter release, when administered pretraining i.c.v. (5 μl of an 80 mM solution) did not affect motor activity in the open field test but did impair learning of both spatial tasks. In addition, swim speed was increased. However, injecting L-AP4 and MAP4 in combination at equimolar concentrations had no effect on learning in both spatial tasks or on swim speed in the water maze. Neither latency in the visible-platform test nor behavior in the open field was affected. We conclude that l-AP4 sensitive metabotropic glutamate receptors play a selective role in learning and memory formation of the rat.