Gonzalo Sánchez

Role of hippocampal M1 and M4 muscarinic receptor subtypes in memory consolidation in the rat

Muscarinic receptors in the hippocampus are relevant to learning and memory, but the role of each subtype is poorly understood. Muscarinic toxins (MTs) from Dendroaspis snakes venom are selective for muscarinic receptor subtypes. MT2, a selective agonist for M(1) receptors, given into the hippocampus immediately after training, improved memory consolidation of an inhibitory avoidance task in rats, whereas the antagonist pirenzepine was amnestic, supporting a facilitatory role of M(1) receptors. Instead, MT3, a selective antagonist at M(4) receptors, caused amnesia. Neither M(1) nor M(4) receptor appeared involved in habituation to a new environment. Thus, our results suggest that memory consolidation of an inhibitory avoidance task in the rat involves the participation of both M(1) and M(4) hippocampal receptors, with a positive modulatory role.

Effects of muscarinic toxins MT1 and MT2 from green mamba on different muscarinic cholinoceptors.

MT1 and MT2, polypeptides from green mamba venom, known to bind to muscarinic cholinoceptors, behave like muscarinic agonists in an inhibitory avoidance task in rats. We have further characterised their functional effects using different preparations. MT1 and MT2 behaved like relatively selective muscarinic M1 receptor agonists in rabbit vas deferens, but their effects were not reversed by washing or prevented by muscarinic antagonists, although allosteric modulators altered responses to MT1. Radioligand binding experiments indicated that both toxins irreversibly inhibited [3H]N-methylscopolamine binding to cloned muscarinic M1 and M4 receptors, and reduced binding to M5 subtype with lower affinity, while they reversibly inhibited the binding of [3H]prazosin to rat cerebral cortex and vas deferens, with 20 fold lower affinity. High concentrations of MT1 reversibly blocked responses of vas deferens to noradrenaline. MT1 and MT2 appear to irreversibly activate muscarinic M1 receptors at a site distinct from the classical one, and to have affinity for some α-adrenoceptors.

Reduction of an Afterhyperpolarization Current Increases Excitability in Striatal Cholinergic Interneurons in Rat Parkinsonism

Striatal cholinergic interneurons show tonic spiking activity in the intact and sliced brain, which stems from intrinsic mechanisms. Because of it, they are also known as “tonically active neurons” (TANs). Another hallmark of TAN electrophysiology is a pause response to appetitive and aversive events and to environmental cues that have predicted these events during learning. Notably, the pause response is lost after the degeneration of dopaminergic neurons in animal models of Parkinsons disease. Moreover, Parkinsons disease patients are in a hypercholinergic state and find some clinical benefit in anticholinergic drugs. Current theories propose that excitatory thalamic inputs conveying information about salient sensory stimuli trigger an intrinsic hyperpolarizing response in the striatal cholinergic interneurons. Moreover, it has been postulated that the loss of the pause response in Parkinsons disease is related to a diminution of IsAHP, a slow outward current that mediates an afterhyperpolarization following a train of action potentials. Here we report that IsAHP induces a marked spike-frequency adaptation in adult rat striatal cholinergic interneurons, inducing an abrupt end of firing during sustained excitation. Chronic loss of dopaminergic neurons markedly reduces IsAHP and spike-frequency adaptation in cholinergic interneurons, allowing them to fire continuously and at higher rates during sustained excitation. These findings provide a plausible explanation for the hypercholinergic state in Parkinsons disease. Moreover, a reduction of IsAHP may alter synchronization of cholinergic interneurons with afferent inputs, thus contributing to the loss of the pause response in Parkinsons disease.

M4 muscarinic receptors are involved in modulation of neurotransmission at synapses of Schaffer collaterals on CA1 hippocampal neurons in rats

All five subtypes of muscarinic acetylcholine receptors (mAChR; M1–M5) are expressed in the hippocampus, where they are involved both in cognitive functions and in synaptic plasticity, such as long‐term potentiation (LTP). Muscarinic toxins (MTs) are small proteins from mamba snake venoms that display exquisite discrimination between mAChRs. MT1 acts as an agonist at M1 and an antagonist at M4 receptors, with similar affinities for both. MT3, the most selective antagonist available for M4 receptors, infused into the CA1 region immediately after training caused amnesia in the rat, indicating the participation of M4 receptors in memory consolidation. Our goal was to investigate the participation of M4 receptor in neurotransmission at the hippocampal Schaffer collaterals‐CA1 synapses. Two different preparations were used: 1) field potential recordings in freshly prepared rat hippocampal slices with high‐frequency stimulation to induce potentiation and 2) whole‐cell voltage clamp in cultured hippocampal organotypic slices with paired stimuli. In preparation 1, a dose of MT3 that was previously shown to cause amnesia blocked LTP; the nonselective antagonist scopolamine blocked LTP without affecting basal transmission, although it was depressed with higher concentration. In preparation 2, basal transmission was decreased and LTP induction was prevented by an MT3 concentration that would bind mainly to M4 receptors. Although M1 receptors appeared to modulate transmission positively at these excitatory synapses, M1 activation concomitant with M4 blockade (by MT1) only allowed a brief, short‐term potentiation. Accordingly, M4 blockade by MT3 strongly supports a permissive role of M4 receptors and suggests their necessary participation in synaptic plasticity at these synapses.

Facilitatory effect of the intra-hippocampal pre-test administration of MT3 in the inhibitory avoidance task

The cholinergic system plays a crucial role in learning and memory. Modulatory mechanisms of this system in the acquisition and consolidation processes have been extensively studied, but their participation in the memory retrieval process is still poorly understood. Conventional pharmacological agents are not highly selective for particular muscarinic acetylcholine receptor subtypes. Muscarinic toxins (MTs) that are highly selective for muscarinic receptors were extracted from the venom of the mamba snake, like the toxin MT3, selective for the M4 receptor subtype. These toxins are useful tools in studies of the specific functions of the M4 mediated transmission. The M4 receptor selective antagonist MT3, given into the dorsal hippocampus before the test, have enhanced the memory retrieval of an inhibitory avoidance task in rats. MT3 had no effect in the habituation to a new environment, including basic motor parameters, meaning that the effect in he inhibitory avoidance is purely cognitive. Our results suggest an endogenous negative modulation of the cholinergic muscarinic system upon the retrieval of previously consolidated aversive memories, hereby shown by the facilitatory effect of MT3.

Decrease of a Current Mediated by Kv1.3 Channels Causes Striatal Cholinergic Interneuron Hyperexcitability in Experimental Parkinsonism

The mechanism underlying a hypercholinergic state in Parkinsons disease (PD) remains uncertain. Here, we show that disruption of the Kv1 channel-mediated function causes hyperexcitability of striatal cholinergic interneurons in a mouse model of PD. Specifically, our data reveal that Kv1 channels containing Kv1.3 subunits contribute significantly to the orphan potassium current known as IsAHP in striatal cholinergic interneurons. Typically, this Kv1 current provides negative feedback to depolarization that limits burst firing and slows the tonic activity of cholinergic interneurons. However, such inhibitory control of cholinergic interneuron excitability by Kv1.3-mediated current is markedly diminished in the parkinsonian striatum, suggesting that targeting Kv1.3 subunits and their regulatory pathways may have therapeutic potential in PD therapy. These studies reveal unexpected roles of Kv1.3 subunit-containing channels in the regulation of firing patterns of striatal cholinergic interneurons, which were thought to be largely dependent on KCa channels.