Cholinergic and glutamatergic effects on neocortical neurons may support rate as well as development of conditioning

Identification of differently timed motor components of conditioned blink responses

Electromyographic recordings were made from the orbicularis oculi muscles of cats in order to identify differently timed motor components of conditioned eye blink responses (CRs). Conditioning was established rapidly by pairing electrical stimulation of the hypothalamus (HS) with a click conditioned stimulus (CS) and a glabella tap unconditioned stimulus (US). Analysis of the EMG responses disclosed five different motor components of the CR that could be distinguished and characterized according to their latencies of occurrence. Four were associated with an increase in EMG activity elicited by the CS (16-48 ms, alpha(1); 48-80 ms, alpha(2); 80 to 120 ms, beta; >/=120 ms, gamma), and one was associated with a decrease in activity (16 to 60 ms, alpha(i)). Analysis of the amplitudes of the different components of the CR during the course of conditioning and extinction disclosed that short latency, alpha(1) components of the CRs were acquired and extinguished in a manner equivalent to longer latency components of the CRs. The observations supported the hypothesis that short and long latency components of blink responses represented comparable rather than substantially different forms of Pavlovian conditioning. The alpha(2) response was present before conditioning began, and increased with other components after conditioning. The alpha(i) response component was also observed prior to conditioning, and represents a previously undetected, inhibitory consequence of presenting weak (70 dB) acoustic stimuli. It could play a role in conditioned inhibition, latent inhibition and blocking as well as suppression of the conditioned motor response during extinction.

Effects of neonatal cholinergic basal forebrain lesions on excitatory amino acid receptors in neocortex

The role of cholinergic basal forebrain projections in the modulation of cortical plasticity and associated functional changes is currently the subject of renewed attention. Excitatory amino acid receptors have been identified as mediators of cortical topographic efferent and afferent information. In addition some of these receptors, notably the NMDA and metabotropic [mGluR] type, participate in cortical plasticity. Growing evidence suggests that interactions between cholinergic and glutamatergic systems contribute to cognitive cortical functions and their anatomical and physiological substrates. Though cholinergic and glutamatergic mechanisms have both been shown to be involved in cortical morphogenesis, few studies have attempted to study their interactions in development. The present study investigates the effect of neonatal lesions to the cholinergic basal forebrain on NMDA, AMPA and mGluR receptors in BALB/CByJ mice, at two different developmental ages. We demonstrated previously that nBM lesions at birth result in transient cholinergic depletion for the first two postnatal weeks, substantial morphogenetic alterations in neocortex and cognitive deficits by adulthood. We show here that unilateral neonatal lesions result in decreases in NMDA and AMPA receptors but increases in mGluRs during the second postnatal week (PND 14). At 30 days postnatal, lesion mediated changes were attenuated, compared with PND 14, but significant sex differences in control and nBM lesioned mice were apparent. These data support the notion that cholinergic/glutamatergic interactions are important during early cortical morphogenesis. Moreover, our results highlight the fact that cholinergic as well glutamatergic developmental mechanisms are sexually dimorphic.

Transient changes of electrical activity in the rat barrel cortex during conditioning

To reveal the dynamics of neurophysiological changes in the rat barrel cortex induced by conditioned stimulation we recorded the local micro-electroencephalographic (EEG) activity and evoked potentials (EPs) in barrel cortex to stimulation of a single vibrissa before and after pairing it with a mild electric shock applied to the rat's tail. Following the introduction of the reinforcing stimulus, the amplitude of the first negative component of evoked potentials in the cortex on the conditioned side grew in relation to the same component of control potentials, evoked by stimulation of the opposite symmetrical vibrissa. This change was accompanied by a latent decrease in spectral power of the EEG within the alpha and beta frequency bands in both hemispheres. The observed changes in both of these electrical manifestations of enhanced neuronal activity reverted after two (EP) or three (EEG) days of conditioning. These results are discussed in relation to the putative activity of neuromodulatory systems.