Cellular processes in the amygdala: gates to emotional memory?

The amygdala is considered a core structure of the so-called limbic system and has been implicated in a variety of functions, including emotional interpretation of sensory information, emotional arousal, emotional memory, fear and anxiety, and related clinical disorders. Despite the clinical and functional importance of the amygdala, it is only recently that some general principles of intra-amygdaloid mechanisms of signal processing that are relevant for fear behavior and memory have emerged from behavioral, anatomical, electrophysiological, and neurochemical studies performed in the amygdala of various mammalian species in vivo, in situ and in vitro.

Synaptic mechanisms of NMDA-mediated hyperpolarization in lateral amygdaloid projection neurons.

Synaptic mechanisms underlying NMDA-mediated responses of neurons in the guinea pig lateral amygdala (AL) were investigated in in vitro slice preparations. Local application of NMDA resulted in initial hyperpolarization of pyramidal-like spiny cells (projection neurons), followed by prolonged depolarization. The slow depolarization represented a direct postsynaptic effect of NMDA, whereas the initial hyperpolarization was induced presynaptically through activation of GABAergic interneurons and was sensitive to blockade by tetrodotoxin as well as the GABA(A)-receptor antagonist bicuculline.

Spike doublets in neurons of the lateral amygdala: mechanisms and contribution to rhythmic activity.

A majority of projection neurons in the lateral amygdala generate oscillatory spike firing in the theta-frequency range, largely due to intrinsic membrane properties. Here we report on the occurrence of spike doublets in about 70% of these cells. Spike doublets consisted of a fast initial and a second slower component, which were mediated by sodium- and calcium-dependent mechanisms, respectively.

Ionic mechanisms of intrinsic oscillations in neurons of the basolateral amygdaloid complex.

Ionic mechanisms underlying low-threshold (LTO) and high-threshold (HTO) oscillations occurring in a class of spiny neurons within the basolateral amygdaloid complex (see companion paper) were investigated in slice preparations of the guinea pig amygdala in vitro. LTOs were abolished through local application of tetrodotoxin (TTX, 10-20 microM) or a decrease in the extracellular sodium concentration ([Na+]o) from 153 to 26 mM, whereas HTOs were more readily elicited under these conditions. The effects of TTX and low [Na+]o were accompanied by a hyperpolarizing shift of the membrane potential by 3 +/- 1 mV and a decrease in apparent input resistance by 14 +/- 11 MOmega.

Two types of intrinsic oscillations in neurons of the lateral and basolateral nuclei of the amygdala.

Intracellular recordings in the guinea pig and cat basolateral amygdaloid (BL) complex maintained as slices in vitro revealed that a subpopulation of neurons (79%) in the lateral (AL) and basolateral (ABl) nuclei generated two types of slow oscillations of the membrane potential upon steady depolarization from resting potential. The cells were of a stellate or pyramidal-like shape and possessed spiny dendrites and an axon leaving the local synaptic environment, and thus presumably represented projection neurons. Similar oscillatory activity was observed in projection neurons of the cat AL nucleus recorded in vivo.

Distributed processing on the basis of parallel and antagonistic pathways simulation of the femur-tibia control system in the stick insect.

In inactive stick insects, sensory information from the femoral chordotonal organ (fCO) about position and movement of the femur-tibia joint is transferred via local nonspiking interneurons onto extensor and flexor tibiae motoneurons. Information is processed by the interaction of antagonistic parallel pathways at two levels: (1) at the input side of the nonspiking interneurons and (2) at the input side of the motoneurons. We tested by a combination of physiological experiments and computer simulation whether the known network topology and the properties of its elements are sufficient to explain the generation of the motor output in response to passive joint movements, that is resistance reflexes.

Connections of the forewing tegulae in the locust flight system and their modification following partial deafferentation.

The flight motor pattern of the adult locust (Locusta migratoria L.) is able to recover from the loss of the hindwing tegulae. This recovery is due to a functional substitution of the hindwing tegulae by the forewing tegulae (Büschges, Ramirez, and Pearson, 1992).