Passive avoidance training and recall are associated with increased glutamate levels in the intermediate medial hyperstriatum ventrale of the day-old chick.

Jonathan N Daisley,Steven P R Rose,Michael Gruss,Katharina Braun

doi:10.1155/np.1998.53

Abstract

In the young chick, the intermediate medial hyperstriatum ventrale is involved in learning paradigms, including imprinting and passive avoidance learning. Biochemical changes in the intermediate medial hyperstriatum ventrale following learning include an up-regulation of amino-acid transmitter levels and receptor activity. To follow the changes of extracellular amino acid levels during passive avoidance training, we used an in vivo microdialysis technique. Probes were implanted in chicks before training the animals, either on a methyl- anthranylate-or water-coated bead. One hour later, recall was tested in both groups by presenting a similar bead. An increase of extra-cellular glutamate levels accompanied training and testing in both groups; during training, glutamate release was higher in methylanthranylate- trained than in water-trained chicks. When compared with the methylanthranylate-trained chicks during testing, the water-trained chicks showed enhanced extra-cellular glutamate levels. No other amino acid examined showed significant changes. After testing, the chicks were anesthetized and release- stimulated with an infusion of 50 mM potassium. Extra-cellular glutamate and taurine levels were significantly increased in both methylanthranylate-and water-trained chicks. The presentation of methylanthranylate as an. olfactory stimulus significantly enhanced glutamate levels, especially in methylanthranylate-trained chicks. The results suggest that such changes in extra-cellular glutamate levels in the intermediate medial hyperstriatum ventrale accompany pecking at either the water- or the methylanthranylate-bead. The taste of the aversant may be responsible for the greater increases found in methylanthranylate-trained birds.

Highlights

In the young chick, the intermediate medial hyperstriatum ventrale is involved in learning paradigms, including imprinting and passive avoidance learning
We have shown changes in amino-acid-transmitter release from slices of intermediate medial hyperstriatum ventrale (IMHV) incubated in high potassium media (Daisley & Rose 1994)
In this paper we report the use of this microdialysis technique to follow the changes in extracellular concentrations of amino acids, glutamate, following training on the one-trial passive avoidance task

Summary

SUMMARY

The intermediate medial hyperstriatum ventrale is involved in learning paradigms, including imprinting and passive avoidance learning. The formation of memory for the passive avoidance task involves a well-documented ascade of biochemical, electrophysiological, morphological events including (a) an increased glucose utilization (Rose & Csillag, 1985); (b) an increased calcium flux; (c) PKC translocation (Burchuladze et al, 1990); and (d) changes in dendritic spine density (Patel et al, 1988) These events appear to be localized to particular regions of the chick brain. 6.5-7hr), the anesthetized chicks were first presented with a dry tissue, which was placed close to the anesthetized chick’s nostrils for a 10-rain sampling period The tissue was removed, and 40 min were allowed to elapse before the tissue (this time soaked in MeA) was again placed for 10 min in a similar position, close to the nostrils of the chick Both groups of chicks (W- and MeA-trained) received MeA as the olfactory stimulus.

Basal level measurements

Effect of potassium stimulation on in vivo glutamate accumulation

The effect of olfactory stimulation with MeA on glutamate release

DISCUSSION