An increase in glutamate release follows a decrease in gamma aminobutyric acid and the pubertal increase in luteinizing hormone releasing hormone release in …

Terasawa, Luchansky, Kasuya - Journal of neuroendocrinology, 1999 - Wiley Online Library
Terasawa, Luchansky, Kasuya
Journal of neuroendocrinology, 1999Wiley Online Library
Previously we have shown that release of γ‐aminobutyric acid (GABA) in the stalk‐median
eminence (S‐ME) is high in prepubertal monkeys and that a decrease in GABA release
triggers the onset of puberty. However, it is still unclear how disinhibition of the luteinizing
hormone releasing hormone (LHRH) neuronal system from GABA input is followed (or
accompanied) by an increase in stimulatory signals, such as glutamatergic input to LHRH
neurons. To clarify the temporal relationship between the reduction of the GABAergic …
Previously we have shown that release of γ‐aminobutyric acid (GABA) in the stalk‐median eminence (S‐ME) is high in prepubertal monkeys and that a decrease in GABA release triggers the onset of puberty. However, it is still unclear how disinhibition of the luteinizing hormone releasing hormone (LHRH) neuronal system from GABA input is followed (or accompanied) by an increase in stimulatory signals, such as glutamatergic input to LHRH neurons. To clarify the temporal relationship between the reduction of the GABAergic inhibitory signal and the enhancement of the glutamatergic stimulatory signal in the control of LHRH release at the onset of puberty, we conducted two experiments using a push–pull perfusion method. In the first experiment, we measured developmental changes in release of LHRH, GABA, and glutamate in the S‐ME. LHRH levels were very low in prepubertal monkeys, increased to higher levels in early pubertal monkeys, with the highest LHRH levels occurring in mid‐pubertal monkeys. As we previously observed, GABA levels were high in prepubertal monkeys and then decreased in early‐ and mid‐pubertal monkeys. In contrast, glutamate levels were very low in prepubertal monkeys, increased dramatically in early pubertal monkeys, and then slightly decreased in mid‐pubertal monkeys, although mid‐pubertal levels remained much higher than prepubertal levels. In the second experiment, we measured GABA, glutamate and LHRH in the same samples obtained from prepubertal monkeys which were infused with an antisense oligodeoxynucleotide (AS) for glutamic acid decarboxylase (GAD) 67 mRNA into the S‐ME. GAD67 is a catalytic enzyme for GABA synthesis from glutamate, and AS GAD67 mRNA interferes with GAD67 synthesis. Infusion of the AS GAD67 induced a decrease in GABA release, which subsequently resulted in an increase in LHRH release. Surprisingly, glutamate release also increased several hours after the decrease in GABA release, and the increased LHRH release continued. These data are interpreted to mean that a decrease in GABA synthesis by interference with GAD67 synthesis and the reduction of GABA release in the S‐ME trigger an increase in LHRH release, but that a subsequent increase in glutamate release in the S‐ME further contributes to the pubertal increase in LHRH release at the onset of puberty. The data further support our hypothesis that GAD plays an important role in the mechanism of the onset of puberty.
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