Effects of estrogen on dopamine turnover, glutamic acid decarboxylase activity and lordosis behavior in septal lesioned female rats

Estradiol benzoate (EB) treatment (2.0 μg/day × 3) of septal lesioned adult female rats produces a marked increase in lordosis behavior over similarly treated sham operated animals. In these animals endogenous dopamine (DA) and norepinephrine (NE) levels were measured and turnover rates were estimated following tyrosine hydroxylase inhibition with α-methyltyrosine, in both EB and oil (0.05 ml × 3 days) treated groups. No consistent pattern of change in the level or rate of turnover of NE was noted for any of the treatment groups. No differences in either the level or turnover of DA were seen in the oil treated septal lesioned group, relative both to EB and oil treated sham operated groups. However, in the amygdala, corpus striatum and nucleus accumbens septi of the septal lesioned animals primed with EB there was both a reduction in endogenous levels (20–50%) and a decrease in synthesis rates (30–70%) of DA relative to both EB and oil treated sham operated groups and the oil treated septal lesioned group. The EB treated septal lesioned animals showed a significant negative correlation between DA levels in the corpus striatum and the level of lordosis behavior (r = −.850), supporting the concept of a possible inhibitory role for DA on female sexual receptivity. Glutamic acid decarboxylase (GAD; the rate limiting enzyme in the synthesis of γ-aminobutyric acid (GABA)) activity was measured in the substantia nigra and ventral tegmental region from the same animals. GAD activity was reduced in both areas in the EB primed sham operated animals, while the EB and oil treated septal lesioned groups remained comparable to the oil treated sham operated animals. Because of the proposed existence of a GABA mediated inhibitory neuronal feedback on DA cell bodies in the midbrain, the reduction in DA turnover in the EB primed septal lesioned female rat and thus the increase in behavioral receptivity could be due in part to the failure of the septal lesioned animal to show a compensatory decrease in GAD activity.