Stimulation frequency-noradrenaline release relationships examined in alpha2A-, alpha2B- and alpha2C-adrenoceptor-deficient mice.

The stimulation frequency-noradrenaline release relationship was studied in the vas deferens and the cerebral cortex of NMRI mice, mice in which the alpha2A-, the alpha2B-, the alpha2C- or both the alphaCA- and the alpha2C-adrenoceptor gene had been disrupted (alpha2AKO, alpha2BKO, alpha2CKO and alpha2ACKO), and the wildtype mice from which the knockout animals had been generated. Tissue pieces were preincubated with 3H-noradrenaline and then superfused and stimulated electrically with a constant number of pulses (30 in vas deferens and 50 in brain cortex) at frequencies between 0.03 and 100 Hz. The frequency-evoked tritium overflow curves ascended monophasically in the vas deferens of wildtype and NMRI mice. Disruption of the alpha2B-adrenoceptor gene caused no change. In the vas deferens of alpha2CKO mice, the overflow evoked by low frequencies (0.3 and 1 Hz) was slightly increased. In the vas deferens of alpha2AKO and alpha2ACKO mice, the evoked overflow was increased to a greater extent. Rauwolscine (1 microM) caused a marked increase of the evoked overflow of tritium from the vas deferens of NMRI, wildtype, alpha2BKO and alpha2CKO mice. Rauwolscine also increased the evoked overflow of tritium from the vas deferens of alpha2AKO and alphaC2ACKO mice, but to a smaller extent. The gene disruptions and rauwolscine slightly steepened the slope of the vas deferens frequency-overflow curve. In the brain cortex of wildtype and NMRI mice, the frequency-evoked tritium overflow curves were U-shaped. In the brain cortex of alpha2BKO and alpha2CKO mice, the evoked overflow was slightly reduced. In the brain cortex of alpha2AKO and alpha2AcKO mice, in contrast, the evoked overflow was increased. Rauwolscine (1 microM) caused a marked increase of the evoked overflow of tritium from the brain cortex of NMRI, wildtype, Q2BKO and alpha2CKO mice. Rauwolscine also increased the evoked overflow of tritium from the brain cortex of alpha2AKO and alpha2ACKO mice, but to a smaller extent. The gene disruptions and rauwolscine flattened the U shape of the brain cortex frequency-overflow curve. It is concluded that alpha2-autoinhibition is one factor that shapes the frequency-noradrenaline release relationships in the mouse vas deferens and cerebral cortex. The autoreceptors are mainly alpha2A and to a minor extent, and well detectable in the vas deferens only, alpha2C. When both the alpha2A- and the alpha2C-adrenoceptor have been deleted, alpha2B-adrenoceptors may be expressed as autoreceptors in noradrenergic neurons. It seems possible that alpha2C-autoreceptors depress mainly release at low (around 1 Hz) whereas alpha2A-autoreceptors depress mainly release at high (around 10 Hz) frequencies.