Binding and competitive inhibition of amine uptake at postsynaptic neurones (transport‐P) by tricyclic antidepressants

1 Peptidergic neurones accumulate amines via an unusual uptake process, designated Transport-P.[ 3 H]-prazosin binds to a 1 adrenoceptors on these cells and is displaceable by unlabelled prazosin in concentrations up to 10 77 M. However, at greater concentrations of prazosin, there is a paradoxical accumulation of [ 3 H]-prazosin which we have attributed to Transport-P. Uptake of prazosin via Transport-P is detectable at 10 710 M prazosin concentration, is linear up to 10 77 M and at greater concentrations becomes non-linear. In contrast, in noradrenergic neurones, noradrenaline uptake is linear and saturates above 10 77 M. In noradrenergic neurones and in non-neuronal cells, there is no uptake of prazosin in concentrations up to 10 76 M, suggesting that Transport-P is a specialised function of peptidergic neurones. 2 Using a mouse peptidergic (gonadotrophin-releasing hormone, GnRH) neuronal cell line which possesses Transport-P, we have studied the interaction of a 1 adrenoceptors with Transport-P. Polymerase chain reactions and DNA sequencing of the products demonstrated that only the a 1B sub-type of adrenoceptors is present in GnRH cells. 3 In COS cells transfected with a 1b adrenoceptor cDNA and in DDT 1 MF-2 cells which express native a 1B adrenoceptors, [ 3 H]-prazosin was displaced by unlabelled prazosin in a normal equilibrium process, with no prazosin paradox in concentrations up to 10 76 M. In DDT 1 MF-2 cells, [ 3 H]-prazosin was displaced likewise by a series of a 1 adrenergic agonists, none of which increased the binding of [ 3 H]-prazosin. Hence, the prazosin paradox is not due to some function of a 1 adrenoceptors, such as internalization of ligand-receptor complexes. 4 In neurones which possess Transport-P, transfection with a 1b adrenoceptor cDNA resulted in over-expression of a 1B adrenoceptors, but the prazosin paradox was unaltered. Thus, a 1 adrenoceptors and Transport-P mediate distinct functions in peptidergic neurones.

Section: Introductionmentioning

confidence: 99%

α_1B adrenergic receptors in gonadotrophin‐releasing hormone neurones: relation to Transport‐P

Al-Damluji

Shen

White

et al. 2001

“…Uptake of prazosin in peptidergic neurones (transport‐P) was distinguishable from presynaptic plasma membrane transporters by its independence of sodium and its reliance on protons for a source of energy (Al‐Damluji & Kopin, 1996a). Although transport‐P resembles the presynaptic vesicular amine transporters by its dependence on protons and V‐ATPase, it differs from these transporters by its insensitivity to reserpine and blockade by antidepressants (Al‐Damluji & Kopin, 1996a,b). The lack of effects of steroid hormones and sensitivity to antidepressants also differentiated transport‐P from the uptake processes in non‐neuronal cells (Al‐Damluji & Kopin, 1996a,b).…”

Section: Introductionmentioning

confidence: 99%

Visual detection of transport‐P in peptidergic neurones

Al-Damluji¹,

Porter²,

Krsmanović

et al. 1997

Hypothalamic peptidergic neurones possess an uptake process for amines (transport‐P), for which prazosin is a substrate. It is characterized by a paradoxical increase in the accumulation of [3H]‐prazosin when the concentration of unlabelled prazosin is increased above 10−7 m. This increase is due to activation of a proton‐dependent, vacuolar‐type ATPase‐linked pump that is blocked by tricyclic antidepressants. This study utilized a fluorescence method to detect amine uptake in individual cells. Prazosin is fluorescent but most of its emission spectrum is in the ultraviolet range. We therefore used an analogue of prazosin in which the furan ring had been substituted with a fluorescent group, BODIPY FL. This compound's emission maximum is in the green part of the visible spectrum. BODIPY FL prazosin accumulated in immortalised peptidergic neurones and the characteristic emission spectrum of the compound was evident in these cells. Accumulation of BODIPY FL prazosin was saturable and was inhibited by the tricyclic antidepressant desipramine and by unlabelled prazosin. As previously described for prazosin, uptake of BODIPY FL prazosin was blocked by cold temperature and by the organic base chloroquine. Thus, prazosin and BODIPY FL prazosin were accumulated by the same uptake process. BODIPY FL prazosin accumulated in a granular distribution, which is compatible with storage in intracellular vesicles. Hypothalamic cells from foetal rats in primary culture also accumulated BODIPY FL prazosin by a desipramine‐sensitive process. Uptake was predominantly in neurones and glial cells did not accumulate the amine. Fluorescent detection provides visual evidence for amine uptake in peptidergic neurones and should enable detailed study of the distribution of this process in the brain. British Journal of Pharmacology (1997) 120, 876–882; doi:

“…Efficacy was expressed as % of the effect of a maximal inhibitory concentration of desipramine (10 −5 m). Typically, desipramine 10 −5 M inhibited the accumulation of prazosin 10 −6 M by 80% (Figure 1; Al‐Damluji & Kopin, 1996b); the remaining 20% was regarded as non‐specific uptake for the purposes of this study. Half‐maximal inhibitory concentrations (IC 50 values) were calculated from the concentration‐response curves.…”

Section: Methodsmentioning

confidence: 95%

“…Drugs were dissolved in uptake buffer consisting of DMEM with 25 mM HEPES and 0.5 × 10 −3 m sodium ascorbate, pH 7.4. The cells were washed twice with 1 ml of buffer and then incubated for 60 min at 37°C in buffer containing [ 3 H]‐prazosin 2 × 10 −9 M and unlabelled prazosin 10 −6 M, with or without phenylethylamine derivatives in concentrations of 10 −6 M to 10 −3 M. Accumulation of prazosin and antidepressants reaches equilibrium within 60 min (Al‐Damluji & Kopin, 1996b). At the end of the incubation period, the wells were placed on ice and the cells were washed twice with 1 ml volumes of ice‐cold buffer.…”

Section: Methodsmentioning

confidence: 99%

Structural properties of phenylethylamine derivatives which inhibit transport‐P in peptidergic neurones

Al-Damluji

Kopin

1998

1 Transport-P is an antidepressant-sensitive, proton-dependent, V-ATPase-linked uptake process for amines in peptidergic neurones of the hypothalamus. It is unusual in its anatomical location in postsynaptic neurones and in that it is activated by its substrate (prazosin). This study examined the structural properties of phenylethylamine derivatives which are substrates for transport-P, as judged by competitive inhibition of the uptake of prazosin 10 76 M in immortalized hypothalamic peptidergic neurones. 2 A basic amine was essential for activity; absence of the amine or neutralization with a carboxyl group abolished activity. Primary, secondary and tertiary amines were active but quaternary and guanyl amines were inactive. 3 A phenyl group was essential for activity at transport-P. Potency at transport-P was reduced by phenolic hydroxyl groups and enhanced by phenolic halogens. Thus, for maximal potency, the phenyl group should be hydrophobic. Phenolic methoxyl groups had no eect on potency at transport-P. 4 A side chain was necessary for activity at transport-P. Potency at transport-P was reduced by bhydroxyl and enhanced by a-methyl groups. 5 These ®ndings further distinguish transport-P from other amine uptake processes in the brain.