Receptor Kinetics Pertaining to Blockade of Nerve-Released Transmitter at Synapses
Abstract
The question is raised as to whether competitive inhibitors should block responses of tissue to nerve-released neurotransmitter to the same extent as they block equivalent responses to exogenous agonist. From a simple dynamic model of synaptic events, which takes into account nonconstancy of transmitter concentration in space and time, it is deduced that equal blockade of responses to nerve-released and exogenous transmitter substance will occur if: (i) there are locally many more receptor molecules than transmitter molecules; (ii) the active agonist--receptor complex, AnR, has n = 1; and (iii) tissue response is insensitive to spatial or temporal inhomogeneity of AR. In such a case there will also be equal sensitivity of responses to other modes of inhibition: irreversible competitive, uncompetitive, and non-competitive. Equal blockade of responses to equi-effective endogenous and exogenous agonist will also occur if nerve stimulation gives rise to a steady uniform concentration of agonist, so that equilibrium kinetics are applicable. When n > 1 and/or when tissue responses reflect local peak AnR, response to nerve-released transmitter will be relatively insensitive to receptor blockade by a competitive inhibitor. The same is true for irreversible competitive blockade or for modulation of receptor density. However, an uncompetitive inhibitor (e.g. a `channel blocker') may be more effective against nerve-released agonist than against exogenous agonist.
- Publication:
-
Proceedings of the Royal Society of London Series B
- Pub Date:
- May 1988
- DOI:
- 10.1098/rspb.1988.0033
- Bibcode:
- 1988RSPSB.233..461Q