Dissociation between nerve-muscle transmission and nerve trophic effects on rat diaphragm using type D botulinum toxin.

ABSTRACT

Small doses of botulinum toxin can produce partial blockage of transmitter release at the nerve--muscle junction. 2. Subthreshold e.p.p.s, 3--10 days after poisoning, show a distribution of amplitudes that is fitted by Poisson statistics. Successive e.p.p.s. in a short train show a marked facilitation. 3. Two weeks or more after poisoning with a dose of toxin that paralyses the whole muscle, when nerve--muscle transmission is in course of recovery, subthreshold e.p.p.s have an amplitude distribution that is fitted by binomial statistics. This property of transmission is similar to those described in newly formed nerve--muscle junctions, during embryogenesis or regeneration. 4. Muscle fibres with subthreshold transmission in the 5--10 day group of muscles were all supersensitive to ACh, as were a number of fibres in which nerve stimulation still produced an action potential. 5. Two weeks or more after poisoning, muscle fibres with subthreshold transmission had lost their extrajunctional ACh-sensitivity, as had many fibres with m.e.p.p.s of roughly normal frequency but no response to nerve stimulation. 6. In diaphragm muscles poisoned with botulinum toxin between 1 and 4 days previously, the rate of fast axonal transport of radioactively labelled proteins down the phrenic nerve is not greatly affected, but the amount of materials carried is reduced to about one quarter of normal. These labelled proteins accumulate in the intramuscular portion of the phrenic nerve, in or near the nerve terminals, to a much greater extent than in controls, showing that the normal release of some of these materials has been prevented by the toxin. 7. It is concluded that the blockage of the trophic effects of nerves by botulinum toxin is due to a blockage of release of trophic factors other than ACh. 8. The muscle nerve cannot maintain a muscle in its normal state simply by activation of contraction, and a regenerating nerve terminal can restore a muscle towards its normal state before it can release enough ACh to produce muscle contraction.