The Regenerative Cycle of Motoneurons, With Special Reference to Phosphatase Activity

Bodian, David; Mellors, Robert C.

doi:10.1084/jem.81.5.469

Cited by 182 publications

(25 citation statements)

References 42 publications

(53 reference statements)

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“…During a 2-week period the Nissl bodies break into smaller and smaller bits and diminish in quantity, the nucleus is displaced toward the periphery of the cell, and swelling of the cell body occurs. The climax of anatomical change comes in the 3rd week, and then alterations previously observed revert to normal over a period of 50-100 days (Bodian & Mellors, 1945). The changes in the function of the inferior mesenteric ganglion described above parallel this orderly sequence of anatomical events.…”

Section: Discussionsupporting

confidence: 52%

“…The discovery of physiological effects of axotomy has led to renewed study of the axonal reaction in spinal motoneurones (Barr & Hamilton, 1948) and to the discovery of parallel changes in certain enzymic activities and other biological phenomena in them (Howe & Mellors, 1945;Bodian & Mellors, 1945). Chromatolysis is known to occur in autonomic ganglia on postganglionic axotomy (De Castro, 1932), but systematic studies of its temporal course or of the biochemical changes which may accompany it in this tissue do not appear to have been reported.…”

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confidence: 99%

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The temporal course of the effects of postganglionic axotomy on the inferior mesenteric ganglion of the cat

Acheson¹,

Remolina²

1955

The Journal of Physiology

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Some years ago it was observed (Acheson, Lee & Morison, 1942) that cutting the phrenic nerve caused, over a period of 3 weeks, a progressive central block of the transmission of nerve impulses from the respiratory centre to the axons of the cut phrenic nerve. At that time a similar phenomenon was noted in the inferior mesenteric ganglion: section of the hypogastric nerve caused a progressive block of the transmission of preganglionic volleys to the postganglionic axons of the cut hypogastric nerve (Acheson, 1952). This phenomenon was independently discovered in the same site by Brown, McLennan & Pascoe (1952). These authors have aimed their experiments chiefly at the mechanism of the block (Brown & Pascoe, 1954;McLennan, 1954). The present paper reports experiments in which the temporal course of the phenomenon was systematically studied. Campbell, Mark & Gasteiger (1949) and Downman, Eccles & McIntyre (1953) have studied a parallel phenomenon which occurs in motoneurones when ventral roots have been cut and dorsal root axons are stimulated. METHODSCats of either sex weighing from 1-5 to 3.5 kg were anaesthetized by the intraperitoneal injection of pentobarbitone sodium (30-40 mg/kg). With aseptic precautions the abdominal cavity was opened, and the right hypogastric nerve was sectioned about 3 cm away from its ganglion. The left side remained untouched, to be used as a control. In some experiments the colonic nerve from the right inferior mesenteric ganglion was also cut; the results to be reported were not different in the experiments in which the colonic nerves were cut. The abdominal wall was closed, and the animals were allowed to recover. At intervals ranging from 2 to 180 days after the operation, under the same kind of anaesthesia the abdominal viscera were removed. A cannula in the femoral vein was employed whenever intravenous injection of drugs was necessary. The preganglionic trunks of both inferior mesenteric ganglia were dissected and placed together on a single pair of silver electrodes for stimulation, while the hypogastric nerves, after dissection, were laid separately on two symmetrical pairs of silver recording electrodes (Fig. 1). The responses of the two hypogastric nerves to stimulation of the preganglionic trunks by supramaximal rectangular

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Section: Discussionsupporting

confidence: 52%

mentioning

confidence: 99%

The temporal course of the effects of postganglionic axotomy on the inferior mesenteric ganglion of the cat

Acheson¹,

Remolina²

1955

The Journal of Physiology

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“…This fibre shrinkage, amounting to some 10 %, can be compared with the axonal shrinkage which takes place in the central stump of a regenerating peripheral nerve (Gutmann & Sanders, 1943;Sanders & Whitteridge, 1946). If, as seems likely, fibre shrinkage of this kind takes place because outflow of axoplasm exceeds its rate of manufacture during regeneration, with consequent reduction of axonal turgor (Bodian & Mellors, 1945), then it appears impossible to achieve fully the aim of silencing presynaptic pathways by operation without altering such pathways in any other respect. Nevertheless, it is considered that this complication does not seriously weaken the significance of the data to be presented, though the arguments favouring this conclusion must be deferred until the experimental results have been fully described.…”

Section: Hitologymentioning

confidence: 99%

The effects of disuse and of activity on mammalian spinal reflexes

Eccles¹,

McIntyre²

1953

The Journal of Physiology

113

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The behaviour of chromatolysed motoneurones studied by intracellular recording

Eccles¹,

Libet²,

Young³

1958

The Journal of Physiology

315

134

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When the axon of a neurone is severed, the cell body exhibits a profound series of morphological and chemical changes (the axon-reaction or chromatolysis) that begins a few days later and reaches a maximum in 2-3 weeks (Cajal, 1909;Bielschowsky, 1932; Hyden, 1943;Nonidez, 1944;Bodian & Mellors, 1945; Brattgard, Edstrom & Hyden, 1957).It has been shown that, concomitant with these morphological changes, chromatolysed motoneurones exhibit changes in their reflex responses (Downman, Eccles & McIntyre, 1953). At the height of the chromatolysis group I afferent volleys from muscles no longer evoked a monosynaptic reflex discharge having the characteristic features of brief latency and virtual synchrony. The reflex latency was lengthened by at least 0 5 msec, even during post-activation potentiation, and the reflex discharge was dispersed over many milliseconds. However, by testing for the facilitation of motoneurones, it was shown that there was still a synaptic excitation with the brief latency of a monosynaptic action, though it was subliminal for evoking a reflex discharge. These observations led Downman et al. (1953) to suggest that the monosynaptic activation of motoneurones was depressed during chromatolysis and that there had been a compensatory development of polysynaptic excitatory pathways.These suggestions can be very effectively tested by the technique of intracellular recording. In a preliminary investigation Bradley, Brock & McIntyre (1955) reported that in chromatolysed motoneurones there was a normal latency for the excitatory post-synaptic potential (EPSP) generated by monosynaptic activation, but that it showed an abnormally prolonged and variable rising phase. This prolonged smooth rise of the EPSP accounted for the long * Fellow ofthe Commonwealth Fund ofNew York.

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The Regenerative Cycle of Motoneurons, With Special Reference to Phosphatase Activity

Cited by 182 publications

References 42 publications

The temporal course of the effects of postganglionic axotomy on the inferior mesenteric ganglion of the cat

The temporal course of the effects of postganglionic axotomy on the inferior mesenteric ganglion of the cat

The effects of disuse and of activity on mammalian spinal reflexes

The behaviour of chromatolysed motoneurones studied by intracellular recording

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