Schwann cell mitosis in response to regenerating peripheral axons in vivo.

Schwann cell mitosis has been demonstrated in chronically denervated cat tibial nerves re-innervated by axons regenerating from the proximal stump of a coapted peroneal nerve. Thymidine incorporation rose above baseline levels at the axon front, with no detectable increase in more distal regions occupied by denervated Schwann cells. Schwann cells therefore enter S phase upon the arrival of a regenerating axon in vivo as previously described in tissue culture. Intraneural treatment of the denervated distal stump with Mitomycin C prior to re-innervation delayed the subsequent appearance of myelin formation. This supports the notion that axonally stimulated division of Schwann cells is a prerequisite for myelination during nerve regeneration. Axonal advancement was also retarded by drug treatment, possibly because of a reduced level of trophic support provided by the compromised Schwann cells. A comparable absence of myelin and poor re-innervation was found in chemically untreated distal stumps that had been maintained in the denervated state for prolonged periods when Schwann cell columns are known to undergo progressive atrophy. These observations suggest that nerve repair should be delayed for limited periods if efficacious regeneration is desired.

Sodium channels in the axolemma of unmyelinated axons: a new estimate.

The saturable uptake of tritium-labeled saxitoxin by the rat left cervical sympathetic trunk, which consists almost entirely of unmyelinated fibers, indicates that the density of sodium channels on the axolemma of these fibers is about 200 channels/microns 2.

Saxitoxin binding to central and peripheral nervous tissue of the myelin deficiency (md) mutant rat.

Tritium-labeled saxitoxin binding was assayed in the CNS and PNS of normal and of 'myelin deficiency' (md) mutant rat pups. This mutant in the Wistar rat is characterized by a virtually complete amyelination of the CNS, the PNS being normal. No significant difference was found in the saxitoxin binding capacity of md and normal brain, spinal cord, or sciatic nerves. This suggests that the presence or absence of myelin does not influence the number of voltage-sensitive sodium channels in the rat.

The role of post-traumatic mitosis in elevation of anaerobic metabolism enzyme (lactic acid dehydrogenase) activity in degenerating central and peripheral nerve.

Glial and Schwann cells undergo marked biochemical and morphological alterations following axonal injury. In the present experiments, the extent of enzyme activity associated with anaerobic (LDH, lactic dehydrogenase) vs aerobic (SDH, succinic dehydrogenase) respiration was assessed distal to the site of nerve fiber injury. Studies were performed in rat central (optic) and peripheral (sciatic) nerves at 2, 7 and 14 days postoperatively (d.p.o.). In sciatic nerves, LDH activity rose 3-fold in traumatized (vs unoperated control) nerve tissue between 2 and 7 d.p.o. and remained elevated at 14 d.p.o. SDH activity in traumatized nerve was equal to that in unoperated nerve at 7 d.p.o., but decreased at 14 d.p.o. LDH activity in optic nerve at 2 d.p.o. was equivalent to that in control nerve, but rose approximately two-fold by 7 d.p.o. However, unlike peripheral nerve, activity in traumatized optic nerve decreased to control levels at 14 d.p.o. SDH activity in traumatized optic nerve remained unchanged at any timepoint examined. Taken in concert, these data are consistent with the hypothesis that there is an overall shift in CNS glial and Schwann cell metabolism from aerobic to anaerobic respiration following nerve injury. Additional studies were performed to determine if this shift requires prior Schwann or glial cell mitosis. Administration of mitotic inhibitor (AraC, cytosine arabinofuranoside) inhibited post-traumatic elevations in LDH activity in optic, but not peripheral nerve. No significant effect of the drug on axonal degeneration (as assessed by saxitoxin binding) was observed.

Reactive glial protein synthesis and early disappearance of saxitoxin binding in degenerating rat optic nerve.

The biochemistry of gliotic CNS tissue was assessed by monotoring changes in de novo protein synthesis distal to site of crush in the rat optic nerve between 3 and 20 days post-operatively. Radioactivity profiles on 12% polyacrylamide SDS gels showed reproducible peaks associated with protein(s) with dissociated molecular weights of 57K, 51K, 42K, 40K, 37K and 23K. Differences between crush and control nerves were observed with respect to the latter two peaks. De novo synthesis of 23K protein (comigrant with myelin proteolipid protein) was evident in control but not crushed nerves. Synthesis of 37K protein (identity unknown) was evident at 7, 10 and (to a lesser extent) 20 days post-operatively in crushed nerves, but not in crushed nerves at 3 days post-operatively or in unoperated nerves at any time point. The appearance of the synthesis of the 37K protein coincides with a drop in the level of functional axolemma (assessed by [3H]saxitoxin binding) in crushed nerves from 78% to 36% of control levels between 3 and 7 days post-operatively.

Sodium channels in the axolemma of normal and degenerating rabbit optic nerve.

Section of a rabbit peripheral nerve leads to axonal degeneration and a proliferation of Schwann cells, and it is known to lead to a profound increase in the saxitoxin binding capacity of its distal portion, suggesting that Schwann cells may bind this marker for sodium channels. The present study shows, however, that crush with subsequent axonal degeneration of the central axons of the rabbit optic nerve leads to a slow monotonic fall in the saxitoxin binding capacity, which by 100 days after crush is not significantly different from zero. This suggests that central glial cells (astrocytes and oligodendrocytes) do not bind saxitoxin, and that the saturable binding of saxitoxin to this nerve is entirely to the axolemma. On this basis, the value for total saxitoxin binding capacity of the normal rabbit optic nerve, taken together with the morphometric data of D. I. Vaney & A. Hughes (J. comp. Neurol. 80, 241-252 (1976)), yields a sodium channel density of about 400-700 channels per square micrometre nodal axolemma.

Ultrastructural studies of the dying-back process. V. Axonal neurofilaments accumulate at sites of 2,5-hexanedione application: evidence for nerve fibre dysfunction in experimental hexacarbon neuropathy.

This study examined the thesis that 2,5-dexanedione (2,5-HD) produces distal (dying-back) axonopathy by direct toxic action on nerve fibers. Single or repeated application of undiluted or 10% 2,5-HD to exposed rat sciatic nerves caused some fibres to develop focal axonal swellings filled with abnormally large numbers of 10 nm neurofilaments. Such changes occurred within four days of application and were especially prominent in equivalently treated nerve segments obtained from animals orally exposed to 0.5% 2,5-HD before surgery. Nerve fibers along the perimeter of tibial nerve fascicles exposed to 2,5-HD or 2,4-hexanedione (2,4-HD), a compound unable to produce systemic neuropathy, underwent non-specific breakdown and Schwann cell necrosis. Nerve fibres located in the centre of such fascicles only developed an hypertrophied paranuclear Schwann cell cytoplasm and did not proliferate intermediate filaments. Saline, hydrochloric acid and 1,6-hexanediol, a water-soluble hexacarbon also lacking systemic neurotoxic properties, produced no intra-fascicular changes when locally applied to the sciatic nerve. It is concluded (1) that 2,5-HD causes a giant axonal swellings by direct toxic action on the nerve fibre, (2) 2,5-HD does not induce a generalized disorder of cytoplasmic intermediate filaments and (3) primary Schwann cell changes produced by locally applied 2,5-HD or 2,4-HD are non-specific and unrelated to the formation of the giant axonal swellings.

Events in degenerating cat peripheral nerve: induction of Schwann cell S phase and its relation to nerve fibre degeneration.

Severance of a peripheral nerve leads to a characteristic series of events in the distal stump, including the dissolution of axons and myelin and the proliferation of Schwann cells within their basal lamina. This study examines the relationship between the spatial-temporal pattern of the induction of the Schwann cell S phase, loss of the structural and functional properties of axolemma, and the clearance of myelin debris in the cat tibial nerve. Nerve transection stimulated a monophasic increase in [3H]thymidine incorporation that peaked at 4 days post-transection throughout an 80-mm length of distal stump. Light microscope autoradiography revealed prominent incorporation into Schwann cells of myelinated fibres. Treatment of distal stumps with mitomycin C at the time of nerve transection greatly retarded thymidine incorporation and clearance of myelin debris, but not the time course of axonal degeneration, decline in the synthesis of the major myelin glycoprotein, P0, or the onset of ovoid formation. Nerve transection also greatly reduced the specific uptake of [3H]saxitoxin (STX), a ligand which binds to voltage-sensitive sodium channels. Binding in the distal stump fell precipitously to 20% of the normal at 4 days post-transection, concurrent with the peak of thymidine incorporation. This low level of binding was maintained for periods of up to 70 days, demonstrating that some STX binds to structures other than axons in denervated distal stumps. Prior treatment with mitomycin C delayed the loss of specific STX binding. In conclusion, these studies suggest that: Schwann cell DNA replication and/or mitosis regulates other events during Wallerian degeneration, including myelin degeneration, catabolism of P0 and the clearance of sodium channels from nodal axolemma; the decline in P0 synthesis and/or shift to synthesis of less extensively processed P0 is independent of the induction of Schwann cell S phase; and Schwann cells enveloping myelinated axons enter S phase within a 24-h period throughout the entire 80-mm length of distal stump.