Puromycin induction of transient regeneration in mammalian spinal cord

Astrocytes secrete basal lamina after hemisection of rat spinal cord

Basal lamina is reconstructed over the lesioned surface of the spinal cord. The following experiment (90 rats) studies the ultrastructure of the formation of this membrane and the immunohistochemistry of laminin production (a major secreted component of basal lamina). After hemisection of the spinal cord at T6 animals were prepared for electron microscopy or antilaminin-biotin-avidin-peroxidase incubation. Three-5 days posthemisection, antilaminin reaction product was observed in astrocytes and their processes which faced the lesion, endothelia of blood vessels or pia. Ultrastructurally (3 days), basal lamina was polymerizing as small projections on the surface of astrocytic membranes facing the lesion, endothelia or pia. By 5 days the basal lamina was a single membrane, folded multiple sheets or in swirls. At 6-10 days the antilaminin reaction and the basal lamina (except for duplications) did not differ from normal. Reactive astrocytes secrete laminin for at least 3-5 days after hemisection and form basal lamina on the lesioned surface of the spinal cord after spinal cord hemisection.

Ultrastructure of fetal spinal cord and cortex implants into adult rat spinal cord

The ultrastructure of cortex and spinal cord from 11-, 12-, and 15-day-old fetuses implanted into the spinal cord of adult rats was studied over 3 months. Under deep Chloropent anesthesia, a 0.5 X 1.0-mm square of fetal cortex or a 1.0-mm segment of fetal spinal cord was implanted subpially between the left dorsal column and the dorsal horn of 70 adult rats. Implants grew toward gray matter, usually interfacing with the host at the isthmus between the horns of the spinal cord. However, implants were observed that occupied the entire left dorsal and ventral horns of the left half of the host spinal cord. Implants had concentric zones: A central zone with basal lamina lined joined channels and subjacent neuroglia; a zone of differentiating implant nervous system; a zone with basal lamina lined implant with overlying pial cells on the dorsal and lateral surfaces of the implant; a zone that interfaced with the host with overlapping neuropil on the lateral and ventral surfaces of the implant. Neuron types were typical for cortical or spinal implants. Implants survived for 3 months and reached stages of neuronal and neuroglial maturation similar to controls. Both fetal spinal cord and brain were successful as implants, had delayed differentiation, and formed complex neuropils. The zone of overlapping interface of the donor and host is an anatomical indication of physiological and functional integration.

[3H]lysine incorporation into protein of hemisected, cycloheximide-treated spinal cord

A single application of a protein synthesis inhibitor, puromycin, in the lesion site of a spinal hemisection transiently decreases protein incorporation for less than 24 h and results in axonal sprouting and dendritic and synaptic stability for at least 60 days. In this study we characterized the protein-altering properties of single applications of a different protein synthesis inhibitor, cycloheximide, for comparison. The protein incorporation of [3H] lysine into hemisected rat spinal cord (left side, T2) treated with cycloheximide (100 micrograms/ml in Gelfoam sponge placed in wound at time of lesion) was tested 3 h, 6 h, 12 h, 1, 3, 7, and 14 days later and compared with that in 0.9% saline in Gelfoam implants as normal controls (N = 54). One hour prior to utilization, the animals were injected subcutaneously with 200 mu Ci L-[4,5(n)-3H]lysine monohydrochloride. No treatment-related differences in brain radioactivity were noted at any time postoperation. In spinal cord, inhibition of amino acid uptake by cycloheximide was not demonstrable at 3 h after hemisection, but could be detected from 6 h to 1 day after implantation. During that time, the TCA-soluble radioactivity at the lesion site was greater than in control animals (P less than 0.05). These results suggest that as with puromycin, morphologic effects produced by cycloheximide on spinal cord regeneration may correspond to chemical events which occurred within the first 24 h after cord hemisection and cycloheximide treatment.

Rehabilitation following brain damage: some neurophysiological mechanisms. Determinants of recovery

General theories of recovery are outlined. The effect of a partial lesion in the central nervous system (CNS) is described with the emphasis on the reaction of the intact and undamaged CNS. The reaction of the CNS includes sprouting of new terminals and the unmasking of synapses. The role of neuroglia is discussed in relation to the dynamic changes following partial damage and consequent reorganization of the CNS. The effect of this reaction, sprouting and unmasking of synapses, is to produce an altered nervous system and it is this altered nervous system, as well as the lesion responsible, which produces the clinical picture in human chronic neurological damage. Although much remains unanswered, the known facts of CNS reorganization (and possible regeneration?) in the experimental animal have definite implications for management of neurological deficit in man; in particular, that the adult nervous system is capable of considerable reorganization and therapeutic procedures may be based on active environmental and artificial stimulation.