J. G. Nicholls

Regeneration of immature mammalian spinal cord after injury

In this review we describe the growth of regenerating fibres through lesions in immature mammalian spinal cord. In newborn opossums and foetal rats, repair occurs rapidly and reliably without antibodies, implants or bridges of undamaged spinal cord. In the neonatal opossum one can compare recovery from lesions made to the CNS at various stages of development in the animal and in culture. As the CNS matures, the capacity for regeneration ceases abruptly. In particular, the extracellular matrix and molecules associated with glia have been shown to play a role in promoting and inhibiting regeneration. Major problems concern the precision with which regenerating axons become reconnected to their targets, and the specificity needed for recovery of function.

Growth of axons through a lesion in the intact CNS of fetal rat maintained in long-term culture

The ability of neurons in the central nervous system (CNS) to grow through a lesion and restore conduction has been analysed in developing spinal cord in vitro. The preparation consists of the entire CNS of embryonic rat, isolated and maintained in culture. Conduction of electrical activity and normal morphological appearance (light microscopical and electron microscopical) were maintained in the spinal cord of such preparations for up to 7 d in culture. A complete transverse crush of the spinal cord abolished all conduction for 2 d. After 3—5 d, clear recovery had occurred: electrical conduction across the crush was comparable with that in uninjured preparations. Furthermore, the spinal cord had largely regained its gross normal appearance at the crush site. Axons stained in vivo by carbocyanine dyes had, by 5 d, grown in profusion through the lesion and several millimetres beyond it. These experiments, like those made in neonatal opossum (Treherne et al. 1992) demonstrate that central neurons of immature mammals, unlike those in adults, can respond to injury by rapid and extensive outgrowth of nerve fibres in the absence of peripheral nerve bridges or antibodies that neutralize inhibitory factors. However, unlike the opossum, in which outgrowth occurred at 24°C, although there was prolonged survival of rat spinal cords at this temperature, outgrowth of axons across the lesion required a temperature of 29°C. With rapid and reliable regeneration in vitro it becomes practicable to assay the effects of molecules that promote or inhibit restoration of functional connections.

Accumulation of laminin and microglial cells at sites of injury and regeneration in the central nervous system of the leech.

Profuse sprouting of leech neurons occurs in culture when they are plated on a substrate consisting of laminin molecules extracted from extracellular matrix that surrounds the central nervous system (CNS). To assess the role of laminin as a potential growth-promoting molecule in the animal, its distribution was compared in intact and regenerating CNS by light and electronmicroscopy, after it had been labelled with an anti-leech-laminin monoclonal antibody (206) and conjugated second antibodies. In frozen sections and electron micrographs of normal leeches the label was restricted to the connective-tissue capsule surrounding the connectives that link ganglia. Immediately after the connectives had been crushed the normal structure was disrupted but laminin remained in place. Two days after the crush, axons began to sprout vigorously and microglial cells accumulated in the lesion. At the same time, labelled laminin molecules were no longer restricted to the basement membrane but appeared within the connectives in the regions of neurite outgrowth. The distribution of laminin at these new sites within the CNS was punctate at two days, but changed over the following two weeks: the laminin became aggregated as condensed streaks running longitudinally within the connectives beyond the lesion. The close association of regenerating axons with laminin suggests that it may promote axonal growth in the CNS of the animal as in culture.

Neurite outgrowth through lesions of neonatal opossum spinal cord in culture

The aim of these experiments was to analyze neurite outgrowth during regeneration of opossum spinal cord isolated from Monodelphis domestica and maintained in culture for 3–5 days. Lesions were made by crushing with forceps. In isolated spinal cords of animals aged 3 days, neurites entered the crush and grew along the basal lamina of the pia mater. Growth cones with pleiomorphic appearance containing vesicles, mitochondria and microtubules were abundant in the marginal zone, as were synaptoid contacts with active zones facing basal lamina. In preparations from animals aged 11–12 days, the lesion site was disrupted and contained only degenerating axons, debris and vesicles. Axons and growth cones entered the edge of the lesion but did not extend into it. Lesions in young animals extended over distances of more than 1 mm and contained no radial glia. The damaged area in older preparations was restricted to the crush site with normal astrocytes, oligodendrocytes and neurons immediately adjacent to the lesion. Thus, similar crushes produced more extensive damage in younger spinal cords that were capable of regeneration than in older cords that were not. Dorsal root ganglion fibers labeled with carbocyanine dye (DiI) were observed by video imaging as they grew through lesions. Individual growth cones examined subsequently by electron microscopy had grown again along pial basal lamina. After 5 days in culture dorsal root stimulation gave rise to discharges in ventral roots beyond the lesion indicating that synaptic connections were formed by growing fibers.

Three-dimensional visualization of the distribution, growth, and regeneration of monoaminergic neurons in whole mounts of immature mammalian CNS

At birth, the opossum, Monodelphis domestica, corresponds roughly to a 14‐day‐old mouse embryo. The aim of these experiments was to compare the distribution of monoaminergic neurons in the two preparations during development and to follow their regeneration after injury. Procedures that allowed antibody staining to be visible in transparent whole mounts of the entire central nervous system (CNS) were devised. Neurons throughout the brain and spinal cord were stained for tyrosine hydroxylase (TH) and for serotonin (5‐HT). At birth, patterns of monoaminergic cells in opossum CNS resembled those found in 14‐day mouse embryos and other eutherian mammals. By postnatal day 5, immunoreactive cell bodies were clustered in appropriate regions of the midbrain and hindbrain, and numerous axons were already present throughout the spinal cord. Differences found in the opossum were the earlier presence of TH neurons in the olfactory bulb and of 5‐HT neuronal perikarya in the spinal cord. Most, if not all, monoaminergic neurons in opossum were already postmitotic at birth. To study regeneration, crushes were made in cervical cords in culture. By 5 days, 8% of all TH‐labeled axons and 14% of serotonergic axons had grown beyond lesions. Distal segments of monoaminergic axons degenerated. In CNS preparations from opossums older than 11 days, no regeneration of monoaminergic fibers occurred. Isolated embryonic mouse CNS also showed regeneration across spinal cord lesions, providing the possibility of using knockout and transgenic animals. Our procedures for whole‐mount observation of identified cell bodies and their axons obviates the need for serial reconstructions and allows direct comparison of events occurring during development and regeneration. J. Comp. Neurol. 390:427–438, 1998.

DEVELOPMENT AND MIGRATION OF OLFACTORY NEURONES IN THE NERVOUS SYSTEM OF THE NEONATAL OPOSSUM

The neonatal opossum (Monodelphis domestica) was used to assess how different populations of cells are generated in the olfactory region, and how they migrate along pathways to the central nervous system. Developing nerve cells were immunocytochemically labelled using antisera directed against two specific markers of olfactory receptor neurones: olfactory marker protein (OMP) and the dipeptide carnosine. In new-born opossums both carnosine and OMP are already co-expressed in primary olfactory neurones and in those axons that extend towards the olfactory bulb. Expression of these markers in olfactory receptor neurones during the first postnatal days reflects the advanced developmental state of this system compared to other regions of the central nervous system (such as the cortex and cerebellum), which are highly immature and less developed in comparison with those of new-born rats or mice. A second, distinct population of carnosine/OMP expressing cells was also identified during the first postnatal week. These neurones were present as clusters along the olfactory nerve bundles, on the ventral-medial aspect of the olfactory bulb and in the basal prosencephalon. The distribution of this cell population was compared to another group of well characterized migratory neurones derived from the olfactory placode, which express the decapeptide GnRH (Gonadotropin-releasing hormone, also known as LHRH). GnRH was never co-localized with carnosine/OMP in the same migratory cells. These observations show that distinct cell populations arise from the olfactory placode in the neonatal opossum and that they migrate to colonize the central nervous system by following common pathways.

Regulation of GABAB receptors by histamine and neuronal activity in the isolated spinal cord of neonatal opossum in culture

The aim of these experiments has been to analyse the properties of receptors for the transmitter γ-aminobutyric acid (GABA) in developing mammalian nervous system. Changes in responses of GABAB receptors have been measured after alterations of the chemical environment and the level of electrical activity. We have previously shown that when the central nervous system (CNS) of the new-born opossum, Monodelphis domestica, is cultured for three to five days in the presence of histidine, inhibition by baclofen, a GABAB agonist, disappears (Stewart et al. 1991). We have now investigated whether histidine acts indirectly by way of conversion to histamine. As with histidine, culture with 150 μm histamine for five days virtually abolished the inhibition by baclofen. The effects of histidine, as well as histamine, were blocked by mepyramine, a histamine H1-receptor antagonist, and by ranitidine, an H2-antagonist. Tetrodotoxin (TTX), which blocks all electrical activity, protected preparations from the action of histidine but not histamine. Our results suggest that histidine is converted to histamine, which reduces the efficacy of GABAB agonists. We conclude that, in the developing mammalian CNS, transmitter levels and electrical activity can selectively influence the properties of receptors.

Fine structure and development of dorsal root ganglion neurons and Schwann cells in the newborn opossum Monodelphis domestica

The aim of these experiments was to determine the state of maturity of dorsal root ganglia and axons in opossums (Monodelphis domestica) at birth and to assess quantitatively changes that occur in early life. Counts made of dorsal root ganglion cells at cervical levels showed that the numbers were similar in newborn and adult animals, approximately 1,600 per ganglion. In cervical dorsal root ganglia of newborn animals, division of neuronal precursors cells had ceased. The number of axons in cervical dorsal roots was similar in newborn and adult animals (about 4,500). For each ganglion cell body, approximately three axons were counted in the dorsal root. At birth, dorsal roots contained several bundles about 30 μm in diameter consisting of small axons (0.05–2 μm in diameter). A few non‐neural cells were identified as Schwann cell perikarya, each enclosing a number of neurites. Later, marked changes occurred in Schwann cells and in their relationship to axons in the roots. Thus, at 12 days, an increase occurred in the number of Schwann cells and fibroblasts, and the bundles had enlarged to about 80 μm with little increase in axon diameter (0.1–2 μm). By 18 days, the bundles were larger, and myelination had already started. At 23 days, the dorsal root contained more than 500 myelinated axons that could reach 5 μm in diameter. The adult dorsal root enclosed about 900 myelinated axons. Throughout this time, the relationship between the Schwann cells and axons changed. Together, these results indicate that the number of axons and cell bodies of sensory dorsal root ganglia in opossum do not show major changes after birth. In addition, these results set the stage for quantitative studies of regeneration of dorsal column fibers in injured neonatal opossum nervous system. J. Comp. Neurol. 396:338–350, 1998.

Chapter 21 Repair of connections in injured neonatal and embryonic spinal cord in vitro

A remarkable preparation for studying development and repair is the CNS of the newborn opossum which, removed in its entirety, survives in culture for more than 1 week. In suitable medium, cells continue to divide, mature and reflex activity is maintained. Moreover, nerve fibers grow rapidly, reliably and extensively across lesions made in the spinal cord. Restoration of conduction has been demonstrated by recording electrically; labeled fibres have been observed directly by light and electron microscopy as they traverse the lesion. Similar experiments have also been made in embryonic (E15) rat CNS in culture. Open questions concern the identity of the fibers that traverse the lesion and the specificity of connections that they make with targets. We are now also analysing mechanisms that favor repair in younger opossums and that prevent it in their older siblings. Of particular interest are oligodendrocytes and myelin that start to appear at about 8-9 days after birth.