Reciprocal Schwann cell-axon interactions.

This article describes the reciprocal interactions between neurones and Schwann cells with particular reference to the role of growth factors and neurokines as signalling molecules between these cells and of the extracellular matrix as a conduit for such signalling. Major recent advances have identified molecules produced by neurones that are responsible for Schwann cell proliferation, as well as some of the Schwann cell factors regulating the expression of molecules shown to play an important role in neuronal survival and differentiation.

Long-term sensory hyperinnervation following neonatal skin wounds.

Skin innervation during wound healing was investigated using immunocytochemical staining with the panneuronal marker antiprotein gene product (PGP) 9.5, which labels the entire innervation of the skin throughout development and in the adult. Full-thickness skin wounds in the hairy skin of the foot in neonatal rats result in pronounced hyperinnervation of the tissue that persists long after the wound has healed (at least 12 weeks). Quantification of this hyperinnervation by image analysis indicates that skin innervation density in the wounded area can increase up to 300%. The effect is greatest when wounds are performed at postnatal day (P) 0 or 7, declining when performed at P14 and P21 to resemble the weaker and transient effect in the adult. Staining with selective markers for different neuronal populations innervating skin (monoclonal anti-RT97 staining the myelinated axons of large light sensory ganglion cells; anticalcitonin gene-related peptide staining unmyelinated C axons, thinly myelinated A delta axons, and a subpopulation of large A fibres) reveal that both A- and C-fibre sensory axons contribute to this response. Destruction of the majority of the C-fibre population with neonatal capsaicin pretreatment, which leaves large A fibres intact, significantly reduces the hyperinnervation response at 14 days, confirming a major contribution from both A and C fibres. Sympathetic axons, stained with anti-tyrosine hydroxylase, do not sprout into the wounded area. Furthermore, pretreatment of neonates with 6-hydroxydopamine, which destroys the sympathetic innervation, does not significantly reduce the overall sprouting response, as identified by anti-PGP9.5 staining. Behavioural sensory testing revealed a 50% drop in the mechanical threshold in the wounded area after 3 weeks. These remarkably long-term and specific effects on sensory terminal axons following neonatal skin wounding indicate the plasticity of cutaneous innervation density following alterations in the target tissue at a critical stage of development.

Neonatal sciatic nerve section results in thiamine monophosphate but not substance P or calcitonin gene-related peptide depletion from the terminal field in the dorsal horn of the rat: the role of collateral sprouting.

The expression of substance P, calcitonin gene-related peptide (CGRP) and thiamine monophosphatase in the sciatic nerve terminal field of the lumbar dorsal horn of the rat was examined following neonatal sciatic nerve section and ligation. The total terminal field from L3 to L5 was mapped from semi-serial sections on the treated side and compared to equivalent maps on the contralateral intact side. To obtain a detailed time course of events, data were obtained 4, 7, 10, 15-20 and 40-60 days after sciatic nerve section. At 4-7 days thiamine monophosphate was depleted from the cut nerve terminals resulting in a gap in dorsal horn thiamine monophosphate stain similar to that seen after adult nerve section. In contrast, substance P and CGRP-containing terminals showed only a transient fall in expression in the first week following nerve section and then staining was no different from that seen on the control side. The depletion of peptides normally observed after adult nerve section did not occur. This phenomenon was only observed if the sciatic nerve was cut at birth. Nerve section at 10 days of age resulted in the same pattern of peptide depletion as is observed in the adult. A week after neonatal sciatic nerve section, thiamine monophosphate-containing nerve terminals from nearby intact nerves begin to sprout into the sciatic nerve territory in the dorsal horn. This, together with some recovery of thiamine monophosphate from the remaining sciatic terminals themselves, results in a slow filling in of the gap in the thiamine monophosphate stain. Resection of the cut sciatic nerve, together with adjacent intact nerves, re-establishes the depletion. Substance P and CGRP terminals from nearby intact nerves also sprout into the deafferented sciatic field and this can be demonstrated by the larger than normal area of depletion following section of these nerves when adult. Furthermore, resection of the neonatally cut sciatic nerve when adult also causes some depletion of substance P and CGRP within the sciatic field, indicating a degree of recovery or up-regulation of peptides in surviving cut afferents. However, even after resection of the cut sciatic nerve and nearby intact nerves, substance P and CGRP staining remained in the terminal region. We conclude that while central collateral sprouting does take place in both substance P and CGRP-containing afferents following peripheral nerve section, it cannot account for the lack of depletion of peptides observed.(ABSTRACT TRUNCATED AT 400 WORDS)

Partial denervation of the medial gastrocnemius muscle results in growth-associated protein-43 immunoreactivity in sprouting axons and Schwann cells.

Regeneration in the mammalian peripheral nervous system following nerve injury is associated with the upregulation of a developmentally regulated phosphoprotein, growth-associated protein-43 (GAP-43), in the injured neurons. We have examined whether uninjured adult neurons also express GAP-43 when they sprout. The model system investigated has been the sprouting induced in the terminal axons of intact motor neurons by a partial muscle denervation. Partial denervation of the medial gastrocnemius muscle in adult rats was produced by resecting the terminal nerve supply to the anterolateral quadrant of the muscle. Three zones could be identified in the motor endplate region of the muscle after such a denervation using protein gene product (PGP) 9.5, calcitonin gene-related peptide and silver staining as axonal markers and S-100 to identify Schwann cells: a normally innervated zone, a totally denervated zone and a border or intermediate zone between the two which contained axons at the endplates with nodal and terminal sprouts. The endplates in the normally innervated zone were GAP-43 negative. In the denervated zone, Schwann cells were GAP-43 positive and had a distinctive appearance with a lack of any normal endplate organization. Endplates in the intermediate zone were GAP-43 immunoreactive. In approximately half, the GAP-43 immunoreactivity was axonal-like, identical to PGP 9.5 in an adjacent section; in the remainder it was Schwann cell-like, identical to S-100 staining. Partial muscle denervation results, therefore, in the appearance of GAP-43 both in axons and Schwann cells in the endplates bordering the denervated zone. The presence of GAP-43 in these cells may contribute to their capacity to sprout.

Time-dependent differences in the increase in GAP-43 expression in dorsal root ganglion cells after peripheral axotomy.

Peripheral axotomy of primary afferent neurons results in the up-regulation of the growth-associated phosphoprotein GAP-43, by dorsal root ganglion cells. We have studied the temporal sequence of GAP-43 expression in those dorsal root ganglion neurons with unmyelinated axons (the small dark cells) and in those with myelinated axons (the large light cells) after sciatic nerve section in the adult rat. Immunoreactivity for the RT 97 neurofilament epitope, which is detectable only in large light dorsal root ganglion cells, was used to differentiate the two types of dorsal root ganglion cell. Within two days of a sciatic nerve section the number of GAP-43-immunoreactive profiles in the ipsilateral ganglion had increased five-fold and this increase persisted for 80 days post-section. While 50% of the small numbers of GAP-43-positive cells in control ganglia were RT 97 positive, only 8% of the large number of GAP-43-immunoreactive cells four days post-section, were RT 97 positive. By 14 days the number of RT 97-positive/GAP-43-positive cells had increased to 29%. This was paralleled by an increase in GAP-43 immunoreactivity in large diameter profiles at 14 days. The signals that alter GAP-43 expression in unmyelinated (small, RT 97 -ve) and myelinated (large, RT 97 +ve) afferents after peripheral nerve injury appear to operate with different time-courses.

GAP-43 expression in the developing rat lumbar spinal cord.

The expression of the growth-associated protein GAP-43, detected by immunocytochemistry, has been studied in the developing rat lumbar spinal cord over the period E11 (embryonic day 11), when GAP-43 first appears in the spinal cord, to P29 (postnatal day 29) by which time very little remains. Early GAP-43 expression in the fetal cord (E11-14) is restricted to dorsal root ganglia, motoneurons, dorsal and ventral roots and laterally positioned and contralateral projection neurons and axons. Most of the gray matter is free of stain. The intensity of GAP-43 staining increases markedly as axonal growth increases, allowing clear visualization of the developmental pathways taken by different groups of axons. Later in fetal life (E14-19), as these axons find their targets and new pathways begin to grow, the pattern of GAP-43 expression changes. During the period, GAP-43 staining in dorsal root ganglia, motoneurons, and dorsal and ventral roots decreases, whereas axons within the gray matter begin to express the protein and staining in white matter tracts increases. At E17-P2 there is intense GAP-43 labelling of dorsal horn neurons with axons projecting into the dorsolateral funiculus and GAP-43 is also expressed in axon collaterals growing into the gray matter from lateral and ventral white matter tracts. At E19-P2, GAP-43 is concentrated in axons of substantia gelatinosa. Overall levels decline in the postnatal period, except for late GAP-43 expression in the corticospinal tract, and by P29 only this tract remains stained.

GAP-43 expression in developing cutaneous and muscle nerves in the rat hindlimb.

The expression of the growth associated protein, GAP-43, in developing rat hindlimb peripheral nerves has been studied using immunocytochemistry. GAP-43, is first detected in lumbar spinal nerves at embryonic day (E)12 as the axons grow to the base of the hindlimb. It is expressed along the whole length of the nerves as well as in the growth cones. GAP-43 staining becomes very intense over the next 36 h while the axons remain in the plexus region at the base of the limb bud before forming peripheral nerves at E14. It remains intense along the length of the growing peripheral nerves, the first of which are cutaneous, branching away from the plexus and growing specifically to the skin, their axon tips penetrating the epidermis of the proximal skin at E15 and the toes at E19. GAP-43-containing terminals form a dense plexus throughout the epidermis which subsequently withdraws subepidermally in the postnatal period. GAP-43 staining is also evident along the growing muscle nerves during muscle innervation, which follows behind that of skin. Axons branch over the surface of proximal muscles at E15 but do not form terminals until E17. As target innervation proceeds, GAP-43 staining declines in the proximal part of the nerve but remains intense in the distal portions. Overall GAP-43 expression in the hindlimb decreases in the second postnatal week as axon growth and peripheral terminal formation decline.

Decreased skin sensory innervation in transgenic mice overexpressing insulin-like growth factor-II.

Cutaneous sensory innervation was studied in transgenic mice overexpressing insulin-like growth factor II using a keratin promoter. The skin area of these animals is enlarged providing increased target for sensory neurons. L4 dorsal root ganglion cell counts revealed that the total number of sensory neurons was the same in transgenics as control animals. Levels of nerve growth factor per unit weight of skin were also unchanged. The cutaneous nerves of the hindlimb were immunostained with the pan-neuronal marker PGP 9.5 in transgenic and control mice at postnatal day 0 and 21. The innervation in transgenic mice was markedly reduced, particularly in superficial dermis and epidermis and in some areas innervation was completely absent. The effect was greatest in distal skin regions and increased with age. Since insulin-like growth factor II has been reported to be a sensory neurotrophic factor, its effect on neurite outgrowth was tested on embryonic day 14 and 18 mouse lumbar dorsal root ganglion explants in culture. Under these conditions insulin-like growth factor II (5-100 ng/ml) did not have strong growth promoting activity and at embryonic day 18, in the presence of 5-10 ng/ml nerve growth factor, neurite outgrowth was suppressed by insulin-like growth factor II. The results show that increased skin target and availability of nerve growth factor per se do not alter the number of innervating sensory neurons. However, reduced sensory terminal arborization and skin hypoinnervation does occur in the presence of excess insulin-like growth factor-II. It is possible that insulin-like growth factor-II inhibits terminal axon growth directly via receptors on sensory neurons or peripheral glia.

The growth-associated protein GAP-43 appears in dorsal root ganglion cells and in the dorsal horn of the rat spinal cord following peripheral nerve injury.

When adult dorsal root ganglion cells are dissociated and maintained in vitro, both the small dark and the large light neurons show increases in the growth-associated protein GAP-43, a membrane phosphoprotein associated with neuronal development and plasticity. Immunoreactivity for GAP-43 appears in the cytoplasm of the cell bodies as early as 3.5 h post axotomy and is present in neurites and growth cones as soon as they develop. At early stages of culture (4 h to eight days) satellite/Schwann cells are also immunoreactive for GAP-43. Neurons in isolated whole dorsal root ganglion maintained in vitro become GAP-43-immunoreactive between 2 and 3 h after axotomy. It takes three days however, after cutting or crushing the sciatic nerve in adult rats in vivo, for GAP-43 immunoreactivity to appear in the axotomized dorsal root ganglion cells. GAP-43 immunoreactivity can be detected in the central terminals of primary afferent neurons in the superficial laminae of the dorsal horn of the lumbar enlargement four days after sciatic cut or crush. The intensity of the GAP-43 staining reaches a peak at 21 days and becomes undetectable nine weeks following crush injury and 36 weeks following sciatic nerve cut. The pattern of GAP-43 staining is identical to the distribution of sciatic small-calibre afferent terminals. Little or no staining is present in the deep dorsal horn, but GAP-43 does appear in the ipsilateral gracile nucleus 22 days after sciatic injury. In investigating the mechanism of GAP-43 regulation, blockade of axon transport in the sciatic nerve with vinblastine (10(-5) M-10(-4) M) or capsaicin (1.5%) was found to produce a pattern of GAP-43 immunoreactivity in the dorsal horn identical to that found with crush, while electrical stimulation of the sciatic nerve had no effect. Axotomy of primary sensory neurons or the interruption of axon transport in the periphery therefore acts to trigger GAP-43 production in the cell body. The GAP-43 is transported to both the peripheral and the central terminals of the afferents. In the CNS the elevated GAP-43 levels may contribute to an inappropriate synaptic reorganization of afferent terminals that could play a role in the sensory disorders that follow nerve injury.

Binding of [3H]phenycyclidine to rat and human blood constituents.

The binding of [3H]phencyclidine (PCP) to rat serum and human plasma was studied using equilibrium dialysis. [3H]PCP bound with a relatively low affinity to both rat serum (KD = 1.5 X 10(-5) M) and human plasma (KD = 6.2 X 10(-6) M). However, the binding capacity was quite large for rat serum (5.7 nmoles/ml) and human plasma (5.6 nmoles/ml). Binding was readily reversible as shown by the efflux of [3H]PCP from a dialysis bag containing the rat serum-drug complex. In addition, the [3H]PCP-human serum complex appeared to dissociate completely when analyzed by Sephadex gel filtration chromatography. The low affinity of PCP for serum appeared to account in large part for the high tissue-to-plasma ratios that are observed in animals and humans injected with this drug. In vitro equilibration of [3H]PCP between rat serum and tissue homogenates resulted in at least a 10-fold accumulation of [3H]PCP in the homogenates. [3H]PCP was found to bind weakly to the major protein components of human serum (macroglobulins, immunoglobulins and albumins). The weak nature of the binding to serum proteins coupled with the relatively high capacity of binding probably account for the failure of other drugs to compete for PCP binding.

Nerve growth factor levels in developing rat skin: upregulation following skin wounding.

Levels of nerve growth factor (NGF) in rat hindpaw skin, measured with a sensitive two-site enzyme-linked immunosorbent assay, show two peaks during normal development. The first (57 +/- 5 pg mg-1) occurs at embryonic days (E) 18-20 and coincides with the arrival of axon terminals into the hindpaw skin. The second, larger peak (132 +/- 10 pg mg-1), occurs later, around postnatal day (P) 21 and may be involved in maintenance of neuronal phenotype. Levels outside the two peaks stay relatively constant throughout development (30 pg mg-1). Skin wounding at birth produces a marked increase in NGF levels (149 +/- 25 pg mg-1) which declines after 4 days. This large increase is not observed if wounding is performed at older ages and may underlie the sensory hyperinnervation that accompanies neonatal wounds.

CSF-brain permeability in the immature sheep fetus: a CSF-brain barrier.

The permeability of the neuroependyma between CSF and brain extracellular space has been studied in fetal sheep of 60 and 125 days gestation. Both radioactive ([3H]inulin, [14C]sucrose, [125I]albumin) and visible (horseradish peroxidase) markers have been perfused through the ventricular system for periods of up to 5 h in anaesthetized exteriorized fetal sheep whose physiological condition was monitored continuously. A previously undescribed barrier between CSF and brain extracellular fluid has been discovered in the immature (60-day) fetal sheep. Horseradish peroxidase penetration was confined to a limited depth of the neuroependyma and was mainly into the cells lining the cerebral ventricles; in older fetuses there was extracellular penetration to a distance of several millimetres from the ventricular surface, as previously described in adult animals. The volumes of distribution of sucrose and insulin were less in the immature brain than in the more mature brain, which may be a reflection of restricted diffusion across the neuroependyma in the younger brains. The morphological nature of the barrier in fetuses of 60 days and younger appears to be a membrane specialization between the cells of the neuroependyma. It is of a type not previously described; it seems to have the effect of narrowing rather than obliterating the extracellular pathway between CSF and brain. The possible functional significance of this observation is discussed.

Comparison of proteins in CSF of lateral and IVth ventricles during early development of fetal sheep.

This study examines the relationship between plasma proteins in blood and in CSF in the developing brain of sheep fetuses between 30 and 60 days gestation. Five proteins account for the very high concentration of protein in fetal CSF (over 1000 mg/100 mg/100 ml at 30 days): alpha-feto-protein, fetuin, albumin, alpha 1-antitrypsin and transferrin; the concentration of each protein is similar in lateral and IVth ventricular CSF at 30 days. By 40 days there is considerable decrease in protein concentration in lateral ventricular CSF. At this age in the IVth ventricle the overall total was unchanged, although there were changes in concentration of individual proteins. At 60 days the concentration of each protein in both compartments had fallen below that at 40 days; the marked concentration difference between lateral and IVth ventricular CSF was still present. Experiments using i.v. [125I]- or [3H] labeled plasma proteins in 30-40-day fetuses showed that very little protein penetrated into lateral ventricular CSF by 3-5 h after injection; in the same experiments [125I]albumin reached a CSF/plasma ratio of about 15% in the IVth ventricle (compared with 55% for the natural steady state). Autoradiographic studies carried out on material from the same animals did not give evidence for transfer of labeled protein across the choroid plexuses although any such penetration may have been below the threshold of the method. Other explanations for the high concentration of protein in CSF that were considered include penetration via cerebral vessels and synthesis of plasma proteins by choroid plexus epithelial cells or neurons within the brain.

Synthesis of plasma proteins by rat fetal brain and choroid plexus.

Several plasma proteins have previously been demonstrated to be within cells (presumed neurons) in the developing brain of various species. The possibility that the plasma proteins α-fetoprotein (AFP) albumin and transferrin may be synthesized by developing brain and choroid plexus has been investigated in fetal rats of 18 to 22 days gestation. Samples of these tissues and of liver were incubated in Krebs solution containing [(3)H]leucine at 37°C for 1 h. Radioactively labelled AFP, albumin and transferrin were extracted and separated by immunoprecipitation. Incorporation of [(3)H]leucine into the plasma proteins was demonstrated in both fetal brain and choroid plexus. Incorporation was completely blocked by cycloheximide. It is concluded that fetal brain and choroid plexus synthesize AFP, albumin and transferrin and that secretion of these proteins by developing brain and choroid plexus cells probably contributes to the high concentration of plasma proteins in fetal csf.

Distribution of the growth associated protein GAP-43 in the central processes of axotomized primary afferents in the adult rat spinal cord; presence of growth cone-like structures.

GAP-43-immunolabelled structures were visualized by electron microscopy in the adult rat L4-L5 superficial dorsal horn 2 weeks after sciatic nerve transection. The majority of immunolabelled elements were unmyelinated axons, but some synaptic terminals and myelinated axons also labelled. The labelled unmyelinated axons were commonly located in prominent bundles which on serial section analysis could be followed into larger single trunks. These enlargements contain many organelles and give rise to smaller processes, which is compatible with their being growth cones. Sciatic nerve transection may result, therefore, in central regenerative processes which reorganize the neuropil and contribute to the decreased sensibility and pain that follows peripheral nerve section.

The distribution of plasma proteins in the neocortex and early allocortex of the developing sheep brain.

The histogenesis of the cerebral neocortex and early allocortex of the sheep has been described and, using an immunohistochemical technique, five plasma proteins have been identified in the telencephalic wall and their distribution followed during its differentiation. The development of the neocortex was studied from 18 days gestation, when the neural tube was still open, to 120 days, when the adult structure was established. A primordial plexiform layer was formed above the ventricular zone by 25 days and by 35 days this layer was divided by the differentiating cortical plate into an outer marginal zone and an inner subplate zone. The appearance of the subventricular and intermediate zones by 50 days gestation completed the formation of the neocortical layers. The differentiation of the allocortex was generally less advanced than the neocortex up to 40 days gestation, when the primordium of the pyramidal layer was beginning to develop. The five plasma proteins identified, fetuin, alpha-fetoprotein, albumin, transferrin and alpha 1-antitrypsin, are quantitatively the most important in the csf and plasma of the sheep fetus. Fetuin was the earliest plasma protein to be detected in the brain and it was also the most widespread; positive staining for this protein was seen in cells and fibres of all layers as they differentiated and could still be identified in some mature neurons at 120 days. alpha-Fetoprotein and albumin had a limited distribution, appearing in cells in the developing cortical plate for a short period early in gestation (35-40 days), but mainly confined to the ventricular zones later and barely detectable by 80 days gestation. Transferrin appeared to have a different distribution, being detected in fibres first in the primordial plexiform layer and then in the marginal and subplate zones, only later being identified in cells of the cortical plate. From their distribution it is suggested that fetuin and transferrin may play an important role in the differentiation of the cortex and the establishment of correct connections between fiber systems and migrating cells at certain stages of development. alpha 1-Antitrypsin was only found in a few cells during a restricted period of gestation. All five plasma proteins were identified in precipitated csf and plasma at most ages examined, although at 18 days gestation albumin, transferrin and alpha 1-antitrypsin and at 120 days, alpha-fetoprotein, could not be detected.(ABSTRACT TRUNCATED AT 400 WORDS)

The distribution of plasma proteins during early embryonic development in the sheep.

The distribution of the five plasma proteins that are quantitatively most important during development in the sheep has been studied in embryos of 15 to 21 days gestation. The three primary embryonic layers and tissues that differentiate from them were tested for the presence of alpha-fetoprotein (AFP), fetuin, albumin, transferrin and alpha 1-antitrypsin using the indirect immunoperoxidase method. Fetuin was the most prominent of these proteins particularly in the developing central nervous system. Fetuin and transferrin appeared early in the differentiating mesoderm and, with albumin and AFP, were detected in tissues originating from all three layers during the course of development. alpha 1-Antitrypsin appeared to have a limited distribution. All five plasma proteins were detected before the establishment of a circulatory system. It is suggested that their appearance in embryonic tissue is related to its stage of development and that they play an important part in early differentiation.

Origin and fate of fetuin-containing neurons in the developing neocortex of the fetal sheep.

The development of the neocortex has previously been extensively studied in carnivores (cat and ferret), rodents (rat and mouse) and primates (monkey and human). In these species, it has been shown that the initial population of cells migrating from the ventricular zone forms the primordial plexiform layer. This is subsequently split into marginal zone and subplate zone by the insertion of later-migrating cells into the primordial plexiform layer, to form the cortical plate proper. Many of the cells derived from the split primordial plexiform layer are transient. The neurons of the subplate zone are found in the deeper part of layer VI, and white matter deep to layer VI in the more mature cortex; most of these neurons disappear by adulthood. [3H]-thymidine labelling in the present study has shown a similar pattern of neocortical development in Artiodactyla (sheep). In addition it has been shown that the previously described staining of subplate and cortical plate cells for the fetal protein fetuin indicates that fetuin is a useful marker for a proportion of this transient population of neurons and defines its extent in neocortical development more clearly. Dividing cells were labelled by a single intra-amniotic injection of [3H]-thymidine at E26 to E35 (birth is at E150). The brains were subsequently examined at E40 or E80 for [3H]-thymidine labelling and fetuin staining by a combination of autoradiography and immunocytochemistry. The earliest generated neocortical cells detected in this study (E26) were found in two layers by E40, the outer marginal zone and inner subplate zone. Neurons of the marginal zone were generated up to E28; those of the early subplate zone were generated up to E31. The cortical plate proper was generated by cells "born" on E32 and later. This sequence is similar to that described in other species, especially the cat. A proportion of the early-generated neurons in the marginal zone, subplate zone and early cortical plate stained for fetuin. By E80 these earliest-generated, fetuin-positive cells were found in the white matter deep to the forming neocortical layers and in layer VI. In adult brains no fetuin-positive neurons could be identified in the neocortex, and neurons had almost entirely disappeared from the white matter. The fetal glycoprotein fetuin seems to be specifically associated with a population of cells that has the same developmental history as the transient marginal zone and subplate neurons described in other species.(ABSTRACT TRUNCATED AT 400 WORDS)

Fetuin as a marker of cortical plate cells in the fetal cow neocortex: a comparison of the distribution of fetuin, alpha 2HS-glycoprotein, alpha-fetoprotein and albumin during early development.

Fetuin, alpha 2HS-glycoprotein (alpha 2HS), alpha-fetoprotein (AFP) and albumin have been shown to be present in some regions of the neocortex in two early stages of development of the cow brain using PAP immunocytochemistry. In the pre-cortical plate stage fibres of the primordial plexiform layer stained positively for fetuin. No staining was seen for albumin but plasma and cerebrospinal fluid (CSF) were positive for alpha 2HS and AFP. In the early cortical plate stage the strongest fetuin positive staining was seen in the earliest formed cells of the plate. alpha 2HS staining was much less intense but similar in distribution. The possible role of fetuin, or related glycoproteins, in cortical plate differentiation is discussed. Staining for AFP and for albumin was seen mainly in the ventricular zone and marginal zone fibres, and had a similar distribution and intensity for both proteins. Plasma and CSF stained for all four proteins. Tests showed some cross-reactivity between fetuin and anti-alpha 2HS and, to a much lesser extent, between antisera to AFP and albumin and antigens denatured by fixation.

Postnatal development of the telencephalon of the tammar wallaby (Macropus eugenii). An accessible model of neocortical differentiation.

The sequence of development of cell layers in the neocortex of the tammar has been followed from 24 days gestation to 213 days postnatal. The tammar is born at 27 days gestation and the major period of its development occurs during the subsequent 250 days, most of this time being spent within the pouch. Although the pattern of differentiation of the cell layers appears to resemble that described for many Eutherian mammals, the neocortex is at an embryonic 2 layered stage at birth and a cortical plate is not present throughout the telencephalon until 10-15 days postnatal. A transient subplate zone, presenting a characteristic appearance with widely spaced rows of cells aligned parallel to the cortical surface, develops between 20 and 70 days postnatal, but no secondary proliferative region is seen in the subventricular zone of the dorso-lateral wall. Preliminary experiments with (3H)-thymidine injections indicate that the cortical plate follows the "inside-out" pattern of development described in many Eutherian mammals and that the oldest neurons are found in the parallel cell rows of the subplate zone. The importance of the late differentiation of the neocortex in relation to the time of birth and the resulting usefulness of the tammar as an experimental model of cortical development is discussed.