Localization of Pi class glutathione-S-transferase in the forebrains of neonatal and young rats: evidence for separation of astrocytic and oligodendrocytic lineages.

The Yp isoform (Pi class) of glutathione-S-transferase has recently been localized in oligodendrocytes in the brains of mature rats. To examine at what postnatal age Pi first appears in oligodendrocytes or precursor cells, antibodies against Pi were used to immunostain tissue sections from the forebrains of neonatal rats and young rats up to 17 days of age. In the brains of neonates Pi immunofluorescence was observed in ovoid cells in the subependymal layer, and in ovoid cells and cells bearing short, thick processes in the corpus callosum and cingulum. These cells did not immunostain for vimentin. During the first postnatal week Pi-positive cells showed positive immunostaining for ganglioside GD3, which is characteristic of oligodendrocyte precursors, and process-bearing Pi-positive cells appeared in the cingulum and at the lateral borders of the corpus callosum in increasing numbers. During the second postnatal week the cytoplasm of Pi-positive cells became more compact, and the processes thinner, and the Pi-positive cells and their processes began to immunostain for 2',3'-cyclic nucleotide-3'-phosphohydrolase, which is characteristic of immature and mature oligodendrocytes and myelin sheaths. By age 17 days Pi was observed in relatively mature oligodendrocytes. The observations suggest that Pi occurs in oligodendrocyte precursors, immature oligodendrocytes, and mature oligodendrocytes in the postnatal through 17 day old rat forebrain. In the accompanying paper (Cammer and Zhang, '92)--if references are permitted in the Abstract a different glutathione-S-transferase isoform, Yb (Mu class), was localized in cells of the astrocyte lineage, beginning in the forebrains of neonatal rats.(ABSTRACT TRUNCATED AT 250 WORDS)     

The distribution of glial fibrillary acidic protein and vimentin in postnatal marmoset (Callithrix jacchus) brain

Antisera to glial fibrillary acidic protein (GFAP) and vimentin were used to elucidate the distribution of these intermediate filament proteins in postnatal marmoset brains of various ages. The ependyma of the lateral ventricles was unique in being equally immunoreactive for both GFAP and vimentin at all ages. Vimentin alone was consistently demonstrated in endothelial and leptomeningeal cells at all ages. In neonates, vimentin immunoreactivity greatly exceeded that of GFAP and was located primarily in radial glia in the subependymal plate of the anterior cerebrum. Their vimentin-positive processes formed thick fascicles in the corpus callosum but separated into fine fibres on entering the cortex. GFAP immunoreactivity in these cells and processes was very limited. With age, GFAP-positive cells increased in number and displayed the typical stellate appearance of astroglia. The vimentin-positive radial glial population decreased considerably during this period and by 6 months had virtually disappeared. The GFAP reaction in adult brain was even more widespread, largely due to the increased number of positive astrocytes in the white matter. Vimentin immunoreactivity in the adult was greatly diminished and positive radial glia were not detectable. A major change in intermediate filament protein expression, therefore, occurs in the early postnatal period and probably reflects phases in the differentiation of radial glial precursors into astrocytes.     

Carbonic anhydrase in distinct precursors of astrocytes and oligodendrocytes in the forebrains of neonatal and young rats.

Carbonic anhydrase is present in oligodendrocytes and astrocytes in the mature rat brain. Whereas carbonic anhydrase-positive oligodendrocyte precursors had been identified during the first postnatal week, no information was available about the earliest occurrence of carbonic anhydrase in the astrocytic cell line, nor had carbonic anhydrase been detected in astrocytes in neonatal rat brains. Beginning on the first postnatal day, rat brains were double immunostained with anti-carbonic anhydrase II and respective 'markers' for immature and mature astrocytes and oligodendrocytes. During the first postnatal week there were intensely carbonic anhydrase-positive cells which were ovoid or had broad processes. On the basis of their shapes and antigen contents these were considered to be precursors of oligodendrocytes. Beginning on the first postnatal day carbonic anhydrase II was also observed in some vimentin-positive radial glia and in other vimentin-positive cells that differed in their appearance from the immature oligodendrocytes. The vimentin-positive, carbonic anhydrase-positive cells were less smooth-surfaced, and had much finer processes, than the oligodendrocyte precursors. By the third postnatal day there appeared carbonic anhydrase-positive, glial fibrillary acidic protein (GFAP)-positive cells that resembled the vimentin-positive cells. It is concluded that the latter are immature astrocytes and that carbonic anhydrase is in distinct precursors of oligodendrocytes and astrocytes as early as the first postnatal day.     

Development of glial cells in the cerebral wall of ferrets: direct tracing of their transformation from radial glia into astrocytes

Coronal sections of the cerebral wall from developing ferrets (newborn to adult) were double-stained with antibodies to vimentin and glial fibrillary acidic protein (GFAP). At birth, the dominant glial population was radial glia and these cells labeled only for vimentin. A small population of immature astrocytes in the cortical plate was double labeled for GFAP and vimentin. In successive days, the number of vimentin-positive radial glia gradually decreased and they disappeared entirely at about 21 days. During this same period, the double-stained astrocytes increased in number and were distributed throughout the cortical plate and intermediate zone. After 6 weeks of age the astrocytes were mostly confined to the developing white matter. Around this time they gradually lost their vimentin staining, and in the adult no vimentin-positive elements were seen except at the ependymal surface. In newborn ferrets single radial glial cells were also visualized by applying the carbocyanine dye DiI onto the pial surface of fixed brains. While most radial glia extended from the ventricular zone to the pial surface, a substantial fraction of them had lost their contact to the ventricular zone. Their somata were displaced into the subventricular zone and lower portion of the intermediate zone. The possibility that radial glia transform into astrocytes was directly tested by injecting fluorescent dyes under the pial surface of newborn ferrets at a time when virtually no GFAP-positive astrocytes are present. The tracer, which was taken up in the upper portion of the cortical plate, stained the radial glial cell somata in the ventricular zone in a similar way as the dye DiI did in the fixed brains. As the radial glial cells disappeared at successively longer survival times, the tracer was ultimately found within newly formed GFAP-positive astrocytes. These results provide strong support for the hypothesis that radial glia cells are the immature form of astrocytes (Choi and Lapham: Brain Res. 148:295-311, '78; Schmechel and Rakic: Anat. Embryol. (Berl.) 156:115-152, '79), and also show that, at least in the ferret cortex, the transformation is accompanied by a change in the expression of intermediate filament protein.     

Expression of GFAP immunoreactivity during development of long fiber tracts in the rat CNS

Astrocyte maturation in the developing corpus callosum and dorsal columns of the spinal cord was studied immunocytochemically in the rat, using antiserum to glial fibrillary acidic protein (GFAP) with a view to determining the relationships of astrocytes to the advancing axons of the corpus callosum and corticospinal tract. Between the eighteenth and nineteenth days of gestation, when the corpus callosum commences forming, most of the GFAP staining in the cerebral hemispheres is contained in radial processes, but some staining of glial cell bodies is also seen in the ventricular zone. At the region of interhemispheric fusion, where the corpus callosum will form, an accumulation of astrocytic processes demonstrable electron microscopically shows light immunocytochemical staining for GFAP. These processes do not adopt a stereotyped orientation. Rather, the overall impression as one moves towards the midline, is of radially disposed processes being disrupted and disoriented by the growing callosal axons at the fusion of the hemispheres. At no time can any orderly arrangement of GFAP-containing processes be seen which might indicate that the processes are serving to guide the growing axons across the midline. There is no immunoreactive staining of cell bodies or processes ventral to the corpus callosum, except in postnatal animals. Prior to the arrival of corticospinal axons in the spinal cord on the first postnatal day (PO)21, GFAP immunoreactivity is greatest in radial processes of the lateral funiculi and in the dorsal median septum. Oblique or vertical processes increase in the cuneate fasciculus from P0 tot P4 but do not appear in the gracile fasciculus until P4. Virtually no stained processes appear in the region to be traversed by the principal corticospinal tract, nor later in the tract itself until late in postnatal development. Only by 3 weeks postnatal is the adult pattern of GFAP staining observed in the corticospinal tract. These results also indicate that the expression of GFAP immunoreactivity is a relatively late phenomenon in astrocytes associated with advancing axons and implies that this aspect of astrocytic maturation is unrelated to any guidance that the immature astrocytes might provide for the growing axons.     

Developmental fates and migratory pathways of dividing progenitors in the postnatal rat cerebellum

To investigate the developmental fates and the migratory pathways of dividing progenitors in both the white matter (WM) and the external granule layer (EGL) in the early postnatal rat cerebellum, a replication-deficient retrovirus carrying the β-galactosidase gene (BAG) was injected into the deep cerebellar tissue or the EGL of postnatal rats to label dividing progenitors. After 1–3 days post-injection (1–3 dpi) of BAG into the deep cerebellar tissue of postnatal day 4/5 (P4/5) rats, labeled immature, unipolar cells were found mainly in the WM. From 4 to 6 dpi, similar cells appeared in the internal granule (IGL), Purkinje cell, and molecular layers, although about half of the labeled cells still resided in the WM and appeared immature. The first morphologically definable Bergmann glia, astrocytes, and oligodendrocytes were also observed. From 14 to 20 dpi, most labeled cells had developed into Bergmann glia, astrocytes, oligodendrocytes, and interneurons in their appropriate layers. When BAG injections were performed at P14, unipolar cells were initially observed, but the majority of these differentiated into myelinating oligodendrocytes in the WM and IGL by 17 dpi. Few immature cells were labeled by injections administered at P20, and these did not develop into mature glia, but into cells with lacy, fine processes, possible representing immature oligodendrocytes. In contrast, BAG-labeled progenitors of EGL produced only granule neurons. Thus, within the first 2 postnatal weeks, dividing progenitors in the WM migrate as immature cells into the cortex before differentiating into a variety of glia and interneurons. The genesis of oligodendrocytes continues through the 2nd postnatal week and largely ceases by P20. EGL cells do not produce glia, but only granule cells. © 1996 Wiley-Liss, Inc.     

Ganglioside GD3 in radial glia and astrocytes in situ in brains of young and adult mice

Ganglioside GD3 occurs in immature cells in the neuroectoderm. However, with regard to particular cellular locations of GD3, rat brain has received more attention than mouse brain. In brains from neonatal mice the most intense GD3 immunostaining appears to occur in structures that differ from those that immunostain the most intensely in brains from neonatal rats (Cammer and Zhang: J Histochem Cytochem 44: 143–149, 1996). In the present study epifluorescence and confocal microscopy were used for the purpose of identifying the types of GD3-immunopositive structures in brains of neonatal, 2-week-old, and adult mice. Vibratome sections from mouse brains were double immunostained for GD3 and respective markers for macrophages, microglia, and cells belonging to the oligodendrocyte lineage. Surprisingly, none of those marker antigens immunostained intensely in the same respective structures as GD3. The GD3-positive structures, however, did resemble protoplasmic astrocytes and radial glia, some with GD3-positive end-feet at the glia limitans; however, we did not rule out the possibility that there might be some GD3 on the surfaces of prooligodendroblasts. The scarcity of glial fibrillary acidic protein (GFAP)-positive cells in brains of neonatal mice made it impractical to look for GD3+/GFAP+ structures that might belong to the astrocyte lineage. The Mu subunit of glutathione-S-transferase (Mu) was shown to label radial glia and the few GFAP-positive cells in brains of neonatal mice. Subsequently, confocal microscopy showed Mu and GD3 to be colocalized in radial glia and protoplasmic astrocytes in the neonate. In brains from mice ≥2 weeks of age GD3 immunostaining was demonstrated in GFAP-positive astrocytes, including reactive astrocytes. Much of the GD3 appeared to occur at the tips of astrocyte processes. It is suggested that GD3 in radial glia and astrocytes may function as a ligand enabling recognition of those structures by neurons or as a precursor of more complex gangliosides in neurons. © 1996 Wiley-Liss, Inc.     

Multifocal pattern of postnatal development of the macroglial framework of the rat fimbria

The development of the rat fimbria over the first postnatal month is associated with an approximate doubling of the tract diameter, a large increase in the number of glial cells, and the transformation of the prenatal radial glial skeleton into the adult interfascicular glial rows of solitary astrocytes and contiguous myelinating oligodendrocytes. The ventricular zone is reduced from a heterogeneous germinal layer of three or more cells thick at birth to the mature adult unicellular ependyma of homogeneous pale, mitotically inactive cells by the end of the second postnatal week. Mitoses are present throughout the body of the tract at all times, and persist, at reduced levels, in the adult. At birth the interior of the fimbria has only few scattered glial cell nuclei, largely solitary, or at most in longitudinal pairs. Over the first two postnatal weeks, the numbers and density of the interfascicular glia increase continuously. The scattered cells and cell clusters become progressively transformed into longer unicellular rows, which are aligned along the longitudinal axis of the tract, and which finally coalesce to form the continuous regular astrocyte/oligodendrocyte units that make up the interfascicular glial rows of the adult fimbrial glial skeleton. The increased cell packing density of the developing fimbrial glia is associated with a substantial decrease in nuclear and cytoplasmic size. From the end of the second postnatal week, the characteristic, large pale solitary astrocytes, and the smaller, more numerous, densely stained, closely packed oligodendrocytes are recognisable. Immunostaining for glial fibrillary acidic protein shows that immediately after birth the characteristic embryonic pattern of regular parallel radial glial processes starts to be modified by the progressive accumulation of longitudinal astrocytic processes, so the prenatal radial glial framework is rapidly transformed into the adult type of rectilinear array of radial and longitudinal processes. The development of the oligodendrocytes is shown clearly by immunostaining for myelin basic protein in enlarged, cytoplasm-rich, symmetrically placed cell pairs first seen at around P7. At P8-P10, there is a characteristic pattern of simultaneous multifocal maturation in which a single oligodendrocyte in each cluster develops a full complement of parallel, rather varicose myelinating processes. By P14 myelination is becoming confluent, oligodendrocytes are smaller, darker, with little cytoplasm, and individual myelinating processes cannot be discerned. Even at the end of the first postnatal month there are still many immature glia of indeterminate morphology. Myelination tends at first to be concentrated in the region adjacent to the hippocampus, and only reaches strengthen the hope that it may in future become possible to devise some form of self-reconstruction of the damaged adult glial tract structure in traumatic lesions completion by the end of the second month. During the first postnatal week, the entire array of fimbrial axons is traversed by the entire population of dentate neuroblasts. The highly vascular connective tissue on the pial surface of the fimbria is occupied by a prominent but transient population of mast cells which disappear in the adult.     

Organization of radial and non-radial glia in the developing rat thalamus

The organization of glia and its relationship with migrating neurons were studied in the rat developing thalamus with immunocytochemistry by using light, confocal, and electron microscopy. Carbocyanine labeling in cultured slice of the embryonic diencephalon was also used. At embryonic day (E) 14, vimentin immunoreactivity was observed in radial fascicles spanning the neuroepithelium and extending from the ventricular zone to the lateral surface of the diencephalic vesicle. Vimentin-immunopositive fibers orthogonal to the radial ones were also detected at subsequent developmental stages. At E16, radial and non-radial processes were clearly associated with migrating neurons identified by the neuronal markers calretinin and gamma-aminobutyric acid. Non-radial glial fibers were no longer evident by E19. Radial fibers were gradually replaced by immature astrocytes at the end of embryonic development. In the perinatal period, vimentin immunoreactivity labeled immature astrocytes and then gradually decreased; vimentin-immunopositive cells were only found in the internal capsule by the second postnatal week. Glial fibrillary acidic protein immunoreactivity appeared at birth in astrocytes of the internal capsule, but was not evident in most of the adult thalamic nuclei. Confocal and immunoelectron microscopy allowed direct examination of the relationships between neurons and glial processes in the embryonic thalamus, showing the coupling of neuronal membranes with both radial and non-radial glia during migration. Peculiar ultrastructural features of radial glia processes were observed. The occurrence of non-radial migration was confirmed by carbocyanine-labeled neuroblasts in E15 cultured slices. The data provide evidence that migrating thalamic cells follow both radial and non-radial glial pathways toward their destination.     

Glial-like cells of the rat pituitary intermediate lobe change morphology and shift from vimentin to GFAP expression during development

This study demonstrated morphological changes in glial-like cells of the rat pituitary intermediate lobe during early postnatal development, and a subsequent shift in protein expression from vimentin to GFAP. Vimentin immunoreactivity was detected in the lobe at embryo day 14 and was localized in radially-oriented, bipolar cells whose processes spanned the thickness of the intermediate lobe. At electron microscopical resolution, processes contained intermediate filaments, cell nuclei were indented while secretory vesicles characteristic of the endocrine cells were not found. Vimentin immunoreactive intensity began to decrease at postnatal day 5. By postnatal day 7, vimentin-positive, setellate cells were observed, with few radial processes found by day 10. The intensity of vimentin immunoreactivity decrease through day 25. Within the lobe parenchyma, vimentin was localized in glial-like cells since double-label immunohistochemistry revealed no colocalization of β-endorphin and vimentin, or fibronectin and vimentin. Dopamine-containing axons were in close apposition to vimentin-positive processes. GFAP immunoreactivity first appeared on postnatal day 20 and, by day 25, stellate cell bodies with three to six extended processes were evident. Cells were primarily distributed in the caudal third of the lobe. The characteristic adult pattern of cell clusters in latero-dorsal and ventral portions of the lobe was fully established by postnatal day 55. The transition from vimentin to GFAP expression and concurrent morphological changes resemble those described for radial glia during cerebral cortical development.     

Alpha isoform of smooth muscle actin is expressed in astrocytes in vitro and in vivo

We have previously reported that astroglial cell lines derived from spontaneously immortalized mouse cerebellar cultures as well as primary astrocyte cultures express the mRNA of the alpha isoform of smooth muscle actin. In this report, we have used an antiserum specific for the alpha smooth muscle actin protein to investigate the presence and the pattern of expression of alpha smooth muscle actin protein at the cellular level with immunocytochemical methods. The results show that an anti-smooth muscle vessels alpha actin antiserum labels a typical actin network in the D19 astroglial cell clone and in flat astrocytes of primary cultures derived from various CNS regions of embryonic and postnatal mice. Furthermore, this antiserum labels distinct populations of astrocytes in the adult mouse brain, in particular in the corpus callosum and the fornix. However, in the corpus callosum, astrocytic processes are strongly labeled by anti-SMV alpha actin antibodies only in parasagittal planes. Thus, alpha smooth muscle actin represents a new marker for subsets of astrocytes.     

Glial environment in the developing superior colliculus of hamsters in relation to the timing of retinal axon ingrowth

We have examined the developmental changes of glial cell organization in the superior colliculus of embryonic and neonatal hamsters in reference to the known sequence of retinal axon ingrowth and arborization in the midbrain. Immunolocalization of vimentin, a marker for neuronal and glial cell precursors, reveals a uniform distribution of radially oriented cells, with perikarya located at the ventricular surface and thin, elongated processes fanning out toward the pia. These vimentin-positive cells, referred to as the lateral radial cells, are present in the tectum from embryonic day (E) 10 (earliest day examined) until approximately postnatal day (P) 5. Vimentin expression in the lateral radial cells decreases markedly during the second week of postnatal life: application of DiI to the ventricular surface reveals that the pial attachment of the lateral radial cells is withdrawn and that the radial processes are gradually pulled back toward the ventricular zone. By P14, virtually no vimentin-positive radial cells are detectable in the superior colliculus. At no time during development are the lateral radial cells immunopositive for the glial fibrillary acidic protein (GFAP); however, shorter, vimentin-positive astrocytic profiles can be seen in the tectum, around the time the radial fibers have been withdrawn, suggesting that at least some radial cells are transformed into astrocytes that will colonize the mature colliculus. At approximately E12, a second group of cells, referred to as the midline radial glia, is detected at the tectal midline. These cells are tightly bundled, forming a raphe in the tectum. They are intensely vimentin positive from E13 until at least P14. From the time of birth, the midline radial cells also exhibit intense immunoreactivity for GFAP. The lateral radial cells are present in the superior colliculus prior to and during the period of neurogenesis but remain well past the time when collicular neuronal migration is completed. Pial processes of the lateral radial cells are present within the superficial tectal layers during the time retinal axons are entering this target; they may be involved in directing the growth and initial collateralization of retinotectal axons. Their withdrawal from retinorecipient collicular zones begins at about the time arbors are being elaborated on retinal axons. In constrast, the midline glia become distinct just prior to the time retinal axons enter the superior colliculus and persist during the time retinotectal projections are being fully established. These raphe glia may be involved in maintaining the laterality of the retinotectal projection. © 1995 Wiley-Liss, Inc.     

Postnatal development of glial fibrillary acidic protein immunoreactivity in the hamster arcuate nucleus

The postnatal development (from 2 days to 1 year) of glial fibrillary acidic protein (GFAP) immunoreactive cells was studied in the arcuate nucleus of male hamsters. In the first postnatal week, GFAP immunoreactivity was observed in radial glial cells whose cell bodies were located in the ependymal layer. Cell processes of GFAP immunoreactive radial glia crossed the arcuate nucleus and reached the pial surface, where they formed a thin and incomplete external limiting membrane. During the second postnatal week, some immunoreactive cell bodies were also located far from the ependymal layer. Some of these cell bodies presented processes that made contact with the ependymal layer whereas others, probably corresponding to maturing astrocytes, did not show ventricular connections. In the third week, only astrocytes showed GFAP immunoreactive perikarya and their immunoreactive processes reached either the blood vessels to form end-feet, or the basal hypothalamic zone to form the glia limitans. In successive weeks, there was an increase of the amount of GFAP-immunoreactive profiles on the glia limitans and surrounding the arcuate nucleus blood vessels. After the 6th postnatal week we observed some GFAP-immunoreactive cells close to arcuate neurons. The number of these cells increased from the 8th postnatal week. From this age on GFAP immunoreactive astrocytic processes compartimentalized the arcuate nucleus defining several rows of aligned neurons. These results indicate that the cytoarchitectonic organization of GFAP immunoreactive elements and their relationship with neurons, blood vessels and pia is not completed until the first 8 weeks of postnatal life in the arcuate nucleus of the hamster.     

Changing role of forebrain astrocytes during development, regenerative failure, and induced regeneration upon transplantation

When the cerebral midline is lesioned in the embryo or neonate, the would-be callosal axons form neuromas. We have shown that an untreated Millipore implant inserted between the neuromas in young acallosal animals can support the migration of immature astrocytes that, in turn, support the de novo growth of commissural axons between the hemispheres. Since callosal neuromas persist into adulthood, we asked whether a critical period exists after which reactive glia no longer promote axon growth. We found that a critical period does exist and have documented a variety of changes in reactive gliosis that, in part, may lead to the axon growth-refractory state. In acallosal mouse postnates given untreated implants on or prior to day 8, glial fibrillary acidic protein (GFAP)+, stellate-shaped astrocytes migrated and attached to the implant by inserting foot processes into the pores of the filter. This form of gliotic response established an axon growth-promoting substratum within 24-48 hours after implantation. During this critical stage there was no evidence of scar formation or necrosis at or around the implant surface. However, when acallosal mice were implanted on or later than postnatal day 14, extensive tissue degeneration occurred, and a mixed population of astrocytes and fibroblasts invaded the surface of the filter, producing a dense scar. Reactive cells within the scar did not promote axonal outgrowth. To determine whether glia from neonates can influence the host environment and/or induce axonal regeneration in acallosal animals after the critical period, we harvested immature astrocytes on Millipore from critical-period mouse forebrains and transplanted the glia-coated prostheses into the brains of post-critical-period acallosal animals. Such transplants reduced glial scarring in the host, inhibited extensive bleeding and secondary necrosis, and promoted axonal regeneration. Our studies suggest that when controlled with a prosthesis, gliosis during the critical period is a beneficial process that can promote the reconstruction of malformed axon pathways; that in older animals a variety of changes in reactive glia and the extracellular matrix may work together to hinder axon regeneration after the critical period; and that axonal regeneration in the postcritical CNS may be stimulated by reintroducing an immature glial environment at the lesion site.     

Differentiation of radial glia from radial precursor cells and transformation into astrocytes in the developing rat spinal cord

Radial glial cell origins and functions have been studied extensively in the brain; however, questions remain relating to their origin and fate in the spinal cord. In the present study, radial glia are investigated in vivo using the neuroepithelial markers nestin and vimentin and the gliogenic markers GLAST, BLBP, 3CB2, and glial fibrillary acidic protein (GFAP). This has revealed heterogeneity among nestin/vimentin-positive precursor cells and suggests a lineage progression from neuroepithelial cell through to astrocyte in the developing spinal cord. A population of self-renewing radial cells, distinct from an earlier pseudo-stratified neuroepithelium, that resemble radial glial cells in morphology but do not express GLAST, BLBP, or 3CB2, is revealed. These radial cells arise directly from the spinal cord neuroepithelium and are probably the progenitors of neurons and the earliest appearing radial glial cells. GLAST/BLBP-positive radial glia first appear in the ventral cord at E14, and these cells gradually transform through one or more intermediate stages into differentiated astrocytes. Few if any neurons appear to be derived from radial glial cells, which are instead the major sources of astrocytes in the spinal cord. Evidence for the nonradial glial cell origins of some white matter astrocytes is also presented.     

Embryonic divergence of oligodendrocyte and astrocyte lineages in developing rat cerebrum

Oligodendrocyte and astrocyte lineages were traced in rat forebrain sections using single- and double-label immunoperoxidase and indirect immunofluorescent techniques. Antibodies were directed against antigenic markers, the expressions of which overlapped in time: GD3 ganglioside in immature neuroectodermal cells; vimentin in radial glia; glial fibrillary acidic protein (GFAP) in astrocytes; and carbonic anhydrase (CA) and galactocerebroside (GC) in oligodendrocytes. A histochemical stain for iron was also used as a marker of oligodendrocytes. Small cells of the subventricular zone (SVZ) were stained with anti-GD3 but not with the other antibodies. By 16 d of gestation (E16), the SVZ generated large, round cells and thick, process-bearing cells that were GD3+/CA+/iron+. These cells then appeared in the cingulum and, with time, increased in numbers and extended thick processes as they filled the subcortical white matter. These cells eventually lost their reactivity to anti-GD3 but became GC+/CA+ with processes extending to myelin sheaths. At E15 radial glia were stained with the anti-vimentin antibody but were negative for GFAP. At birth, only the vimentin+ radial glia midline between the 2 ventricles were GFAP+, but with time more vimentin+ cells became GFAP+. By 7 d of postnatal age all the vimentin+ cells were GFAP+ and had converged predominately on the cingulum. With time these cells condensed and took on characteristic shapes of astrocytes. The embryonic separation of the oligodendrocyte and the astrocyte lineage is supported by four pieces of evidence: (1) GD3+ cells were double labeled with anti-CA, and then went on to become GC+; (2) vimentin+ and GFAP+ cells were not also GD3+; (3) ultrastructural localization of anti-GD3 was confined to cells with characteristics consistent with developing oligodendrocytes; and (4) the shapes of GD3+, CA+, GC+, or iron+ cells did not resemble those of the vimentin+ or GFAP+ cells.     

Expression of 27 kDa heat shock protein (Hsp27) in immature rat brain after a cortical aspiration lesion.

The 27 kDa heat shock protein (Hsp27) is a well-known member of the astroglial response to injury, playing a protective role against oxidative stress, apoptosis, and cytoskeletal destruction. Although several studies have been focused on the damaged adult brain, little is known about Hsp27 expression in the immature brain. In this work, we have examined the spatiotemporal pattern of Hsp27 expression in the normal postnatal rat brain following a cortical aspiration lesion at postnatal day 9. In the immature brain, Hsp27 is mainly observed in the internal capsule, although some scattered cells are also found in the ependyma, the corpus callosum, the septum, and hypothalamic glia limitans. In the internal capsule, Hsp27 expression is developmentally regulated, being significantly decreased from postnatal day 14. After a cortical aspiration lesion, de novo expression of Hsp27 is observed in cortical injured areas as well as in the secondary affected thalamus. In the cortex, expression of Hsp27 is first seen at day 1 postlesion (PL) surrounding the neurodegenerative area, becoming restricted to the glial scar at longer survival times. Although a pulse-like expression of Hsp27 is observed in some microglial cells at day 1 PL, most Hsp27-labeled cells are reactive astrocytes, which show GFAP overexpression and coexpress vimentin from day 3 PL. In the thalamus, astroglial Hsp27 expression is delayed, being first observed at day 5 PL. Thalamic Hsp27-labeled astrocytes do not show vimentin expression. Our observations demonstrate astroglial expression of Hsp27 in areas of tissue damage following postnatal traumatic injury, suggesting an involvement of this cytoskeleton-stabilizing protein in the remodeling processes following postnatal brain damage.     

The subependymal layer and neighboring region in the brain of the young rat

The subependymal layer found below the ependyma of the lateral ventricle, as well as the border area separating the layer from corpus callosum and caudate nucleus, were investigated in the brain of 40- and 80-gm rats with the help of the electron microscope. The subependymal layer is composed of cells packed under the ependymal epithelium. These cells undergo division frequently. They are characterized by an irregular nucleus with patches of ill defined chromatin and a scanty cytoplasm rich in free ribosomes. These features are suggestive of immaturity, although the presence of processes indicates some degree of differentiation. The border area is characterized by the presence of cells scattered among neuronal and glial processes. The cells in 40-gm rats include a few neuroblasts and, in both 40- and 80-gm rats, neurons and neuroglia, as well as numerous cells which resemble the cells of the subependymal layer or appear intermediate between them and oligodendrocytes or astrocytes. Such transitional cells are also found in corpus callosum and caudate nucleus. It is suggested that cells may leave the subependymal layer, cross the border area and enter white and gray matter while undergoing differentiation. Perhaps neuroblasts arise from these cells in the younger group studied (40-gm rats). In both groups, most of these cells seem to differentiate into astrocytes and oligodendrocytes.     

Brain mechanisms and feeding behavior in the pigeon (Columba livia). II. Analysis of feeding behavior deficits after lesions of quinto-frontal structures

Strong labeling of the cells in the subependymal layer was produced by stereotaxic injection of 5 μCi of ³H-thymidine into the left lateral ventricle of the brain of one and a quarter month old rats weighing about 100 gm. These animals were sacrificed by glutaraldehyde perfusion from two hours to 21 days later. Blocks of corpus callosum with adjacent subependymal and ependymal layers were excised from the injected and non-injected sides, and embedded in Epon; 0.5 μ thick sections were radioautographed and stained with toluidine blue. In the subependymal region, on both injected and non-injected sides, there was an immediate uptake of label by many cells followed by an increase and later a decrease in the percent cells labeled. In the corpus callosum while at first the percent labeling of glial cells was rather low, it did increase slowly with time and, after seven days, exceeded that in the subependymal region. These results were interpreted as indicating that cells arising in the subependymal layer had migrated into the corpus callosum. Up to four days after injection, most of the label in corpus callosum was present in immature-looking cells resembling the cells of the subependymal layer and referred to as free subependymal cells. With time, the percent labeling decreased in these cells while increasing in some of the glial cells. A labeling peak was observed for light oligodendrocytes at four to seven days and for dark oligodendrocytes at 21 days, whereas labeling of medium shade oligodendrocytes occurred at intermediate times. The succession of labeling peaks indicated a sequence of development from free subependymal cells through light and medium shade to dark oligodendrocytes. Few astrocytes carried label at any time; those which did seemed to have arisen from the transformation of labeled free subependymal cells. Microglia were unlabeled at two hours, but their percent labeling was high at 4–14 days. While the labeling of other glial cells reflected their physiological behavior, the labeling of microglia was a consequence of the trauma produced by the injection 0f tracer into the ventricle. In conclusion, cells coming from the subependymal layer appear to migrate into the corpus callosum where, in 100 gm rats, many of them transform into oligodendrocytes and a few into astrocytes.