Developmental biology of the meninges.

The meninges are membranous layers surrounding the central nervous system. In the head, the meninges lie between the brain and the skull, and interact closely with both during development. The cranial meninges originate from a mesenchymal sheath on the surface of the developing brain, called primary meninx, and undergo differentiation into three layers with distinct histological characteristics: the dura mater, the arachnoid mater, and the pia mater. While genetic regulation of meningeal development is still poorly understood, mouse mutants and other models with meningeal defects have demonstrated the importance of the meninges to normal development of the calvaria and the brain. For the calvaria, the interactions with the meninges are necessary for the progression of calvarial osteogenesis during early development. In later stages, the meninges control the patterning of the skull and the fate of the sutures. For the brain, the meninges regulate diverse processes including cell survival, cell migration, generation of neurons from progenitors, and vascularization. Also, the meninges serve as a stem cell niche for the brain in the postnatal life. Given these important roles of the meninges, further investigation into the molecular mechanisms underlying meningeal development can provide novel insights into the coordinated development of the head.

Mutations in the beta-tubulin gene TUBB2B result in asymmetrical polymicrogyria.

Polymicrogyria is a relatively common but poorly understood defect of cortical development characterized by numerous small gyri and a thick disorganized cortical plate lacking normal lamination. Here we report de novo mutations in a beta-tubulin gene, TUBB2B, in four individuals and a 27-gestational-week fetus with bilateral asymmetrical polymicrogyria. Neuropathological examination of the fetus revealed an absence of cortical lamination associated with the presence of ectopic neuronal cells in the white matter and in the leptomeningeal spaces due to breaches in the pial basement membrane. In utero RNAi-based inactivation demonstrates that TUBB2B is required for neuronal migration. We also show that two disease-associated mutations lead to impaired formation of tubulin heterodimers. These observations, together with previous data, show that disruption of microtubule-based processes underlies a large spectrum of neuronal migration disorders that includes not only lissencephaly and pachygyria, but also polymicrogyria malformations.

Breaches of the pial basement membrane and disappearance of the glia limitans during development underlie the cortical lamination defect in the mouse model of muscle-eye-brain disease.

Neuronal overmigration is the underlying cellular mechanism of cerebral cortical malformations in syndromes of congenital muscular dystrophies caused by defects in O-mannosyl glycosylation. Overmigration involves multiple developmental abnormalities in the brain surface basement membrane, Cajal-Retzius cells, and radial glia. We tested the hypothesis that breaches in basement membrane and the underlying glia limitans are the key initial events of the cellular pathomechanisms by carrying out a detailed developmental study with a mouse model of muscle-eye-brain disease, mice deficient in O-mannose beta31,2-N-acetylglucosaminyltransferase 1 (POMGnT1). The pial basement membrane was normal in the knockout mouse at E11.5. It was breached during rapid cerebral cortical expansion at E13.5. Radial glial endfeet, which comprise glia limitans, grew out of the neural boundary. Neurons moved out of the neural boundary through these breaches. The overgrown radial glia and emigrated neurons disrupted the overlying pia mater. The overmigrated neurons did not participate in cortical plate (CP) development; rather they formed a diffuse cell zone (DCZ) outside the original cortical boundary. Together, the DCZ and the CP formed the knockout cerebral cortex, with disappearance of the basement membrane and the glia limitans. These results suggest that disappearance of the basement membrane and the glia limitans at the cerebral cortical surface during development underlies cortical lamination defects in congenital muscular dystrophies and a cellular mechanism of cortical malformation distinct from that of the reeler mouse, double cortex syndrome, and periventricular heterotopia.

Visualization of cell cycling by an improvement in slice culture methods.

Slice culture combined with the use of fluorescent dyes and/or the introduction of fluorescent protein genes provides live and three-dimensional information on cytogenetic and histogenetic events at the level of the individual cell. Using slices prepared from midembryonic mouse cerebral wall tissue upon which fine DiI crystals were placed on the pial or ventricular surface, we recently found that dividing progenitor cells do not lose their pia-connected (basal) processes and that the processes are inherited by daughter cells, including neurons (Miyata et al. [2001] Neuron 31:727-741). To understand more fully the biological significance of this inheritance process, the fate of each daughter cell should be monitored over a culture period extended long enough to allow a neuron to migrate up to the cortex or for a progenitor to proceed to the next round of division. Exposure of slices to 40%, instead of 20%, O(2) significantly improved their overall thickening, cell production, and layer formation and also provided better spatial resolution by preventing the loss of transparency that accompanies cell death.

A critical function of the pial basement membrane in cortical histogenesis.

Mice with a targeted deletion of the nidogen-binding site of laminin gamma1 were used to study the function of the pial basement membrane in cortical histogenesis. The pial basement membrane in the mutant embryos assembled but was unstable and disintegrated at random segments. In segments with a disrupted basement membrane, radial glia cells were retracted from the pial surface, and radially migrating neurons, including Cajal-Retzius cells and cortical plate neurons, passed the meninges or terminated their migration prematurely. By correlating the disruptions in the pial basal lamina with changes in the morphology of radial glia cells, the aberrant migration of Cajal-Retzius cells, and subsequent dysplasia of cortical plate neurons, the present data establish a causal relationship of proper cortical histogenesis with the presence of an intact pial basement membrane.

Meningeal-cutaneous relationships in anencephaly: evidence for a primary mesenchymal abnormality.

The pathogenesis of cranial and spinal dysraphia has been controversial. Studies of spinal dysraphia have shown that the relationships of the pia and dura to the cutaneous layers were best understood as the result of a primary abnormality of mesenchymal structures, with the nervous system lesions occurring as a result of exposure of the bare spinal cord on the body surface. This study was undertaken to determine if the relationship of the cutaneous layers in anencephaly were similar to those found in spinal dysraphia. We reviewed serial histologic sections of the cranial structures of 10 anencephalic fetuses autopsied at The Johns Hopkins Hospital. We found the dura to be continuous with the deep dermis and the pia continuous with the superficial dermis and epidermis, the same arrangement observed in myelomeningocele. The development of eyes and cranial nerves, the absence of a bony calvarium, and the meningeal-cutaneous relationships found in this study support the idea that anencephaly can originate as an abnormality of mesenchymal structures and that the brain is secondarily lost to injury in utero because of its exposed position.

Ephrin B1 is expressed on neuroepithelial cells in correlation with neocortical neurogenesis.

To identify molecules involved in neurogenesis, we have raised monoclonal antibodies against embryonic day 12.5 mouse telencephalon. One antibody, monoclonal antibody 25H11, stains predominantly the ventricular zone of the anterior and lateral telencephalon. Purification of the 25H11 antigen, a 47 kDa integral membrane protein, from approximately 2500 mouse telencephali reveals its identity with ephrin B1. Ephrin B1 appears at the onset of neocortical neurogenesis, being first expressed in neuron-generating neuroepithelial cells and rapidly thereafter in virtually all neuroepithelial cells. Expression of ephrin B1 persists through the period of neocortical neurogenesis and is downregulated thereafter. Ephrin B1 is present on the ventricular as well as basolateral plasma membrane of neuroepithelial cells and exhibits an ventricular-high to pial-low gradient across the ventricular zone. Expression of ephrin B1 is also detected on radial glial cells, extending all the way to their pial endfeet, and on neurons in the mantle/intermediate zone but not in the cortical plate. Our results suggest that ephrin B1, presumably via ephrin-Eph receptor signaling, has a role in neurogenesis. Given the ventricular-to-pial gradient of ephrin B1 on the neuroepithelial cell surface and its known role in cell migration in other systems mediated by its repulsive properties, we propose that ephrin B1 may be involved in the migration of newborn neurons out from the ventricular zone toward the neocortex.

Progressive and transient expression of tissue plasminogen activator during fetal development.

In previous studies of the role of tissue plasminogen activator (tPA) in the lung inflammatory response, we observed that tPA expression was present exclusively in the small arteries and arterioles within the lung and absent from the capillaries, veins, and large pulmonary arteries. To define more completely the expression pattern of tPA, we evaluated the distribution of this protein during prenatal and postnatal development. tPA was first observed in the rat fetus at day 13 in the large arteries of both the thoracic and cranial cavities, including the dorsal aortas and pulmonary arteries in the former and the internal carotid and middle cerebral arteries in the latter. By day 15, tPA was no longer detectable in the aortas but appeared throughout the pulmonary, subclavian, vertebral, and basilar arteries. At day 17, tPA had disappeared from the subclavian artery and the proximal portion of the vertebral artery but was found in the smaller arterial branches of these 2 large vessels. By the end of gestation, tPA had also disappeared from the main pulmonary arteries but remained in the branches at the hilus of the lung. At birth, tPA was concentrated in the endothelia of arteries within the pia mater, the basilar and superficial cerebral arteries, and the lung arterial system. As the animals reached maturity, tPA disappeared from the larger cerebral arteries and their cortical branches but continued to be expressed in the vessels of the pia mater and lung. This study indicates that tPA expression is a dynamic process that responds to a changing arterial environment during vascular development.

Birth-related expression of c-fos, c-jun and substance P mRNAs in the rat brainstem and pia mater: possible relationship to changes in central chemosensitivity.

In situ hybridization was used to characterize respiration-related areas of the brainstem activated around the time of birth as well as their postnatal sensitivity to CO2. Levels of mRNA corresponding to the immediate early genes (IEG), c-fos and c-jun, and of substance P precursor, ppt-A, were determined in rat fetuses (E21) and neonatal pups (1 h, 1 day and 6 days after normal birth) and after exposure to hypercapnia (12% CO2 for 1 h). Transient increases in c-fos mRNA were observed in the central chemoreceptor area of the ventral medullary surface (VMS), in the lateral reticular nucleus (LRN), in the nucleus of the solitary tract (NTS), and in the nucleus raphé pallidus (RPA) 1 h after birth. Increased expression of c-fos mRNA in the VMS could also be evoked by hypercapnia and this response was particularly pronounced 1 day after birth. On the other hand, c-jun mRNA could be detected already at E21 in the hypoglossal nucleus (XII) and LRN and these levels were not significantly altered at 1 h after birth. There was, however, an increase in the expression of c-jun mRNA in the pia mater surrounding the brainstem after birth. At 1 day after birth, c-jun mRNA levels had decreased in the LRN and pia mater, and later on (6 days after birth) in XII. Furthermore, the ppt-A mRNA level in NTS increased immediately after birth and remained high 1 and 6 days later. These results suggest that (a) the central chemoreceptor area of the VMS, as well as the NTS, LRN, RPA and pia mater are activated following birth; (b) the VMS, but not the other structures examined, can be activated immediately after birth by hypercapnia; and (c) increased expression of ppt-A mRNA may be related to the transition of respiratory control at birth.

Different origins and developmental histories of transient neurons in the marginal zone of the fetal and neonatal rat cortex.

Two major classes of early-born neurons are distinguished during early corticogenesis in the rat. The first class is formed by the cortical pioneer neurons, which are born in the ventricular neuroepithelium all over the cortical primordium. They appear at embryonic day (E) 11.5 in the lateral aspect of the telencephalic vesicle and cover its whole surface on E12. These cells, which show intense immunoreactivity for calbindin and calretinin, are characterized by their large size and axonal projection. They remain in the marginal zone after the formation of the cortical plate; they project first into the ventricular zone, and then into the subplate and the internal capsule. Therefore, these cells are the origin of the earliest efferent pathway of the developing cortex. Pioneer neurons are only present in prenatal brains. The second class is formed by subpial granule neurons, which form the subpial granular layer (SGL), previously considered to be found exclusively in the human cortex. SGL neurons are smaller than pioneer neurons. They are generated in a transient compartment of the retrobulbar ventricle between E12 and E14, and we propose the hypothesis that they invade the marginal zone, through tangential subpial migration, at different moments of fetal life. SGL neurons contain calbindin, calretinin, and gamma-aminobutyric acid (GABA), but the GABA-immunoreactive group becomes inconspicuous before birth. The extracellular matrix-like glycoprotein reelin, a molecule crucial for cortical lamination, is prenatally expressed by SGL neurons; postnatally, it is present in both Cajal-Retzius cells and subpial pyriform cells, both derivatives of SGL cells. In the rat, Cajal-Retzius cells are horizontal neurons that remain only until the end of the first postnatal week. They are located in layer I at a critical distance of approximately 20 microm from the pial surface and express reelin and, only occasionally, calretinin. Subpial pyriform cells coexpress reelin and calretinin and remain in layer I longer than Cajal-Retzius cells. Both pioneer neurons and subpial granule neurons are specific to the cortex. They mark the limit between the rudimentary cerebral cortex and olfactory bulb in the rat during early corticogenesis.

The functions of the preplate in development and evolution of the neocortex and hippocampus.

Recently, it has been shown that the early developmental organization of the archicortical hippocampus resembles that of the neocortex. In both cortices at embryonic stages, a preplate is present, which is split by the formation of the cortical plate into a marginal zone and a subplate layer. The pioneer neurons of the preplate are believed to form a phylogenetically ancient cortical structure. Neurons in these preplate layers are the first postmitotic neurons and have important roles in the development of the cerebral cortex. Cajal-Retzius cells in the marginal zone regulate the phenotype of radial glial cells and may direct neuronal migration establishing the inside-out gradient of corticogenesis. Furthermore, pioneer neurons form the initial axonal connections with other (sub)cortical structures. A significant difference between the hippocampus and neocortex, however, is that in the hippocampus, most afferents are guided by the pioneer neurons in the prominent marginal zone, while in the neocortex most ingrowing afferent axons enter via the subplate. At later developmental periods, most pioneer neurons disappear by cell death or transform into other neuronal shapes. Here, we review the early developmental organization of the mammalian cerebral cortex (both neocortex and hippocampus) and discuss the functions and fate of pioneer neurons in cortical development, in particular that of Cajal-Retzius cells. Evaluating the developmental properties of the hippocampus and neocortex, we present the hypothesis that the distribution of the main ingrowing afferent systems in the developing neocortex, which differs from the one in the hippocampal region, may have enabled the specific evolution of the neocortex.

Embryonic CNS macrophages and microglia do not stem from circulating, but from extravascular precursors.

Invasion of mesoderm-derived cells into the developing spinal cord and brain has been shown to produce early central nervous system (CNS) macrophage and microglia populations in avian embryos. A triplicate mode of entry has been proposed: through the endothelial wall of CNS blood vessels; from the ventricular cavities; and through the pial surface. Invasion of circulating blood cells (monocytes) has not yet been proved in embryonic CNS. This report demonstrates: 1) the use of chick-quail blood chimeras by way of parabiosis (two embryos in one egg); 2) the use of QH1 monoclonal antibody for detection of quail cells circulating in chick blood vessels; 3) the presence of extravascular QH1-positive cells (macrophages) in E7-10 CNS in parabiosis quail, and their absence in parabiosis chick. We conclude that avian macrophages/microglia precursors do not penetrate through the wall of embryonic CNS vessels. In combination with published results, this finding strongly supports the view that invasion of migratory macrophages from the pial surface and proliferation inside the CNS generate all microglia in avian embryos.

Ontogenetic development of diffusional restriction to protein at the pial surface of the rat brain: an electron microscopical study.

Blood-brain, blood-CSF and ventricular CSF-brain barriers to protein are present very early in brain development. In order to determine whether the outer pial surface of the brain also restricts free penetration of macromolecules, the dorso-lateral part of the sensorimotor cortex from rats at embryonic day 12 (E12), 14, 16, and 18, the day of birth (P0), and adult rat, was studied by electron microscopical techniques. Potassium ferrocyanide, Ruthenium Red and immunogold labelling of endogenous albumin were used to investigate junctional structures and the sites of restriction to albumin diffusion. At E12, large fenestrated sinusoids were present in the pia-arachnoid and the brain surface was formed by an incomplete layer of neuroepithelial and presumptive radial glial end feet, but capillaries in the pia-arachnoid showed no fenestrations at E14 or later. From E14, we observed the progressive appearance of distinct junctional structures between the glial end feet which, to our knowledge, have not been described before. Analysis of albumin distribution from E16 to P0 suggests that the junctions may contribute to restriction of diffusion between the subarachnoid space and the brain extracellular fluid. The restriction to the penetration of protein at both the pial and the ependymal surfaces may ensure the isolation of the neural environment during a critical phase in development of the nervous system. The changes in the structure of the junctions between E12 and P0 suggests a transitional series of embryonic junctional types, which eventually give way to the mature junctions of the adult. Parallels between the embryonic glial junctions and junctions described in adult invertebrate brain, suggest some interesting parallels in junctional development in phylogeny and ontogeny.

[The middle cerebral artery system in fetuses: the distribution of the pial branches]. / Sistemul arterei cerebrale mijlocii la fat: distributia ramurilor piale.

The aim of our study is to point out the influence of the cerebral development on the evolution of the middle cerebral artery (MCA) system. Brains of 20 fresh fetuses (16-22 weeks) were injected with gelatin-ink China mixture, observed and dissected under surgical microscope in correlation with the evolution of the sylvian fossa. Ending pattern of MCA and territories of distribution of its branches were also discussed.

Ontogeny of four blood-brain barrier markers: an immunocytochemical comparison of pial and cerebral cortical microvessels.

Pial and cortical microvessels possess many blood-brain barrier (BBB) properties in common, including impermeability to electron dense tracers, high transendothelial electrical resistance and specialised endothelial cell ultrastructural features. To compare pial and cortical microvessels further, a developmental, immunocytochemical study was undertaken of 4 BBB markers in the rat: OX-47, EBA, GLUT-1 and s-laminin. The appearance of the markers was monitored from embryonic d 16, to postnatal and adult stages. Each of the 4 markers appeared simultaneously in both pial and cortical vessels. GLUT-1 and OX-47 were present in endothelial cells of the BBB from E 16 to the adult. EBA and s-laminin appeared from postnatal d 7 through to the adult. Pial microvessels lack the ensheathment of astrocytes which may be involved in the induction and/or maintenance of BBB markers in the cortex. It is possible that astrocyte-derived factors diffusing from the brain surface are responsible for induction of BBB properties in the pial microvessels.

Scanning electron microscopy of human cerebral meningeal stomata.

The human dura mater and pia mater were studied by using a scanning electron microscope and a computer image processing system (C.I.P.). The human cerebral meningeal stomata are located between the mesothelial cells of the cerebral meninges. They are round or oval in shape with diameters of 0.33-2.98 microns. The cerebral meningeal stomata are stable structures, scattered or clustered together. Their density in the dura mater is greater than in the pia mater (P < 0.01), and they are regularly distributed. The statistical analysis showed that the stomata diameter and distribution density in the dura mater are 1.34 microns and 381.55/0.1 mm2; while in the pia mater they are 0.88 micron and 195.06/0.1 mm2 respectively. The cerebral meningeal stomata are probably part of the cerebral prelymphatic capillary system, which undertakes the cerebral lymph drainage because there are no lymphatic vessels in the brain although yet there is lymph drainage. Thus, we believe that the cerebral meningeal stomata are involved in maintaining the physiological function of the brain as part of the cerebrospinal fluid (CSF) which absorbs the cerebral interstitial fluid.

[Rosette formation in explants of human embryonic neocortex (an electron-microscopic study)]. / Obrazovanie rozetok v éksplantatakh neokorteksa émbrionov cheloveka (élektronno-mikroskopicheskoe issledovanie).

Multiple invaginations and closed cavities (rosettes) were developed in 199 fragments of wall of human anterior cerebral vesicle. Contraction of neuroepithelial cells apexes after the principle of the gathered tobacco pouch was involved into the process. This confirms the previous suggestion of the authors on the similarity between the mechanisms of rosettes forming and neurulation. The participation of radial glia cells and neuroblasts in the reorganization of the neocortex germ was also studied.

Amoeboid microglia expressing GD3 ganglioside are concentrated in regions of oligodendrogenesis during development of the rat corpus callosum.

In recent study we demonstrated expression of the platelet-derived growth factor alpha receptor (PDGFR alpha) in cells of the early oligodendrocyte lineage that were identified as either GD3 ganglioside + oligodendrocyte progenitors or O4 sulfatide+ preoligodendrocytes. We also identified a subpopulation of GD3 immunoreactive cells that did not express mRNA for the PDGF receptor. The distinct large amoeboid morphology of these cells was characteristic of cells in the macrophage lineage rather than in the oligodendrocyte lineage. To determine if the GD3-positive but PDGFR alpha mRNA-negative cells were in the macrophage lineage, we compared the spatial and temporal expression patterns of GD3 ganglioside and ED1, a macrophage-specific antigen. Analysis prenatally indicated that at embryonic day 15, ED1+ and GD3+ cell populations resided in the subpial connective tissue. At embryonic day 21, these two populations were seen in a region extending from the lateral ventricle through the subventricular and intermediate zones. In this study we report that these large, round, GD3 immunoreactive cells have the same cell morphology and anatomical distribution as the ED1 immunoreactive cells. Both cell populations contained pyknotic nuclei within their cytoplasm. Furthermore, the GD3+/PDGFR alpha- cells appear to be involved in clearing cellular debris in regions of gliogenesis. These data suggest that this subpopulation of GD3 immunoreactive cells belongs to the microglia/macrophage lineage.