Three-plane description of astroglial architecture and gliovascular connections of area postrema in rat: Long tanycyte connections to other parts of brainstem.

The study demonstrates the astroglial and gliovascular structures of the area postrema (AP) in three planes, and compares them to our former findings on the subfornical organ (SFO) and the organon vasculosum laminae terminalis (OVLT). The results revealed long glial processes interconnecting the AP with deeper areas of brain stem. The laminin and ß-dystroglycan immunolabeling altered along the vessels indicating alterations of the gliovascular relations. These and the distributions of glial markers displayed similarities to the SFO and OVLT. In every organ, there was a central area with vimentin- and nestin-immunopositive glia, whereas GFAP and the water-channel aquaporin 4 were found at the periphery. This separation supports different functions of the two regions. The presence of nestin may indicate stem cell capabilities, whereas aquaporin 4 has been suggested by other studies to be a possible participant of osmoperception. Numerous S100-immunopositive glial cells were found approximately evenly distributed in both parts of the AP. Frequency of glutamine synthetase-immunoreactive cells was similar in the surrounding brain tissue in contrast to that found in the OVLT and SFO. Our findings on the three sensory circumventricular organs (AP, OVLT, and SFO) are compared in parallel.

Three-plane description of astroglial populations of OVLT subdivisions in rat: Tanycyte connections to distant parts of third ventricle.

This study demonstrates glial and gliovascular markers of organon vasculosum laminae terminalis (OVLT) in three planes. The distribution of glial markers displayed similarities to the subfornical organ. There was an inner part with vimentin- and nestin-immunopositive glia whereas GFAP and the water-channel aquaporin 4 were found at the periphery. This separation indicates different functions of the two regions. The presence of nestin may indicate stem cell-capabilities whereas aquaporin 4 has been reported to promote the osmoreceptor function. Glutamine synthetase immunoreactivity was sparse like in the area postrema and subfornical organ. The laminin and ß-dystroglycan immunolabelings altered along the vessels such as in the subfornical organ indicating altering gliovascular relations. The different subdivisions of OVLT received glial processes of different origins. The posterior periventricular zone contained short vimentin-immunopositive processes from the ependyma of the adjacent surface of the third ventricle. The lateral periventricular zone received forceps-like process systems from the anterolateral part of the third ventricle. Most interestingly, the "dorsal cap" received a mixed group of long GFAP- and vimentin-immunopositive processes from a distant part of the third ventricle. The processes may have two functions: a guidance for newly produced cells like radial glia in immature brain and/or a connection between distant parts of the third ventricle and OVLT.

Disappearance of cerebrovascular laminin immunoreactivity as related to the maturation of astroglia in rat brain.

The present paper provides novel findings on the temporo-spatial correlation of perivascular laminin immunoreactivity with the early postnatal astrocyte development. The cerebrovascular laminin immunoreactivity gradually disappears during development. The fusion of the glial and vascular basal laminae during development makes the laminin epitopes inaccessible for antibody molecules (Krum et al., 1991, Exp Neurol 111:151). The fusion is supposed to correlate with the maturation of the glio-vascular connections. Glial development was followed by immunostaining for GFAP (glial fibrillary acidic protein), S100 protein, glutamine synthetase as glial markers and for nestin to visualize the immature glial structures. Our investigation focused on the period from postnatal day (P)2 to P16, on the dorso-parietal pallium. In the wall of the telencephalon the laminin immunoreactivity disappeared between P5 and P10; in subcortical structures it persisted to P12 or even to P16. Its disappearance overlapped the period when GFAP-immunopositive astrocytes were taking the place of radial glia. Despite the parallel time courses, however, the spatial patterns of the two processes were just the opposite: disappearance of the laminin immunoreactivity progressed from the middle zone whereas the appearance of GFAP from the pial surface and the corpus callosum. Rather, the regression of the vascular laminin immunoreactivity followed the progression of the immunoreactivities of glutamine synthetase and S100 protein. Therefore, the regression really correlates with a 'maturation' of astrocytes which, however, affects other astrocyte functions rather than cytoskeleton.

Glial and perivascular structures in the subfornical organ: distinguishing the shell and core.

The subfornical organ (SFO) is a circumventricular organ with a chemosensitive function, and its vessels have no blood-brain barrier. Our study investigated the glial and vascular components in the SFO to determine whether their distributions indicate subdivisions, how to characterize the vessels and how to demarcate the SFO. To this end, we investigated glial markers (GFAP, glutamine synthetase, S100) and other markers, including vimentin and nestin (immature glia), laminin (basal lamina), ß-dystroglycan (glio-vascular connections), and aquaporin 4 (glial water channels). We determined that the 'shell' of the SFO was marked by immunoreactivity for S100, GFAP and aquaporin 4. Nestin immunoreactivity was characteristic of the 'core'. Vimentin was almost evenly distributed. Glutamine synthetase immunoreactivity occurred in the shell but its expression was sparse. Vessels in the core were decorated with laminin but showed a discontinuous expression of aquaporin 4. Vimentin and GFAP staining was usually in separate glial elements, which may be related to their functional differences. Similar to other vessels in the brain, ß-dystroglycan was detected along the shell vessels but laminin was not. The gradual disappearance of the laminin immunopositivity was attributed to the gradual disappearance of the perivascular space. Thus, our findings suggest that the shell and core glio-vascular structures are adapted to different sensory functions: osmoperception and the perception of circulating peptides, respectively.

Immunohistochemical detectability of cerebrovascular utrophin depends on the condition of basal lamina.

Utrophin is an autosomal homologue of dystrophin. Dystrophin is a member of the dystrophin-glycoprotein complex, which is a cell surface receptor for basal lamina components. In recent opinions utrophin occurs in the cerebrovascular endothelium but not in the perivascular glia. Cerebrovascular laminin immunoreactivity can only be detected in the subpial segments of the vessels, in circumventricular organs lacking blood-brain barrier, in immature vessels and following brain lesions. In our former experience utrophin immunoreactivity showed similar phenomena to that of laminin. The present study investigates the parallel occurrence of vascular utrophin and laminin immunoreactivity in the brain tissue, especially in the circumventricular organs, and during the parallel postnatal regression of both utrophin and laminin immunoreactivity. Their cerebrovascular immunoreactivity observed in frozen sections renders plausible the role of hidden but explorable epitopes, instead of a real absence of laminin and utrophin. The laminin epitopes are supposed to be hidden due to the fusion of the glial (i.e. brain parenchymal) and vascular basal laminae (Krum et al., Exp. Neurol. 111 (1991) 151). In all cases including its post-lesion re-appearance published formerly by us, laminin immunoreactivity may be attributed to the separation of glial and vascular basal laminae. Utrophin is localized, however, intracellularly, therefore a more complex molecular mechanism is to be assumed and it remains to be investigated how structural changes of the basal lamina may indirectly affect the immunoreactivity of utrophin. The results indicate that immunoreactivity may be influenced not only by the presence or absence of macromolecules but also by their functional state.

Extracellular matrix components mark the territories of circumventricular organs.

In the central nervous system the extracellular matrix has important roles, e.g. supporting the extracellular space, controlling the tissue hydration, binding soluble factors and influencing their diffusion. The distribution of the extracellular matrix components in the brain has been mapped but data on the circumventricular organs (CVOs) is not available yet. The CVOs lack the blood-brain barrier and have relatively large perivascular spaces. The present study investigates tenascin-R and the lecticans: aggrecan, brevican, neurocan, and versican in the median eminence, the area postrema, the vascular organ of the lamina terminalis, the subfornical organ, the pineal body and the subcommissural organ of the rat applying immunohistochemical methods, and lectin histochemistry, using Wisteria floribunda agglutinin (WFA). The extracellular matrix components were found intensely expressed in the CVOs with two exceptions: aggrecan immunoreactivity visualized only neurons in the arcuate nucleus, and the subcommissural organ was not labeled with either WFA, or lecticans, or tenascin-R. The different labelings usually overlapped each other. The distribution of the extracellular matrix components marked the territories of the CVOs. Considering these we suppose that the extracellular matrix is essential in the maintenance of CVO functions providing the large extracellular space which is required for diffusion and other processes important in their chemosensitive and neurosecretory activities. The decrease of extracellular matrix beyond the border of the organs may contribute to the control of the diffusion of molecules from the CVOs into the surrounding brain substance.

Components of the basal lamina and dystrophin-dystroglycan complex in the neurointermediate lobe of rat pituitary gland: different localizations of beta-dystroglycan, dystrobrevins, alpha1-syntrophin, and aquaporin-4.

The so-called neurointermediate lobe is composed of the intermediate and neural lobes of the pituitary. The present immunohistochemical study investigated components of the basal lamina (laminin, agrin, and perlecan), the dystrophin-dystroglycan complex (dystrophin, beta-dystroglycan, alpha1-dystrobrevin, beta-dystrobrevin, utrophin, and alpha1-syntrophin), and the aquaporins (aquaporin-4 and -9). Glia markers (GFAP, S100, and glutamine synthetase) and components of connective tissue (collagen type I and fibronectin) were also labeled. In the neurohypophysis, immunostaining of basal lamina delineated meningeal invaginations. In these invaginations, vessels were seen to penetrate the organ without submerging into its parenchyma. On the parenchymal side of the invaginations, beta-dystroglycan was detected, whereas utrophin was detected in the walls of vessels. Immunostaining of alpha1-dystrobrevin and alpha1-syntrophin did not delineate the vessels. The cells of the intermediate lobe were fully immunoreactive to alpha1-dystrobrevin and alpha1-syntrophin, whereas components of the basal lamina delineated the contours of the cells. GFAP-immunoreactive processes surrounded them. Aquaporin-4 localized at the periphery of the neurohypophysis, mainly adjacent to the intermediate lobe but not along the vessels. It colocalized only partially with GFAP and not at all with alpha1-syntrophin. Aquaporin-9 was not detected. These results emphasize the possibility that the components of the dystrophin-dystroglycan complex localize differently and raise the question about the roles of dystrobrevins, alpha1-syntrophin, and aquaporin-4 in the functions of the intermediate and neural lobes, respectively.

Distribution of components of basal lamina and dystrophin-dystroglycan complex in the rat pineal gland: differences from the brain tissue and between the subdivisions of the gland.

The pineal gland is an evagination of the brain tissue, a circumventricular neuroendocrine organ. Our immunohistochemical study investigates basal lamina components (laminin, agrin, perlecan, fibronectin), their receptor, the dystrophin-dystroglycan complex (beta-dystroglycan, dystrophin utrophin), aquaporins (-4,-9) and cellular markers (S100, neurofilament, GFAP, glutamine synthetase) in the adult rat corpus pineale. The aim was to compare the immunohistochemical features of the cerebral and pineal vessels and their environment, and to compare their features in the distal and proximal subdivisions of the so-called 'superficial pineal gland'. In contrast to the cerebral vessels, pineal vessels proved to be immunonegative to alpha1-dystrobrevin, but immunoreactive to laminin. An inner, dense, and an outer, loose layer of laminin as two basal laminae were present. The gap between them contained agrin and perlecan. Basal lamina components enmeshed the pinealocytes, too. Components of dystrophin-dystroglycan complex were also distributed along the vessels. Dystrophin, utrophin and agrin gave a 'patchy' distribution rather than a continuous one. The vessels were interconnected by wing-like structures, composed of basal lamina-components: a delicate network forming nests for cells. Cells immunostained with glutamine synthetase, S100-protein or neurofilament protein contacted the vessels, as well as GFAP- or aquaporin-immunostained astrocytes. Within the body a smaller, proximal, GFAP-and aquaporin-containing subdivision, and a larger, distal, GFAP-and aquaporin-free subdivision could be distinguished. The vascular localization of agrin and utrophin, as well as dystrophin, delineated vessels unequally, preferring the proximal or distal end of the body, respectively.