Astroglial architecture of the carp ( Cyprinus carpio ) brain as revealed by immunohistochemical staining against glial fibrillary acidic protein (GFAP)

 The present paper is the first comprehensive study on the astroglia of a teleost fish that is based on the immunohistochemical staining of GFAP (glial fibrillary acidic protein, an immunohistochemical marker of astroglia). The ray-finned fishes (Actinopterygii) and their largest group, the Teleostei, represent a separate pathway of vertebrate evolution. Their brain has a very complex macroscopic structure; several parts either have no equivalents in tetrapods or have a very different shape, e.g., the telencephalon. The results show that the teleost brain has a varied and highly specialized astroglial architecture. The primary system is made up of radial glia, which are of ependymal origin and cover the pial surface with endfeet. The tendency is, however, that the more caudal a brain area is, the less regular is the radial arrangement. A typical radial glia dominates some parts of the diencephalon (median eminence, lobus inferior and habenula) and the telencephalon. In the rest of the diencephalon and in the mesencephalon, the course of the glial fibers is modified by brain tracts. The most specialized areas of the teleost brain, the optic tectum and the cerebellum, display elaborate variations of the original radial system, which is adapted to their layered organization. In the cerebellum, an equivalent of the Bergmann-glia can be found, although its fiber arrangement shows meaningful differences from that of mammals or birds. In the lower brain stem radial glia are confined to fibers separating the brain tracts and forming the midline raphe. A dense ependymoglial plexus covers the inner surface of the tectum and the bottom of the rhombencephalic ventricle, intruding into the vagal and facial lobes. The structure and the position of the rhombencephalic plexus suggest that it corresponds to a circumventricular organ that entirely occupies the bottom of the ventricle. Perivascular glia show an unusual form as they consist of long fibers running along the blood vessels. In the large brain tracts long glial fibers run parallel with the course of the neural fibers. At least in the diencephalon, these glial fibers seem to be modified radial fibers. Real astrocytes (i.e., stellate-shaped cells) can be found only in the brain stem and even there only rarely. The glial specialization in the various areas of the teleost brain seems to be more elaborate than that found either in amphibia or in reptiles. Accepted: 15 May 1998     

Distribution of glial fibrillary acidic protein (GFAP)-immunoreactive astrocytes in the rat brain

Summary The topographical mapping of glial fibrillary acidic protein (GFAP)-immunoreactivity was performed in coronal serial sections of the rat mesencephalon, rhombencephalon and spinal cord. Relative to a background of poor or moderate overall staining of the mesencephalon, the interpeduncular nucleus, substantia nigra and the periaqueductal grey matter were prominent by their intense GFAP-immunoreactivity. The pons and particularly the medulla contained more GFAP-labelled elements compared with the mesencephalon. The spinal trigeminal nucleus and Rolando substance were distinguished by their intense staining. Large fibre tracts were usually poor in immunoreactive GFAP. In a concluding discussion, findings relevant to the GFAP-mapping of the whole rat CNS are evaluated with regard to possible reasons underlying the observed differential distribution of GFAP-immunoreactivity.     

Astroglial architecture of the carp (Cyprinus carpio) brain as revealed by immunohistochemical staining against glial fibrillary acidic protein (GFAP)

The present paper is the first comprehensive study on the astroglia of a teleost fish that is based on the immunohistochemical staining of GFAP (glial fibrillary acidic protein, an immunohistochemical marker of astroglia). The ray-finned fishes (Actinopterygii) and their largest group, the Teleostei, represent a separate pathway of vertebrate evolution. Their brain has a very complex macroscopic structure; several parts either have no equivalents in tetrapods or have a very different shape, e.g., the telencephalon. The results show that the teleost brain has a varied and highly specialized astroglial architecture. The primary system is made up of radial glia, which are of ependymal origin and cover the pial surface with endfeet. The tendency is, however, that the more caudal a brain area is, the less regular is the radial arrangement. A typical radial glia dominates some parts of the diencephalon (median eminence, lobus inferior and habenula) and the telencephalon. In the rest of the diencephalon and in the mesencephalon, the course of the glial fibers is modified by brain tracts. The most specialized areas of the teleost brain, the optic tectum and the cerebellum, display elaborate variations of the original radial system, which is adapted to their layered organization. In the cerebellum, an equivalent of the Bergmann-glia can be found, although its fiber arrangement shows meaningful differences from that of mammals or birds. In the lower brain stem radial glia are confined to fibers separating the brain tracts and forming the midline raphe. A dense ependymoglial plexus covers the inner surface of the tectum and the bottom of the rhombencephalic ventricle, intruding into the vagal and facial lobes. The structure and the position of the rhombencephalic plexus suggest that it corresponds to a circumventricular organ that entirely occupies the bottom of the ventricle. Perivascular glia show an unusual form as they consist of long fibers running along the blood vessels. In the large brain tracts long glial fibers run parallel with the course of the neural fibers. At least in the diencephalon, these glial fibers seem to be modified radial fibers. Real astrocytes (i.e., stellate-shaped cells) can be found only in the brain stem and even there only rarely. The glial specialization in the various areas of the teleost brain seems to be more elaborate than that found either in amphibia or in reptiles.     

Distribution of glial fibrillary acidic protein (GFAP)-immunoreactive astrocytes in the rat brain

In the first of two papers dealing with the distribution of glial fibrillary acidic protein-(GFAP)-immunoreactive elements in the rat brain, the localization of immunostaining in the forebrain is systematically described. While the limbic cortex was found to contain intensely stained, evenly distributed astrocytes, the neocortex showed clearly stratified GFAP-staining, with substantially less immunoreactivity occurring in the middle layers than in the areas close to the brain surface or the white matter. A remarkably regular staining pattern was observed in the hippocampus and dentate gyrus. The striatum remained unstained in sharp contrast to the pallidum. In the diencephalon, the main thalamic nuclei were poor in GFAP-labelled elements in contrast to the internuclear border zones. In the hypothalamus, nuclei were conspicuous by their GFAP-staining. A consistent differential staining pattern was obtained in the epithalamic structures. The observed distributional pattern of diencephalic GFAP-immunoreactivity is thought to be due to different regional proliferation of the embryonic neuroepithelium of the diencephalon. The uneven distribution of GFAP-immunoreactivity in the forebrain is explained on a mainly developmental basis.     

Immunohistochemical demonstration of glial fibrillary acidic protein (GFAP) in nasal gliomas

Using the Sternberger method (Immunoluk Histoset KIT) GFAP (glial fibrillary acidic protein) was demonstrated immunohistochemically in 4 nasal gliomas. In these histologically complex tumour-like lesions mesenchymal, epithelial, and neuroglial tissues as well as small groups of scattered glial elements could be differentiated specifically by the highly sensitive GFAP immunoperoxidase technique. GFAP was present in astrocytes and astrocyte-like differentiations. The reactivity of cell processes was essentially lower. The GFAP immunostain does not always correlate with Mallory's phosphotungstic acid hematoxylin (PTAH) stain and Gallyas' silver impregnation method for astrocytes. Additionally the immunohistochemical investigation of semithin sections prepared by the so-called pop off technique after Bretschneider et al. (1981) allows the correct localization of GFAP in astrocytes and their modulations. Furthermore, in this study, the intimate connection of epithelium and glial cells as well as astrocytes containing hemosiderin granules could be demonstrated. The latter findings suggest a possible phagocytotic activity of astrocytes. Our results show that the demonstration of GFAP by the Sternberger method is a valuable aid in establishing astrocytic glial differentiations and modulations in complex tumour-like lesions such as nasal gliomas.     

Characterization of glial fibrillary acidic protein (GFAP)-expressing hepatic stellate cells and myofibroblasts in thioacetamide (TAA)-induced rat liver injury

Hepatic stellate cells (HSCs), which can express glial fibrillary acidic protein (GFAP) in normal rat livers, play important roles in hepatic fibrogenesis through the conversion into myofibroblasts (MFs). Cellular properties and possible derivation of GFAP-expressing MFs were investigated in thioacetamide (TAA)-induced rat liver injury and subsequent fibrosis. Seven-week-old male F344 rats were injected with TAA (300 mg/kg BW, once, intraperitoneally), and were examined on post single injection (PSI) days 1–10 by the single and double immunolabeling with MF and stem cell marker antibodies. After hepatocyte injury in the perivenular areas on PSI days 1 and 2, the fibrotic lesion consisting of MF developed at a peak on PSI day 3, and then recovered gradually by PSI day 10. MFs expressed GFAP, and also showed co-expressions such cytoskeletons (MF markers) as vimentin, desmin and α-SMA in varying degrees. Besides MFs co-expressing vimentin/desmin, desmin/α-SMA or α-SMA/vimentin, some GFAP positive MFs co-expressed with nestin or A3 (both, stem cell markers), and there were also MFs co-expressing nestin/A3. However, there were no GFAP positive MFs co-expressing RECA-1 (endothelial marker) or Thy-1 (immature mesenchymal cell marker). GFAP positive MFs showed the proliferating activity, but they did not undergo apoptosis. However, α-SMA positive MFs underwent apoptosis. These findings indicate that HSCs can proliferate and then convert into MFs with co-expressing various cytoskeletons for MF markers, and that the converted MFs may be derived partly from the stem cell lineage. Additionally, well-differentiated MFs expressing α-SMA may disappear by apoptosis for healing. These findings shed some light on the pathogenesis of chemically induced hepatic fibrosis.     

星形细胞瘤的胶质纤维酸性蛋白和波形蛋白免疫组织化学定量研究

应用图像分析仪对２５例Ⅱ～Ⅳ级星形细胞瘤进行ＧＦＡＰ，ＶｌＭ免疫组织化学定量研究。结果表明：２５例星形细胞瘤全部呈ＧＦＡＰ、ＶＩＭ阳性反应，ＧＦＡＰ、ＶＩＭ免疫反应强度与肿瘤组织的分化程度有关，高分化的星形细胞瘤（Ⅱ级），ＧＦＡＰ反应强，ＶＩＭ反应弱，而低分化的星形细胞瘤（Ⅲ、Ⅳ级）中，ＶＩＭ反应强，ＧＦＡＰ反应弱，即ＧＦＡＰ与肿瘤恶性度负相关；ＶＩＭ与肿瘤组织恶性程度正相关。     

Glial fibrillary acidic protein (GFAP)-like immunoreactivity in normal and transected rat olfactory nerve

Summary Normal and transected rat olfactory nerves were stained immunohistochemically using a monoclonal antibody previously shown to selectively detect GFAP-like immunoreactivity in central astrocytes but not in peripheral Schwann cells. Low levels of central type GFAP were found in the olfactory nerves, presumably in ensheathing cells. The levels of GFAP increased dramatically after nerve transection. A population of strongly GFAP-positive cells was detected at the junction between the olfactory epithelium and initial part of the nerves, of possible relevance to the regenerative abilities of this pathway.     

Glial fibrillary acidic protein (GFAP) immunochemical profile after Junin virus infection of rat cultured astrocytes

After five steps of purification including gel permeation, anti-angiotensin I affinity column chromatography followed by reverse-phase HPLC, a peptide immunoreactive to two different antisera (anti-angiotensin I) was purified to homogeneity from extracts of the leech Theromyzon tessulatum. The first 14 amino acid residues of the purified peptide (DRVYIHPFLLXWG) established by automated Edman degradation, reveal the existence in leeches of an angiotensin I-like molecule close to human angiotensin I. The sequence of the purified peptide presents 78.5% of homology with the N-terminal part of human angiotensin. Moreover, in its sequence, this peptide presents the cleavage sites of vertebrate angiotensin metabolic enzymes, i.e. the renin and the angiotensin-converting enzyme. This finding constitutes the first biochemical characterization of an angiotensin I in Invertebrates. It also reflects the high conservation of angiotensins in the course of evolution, suggesting a fundamental role of this family in fluid homeostasis.     

Immunocytochemical distribution of glial fibrillary acidic protein in the central nervous system of the Japanese quail (Coturnix coturnix japonica)

Summary In the present study we detailed the distribution of GFAP-immunopositive structures within the central nervous system of the Japanese quail. Different fixation and embedding procedures were applied. The best results were obtained on frozen cryostatic sections from freshly dissected brains subsequently fixed by a short immersion in cold acetone. Immunopositive structures were observed both with immunofluorescence, and with immunoperoxidase methods. Immunoreactive cell bodies and processes were observed within the whole central nervous system, and different cell types can be identified on the basis of their topographical location and morphology. A first class of astrocytes is composed of intensely stained unipolar cells lining the inner surface of the pia mater and the large blood vessels. A second type is represented by multipolar astrocytes of variable size, provided with an irregular cell body. The last type is represented by similar elements, showing an immunonegative cell body, that can be identified only by the presence of converging processes. These three types of cells, and several isolated processes, show a differential distribution within the quail central nervous system, both in the grey and in the white matter. Present results suggest that GFAP may represent a good marker for at least part of the astroglial population in quail.     

Immunohistochemical distribution of S-100 protein and glial fibrillary acidic protein in normal and neoplastic salivary glands

Summary Immunohistochemical localization of S-100 protein, its and subunits, and glial fibrillary acidic protein (GFAP) in normal and neoplastic salivary glands was studied by the peroxidase-antiperoxidase method and immunoblot analysis. Positive immunostaining for S-100 protein was observed in pleomorphic adenoma, adenolymphoma, tubular adenoma, adenoid cystic carcinoma, acinic cell tumour, adenocarcinoma and carcinoma in pleomorphic adenoma. S-100 protein was localized in myoepithelial cells, epithelial cells of intercalated ducts and serous acinar cells of normal salivary gland. Both and subunits of S-100 protein showed almost identical distribution in normal and neoplastic salivary glands, but skeletal muscle cells were -positive/-negative whereas Schwann cells and fat cells were -negative/-positive in the stroma and neighbouring tissue. GFAP was only found in pleomorphic adenoma and its malignant counterpart. Immunoblot analysis showed that the GFAP-related antigen consisted of several polypeptide bands with a molecular weight ranging between 35,000 to 50,000 daltons.     

Comparative immunohistochemical study of the presence of glial fibrillary acidic protein in the pituitary of several vertebrates

The presence and distribution of the astrocytic marker protein GFAP (glial fibrillary acidic protein) in the pituitaries of several mammalian as well as of some submammalian vertebrates were examined immunohistochemically. Our study revealed that GFAP-immunoreactive pituicytes, probably reflecting the presence of the filament-rich fibrous type of pituicyte, are a common feature of the mammalian neural lobe. Moreover, interspecific and interindividual differences of the neurohypophyseal immunostaining could be observed. In the distal neurohypophysis of some submammalian vertebrates, processes of ependymal glia showed GFAP-like immunoreactivity. Our results are in agreement with the well established evolutionary stability of GFAP elsewhere in the brain. In contrast to the neurohypophysis, GFAP-positive cells within the intermediate lobe were inconstantly present in only some species. They may be derived from neurohypophyseal glia. Folliculo-stellate cells of the adenohypophyseal pars distalis were not stained.     

宫内感染后低龄大鼠脑组织中胶质纤维酸性蛋白的表达变化

目的:探讨胶质纤维酸性蛋白(GFAP)在宫内感染后低龄大鼠脑组织中的表达变化及其意义。方法: 对孕大鼠子宫内注入大肠杆菌建立宫内感染的大鼠模型,以子宫内注入生理盐水为对照组。两组分别于生后1、3、7、14及21 d取幼鼠脑组织,应用免疫组化方法检测脑组织中不同脑区GFAP的表达。结果: 生后1、3 d龄大鼠仅脑室旁白质区可见少许GFAP阳性细胞,两组细胞数无显著差异(P>0.05),其余脑区未见明显GFAP表达。感染组7日龄大鼠脑室旁白质和海马区GFAP阳性细胞数增多,与对照组比较差异显著(脑室旁白质区:9.73±3.55 vs 5.67±1.90,P<0.05;海马区:7.81±3.61 vs 2.16±1.11,P<0.05)。感染组14 d龄大鼠脑室旁白质、胼胝体及皮层区GFAP阳性细胞数增多,与对照组比较均有显著差异(脑室旁白质区:12.72±1.81 vs 9.00±0.93,P<0.01;胼胝体区:10.98±3.26 vs 4.44±1.15,P<0.01;皮层区:5.43±1.79 vs 2.71±0.67,P<0.01)。两组21 d龄大鼠各脑区GFAP阳性细胞数无显著差异(P>0.05)。结论: 宫内感染后低龄大鼠脑组织中GFAP表达增加。     

The glial architecture of the median eminence of the Mongolian gerbil (Meriones unguiculatus); a study of glial fibrillary acidic protein (GFAP) immunoreactivity in semithin sections.

The glial architecture of the median eminence (ME) of the Mongolian gerbil (Meriones unguiculatus) was studied immunohistochemically. For this purpose, semithin sections of the proximal ME were processed according to the PAP technique using antibodies directed against glial fibrillary acidic protein (GFAP). Various glial cells were stained. Their distribution, the arrangement and morphology of their processes, and the spatial relations with adjacent tissue components could be examined in detail. Most of the immunoreactive cells were identified as either tanycytes (present throughout the internal zone, but preferentially located in the ependymal and subependymal layer), or as tanycyte-like cells (present throughout the external zone, but preferentially situated in the reticular layer). The processes of both cell types established numerous contacts with capillaries of the primary portal plexus in the external zone. Moreover, many projections of tanycyte processes to capillaries of the internal zone were revealed, most notably in the subependymal layer. Peculiar uni- and bipolar cells could be detected in the fibre layer of the internal zone, the processes of which were oriented parallel to the course of the axons of the hypothalamo-neurohypophyseal system. It was demonstrated that the methodology used to study the glial cells of the ME was also well applicable to the neural lobe. This technique, therefore, provides a valuable tool for the precise visualization of the majority of glial cells in the whole neurohypophysis of the gerbil. Thus, by sequential immunostaining of serial semithin sections investigations concerning the presence of multiple substances within single neurohypophyseal glial cells become possible.     

Importance of immunohistochemistry for neuro-oncology. II. Localization of factor VIII-associated proteins and glial fibrillary acidic protein (GFAP) in angiomatous and sarcomatous tumors

Immunhistochemical methods utilizing specific antibodies against Factor VIII-related antigen and glial fibrillary acidic protein were employed in studies of 48 intracranial and intraspinal tumors. Factor VIII-related antigen occurred only in endothelial cells of the vascular wall and is therefore not of importance for the differential diagnosis of CNS tumors. Isolated Factor VIII positive cells in the stroma of hemangioblastomas turned out to be mast cells which may also normally contain this substance. The GFAP positive cells in hemangioblastomas are believed to all be of astrocytic lineage. Many of the multinuclear giant cells present in monstrocellular sarcomas contained GFAP but were Factor VIII negative. Genuine fibroxanthoma of the meninges can apparently exist next to pleomorphic xanthoastrocytomas. As demonstrated by one of our cases, the demonstration of GFAP alone can successfully distinguish between them.     

Importance of immunohistochemistry for neuro-oncology. III. Demonstration of glial fibrillary acidic proteins (GFAP) in anaplastic astrocytomas and glioblastomas

Expression of gliofibrillary acidic protein in 23 anaplastic astrocytomas and 33 glioblastomas has been investigated and correlated with tumor behavior as reflected in both the length of the preoperative history and in the post-operative survival time. Three degrees of positive immunoreactivity to anti-GFAP can be distinguished: positive GFAP reaction in more than 2/3 of cells; in 1/3 to 2/3 of all cells; in less than 1/3 of all cells; negative reaction. All anaplastic astrocytomas and 27 of 33 glioblastomas showed GFAP positive reactions. The proportion of highly reactive tumors is higher by anaplastic astrocytomas than by glioblastomas (7 of 33). For both astrocytomas and glioblastomas there is a tendency for a decrease in the expression of GFAP to be associated with a shorter preoperative history and with a shorter survival time. This is more prominent for astrocytomas than for glioblastomas. This finding supports the opinion expressed in previous publications that the GFAP expression is reversely related to the level of tumor anaplasticity.     

Age-related changes of glial fibrillary acidic protein immunoreactive astrocytes in the rat cerebellar cortex.

Age-related changes of glial fibrillary acidic protein (GFAP) immunoreactivity were investigated in the cerebellar cortex of young (3 months), adult (12 months) and old (24 months) rats using immunohistochemical techniques associated with image analysis. In young rats, cell bodies of GFAP-immunoreactive astrocytes were found in the white matter and in the granular layer of cerebellar cortex. Radially-oriented branches of astrocytes which are sited in the granular layer were also observed in the molecular layer. The number of GFAP-immunoreactivity astrocytes of white matter was decreased in adult and old rats in comparison with young cohorts, whereas their size increased progressively from 3 to 24 months old. The number and the size of GFAP-immunoreactive astrocytes of the granular layer was similar in young and adult rats. An increased number and size of GFAP-immunoreactive astrocytes was noticeable in old rats in comparison with younger cohorts. The number of radially oriented branches of the molecular layer was the same in the three age groups investigated. The above results indicate that GFAP-immunoreactive astrocytes of rat cerebellar cortex undergo age-related changes. The not homogeneous sensitivity to aging of cerebellar astrocytes suggests that evaluation of changes of different cell populations of cerebellar cortex should represent an important step of research on aging cerebellum.     

Application of glial fibrillary acidic protein immunohistochemistry in the quantification of astrocytes in the rat brain

Immunohistochemical staining for glial fibrillary acidic protein (GFAP) was employed as a tool for quantification of astrocytes in the rat brain. One-micron-methacrylate sections were prepared from 70-μm slices stained for GFAP by using a preembedding staining procedure. Numbers/unit area of astrocytes and nonastrocytes were determined for cortex, corpus callosum, and hippocampal neuropil. In each, counts from GFAP-stained, toluidine-blue-counterstained sections were compared with counts obtained from sections stained with toluidine blue alone. Numbers of nonastrocytes and total glia in all three regions were comparable in both groups of sections. Astrocyte counts in the cortex and hippocampus also showed no significant differences between the two groups. In contrast, the number of astrocytes in the corpus callosum was significantly lower in GFAP-stained, toluidine-blue-counterstained sections than in sections stained with toluidine blue alone. GFAP immunohistochemistry is a useful tool for the quantification of astrocytes in semithin plastic sections of rat brain.