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Volume 17, Number 7, Issue of April 1, 1997 pp. 2376-2382
Copyright ©1997 Society for NeuroscienceProstaglandin D Synthase (
-Trace) in Human Arachnoid and Meningioma Cells: Roles as a Cell Marker or in Cerebrospinal Fluid Absorption, Tumorigenesis, and Calcification Process
Tetsumori Yamashima1, Kazushige Sakuda1, Yasuo Tohma1, Junkoh Yamashita1, Hiroshi Oda2, Daisuke Irikura3, Naomi Eguchi4, Carsten T. Beuckmann3, Yoshihide Kanaoka3, Yoshihiro Urade3, and Osamu Hayaishi3 1 Department of Neurosurgery, Kanazawa University School of Medicine, Kanazawa 920, Japan, 2 Department of Biological Chemistry, Central Research Institute, Maruha Corporation, Tsukuba 300-42, Japan, 3 Department of Molecular Behavioral Biology, Osaka Bioscience Institute, Osaka 565, Japan, and 4 Department of Precursory Research for Embryonic Science and Technology, Osaka 590-02, Japan
ABSTRACT
Glutathione-independent prostaglandin D synthase (PGDS) is an enzyme responsible for biosynthesis of prostaglandin D2 in the CNS and is identical to a major cerebrospinal fluid protein,
Key words: arachnoid; arachnoid villus; meningioma; prostaglandin D synthase;-trace. Although PGDS has been identified recently in rat leptomeninges, little information is available about human meninges or meningiomas. Here, we report PGDS to be expressed consistently in 10 human arachnoid and arachnoid villi and in 21 meningiomas by immunohistochemistry, Western blot, and reverse transcription (RT)-PCR analyses. In arachnoid, PGDS immunoreactivity was seen in arachnoid barrier cells but was negligible in arachnoid trabecula and pia mater. In contrast, in arachnoid villi, PGDS was seen in core arachnoid cells rather than in the cap cell cluster or arachnoid cell layer. Meningioma cells also showed intense immunoreactivity in the perinuclear region, and it was often concentrated within meningocytic whorls and around calcifying psammoma bodies. Immunoelectron microscopic data, when compared with the ultrastructure, showed that PGDS was localized at rough endoplasmatic reticulum of arachnoid and meningioma cells. Western blot showed a 29 kDa immunoreactive band indicating PGDS, but the extent of expression was variable from case to case, which was compatible with immunohistochemical data. RT-PCR revealed PGDS gene expression in all meningiomas studied, regardless of histological subtypes, and also in human arachnoid villi. Because human arachnoid and meningioma cells exclusively express PGDS, it can be considered their specific cell marker. These results show functional differences in various types of meningeal cells attributable to differences in PGDS expression.
INTRODUCTION
Since the discovery of prostaglandin (PG) in 1930, various types of PGs have been demonstrated throughout almost all types of cells in mammalian organs and tissues. PGs are well known to play vital roles in contraction and relaxation of smooth muscles, aggregation and disaggregation of platelets, inflammation, and pain.
PGD2 had long been considered a minor and biologically inactive prostanoid. In the late 1970s, Hayaishi and his co-workers found a large amount of PGD2 in the brains of rats and other mammals, including humans (for review, see Hayaishi, 1994
). In rats (Ueno et al., 1983
Glutathione-independent PGD synthase (PGDS) [(5Z,13E)-(15S)-9
,11
We have demonstrated both this enzyme and its mRNA in the leptomeninges, choroid plexus, and retina of rats (Urade et al., 1993
MATERIALS AND METHODS
Human materials. Both arachnoid and arachnoid villi were obtained from 10 cases (eight male and two female with an average age of 47 years) at autopsy within a few hours postmortem or at surgery and were used for immunohistochemical and immunoelectron microscopic analyses. A fresh sample of arachnoid villi obtained at surgery was used for RT-PCR analysis. The samples of 19 meningiomas histologically comprising five syncytial, five transitional, one fibroblastic, one angiomatous, and seven atypical types were obtained fresh at surgery and were used for immunohistochemical, immunoelectron microscopic, Western blot, and RT-PCR analyses. Furthermore, two typical psammomatous or ossifying meningiomas, including numerous psammoma bodies or ossification deposits, were used for immunohistochemical analysis.
For immunohistochemistry, the samples were fixed with 3.7% formalin or 4% paraformaldehyde and embedded in paraffin. For immunoelectron microscopy, the samples were fixed with 4% paraformaldehyde and processed for pre-embedding procedure. The samples of meningiomas obtained at surgery for Western blot and RT-PCR analyses were frozen and stored.
Antiserum and primers. According to the methods described previously for rabbit anti-rat PGDS serum (Urade et al., 1985
The oligonucleotide primers used for PCR amplification were as follows: PGDS (5 -primer, 5
Immunohistochemistry. Sections of 4 µm thickness were incubated overnight at 4°C in anti-PGDS serum diluted 1:5000. The immunoreaction was visualized by the immunoperoxidase method using anti-rabbit IgG and avidin-biotin-peroxidase complex (Vector, Burlingame, CA). Then, the sections were immersed in a solution of 500 µg/ml diaminobenzidine hydrochloride (DAB) (Sigma, St. Louis, MO) in 50 mM Tris-buffered saline (TBS, pH 7.6) for 30 sec. The controls for immunohistochemistry were made using primary antibody preabsorbed with a threefold volume of recombinant
Immunoelectron microscopy. Vibratome sections of 50 µm thickness were incubated for 15 min with 0.02% saponin for etching. Washings between each step were performed with 50 mM TBS. The sections were incubated with 0.3% H2O2 in methanol for 1 hr and with blocking antibody for 2 hr. The sections were then incubated with anti-PGDS serum diluted 1:3000 overnight at 4°C. The sections were subsequently incubated with biotinylated antibody against rabbit IgG for 2 hr and were incubated with avidin-biotin-peroxidase complex for 2 hr. The sections were fixed with 0.1% glutaraldehyde for 30 min and immersed in a solution of 500 µg/ml DAB in TBS for 30 min and further in the same solution containing 0.03% H2O2 for 15 min. The sections were post-fixed with 1% OsO4 for 60 min, dehydrated by passage through an ascending series of ethanol, and embedded in an Epon-Araldite mixture. Ultrathin sections were cut on an LKB ultramicrotome and examined with Hitachi H-600 electron microscope without counterstaining.
The controls for immunoelectron microscopy were made using nonimmunized rabbit serum as primary antibody.
Electron microscopy. Biopsy specimens of meningiomas were fixed in cacodylate-buffered 2.5% glutaraldehyde for 2 hr and post-fixed in 1% OsO4 in the same buffer for 1 hr. They were subsequently dehydrated through graded concentrations of ethanol and were embedded in an Epon-Araldite mixture. Semithin sections were cut with an LKB ultramicrotome and stained with toluidine blue. Ultrathin sections of selected areas were stained with uranyl acetate followed by lead citrate and were examined with a Hitachi H-600 electron microscope.
Western blot. After a protein assay, samples of meningiomas were subjected to SDS-PAGE using a ready-made polyacrylamide gel Multi Gel 15/25 (Daiichi Pure Chemicals, Tokyo, Japan). Then, proteins were transferred to polyvinylidene difluoride membranes (Atto, Tokyo, Japan) for immunoblotting. The primary anti-PGDS antibody was diluted 1:5000. The secondary antibody, peroxidase-conjugated goat anti-rabbit IgG (Sigma), was diluted 1:10,000 in 20 mM Tris/HCl buffer containing 1% bovine serum albumin and 0.1% Tween 20. Immunoreactive species were visualized using an alkaline phosphatase substrate kit (Vector).
RT-PCR. Total cytoplasmic RNA was isolated by the acid guanidine thiocyanate-phenol-chloroform method (Chomczynski and Sacchi, 1987
For RT, total RNA (1 µg) was mixed in a 20 µl reaction mixture containing 1 mM MgCl2, 400 µM dNTP mixture, 1 U RNase inhibitor, 125 nM oligo(dT)20-M4 adaptor primer, and 0.25 U avian myeloblastosis virus reverse transcriptase XL (Life Sciences, Hialeah, FL) in RNA PCR buffer (10 mM Tris/HCl and 50 mM KCl). After synthesis of first-strand cDNA at 42°C for 15 min, a denaturation step at 99°C for 5 min was performed. For PCR, the template (2 µl) was subjected to amplification in a 50 µl PCR reaction mixture containing 40 µM dNTP mixture, 2 pM of each PCR-primer for PGDS or GAPDH, and 0.1 U Taq polymerase (Takara Shuzo) in RNA PCR buffer. Denaturation was carried out at 94°C for 105 sec, and amplification was carried out for 25 cycles at 94°C for 30 sec and at 68°C for 90 sec in an automated DNA Thermal Cycler (GeneAmp PCR System 2400, Perkin-Elmer, Norwalk, CT). After amplification, the RT-PCR reaction mixture (10 µl) was electrophoresed on a 2% agarose gel which was visualized by ethidium bromide staining with an ultraviolet transilluminator (FAS II, Toyobo, Osaka, Japan).
RESULTS
Light and electron microscopic localization of PGDS
Arachnoid PGDS was immunohistochemically demonstrated in all of the 10 arachnoid samples studied. PGDS immunoreactivity was intense in arachnoid barrier layer and weak in the underlying arachnoid cells, but was negligible in dural border cells, arachnoid trabecula, pia mater, and the underlying brain. PGDS immunoreactivity was seen as granular DAB reaction products in the cytoplasm of arachnoid barrier cells (Fig. 1A,C).
Fig. 1. Immunohistochemical staining for PGDS in human arachnoid. A, Light microscopic low-power view shows intense granular DAB reaction products in arachnoid barrier cells overlying the subarachnoid space (asterisk). B, Control using preabsorbed antibody (same magnification as A). C, Higher magnification of A reveals that both dural border cells (arrows) and the underlying arachnoid cells (star) show only weak immunoreactivity. D, Immunoelectron micrograph of arachnoid barrier cells shows PGDS at the rough ER membrane (no counterstaining), when it is compared with the conventional electron micrograph F. N, Nucleus. E, Control using nonimmunized rabbit serum (same magnification as D). N, Nucleus. F, Electron micrograph of an arachnoid barrier cell shows abundant rough ER membrane (arrows) in the electron-lucent cytoplasm (uranyl and lead staining). N, Nucleus. Scale bars: A, 20 µm; C, 10 µm; D, 2 µm; F, 3 µm.
[View Larger Version of this Image (124K GIF file)]
By immunoelectron microscopy, PGDS was demonstrated to be localized at the rough endoplasmatic reticulum (ER) membrane (Fig. 1D), when it was compared with the conventional ultrastructural feature (Fig. 1F). Aggregates of DAB reaction products were often seen within the cisternae of rough ER and appeared to be consistent with granular DAB reaction products observed by light microscopy. Arachnoid villi PGDS was immunohistochemically demonstrated in all of the 10 arachnoid villi samples studied. The immunostaining pattern of arachnoid villi was different, however, from that of arachnoid: PGDS immunoreactivity was intense in core arachnoid cells rather than in the cap cell cluster and arachnoid barrier layer (Fig. 2A,C).
Arachnoid barrier cells were ultrastructurally abundant with enlarged rough ER (Fig. 1F). 
Fig. 2. Immunohistochemical staining for PGDS in human arachnoid villi. A, Light microscopic low-power view shows intense DAB reaction products in the cytoplasm of core arachnoid cells. Note that the cap cell cluster shows very little immunoreaction. B, Control using preabsorbed antibody (same magnification as A). C, In contrast, higher magnification of A reveals that the surrounding arachnoid cell layer (arrows) shows very little immunoreactivity (A-C counterstained with hematoxylin). D, Immunoelectron micrograph of a core arachnoid cell shows PGDS at the rough ER membrane (no counterstaining), when it is compared to the conventional electron micrograph F. N, Nucleus. E, Control using nonimmunized rabbit serum (same magnification as D). N, Nucleus. F, Electron micrograph of core arachnoid cells shows abundant rough ER membrane in the cytoplasm (uranyl and lead staining). N, Nuclei. Scale bars: A, 20 µm; C, 10 µm; D, 2 µm; F, 2 µm.
[View Larger Version of this Image (142K GIF file)]
By immunoelectron microscopy, PGDS was also demonstrated to be localized at the rough ER membrane of core arachnoid cells (Fig. 2D). Meningiomas PGDS was immunohistochemically demonstrated in all of the 21 meningiomas studied; however, the extent of PGDS immunostaining was variable from case to case, and even in the same case from syncytium to syncytium, from whorl to whorl, and from psammoma to psammoma. Usually, PGDS immunoreactivity was intense in the tumor that included more syncytial portions, where cell borders had disappeared and individual cells were no longer distinguishable. The immunoreactive deposits could be seen throughout the cytoplasm or were occasionally concentrated in the perinuclear region (Fig. 3C). Meningocytic whorls, where cells were arranged in a spiral-like structure, often showed an intense PGDS immunoreactivity (Fig. 3A), especially when they contained calcification deposits, the so-called psammoma bodies.
Arachnoid cells in the villous core were ultrastructurally abundant with enlarged rough ER membrane (Fig. 2F). 
Fig. 3. Immunohistochemical staining for PGDS in human meningioma of the syncytial type. A, At low magnification, intense DAB reaction products are seen within whorls (arrows). B, Control using preabsorbed antibody (same magnification as A). C, High-power light microscopic photograph reveals cytoplasmic PGDS immunoreactivity near cell nuclei (A-C counterstained with hematoxylin). D, Immunoelectron micrograph of a meningioma cell shows PGDS at the rough ER membrane, when it is compared with the conventional electron micrograph F, and aggregates of DAB reaction products are seen within the cistern of the perinuclear region (arrows; no counterstaining). N, Nucleus. E, Control using nonimmunized rabbit serum (same magnification as D). N, Nucleus. F, Electron micrograph of a meningioma cell shows abundant rough ER membrane in the cytoplasm (uranyl and lead staining). N, Nuclei. Scale bars: A, 200 µm; C, 50 µm; D, 2 µm; F, 3 µm.
[View Larger Version of this Image (129K GIF file)]
By immunoelectron microscopy, PGDS was also demonstrated to be localized at the rough ER membrane. PGDS often was concentrated in the perinuclear region as an aggregate of DAB reaction products (Fig. 3D).
Meningioma cells were ultrastructurally abundant with enlarged rough ER membrane (Fig. 3F), similar to arachnoid barrier cells (Fig. 1F) or core arachnoid cells (Fig. 2F).
Furthermore, in an additional immunohistochemical study, intense PGDS immunoreactivity was seen, especially in the outer aspects of spherical calcification corpuscles, psammoma bodies, or ossification deposits, which are sand-like centrically laminated, calcareous structures in the typical psammomatous (Fig. 4A) or ossifying meningiomas (Fig. 4B), although the surrounding tumor cells showed little staining. 
Fig. 4. Immunohistochemical staining for PGDS in human psammomatous meningioma or ossifying meningioma. A, In psammomatous meningioma, intense DAB reaction products are detected, especially in the outer aspects of psammoma bodies (arrows). B, Another example of PGDS localization in ossification deposits (asterisk) in ossifying meningioma. (A and B counterstained with hematoxylin.) Scale bars, 100 µm.
[View Larger Version of this Image (150K GIF file)]
Control stainings
The control immunohistochemical stainings of arachnoid (Fig. 1B,E), arachnoid villi (Fig. 2B,E), and meningiomas (Fig. 3B,E), using preabsorbed antibody and/or nonimmunized rabbit serum as primary antibodies, were negligible at both light and electron microscopic levels.Biochemical and molecular biological detection of PGDS
As revealed by Western blot (Fig. 5), the extent of PGDS expression varied from case to case, although PGDS bands were specifically identified at ~29 kDa in all cases.
Fig. 5. Western blot analysis for PGDS in human meningiomas. PGDS is expressed to a variable extent in various types of meningiomas (S, syncytial; T, transitional; F, fibroblastic; Ag, angiomatous; At, atypical). The position of molecular weight marker is indicated at the left.
[View Larger Version of this Image (41K GIF file)]
PCR was performed for the PGDS and GAPDH cDNA in parallel under the same conditions (Fig. 6). Both PGDS- and GAPDH-specific oligonucleotide primers generated a distinct single fragment of 342 and 600 bp, respectively, although it was weak in the fibroblastic type, presumably because of the small cell number. The PGDS gene showed an almost equal amount of expression in all cases, regardless of the histological subtypes and regardless of benign or malignant character. Arachnoid villi similarly showed PGDS gene expression. 
Fig. 6. RT-PCR analysis for PGDS gene in human arachnoid villi and meningiomas. PGDS gene is amplified by RT-PCR, and its expression of 342 bp (top) is observed consistently in arachnoid villi (Ar) and all meningioma cases (S, syncytial; T, transitional; F, fibroblastic; Ag, angiomatous; At, atypical types). As an internal control, the expression of GAPDH gene of 600 bp (bottom) is also shown.
[View Larger Version of this Image (36K GIF file)]
DISCUSSION
PGDS in arachnoid cells
The present immunoelectron microscopic data, when compared with the conventional ultrastructural feature, indicate that PGDS is synthesized mainly at the rough ER membrane of arachnoid cells. This is consistent with the previous findings in oligodendrocytes of adult rats (Urade et al., 1987
In rat leptomeninges, we found a different pattern of PGDS localization (N. Eguchi, C. T. Beuckmann, Y. Urade, and O. Hayaishi, unpublished results). In rat, PGDS is not located in arachnoid barrier cells but is located exclusively in arachnoid trabecular cells, which in humans do not possess PGDS. The intracellular localization of PGDS in rat arachnoid trabecular cells is the outer nuclear envelope and ER membrane. These findings may reflect an important aspect of functional difference in PGDS among species. Anatomically and histologically, human and rat leptomeninges differ remarkably. For instance, in rat arachnoid membrane only very few arachnoid villi can be found, and they do not show development of arachnoid cell layers or cap cell clusters. Furthermore, in contrast to human CSF, the bulk flow of CSF in rat is drained via a nasal route into the lymphatics (Kida et al., 1993 PGDS in meningioma cells
The roles of PGDS in human meningiomas are unclear at present, but their further characterization might allow a clear understanding of these tumors. The present study demonstrated abundant expression and biosynthesis of PGDS in human meningioma cells. Although the extent of PGDS expression and immunoreactivity varied from case to case, an almost equal amount of amplified PGDS gene was found in all of the histological subtypes of meningiomas, regardless of benign or malignant character. Because human brain tumors such as malignant astrocytomas (five cases), oligodendrogliomas (three), acoustic neurinomas (three), ependymomas (three), pituitary adenomas (three), craniopharyngiomas (three), hemangioblastomas (three), metastatic brain tumors (three), and choroid plexus papilloma (one) showed negligible PGDS immunoreactivity in our additional study (data not shown) using the same antibody, PGDS can be considered a specific cell marker of meningiomas.
Yamashima and Yamashita (1990)
Interestingly, the PGDS immunolocalization in meningiomas was often concentrated both within meningocytic whorls containing calcification deposits and at the hot calcification or ossification sites around psammoma bodies (Fig. 4). It was already demonstrated that there are numerous precursors of psammoma bodies in the vicinity of immature psammoma bodies and within meningocytic whorls in arachnoid villi (Yamashima et al., 1986 Dual function of PGDS
Finally, the present data point out that human arachnoid and meningioma cells can serve as an excellent material to study both the function and metabolism of PGD2 and the bifunctional ability of PGDS as a PGD2-producing enzyme and a potential lipophilic ligand transporter, as proposed previously (Urade, 1996
To clarify the function of PGDS in the human brain and meningiomas, possible lipophilic candidates as a ligand for this transport enzyme should be determined. The outcome of possible candidates should be studied further with particular attention paid to the function of arachnoid cells or arachnoid villi, differentiation of meningioma cells, and participation in calcification or ossification processes. The possibility should also be considered that PGD2 itself is attached to the enzyme of its synthesis, transferred with the circulating CSF, and then taken up by neurons or glial cells where it might elicit a function.
FOOTNOTES
Received Sept. 26, 1996; revised Dec. 18, 1996; accepted Jan. 9, 1997.
Correspondence should be addressed to Tetsumori Yamashima, Department of Neurosurgery, Kanazawa University School of Medicine, Takaramachi 13-1, Kanazawa 920, Japan.
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