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Mesothelin Expression in the Leptomeninges and Meningiomas

Mahlon D. Johnson, Fran Vito and Mary J. O'Connell

Division of Neuropathology, Department of Pathology, University of Rochester Medical Center, Rochester, New York

Correspondence to: Mahlon Johnson, MD, PhD, Department of Pathology and Laboratory Medicine, University of Rochester Medical Center, 601 Elmwood Avenue, Box 626, Rochester, NY 14623. E-mail: mahlon_johnson{at}urmc.rochester.edu

	Summary

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The identity and functions of surface proteins on human leptomeningeal and meningioma cells are incompletely characterized. Some structural and functional similarities between the leptomeninges and pleura suggest that proteins important to pleural function and tumorigenesis might also be relevant to leptomeningeal disease. Mesothelin is a recently described, 40-kDa membrane protein expressed in pleura. Its functions in this tissue are under investigation. Sections of 20 normal adult brains with leptomeninges and 49 World Health Organization (WHO) grade I, 21 grade II, and 2 grade III meningiomas were analyzed using an extensively characterized monoclonal antibody to mesothelin and streptavidin-biotin complex immunohistochemistry. Five meningiomas were also evaluated by Western blot. Mesothelin immunoreactivity was detected in the arachnoid in 6 of 20 cases and in 23 of 49 WHO grade I meningiomas. It was also detected in 7 of 21 WHO II tumors and 1 of the 2 anaplastic meningiomas. By Western blot, all five meningiomas exhibited mesothelin precursor protein, including one where notable immunoreactivity was not identified in a formalin-fixed tissue section. These findings suggest that mesothelin is expressed in at least some arachnoid and meningioma cells. Future studies may clarify its role in the development of meningiomas, meningeal seeding of gliomas, and metastases to the leptomeninges. (J Histochem Cytochem 56:579–585, 2008)

Key Words: mesothelin • meningioma • leptomeninges • arachnoid

	Introduction

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THE IDENTITY and functions of surface proteins on human leptomeningeal cells are incompletely understood. Their role in the pathogenesis of meningiomas, meningeal carcinomatosis, or meningitis is not established. Some structural and functional similarities between the leptomeninges and pleura raise the possibility that proteins important to pleural function and tumorigenesis might also be expressed in, and important to the function of, leptomeningeal or meningioma cells (Mutsaers 2002; Weller 2005). Recently, mesothelin, a 40-kDa glycosyl-phosphatidylinositol-anchored protein cell surface protein, has been identified in mesothelial cells of the pleura. The human mesothelin gene encodes a 71-kDa precursor protein including a 31-kDa NH2-terminal fragment, megakaryocyte-potentiating factor, which is cleaved and released from the cell to produce the 40-kDa carboxyl, membrane-bound mesothelin (Yamaguchi et al. 1994; Kojima et al. 1995; Chang and Pastan 1996). Three variants have now been identified, including a soluble mesothelin-1, a unique mesothelin-2 transcript, and mesothelin-3, a variant with an extended C terminus (Scholler et al. 1999; Muminova et al. 2004). Mesothelin-1 has been found in the pleura, pericardium, and peritoneum and on surface epithelium of the ovaries, tonsils, and fallopian tubes (Ordonez 2003). It is also overexpressed in mesotheliomas, pancreatic adenocarcinomas, and squamous cell carcinomas of the head, neck, lung, esophagus, cervix, and vulva (Chang and Pastan, 1992,1996; Frierson et al. 2003).

Mesothelin is a cell surface differentiation protein. The functions of mesothelin are not established but may include a role in cell adhesion (Chang and Pastan 1996). However, the importance of this role is uncertain because mice deficient in mesothelin develop normally, reproduce, and display no overt histologic abnormalities in a number of tissues (Bera and Pastan 2000).

The expression of mesothelin in the human leptomeninges and meningiomas has not been studied. Nonetheless, some similarities in the structure and functions of the pleura and leptomeninges suggest that mesothelin might be expressed in leptomeningeal cells or meningiomas and important to meningeal function. In this study, we analyzed leptomeninges in adults and World Health Organization (WHO) grade I–III meningiomas.

	Materials and Methods

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Leptomeninges from autopsy samples of 20 adult patients who died without neurologic disease or central nervous system lesions and 72 meningiomas were analyzed. The latter group included 49 WHO grade I, 21 WHO grade II, and 2 WHO grade III meningiomas (Perry et al. 2007) collected between 2000 and 2007 from the University of Rochester or from the consultation service. Patient characteristics for the leptomeningeal samples and tumor characteristics are listed in Tables 1 and 2, respectively.

Western Blots
Protein from five WHO grade I meningiomas was obtained by mechanical homogenization in RIPA Lysis Buffer (Upstate Biotechnology; Waltham, MA) with 1:100 Protease Inhibitor Cocktail (Sigma) and frozen at –85C. The tissue slurries were thawed on ice and vortexed vigorously. Solids were removed by centrifugation. Protein concentrations were quantified using a Bradford assay (BioRad Protein Assay reagent), and 35 µg protein from each was loaded on 7.5% acrylamide gels and transferred to 0.45-µm nitrocellulose membrane. The membrane was blocked overnight at 4C in 5% milk in Tris-Cl buffer with Tween 20 and reacted with an affinity purified goat anti-mesothelin 69-kDa precursor primary antibody (sc-27714; Santa Cruz Biotechnology, Santa Cruz, CA) at 1:200 for 2 hr at room temperature. This was followed by horseradish peroxidase–conjugated secondary antibody treatment. Detection was achieved with Western Lightening (PerkinElmer; Boston, MA) on Xomat film (Kodak; Rochester, NY).

	Results

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Immunohistochemical findings are summarized in Tables 1 and 2. Mesothelin immunoreactivity was not detected in normal pia but was found in the cytoplasm of arachnoid cells in six cases with leptomeninges (Figure 1A ). In meningiomas, mesothelin immunoreactivity was detected in the cytoplasm and was variably distinct in the cell membrane in 23 of 49 (47%) WHO grade I meningiomas (Figure 1B), including 10 of 14 (71%) meningothelial, 9 of 18 (59%) transitional, and 1 of 11 (9%) fibrous tumors. The percentage expression in the meningothelial and transitional subtypes was significantly different than that in the fibroblastic group (p<0.005). It was also detected in 7 of 21 (38%) WHO grade II tumors, including 4 of 9 (44%) meningothelial, 2 of 5 (40%) transitional, and 1 of 5 fibrous (20%) subtypes. One of the two anaplastic meningiomas was positive.

View larger version (127K): [in this window] [in a new window]   Figure 1 Mesothelin immunohistochemistry. (A) Mesothelin immunoreactivity is seen in arachnoid cells (arrow) in leptomeninges but not in connective tissue. Mesothelin immunoreactivity is also seen in (B) WHO grade I meningothelial cells but not in endothelial cells or blood vessels; (C) in transitional meningioma cells but not the dura (left and bottom right); and (D) in fibrous meningioma cells but not the interspersed collagen.

View larger version (31K): [in this window] [in a new window]   Figure 2 Mesothelin Western blot. Mesothelin precursor protein (69 kDa) is detected in all five WHO grade I meningiomas (Cases 43, 45, and 47–49).

	Discussion

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In our study, immunoreactivity was seen in the cytoplasm with a variable membrane distribution similar to the cytoplasmic, with or without membranous, immunostaining as seen in many tumors including mucinous carcinomas of the ovary, adenomatoid tumors, adenocarcinoma of the endometrium, and pancreatic adenocarcinomas (Ordonez 2003; Jhala et al. 2006). In our mesothelioma controls, using the monoclonal antibody titered to a greater dilution than used in cited studies, nests of mesothelioma cells showed membrane, but also showed cytoplasmic staining. Because meningiomas are solid, often syncytial tumors that, by definition, have interdigitating membranes, processes, and desmosomes, the distinction may be more difficult than in papillary structures such as the majority of gland and lumen-bearing adenocarcinomas studied previously, and it is felt that membrane localization occurs.

In this initial study, mesothelin was detected more commonly in meningothelial and transitional than fibrous meningiomas but was not restricted to a specific histological subtype. Several studies have suggested that sporadic WHO grade I and II meningiomas might be divided into meningothelial and non-meningothelial subtypes based on the relative expression of the neurofibromatosis type 2 tumor suppressor gene (NF-2) and merlin, its protein product. Although NF-2/merlin expression is intact in the majority of meningothelial meningiomas, inactivating mutations of the NF-2 gene and decreased merlin expression occur in 75% of WHO grade I and II transitional and fibrous subtypes (Wellenreuther et al. 1997; Buccoliero et al. 2007). Nonetheless, in this study, mesothelin was detected in 64% and 59% of grade I and II meningothelial and 59% and 60% of transitional grade I and II meningiomas, respectively. This suggests that mesothelin expression, like many proteins, might not be restricted to either meningothelial or non-meningothelial groups. To our knowledge, analysis of NF-2 gene regulation of mesothelin expression has not been studied in any tissue.

The functions of mesothelin in the normal leptomeninges and meningiomas have yet to be studied. Moreover, they have not been established in mesothelium, mesotheliomas, or other carcinomas (Ho et al. 2007). Mice deficient in mesothelin develop normally and have tissues reported to be histologically normal, although the brain was not extensively analyzed (Bera and Pastan 2000). Nonetheless, in bronchial, ovarian, pancreatic, and gastrointestinal carcinomas, the 4- to 10-fold overexpression of mesothelin suggests it plays an important role in the oncogenesis of many tumors (Chang and Pastan 1992,1996; Scholler et al. 1999; Ordonez 2003; Hucl et al. 2007).

In some pathologic conditions, mesothelin may facilitate binding of neoplastic cells to peritoneum or pleura. For example, mesothelin has been shown to bind MUC16, a mucin glycoprotein with high affinity (Rump et al. 2004; Gubbels et al. 2006). This seems to facilitate binding of ovarian carcinomas to peritoneum and may facilitate seeding (Rump et al. 2004; Gubbels et al. 2006). Although this interaction alone does not seem sufficient to secure this anchoring, it may represent an initial step in a cascade of events resulting in cell adhesion analogous to leukocyte adherence to damaged endothelium mediated by a number of selectins (Rump et al. 2004; Gubbels et al. 2006). Thus, mesothelin expression by peritoneal cells seems to bind MUC16 and facilitate ovarian carcinomatous peritonitis. Because a number of adenocarcinomas express MUC16, and adenocarcinomas represent one of the most common carcinomas metastasizing to the leptomeninges, it is conceivable that this interaction with mesothelin facilitates establishment of metastases there and development of meningeal carcinomatosis.

Screening for soluble mesothelin-related peptides (SMRPs) or the cleavage product megakaryocyte potentiation factor (MPF) in serum has been proposed as a diagnostic tool to screen for occult mesotheliomas and some carcinomas in peripheral tissues (Onda et al. 2005,2006; Scherpereel et al. 2006; Creaney et al. 2007; Ho et al. 2007). One study found significantly higher SMRPs in pleural fluid of patients with mesothelioma than in patients with other lung tumors or pleuritis, with a specificity of 98% and sensitivity of 67% (Creaney et al. 2007). Nonetheless, levels of SMRPs did not correlate with tumor volume (Hassan et al. 2006). Because meningiomas reside outside the blood–brain barrier, a study in progress is evaluating whether increased SMRPs or MPF may be detected in the serum of patients with meningiomas and might identify early recurrence.

The expression of mesothelin in the brain has not been extensively studied. In our evaluation of sections of normal cortex, mesothelin appeared confined to the arachnoid and was not widely detected. The relatively restricted expression of mesothelin in human tissues suggests that therapies targeting mesothelin in tumors might not produce extensive damage to many normal tissues. In recognition of this, monoclonal antibodies against mesothelin are being developed as a possible therapy for carcinomas widely expressing mesothelin (Hassan et al. 2004; Onda et al. 2005). Demonstration of mesothelin in the leptomeninges and meningiomas, which are outside the blood–brain barrier, raises the possibility that such immunotherapies might also be useful for treating meningiomas. Such antibodies might also be useful in blocking or limiting the adhesion of metastasis, particularly of mucin-16–expressing carcinomas to the leptomeninges. Studies underway are evaluating these possibilities.

	Acknowledgments

 
We thank Dr. Jay Reeder for helpful comments on the project.

	Footnotes

 
Received for publication January 14, 2008; accepted February 28, 2008

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