Abstract
Diagnostic markers of malignant mesothelioma (MM) have been extensively investigated. Immunohistochemistry (IHC) markers, such as calretinin, have been used for pathologic diagnosis. However, more diagnostic markers are required to improve the specificity and sensitivity of pathologic diagnosis. This study proposed two proteins as diagnostic markers for epithelioid MM. One is RhoA, an MM mutation-susceptible locus-derived protein, and another is vigilin, a lung small cell carcinoma marker. IHC was performed using 93 MM (epithelioid, 71 cases; sarcomatoid, 13 cases; and biphasic, 9 cases), 64 lung adenocarcinoma (LAC), 60 lung squamous cell carcinoma (LSC), and 14 normal mesothelial (NM) tissues. The majority of epithelioid MM cases were positive for both RhoA and vigilin, whereas both IHCs showed lower stainability in biphasic and sarcomatoid MM. Besides, both IHCs showed significantly higher stainability for RhoA and vigilin in epithelioid MM than in LAC and LSC (p < 0.05). Chi-square tests showed that both RhoA and vigilin IHC positive rate in epithelioid MM was not significantly different from that of calretinin (p > 0.05). In the differential diagnosis of MM from lung cancer, the accuracy and specificity of RhoA, vigilin, and calretinin staining were almost equivalent. Further, H-score test showed that there was no significant difference between RhoA versus calretinin and vigilin versus calretinin in IHC positivity in epithelioid MM (p > 0.05). In conclusion, RhoA and vigilin may be candidates for immunohistochemical markers for epithelioid MM.
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Introduction
Malignant mesothelioma (MM) is a tumour derived from the mesothelial cells in the serosa that cover the body cavity's inner surface. Exposure to asbestos has been epidemiologically proven to be an etiologic factor for the onset of MM1. In Japan, asbestos has affected the health of factory workers as well as members of the general public with no occupational exposure history. According to prevalence statistics data from the Ministry of Health, Labour, and Welfare, Japan, the number of asbestos-related deaths in Japan tripled from 500 in 2005 to 1400 in 20142.
The clinical diagnosis of MM requires a comprehensive analysis of the patient’s history of asbestos exposure, image-based diagnosis, and assessment of hyaluronic acid levels in the pleural effusion. However, the diagnosis of tumours using standardised biochemical tests is challenging because tumour markers or MM-specific proteins necessary for pathological diagnosis have not been identified. It is also difficult to distinguish between MM and pleuritis or to make a differential diagnosis of MM from ovarian cancer, lung adenocarcinoma (LAC), sarcomatoid cancer, and pleurisy3. The histological diversity of tumour subtypes also makes diagnosis time-consuming4.
Novel techniques using next-generation sequencing to analyse the MM genome have shown that MM has relatively few gene mutations, with an average of 24 amino acid mutations (non-synonymous mutations) reported through exosome analysis5. However, detailed reports for MM proteins in tissues are limited. This study aimed to examine RhoA, a mutation-susceptible locus-derived protein, and vigilin (high-density lipoprotein-binding protein; HDLBP), an endoplasmic reticulum (ER)-localised protein, as potential diagnostic markers of epithelioid MM.
The five genes with the highest mutation ratios in MM are CDKN2A (cyclin-dependent kinase inhibitor 2A)6, BAP1 (BRCA1-associated protein 1)7, NF2 (neurofibromatosis type 2), TP538, and RhoA9,10. A high-risk germline mutation in the BAP1 gene has been previously reported for MM, with somatic BAP1 mutations found to be latent in more than 20% of MM patients11,12. In addition to BAP1 loss13, MTAP(methylthioadenosine phosphorylase) loss help diagnose mesothelioma tumorigenesis6,9,14,15. NF2 has also been a target molecule for MM therapy16.
First, we noted RhoA as a candidate marker. Second, we noted vigilin protein, an RNA-binding nuclear-cytoplasmic shuttle protein that is localised to the nucleus and the rough ER. This protein plays a vital role in cellular sterol metabolism17 and is one of the candidate markers of lung small cell carcinoma18. ER stress has been noted as one of the pathogenic factors of MM19. Thereafter, we conducted IHC assay for the two proteins.
Results
IHC of RhoA
Patient characteristics are shown in Table 1. The majority of epithelioid MM cases were positive (overall, 67%; pleural, 88%; abdominal, 50%), and the staining was diffuse in the cytoplasm for RhoA (Fig. 1a and 2a; Tables 2 and 3). Sarcomatoid MM and most of the biphasic MM cases were negative for RhoA (Supplementary Figs. 1a and 2a; Table 2). Normal mesothelial (NM) tissues were also negative for RhoA. RhoA positivity rate in epithelioid MM tissue samples was higher than that in other types of MM, LAC, and LSC tissue samples (7% and 8%), consistent with the results of previous studies20,21 (Fig. 2b and 2c; Table 3). Chi-square tests of the RhoA positivity for epithelioid MM showed significant differences in p-values compared to that for LAC and LSC (p < 0.05) (Table 3). This result suggested that RhoA may be a promising marker for the differential diagnosis of epithelioid MM.
IHC of vigilin
The majority of epithelioid MM cases were positive for vigilin (overall, 79%; pleural, 77%; abdominal, 81%) (Fig. 1b and 2b; Tables 2 and 3). Staining was diffuse in the cytoplasm. Sarcomatoid MM and biphasic MM were negative for vigilin (Supplementary Figs. 1b and 2b). The positivity of LAC and LSC for vigilin was 8% and 5%, respectively (Fig. 2d and 2e; Table 3). Chi-square tests of the vigilin positivity for epithelioid MM showed significant differences in p-values compared to that for LAC and LSC (p < 0.05) (Table 3). NM cells were negative for vigilin. Parallel to our findings with RhoA, vigilin IHC results clearly distinguish between MM and lung cancer.
Usability of RhoA and vigilin staining for epithelioid MM diagnosis
We compared the IHC positivity of RhoA, vigilin, D2-40 and calretinin. The results of each immunostaining of epithelioid MM are shown in Table 3 and Fig. 3a–c . The positivity rate for calretinin was 81%, consistent with previously reported results22. Besides, The H-score was evaluated based on each IHCstaining intensity and positivity (Fig. 3d and 3e and supplementary Fig. 3a–f). There were no significant differences in the scoring for RhoA (the mean score = 61.0) and vigilin (73.4) compared to that for calretinin (96.7) (p = 0.24, Rho A vs. calretinin; p = 0.40, vigilin vs. calretinin). The H-score in RhoA IHC showed a moderate correlation with vigilin, D2-40, and calretinin. The H-score in vigilin IHC showed a weak correlation with D2-40 and calretinin. Finally, chi-square tests of the RhoA and vigilin IHC(positive for epithelioid MM and negativity for lung cancer) showed no significant difference compared to the calretinin IHC (p > 0.05) (Table 4). These results showed the same usefulness of RhoA and vigilin in IHC of epithelioid MM as calretinin.
Discussion
This study found that RhoA and vigilin are candidates for novel biomarkers for the diagnosis of MM. RhoA has the GTPase activity and contributes to the cytoskeleton proteins polymerisation. RhoA regulates non-small lung cancer cell migration, but RhoA-related signal cascades in mesothelioma cells are inhibited by crocidolite, a type of asbestos23. Crocidolite activates NF-κB and promotes the nitric oxide synthesis by inhibiting the RhoA signalling pathway24. Furthermore, RhoA signalling inhibits the migration of breast cancer cells by decreasing stress fibres25.
Thus, because RhoA is involved in cell migration, its mutation may affect mesothelioma migration. It is essential to examine the correlation between RhoA gene mutations and RhoA protein expression levels. Several mutations are non-synonymous with possible functional damage; however, the expression level is not necessarily reduced9. Considering that crocidolite suppresses the RhoA-related signal pathway, the increase in RhoA may be a reactive compensation response. If IHC positivity and the RhoA mutation are positively correlated, IHC may be an alternative analytical method. As an IHC marker, RhoA showed less staining variation between tumour cells than did D2-40 in epithelioid MM (Fig. 3a,b). Therefore, RhoA staining is highly stable and useful for the differential diagnosis of epithelioid MM26,27.
Vigilin was diffusely positive in the cytoplasm, consistent with its localisation in the ER. We hypothesise that the high IHC stainability of calretinin and vigilin may indicate that ER stress in MM28 promotes the accumulation of vigilin17. The ER also functions as an intracellular calcium reservoir and is a calcium-mediated signal transmission site. As calcium signalling is tightly regulated by homeostasis, calretinin upregulation may indicate active ER metabolism under asbestos-exposure stress. Also, vigilin may promote hepatocellular carcinoma cell proliferation and tumour growth29. Besides, vigilin is downregulated in breast cancer cells and is known to downregulate the post-transcriptional expression of the proto-oncogene c-fms encoding CSF-1R in breast cancer17. However, it remains unclear whether vigilin is directly involved in the tumorigenesis of epithelioid MM.
The IHC positivity rates of RhoA and vigilin for epithelioid MM were not significantly inferior to that of calretinin22,30 (Figs. 2 and 3). Although there was no significant difference in H-score, the IHC stainability of calretinin was more definite than that of both RhoA and vigilin. Therefore, it is necessary to improve the IHC protocols of RhoA and vigilin to obtain more sufficiently stable staining properties in the future for IHC application of both RhoA and vigilin.
As shown in Table 2, the positivity rate of both RhoA and vigilin in biphasic and sarcomatoid MM is not high, suggesting that the pathogenesis of epithelial MM is different from that of sarcomatoid and biphasic MM. A recent study has shown that mesothelial-to-mesenchymal transition (EMT) in mesothelial cells is associated with progression of mesothelioma and its poor prognosis31. We demonstrated that both RhoA- and vigilin-positive epithelioid MM cells had retained morphologic features of normal monolayer mesothelial cells (Fig 1a and b). We speculate that mesothelial cells progress to epithelioid MM during EMT, biphasic MM during tumour progression, and sarcomatoid tumours at later stages in parallel with loss of RhoA and vigilin expression. A previous study has demonstrated that the combination of MTAP and BAP1 IHC helps distinguish sarcomatoid mesothelioma from fibrous pleuritis32. We will compare RhoA and vigilin positivity with these sarcomatoid markers.
Differentiating between MM cells and LAC cells in pleural fluid is often difficult because of the morphological similarity between these tumours; therefore, immunostaining is helpful. Table 4 shows that the accuracy, sensitivity, and specificity of RhoA, vigilin, and calretinin staining in differentiating lung cancer from epithelioid MM were almost equivalent. For verification of the usability of RhoA and vigilin as diagnostic markers, the sample size was insufficient; however, the pertinence of this study lies in the elucidation of candidates. Furthermore, studies focusing on the comparison between MM, soft tissue tumours, and reactive mesothelial tissues will be necessary for a more accurate differential diagnosis of MM.
In summary, we observed that RhoA and vigilin could serve as reliable immunostaining markers for epithelioid MM. In the future, we hope to confirm and expand on these findings, both with increased numbers of MM cases and by comparing the expressed protein with clinical test data.
Methods
Samples
MM, including epithelioid type, normal mesothelial (NM) tissues adjacent to MM lesions, and LAC tissues, obtained as a tissue microarray (mesothelioma: MS801b, MS1001a, MS481d; core size 1.0 mm), LAC (LC641), and lung squamous cell carcinoma (LSC) (BS04041) (US Biomax, Inc., Rockville, MD) were used. Informed consent was obtained from all patients before the collection of primary samples, which were residual tissues, by doctors consulted by Biomax. The study was performed in compliance with the guidelines and with the permission of the Medical Ethics Committee of the Kyoto University Graduate School of Medicine, Japan. No genetic data were obtained. The profiles of 93 MM patients and reference materials, including lung cancer samples (LAC 64 cases, LSC 60 cases, and 28 NM tissues of adjacent tumours) are listed in Table 1. For each patient, two different tissues were used in the analysis to confirm the IHC data. The histology of these tissues was validated by two pathologists using additional IHC of D2-40, WT-1, and calretinin. NM tissues were selected using microscopic analysis. Two pathologists confirmed MM using IHC.
IHC
RhoA, vigilin, and D2-40 were stained using an EnVision kit (Agilent Life Technologies, Dako, Glostrup, Denmark) following the manufacturer’s protocol. The antibodies used for IHC were RhoA (ab236728, rabbit polyclonal, Abcam, Cambridge, UK), HDLBP/Vigilin (LS‑C440679; LSBio, Seattle, WA), and podoplanin/gp36 (D2-40) (ab77854, mouse monoclonal, clone D2-40, Abcam). All antibodies used were appropriate for IHC of FFPE. The antibodies were diluted 1:20 for staining. To confirm the diagnosis of MM, additional IHC was performed using a Ventana BenchMark AutoStainer (Ventana Medical Systems, Tucson, AZ) with a primary antibody against BAP1 (clone C4, rabbit monoclonal, Santa Cruz Biotechnology, Santa Cruz, CA), WT1 (clone 6F-H2, Mouse, Dako M3561, Agilent, Santa Clara, California), and calretinin (rabbit polyclonal, Invitrogen 08-1211, Waltham, MA). BAP1 staining was considered negative or weak in MM. In IHC for LC641, the cases showing squamous features were excluded because of non-specific staining and tissue damage. We selected TMA cores from 93 cases (2 cores per case for a total of 186 cores) with at least two of these four markers positive and immunostained them with anti-RhoA and anti-vigilin antibodies. The criteria of positivity/retained and negativity in BAP-1 immunostaining was based on a previous study13.
Histological evaluation and chi-square test
H score was determined based on staining intensity and the percentage of stained cells as follows: (% tumour cells-stained 1+ × 1) + (% of tumour cells-stained 2+ × 2) + (% tumour cells stained 3+ × 3)33. Scores of 3+, 2+, and 1+ were assigned to each antibody. The following scoring was applied to RhoA, vigilin, and calretinin: 3, definite positivity of > 50% of cells; 2, definite positivity of < 50% of cells or weak positivity of > 50% of cells; 1, weak positivity of < 50% of whole cells; 0, negative staining34,35,36. In case of scores 3 and 2, the IHC for RhoA and vigilin was deemed positive (Supplementary Fig. 3). Chi-square test was performed using Excel software (Redmond, Washington, U.S.).
Data availability
The datasets generated and/or analysed during the current study are available from the corresponding author upon reasonable request.
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Acknowledgements
We thank the Medical Research Support Center and Center for Anatomical, Pathological and Forensic Medical Research and Medical Research Support Center, Graduate School of Medicine, Kyoto University for immunohistochemistry. The Radiation Effects Research Foundation, Hiroshima and Nagasaki, Japan, is a public interest foundation funded by the Japanese Ministry of Health, Labour and Welfare (MHLW) and the US Department of Energy (DOE). The views of the authors do not necessarily reflect those of the two governments.
Funding
This study was supported by a Grant-in-Aid from the Ministry of Education, Culture, Sports, Science, and Technology of Japan [Grant number 17H04059].
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T.H., A.Y., and T.T. performed experiments and analysed imaging data. T.T. selected samples and performed experiments. T.H. and T.T. and analysed imaging data. T.Y. and Y.Y. supported in data analysis. T.T. prepared the original draft of the manuscript. S.T. reviewed the manuscript.
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Hiratsuka, T., Yamamoto, T., Yoshizawa, A. et al. RhoA and vigilin are candidates for immunohistochemical markers for epithelioid malignant mesothelioma. Sci Rep 12, 18519 (2022). https://doi.org/10.1038/s41598-022-20334-0
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DOI: https://doi.org/10.1038/s41598-022-20334-0
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