Clinicopathologic Characteristics and Mutational Status of Succinate Dehydrogenase Genes in Paraganglioma of the Urinary Bladder: A Multi-Institutional Korean Study.
It was demonstrated that an absence of SDHB staining in tumor cells indicates underlying SDH germ line mutations with high reliability. (11) In contrast, a loss of SDHA staining in tumor cells has been observed only in SDHA mutations. (12) Concurrent loss of SDHA and SDHB staining is encountered in tumors with only SDHA mutations, but a loss of only SDHB staining is found in tumors with all SDH mutations, except for the SDHA mutation. Therefore, it is recommended that SDHA sequencing be performed if a tumor shows a loss of both SDHA and SDHB stains. Sequencing of SDHB, SDHC, or SDHD is required if a tumor shows a loss of SDHB staining and intact SDHA staining. (13)
Primary bladder PGs (PBPGs) are extremely rare, accounting for less than 0.05% of all bladder tumors. (14) Because of the limited number of available PBPG cases, the rates of SDH mutations and clinicopathologic characteristics of SDH-deficient tumors have not been fully determined. Herein, we report a retrospective study that was performed using 52 PBPG cases collected from major institutions in Korea.
MATERIALS AND METHODS
Pathology and Medical Record Review
A search of pathology databases was performed for PBPGs from 19 institutions--namely, Ewha Womans University Mok-dong Hospital (Seoul), Samsung Medical Center (Seoul), Ajou University Hospital (Suwon), Yonsei University Severance Hospital (Seoul), Korea University Anam Hospital (Seoul), Inje University Haeundae Paik Hospital (Pusan), Inje University Sanggye Paik Hospital (Seoul), Seoul National University Hospital (Seoul), Hanyang University Guri Hospital (Guri), Pusan National University Hospital (Pusan), Incheon St Mary's Hospital (Incheon), Kyung Hee University Medical Center (Seoul), Dankook University Hospital (Cheonan), Dongguk University Hospital (Gyeonju), Inje University Busan Paik Hospital (Pusan), Asan Medical Center (Seoul), Gachon University Gil Medical Center (Incheon), Konyang University Hospital (Daejeon), Seoul National University Bundang Hospital (Sungnam), and Seoul St Mary's Hospital (Seoul)--in South Korea. After reviewing all available hematoxylin-eosin stained slides, either one representative paraffin block from each case or additional unstained slides from each case were collected from each institution for further immunohistochemical and SDH mutational studies. Clinical data for each case included age at diagnosis, sex, personal tumor history, family tumor history, and clinical outcome. Pathology data for each case included type of specimen, tumor location, mitotic count, presence of necrosis, lymphovascular invasion and proper muscle invasion, and immunohistochemical staining results (when available). The Institutional Review Board at Ewha Womans University Hospital approved the study.
All immunohistochemical stains for SDHA and SDHB were performed on 4-[micro]m-thick, formalin-fixed, paraffin-embedded whole-tissue sections provided from 19 institutions after pressure cooker antigen retrieval (0.001 M citrate buffer; pH 6.0), using mouse anti-SDHA (1:700 dilution; 40-minute incubation; clone 2E3GC12FB2AE2, Abcam, Cambridge, Massachusetts) and antiSDHB (1:100 dilution; 40-minute incubation; clone 21A11AE7, Abcam) monoclonal antibodies, as previously described. (13) One case of pheochromocytoma with a known SDHB mutation, and one with a known SDHD mutation, were used as controls for tumors with loss of SDHB immunohistochemical staining. (15,16) For a negative control used for SDHA antibody, dilution buffer was used instead of the primary antibody. Expression was evaluated as "intact" when granular cytoplasmic staining was observed in tumor cells. On the other hand, expression was evaluated as "deficient" when there was a complete absence of granular cytoplasmic staining in tumor cells along with positive staining in the internal positive control cells, such as sustentacular or proper muscle cells of the urinary bladder.
In cases of SDHB expression loss, mutation analyses of SDHB, SDHC, and SDHD were performed. Genomic DNA was isolated from the tumor using a QIAamp DNA FFPE tissue kit (Qiagen, Valencia, California). Tumor DNA was amplified using primers for exons 8, 6, and 4 of SDHB, SDHC, and SDHD, respectively (primers used are listed in Table 1). Normal corresponding tissues were not available. Bidirectional sequencing was performed using the BigDye Terminator v1.1 kit (Applied Biosystems, Foster City, California) on an ABI 3130xl genetic analyzer (Applied Biosystems). Sequencer version 4.10.1 (Gene Codes Corporation, Ann Arbor, Michigan) was used, along with manual chromatogram reviews for sequence analysis. Confirmatory resequencing from replicate polymerase chain reaction (PCR) was performed for sequences that were ambiguous or deviated from wild-type, so that all abnormal sequences were confirmed in at least quadruplicate for replicate amplification reactions. The results were marked as mutation-positive if a mutation was detected in both the forward and reverse DNA strands.
Clinicopathologic data are summarized in Table 2. The patient population (N = 52) included 27 male (52%) and 25 female (48%) patients, with a mean age of 56 years at diagnosis (range, 22-79 years). At the time of diagnosis, patients with SDHB-deficient tumors were relatively younger than patients with SDHB-intact tumors (means, 43 and 59 years, respectively; P = .002). All patients presented with a single isolated tumor. Tumor sizes were available in 50 of the 52 cases, including 41 SDHB-intact and 9 SDHB-deficient cases. The mean tumor size was 2.4 cm, and it was larger for SDHB-deficient tumors compared with SDHB-intact tumors (means, 4.5 and 1.9 cm, respectively; P < .001). A nested, zellballen pattern was present in all cases (Figure 1, A). The mean number of mitoses per 10 high-power fields was 0.3, and it was higher for SDHB-deficient tumors compared with SDHB-intact tumors (means, 2.6 and 0.1, respectively; P = .002). One atypical mitosis was identified in a case of an SDHB-deficient tumor (Figure 1, B). Of 52 cases, tumor necrosis was present in 5 cases (10%), proper muscle invasion was present in 41 cases (79%), and lymphovascular invasion (LVI) was present in 6 cases (12%; Figure 1, C and D). The presence of LVI was found to occur more frequently in SDHB-deficient cases compared with SDHB-intact tumors (3 of 9; 33%; and 3 of 43; 7%; respectively; P = .02). The presence or absence of tumor necrosis and proper muscle invasion, as well as tumor cell morphology (polygonal versus spindle), nuclear size, and nuclear pleomorphism, were not associated with SDHB status or malignant PGs. Only 3 of 52 patients (6%) developed metastases during a follow-up period of 41 months (range, 1-161 months): 1 had intact SDHB and 2 were SDHB deficient. A single SDHB-intact patient had bone and lymph node metastases 3 years after initial diagnosis, an SDHB-deficient patient had lymph node metastases at the time of diagnosis, and a second SDHB-deficient patient had multiple bone metastases 8 years after the initial diagnosis. None had a family history of PGs. Comparison of benign and malignant PGs is shown in Table 3. The mean tumor size was 2.4 cm, and it was larger for malignant PGs compared with benign PGs (means, 6.2 and 2.1 cm, respectively; P= .002). Presence of LVI was found to occur more frequently in malignant PGs compared with benign PGs (2 of 3; 67%; and 4 of 49; 8%; respectively; P= .03).
Results of Immunohistochemical Analyses
SDHA and SDHB immunostaining was performed in all 52 cases, and all showed intact staining for SDHA. Of 52 cases, 9 cases (17.3%) showed a loss of SDHB expression. The remaining 43 cases (83%) showed intact staining for both SDHA and SDHB. Representative images of SDHA and SDHB staining are shown in Figure 2. Homogeneous cytoplasmic granular staining of SDHA and SDHB was observed throughout the tumors in all positive cases (Figure 2, A). Loss of SDHB staining was observed uniformly in the tumor cells, compared with positive staining of the internal control cells (endothelial, sustentacular, and proper muscle cells; Figure 2, B).
Results of Sequencing Analyses
Genetic analyses detected SDHB mutations in all 6 SDHB-deficient tumors that were successfully sequenced. The results of the sequencing analyses for the 6 cases were as follows: in the first case, 4 missense mutations were detected in exons 3 and 8. A heterozygous single-base pair substitution was found at 2 points of exon 3, c.233 A.G (p.K78R) and c.241 A>G (p.N81D); and at 2 points of exon 8, c.776 C>T (p.P259L) and c.818 A>G (p.Y273S). In the second case, 2 missense mutations were detected at exon 6, c.571 T>A (p.C191S) and c.578 G>A (p.S193N). In the third case, 1 missense mutation was detected at exon 3, c.221 T>C (p.M71T). In the fourth case, 1 silent mutation was detected at exon 1, c.171C>T (p.T57T). In the fifth case, 1 silent mutation was detected at exon 3, c.225T>C (p.A75A). In the sixth case, 1 intronic mutation was detected at exon 1, c.72+24G>A; and 1 silence mutation at exon 3, c.225T>C (p.A75A). Features of SDHB-mutated PBPGs are summarized in Table 4.
Primary bladder PGs are rare, with an incidence of only 0.67% (2 of 297) of total PGs reported. (2) Moreover, malignant PBPGs in particular are extremely rare, and the incidence of malignancy is not well known, because the relevant criteria have not been well established. In previous studies, the incidence of malignancy in PBPGs was from 6.6% to 18% of all PBPGs. (13,17,18) Based on World Health Organization criteria, PGs are defined as malignant only when metastases are identified at the anatomic sites where ganglia are normally absent. (19) Predicting the malignant potential is an issue of great interest. Clinicopathologic characteristics and a scoring system have been suggested to predict malignant potential in pheochromocytomas of adrenal glands. (20) However, this scoring system has not been well accepted for PBPGs, and the biologic characteristics of PGs arising in the bladder may be different from the pheochromocytoma of the adrenal glands. A total of 37 cases of malignant PBPGs have been previously reported, as previously summarized by literature review. (21) In this review, malignant tumors occurred more frequently in younger males, whereas size was not correlated with the likelihood of metastasis. (21) In our study, we have also found that patients with SDHB-deficient tumors were younger than patients with SDHB-intact tumors (43 and 59 years, respectively; P = .002) at the time of diagnosis, but no preference in sex was identified (P = .09). A recent report showed a female predilection (8 of 11; 73%). (22) In contrast to the literature review, we found larger sizes of SDHB-deficient tumors compared with SDHB-intact tumors (means, 4.5 and 1.9 cm, respectively; P < .001). Our result is also consistent with the recent report by Gupta et al. (22) In the literature review, metastases in the pelvic lymph nodes were most common, followed by extrapelvic metastases, including mediastinum, lung, mesentery, liver, bone, and peritoneum. (21) Regarding our 3 cases, lymph nodes and bones were the metastatic sites.
We found that mitotic activity was higher for SDHB-deficient tumors compared with SDHB-intact tumors (2.6 and 0.1 mitoses per 10 high-power fields, respectively; P = .002). This result is consistent with previous research. (13) In our study, mitotic figures were very rare and difficult to find in SDHB-intact PGs, but occasional mitoses were identified in SDHB-deficient PGs, with 1 case of an SDHB-deficient PG exhibiting an atypical mitosis. We also found that the frequency of LVI was higher for SDHB-deficient tumors compared with SDHB-intact tumors (33% and 7%, respectively; P = .02). Reliable pathologic criteria have not been established for malignancy to date. In our study, we did not definitely identify any morphologic features that could be useful when predicting malignant PBPGs, because only 3 cases showed evidence of malignancy. However, large tumor size (6.2 and 2.1 cm, respectively; P = .002) and the presence of LVI (67% and 8%, respectively; P = .03) may be useful features in predicting aggressive biologic behavior of PBPGs.
SDH mutations have been found in approximately 30% of both head and neck, and thoracoabdominal PGs, (6,7) with SDHB mutations being detected more frequently in thoracoabdominal PGs compared with head and neck PGs. (6) Although SDHB mutations in PBPGs have been reported, the rate of SDH mutations in PBPGs has not been established to date. In 2 recent reports, SDH mutations were mainly SDHB, although SDHA mutations were also noted. (13) In accordance with these studies, our results also demonstrated that SDHB mutations predominated. SDHB mutations correlated with malignant behavior in both PGs and pheochromocytomas. (7-10) In our study, all 6 SDH-deficient cases that were successfully sequenced showed SDHB mutations. Until now, only 2 cases have shown malignant behavior and 4 exhibited a benign clinical course (Table 4). Two cases with malignant behavior have been followed up for an extended period of time (111 and 161 months, respectively), but 4 cases with indolent behavior have been followed up for a relatively short period of time, except for 1 case (21, 24, 72, and 120 months, respectively). Therefore, these 4 SDHB-mutated indolent PGs have to be followed up for an extended period of time in order to fully confirm whether they are truly benign or not, because in some cases, metastases can occur many years after the initial diagnosis.
Our study has several limitations. First, it was a retrospective, nationwide, multi-institutional study that evaluated the clinicopathologic characteristics of PBPGs and, as such, only paraffin-embedded tumor tissues were available for mutational analyses. This prevented a distinction between germ line and somatic mutations. However, cases with SDHB mutations are expected to be mostly germ line, because it is known that the vast majority of SDH-deficient PGs harbor germ line SDH mutations, with only rare reports of somatic SDH mutations. (23,24) Moreover, recent studies have also demonstrated that most cases with SDHB mutations were germ line. (13,25) Second, the follow-up period was relatively short (a mean of 41 months) compared with previous studies (means of 70 and 124 months, respectively). (13,22) This could explain the lower frequency of malignant PGs in our study (3 of 52; 5.8%) compared with the previous studies (2 of 11; 18%; and 5 of 11; 45%; respectively). (13,22) In one particular study, a single case of distant metastasis developed 10 years after diagnosis. (17) Therefore, longer follow-up periods are recommended to determine the exact frequency of malignant PBPGs. Third, mutational analysis was not available for 1 SDHB-intact tumor that developed metastasis. Even though immunohistochemistry for SDHB provides a sensitive and specific method for identifying tumors with SDH mutation, (10) in this case, the tissue was not available for mutational analysis to document unequivocal mutation results. Nonetheless, in our study we used a relatively large cohort size of 52 cases with PBPGs, which were collected nationwide from multiple institutions in Korea; therefore, we believe that this study is representative of the general clinicopathologic characteristics of PBPGs.
In conclusion, PBPG is a very rare bladder tumor with 17% (9 of 52) incidence of SDH deficiency and 5.8% (3 of 52) incidence of malignancy. Younger age of the patient, large tumor size, higher number of mitoses, and presence of LVI and SDHB mutations are potential criteria to predict the malignant behavior of PBPGs.
Please Note: Illustration(s) are not available due to copyright restrictions.
(1.) Lenders JW, Eisenhofer G, Mannelli M, Pacak K. Phaeochromocytoma. Lancet. 2005; 366(9486):665-675.
(2.) Erickson D, Kudva YC, Ebersold MJ, et al. Benign paragangliomas: clinical presentation and treatment outcomes in 236 patients. J Clin Endocrinol Metab. 2001; 86(11):5210-5216.
(3.) Nakamura E, Kaelin WG Jr. Recent insights into the molecular pathogenesis of pheochromocytoma and paraganglioma. Endocr Pathol. 2006; 17(2):97-106.
(4.) Lancaster CR. Succinate:quinone oxidoreductases: an overview. Biochim Biophys Acta. 2002; 1553(1-2):1-6.
(5.) Baysal BE, Willett-Brozick JE, Lawrence EC, et al. Prevalence of SDHB, SDHC, and SDHD germline mutations in clinic patients with head and neck paragangliomas. J Med Genet. 2002; 39(3):178-183.
(6.) Mannelli M, Castellano M, Schiavi F, et al. Clinically guided genetic screening in a large cohort of italian patients with pheochromocytomas and/or functional or nonfunctional paragangliomas. J Clin Endocrinol Metab. 2009; 94(5):1541-1547.
(7.) Amar L, Bertherat J, Baudin E, et al. Genetic testing in pheochromocytoma or functional paraganglioma. J Clin Oncol. 2005; 23(34):8812-8818.
(8.) Brouwers FM, Eisenhofer G, Tao JJ, et al. High frequency of SDHB germline mutations in patients with malignant catecholamine-producing paragangliomas: implications for genetic testing. J Clin Endocrinol Metab. 2006; 91(11):4505-4509.
(9.) Gimenez-Roqueplo AP, Favier J, Rustin P, et al. Mutations in the SDHB gene are associated with extra-adrenal and/or malignant phaeochromocytomas. Cancer Res. 2003; 63(17):5615-5621.
(10.) Neumann HP, Pawlu C, Peczkowska M, et al. Distinct clinical features of paraganglioma syndromes associated with SDHB and SDHD gene mutations. JAMA. 2004; 292(8):943-951.
(11.) van Nederveen FH, Gaal J, Favier J, et al. An immunohistochemical procedure to detect patients with paraganglioma and phaeochromocytoma with germline SDHB, SDHC, or SDHD gene mutations: a retrospective and prospective analysis. Lancet Oncol. 2009; 10(8):764-771.
(12.) Korpershoek E, Favier J, Gaal J, et al. SDHA immunohistochemistry detects germline SDHA gene mutations in apparently sporadic paragangliomas and pheochromocytomas. J Clin Endocrinol Metab. 2011; 96(9):E1472-E1476.
(13.) Mason EF, Sadow PM, Wagner AJ, et al. Identification of succinate dehydrogenase-deficient bladder paragangliomas. Am J Surg Pathol. 2013; 37(10): 1612-1618.
(14.) Dahm P, Gschwend JE. Malignant non-urothelial neoplasms of the urinary bladder: a review. Eur Urol. 2003; 44(6):672-681.
(15.) Kim ES, Kim SY, Mo EY, Jang DK, Moon SD, Han JH. Novel germline SDHD mutation in a patient with recurrent familial carotid body tumor and concomitant pheochromocytoma. Head Neck. 2014; 36(12):E131-E135.
(16.) Lee SA, Kim EH, Lee YM, et al. A novel mutation of the succinate dehydrogenase B gene in a Korean family with pheochromocytoma. Fam Cancer. 2010; 9(4):643-646.
(17.) Menon S, Goyal P, Suryawanshi P, et al. Paraganglioma of the urinary bladder: a clinicopathologic spectrum of a series of 14 cases emphasizing diagnostic dilemmas. Indian J Pathol Microbiol. 2014; 57(1):19-23.
(18.) Zhou M, Epstein JI, Young RH. Paraganglioma of the urinary bladder: a lesion that may be misdiagnosed as urothelial carcinoma in transurethral resection specimens. Am J Surg Pathol. 2004; 28(1):94-100.
(19.) Thompson LD YW, Kawashima A, Kmminoth P, Tischler AS. Malignant adrenal phaeochromocytoma. In: DeLellis RA LR, Heitz PU, Eng C, eds. Pathology and Genetics of Tumours of Endocrine Organs. Lyon, France: IARC Press; 2004:147-150. World Health Organization Classification of Tumours; vol 8.
(20.) Thompson LD. Pheochromocytoma of the Adrenal gland Scaled Score (PASS) to separate benign from malignant neoplasms: a clinicopathologic and immunophenotypic study of 100 cases. Am J Surg Pathol. 2002; 26(5):551-566.
(21.) Quist EE, Javadzadeh BM, Johannesen E, Johansson SL, Lele SM, Kozel JA. Malignant paraganglioma of the bladder: a case report and review of the literature. Pathol Res Pract. 2015; 211(2):183-188.
(22.) Gupta S, Zhang J, Rivera M, Erickson LA. Urinary bladder paragangliomas: analysis of succinate dehydrogenase and outcome. Endocr Pathol. 2016; 27(3): 243-252.
(23.) Gimm O, Armanios M, Dziema H, Neumann HP, Eng C. Somatic and occult germ-line mutations in SDHD, a mitochondrial complex II gene, in nonfamilial pheochromocytoma. Cancer Res. 2000; 60(24):6822-6825.
(24.) van Nederveen FH, Korpershoek E, Lenders JW, de Krijger RR, Dinjens WN. Somatic SDHB mutation in an extraadrenal pheochromocytoma. N Engl J Med. 2007; 357(3):306-308.
(25.) Giubellino A, Lara K, Martucci V, et al. Urinary bladder paragangliomas: how immunohistochemistry can assist to identify patients with SDHB germline and somatic mutations. Am I Surg Pathol. 2015; 39(11):1488-1492.
Sanghui Park, MD; So Young Kang, PhD; Ghee Young Kwon, MD; Ji Eun Kwon, MD; Sang Kyum Kim, MD; Ji Yeon Kim, MD; Chul Hwan Kim, MD; Hyun-Jung Kim, MD; Kyung Chul Moon, MD; Ju Yeon Pyo, MD; Won Young Park, MD; Eun Su Park, MD; Ji-Youn Sung, MD; Sun Hee Sung, MD; Young-Ha Oh, MD; Seung Eun Lee, MD; Wonae Lee, MD; Jong Im Lee, MD; Nam Hoon Cho, MD; Soo Jin Jung, MD; Min-Sun Cho, MD; Yong Mee Cho, MD; Hyun Yee Cho, MD; Eun Jung Cha, MD; Yang-Seok Chae, MD; Gheeyoung Choe, MD; Yeong Jin Choi, MD; Jooryung Huh, MD; Jae Y. Ro, MD
Accepted for publication September 20, 2016.
Published as an Early Online Release November 7, 2016.
From the Department of Pathology, Ewha Womans University School of Medicine, Seoul, Korea (Drs S. Park, S.H. Sung, and M.S. Cho); the Department of Pathology and Translational Genomics, Samsung Medical Center, Sungkyunkwan University College of Medicine, Seoul, Korea (Drs Kang and G.Y. Kwon); the Department of Pathology, Ajou University School of Medicine, Suwon, Korea (Dr J.E. Kwon); the Department of Pathology, Yonsei University College of Medicine, Seoul, Korea (Dr S.K. Kim and N.H. Cho); the Department of Pathology, Inje University Haeundae Paik Hospital, Pusan, Korea (DrJ.Y. Kim); the Department of Pathology, Korea University School of Medicine, Seoul, Korea (Drs C.H. Kim and Chae); the Department of Pathology, Inje University Sanggye Paik Hospital, Seoul, Korea (Dr H.J. Kim); the Department of Pathology and Kidney Research Institute, Medical Research Center, Seoul National University College of Medicine, Seoul, Korea (Dr Moon); the Department of Pathology, College of Medicine, Hanyang University Guri Hospital, Guri, Korea (Drs Pyo and Oh); the Department of Pathology, Pusan National University Hospital College of Medicine, Pusan, Korea (DrW.Y. Park); the Department of Hospital Pathology, Incheon St Mary's Hospital, College of Medicine, Catholic University of Korea, Incheon, Korea (Dr E.S. Park); the Department of Pathology, Kyung Hee University Medical Center, Kyung Hee University School of Medicine, Seoul, Korea (DrJ.Y. Sung); the Department of Pathology, Konkuk University School of Medicine, Seoul, Korea (Dr S.E. Lee); the Department of Pathology, Dankook University College of Medicine, Cheonan, Korea (Dr W. Lee); the Department of Pathology, Dongguk University College of Medicine, Gyeonju, Korea (Dr J.I. Lee); the Department of Pathology, Inje University Busan Paik Hospital, Pusan, Korea (Dr Jung); the Department of Pathology, Asan Medical Center, University of Ulsan College of Medicine, Seoul, Korea (Drs Y.M. Cho and Huh); the Department of Pathology, Gachon University Gil Medical Center, Incheon, Korea (Dr H.Y. Cho); the Department of Pathology, Konyang University School of Medicine, Daejeon, Korea (Dr Cha); the Department of Pathology, Seoul National University Bundang Hospital, Seoul National University College of Medicine, Seoul, Korea (Dr Choe); the Department of Hospital Pathology, Seoul St Mary's Hospital, The Catholic University of Korea, Seoul, Korea (Dr Choi); and the Department of Pathology and Genomic Medicine, The Methodist Hospital and Weill Medical College of Cornell University, Houston, Texas (Dr Ro).
This study was supported by a grant from the 39th Annual Spring Meeting of the Korean Society of Pathologists.
The authors have no relevant financial interest in the products or companies described in this article.
Presented in part at the 105th Annual Meeting of the United States and Canadian Academy of Pathology; March 12-18, 2016; Boston, Massachusetts.
Reprints: Jae Y. Ro, MD, PhD, Department of Pathology and Genomic Medicine, Houston Methodist Hospital and Weill Medical College of Cornell University, 6565 Fannin St, Houston, TX 77030 (email: firstname.lastname@example.org).
Caption: Figure 1. Examples of SDHB-deficient paragangliomas. A, Hematoxylin-eosin-stained slide. B, Atypical mitosis (arrow). C, Lymphovascular invasion. D, Lymphovascular invasion highlighted by immunohistochemical staining (original magnification 3200 [A]; hematoxylin-eosin, original magnifications3400 [B] and3100 [C]; D2-40, original magnification3100 [D]).
Caption: Figure 2. A, Immunohistochemical staining for SDHA in a paraganglioma with intact expression of SDHB. Staining is cytoplasmic and granular. B, Immunohistochemical staining for SDHB in a paraganglioma with loss of SDHB expression. Sustentacular cells show positive staining as an internal positive control (original magnifications X100 [A] and X200 [B]).
Table 1. Primer Sequences and Polymerase Chain Reaction Conditions for Detection of SDHB, SDHC, and SDHD Primer Names Forward Primer Sequence Reverse Primer Sequence SDHB EX1 GGTCCTCAGTGGATGTAGGC CTTGCCCTATGCTTCCTCAG SDHB EX2 TGGATATTGAATGCCTGCCT GCCTTCCAAGGATGTGAAAA SDHB EX3 ACATCCAGGTGTCTCCGATT CCCACGTACCTTCTCTGCAT SDHB EX4 TGGATATTGAATGCCTGCCT ACAAATCCTGCCCTGAAAAA SDHB EX5 CAGTGTCCAAGAAATGGGGT TGCCAGTTCCTCTCCAGAAT SDHB EX6 GCACTGACCCCAAAGGTAAC ATGGCAATGAAGGAAACCAG SDHB EX7 CCAGAGCTTTGAGTTGAGCC TGGTCCCTTTCCTTCTCAAA SDHB EX8 AACCCCTATGGTTTTGAGGG TGCTGTATTCATGGAAAACCAA SDHC EX1 GTCACATGACACCCCCAAC CCCAGGCACAGGATAAACAG SDHC EX2 TCTATCCCTTCACCCCTAAAAA CGCCTGTAGTCCCAGCTACT SDHC EX3 TTTTCAAACGGTCTGGTTTT TGGTTGAGTAAAAGTGAGGGAAG SDHC EX4 GAGCTGAGATCATGCCATTG TTCAAAGGAGGCGGAGACTA SDHC EX5 CAGGGGTCCCAGTTTTATGT AGTCTCCCCACTCCCTTCAC SDHC EX6 CGCTTTTCTCTAGAATCATGCTG TTCCCAGGCTGGAGATAAGA SDHD EX1 TTCACCCAGCATTTCCTCTT CTGGAGGCTACGCTAAGCAC SDHD EX2 TCAGTCCTGTTAAAGGAGAGGTTC CCCCCTACAGGTAGGAAGTC SDHD EX3 TTTGGGTTACTGTGTG GCATA CACAGCAAACAAACTGAGCA SDHD EX4 TTTTTGCAGCCAAGTTATCTGT CATGACAAAGCAG AGGCAA Primer Names Ta, [degrees]C SDHB EX1 58 SDHB EX2 58 SDHB EX3 58 SDHB EX4 58 SDHB EX5 58 SDHB EX6 58 SDHB EX7 58 SDHB EX8 58 SDHC EX1 60 SDHC EX2 60 SDHC EX3 62 SDHC EX4 62 SDHC EX5 58 SDHC EX6 58 SDHD EX1 58 SDHD EX2 58 SDHD EX3 58 SDHD EX4 58 Abbreviation: Ta, annealing temperature. Table 2. Clinicopathologic Characteristics of Paragangliomas of Bladder (a) Total Cohort SDHB Intact Characteristics (N = 52) (n = 43) Sex, No. (%) Female 25 (48) 23 (53) Male 27 (52) 20 (47) Age at diagnosis, y Mean 56 59 Range 22-79 34-79 Isolated bladder PGL, No. (%) Yes 52 (100) 43 (100) No 0 (0) 0 (0) Tumor characteristics Size, cm, mean 2.4 1.9c Mitoses, mean per 10 HPF 0.3 0.1 Necrosis, No. (%) 5 (10) 4 (9) Lymphovascular invasion, No. (%) 6 (12) 3 (7) Proper muscle invasion, No. (%) 41 (79) 32 (74) Metastatic disease, No. (%) No 49 (94) 42 (98) Yes 3 (6) 1 (2) Systemic metastases 2 (4) 1 (2) Nodal metastases 2 (4) 1 (2) Family history of PGL No 52 (100) 43 (100) Yes 0 (0) 0 (0) SDH mutational analysis, No. (%)g SDHB mutation SDHB wild type SDHB Deficient Total Without With Characteristics (n = 9) Metastases Metastases (n = 7) (n = 2) Sex, No. (%) Female 2 (22) 2 (29) 0 (0) Male 7 (78) 5 (71) 2 (100) Age at diagnosis, y Mean 43 45 36.5 Range 22-65 26-65 22-51 Isolated bladder PGL, No. (%) Yes 9 (100) 7 (100) 2 (100) No 0 (0) 0 (0) 0 (0) Tumor characteristics Size, cm, mean 4.5 3.7 7.3 Mitoses, mean per 10 HPF 2.6 1.1 4 Necrosis, No. (%) 1 (11) 0 (0) 1 (50) Lymphovascular invasion, No. (%) 3 (33) 2 (29) 1 (50) Proper muscle invasion, No. (%) 9 (100) 7 (100) 2 (100) Metastatic disease, No. (%) No 7 (78) 7 (100) 0 (0) Yes 2 (22) 0 (0) 2 (100) Systemic metastases 1 (11) 0 (0) 1 (100) Nodal metastases 1 (11) 0 (0) 1 (100) Family history of PGL No 9 (100) 7 (100) 2 (100) Yes 0 (0) 0 (0) 0 (0) SDH mutational analysis, No. (%)g SDHB mutation 6 (100) 4 (100) 2 (100) SDHB wild type 0 (0) 0 (0) 0 (0) Characteristics P (b) Sex, No. (%) .09 (c) Female Male Age at diagnosis, y .002 (d) Mean Range Isolated bladder PGL, No. (%) Yes No Tumor characteristics Size, cm, mean <.001 (e) Mitoses, mean per 10 HPF .002 (f) Necrosis, No. (%) .87 (c) Lymphovascular invasion, No. (%) .02 (c) Proper muscle invasion, No. (%) .09 (c) Metastatic disease, No. (%) .02 (c) No Yes Systemic metastases Nodal metastases Family history of PGL No Yes SDH mutational analysis, No. (%)g SDHB mutation SDHB wild type Abbreviations: HPF, high-power field; PGL, paraganglioma. (a) Tumor size was available for 41 of 43 SDHB-intact cases. (b) SDHB intact (n 1/4 43) versus SDHB deficient (n 1/4 9). (c) Chi-square test. (d) By t test. (e) Mann-Whitney. (f) Fisher exact test. (g) SDH mutational analysis was successfully performed in 6 of 9 SDHB-deficient cases. Table 3. Comparison of Benign and Malignant Paragangliomas of Bladder (a) Characteristics Total Cohort Benign PG (N = 52) (n = 49) Sex, No. (%) Female 25 (48) 25 (51) Male 27 (52) 24 (49) Age at diagnosis, y Mean 56 57 Range 22-79 26-79 Isolated bladder PG, No. (%) Yes 52 (100) 49 (100) No 0 (0) 0 (0) Tumor characteristics Size, cm, mean 2.4 2.1 Mitoses, mean per 10 HPF 0.3 0.2 Necrosis, No. (%) 5 (10) 4 (8) Lymphovascular invasion, No. (%) 6 (12) 4 (8) Proper muscle invasion, No. (%) 41 (79) 38 (78) Family history of PG, No. (%) No 52 (100) 49 (100) Yes 0 (0) 0 (0) SDHB IHC, No. (%) Intact 43 (83) 42 (86) Deficient 9 (17.3) 7 (14) SDHB mutation, No. (%) Mutation 6 4 Not done 46 45 Characteristics Malignant PG P (n = 3) Sex, No. (%) Female 0 (0) .24 (b) Male 3 (100) Age at diagnosis, y .11 (c) Mean 41 Range 22-51 Isolated bladder PG, No. (%) Yes 3 (100) No 0 (0) Tumor characteristics Size, cm, mean 6.2 .002 (c) Mitoses, mean per 10 HPF 1 .14 (c) Necrosis, No. (%) 1 (33) .27 (b) Lymphovascular invasion, No. (%) 2 (67) .03 (b) Proper muscle invasion, No. (%) 3 (100) >.99 (b) Family history of PG, No. (%) No 3 (100) Yes 0 (0) SDHB IHC, No. (%) .07 (b) Intact 1 (33) Deficient 2 (67) SDHB mutation, No. (%) .003 (b) Mutation 2 Not done 1 Abbreviations: HPF, high-power field; IHC, immunohistochemistry; PG, paraganglioma. (a) Tumor size was available for 50 cases (47 benign, 3 malignant). (b) Fisher exact test. (c) Mann-Whitney. Table 4. Features of 6 SDHB-Mutated Paragangliomas of Bladder Case Age Size, Atypical Mitotic Follow-up, No. y/Sex cm Mitosis Count, HPF LVI mo 1 56/M 4.6 -- 0 -- 21 2 32/F 4.5 -- 2 + 24 3 22/M 8 -- 3 + 111 4 51/M 6.5 -- 0 -- 161 5 35 M 3.5 + 4 -- 72 6 65/F 3 -- 0 -- 120 Case No. SDHB Mutational Status Metastasis 1 4 missense mutations: exon 3, c.233 A.G -- (p.K78R) and c.241 A>G (p.N81D); and exon 8, c.776 C>T (p.P259L) and c.818 A>G (p.Y273S) 2 2 missense mutations: exon 6, c.571 T>A -- (p.C191S) and c.578 G>A (p.S193N) 3 1 missense mutation: exon 3, c.221 T>C + (p.M71T) 4 1 silent mutation: exon 1, c.171C>T (p.T57T) + 5 1 silent mutation: exon 3, c.225T>C (p.A75A) -- 6 1 intronic mutation: exon 1, c.72+24G>A;and -- 1 silent mutation: exon 3, c.225T>C (p.A75A) Abbreviations: HPF, high-power field; LVI, lymphovascular invasion; -, not present; +, present.
|Printer friendly Cite/link Email Feedback|
|Title Annotation:||Original Articles|
|Author:||Park, Sanghui; Kang, So Young; Kwon, Ghee Young; Kwon, Ji Eun; Kim, Sang Kyum; Kim, Ji Yeon; Kim, Ch|
|Publication:||Archives of Pathology & Laboratory Medicine|
|Date:||May 1, 2017|
|Previous Article:||Facebook Discussion Groups Provide a Robust Worldwide Platform for Free Pathology Education.|
|Next Article:||AlphaGo, Deep Learning, and the Future of the Human Microscopist.|