Novel succinate dehydrogenase subunit B (SDHB) mutations in familial phaeochromocytomas and paragangliomas,but an absence of somatic SDHB mutations in sporadic phaeochromocytomas

Phaeochromocytomas arising in adrenal or extra-adrenal sites and paragangliomas of the head and neck, in particular of the carotid bodies, occur sporadically and also in a familial setting. In addition to mutations in RET and VHL in familial disease, germline mutations in SDHD and SDHB genes that encode subunits of mitochondrial complex II have also been associated with the development of familial phaeochromocytomas. To further investigate the role of SDHD and SDHB in the development of these tumours we determined the occurrence of germline SDHD and SDHB mutations in four patients with a family history of phaeochromocytoma with associated head and neck paraganglioma, one patient with a family history of phaeochromocytoma only and two patients with apparently sporadic extra-adrenal phaeochromocytoma, one of whom had early onset disease. Secondly, we investigated whether somatic SDHB mutations correlated with loss of heterozygosity at 1p36 in a subgroup of 11 sporadic and three MEN 2-associated RET-mutation-positive phaeochromocytomas. Novel SDHB mutations were identified in the probands from four families and two apparently sporadic cases (six of seven probands studied), including two missense mutations, a single nonsense and frameshift mutation, as well as two splice site mutations, one of which was shown to have partial penetrance resulting in 'leaky' splicing. Further, five intronic polymorphisms in SDHB were found. No SDHD mutations were identified. In addition, no somatic SDHB mutations were found in the remaining allele of the 11 sporadic adrenal phaeochromocytomas with allelic loss at 1p36 or the three MEN 2-associated RET-mutation-positive phaeochromocytomas. Therefore, we conclude that SDHB has a major role in the pathogenesis of familial phaeochromocytomas, but the possible role of SDHB in sporadic tumours showing allelic loss at 1p36 has yet to be ascertained.     

Active succinate dehydrogenase (SDH) and lack of SDHD mutations in sporadic paragangliomas

BACKGROUND: Paragangliomas are benign, slow-growing tumours of the head and neck region. The candidate gene for familial and some sporadic paragangliomas, SDHD (succinate dehydrogenase, subunit D), has been mapped to the PGL1 locus in 11q23.3. MATERIALS AND METHODS: Normal and tumour DNA of 17 patients with sporadic paragangliomas were analysed by sequencing (SDHD, SDHB and SDHC genes), fluorescence in situ hybridisation (FISH). In addition, loss of heterozygosity (LOH) and succinate dehydrogenase (SDH) enzyme activity assays were performed. RESULTS AND CONCLUSION: Only two patients from our collective showed SDH gene mutations, one in SDHD and one in SDHB, respectively. Moreover, SDH activity detected in 5/8 patients confirmed the fact that SDH inactivation is not a major event in sporadic paragangliomas. LOH and FISH analysis demonstrated a frequent loss of regions within chromosome 11, indicating that additional genes in 11q may play a role in tumour genesis of sporadic paragangliomas.     

A novel germline SDHB mutation in a gastrointestinal stromal tumor patient without bona fide features of the Carney–Stratakis dyad

Gastrointestinal stromal tumors (GISTs) are the most common mesenchyme neoplasms of the gastrointestinal tract. Gain-of-function somatic mutations of the KIT or PDGFRA genes represent the most prevalent molecular alterations in GISTs. In Carney-Stratakis dyad, patients portray germline mutations of the succinate dehydrogenase subunits B (SDHB), C (SDHC) and D (SDHD) and develop multifocal GISTs and multicentric paragangliomas (PGLs). We herein report a novel germline SDHB mutation (c.T282A--Ile44Asn) occurring in a 26 years-old patient diagnosed with a spindle cell intermediate risk GIST that did not present KIT/PDGFRA/BRAF gene mutations. Further analyses revealed loss of the wild-type SDHB allele and complete loss of SDHB expression in the tumor tissue. After genetic screening of other family members, we detected in the patient's mother a SDHB mutation without any clinical/laboratorial evidence of GIST or PGL. Altogether, our findings (germline SDHB mutation with absence of PGL in the index case and of GIST and/or PGL in his mother) raise the possibility that this familiar setting corresponds to an incomplete phenotype of the Carney-Stratakis dyad.     

Mutations in the SDHB gene are associated with extra-adrenal and/or malignant phaeochromocytomas

Germ-line mutations in the genes encoding succinate dehydrogenase complex subunits B (SDHB) and D (SDHD) have been reported in familial paragangliomas and apparently sporadic phaeochromocytomas (ASP), but the genotype-phenotype relationships of these mutations are unknown. Eighty-four patients (all but 2 followed up for 8.8 +/- 5.7 years) with ASP (57 with adrenal tumors, 27 with extra-adrenal, multiple, malignant, or recurrent tumors) were screened for the major susceptibility genes for phaeochromocytoma (RET, VHL, SDHD, and SDHB). Thirty-three tumors were available for molecular analysis, enzyme assays, and immunohistochemistry. No (0%) RET and 2 (2.4%) VHL mutations were detected. Only two coding single nucleotide polymorphisms in the SDHD gene (G12S and H50R) were found in 6 patients (7%). Conversely, six deleterious mutations in the SDHB gene were identified in 8 patients (9.5%). Ectopic site and recurrence or malignancy were strongly associated with SDHB mutations (7 of 8, 87%, versus 20 of 76, 26%; P = 0.001). Somatic DNA analysis indicated a loss of heterozygosity at chromosome 1p36 (SDHB locus) in 16 of 33 cases (48%). A loss of heterozygosity at the SDHB locus was found in all tumors with SDHB mutation, and assays of respiratory chain enzymes showed a complete loss of complex II catalytic activity. The vascular architecture of tumors with SDHB mutations displayed features typical of malignancy. These data strongly suggest that SDHB gene is a tumor suppressor gene and that the identification of germ-line mutations in SDHB gene in patients with ASPs should be considered as a high-risk factor for malignancy or recurrence.     

Common genetic mutations in the start codon of the SDH subunit D gene among Chinese families with familial head and neck paragangliomas

Head and neck paragangliomas (HNPGLs) are rare, and frequently associated with germline mutations of the succinate dehydrogenase (SDH) genes, especially for familial cases. The purpose of the study is to explore SDH mutations in Chinese families with familial HNPGLs in Taiwan. Four unrelated families with familial HNPGLs were screened for germline mutations in the SDHB, SDHC and SDHD genes by direct sequencing. One hundred healthy subjects without a diagnosis or family history of HNPGLs were screened as normal controls. Immunohistochemistry with SDHB antibody was performed for a carotid body tumor. Two allele variants were identified, including p.Met1Val (c.1A>G) in the SDHD gene in one family and p.Met1Ile (c.3G>C) in the SDHD gene in the other three families. Both variants are considered pathogenic because of the absence of these variants in 100 normal controls, 100% evolutionary conservation of the p.Met1 residue, co-segregation of the variants with the phenotype of HNPGL in pedigrees, and predicted abolishment of the translation start site. The tumor cells obtained from one proband harboring c.3G>C mis-sense mutation were weak diffuse staining in the cytoplasm of tumors cells. This study demonstrates that two mis-sense mutations at the start codon of the SDHD gene, including p.Met1Val (c.1A>G) and p.Met1Ile (c.3G>C), might be mutation hotspots in Chinese patients with familial HNPGLs.     

Allele-specific methylation analysis on upstream promoter region of H19 by methylation-specific PCR with confronting two-pair primers

H19 and IGF2 genes are imprinted genes and expressed differently depending on whether they are carried by a chromosome of maternal or paternal origin; H19 is expressed only from the maternal allele and IGF2 only from the paternally inherited allele. The upstream promoter region of H19 has the imprinting-control region (ICR) or CTCF binding sites, where the methylation status of this region is critical to the regulation of imprinting of the H19/IGF2 locus located in chromosome 11p15. There are various reports on imprinting disorders in this region. In colorectal cancer aberrant biallelic methylation of CTCF binding site has been reported, and aberrant hypomethylation of this region in bladder cancer. Thus, certain human neoplasms have either hyper- or hypo-methylation in the ICR. Hence it is still difficult to analyze allele-specific methylation disorder of the region, or differentially methylated regions (DMR), locate upstream of H19. Here we report a new method, which could distinguish paternal epigenetic or maternal epigenetic pattern by a single PCR assay, to combine methylation-specific PCR and PCR with confronting two-pair primers (MSP-CTPP). Using this method, we investigated the region close to H19 ICR in 161 colorectal cancer and 65 gastric cancer cases.     

Absence of somatic SDHD mutations in sporadic neuroendocrine tumors and detection of two germline variants in paraganglioma patients

Allelic loss of the long arm of chromosome 11 is frequent in neuroendocrine tumors (NET) of different organs. However, the MEN1 gene on 11q13 is mutated only in a subset of NET and allelic losses on 11q frequently extend to the telomere. In this genetic region lies the tumor suppressor gene SDHD which is associated with hereditary paragangliomas (PGL1). We sought to determine whether SDHD plays a role in the development of sporadic NET. By mutation and deletion analysis of SDHD we were unable to detect any SDHD mutation in 45 NET of the lung, gastrointestinal tract, pancreas or parathyroid. However, we found allelic deletions in 20 to 50% of all tumors but parathyroid adenomas. Furthermore, we found heterozygous germline variants in 2/8 paragangliomas. A first case of variant c.149 A>G (H50R) was found in a patient with an extra-adrenal pheochromocytoma, the other variant c.34 G>A (G12S) in a patient with a paratracheal paraganglioma, C-cell hyperplasia of the thyroid and hyperplasia of ACTH-producing cells of the pituitary gland. Both variants were absent in 93 controls. Our results demonstrate that somatic SDHD mutations are rare in sporadic NET. However, LOH alone could lead to a complete loss of function since SDHD is an imprinted gene. Furthermore, we describe two germline variants possibly causing hereditary paragangliomas.     

Mitochondrial tumour suppressors: a genetic and biochemical update

Since the discovery 5 years ago that the D-subunit of succinate dehydrogenase (SDHD) can behave as a classic tumour suppressor, other nuclear-encoded mitochondrial proteins (SDHB, SDHC and fumarate hydratase) have been implicated in tumour susceptibility. Mutations in these proteins are principally involved in familial predisposition to benign tumours, but the spectrum of inherited lesions is increasingly recognized to include malignant tumours, such as malignant phaeochromocytomas and renal cell carcinomas. Here we review recent advances in the field of mitochondrial tumour suppressors, the biochemical pathway that links mitochondrial dysfunction with tumorigenesis, and potential therapeutic approaches to these malignancies.     

颈动脉体瘤相关致病基因与其临床病理特征关系的初步研究

目的：初步了解与颈动脉体瘤（carotid body tumor,CBT）发病相关的琥珀酸脱氢酶（succinate dehydro-genase,SDH）亚单位B、C、D基因突变位点、突变率及其与临床病理特征之间的关系。方法：选取2006年4月至2011年1月间天津医科大学附属肿瘤医院收治具有完整临床资料的24例CBT患者作为研究对象,统计其年龄、性别、肿瘤大小、单双侧、良恶性等临床特征。同时提取患者肿瘤组织/外周血细胞基因组DNA,PCR法扩增SDHB、SDHC、SDHD基因各外显子后测定DNA序列,并将测序结果与临床资料进行配比分析。结果：24例CBT患者中良性21例,其中4例（19.1%）患者携带SDH基因突变,分别为SDHB 1例（4.8%）,SDHD 3例（14.3%）;SDHB基因为发生于第六外显子的错义突变S198R;SDHD基因突变中,2例为发生于第二外显子的无义突变R38X,1例为发生于第三外显子的错义突变H104P;3例恶性病例中,2例（66.7%）患者携带SDH基因突变,均为SDHB第一外显子的同义突变A6A。结论：国人CBT患者易携带SDHB、SDHD基因突变,其中SDHD基因突变主要与良性CBT发病相关;SDHB基因突变与恶性CBT发生有一定的相关性。     

Germline SDHB mutations and familial renal cell carcinoma

Familial renal cell carcinoma (RCC) is a heterogeneous disorder that is most commonly caused by germline mutations in the VHL, MET, and FLCN genes or by constitutional chromosome 3 translocations. However, for many patients with familial RCC, the genetic basis of the disease is undefined. We investigated whether germline mutations in fumarate hydratase (FH) or succinate dehydrogenase subunit genes (SDHB, SDHC, SDHD) were associated with RCC susceptibility in 68 patients with no clinical evidence of an RCC susceptibility syndrome. No mutations in FH, SDHC, or SDHD were identified in probands, but 3 of the 68 (4.4%) probands had a germline SDHB mutation. Patients with a germline SDHB mutation presented with familial RCC (n = 1) or bilateral RCC (n = 2) and no personal or family history of pheochromocytoma or head and neck paraganglioma. Age at diagnosis of RCC in SDHB mutation carriers ranged from 24 to 73 years. These findings 1) demonstrate that patients with suspected inherited RCC should be examined for germline SDHB mutations, 2) suggest that all identified SDHB mutation carriers should be offered surveillance for RCC, and 3) provide a further link between familial RCC and activation of hypoxic-gene response pathways.     

Reduced succinate dehydrogenase B expression is associated with growth and de-differentiation of colorectal cancer cells

Succinate dehydrogenases (SDH), including SDHA, SDHB, SDHC, and SDHD, form the respiratory complex II in the mitochondria and play an important role in cell growth and homeostasis. In order to evaluate the expression and functional significance of SDH in colorectal cancer, the expression of four SDH subunits was analyzed, and SDHB protein was found to be significantly lower in colorectal cancer tissues. In vitro experiments including cell growth assay, colony formation assay, cell cycle analysis, and nude mouse xenograft of SDHB-transfected colorectal cancer cell line SW620 were performed. Notably, reduced SDHB expression in tumor tissues was associated with tumor de-differentiation, and restoration of SDHB could inhibit the growth of cancer cells both in vitro and in vivo. Furthermore, cDNA microarray of SDHB-transfected cell line showed that most of the differentially expressed genes are related to cell cycle control and cell proliferation. Thus, we conclude that SDHB expression is significantly decreased in human colorectal cancer tissues, and reconstitution of SDHB in colorectal cancer may be a potential therapeutic approach to inhibit aggressiveness of colorectal cancer.     

Relaxation of IGF2 imprinting in Wilms tumours associated with specific changes in IGF2 methylation

Relaxation of IGF2 imprinting occurs in Wilms tumours and many other cancers, but the mechanism of loss of imprinting (LOI) remains unknown. To investigate the role of altered DNA methylation in LOI, we examined the pattern of methylation of the human insulin-IGF2 region in Wilms tumours and the normal kidney. The analysis included regions homologous to three 'differentially methylated regions' of the mouse Igf2 gene (dmrs 0, 1 and 2). In tumours displaying normal IGF2 imprinting, and in the normal kidney, maternal allele-specific DNA methylation was identified spanning exons 2 and 3. This region is homologous to dmr 0, a site of maternal-specific differential methylation in the mouse. In Wilms tumours with relaxed imprinting or 11p15.5 LOH this region was unmethylated. No other differential methylation was identified. In particular, two sites of paternal methylation in the mouse (dmrs 1 and 2), and all three imprinted IGF2 promoters were not methylated in the kidney or in Wilms tumours. We postulate that LOI in Wilms tumours is associated with loss of maternal allele-specific methylation from a region located upstream of the imprinted IGF2 promoters. This region may contain cis acting sequences that coordinately influence imprinting.     

Equivalent Parental Distribution of Frequently Lost Alleles and Biallelic Expression of the H19 Gene in Human Testicular Germ Cell Tumors

Epigenetic alterations such as genomic imprinting might play an important role in human tumorigenesis, in addition to specific genetic alterations. To clarify the role of genetic and/or epigenetic alterations in the tumorigenesis of testicular germ cell tumors (GCTs), we analyzed 40 primary and 3 metastatic testicular GCTs with regard to specific chromosomal losses and their parental origin. A high incidence of loss of heterozygosity (LOH) was demonstrated on chromosomes 1p, 3p, 11p, and 17p: 9/19 (47%), 18/39 (46%), 13/40 (33%) and 20/36 (56%), respectively. However, there was no correlation between the frequency of LOH on any chromosome and clinicopathological features. Regarding the parental origin of the lost allele at these chromosomes, preferential loss was not demonstrated in this study. To clarify the imprinting status in GCTs, we analyzed the allele-specific expression of the H19 gene, which is paternally imprinted on chromosome 11p. All of 11 tumors without LOH at this locus showed biallelic expression of H19. Based on previous work demonstrating the biallelic expression of H19 in primordial germ cells and spermatogonia in the mouse germ line, these results suggest that the biallelic expression of H19 in testicular GCTs reflects the characteristics of the original germ cells in which the imprinting marking has been erased and not established, rather than loss of imprinting during tumorigenesis. It is also possible that a failure to re-establish the imprinting might be an initial event which leads to testicular GCTs.     

Molecular Cytogenetic Characterization in Four Pediatric Pheochromocytomas and Paragangliomas

Pheochromocytomas (PCCs) are rare tumors among children and adolescents and therefore are not genetically well characterized. The most frequently observed chromosomal changes in PCC are losses of 1p, 3q and/or 3p, 6q, 17p, 11q, 22q, and gains of 9q and 17q. Aberrations involving chromosome 11 are more common in malignant tumors. Unfortunately information about gene aberrations in childhood PCC’s is limited. We used comparative genomic hybridization (CGH) and array comparative genomic hybridization (aCGH) to screen for copy number changes in four children suffering from pheochromocytoma or paraganglioma. Patients were diagnosed at the age 13 or 14 years. Bilateral pheochromocytoma was associated with von Hippel-Lindau syndrome (VHL). Multiple paraganglioma was associated with a germline mutation in SDHB. We found very good concordance between the results of CGH and aCGH techniques. Losses were observed more frequently than gains. All cases had a loss of chromosome 11 or 11p. Other aberrations were loss of chromosome 3 and 11 in sporadic pheochromocytoma, and loss of 3p and 11p in pheochromocytoma, which carried the VHL mutation. The deletion of chromosome 1p and other changes were observed in paragangliomas. We conclude that both array CGH and CGH analysis identified similar chromosomal regions involved in tumorigenesis of pheochromocytoma and paragangliomas, but we found 3 discrepancies between the methods. We didn’t find any, of the proposed, molecular markers of malignancy in our benign cases and therefore we speculate that molecular cytogenetic examination may be helpful in separating benign and malignant forms in the future.     

A third Wilms' tumor locus on chromosome 16q.

Loss of heterozygosity studies have been used to identify chromosomal regions which are frequently deleted and thus indicate areas which may harbor tumor suppressor genes. As a result, both the WT1 gene located in chromosome 11p13 and an unidentified gene(s) within chromosome 11p15 have been implicated in Wilms' tumorigenesis. Cytogenetic and linkage studies suggest that additional non-chromosome 11 sites are involved in Wilms' tumor. Because these sites may also involve loss of heterozygosity, loci on 33 autosomal arms were screened for allele loss in a series of Wilms' tumors. We found that in addition to loss on chromosome 11p (11 of 25 informative tumors) there was significant loss on chromosome 16q (9 of 45 informative tumors), while the total frequency of allele loss excluding these loci was low (9 of 426 total informative loci). These data indicate that losses of both chromosome 11p and 16q alleles are nonrandom events and suggest that 16q is the location of a third tumor suppressor gene underlying Wilms' tumorigenesis. The parental origin of the lost chromosome 16q allele was determined in eight sporadic tumors. Alleles of paternal and of maternal origin were each lost in four sporadic tumors indicating that, unlike chromosome 11p, alleles of either parental origin are lost on 16q.