The RET (rearranged during transfection) proto-oncogene located on chromosomal region 10q11.2 consists of 21 exons, and it encodes a receptor tyrosine kinase (1). Germline gain-of-function mutations of the RET proto-oncogene cause multiple endocrine neoplasia type 2 (MEN2), an autosomal dominantly inherited disease with an approximate prevalence of 2.5 per 100.000 in the general population (1). MEN2 has three subtypes: i) MEN2A, characterized by medullary thyroid carcinoma (MTC), pheochromocytoma (Pheo) and primary hyperparathyroidism; ii) MEN2B, which presents with the most aggressive MTC, pheochromocytoma, neuromas and marfanoid phenotype; and iii) familial MTC (FMTC), the mildest form of MTC. Several important genotype–phenotype associations have been determined; the most commonly affected codon, 634 (nearly 85% of MEN2A cases), frequently associates with Pheo and hyperparathyroidism, whereas mutations of codons 609, 611, 618, and 620 (accounting for 10–15% of MEN2A) usually associate with the milder form of MEN2 (1–3). However, the phenotypic heterogeneity observed even in members of the same family suggests that other factors, for example genetic modifiers, may influence the clinical manifestation of the disease (4–7).

Hereditary paraganglioma/pheochromocytoma (PGL) syndrome is caused by the germline heterozygous mutations of the SDHx genes (SDHB, SDHC, SDHD, encoding subunits B, C and D, respectively) (8–10) and the newly identified SDH5 gene (11) and TMEM127. SDHx genes encode subunits of the mitochondrial complex II (succinate dehydrogenase, SDH), an enzyme involved in oxidative phosphorylation and intracellular oxygen sensing and signaling (12).

Both MTC and paraganglioma/pheochromocytoma arise from neural crest-derived precursor cells. Accumulation of amino-acid coding polymorphisms (S163P in SDHB, G12S, and H50R in SDHD) has been found among patients with MTC, especially in those with familial tumors (13). In addition, these rare genetic variants have been identified in patients with Cowden-like syndrome (14) and the H50R polymorphism has been described in six members of a family with non-RET-associated C-cell hyperplasia and hypercalcitoninemia (15). These previous data may suggest a possible connection between SDHx polymorphisms and familial MTC and/or C-cell hyperplasia/hypercalcitoninemia; however, the occurrence of the SDHx variants among patients harboring germline RET mutations has not been previously examined. Therefore, the aim of the present study was to investigate whether polymorphisms of the SDHx genes could influence clinical manifestations of the disease in a cohort of subjects harboring RET mutations. In addition, we wanted to determine whether the prevalence of SDHx polymorphisms in patients with sporadic MTC, sporadic Pheo and healthy subjects might be different from that found in RET mutation carriers.

Written informed consent was obtained from all patients and family members who participated in the study. Patients underwent a complete clinical examination, laboratory testing, including serum basal calcitonin measurement [hCalcitonin IRMA kit (Diagnostic Systems Laboratories, Inc., Budapest, Hungary), reference range: male <15 pg/ml, female <10 pg/ml until December 2007; and Liaison (Diasorin SPA, Stillwater, MN, USA), reference value: male <18.9 pg/ml and female <6 pg/ml after January 2008], plasma parathyroid hormone (Elecsys; Roche Diagnostics, Basel, Switzerland), urinary catecholamine metabolites (high pressure liquid chromatography with electrochemical detection), and imaging studies, including cervical ultrasonography, thoracal and abdominal computed tomography (CT), and whole-body metaiodobenzylguanidine scintigraphy (MIBG).

Restriction fragment length polymorphism (RFLP) analysis for identification the G12S polymorphism of the SDHD gene

The nucleotide change of G to A, which corresponds to the G12S polymorphism, results in the preservation of the BanI restriction cleavage site. Therefore, digestion with the BanI restriction enzyme (New England BioLabs Inc., Ipswich, MA, USA) for 90 min at 37°C was performed after polymerase chain reaction (PCR) amplification of exon 1 of the SDHD gene for genotyping of RET mutation carriers, sporadic MTC patients, and 100 controls (Figure 1). Samples from patients with positive results were examined by direct DNA sequencing. The results obtained with both methods were the same in all cases.

Figure 1.

(A) Gel electrophoresis of PCR fragments after digestion with BanI for identification of the G12S polymorphism of the SDHD gene by RFLP (L = DNA ladder; C+ = positive control; heterozygote for G12S; C- = negative control; G12 normal, P1–P5 = patients. (B) Chromatograms of exon 1 of the SDHD gene showing the wild type and the heterozygote form of the G12S (GGT12AGT) polymorphism.

(0.01MB).

Eight of the 55 patients with MEN2A (15.5%) had the G12S variant, whereas it was absent in the MEN2B and FMTC groups. No patient with sporadic MTC and/or sporadic Pheo carried this variant. Among the 100 population-based, healthy control individuals, only one individual carried this variant (prevalence, 1%) (Table 1). No association between the G12S polymorphism of the SDHD gene and the incidence of Pheo or hyperparathyroidism in RET mutation carriers was observed, and the age of disease manifestation was similar in G12S carriers and in non-carriers (43±9 versus 40±3 years in probands and 29.6±19.3 versus 32.5±20.5 years in non-carriers). Among probands with RET mutations, carriers of the G12S had higher serum calcitonin levels compared with those who did not carry the SDHD G12S variant (6,864±11,111 versus 1,250±932 pg/ml), but the difference was not significant. Among family members with RET mutations, serum calcitonin levels were similar in G12S carriers and non-carriers 436±876 versus 393±556 pg/ml) (Table 2).

The phenotypic heterogeneity seen in families with different RET mutations, the variation of clinical course within families with the same RET mutation, and the results from RET transgenic mouse models suggest a potential role of genetic components in phenotype modulation (2),(19). Polymorphisms of the RET gene have been analyzed as such genetic modifiers, but the results from these studies are conflicting. Robledo et al. showed that two RET variants (G691S and S904S) may modify the age of onset of MTC in family members (5); and Tamanaha et al. reported that two intronic polymorphisms of RET may modify the phenotype in a large family with G533C RET mutation (7), while Baumgartner-Parzer found that the L769L and the IVS14-24 may act as modifiers in some forms of hereditary and sporadic MTC (20). However, Lesueur et al. were unable to replicate this association in a large cohort of 384 members of MEN2 families from four different European populations. This latter study showed that of the several polymorphisms of genes encoding the RET protein, its co-receptors and ligands, only the synonymous polymorphism A432A of the RET gene associated weakly with tumor spectra in patients with MEN2A (6). MEN2-related MTC RET variants have been analyzed as genetic susceptibility factors for the development of sporadic MTC: polymorphisms located in coding regions of RET, G691S, L769L, S836S, and S904S have been shown to be over-represented in patients with sporadic MTC (21–23) compared with the general population, but others were unable to confirm these associations (24),(25).

Germline mutations of SDHx genes encoding subunits of the mitochondrial complex II represent a genetic susceptibility for Pheo/PGL. These tumors are derived from cells of the neural crest, similar to MTC. RET mutations also cause Pheo, again suggesting a link between the genetic background of Pheo and MTC. Therefore, it has been assumed that mutations of these genes may be involved in the pathogenesis of MTC. Lima et al. reported a family with C-cell hyperplasia, a pre-cancerous state of MTC, who were proved to have the H50R variant of the SDHD gene (15). Montani et al. demonstrated an increased frequency of amino acid-coding SDHx polymorphisms in patients with sporadic and familial MTC (13). In addition, a systemic evaluation of genetic variants of the SDHx genes among patients with sporadic MTC showed a significant association between the H50R variant and sporadic MTC in Spanish patients, although this observation was absent in an English cohort (26). Variants of the SDHx genes have been implicated in the pathogenesis of various endocrine and non-endocrine tumors, such as Merkel cell carcinoma, carcinoid, papillary thyroid cancer, and renal cell cancer found in patients with Cowden-like syndrome (14).

In the present study, we found that the G12S variant was significantly over-represented among RET mutation carriers compared with sporadic MTC, sporadic Pheo, or control individuals. In our study, this variant occurred mainly in patients with MEN2A, while Montani et al. detected G12S in a patient with MEN2B harboring the M918T mutation of the RET gene (13). Interestingly, the prevalence of alterations of the SDHx genes in patients with RET mutations was similar in our study and the study of Montani et al. (13).

The prevalence of the G12S in the general population is between 2.5% and 5% (27) according to the Leiden Open Variation Database (http://chromium.liacs.nl) (28), which is somewhat higher than in our control population (1%). This difference may be due to differences in the selection criteria applied for controls. Our control group were evaluated for endocrine dysfunction; none of them had signs or symptoms characteristic of thyroid cancer or Pheo. By contrast, population-based controls, frequently anonymous blood donors, have never been tested for these rare conditions. Alternatively, the difference between the studies in prevalence of G12S can also be attributed to the ethnic background of the different populations tested. Our patients and controls were of Hungarian origin, representing an independent entity among Caucasian populations. More importantly, in our study, the high incidence of the G12S variant among RET carriers, especially in those with the MEN2A phenotype, raised the possibility that this variant may have a role in the phenotypic modulation of the disease. However, we were unable to detect significant differences in the clinical presentation between G12S carriers and non-carriers. Whether this failure was a result of the relatively small size of our patient cohorts remains to be further investigated. Interestingly, Waldmann et al. reported an increased prevalence of intronic SDHB polymorphisms among patients with malignant Pheo compared with patients with benign tumors (29).

In conclusion, we found a significantly higher prevalence of the G12S variant of the SDHD gene among germline RET mutation carriers presenting with MEN2A compared with the control group. The high prevalence of the G12S variant in these patients supports its genetic modifier role, but this proposal remains to be established.