In 1993, the RET proto-oncogene (“rearranged during transfection”), located on chromosome 10q11, was cloned and characterized as encoding a transmembrane tyrosine kinase with a cysteine-rich extracellular receptor domain (Fig. 25.2) present on neuroendocrine cells of neural crest origin [30, 31]. RET spans 60 kb with 21 exons encoding a protein of approximately 1,100 amino acids [1]. Glial cell-derived neurotrophic factor and neurturin are two ligands for the RET receptor domain [32]. The ligands initiate homodimerization of RET protein molecules resulting in phosphorylation and activation of the tyrosine kinase domain, leading to downstream signal transduction [32]. RET is the only gene known to be associated with MEN2. Missense mutations in the RET gene were characterized in individuals with the MEN2 syndromes [30, 31, 33, 34] with a very restricted pattern of variations (Fig. 25.2). In patients with MEN2A or FMTC, nearly all the mutations in this gene are activating, gain-of-function missense mutations localized to exons 10, 11, and 13–15. Most commonly, heterozygous missense mutations are found in a cysteine-rich, extracellular domain adjacent to the transmembrane domain of the RET protein including six conserved cysteine residues in RET exon 10 (codons 609, 611, 618, and 620) and exon 11 (codons 630 and 634) (Table 25.1 and Fig. 25.2) [30, 31, 33]. Most of these mutations replace a cysteine with another amino acid that cannot form intramolecular disulfide bonds. The unpaired cysteine is then able to form a disulfide bond with another RET protein molecule producing constitutive dimerization and increased kinase activation of the aberrant RET protein [35, 36]. Missense mutations in codons 768 and 804, located in exons 13 and 14, respectively (Table 25.1), affect the intracellular portions of the RET protein next to the transmembrane domain (Fig. 25.2) [37, 38]. Nearly 95 % of all patients diagnosed with MEN2B have been characterized with a single missense mutation in codon 918 of RET exon 16, M918T, replacing a methionine residue with a threonine [33, 34]. Another 2–3 % of patients have an Ala833Phe mutation in exon 15. Both variants affect the intracellular tyrosine kinase catalytic domain (Fig. 25.2), altering substrate recognition, which leads to cellular transformation [35]. In each case, these common RET mutations produce a gain-of-function change for the aberrant RET protein. Online information about many other RET mutations is available from the Human Gene Mutation Database Cardiff (http://​www.​hgmd.​cf.​ac.​uk/​ac/​index.​php, accessed 10/2/2014), the Weizmann Institute of Science GeneCards (http://​www.​genecards.​org/​cgi-bin/​carddisp.​pl?​gene=​RET&​search=​RET, accessed 10/2/2014), and the ARUP Institute for Clinical and Experimental Pathology (http://​www.​arup.​utah.​edu/​database/​MEN2/​MEN2_​welcome.​php, accessed 10/2/2014).

Hirschsprung disease (HSCR), an absence of enteric ganglia in the colon, also is associated with somatic or germline RET mutations, either in codons 609, 618, or 620, or distributed throughout other regions of the RET gene [40, 41]. Some families have been described in which HSCR cosegregates with either MEN2A or FMTC [42]. RET mutations in patients with HSCR may produce either loss or gain of RET protein function and include frameshift and nonsense mutations. Papillary thyroid carcinoma is associated with somatic gene rearrangements of the RET gene [43].

In an autosomal dominant inherited disorder, an individual with a single RET allele mutation has (1) a high likelihood of developing MTC (approximately 95 % of carriers) and (2) a 50 % risk of transmitting this risk allele and the high likelihood of developing MTC to each offspring. Genetic testing for RET mutations is the accepted best practice for confirmation of the diagnosis of MEN2, predictive risk-assessment testing for family members, and prenatal diagnosis of MEN2. Approximately 25 % of all MTC occurs as part of MEN2. Early detection of a pathogenic RET mutation improves the prognosis for presymptomatic individuals by offering an opportunity for therapeutic intervention prior to advanced disease, metastasis, or both [44–46]. Reduced morbidity and mortality is achieved by increased clinical monitoring, prophylactic thyroidectomy (followed by thyroid hormone replacement therapy plus autotransplantation of the parathyroids), or both [1, 47]. This can be a very effective treatment to prevent disease metastasis. Resected thyroid tissue from children and adults with positive genetic findings demonstrates C cell hyperplasia or microscopic foci of malignancy in the absence of biochemical screening abnormalities or clinical symptoms [46]. Thus, genetic testing for RET mutations is a more sensitive and specific screening tool than either physiological testing or histopathologic examination of the thyroid for assessing familial cancer risk for MEN2 in these families [44–46].

The clinical significance of identifying a RET mutation is considerable, given that there is virtually 100 % penetrance of these mutations for MTC. But genetic findings alone cannot predict the age of disease onset; thus, continued surveillance for residual or recurrent MTC plus adrenal tumors is included in the follow-up care of MEN2 patients and asymptomatic carriers. About 50 % of MEN2 patients (both subtypes A and B) will develop pheochromocytoma, while 20–30 % of MEN2A patients develop parathyroid hyperplasia [1]. Patients with FMTC typically develop only MTC and none of the other clinical manifestations of MEN2A or MEN2B. Each subtype appears to be consistent within a family. Any RET mutation in codon 634 in exon 11 results in a higher incidence of pheochromocytomas and hyperparathyroidism. In particular, the C634R (Cys to Arg) mutation has been associated with a higher incidence of metastases at diagnosis; the allele is virtually absent in patients with FMTC [48]. Families with both MEN2A or FMTC and HRSC most frequently have germline RET mutations in codons 609, 618, or 620 in exon 10 [49]. Individuals within the same family who carry the same RET mutation may still display a variable phenotype indicating that additional modifier gene functions or environmental or epigenetic factors affect the expression of altered RET protein function and tumorigenesis. Concomitant mutations in genes coding for RET ligands or coreceptors are the most likely modifier molecules.

Genetic screening and mutation identification are currently recommended by 5 years of age for children who are at risk in MEN2A families. Children should be screened at birth if MEN2B has been diagnosed in close relatives, due to the earlier age of onset and aggressive clinical course of the MEN2B type [44, 45]. Patients with MEN2B should be treated as soon as the diagnosis is made. Some of the other advantages of DNA testing in MEN2 are that the test is relatively noninvasive and low risk, it is usually better tolerated by the patient than biochemical screening by metabolic challenge [47], genotype results are not subject to physiologic status, and serial genotype testing is not necessary. Individuals in MEN2 families who are not carriers of the familial RET mutation have the lower, general population risk for sporadic incidence of these endocrine neoplasias and do not require the same frequent monitoring for abnormal thyroid or adrenal function in the absence of clinical symptoms.