About 30% up to 35% of pheochromocytomas and paragangliomas (PPGL) have an accountable germline mutation in 1 of more than 20 susceptibility genes described while 35% up to 40% are affected by somatic mutations.1 Genetic testing allows allocations to 1 of the 3 main molecular clusters: cluster 1 mutations (Krebs cycle/VHL/EPAS1) are associated with pseudohypoxic pathway, vascular endothelial growth factor hyperexpression and increased vascularization2; they tend to be extra-adrenal with a noradrenergic biochemical profile, sustained hypertension and significant recurrence/metastatic risk1; cluster 2 tumors are mostly adrenal and are associated with abnormal kinase signaling pathways (PI3Kinase/AKT, RAS/RAF/ERK, mTOR), adrenergic intermittent secretion with sporadic symptoms and a less aggressive behavior.2 Wnt signaling – related cluster 3 mutations are poorly described and seem to have an aggressive behavior.1 TMEM-127 gene mutation is rarely reported (<2% of patients) and it is transmitted in a dominant autosomal inheritance pattern with no syndromic features.1–3 TMEM-127 is a tumor suppressor gene involved in kinase signaling and it has been included within cluster 2 tumors.1 When mutated, it triggers kinase overactivation with sustained cell growth, survival, proliferation, and angiogenesis. TMEM-127-related tumors (TMEM-127-RT) are described as almost exclusively adrenal (96%), frequently unilateral (62%) and with an essentially non-metastatic behavior (>95% of cases).1,4 The median age at diagnosis is older than 40 years, resembling sporadic pheochromocytomas and inconsistent with most familial PPGL, conditioning a challenging clinical distinction.1,5 This article was previously presented as an oral communication at Congresso Português de Endocrinologia, on March 3rd, 2024.

The authors report a 30-year pregnant woman with a hypertension medical history diagnosed at a young age. During obstetric follow-up, the second-trimester ultrasound documented an incidental right adrenal mass with poorly demarcated dimensions according to this imaging modality. On the physical examination, the patient had no virilization signs, Cushing’ clinical stigmata or other associated comorbidities. The lesion was then appropriately characterized by abdominal magnetic resonance imaging (MRI) to avoid radiation exposure during pregnancy and was described as “cystic and solid 14cm×12cm×12cm right adrenal mass, resembling a pheochromocytoma”. Endocrine test of adrenal incidentaloma revealed elevated fractionated catecholamines and metanephrines (UFCM) in 24-h urine with an adrenergic predominance confirming initial suspicion of pheochromocytoma (Table 1). Optimal medical therapy with combined alpha and beta blockade (phenoxybenzamine plus labetalol) was initiated prior to surgery and maintained until labor with satisfactory blood pressure levels and heart rate control. Afterwards, a sequential surgical strategy was adopted: the patient first underwent an elective C-section on week 36 of her pregnancy with no postoperative complications; the surgery was followed by tumoral staging with thoracoabdominopelvic computed tomography (CT) that excluded metastatic disease; afterwards, the patient underwent successfully right adrenalectomy and was discharged from the hospital clinically stable. Pathology report confirmed the diagnosis of pheochromocytoma. Three months later, biochemical testing with UFCM and postoperative abdominal imaging was suggestive of total tumor removal. The patient maintained endocrine annual follow-up with UFCM levels and remained biochemically stable for 10 years. After this, the patient started experiencing occasional palpitations suggestive of catecholamines hypersecretion and the UFCM confirmed the presence of biochemical disease relapse (Table 2). Abdominopelvic CT (APCT) revealed a 16mm adrenal nodule in the left contralateral adrenal gland with 32 Hounsfield Units (HU). Functional imaging was conducted and both metaiodobenzylguanidine (MIBG) scintigraphy and single-photon emission computed tomography (SPECT) demonstrated localized hyperfixation in the left adrenal gland. The patient underwent left adrenalectomy with no postoperative complications. Pathology report suggested pheochromocytoma diagnosis with no invasion of other structures, Ki-67 index <5% with positive immunohistochemical staining for chromogranin and synaptophysin. In the 3-month postoperative test, disease persistence was documented (Table 2). The patient repeated APCT that revealed no traces of metastasis; however nuclear medicine imaging with 68Ga-DOTANOC PET/CT (Fig. 1) and MIBG detected metastatic disease in the right kidney posterior region, hepatic foci and peritoneal carcinomatosis. The patient underwent biochemical, anatomic, and functional imaging exams throughout an 8-month period that showed stable metastatic disease. Attending to the complex nature of this case, it was discussed with a multidisciplinary team of a reference cancer center and clinical follow-up was determined. In case of disease progression, the patient would be proposed to peptide receptor radionuclide therapy using somatostatin receptors. The patient underwent genetic testing and a germline pathogenic variant (c.410-2A>C) in TMEM-127 gene was documented. Her only daughter was also tested when she was 14 years old and presented the same genetic mutation. She is currently asymptomatic and awaits biochemical evaluation.

Figure 1.

Functional imaging modality with evidence of metastatic disease. A 68Ga-DOTANOC PET/CT was performed after biochemical persistence disease documentation following bilateral adrenalectomy. Radiotracer uptake was consistent with multiple metastatic foci expression in the following locations: right kidney posterior region, liver medial region, and anterior region of the right 12th rib; several peritoneal lesions were found on the right paravertebral and right preaortic perihepatic region and lateral liver surface (segment V/VI), along with multiple hepatic hilum foci, which may be adenopathies or peritoneal lesions.

Although the treatment of TMEM-127-RT is surgical whenever possible, it is not necessarily curative1 since these tumors might be recurrent or multifocal. If surgical approach is unfeasible, systemic therapy may include chemotherapy, radionuclide therapy, tyrosine kinase inhibitors and immunotherapy; genetically driven cluster-specific therapy is currently under investigation as a promising emerging therapy; however it is not currently well established.1,3 Current management recommendations released by the of the European Society of Hypertension Working Group on Endocrine Hypertension for metastatic PPGL suggest chemotherapy as a first-line therapy for rapidly progressing PPGL (<6 months) and radionuclide therapy (131I-metaiodobenzylguanidine [131I-MIBG] or peptide receptor radionuclide therapy [PRRT] depending on tumor uptake and location) as first-line therapy for slow-to-moderately progressing PPGL (>6 months).3 Other therapies include tyrosine kinase inhibitors (sunitinib, cabozantinib, lenvatinib), somatostatin analogues or other specific targeted signaling pathway inhibitors.1,3 Systemic therapy is rarely necessary in cluster 2 tumors due to the low metastatic risk involved.

Disease penetrance associated with TMEM-127 gene mutation is unknown due to its rare occurrence (<2% of patients) with conflicting data: although some studies have suggested a low penetrance level, recent evidence suggests the high penetrance capabilities of PPGL.1,4

Inconsistent data have been reported on PPGL biochemical profile: a study reported no predominant catecholamine secretion6 and others suggested an adrenaline secretion predominance.7–9 There are no specific recommendations on the at-risk patients’ ideal age to offer genetic testing or clinical follow-up of asymptomatic mutation carriers. Toledo et al. suggested genetic screening at age 22 years and annual clinical follow-up with biochemical testing in mutation carriers.4

2017 WHO classification abandoned the terms “benign” and “malignant” for PPGL characterization regarding the absence of a histological classification predictable of metastatic behavior and instead endorsed the term “metastatic” as a more suitable term. All pheochromocytomas have metastatic potential but it has rarely been described with this mutation.2,3 Currently, there are no predictive biomarkers of metastatic behavior, nevertheless there are some risk features: tumor size ≥5cm, multifocality, extra-adrenal location, specific mutations (SDHx, fumarate hydratase, malate dehydrogenase 2, solute carrier family 25 Member 11, hypoxia inducible factor 2α), noradrenergic/dopaminergic phenotype, high Ki-67 index or previously detectable metastatic lesions.1–3 This aggressive phenotype was unpredictable at diagnosis since none of these prognostic features were present at the time.

PPGL clinical characterization and treatment has grown exponentially in the last years and cluster-specific management is being addressed. Recent published guidelines released in 2021 by the Endocrine Society advocate for a personalized management according to cluster groups. In patients with PPGL history, periodic clinical follow-up of the removed adrenal surgical site and contralateral gland is recommended due to its multicentric/bilaterality occurrence.4 More recent evidence suggests annual biochemical evaluation and abdominal/pelvic MRI once every 5 years in TMEM-127-RT (by analogy to RET- and NF1-mutation, both cluster 2 mutations).1

This case reveals an unpredicted metastatic behavior in a tumor with slow-to-moderate progression related to TMEM-127 gene mutation. Although described as almost exclusively non-metastatic, some authors documented metastatic behavior or aggressive histological profile in other genetic variants.5,6,10,11 Nonetheless, Toledo et al. studied a six-generation family carrying this specific variant (c.410-2A>C) and no metastases were found.

The authors emphasize that all PPGL have potential metastatic behavior, even if they are categorized as low-risk metastatic cluster 2 tumors and exhibit an adrenergic profile (that should not promptly be interpreted as a benign course predictor). The genotype–phenotype correlation promotes tumor behavior prediction, nonetheless it should not be empirically interpreted since some of these genetic changes are still under characterization. Another distinct feature of this case was the early age at which diagnosis was established (30 years) compared with the older age often described in TMEM-127-RT (>40 years), which speaks for how sporadic these early cases really are. Particularly in the case of TMEM-127-RT, clinical follow-up of the removed adrenal surgical site and contralateral gland is needed throughout life due to its multicentric/bilaterality nature. Considering that PPGL are the most hereditary endocrine tumors, genetic testing is mandatory in all cases regardless of the characteristics of the patients and their families.

Nothing to declare.

None declared.