Keywords
pheochromocytoma, paraganglioma, risk factor, prognostic prediction
pheochromocytoma, paraganglioma, risk factor, prognostic prediction
Phaeochromocytomas and paragangliomas (PPGLs) are catecholamine-secreting tumours of neural crest origin, which arise in the adrenal medulla and extra-adrenal paraganglia, respectively1. Despite advances in the field, risk factors of PPGL malignancy remain limited and few options are available for patients with metastatic PPGL2.
Over the past two decades, progress in the molecular genetics of PPGLs has provided key insights into the primary driver event underlying their pathogenesis. PPGLs are genetically heterogeneous tumours caused by mutations in over 20 distinct genes3. A pathogenic mutation, either germline or somatic, can be identified in two-thirds of the tumours largely in a mutually exclusive manner4. These various aberrations have led to a classification of PPGLs into distinct biological subgroups, as illustrated in Table 1. However, these subgroups have poor prognostic discriminatory power.
Most PPGLs have a benign course and can be successfully treated by surgery. Approximately 15% of PPGLs are malignant and not curable by current therapies2. In fact, malignancy status in PPGLs is predicated on the detection of metastases at distant sites unrelated to the paraganglial tissue. Therefore, by definition, malignant PPGLs are diagnosed late. A second category of PPGLs, though not fulfilling these metastatic criteria, comprises tumours with aggressive clinical behaviour that involves fast growth, multiple recurrences, or both, some of which are inoperable, thus leading to poorly controlled disease. As a group, ‘aggressive’ and metastatic PPGLs represent a substantial number of patients for whom therapeutic options remain scarce. Currently, predictive factors for malignant PPGL and for ‘aggressive’, non-metastatic PPGL are limited and imprecise5. An intrinsic limitation of the current definition of poor outcome is the inability to distinguish truly ‘benign’ PPGLs from those that eventually will progress to malignant or aggressive disease in the absence of long-term clinical follow-up. This shortcoming reduces the specificity of predictive models. Therefore, there is a clear need for markers that allow precise and early recognition of tumours with negative clinical outcomes.
We posit that despite the indisputable value of molecular discoveries to the genetic diagnosis of PPGLs, this progress has yet to be translated into broad, reliable prognostic predictions. Novel clinical trials targeting specific molecular aberrations found in PPGLs are beginning to emerge and are expected to expand the therapeutic options available for patients with metastatic disease2. The prospect of more effective treatment of advanced malignant PPGL is encouraging, yet the identification of predictive markers with the potential to impact patient care remains the most pressing challenge in PPGL management.
PPGLs are infrequent neuroendocrine tumours that arise from cells of the autonomic lineage, sympathetic or parasympathetic, derived from the neural crest1,6. Sympathetic lineage cells, also known as chromaffin cells, give rise to the more frequent form of tumour presentation (that is, PPGLs that have the potential to secrete catecholamines), whereas parasympathetic-derived paragangliomas are histologically related but do not usually have catecholamine-secreting ability. PPGLs have the highest rate of heritability of all human tumours; approximately 40% are caused by an inherited autosomal dominant mutation in one of more than a dozen susceptibility genes1 (Table 1). Thus, the identification of an inherited pathogenic PPGL mutation has immediate clinical impact, as it can lead to early diagnosis of at-risk individuals in families through genetic testing. In addition, since hereditary PPGLs often present as part of multi-tumour syndromes, mutation detection can also lead to planned surveillance and early diagnosis of co-occurring cancers in probands and in their mutation-carrier relatives1.
PPGLs are often benign and curable by surgery. However, these tumours can be clinically aggressive with multiple recurrences or can spread to non-chromaffin derived, metastatic sites, including liver, lung, bone, and lymph node2,7. Both hereditary and sporadic PPGLs can progress to metastatic disease. The overall survival rate of patients with metastatic PPGL is 60% in five years, although there is extensive heterogeneity2,8. It has been recognised that a substantial number of patients with untreated malignant PPGL—almost half by some accounts—can remain stable without disease progression for months after the initial diagnosis8,9. However, currently, it is not possible to anticipate, prior to treatment, the growth and spread rate of individual metastatic PPGLs. The ability to distinguish more indolent tumours from fast-growing, highly symptomatic cases would have obvious impact on clinical decision-making. For example, patients with slow-growing, oligo/asymptomatic tumours could potentially benefit from active surveillance before initiating any therapy, as recently advocated for low-risk cancers as a way to reduce negative consequences of overtreatment10.
On the other end of the spectrum, PPGLs that do not metastasize but are highly recurrent, either locally or at new paraganglial sites, can pose a therapeutic challenge from the surgical perspective, either because of tumour location or multiple prior interventions that limit surgical success or because of patients’ catecholamine-related symptoms11. These ‘aggressive non-metastatic’ tumours share some of the risk factors associated with metastatic PPGLs5. Recognition of precise risk factors for recurrence could provide the opportunity for more tailored therapeutic planning and follow-up.
Distinguishing benign PPGLs from tumours with metastatic potential is not possible on histologic grounds. Conventional approaches to estimate proliferative potential in cancers, such as the well-known Ki-67 index, measured by immunohistochemistry, has proven to be a reliable indicator of proliferating paraganglioma/phaeochromocytoma cells and for predicting tumour progression, when positive12. However, the Ki-67 labelling index is often low or negative in PPGLs, limiting its use as a single prognostic indicator13. In view of this limitation, a scoring system involving multiple histological features, known as PASS (phaeochromocytoma of the adrenal gland scaled score), was developed in an attempt to identify phaeochromocytomas (but not paragangliomas) with metastatic potential14. Subsequent studies applying the PASS revealed significant variation in the interpretation of the different components, limiting its clinical utility15. A second scoring system, GAPP (grading system for PPGL), which also included paragangliomas, was subsequently developed16. Acknowledging the limitations of histomorphology alone in predicting PPGL biologic behaviour, GAPP includes, in addition to morphological parameters, the type of catecholamine secreted by the tumours. This feature was meant to function as a surrogate for tumour location, based on the long-established observation that norepinephrine (noradrenaline)-secreting tumours, which occur predominantly in paragangliomas, are more frequently malignant than those that secrete epinephrine (adrenaline), which are located almost exclusively in the adrenal gland (phaeochromocytomas)17. However, despite this important addition, GAPP still has limitations18. Catecholamine metabolites, metanephrines, are more faithful markers of tumour secretion than direct measurement of short-lived catecholamines. In addition, other relevant features which have been independently validated as prognostic markers, further discussed below, are not included in the score. Moreover, GAPP excludes paediatric patients, a group in whom the proportion of metastatic cases is twofold to threefold higher when compared with adults19. It is possible that future iterations of this system will incorporate some of these parameters.
Non-histological predictors of PPGL malignancy, tumour size and location, have been recognised20 (Table 2). Tumours larger than 5 cm are more likely to spread, either because of an intrinsic accelerated growth rate or as a result of delayed diagnosis due to fewer symptoms (for example, as in the case of oligo- or non-secreting, less-differentiated tumours). Paragangliomas metastasize more often than phaeochromocytomas, regardless of the primary tumour size; as much as 20% of paragangliomas smaller than 5 cm are accompanied by metastases2,8. These two parameters have been incorporated into a new staging classification of PPGLs, based on the TNM (tumour, lymph node, and metastasis), which was recently developed by the American Joint Committee on Cancer. This classification was developed to help improve treatment planning of metastatic PPGLs. In its initial version, the TNM classification did not include molecular data2.
Category | Parameter | Strength | Validation statusa |
---|---|---|---|
Molecular | Germline SDHB mutation | H | Y |
Anatomical/Histological | Primary tumour size (>5 cm) | H | Y |
Anatomical/Histological | Primary tumour location | H | Y |
Anatomical/Histological | Proliferation index (Ki-67) | M (H when elevated) | N |
Anatomical/Histological | Vascular invasion | L | N |
Biochemical | Norepinephrine (noradrenaline) secretion | M | N |
Biochemical | 3-methoxytyramine levels (plasma) | M/H | ? |
Anatomical/Histological | c-Erb2 expression by immunohistochemistry | M/H | ? |
Molecular | Hypermethylation subtype | Interdependent with SDHB mutation? | ? |
Molecular | Pseudohypoxia subtype | Interdependent with SDHB mutation? | ? |
Molecular | Somatic ATRX mutation | ? | ? |
Molecular | Other genetic mutations (MAX, FH) | ? | ? |
Molecular | Somatic MAML3 fusion | ? | ? |
Molecular | WNT signalling subtype | Interdependent with MAML3 fusion? | ? |
Molecular | RDBP hypermethylation | ? | ? |
Molecular | Somatic SETD2 mutation | ? | ? |
Plasma levels of 3-methoxytyramine, a sensitive indicator of tumour dopamine secretion, which can reflect poor differentiation of the catecholamine synthetic process by metastatic PPGLs, have shown initial promise as an additional biomarker, especially when combined with tumour size and location to predict the likelihood of malignancy in PPGLs20. Importantly, high plasma 3-methoxytyramine was also detected in non-SDHB-related metastatic PPGLs, suggesting that this marker may have broader value, regardless of the genetic background of tumours20. Prospective studies should provide further validation of the predictive power of 3-methoxytyramine in various clinical contexts.
The best-known genetic predictor of malignancy is the presence of a germline mutation of the succinate dehydrogenase subunit B gene, SDHB21 (Table 2). SDH is a multi-unit enzymatic complex that is a component of both the Krebs cycle and the mitochondrial electron transport chain. Most patients with a germline SDHB mutation have extra-adrenal disease and approximately 50% of these patients progress to metastatic disease22. In addition, patients with SDHB mutant malignant PPGLs have shorter median overall survival than non-SDHB mutant metastatic PPGLs (42 versus 244 months after the diagnosis of the first metastasis, respectively)21. Mutations in other SDH component genes—SDHA, SDHC, SDHD, and SDHAF2—also lead to paragangliomas or phaeochromocytomas or both; however, malignancy is rarely associated with these tumours. SDH mutations cause a metabolic imbalance that leads to a DNA and histone hypermethylation phenotype; genes targeted by aberrant methylation are thought to be required for tumour development in these models23. However, why mutations in SDHB, but not in the other SDH genes, specifically confer increased risk of malignancy is not known. Notably, despite its unquestionable role as an independent risk factor for malignancy, two-thirds of metastatic PPGLs do not have SDHB mutations, implying the existence of other markers of poor prognosis24. Malignancy has also been reported in other genetic models of PPGLs but at much lower rates than those of SDHB mutant cases25,26.
A recent integrated analysis of PPGLs as part of The Cancer Genome Atlas (TCGA) using genomic, mRNA, and microRNA expression, methylation profiling, and protein expression arrays identified new pathogenic lesions in PPGLs4. This study delineated four PPGL subtypes and identified nine outcome markers, as defined broadly by the time until the occurrence of distant metastases, local recurrence, or positive regional lymph nodes. Those included SDHB mutation, inclusion in the hypermethylation subtype, and inclusion in the pseudohypoxia subtype; the latter two are the groups that contain SDHB mutant tumours. Detection of a larger number of somatic mutations was also associated with worse outcome, although other studies did not observe such a correlation27,28. Importantly, novel molecular markers were found: MAML3 (mastermind-like protein 3) fusions, SETD2 (SET domain containing 2) or ATRX somatic mutations, and WNT-related expression subtype, which comprise the tumours with MAML3 fusion tumours4. Interestingly, almost all tumours carrying this fusion were phaeochromocytomas, in contrast with the predominant paraganglioma location of SDHB mutants, and represented a biological group distinct from the latter. Analysis including only the classic definition of malignant PPGLs (distant metastases) did not reveal any additional outcome markers. Future studies to validate these promising new candidate risk markers will be required.
Genes targeted by methylation that may associate with metastatic tumours, including RBDP, have also been identified and will need to be independently verified29.
A recent study used multivariate logistic regression analysis and decision curve analysis of training and validation PPGL sets to develop a nomogram based on the combination of clinical (tumour size, location, and vascular invasion) and non-clinical (SDHB status and c-Erb2 expression) markers30. The refined nomogram achieved good predictive power to distinguish PPGLs with metastatic potential. Independent verification of these findings in other cohorts is warranted. Importantly, this model lends itself to the addition of other recently identified markers and thus can prove adaptable to new discoveries.
Fundamental to the successful identification of risk factors for malignant/aggressive PPGLs is a better understanding of their biological basis. For example, it is not clear whether a given PPGL is intrinsically aggressive at its onset or whether malignant transformation occurs later during tumour progression. The fact that an initiating driver mutation, SDHB, confers an independent risk of malignancy argues in favour of the former. However, as not all patients with an SDHB mutation develop metastatic disease, even within the same family (that is, carriers of the same mutation), other risk factors, either inherited through different alleles or acquired, might exist21. Furthermore, metastatic PPGLs in children are more frequent than in adults independently of the heredity status, suggesting that tumours that manifest in childhood may be intrinsically more aggressive regardless of their genetic background19. Additionally, the association between malignant PPGLs with structural abnormalities that might indicate genomic instability remains controversial4,27,28. These unresolved questions expose our limited knowledge of the underlying biology of a malignant PPGL and represent an enduring obstacle to our ability to recognise these tumours at an early stage.
In conclusion, existing prognostic markers cannot fully predict PPGL behaviour. Recently found, and eventually future, candidate markers will require further verification and independent validation before they can be incorporated into outcome prediction algorithms. Prospective large multicentre studies that collect uniform, detailed long-term clinical follow-up data from heterogeneous population groups of patients and multidimensional large-scale data (comprehensive genetic, genomic, epigenetic, metabolic, immune, and proteomic) will be required to fill this important gap in our understanding of PPGLs and how that might impact patient care.
GAPP, grading system for phaeochromocytoma and paraganglioma; MAML3, mastermind-like protein 3; PASS, phaeochromocytoma of the adrenal gland scaled score; PPGL, phaeochromocytoma and paraganglioma; RBDP, negative elongation factor complex member E; SDHB, succinate dehydrogenase subunit B; TNM, tumour, lymph node, and metastasis.
PLD is a recipient of CPRIT RP140473 and NIH GM114102 awards.
The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
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Competing Interests: No competing interests were disclosed.
Competing Interests: No competing interests were disclosed.
Competing Interests: No competing interests were disclosed.
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