The GNAS gene, located on chromosome 20, encodes, among other products, the α-subunit of the stimulatory G protein (Gsα) (49). This protein is widely expressed and mediates the action of several hormones, neurotransmitters, and paracrine factors through the generation of the second messenger cAMP (49). Under physiological conditions, Gsα remains bound to GDP in a heterotrimeric complex with the β and γ subunits (49). Activation of G protein–coupled receptors induces the exchange of GDP for GTP and promotes the dissociation of Gsα from the Gβγ complex (49). Gsα then activates AC, which converts ATP into cAMP and triggers the release of the catalytic subunits of PKA, resulting in diverse intracellular responses (9, 13). The intrinsic GTPase activity of Gsα hydrolyzes GTP back to GDP, restoring the inactive state and ensuring that signaling remains transient and tightly regulated (49). Studies have shown that constitutive activation of Gsα enhances AC activity and aberrant cAMP synthesis, establishing a direct mechanism for autonomous steroidogenesis (43, 46).

MAS is the classic disorder associated with activating PV in GNAS (50). It results from postzygotic somatic mosaicism, in which mutated and normal cells coexist within different tissues, typically involving hotspot variants at Arg201 or Gln227 of GNAS gene (50). Clinically, MAS is characterized by the triad of café-au-lait skin pigmentation, polyostotic fibrous dysplasia, and precocious puberty, but it may also include cortisol excess, thyroid hyperfunction, and acromegaly, depending on the tissues affected (50, 51). In cases with adrenal involvement, autonomous cortisol secretion has been reported together with a distinctive histological pattern of bimorphic cortical hyperplasia, sustained by constitutive Gsα signaling in clusters of mutated cells (52). Because it arises from a PV acquired during postzygotic embryogenesis, MAS may present with CS already in newborns and children (29, 43). This condition is frequently associated with arterial hypertension and, in severe cases, may require bilateral adrenalectomy for hypercortisolism control (29, 51).

Beyond the syndromic context, activating GNAS PV have also been identified in acquired forms of ACTH-independent CS (33). In a cohort of five patients with CS due to primary bilateral macronodular adrenal hyperplasia (PBMAH), three carried somatic variants in this gene, including two p.R201H and one p.R201S variants in adrenal nodules, reinforcing the role of these alterations in adrenal tumorigenesis (33). None of these patients exhibited sufficient clinical features to support a diagnosis of MAS, representing the first reported cases of AIMAH caused by activating PV in the G protein. Another clinical case supporting the involvement of GNAS in the development of CS outside the syndromic setting described a patient with subclinical CS and bilateral functioning autonomous cortisol-secreting adrenocortical tumors, in whom a somatic p.R201H variant was identified in association with a paradoxical cortisol response to dexamethasone, indicating dysregulation of the cAMP-PKA pathway (53).

More recently, a novel somatic variant p.K58Q has been characterized in a cortisol-producing adrenocortical adenoma (32). Functional studies demonstrated that this alteration leads to increased basal cAMP levels, enhanced pCREB phosphorylation, and CRE-luciferase activation, in addition to influencing cell viability and apoptosis (32). These findings indicate a gain-of-function effect similar to Arg201 PV and broaden the mutational spectrum of GNAS in adrenal CS, underscoring that variants outside classical hotspots can also drive autonomous steroidogenesis through constitutive activation of the cAMP–PKA pathway (32).

Among the regulatory subunits of PKA, RIα is distinguished by its almost ubiquitous distribution and by constituting the main component of type I PKA, the isoform most sensitive to cAMP and predominant in mediating this pathway in human cells (54, 55). The PRKAR1A gene, located on chromosome 17q22-24, encodes RIα and plays an essential role in maintaining the catalytic activity of the enzyme under cAMP control, ensuring that phosphorylation of target proteins occurs in a transient manner and adjusted to physiological demands (54). Alterations affecting this gene compromise this regulation, leading to constitutive activation of PKA and autonomous cortisol production, with direct repercussions on the development of endocrine hypertension (56–58).

CNC represents the main clinical condition associated with germline inactivating variants in PRKAR1A, showing autosomal dominant inheritance and high penetrance (14, 56). It is characterized by cutaneous pigmentation in lentigines, cardiac and cutaneous myxomas, and multiple endocrine and non-endocrine tumors (57, 59). Among the endocrine manifestations, PPNAD is the most common, present in about 25% of affected individuals, and can occur either in isolation or in association with CNC, being characterized by autonomous cortisol secretion and the development of ACTH-independent CS (56, 57, 59). Germline-inactivating variants of PRKAR1A are found in approximately 45 to 65% of patients with CNC, but this proportion can reach up to 80% in cases where PPNAD leads to CS, highlighting the central role of the gene in adrenal pathogenesis (60). Most of these alterations introduce premature termination codons, generally through nonsense or frameshift events, ultimately leading to loss of RIα expression (61). Furthermore, similar variants have also been described in sporadic or isolated forms of PPNAD, indicating that loss of RIα function constitutes a pathological mechanism both in familial disease and in non-syndromic cases (58, 60).

In addition to the regulatory subunits, the catalytic ones also play a decisive role in the cAMP–PKA pathway, with the α isoform, encoded by the PRKACA gene, being the most relevant in the context of adrenal steroidogenesis (62). Located on chromosome 19p13.1, this gene spans approximately 26 kb organized into 10 exons and encodes a 351–amino acid protein, considered the main catalytic subunit of PKA and ubiquitously expressed in human tissues (37, 62). Under physiological conditions, Cα remains associated with the regulatory subunits, being released only after cAMP binding, which ensures that its kinase activity, responsible for phosphorylating target proteins on serine or threonine residues, occurs in a controlled and transient manner (37, 62). Alterations that disrupt this balance can lead to dissociation independent of cAMP and constitutive activation of Cα, promoting autonomous cortisol production and proliferative stimulus, thus constituting a central mechanism for the development of cortisol-producing adrenocortical tumors and endocrine hypertension (37, 38, 63, 64).

The main genetic alteration identified in PRKACA is the recurrent somatic PV p.L206R, described in approximately 20 to 70% of cortisol-producing adrenocortical adenomas, depending on the cohort (37, 62). This substitution is located in the p+1 loop region of the protein and compromises the interaction with the regulatory subunit RIα, preventing the stable formation of the holoenzyme and resulting in constitutive PKA activity (37, 62, 64). Functional studies in HEK293T cells demonstrated that this PV increases phosphorylation of downstream targets such as CREB and ATF1 by about 4 fold, thereby sustaining continuous steroidogenesis and autonomous cortisol secretion (37, 38).

Beyond the classical p.L206R, germline amplification of PRKACA has also been reported, leading to overexpression of the catalytic subunit and the development of PBMAH (65, 66). Additionally, studies in cortisol-producing adrenocortical adenomas demonstrated that PKA activation resulting from these PV directly correlates with overexpression of the steroidogenic acute regulatory protein (StAR), a key mediator of mitochondrial cholesterol transport and the rate-limiting step in steroidogenesis (31). A genotype–phenotype correlation has also been observed, with patients carrying PRKACA PV presenting with more severe hypercortisolism, earlier age at diagnosis, and generally smaller tumors compared with those without PV in this gene (65). These findings establish PRKACA as the most frequently altered gene in cortisol-producing adrenocortical adenomas, representing a central pathological mechanism in the development of ACTH-independent CS and its cardiovascular manifestations, including hypertension.

The PDEs, already recognized as essential modulators of the cAMP–PKA pathway, also hold clinical relevance in the pathophysiology of adrenocortical tumors. Among the isoforms expressed in the adrenal cortex, PDE11A and PDE8B are noteworthy for their inactivating variants, which have been associated with micronodular hyperplasia exhibiting autonomous cortisol secretion (25, 26). Although less frequent than PRKAR1A or PRKACA PV, these alterations demonstrate that impaired degradation of cAMP results in constitutive activation of PKA, promoting steroidogenic autonomy and contributing to the spectrum of ACTH-independent CS, often accompanied by cardiovascular manifestations, including endocrine hypertension.

PDE11A, located on chromosome 2q31.2, encodes a dual-specificity enzyme capable of degrading both cAMP and cGMP, with the PDE11A4 isoform being the predominant form expressed in adrenal tissue (26). In a 2006 study, germline variants in this gene were described in individuals with PPNAD and isolated micronodular adrenocortical hyperplasia associated with CS (26). These alterations resulted in loss of heterozygosity in the 2q31–2q35 region, accompanied by reduced PDE11A4 expression and increased CREB phosphorylation, reflecting inefficient cAMP degradation and consequent sustained activation of the PKA pathway, thus establishing a direct mechanism of steroidogenic dysregulation. Subsequently, in an expanded cohort of patients with AIMAH, missense variants in PDE11A were identified in 28% of cases, compared with 7.2% of controls, confirming its association with genetic predisposition (21). Functional assays based on these findings demonstrated that substitutions such as D609N and M878V reduce enzymatic activity, leading to intracellular cAMP accumulation, enhanced CREB-dependent transcription, and an augmented forskolin-stimulated response in adrenocortical cells, consolidating the link between loss of enzymatic function and PKA hyperactivation.

More recently, a study involving patients with PBMAH demonstrated that deleterious PDE11A variants occur at similar frequencies among individuals with or without ARMC5 PV, the main tumor suppressor gene implicated in this condition, being associated with a milder phenotype, characterized by lower cortisol levels and fewer adrenal nodules (67). These findings indicate that PDE11A functions as a phenotypic modifier and low-penetrance allele, rather than an isolated cause of disease.

PDE8B, in turn, located on chromosome 5q13.3, encodes a high-affinity, cAMP-specific phosphodiesterase that is abundantly expressed in the zona fasciculata of the adrenal cortex, where it regulates steroidogenesis (68). In 2008, Horvath and colleagues described a germline inactivating PV (c.914A>C, p.H305P) in a child with micronodular adrenocortical hyperplasia and CS, inherited from an asymptomatic parent with mild adrenal hyperplasia, suggesting an autosomal dominant inheritance with low penetrance (25). Functional assays in HEK293 cells transfected with this variant demonstrated intracellular cAMP accumulation and reduced enzymatic activity, indicating loss of function. Subsequently, missense and splicing variants in PDE8B were identified in PPNAD and cortisol-producing adrenocortical adenomas, all associated with increased cAMP levels and PKA hyperactivation (68, 69). In a transcriptomic analysis of unilateral adenomas, PDE8B showed the strongest positive correlation with cortisol secretion, reinforcing its role as a critical regulator of cAMP homeostasis and a modulator of PKA-dependent adrenocortical tumorigenesis (68).