Longterm-Outcomes In Patients With Cushing’s Disease vs. Non-Functioning Pituitary Adenoma After Pituitary Surgery: An Active-Comparator Cohort Study

Posted on July 22, 2024 by MaryO

Abstract

Objective

There is increasing evidence that multisystem morbidity in patients with Cushing’s disease (CD) is only partially reversible following treatment. We investigated complications from multiple organs in hospitalized patients with CD compared to patients with non-functioning pituitary adenoma (NFPA) after pituitary surgery.

Design

Population-based retrospective cohort study using data from the Swiss Federal Statistical Office between January 2012 and December 2021.

Methods

Through 1:5 propensity score matching, we compared hospitalized patients undergoing pituitary surgery for CD or NFPA, addressing demographic differences. The primary composite endpoint included all-cause mortality, major adverse cardiac events (i.e., myocardial infarction, unstable angina, heart failure, cardiac arrest, ischemic stroke), hospitalization for psychiatric disorders, sepsis, severe thromboembolic events, and fractures in need of hospitalization. Secondary endpoints comprised individual components of the primary endpoint and surgical reintervention due to disease persistence or recurrence.

Results

After matching, 116 patients with CD (mean age 45.4 years [SD, 14.4], 75.0% female) and 396 with NFPA (47.3 years [14.3], 69.7% female) were included and followed for a median time of 50.0 months (IQR 23.5, 82.0) after pituitary surgery. CD presence was associated with a higher incidence rate of the primary endpoint (40.6 vs. 15.7 events per 1,000 person-years, HR 2.75; 95% CI, 1.54 to 4.90). CD patients also showed increased hospitalization rates for psychiatric disorders (HR 3.27; 95% CI, 1.59 to 6.71) and a trend for sepsis (HR 3.15; 95% CI, 0.95 to 10.40).

Conclusions

Even after pituitary surgery, CD patients faced a higher hazard of complications, especially psychiatric hospitalizations and sepsis.

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Evaluating the usefulness of plasma chromogranin A measurement in cyclic ACTH-dependent Cushing’s syndrome

Posted on July 19, 2024 by MaryO
Abstract

Cushing’s syndrome, a clinical condition characterized by hypercortisolemia, exhibits distinct clinical signs and is associated with cyclic cortisol secretion in some patients. The clinical presentation of cyclic Cushing’s syndrome can be ambiguous and its diagnosis is often challenging.

We experienced a 72-year-old woman with cyclic ACTH-dependent Cushing’s syndrome caused by a pulmonary carcinoid tumor. Diagnosis was challenging because of the extended trough periods, and the responsible lesion was initially unidentified. A subsequent follow-up computed tomography revealed a pulmonary lesion, and ectopic ACTH secretion from this lesion was confirmed by pulmonary artery sampling. Despite the short peak secretion period of ACTH (approximately one week), immunostaining of the surgically removed tumor confirmed ACTH positivity. Interestingly, stored plasma chromogranin A levels were elevated during both peak and trough periods.

The experience in evaluating this patient prompted us to investigate the potential use of plasma chromogranin A as a diagnostic marker of ACTH-dependent Cushing’s syndrome. A retrospective study was conducted to determine the efficacy of plasma chromogranin A in three patients with ectopic ACTH syndrome (EAS), including the present case, and six patients with Cushing’s disease (CD) who visited our hospital between 2018 and 2021. Notably, plasma chromogranin A levels were higher in patients with EAS than in those with CD. Additionally, a chromogranin A level in the present case during the trough phase was lower than that in the peak phase, and was similar to those in CD patients. The measurement of plasma chromogranin A levels could aid in differentiating EAS from CD.

Keywords: ACTH-dependent Cushing’s syndromeCyclicCarcinoidPulmonary arterial samplingChromogranin A

From https://www.jstage.jst.go.jp/article/endocrj/advpub/0/advpub_EJ24-0128/_article

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Spontaneous Cushing’s Disease Remission Induced by Pituitary Apoplexy

Posted on July 17, 2024 by MaryO

Abstract

Spontaneous remission of Cushing’s disease (CD) is uncommon and often attributed to pituitary tumor apoplexy. We present a case involving a 14-year-old female who exhibited clinical features of Cushing’s syndrome. Initial diagnostic tests indicated CD: elevated 24h urinary cortisol (235 µg/24h, n < 90 µg/24h), abnormal 1 mg dexamethasone overnight test (cortisol after 1 mg dex 3.4 µg/dL, n < 1.8 µg/dL), and elevated adrenocorticotropic hormone concentrations (83.5 pg/mL, n 10-60 pg/mL). A pituitary adenoma was suspected, so a nuclear MRI was performed, with findings suggestive of a pituitary microadenoma. The patient was referred for a transsphenoidal resection of the microadenoma. While waiting for surgery, the patient presented to the emergency department with a headache and clinical signs of meningism. A computed axial tomography of the central nervous system was performed, and no structural alterations were found. The symptoms subsided with analgesia. One month later, she presented again to the emergency department with clinical findings of acute adrenal insufficiency (cortisol level of 4.06 µg/dL), and she was noted to have spontaneous biochemical remission associated with the resolution of her symptoms of hypercortisolism. For that reason, spontaneous CD remission induced by pituitary apoplexy (PA) was diagnosed. The patient has been managed conservatively since the diagnosis and remains in clinical and biochemical remission until the present time, after 10 months of follow-up. There are three unique aspects of our case: the early age of onset of symptoms, the spontaneous remission of CD due to PA, which has been rarely reported in the medical literature, and the fact that the patient presented a microadenoma because there are fewer than 10 clinical case reports of PA associated with microadenoma.

Introduction

Cushing’s disease (CD) is characterized by excessive production of adrenocorticotropic hormone by a pituitary adenoma and represents the most common cause of endogenous Cushing’s syndrome (CS) [1]. CD was first reported in 1912 by Harvey Williams Cushing, and he described 12 cases at the Peter Bent Brigham Hospital in Baltimore [2]. This disease has a global incidence of approximately 2.2 cases per 1,000,000 people and occurs more frequently in women from 20 to 50 years of age [3]. Pituitary apoplexy (PA) is a rare condition that occurs in 2-12% of cases, and it has a high morbidity and mortality rate [4]. We report an interesting case of a woman diagnosed with CD who achieved spontaneous remission of her disease after a PA.

Case Presentation

A 14-year-old female presented with a two-year history of weight gain (32 kg), depression, elevated blood pressure, type 2 diabetes mellitus, and growth failure (height less than the third percentile). Her height was 140 cm, and her BMI was 28.1 (97th percentile). At presentation, she had not yet reached menarche. Physical examination revealed Tanner 2 breast development, acne, hirsutism, moon facies, dorsocervical fat pad, central obesity, and stretch marks. Initial laboratory tests showed hemoglobin A1C of 13%, low-density lipoprotein of 167 mg/dL, triglycerides of 344 mg/dL, high-density lipoprotein of 26 mg/dL, creatinine of 0.4 mg/dL, and elevated liver enzymes. Abdominal ultrasound indicated moderate hepatic steatosis changes.

Given the high suspicion of CS, a hormonal profile was conducted (Table 1), confirming CS and subsequently diagnosing CD. A nuclear MRI revealed a 2.6 × 1.8 mm pituitary lesion (Figure 1), prompting referral for transsphenoidal resection of the pituitary microadenoma.

Laboratories Reference range Initial One month Three months Six months
TSH (mUI/L) 0.35-4.94 2.17 2.01
AM cortisol (µg/dL) 6.02-18.4 17.3 4.06 <0.5 4.7
1 mg DST (µg/dL) <1.8 3.4
8 mg DST (µg/dL) <50% suppression 1.9 (78% suppression)
Urine-free cortisol (µg/24h) <90 235
ACTH (pg/mL) 10-60 83.5 19.2 9.7
IGF-1 (ng/mL) 36-300 293
Table 1: Pertinent laboratory investigation at baseline and follow-up with our patient

ACTH, adrenocorticotropic hormone; DST, dexamethasone suppression test; IGF-1, insulin growth factor-1; TSH, thyroid-stimulating hormone

Axial-view-of-a-T1-MRI-with-contrast-showing-a-sellar-lesion
Figure 1: Axial view of a T1 MRI with contrast showing a sellar lesion

The red arrow shows a microadenoma in relation to the normal pituitary gland.

Approximately one month after the suppression tests and while awaiting surgery, the patient presented to the emergency department with a sudden, severe, holocranial headache accompanied by projectile vomiting and diplopia, suggestive of meningism. A computed axial tomography of the central nervous system was conducted, revealing no structural abnormalities. Symptoms resolved with intravenous analgesia within approximately four to six hours. Subsequently, the patient experienced a significant decrease in insulin requirements, ultimately leading to the suspension of insulin therapy due to persistent hypoglycemia.

Weeks after the headache episode, the patient was reevaluated in the emergency department with a three-day history of diffuse abdominal pain, vomiting, asthenia, myalgia, hypotension, tachycardia, orthostatism, and recurrent hypoglycemia despite insulin suspension. Acute adrenal insufficiency was suspected and confirmed by a cortisol level of 4.06 µg/dL. Treatment with intravenous hydrocortisone 50 mg every six hours was initiated, leading to complete resolution of symptoms within 72 hours. The patient was discharged on maintenance therapy with oral hydrocortisone (20 mg in the morning and 10 mg at night). Subsequent follow-ups showed undetectable cortisol levels. Currently, the patient has been followed up for 10 months post-event, showing persistent clinical and hormonal remission of her disease.

Discussion

CD represents approximately 80% of cases of endogenous hypercortisolism, and pituitary microadenomas are the most common cause of CD in all age groups [5]. CD prevalence is 0.3-6.2 cases per 100,000 people [3], which represents 4.4% of all pituitary adenomas [6], and it is up to five times more likely to occur in women than men. Spontaneous remission of CD is rare, and it is mainly due to the apoplexy of a pituitary tumor [7].

PA is a potentially fatal condition resulting from hemorrhage or necrosis of a pituitary adenoma that produces compression of the surrounding structures with symptoms that can be critical and even fatal [8]. PA affects between 2% and 12% of patients with pituitary adenomas, mainly in nonfunctional macroadenomas [9]. Although the main mechanism of PA is hemorrhage, it can also be due to a hemorrhagic infarction or an infarction without hemorrhage; this last scenario is clinically less aggressive [10]. Among the most important precipitating factors are craniocerebral trauma, pregnancy, thrombocytopenia, coagulopathies, pituitary stimulation tests, drugs such as anticoagulants and estrogens, surgeries that are complicated by hypotension, and radiotherapy [4,11,12].

There are three unique aspects of our case. First, the age of onset is 14 years old. This characteristic has been reported in less than 6% of cases of CD, with a mean age of onset between 12.3 and 14.1 years and a slightly higher incidence in men (63%) [13]. In this population, CD is the most common cause of hypercortisolism, accounting for 75-80% of all cases [14]. Furthermore, our patient presented a significant weight gain, severe compromise in her height, hypertension, depression, and diabetes mellitus, which is compatible with the classic profile described for CD in pediatric ages. It is important to clarify that although type 2 diabetes mellitus is common in adults, it is unusual in the pediatric population [13].

Second, spontaneous remission in CD due to apoplexy has been rarely reported in the past; hence, our case is an important addition to the scant literature on this unusual phenomenon. Although there are characteristics suggestive of PA, such as hyperdense lesions within the pituitary gland and the reinforcing ring, a CT scan has a low sensitivity for detecting pituitary hemorrhage (21-46%); therefore, a negative CT scan does not rule out PA in cases where there is infarction without hemorrhage, a situation that could correspond to our case [15].

The third unique feature of our case is that the stroke occurred in the context of a microadenoma, a situation reported in less than 10 cases in the literature. Despite being a microadenoma, the symptoms of PA were severe, with symptoms of meningism, an intense headache, vomiting, and the development of adrenal insufficiency. Taylor et al. [16] reported a similar case of a 41-year-old female with microadenoma whose PA was associated with severe headache and vomiting.

The main differential diagnosis in our case is cyclical CS (CCS), a disorder that occurs in 15% of CS cases, especially in CD [17]. The diagnosis of CCS is classically established with three peaks and two valleys in cortisol secretion, spontaneous fluctuations, and clinical features of CS [7]. The possibility of CCS was ruled out due to the typical presentation of the PA event and the persistence of hypocortisolism.

Finally, several cases of recurrence of their disease have been described after remission of CS due to AP. Those recurrences usually develop in follow-ups of up to seven years [18]. At the time of the last evaluation (10 months post-PA), the patient remained in remission, but long-term follow-up is required to detect both reactivation and hypopituitarism [19].

Conclusions

CD is a rare entity in the pediatric population, usually associated with a pituitary microadenoma. Spontaneous remission of this disease is very uncommon, but when it occurs, it is mainly due to PA. We describe a case with three unique aspects: CD with an early age of onset of symptoms, spontaneous remission of CD due to PA, which has been rarely reported in the medical literature, and the fact that there are less than 10 clinical case reports of PA associated with microadenoma. It is imperative for clinicians to be aware of this possible outcome in patients with CD.

References

  1. Fleseriu M, Auchus R, Bancos I, et al.: Consensus on diagnosis and management of Cushing’s disease: a guideline update. Lancet Diabetes Endocrinol. 2021, 9:847-75. 10.1016/S2213-8587(21)00235-7
  2. Bray DP, Rindler RS, Dawoud RA, Boucher AB, Oyesiku NM: Cushing disease: medical and surgical considerations. Otolaryngol Clin North Am. 2022, 55:315-29. 10.1016/j.otc.2021.12.006
  3. Giuffrida G, Crisafulli S, Ferraù F, et al.: Global Cushing’s disease epidemiology: a systematic review and meta-analysis of observational studies. J Endocrinol Invest. 2022, 45:1235-46. 10.1007/s40618-022-01754-1
  4. Briet C, Salenave S, Bonneville JF, Laws ER, Chanson P: Pituitary apoplexy. Endocr Rev. 2015, 36:622-45. 10.1210/er.2015-1042
  5. Newell-Price J, Bertagna X, Grossman A, Nieman L: Cushing’s syndrome. Lancet. 2006, 367:1605-17. 10.1016/S0140-6736(06)68699-6
  6. Daly AF, Beckers A: The epidemiology of pituitary adenomas. Endocrinol Metab Clin North Am. 2020, 49:347-55. 10.1016/j.ecl.2020.04.002
  7. Popa Ilie IR, Herdean AM, Herdean AI, Georgescu CE: Spontaneous remission of Cushing’s disease: a systematic review. Ann Endocrinol (Paris). 2021, 82:613-21. 10.1016/j.ando.2021.10.002
  8. Siwakoti K, Omay SB, Inzucchi SE: Spontaneous resolution of primary hypercortisolism of Cushing disease after pituitary hemorrhage. AACE Clin Case Rep. 2020, 6:e23-9. 10.4158/ACCR-2019-0292
  9. Dubuisson AS, Beckers A, Stevenaert A: Classical pituitary tumour apoplexy: clinical features, management and outcomes in a series of 24 patients. Clin Neurol Neurosurg. 2007, 109:63-70. 10.1016/j.clineuro.2006.01.006
  10. Semple PL, De Villiers JC, Bowen RM, Lopes MB, Laws ER Jr: Pituitary apoplexy: do histological features influence the clinical presentation and outcome?. J Neurosurg. 2006, 104:931-7. 10.3171/jns.2006.104.6.931
  11. Turgut M, Ozsunar Y, Başak S, Güney E, Kir E, Meteoğlu I: Pituitary apoplexy: an overview of 186 cases published during the last century. Acta Neurochir (Wien). 2010, 152:749-61. 10.1007/s00701-009-0595-8
  12. Wildemberg LE, Glezer A, Bronstein MD, Gadelha MR: Apoplexy in nonfunctioning pituitary adenomas. Pituitary. 2018, 21:138-44. 10.1007/s11102-018-0870-x
  13. Concepción-Zavaleta MJ, Armas CD, Quiroz-Aldave JE, et al.: Cushing disease in pediatrics: an update. Ann Pediatr Endocrinol Metab. 2023, 28:87-97. 10.6065/apem.2346074.037
  14. Ferrigno R, Hasenmajer V, Caiulo S, et al.: Paediatric Cushing’s disease: epidemiology, pathogenesis, clinical management and outcome. Rev Endocr Metab Disord. 2021, 22:817-35. 10.1007/s11154-021-09626-4
  15. Banerjee AK: Diagnostic imaging: Brain. 2nd edition. Br J Radiol. 2010, 83:450-1.
  16. Taylor HC, McLean S, Monheim K: Resolution of Cushing’s disease followed by secondary adrenal insufficiency after anticoagulant-associated pituitary hemorrhage: report of a case and review of the literature. Endocr Pract. 2003, 9:147-51. 10.4158/EP.9.2.147
  17. Alexandraki KI, Kaltsas GA, Isidori AM, et al.: The prevalence and characteristic features of cyclicity and variability in Cushing’s disease. Eur J Endocrinol. 2009, 160:1011-8. 10.1530/EJE-09-0046
  18. Kamiya Y, Jin-No Y, Tomita K, et al.: Recurrence of Cushing’s disease after long-term remission due to pituitary apoplexy. Endocr J. 2000, 47:793-7. 10.1507/endocrj.47.793
  19. Machado MC, Gadelha PS, Bronstein MD, Fragoso MC: Spontaneous remission of hypercortisolism presumed due to asymptomatic tumor apoplexy in ACTH-producing pituitary macroadenoma. Arq Bras Endocrinol Metabol. 2013, 57:486-9. 10.1590/s0004-27302013000600012

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Whole Blood Transcriptomic Signature of Cushing’s Syndrome

Posted on July 15, 2024 by MaryO

Abstract

Objective

Cushing’s syndrome is characterized by high morbidity and mortality with high interindividual variability. Easily measurable biomarkers, in addition to the hormone assays currently used for diagnosis, could reflect the individual biological impact of glucocorticoids. The aim of this study is to identify such biomarkers through the analysis of whole blood transcriptome.

Design

Whole blood transcriptome was evaluated in 57 samples from patients with overt Cushing’s syndrome, mild Cushing’s syndrome, eucortisolism, and adrenal insufficiency. Samples were randomly split into a training cohort to set up a Cushing’s transcriptomic signature and a validation cohort to assess this signature.

Methods

Total RNA was obtained from whole blood samples and sequenced on a NovaSeq 6000 System (Illumina). Both unsupervised (principal component analysis) and supervised (Limma) methods were used to explore the transcriptome profile. Ridge regression was used to build a Cushing’s transcriptome predictor.

Results

The transcriptomic profile discriminated samples with overt Cushing’s syndrome. Genes mostly associated with overt Cushing’s syndrome were enriched in pathways related to immunity, particularly neutrophil activation. A prediction model of 1500 genes built on the training cohort demonstrated its discriminating value in the validation cohort (accuracy .82) and remained significant in a multivariate model including the neutrophil proportion (P = .002). Expression of FKBP5, a single gene both overexpressed in Cushing’s syndrome and implied in the glucocorticoid receptor signaling, could also predict Cushing’s syndrome (accuracy .76).

Conclusions

Whole blood transcriptome reflects the circulating levels of glucocorticoids. FKBP5 expression could be a nonhormonal marker of Cushing’s syndrome.

Significance

In Cushing’s syndrome, specific hormone assays inform about the level of deviation from normal range. The blood transcriptome signature proposed here is also able to discriminate patients, without any hormone measurements. This direct measurement of the biological impact of glucocorticoids at a tissue level may better reflect the individual consequences of glucocorticoid excess.

Introduction

Cushing’s syndrome (CS) is a condition characterized by chronic cortisol excess related to glucocorticoid treatment (exogenous Cushing’s syndrome) or to endogenous hypercortisolism. The excessive cortisol secretion may be due to either adrenocorticotropic hormone (ACTH)–dependent conditions, most often an ACTH-producing pituitary adenoma (Cushing’s disease), or ACTH-independent causes, commonly a benign adrenal adenoma.1 Chronic exposure to glucocorticoid excess results in specific complications, including cardiovascular and thromboembolic diseases, diabetes mellitus, metabolic syndrome, osteoporosis, and neurocognitive disorders. Numerous comorbidities result in impaired quality of life and increased mortality.2-4

Despite the availability of different hormonal tests for diagnosis and follow-up, the clinical management of these patients remains challenging, since none of the available tools proved to be fully accurate due to the variable pattern of cortisol secretion and the pitfalls of the hormonal immunoassays.5,6 Moreover, the clinical effects of glucocorticoid exposure on peripheral tissues depend not only on the intensity and duration of glucocorticoid excess but also on the peripheral glucocorticoid metabolism and the individual sensitivity to glucocorticoids, not accurately estimated by hormonal parameters. This results in the high interindividual variability frequently reported in Cushing’s syndrome.7,8 Recent studies suggested that the combined assessment of cortisol secretion, cortisone-to-cortisol peripheral activation by the 11β-hydroxysteroid dehydrogenase enzyme, and glucocorticoid receptor sensitizing variants may better estimate the risk to develop each type of complications.9-11

These aspects are crucial mainly for the management of patients with mild Cushing’s syndrome, not clearly characterized by classical features of cortisol excess but consistently associated to an increased risk of morbidities and mortality.12,13 Mild hypercortisolism can occur in different settings. In patients with adrenal incidentalomas, mild hypercortisolism is currently referred to as mild autonomous cortisol secretion (MACS).14 In patients with Cushing’s disease, mild hypercortisolism occurs when hypercortisolism persists/recurs after pituitary surgery or under medical treatment.12,15,16 Irrespective of the origin of cortisol excess, it is still debated whether patients with mild hypercortisolism, as well as those under low-dose systemic or local glucocorticoid therapy, need a close follow-up for cortisol excess–related complications and specific preventive treatments.17-19

In this context, genomic-based studies have recently focused on the identification of blood molecular markers in patients exposed to glucocorticoid excess, aiming to a better individual characterization of these patients. Particularly, DNA methylation profile has been investigated as a potential biological hallmark of glucocorticoid action. Previous studies suggested an association between hypothalamic–pituitary–adrenal axis dysregulation and specific blood DNA methylation profiles, particularly in post-traumatic stress disorders, while recently a dynamic whole blood DNA methylation signature reflecting glucocorticoid excess has been identified.20-22 In both genomic-based and preclinical studies, FKBP5, a gene implicated in glucocorticoid signaling, emerged as potential non hormonal marker of glucocorticoid excess.22-24

The present study completes the previous approaches exploring the impact of glucocorticoids on whole blood transcriptome to better understand the molecular mechanisms of glucocorticoid impregnation. Specifically, through the analysis of whole blood transcriptome profiles from patients with endogenous Cushing’s syndrome, eucortisolism, or adrenal insufficiency, we proposed a transcriptome signature predicting glucocorticoid excess.

Materials and methods

Patients and samples

Fifty-seven blood samples were collected from 43 patients with a confirmed diagnosis of endogenous Cushing’s syndrome, followed in Cochin Hospital (APHP, Paris, France). Diagnostic criteria of Cushing’s syndrome included increased 24-h urinary free cortisol, abnormal cortisol after 1 mg dexamethasone suppression, and altered circadian cortisol rhythm, following consensus guidelines.25

For 14 patients, blood samples were collected before correction of Cushing’s syndrome and at least 3 months after Cushing’s syndrome treatment. At the time of blood sampling, patients were classified as overt Cushing’s syndrome, mild Cushing’s syndrome, eucortisolism, or adrenal insufficiency, depending on clinical and hormonal evaluation. Briefly, overt Cushing’s syndrome patients presented clinical signs and increased 24-h urinary free cortisol (>240 nmol/24 h), increased midnight salivary cortisol (>6 nmol/L), and insufficient cortisol suppression after 1 mg dexamethasone (>50 nmol/L). The mild Cushing’s syndrome cohort included patients with mild hypercortisolism due to either Cushing’s disease or benign adrenal Cushing’s syndrome. The former were patients with persistent or recurrent hypercortisolism after pituitary surgery or during medical treatment; in these patients, the diagnosis of Cushing’s disease was confirmed by the histopathological report consistent with a corticotroph adenoma in the surgically treated patients (6 out of 7) and by the magnetic resonance imaging evidence of a pituitary adenoma in the upfront medically treated patient. Mild hypercortisolism in patients with Cushing’s disease was defined, as previously reported,16,26 by the absence of clinically overt signs of CS and a slight alteration in cortisol secretion, including either increased 24-h urinary free cortisol or increased midnight cortisol or inadequate cortisol suppression after 1 mg of dexamethasone. For mild hypercortisolism due to benign adrenal CS, MACS criteria were used—post-dexamethasone serum cortisol concentration above 50 nmol/L—following recent consensus guidelines.14 The term “mild” was retained for 1 patient with benign adrenal CS who had a borderline dexamethasone suppression test (48 nmol/L) but increased 24-h urinary free cortisol. Eucortisolism was defined as a combination of normalized 24-h urinary free cortisol and of restored cortisol circadian rhythm after either surgery or medical treatment. Adrenal insufficiency was secondary to pituitary surgery for Cushing’s disease. The diagnosis was based on low morning plasma cortisol (<160 nmol/L) and confirmed by the insufficient response to 250 µg corticotropin stimulation test (<500 nmol/L), following the current consensus guidelines.27,28 Detailed hormone values for each sample are provided in Table S1.

Thirty additional samples were collected from patients followed in Hôpital Européen Georges Pompidou Hospital (APHP, Paris, France). These patients presented pheochromocytoma (n = 19) and primary hyperaldosteronism (n = 11; Table S1). The diagnosis was made following the consensus guidelines.29,30

The study was conducted in accordance with the Declaration of Helsinki. Signed informed consent for molecular analysis of blood samples and for access to clinical data was obtained from all patients, and the study was approved by the institutional review board (Comité de Protection de Personnes Ile de France 1, projects 13495 and 13311).

RNA collection and extraction

Whole blood samples were collected into PAXgene Blood RNA Tube (PreAnalytiX, Hombrechtikon, Switzerland), following the manufacturer’s instructions. Total RNA was extracted by using PAXgene Blood RNA Kit, v2 (Qiagen, Hilden, Germany), following the manufacturer’s instructions.

Transcriptome data generation

After RNA extraction, RNA concentrations were obtained using nanodrop or a fluorometric Qubit RNA assay (Life Technologies, Grand Island, NY, USA). The quality of the RNA (RNA integrity number, RIN) was determined on the Agilent 2100 Bioanalyzer (Agilent Technologies, Palo Alto, CA, USA) following manufacturer’s instructions.

To construct the libraries, 250 ng of high-quality total RNA sample (RIN > 8) was processed using the Stranded mRNA Prep kit (Illumina, San Diego, CA, USA) according to the manufacturer’s instructions. Briefly, after purification of poly-A–containing mRNA molecules, mRNA molecules were fragmented and reverse-transcribed using random primers. Replacement of dTTP (deoxythymidine triphosphate) by dUTP (deoxyuridine triphosphate) during the second-strand synthesis permitted to achieve the strand specificity. Addition of a single A base to the cDNA was followed by ligation of Illumina adapters. Libraries were quantified on a Qubit fluorometer (Thermo Fisher Scientific, Waltham, MA, USA), and profiles were assessed using the DNA High Sensitivity LabChip kit on an Agilent Bioanalyzer (Agilent Technologies). Libraries were sequenced on a NovaSeq 6000 System (Illumina), using 51 base-lengths read in a paired-end mode.

Whole blood methylome data

Among the 57 samples included in the transcriptome analysis, 32 were also used for a methylome analysis recently published.22 For each gene, potentially methylated cytosines-referred to as CpGs- in the promoter regions were defined as CpGs belonging to the TSS1500, TSS200, 5′UTR, and first exon regions. CpG methylation levels were analyzed using M-values generated as previously reported.22

Bioinformatics and statistics

Quality control was performed on raw count matrix, with a target of >5 million reads per sample. All samples passed this control. Illumina adapters were removed using Trimmomatic (v0.39) in paired-end mode.31 Reads were aligned to the reference human genome (GRCh37) and counted using STAR (v2.7.9a).32 Counts were aggregated for transcripts corresponding to the same gene, and only genes with a count sum > 0 in all samples were further considered. Globin genes and sex-related genes were also discarded, as previously published.33

Counts were normalized with DESeq2, using rlog transformation34 (v.1.24.0): raw counts were converted to distributed data structures (dds), and lowly expressed genes were removed using a dds > 1 in at least 3 samples as cutoff, obtaining a final dataset of n = 21 116 and n = 57 samples. The 1500 most variable genes were selected to assess the global data structure by principal component analysis (PCA). Overrepresentation analysis of genes most contributing to PCA components was performed using clusterProfiler package35 (v.3.12.0).

From gene counts, blood cell composition was inferred using the online CIBERSORTx tool (Stanford University 2022),36 with the following parameters: B-mode batch correction, disabled quantile normalization, absolute mode, and n = 500 permutations. For each cell types, a score was generated, reflecting the absolute proportion of each cell type in a mixture.

For supervised differential expression analysis, the edgeR package37 (v.3.26.8) was used to read and preprocess the data before analysis: raw counts were converted to counts per million (CPM), and lowly expressed genes were removed using a CPM > 1 in at least 3 samples as cutoff. To remove heteroscedascity of count data, normalized data were transformed using the voom function.38 Differential expression analysis was performed by applying linear modeling using the limma package39 (v. 3.40.6). Differentially expressed genes were selected using a Benjamin–Hochberg adjusted P < .05 and a logFC > 1 as cutoffs. Overrepresentation analysis of differentially expressed genes was performed using the clusterProfiler package. Of note, the edgeR normalization did not significantly modify the normalized expression levels compared to DESeq2 (gene expression correlation r = .9924, P < 2.2e−16).

For predicting glucocorticoid status from transcriptome, we carried out a Ridge-regularized regression (α = 0) using the 1500 most variable genes, with a 4-fold cross-validation, using the glmnet package40 (v. 4.1-1). The optimization of the 1500 gene predictor was performed on a training cohort of 29 samples, randomly selected from the whole cohort and including 18 samples corresponding to overt Cushing’s syndrome and 11 samples corresponding to either eucortisolism or adrenal insufficiency (patients with mild Cushing’s syndrome were excluded). The accuracy of the 1500 gene predictor was assessed on 2 validation cohorts: a first one (n = 17) including overt Cushing’s syndrome, eucortisolism, and adrenal insufficiency samples, and a second one (n = 30) including pheochromocytoma and primary hyperaldosteronism samples. The latter cohort was used to test the specificity of the predictor, given the different nature of catecholamine excess and primary hyperaldosteronism from Cushing’s syndrome.

Quantitative variable comparisons between groups were performed using Student’s t-test for variables following a normal distribution, or Wilcoxon’s test and Kruskal–Wallis test for variables not following a normal distribution. Quantitative variable correlations were performed using Pearson’s or Spearman’s test according to data distribution. Multivariate logistic regression model including the 1500 gene transcriptome predictor and the neutrophil score was used to test the association with glucocorticoid status. All P-values were 2-sided, and the level of significance was set at .05. All tests were computed in R software environment (3.6.0 version).

Results

Cohort presentation

Fifty-seven blood samples were collected from 43 patients (Table 1;  Table S1). Samples were collected at different time points during the disease, thus reflecting different glucocorticoid status: overt Cushing’s syndrome (n = 28), mild Cushing’s syndrome (n = 11), eucortisolism (n = 10), and adrenal insufficiency (n = 8).
Table 1.

Overall cohort presentation and group comparisons.

Glucocorticoid status Whole cohort
median (IQR)		 Training cohort
median (IQR)		 First validation cohort
median (IQR)		 P-valuea
Samples Total 57 29 17
 Overt Cushing’s syndrome N 28 18 10
Urinary free cortisol
nmol/24 h (<240)		 879.5
(419)		 879.5
(307.5)		 904.5
(5469.25)		 .688
Midnight salivary cortisol
nmol/L (<6)		 14
(12)		 11
(8.5)		 17.5
(27.5)		 .034
Plasma cortisol after 1 mg DST
nmol/L (<50)		 232
(288)		 218
(271)		 232
(460)		 .419
 Mild Cushing’s syndrome N 11 NA NA NA
Urinary free cortisol
nmol/24 h (<240)		 273
(100)		 NA NA NA
Midnight salivary cortisol
nmol/L (<6)		 7
(5.5)		 NA NA NA
Plasma cortisol after 1 mg DST
nmol/L (<50)		 56
(19.75)		 NA NA NA
 Eucortisolism N 10 6 4
Urinary free cortisol
nmol/24 h (<240)		 183
(87.75)		 159
(71.25)		 204
(39.25)		 .521
Midnight salivary cortisol
nmol/L (<6)		 4
(1)		 4
(0)		 4.5
(1.25)		 .797
Plasma cortisol after 1 mg DST nmol/L (<50) 35
(11)		 31
(8.5)		 41.5
(6.5)		 .4
 Adrenal insufficiency N 8 5 3
Early morning plasma cortisol nmol/L (160–500) 95.5
(66.75)		 95.5
(28.25)		 98
(98)		 1
Cortisol after ACTH stimulation nmol/L (<500) 405.5
(165.25)		 435.5
(128.75)		 308
(163)		 .142

Cortisol values are provided as median values with interquartile range (IQR). aWilcoxon’s test comparing training and first validation cohorts.

Median age was 48 years (range: 26 to 73), with a female predominance (2.35 to 1). Cushing’s syndrome corresponded either to Cushing’s disease (n = 26) or to benign adrenal Cushing’s syndrome (n = 17). Mild Cushing’s syndrome cohort included 7 patients with Cushing’s disease and 4 patients with a benign adrenal tumor. Hypercortisolism-related complications, including hypertension, diabetes, and osteoporosis, were present in 41 (71.9%), 16 (28.0%), and 10 (17.5%) patients, respectively.

For the purpose of building and evaluating a glucocorticoid status predictor from blood transcriptome, we focused on patients with overt Cushing’s syndrome, eucortisolism, and adrenal insufficiency, excluding patients with mild Cushing’s syndrome (n = 11) due to their uncertain glucocorticoid status. Patients were randomly assigned either to a training (n = 29) or to a first validation cohort (n = 17). A second validation cohort of 30 samples was used to test the specificity of the predictor, including 19 patients with pheochromocytoma and 11 patients with primary hyperaldosteronism (Table S1).

Impact of glucocorticoid level on whole blood transcriptome

Unsupervised PCA on the 1500 most variable genes of the whole cohort (samples = 57) discriminated patients according to their glucocorticoid status (Figure 1A). This discrimination was mainly based on the first principal component (PC1; Table S2). In terms of gene expression signature, PC1 was enriched in signaling pathways related to immune response, particularly those relative to neutrophils’ activation and degranulation (Figure 1BTable S3). Beyond the immune response, PC1 was also enriched in genes more generally involved in the response to glucocorticoids,41 including FKBP5PBX1SPI1CDK5R1CXCL8NR4A1, and TBX21 (Table S2).

Impact of glucocorticoid levels on whole blood transcriptome. (A) Sample projections based on the combination of the first 2 principal components (PC1 and PC2) of unsupervised PCA performed on the 1500 most variable genes of the whole cohort (n = 57). (B) Dot plot of the 10 most GO-enriched signaling pathways in overt Cushing's syndrome, using the PC1 coefficients.

Figure 1.

Impact of glucocorticoid levels on whole blood transcriptome. (A) Sample projections based on the combination of the first 2 principal components (PC1 and PC2) of unsupervised PCA performed on the 1500 most variable genes of the whole cohort (n = 57). (B) Dot plot of the 10 most GO-enriched signaling pathways in overt Cushing’s syndrome, using the PC1 coefficients.

Accordingly, a supervised comparison of Cushing’s syndrome samples (n = 28) against eucortisolism/adrenal insufficiency samples (n = 18) provided similar results (Figure 2Table S4).

Differentially expressed genes in overt Cushing's syndrome. Volcano plot of the differentially expressed genes (n = 517) in overt Cushing's syndrome (n = 28) versus eucortisolism/adrenal insufficiency (n = 18).

Figure 2.

Differentially expressed genes in overt Cushing’s syndrome. Volcano plot of the differentially expressed genes (n = 517) in overt Cushing’s syndrome (n = 28) versus eucortisolism/adrenal insufficiency (n = 18).

Predicting glucocorticoid status by blood transcriptome

To predict glucocorticoid status by whole blood transcriptome, we performed a cross-validated Ridge-regularized regression, using the 1500 most variable genes. The 1500 transcriptome predictor was optimized in the training cohort to discriminate overt Cushing’s syndrome from eucortisolism/adrenal insufficiency (Table S5). The predictive value of this model was confirmed on both the first and the second validation cohorts (accuracy of .82 and 1, respectively, Table 2Table S6). Accordingly, samples from the second validation cohort clustered with eucortisolism/adrenal insufficiency samples, as assessed by PCA (Figure S1).
Table 2.

Performance of molecular predictors, based on the whole blood transcriptome signature and on FKBP5 expression level, in discriminating glucocorticoid excess.

Cohort Predictor Accuracy Sensitivity Specificity
First validation cohort Predictor based on 1500 genes .82 .90 .85
Predictor based on FKBP5 .76 .80 .71
Second validation cohort Predictor based on 1500 genes 1 NAa 1
Predictor based on FKBP5 .46 NAa .46

aNot applicable due to the lack of true positives in the second validation cohort.

Mild Cushing’s syndrome samples—excluded from the training and validation cohorts—were classified either as overt Cushing’s syndrome (n = 5/11, 45.5%) or as eucortisolism/adrenal insufficiency (n = 6/11, 54.5%). Of note, the Ridge scores for samples classified as overt Cushing’s syndrome in the mild Cushing’s syndrome cohort was lower than in the training and the first validation cohorts (Wilcoxon, P = .008). The Ridge scores for samples classified as eucortisolism/adrenal insufficiency in the mild Cushing’s syndrome cohort did not differ from the training and first validation cohorts (Wilcoxon, P = .9; Table S6). Accordingly, mild Cushing’s syndrome samples were projected in-between overt Cushing’s syndrome and eucortisolism samples on PCA (Figure 1A).

We then tested whether the glucocorticoid status could be predicted using a single gene. We focused on FKBP5, due to (1) its Ridge regression coefficient being among the highest (Table S5), (2) its potential ability to discriminate Cushing’s syndrome,22,23 and (3) its known implication in glucocorticoid signaling (Figure 3A).42 The prediction accuracy of FKBP5 expression was comparable to the 1500 gene transcriptome predictor in the first validation cohort (accuracy: .76), but lower in the second validation cohort (accuracy: .46; Table 2Table S7). The other genes involved in the glucocorticoid response found enriched in PC1 were not further analyzed as potential single biomarkers, since their association with Cushing’s syndrome was not confirmed in supervised analysis, and since their Ridge regression coefficients were lower than FKBP5 coefficient (Table S5).

FKBP5 expression related to the different glucocorticoid status. (A) Boxplot of FKBP5 gene expression in the different study groups. *Student's t-test P < .001. (B) Representation of the positive correlation between the 24-h urinary free cortisol and FKBP5 expression (r = .72, P = 2.032e−10). (C) Representation of the inverse correlation between FKBP5 expression and the mean methylation level (M-value) of FKBP5 promoter–associated CpG site (r = −.86, P = 1.312e−10).

Figure 3.

FKBP5 expression related to the different glucocorticoid status. (A) Boxplot of FKBP5 gene expression in the different study groups. *Student’s t-test P < .001. (B) Representation of the positive correlation between the 24-h urinary free cortisol and FKBP5 expression (r = .72, P = 2.032e−10). (C) Representation of the inverse correlation between FKBP5 expression and the mean methylation level (M-value) of FKBP5 promoter–associated CpG site (r = −.86, P = 1.312e−10).

We then tested the contribution of blood cell composition in the 1500 gene transcriptome predictor. We inferred the different blood cell subtype proportions from the whole blood transcriptome of each sample. An expected increase of neutrophil proportion in overt Cushing’s syndrome43,44 was observed (Kruskal–Wallis’s test, P = 8.5e−06; Table S1 and Figure S2). In a multivariate model combining the 1500 gene transcriptome predictor and the neutrophil score, the 1500 gene transcriptome predictor remained significant (P = .002; Table 3).
Table 3.

Multivariate model combining the 1500 gene transcriptome predictor and neutrophil scores.

Variables OR 95% CI P-value
1500-genes predictor 4.37 2.06–15.3 .002
Neutrophils score .48 .02–6.13 .6

Training and first validation cohorts were combined. Two statuses were considered: overt Cushing’s syndrome and eucortisolism/adrenal insufficiency.

Abbreviations: OR, odds ratio; CI, confidential Interval.

Association between blood transcriptome and Cushing’s syndrome complications

The 1500 gene transcriptome predictor was positively correlated to the 24-h urinary free cortisol (r = .78, P = 2.993e−13; Figure S3). The 1500 gene transcriptome predictor was higher in patients with osteoporosis (Wilcoxon, P = 2.9e−05), while the 24-h urinary free cortisol did not show any difference (Wilcoxon, P-value of .17, Figure 4A and B). No difference was observed between patients with and without diabetes (Wilcoxon, P = .31), nor with or without hypertension (Wilcoxon, P = .25), and the 1500 gene transcriptome predictor was not correlated to body mass index (BMI) (P-value = .108).

Potential markers of osteoporosis in overt Cushing's syndrome. Association between osteoporosis and 24-h urinary free cortisol (A), 1500 gene transcriptome predictor (B), and FKBP5 expression (C). For 24-h urinary free cortisol, values are expressed as log10.

Figure 4.

Potential markers of osteoporosis in overt Cushing’s syndrome. Association between osteoporosis and 24-h urinary free cortisol (A), 1500 gene transcriptome predictor (B), and FKBP5 expression (C). For 24-h urinary free cortisol, values are expressed as log10.

Similar findings were obtained with FKBP5 expression level, including a positive correlation with the 24-h urinary free cortisol (r = .72, P = 2.032e−10, Figure 3B), a higher expression in patients with osteoporosis (Wilcoxon, P = 2.9e−05; Figure 4C), no difference in patients with diabetes (Wilcoxon, P = .72) or hypertension (Wilcoxon, P = .4), and no correlation with BMI (P = .657).

Association of whole blood transcriptome with whole blood methylome

For 32 samples with both whole blood transcriptome and methylome22 available (n = 32), a correlation analysis was performed. A majority of genes differentially expressed in overt Cushing’s syndrome showed a negative correlation with CpG sites of their promoter regions (Table S8). FKBP5 was among the genes showing the strongest inverse correlation (r = − .86, P adjusted = 5.94e−09; Figure 3C).

Discussion

In this study, we identified a whole blood transcriptome signature predicting the glucocorticoid excess. This signature, in addition to the hormone assays currently used for diagnosis, could reflect the individual biological impact of glucocorticoids.

We designed a predictor with optimal selection of transcriptome biomarkers able to differentiate overt Cushing’s syndrome from eucortisolism and adrenal insufficiency. The predictive value of such transcriptome predictor was confirmed on 2 validation cohorts. For patients with mild Cushing’s syndrome, our predictor showed intermediate classification, confirming the clinical heterogeneity of this group. Indeed, these intermediate patients indisputably fall in-between patients with overt Cushing’s syndrome and eucortisolism, with some overlap in both groups. Whether such non hormonal biomarkers, directly measuring glucocorticoid action, can be useful for the specific management of these patients remains to be established. The question is important, considering the high prevalence of mild Cushing’s syndrome in the general population and the still-ongoing debate on complications’ surveillance and treatment of choice.45 Here, a proper evaluation of mild Cushing’s syndrome is difficult, due to both the lack of a clear clinical definition and to the size of the cohort, not large enough to assess the existence of a specific signature for these patients, thus representing a limitation of this study. Another open question is whether the markers presented here would have comparable relevance in patients with exogenous Cushing’s syndrome, related to glucocorticoid treatments, especially for the common situation of long-term treatment with low glucocorticoid doses or with “local” glucocorticoid treatments.

Noteworthy, this identified signature derives from whole blood, a mixture of various cell types with potentially cell-dependent impact of glucocorticoids on transcriptome profile. Indeed, glucocorticoids have a direct effect on white blood cell count inducing an increase in the neutrophil proportion.43,44 We inferred white blood cell count from transcriptome profile for each sample, and, as expected, overt Cushing’s syndrome samples were characterized by higher neutrophil score, and, accordingly, genes differentially expressed in this group were enriched in immunity-related pathways, mainly in the activation and degranulation of neutrophils. However, among the genes differentially expressed in overt Cushing’s syndrome, we also identified genes more specifically involved in glucocorticoid response, suggesting differences not only related to immunity. Moreover, we demonstrated that the prediction based on transcriptome signature remained significant after adjustment for neutrophil score and therefore that transcriptome profile does not only reflect blood composition variations.

Whole blood transcriptome analysis is not easily reproducible in clinical practice. Thus, we tried to simplify the marker by focusing on one single gene. FKBP5, as a potential surrogate of the 1500 gene transcriptome signature, was able to differentiate and predict Cushing’s syndrome with a good accuracy. FKBP5 (FK506-binding protein 51) is a co-chaperone of heat shock protein 90 (Hsp90) involved in the regulation of the glucocorticoid receptor activity, maintaining it unbound and inactive in the cytoplasm, thus restricting the nuclear translocation of the cortisol receptor complex.24,46 According to preclinical studies, in the presence of glucocorticoid excess, FKBP5 expression increases at both mRNA and protein levels as an effect of intracellular negative feedback.47 Previous studies also showed that FKBP5 expression is sensitive to exogenous glucocorticoids in healthy volunteers and that FKBP5 levels are higher in patients with Cushing’s syndrome, while decreasing to normal baseline levels after successful surgery.23 It has been also demonstrated that the methylation of FKBP5 is affected by stress and dynamically by glucocorticoid level in patients with endogenous Cushing’s syndrome.42 Of note, in our second validation cohort, including patients with pheochromocytoma and primary aldosteronism, the ability of FKBP5 expression level to properly call the absence of Cushing’s syndrome dropped compared to the first validation cohort, raising concerns about potential limits in specificity. These results also highlight the importance of using larger validation cohorts with a wide variety of conditions before using such a biomarker in routine.

Interestingly, in patients with overt Cushing’s syndrome, beyond the correlation between gene expression and 24-h urinary free cortisol, the variability of gene expression was higher in patients with moderate increase of 24-h urinary free cortisol. This suggests a potential informative role of gene expression markers in patients with moderate cortisol increase. In this line, Guarnotta et al. showed that the level of urinary hypercortisolism does not seem to correlate with Cushing’s syndrome severity and that clinical features and cortisol excess–related comorbidities are more reliable indicators in the assessment of disease severity.48 In our study, the transcriptomic profile could discriminate Cushing’s syndrome patients with and without osteoporosis, although the 24-h urinary free cortisol values did not differ between the two groups. However, these results need additional validation, due to the limited cohort size and because of potential confounders not considered, including pre-existing diagnosis of osteoporosis and other determinants of skeletal fragility. Although this preliminary finding further supports the potential value of gene expression markers in predicting catabolic complications, to which extent these biomarkers are relevant in clinical practice remains to be established and better explored in larger cohorts of patients with moderate Cushing’s syndrome.

The transcriptome profile identified in this study also confirmed the previous findings obtained by analyzing the whole blood methylome in Cushing’s syndrome. The negative correlation between promoter methylation and gene expression strengthens our results and underlines the importance of epigenetic alterations in Cushing’s syndrome.49

In conclusion, we showed that the whole blood transcriptome reflects the circulating levels of glucocorticoids and that FKBP5 expression level could be a single gene non hormonal marker of Cushing’s syndrome.

Acknowledgments

We thank the Genomic platform and the team “Genomic and Signaling of Endocrine Tumors” of Institut Cochin, the French COMETE research network, the European Network for the Study of Adrenal Tumor (ENSAT), and the European Reference Network on Rare Endocrine Conditions (Endo-ERN).

Supplementary material

Supplementary material is available at European Journal of Endocrinology online.

Funding

This project has received funding from the European Union’s Horizon 2020 Research and Innovation program under grant agreement no. 633983 and the Programme Hospitalier de Recherche Clinique “CompliCushing” (PHRC AOM 12-002-0064). This work was also supported by the Programme de Recherche Translationnelle en Cancérologie to the COMETE network (PRT-K COMETE-TACTIC).

Authors’ contribution

Maria Francesca Birtolo (Data curation [equal], Formal analysis [equal], Writing—original draft [equal]), Roberta Armignacco (Conceptualization [equal], Data curation [equal], Formal analysis [equal], Writing—review & editing [equal]), Nesrine Benanteur (Formal analysis [equal]), Bertrand Baussart (Writing—review & editing [equal]), Chiara Villa (Writing—review & editing [equal]), Daniel De Murat (Formal analysis [equal]), Laurence Guignat (Writing—review & editing [equal]), Lionel Groussin (Writing—review & editing [equal]), Rosella Libé (Writing—review & editing [equal]), Maria-Christina Zennaro (Data curation [equal], Writing—review & editing [equal]), Meriama Saidi (Data curation [equal]), Karine Perlemoine (Data curation [equal]), Franck Letourneur (Data curation [equal]), Laurence Amar (Data curation [equal], Writing—review & editing [equal]), Jérôme Bertherat (Writing—review & editing [equal]), Anne Jouinot (Conceptualization [equal], Formal analysis [equal], Writing—original draft [equal]), and Guillaume Assié (Conceptualization [equal], Formal analysis [equal], Funding acquisition [equal], Project administration [equal], Writing—original draft [equal]).

Data availability

Transcriptome data generated and analyzed in this study are available in the EMBL-EBI BioStudies repository (reference number: S-BSST1241).

Author notes

Conflict of interest: G.A. is on the editorial board of EJE. G.A. was not involved in the review or editorial process for this paper, on which he is listed as an author.

© The Author(s) 2024. Published by Oxford University Press on behalf of European Society of Endocrinology.
This is an Open Access article distributed under the terms of the Creative Commons Attribution License (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted reuse, distribution, and reproduction in any medium, provided the original work is properly cited.

 

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Unveiling the Uncommon: Cushing’s Syndrome (CS) Masquerading as Severe Hypokalemia

Posted on July 2, 2024 by MaryO

Abstract

Cushing’s syndrome (CS) arises from an excess of endogenous or exogenous cortisol, with Cushing’s disease specifically implicating a pituitary adenoma and exaggerated adrenocorticotropic hormone (ACTH) production. Typically, Cushing’s disease presents with characteristic symptoms such as weight gain, central obesity, moon face, and buffalo hump.

This case report presents an unusual manifestation of CS in a 48-year-old male with a history of hypertension, where severe hypokalemia was the primary presentation. Initial complaints included bilateral leg swelling, muscle weakness, occasional shortness of breath, and a general feeling of not feeling well. Subsequent investigations revealed hypokalemia, metabolic alkalosis, and an abnormal response to dexamethasone suppression, raising concerns about hypercortisolism. Further tests, including 24-hour urinary free cortisol and ACTH testing, confirmed significant elevations. Brain magnetic resonance imaging (MRI) identified a pituitary macroadenoma, necessitating neurosurgical intervention.

This case underscores the rarity of CS presenting with severe hypokalemia, highlighting the diagnostic challenges and the crucial role of a collaborative approach in managing such intricate cases.

Introduction

Cushing’s syndrome (CS), characterized by excessive cortisol production, is well-known for its diverse and often conspicuous clinical manifestations. Cushing’s disease is a subset of CS resulting from a pituitary adenoma overproducing adrenocorticotropic hormone (ACTH), leading to heightened cortisol secretion. The classic presentation involves a spectrum of symptoms such as weight gain, central obesity, muscle weakness, and mood alterations [1].

Despite its classic presentation, CS can demonstrate diverse and atypical features, challenging conventional diagnostic paradigms. This case report sheds light on a rare manifestation of CS, where severe hypokalemia was the primary clinical indicator. Notably, instances of CS prominently manifesting through severe hypokalemia are scarce in the literature [1,2].

Through this exploration, we aim to provide valuable insights into the diagnostic intricacies of atypical CS presentations, underscore the significance of a comprehensive workup, and emphasize the collaborative approach essential for managing such uncommon hormonal disorders.

Case Presentation

A 48-year-old male with a history of hypertension presented to his primary care physician with complaints of bilateral leg swelling, occasional shortness of breath, dizziness, and a general feeling of malaise persisting for 10 days. The patient reported increased water intake and urinary frequency without dysuria. The patient was diagnosed with hypertension eight months ago. He experienced progressive muscle weakness over two months, hindering his ability to perform daily activities, including using the bathroom. The primary care physician initiated a blood workup that revealed severe hypokalemia with a potassium level of 1.3 mmol/L (reference range: 3.6 to 5.2 mmol/L), prompting referral to the hospital.

Upon admission, the patient was hypertensive with a blood pressure of 180/103 mmHg, a heart rate of 71 beats/minute, a respiratory rate of 18 breaths/minute, and an oxygen saturation of 96% on room air. Physical examination revealed fine tremors, bilateral 2+ pitting edema in the lower extremities up to mid-shin, abdominal distension with normal bowel sounds, and bilateral reduced air entry in the bases of the lungs on auscultation. The blood work showed the following findings (Table 1).

Parameter Result Reference Range
Potassium (K) 1.8 mmol/L 3.5-5.0 mmol/L
Sodium (Na) 144 mmol/L 135-145 mmol/L
Magnesium (Mg) 1.3 mg/dL 1.7-2.2 mg/dL
Hemoglobin (Hb) 15.5 g/dL 13.8-17.2 g/dL
White blood cell count (WBC) 13,000 x 103/µL 4.5 to 11.0 × 109/L
Platelets 131,000 x 109/L 150-450 x 109/L
pH 7.57 7.35-7.45
Bicarbonate (HCO3) 46 mmol/L 22-26 mmol/L
Lactic acid 4.2 mmol/L 0.5-2.0 mmol/L
Table 1: Blood work findings

In order to correct the electrolyte imbalances, the patient received intravenous (IV) magnesium and potassium replacement and was later transitioned to oral. The patient was also started on normal saline at 100 cc per hour. To further investigate the complaint of shortness of breath, the patient underwent a chest X-ray, which revealed bilateral multilobar pneumonia (Figure 1). He was subsequently treated with ceftriaxone (1 g IV daily) and clarithromycin (500 mg twice daily) for seven days.

A-chest-X-ray-revealing-(arrows)-bilateral-multilobar-pneumonia
Figure 1: A chest X-ray revealing (arrows) bilateral multilobar pneumonia

With persistent abdominal pain and lactic acidosis, a computed tomography (CT) scan abdomen and pelvis with contrast was conducted, revealing a psoas muscle hematoma. Subsequent magnetic resonance imaging (MRI) depicted an 8×8 cm hematoma involving the left psoas and iliacus muscles. The interventional radiologist performed drainage of the hematoma involving the left psoas and iliacus muscles (Figure 2).

Magnetic-resonance-imaging-(MRI)-depicting-an-8x8-cm-hematoma-(arrow)-involving-the-left-psoas-and-iliacus-muscles
Figure 2: Magnetic resonance imaging (MRI) depicting an 8×8 cm hematoma (arrow) involving the left psoas and iliacus muscles

In light of the concurrent presence of hypokalemia, hypertension, and metabolic alkalosis, there arose concerns about Conn’s syndrome, prompting consultation with endocrinology. Their recommended workup for Conn’s syndrome included assessments of the aldosterone-renin ratio and random cortisol levels. The results unveiled an aldosterone level below 60 pmol/L (reference range: 190 to 830 pmol/L in SI units) and a plasma renin level of 0.2 pmol/L (reference range: 0.7 to 3.3 mcg/L/hr in SI units). Notably, the aldosterone-renin ratio was low, conclusively ruling out Conn’s syndrome. The random cortisol level was notably elevated at 1334 nmol/L (reference range: 140 to 690 nmol/L).

Furthermore, a low-dose dexamethasone suppression test was undertaken due to the high cortisol levels. Following the administration of 1 mg of dexamethasone at 10 p.m., cortisol levels were measured at 9 p.m., 3 a.m., and 9 a.m. the following day. The results unveiled a persistently elevated cortisol level surpassing 1655 nmol/L, signaling an abnormal response to dexamethasone suppression and raising concerns about a hypercortisolism disorder, such as CS.

In the intricate progression of this case, the investigation delved deeper with a 24-hour urinary free cortisol level, revealing a significant elevation at 521 mcg/day (reference range: 10 to 55 mcg/day). Subsequent testing of ACTH portrayed a markedly elevated level of 445 ng/L, distinctly exceeding the normal reference range of 7.2 to 63.3 ng/L. A high-dose 8 mg dexamethasone test was performed to ascertain the source of excess ACTH production. The baseline serum cortisol levels before the high-dose dexamethasone suppression test were 1404 nmol/L, which decreased to 612 nmol/L afterward, strongly suggesting the source of excess ACTH production to be in the pituitary gland.

A CT scan of the adrenal glands ruled out adrenal mass, while an MRI of the brain uncovered a 1.3×1.3×3.2 cm pituitary macroadenoma (Figure 3), leading to compression of adjacent structures. Neurosurgery was consulted, and they recommended surgical removal of the macroadenoma due to the tumor size and potential complications. The patient was referred to a tertiary care hospital for pituitary adenoma removal.

Magnetic-resonance-imaging-(MRI)-of-the-brain-depicting-a-1.3x1.3x3.2-cm-pituitary-macroadenoma-(star)
Figure 3: Magnetic resonance imaging (MRI) of the brain depicting a 1.3×1.3×3.2 cm pituitary macroadenoma (star)

Discussion

CS represents a complex endocrine disorder characterized by excessive cortisol production. While the classic presentation of CS includes weight gain, central obesity, and muscle weakness, our case highlights an uncommon initial manifestation: severe hypokalemia. This atypical presentation underscores the diverse clinical spectrum of CS and the challenges it poses in diagnosis and management [1,2].

While CS typically presents with the classic symptoms mentioned above, severe hypokalemia as the initial manifestation is exceedingly rare. Hypokalemia in CS often results from excess cortisol-mediated activation of mineralocorticoid receptors, leading to increased urinary potassium excretion and renal potassium wasting. Additionally, metabolic alkalosis secondary to cortisol excess further exacerbates hypokalemia [3,4].

Diagnosing a case of Cushing’s disease typically commences with a thorough examination of the patient’s medical history and a comprehensive physical assessment aimed at identifying characteristic manifestations such as central obesity, facial rounding, proximal muscle weakness, and increased susceptibility to bruising. Essential to confirming the diagnosis are laboratory examinations, which involve measuring cortisol levels through various tests, including 24-hour urinary free cortisol testing, late-night salivary cortisol testing, and dexamethasone suppression tests. Furthermore, assessing plasma ACTH levels aids in distinguishing between pituitary-dependent and non-pituitary causes of CS. Integral to the diagnostic process are imaging modalities such as MRI of the pituitary gland, which facilitate the visualization of adenomas and the determination of their size and precise location [1-4].

Treatment for Cushing’s disease primarily entails surgical removal of the pituitary adenoma via transsphenoidal surgery, with the aim of excising the tumor and restoring normal pituitary function. In cases where surgical intervention is unsuitable or unsuccessful, pharmacological therapies employing medications such as cabergoline (a dopamine receptor agonist) or pasireotide (a somatostatin analogue) may be considered to suppress ACTH secretion and regulate cortisol levels. Additionally, radiation therapy, whether conventional or stereotactic radiosurgery, serves as a supplementary or alternative treatment approach to reduce tumor dimensions and mitigate ACTH production [5,6]. To assess the effectiveness of treatment, manage any problem, and assure long-term illness remission, diligent long-term follow-up and monitoring are essential. Collaborative multidisciplinary care involving specialists such as endocrinologists, neurosurgeons, and other healthcare professionals is pivotal in optimizing patient outcomes and enhancing overall quality of life [2,4].

The prognosis of CS largely depends on the underlying cause, stage of the disease, and efficacy of treatment. Early recognition and prompt intervention are essential for improving outcomes and minimizing long-term complications. Surgical resection of the adrenal or pituitary tumor can lead to remission of CS in the majority of cases. However, recurrence rates vary depending on factors such as tumor size, invasiveness, and completeness of resection [2,3]. Long-term follow-up with endocrinologists is crucial for monitoring disease recurrence, assessing hormonal function, and managing comorbidities associated with CS.

Conclusions

In conclusion, our case report highlights the rarity of severe hypokalemia as the initial presentation of CS. This unique presentation underscores the diverse clinical manifestations of CS and emphasizes the diagnostic challenges encountered in clinical practice. A multidisciplinary approach involving endocrinologists, neurosurgeons, and radiologists is essential for the timely diagnosis and management of CS. Early recognition, prompt intervention, and long-term follow-up are essential for optimizing outcomes and improving the quality of life for patients with this endocrine disorder.

References

  1. Nieman LK, Biller BM, Findling JW, Newell-Price J, Savage MO, Stewart PM, Montori VM: The diagnosis of Cushing’s syndrome: an Endocrine Society Clinical Practice Guideline. J Clin Endocrinol Metab. 2008, 93:1526-40. 10.1210/jc.2008-0125
  2. Newell-Price J, Bertagna X, Grossman AB, Nieman LK: Cushing’s syndrome. Lancet. 2006, 367:1605-17. 10.1016/S0140-6736(06)68699-6
  3. Torpy DJ, Mullen N, Ilias I, Nieman LK: Association of hypertension and hypokalemia with Cushing’s syndrome caused by ectopic ACTH secretion: a series of 58 cases. Ann N Y Acad Sci. 2002, 970:134-44. 10.1111/j.1749-6632.2002.tb04419.x
  4. Elias C, Oliveira D, Silva MM, Lourenço P: Cushing’s syndrome behind hypokalemia and severe infection: a case report. Cureus. 2022, 14:e32486. 10.7759/cureus.32486
  5. Fleseriu M, Petersenn S: Medical therapy for Cushing’s disease: adrenal steroidogenesis inhibitors and glucocorticoid receptor blockers. Pituitary. 2015, 18:245-52. 10.1007/s11102-014-0627-0
  6. Pivonello R, De Leo M, Cozzolino A, Colao A: The treatment of Cushing’s disease. Endocr Rev. 2015, 36:385-486. 10.1210/er.2013-1048

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