Case Report: Neonatal Cholestasis as Early Manifestation of Primary Adrenal Insufficiency

Neonatal cholestasis (NC) may be due to multiple surgical and non-surgical causes, some of which are potentially fatal. The list of potential causes of NC is long, and the systematic search for each of them is challenging in infants, especially when overt signs of underlying disease are lacking. Endocrinological diseases as causes of NC are rare and sometimes misdiagnosed. We report the case of an infant with prolonged cholestatic jaundice due to adrenal insufficiency suspected because of a single episode of hypoglycemia occurring at birth in the absence of clinical signs of adrenal impairment. Clinical exome analysis identified a new homozygous variant in MC2R gene as a putative responsible for familial glucocorticoid deficiency (FGD). Adrenal insufficiency should always be considered in all cholestatic infants, even in the absence of specific symptoms, since early recognition and treatment is essential to prevent life-threatening events.

Severe Posaconazole-Induced Glucocorticoid Deficiency with Concurrent Pseudohyperaldosteronism: An Unfortunate Two-for-One Special

A 56-year-old Hispanic man with a history of disseminated coccidioidomycosis was diagnosed with persistent glucocorticoid insufficiency and pseudohyperaldosteronism secondary to posaconazole toxicity. This case was notable for unexpected laboratory findings of both pseudohyperaldosteronism and severe glucocorticoid deficiency due to posaconazole’s mechanism of action on the adrenal steroid synthesis pathway. Transitioning to fluconazole and starting hydrocortisone resolved the hypokalemia but not his glucocorticoid deficiency. This case highlights the importance of recognizing iatrogenic glucocorticoid deficiency with azole antifungal agents and potential long term sequalae.

A rare and preventable aetiology of neurodevelopmental delay and epilepsy: familial glucocorticoid deficiency

Objectives Familial glucocorticoid deficiency (FGD) is a rare autosomal recessive disorder characterised by isolated glucocorticoid deficiency. Melanocortin receptor 2 (MC2R) mediates the functions of adrenocorticotropic hormone (ACTH) in the adrenal cortex. MC2R accessory protein (MRAP) is a transmembrane protein involved in the trafficking of MC2R to the cell surface. Mutations in MC2R and MRAP genes cause FGD type 1 and 2. In the present case series, we evaluate the clinical characteristics and long-term follow-up of six cases with FGD due to mutations in MC2R and MRAP. Case presentation Data of six cases with FGD (five with mutations in MC2R and one with a mutation in MRAP) who were being followed at our paediatric endocrine centre was evaluated. Diagnosis of FGD was considered in case of elevated ACTH and inappropriately low cortisol level, and exclusion of other aetiologies. The main presenting complaints were hyperpigmentation and hypoglycaemic convulsion in all cases. During a follow-up period of 26–115 months, one patient with homozygous 560delT mutation in MC2R, one female with G226R mutation in MC2R and one female with IVS3ds+1delG mutation in MRAP had a neurodevelopmental delay (NDD), while the other three patients had normal neurodevelopment. Conclusions FGD patients due to MC2R and MRAP mutations with early diagnosis and compliance to the hydrocortisone therapy had normal neurodevelopment, while delay in diagnosis and poor compliance was associated with severe hypoglycaemic convulsions and subsequent complications NDD.

Unmasking of Neurosarcoidosis

Introduction: Central diabetes insipidus is a rare complication of neurosarcoidosis. In patients with concomitant adrenal insufficiency (AI), the symptoms of Diabetes Insipidus (DI) can be masked. Case: A 55-year-old female with past medical history of sarcoidosis presented to the hospital with hematemesis, nausea and dizziness. She has a past medical history of cardiac sarcoidosis that was revealed on a PET scan done before 10 years for which she was being treated with methotrexate and prednisone. She was off prednisone for a year prior to hospitalization. She underwent an upper endoscopy that showed diffusely erythematous gastric mucosa in the antrum. She was also hypotensive on admission, and she received packed red blood transfusions after which her sodium increased from 145mmol/L to 165mmol/L (Normal: 135-145mmol/L) in 48 hours. Further workup revealed persistent hypernatremia and urine osmolality was 75mOsm/kg H2O. (Normal: 50-1200mOsm/kg H2O). She was also hypoglycemic and hypotensive requiring multiple fluid boluses throughout her hospitalization. This prompted us to perform a random cortisol that came back at 2.1ug/dl (Normal: 3-23ug/dl) and 1.8ug/dl on two occasions. Cortisol Stimulation test was subsequently ordered, but was done only at 30 minutes, and Cortisol increased from 1.8ug/dl to 6.3ug/dl. Free thyroxine was 0.5 ng/dl (Normal: 0.9-1.8 ng/dl) and her TSH was 7.58uIU/ml (Normal: 0.55-4.78uIU/ml). MRI of the brain revealed extensive areas of extra-axial supra-sellar/infundibular nodular homogeneous intense enhancement that is most consistent with neuro-sarcoid. She was started on prednisone 40 mg daily, Desmopressin 0.05 mg twice daily, and levothyroxine as well. Her sodium level normalized and was 137mmol/L at discharge. She followed up later with outpatient Endocrinology and reported around 90lbs weight gain and no more episodes of nausea or vomiting or epistaxis or lightheadedness. Conclusion: The involvement of the hypothalamic-pituitary axis in sarcoidosis is extremely rare and attributes to < 1% of patients with a sellar mass. Small case series have shown that hypogonadism is the most common endocrine abnormality followed by DI. Our patient had a long-standing history of sarcoidosis with her pituitary dysfunction unmasked only on admission for other causes. She did not manifest any symptoms of DI or AI. There have been case reports where the symptoms of DI are masked due to underlying glucocorticoid deficiency. There have been theories that glucocorticoid deficiency impairs renal water excretion by both ADH (Anti-diuretic hormone) dependent and ADH independent pathways. Another notable feature in our case is that our patient presented with primary hypothyroidism. In fact, sarcoidosis has been commonly implicated in auto-immune polyglandular syndromes type 3, which can present with auto-immune thyroiditis more so in females.

Concurrent Pseudohyperaldosteronism and Primary Glucocorticoid Deficiency From Posaconazole

Background: Posaconazole can cause pseudohyperaldosteronism via inhibition of 11-beta hydroxylase and 11-beta-hydroxysteroid dehydrogenase type 2 (1). The accumulation of 11-deoxycorticosterone and increased cortisol-to-cortisone ratio in the kidney causes apparent mineralocorticoid excess. The effect of posaconazole on the glucocorticoid axis is less established. Clinical Case: A 56-year-old Hispanic man with a history of chronic septic arthritis of the left ankle from Coccidioides presented with 3 months of malaise, nausea, weight loss of 30 pounds, and recurrent hypokalemia. He was recently switched from long-term fluconazole therapy to posaconazole around the time his symptoms began. His initial labs at our hospital were notable for low potassium (2.9 mmol/L, nl 3.5–5.5 mmol/L) and a random cortisol of 5.8 mcg/dL (nl ≥2.0 mcg/dL). A Cosyntropin stimulation test revealed elevated ACTH (168 pg/mL, nl 7.2–63.3 pg/mL) with minimal rise of cortisol from 4.6 to 7.2 mcg/dL at 1 hour after Cosyntropin administration (nl ≥18 mcg/dL at 1-hour post-Cosyntropin). His plasma renin activity was below detection (<0.6 ng/ml/h, nl 0.6–3.0 ng/mL/h), consistent with renin suppression from apparent mineralocorticoid excess. Hydrocortisone for glucocorticoid deficiency was started. A posaconazole determination indicated elevation (5240 ng/mL, usual therapeutic range ≥1000 ng/mL). His posaconazole was stopped, and he was switched back to fluconazole. Three months later, his symptoms were improved with regain of lost weight. Repeat Cosyntropin stimulation test showed ongoing primary glucocorticoid deficiency (ACTH 123 pg/mL, cortisol 4.1 mcg/dL at 1-hour post-Cosyntropin) but normal levels of plasma renin activity (1.2 ng/mL/h), aldosterone (8.6 ng/dL, nl ≤21 ng/dL), and potassium. Quantiferon TB and 21-hydroxylase antibody tests were negative. Hydrocortisone has been continued with plans to repeat Cosyntropin testing in 3 months to reassess. Conclusion: Pseudohyperaldosteronism with glucocorticoid deficiency requiring hydrocortisone treatment has thus far not been reported with posaconazole. Our case shows that posaconazole may lead to true primary glucocorticoid deficiency that can persist after discontinuation of posaconazole and reversal of pseudohyperaldosteronism. Reference: (1) Sanchez-Niño MD, Ortiz A. Unravelling drug-induced hypertension: Molecular mechanisms of aldosterone-independent mineralocorticoid receptor activation by posaconazole. Clin Kidney J 2018;11(5):688–90.

PTH-Independent Hypercalcemia in Undiagnosed Adrenal Insufficiency

In contrast to PTH-dependent hypercalcemia, the differential diagnosis of PTH-independent hypercalcemia is extensive. Thorough history and physical examination can help direct the clinician in the right direction and avoid extensive and unnecessary work up. A 27-year-old-female with a medical history significant only for untreated subclinical hypothyroidism was admitted to the hospital for hypercalcemia and acute kidney injury after presenting with dizziness, nausea, vomiting, dyspnea, and multiple syncopal episodes prior to admission. Serum calcium on presentation was elevated to 15.9 (8.5–10.2 mg/dL) with an intact parathyroid hormone level of 3.6 (8.5–75 pg/mL). On initial presentation, she was hypotensive, tachycardic, and was noted to be underweight with a body mass index of 17 kg/m2. The patient’s skin was diffusely hyperpigmented, with increased pigmentation in the creases of her hands and on the sides of her fingers. Further lab evaluation was remarkable for hyponatremia and hyperkalemia as well as an undetectable 8 AM cortisol of <1.0 (7–25 µg/dL), adrenocorticotropic hormone (ACTH) level significantly elevated to >1,250 (6–58 pg/mL), aldosterone <4 (<21 ng/dL), and plasma renin activity elevated to 18 (<0.6–3 ng/mL/h). Antibodies to 21-alpha hydroxylase were positive, confirming a diagnosis of Addison’s disease. Prior to the workup confirming an elevated ACTH and low cortisol levels, the patient was treated with aggressive intravenous fluid repletion and calcitonin with overnight improvement in calcium to 11.4 mg/dL. After the diagnosis of primary adrenal insufficiency was confirmed, she was treated with stress doses of intravenous hydrocortisone then gradually tapered to physiologic doses of oral hydrocortisone and fludrocortisone with resolution of her hypercalcemia by the fourth day of hospitalization. Adrenal insufficiency is a known but uncommon cause of PTH-independent hypercalcemia, but the exact mechanism is unknown. Hypercalcemia is thought to result from a combination of a hypovolemic state seen in adrenal insufficiency which leads to decreased urinary calcium excretion as well as increased bone resorption, which may result from increased serum sclerostin concentrations. Adrenal insufficiency should be considered in the differential of PTH-independent hypercalcemia. This case highlights the improvement in hypercalcemia that is seen with correction of glucocorticoid deficiency, and supports delaying additional work up for other PTH-independent causes until appropriate treatment has been given.

In Vitro Splicing Assay Proves the Pathogenicity of Intronic Variants in MRAP

Introduction: Familial glucocorticoid deficiency (FGD) is characterised by isolated glucocorticoid deficiency in a patient who retains normal mineralocorticoid production. FGD causing mutations in the MC2R accessory protein, MRAP, are often splice-site or nonsense mutations resulting in a truncated protein. Many of these mutations occur at the canonical donor splice-site of intron 3, where it has been shown previously that c.106 + 2_3dupTA, for example, results in skipping of the first coding exon with unknown consequences at the protein level. Patients and methods: DNA was isolated from three consanguineous individuals diagnosed with early onset FGD (0 - 13 months) with high ACTH and/or low cortisol levels and underwent whole exome sequencing. The proband in family 1 (P1) presented at 13 months and had a hyperpigmented sibling who died in neonatal period due to adrenal failure. Patient 2 (P2), who also had a family history of adrenal insufficiency, was noted to be hyperpigmented at birth with markedly raised ACTH, patient 3 (P3) was noted to have diffuse hyperpigmentation in the early neonatal period and on formal testing at 16m was found to have low serum cortisol. Variants were confirmed using Sanger sequencing and predicted splice-site mutations were investigated using an in vitro splicing assay. Results: Homozygous mutations in MRAP were identified in all three cases which were heterozygous in their parents. Previously described mutations, c.106 + 1delG (chr21:33671388delG; rs1476574441; CD050155) in P1 and c.106 + 2dupT (Chr21: 33671390_91insT; rs761576317; CI118288) in P2 at the canonical donor splice-site of intron 3, were identified, with the former predicted to destroy the splice site and the latter to weaken it. These mutations in vitro resulted in the complete skipping of exon 3, which contains the translational start site, and presumably result in no protein product. A novel homozygous mutation in intron 4, c.206 + 5G>T; (chr21:33679055G>T rs1064796398) was identified in P3, but was not predicted to alter splicing. In vitro, this mutation negates the canonical donor splice site and creates two different alternative sites, both resulting in frameshifts and predicted early termination of the protein (p.Val44fs*50, p.Pro72fs*90). Conclusion: All mutations reported here are predicted to produce no protein, either because the start site is excluded (for c.106 + 1delG and c.106 + 2dupT) or because the transcripts are likely to undergo nonsense mediated decay (for c.206 + 5G>T), resulting in the early onset FGD seen in the patients. Splice prediction protocols, although effective for variants within 2bp of exon/intron boundaries may not predict the true outcome of a base change whereas the splice assay conclusively revealed the effect of all three variants allowing us to assign pathogenicity to them.

A Rare Case of Resistant Pigmentation

Introduction: Familial glucocorticoid deficiency (FGD) is characterised by ACTH resistance & isolated glucocorticoid deficiency, with typical biochemical findings of low serum cortisol & high plasma ACTH. Patients present with hyperpigmentation (due to stimulation of MC1R by POMC products) & hypoglycemia. Clinical presentation includes failure to thrive & susceptibility to infections. Case Report: A 14 year old girl presented to us with generalised hyperpigmentation of the skin and oral mucosa- it started when she was 4 years of age. There was history of recurrent respiratory infections around the same time the hyperpigmentation appeared - the patient required multiple hospitalisations for the same (she was admitted 3 times in 6 months). Her random serum cortisol was measured – it came out to be 8.27nmol/L. Her serum Na+ was 140 mEq/L & K+ was 3.5 mEq/L. She was also diagnosed with subclinical hypothyroidism at that time (TSH- 7.3 mIU/L, anti TPO antibodies positive). There was no history of alacrimia or achalasia. Her 17-OHP was 2.20 nmol/L. A probable diagnosis of autoimmune polyendocrine syndrome was made & oral hydrocortisone (@ 12 mg/m2) & levothyroxine (@25 mcg) was started. The patient was compliant with the treatment, but the mother complained that her hyperpigmentation improved only by 20–30 % despite continued treatment. There was no history of salt wasting crises or hospitalisations after the initiation of treatment. Her serum ACTH values were checked 2 times (2011 & 2015) and were > 2000 pg/ml on both the occasions. The hydrocortisone dose was increased to 20mg/m2 for 1 year in between, without any improvement in hyperpigmentation. Patient presented to us with persistent hyperpigmentation in 2019. She was a product of consanguineous marriage. Non-compliance was ruled out. She had attained menarche at the age of 12 years. There was history of delayed pubarche (started @ age of 13 years) & axillary hair was absent. Again, her serum ACTH was > 2000 pg/ml and electrolytes and BP were normal. In view of normal electrolytes with low cortisol at the time of diagnosis & persistent hyperpigmentation even on supraphysiological doses of hydrocortisone, Familial Glucocorticoid Deficiency was considered. Genetic analysis showed mutation in Thioredoxin Reductase (TXNRD2) Gene. This gene mutation has recently been reported in FGD. (Prasad R et al, JCEM Aug 2014.) Conclusion: In cases of primary adrenal insufficiency with normal electrolytes & resistant hyperpigmentation, familial glucocorticoid deficiency should be thought of. Treatment with standard glucocorticoid therapy should be given. Serum ACTH values should not be chased. The hyperpigmentation may not resolve completely. TXNRD2 deficiency leads to impaired redox homeostasis, highlights the important redox pathway in addition to defective ACTH signaling, giving us new insights in regard to steroidogenesis.

Sphingosine 1- Phosphate Lyase Insufficiency Syndrome (SPLIS); A Role in Multiple Endocrinopathies

Sphingosine 1-phosphate lyase insufficiency syndrome (SPLIS) was described in 2017 as a novel condition affecting sphingolipid metabolism. There is a multisystemic phenotype including nephrotic syndrome and primary adrenal insufficiency (PAI) and to a lesser extent ichthyosis, neurological disease and lymphopenia. A proportion of patients also presented with hypothyroidism and hypogonadism. To interrogate the endocrine aspect of the syndrome we reviewed clinical data within our patient cohort with SPLIS and those within the wider literature. To date there have been 45 patients identified with SPLIS with significant associated mortality (n=23/45, 51%; 4 of these in utero). There is no clear genotype-phenotype correlation. Whilst nephrotic syndrome is most prevalent (n=34/45; 76%), a significant proportion of patients (n=27/45, 60%) also presented with glucocorticoid deficiency, some with additional mineralocorticoid deficiency (n=7/27). Five further patients were noted to have adrenal calcifications though biochemistry was not undertaken. Most patients presented with PAI in the first 2 years of life (n=21/27), with the oldest presentation being 11 years of age. Adrenal calcifications are a common finding in those who had documented imaging (n=13/15, 87%). Primary gonadal failure has been reported in 8 male cases, all with concomitant PAI. Presenting features included microphallus (n=7/8) and cryptorchidism (n=8/8), indicating reduced in utero androgen exposure. All who had biochemical evaluation demonstrated raised basal LH and FSH/ exaggerated response to LHRH stimulation, a lack of testosterone response to HCG stimulation and low antimullerian hormone (AMH) levels. To date there are no reports of pubertal delay in female patients, and those of age within our cohort have normal ovarian reserve as evidenced by AMH levels (n=2). Primary hypothyroidism, with mildly raised TSH and low Free T4 is reported in 12 patients. Most did not have goiters and had concomitant PAI and nephrotic syndrome (n=11/12). SPLIS is unique amongst sphingolipid disorders in presenting with significant endocrinopathy. This may be the consequence of the particular sphingolipid signature of the disease and the pathogenic mechanisms need to be explored further. It is clear that endocrine dysfunction needs to be considered at diagnosis and surveillance undertaken to detect evolving disease which could have a significant impact on morbidity and mortality.

Current Insights Into Adrenal Insufficiency in the Newborn and Young Infant

Adrenal insufficiency (AI) is a potentially life-threatening condition that can be difficult to diagnose, especially if it is not considered as a potential cause of a child's clinical presentation or unexpected deterioration. Children who present with AI in early life can have signs of glucocorticoid deficiency (hyperpigmentation, hypoglycemia, prolonged jaundice, poor weight gain), mineralocorticoid deficiency (hypotension, salt loss, collapse), adrenal androgen excess (atypical genitalia), or associated features linked to a specific underlying condition. Here, we provide an overview of causes of childhood AI, with a focus on genetic conditions that present in the first few months of life. Reaching a specific diagnosis can have lifelong implications for focusing management in an individual, and for counseling the family about inheritance and the risk of recurrence.