Unusual Endocrinopathies in 18q Deletion Syndrome: Pseudoparathyroidism and Hyper-/Hypo-Thyroidism
Journal: 2021/June - Clinical Case Reports
Abstract:
Objective: To describe new and unusual endocrinopathies in children with de novo 18q deletion (18q-) syndrome.
Methods: We describe 2 patients who have atypical thyroid conditions and 1 who also developed symptomatic hypocalcemia.
Results: The first patient developed hyperthyroidism at the age of 3 years, with a free thyroxine level of 3.9 (range, 0.8-1.8) ng/dL. Thyroid peroxidase antibodies were 262 (range, 0-32) IU/mL, and thyroid-stimulating immunoglobulin antibodies were 384% (range, 0-139%). On low-dose methimazole treatment, she developed hypothyroidism. Thyroid-stimulating hormone (TSH) level was 163 (range, 0.4-4.5) mIU/mL. Moreover, she later developed growth hormone deficiency. The second patient developed hypothyroidism at the age of 4 years, with a TSH level of 46 mIU/mL. However, TSH remained elevated at levels of 10 to 24 mIU/mL for 3 years, despite appropriate treatment, suggesting TSH resistance. She then developed hypocalcemic seizures and was diagnosed with pseudohypoparathyroidism. Her total calcium level was 6.6 (range, 8.5-10.5) mg/dL and parathyroid hormone level was 432 (range, 15-65) pg/dL.
Conclusion: The first patient had a mixed picture of autoimmune hypothyroidism and hyperthyroidism, requiring a combination of methimazole and levothyroxine to achieve a euthyroid state. For the second patient, the mild TSH resistance was possibly the early suggestion of a parathyroid hormone resistant state. Although growth hormone deficiency and hypothyroidism are common in patients with 18q- syndrome, the occurrence of hyperthyroidism due to Graves' disease with the coexistence of Hashimoto's hypothyroidism is rare. Pseudohypoparathyroidism has not yet been reported in patients with 18q- syndrome.
Keywords: 18q-, 18q deletion; MTZ, methimazole; PHP, pseudohypoparathyroidism; PTH, parathyroid hormone; TPO, thyroid peroxidase; TSH, thyroid-stimulating hormone; TSI, thyroid-stimulating immunoglobulin; genetics; growth disorder; parathyroid diseases; pediatrics; thyroid diseases.
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Unusual Endocrinopathies in 18q Deletion Syndrome: Pseudoparathyroidism and Hyper-/Hypo-Thyroidism

Abstract

Objective

To describe new and unusual endocrinopathies in children with de novo 18q deletion (18q-) syndrome.

Methods

We describe 2 patients who have atypical thyroid conditions and 1 who also developed symptomatic hypocalcemia.

Results

The first patient developed hyperthyroidism at the age of 3 years, with a free thyroxine level of 3.9 (range, 0.8-1.8) ng/dL. Thyroid peroxidase antibodies were 262 (range, 0-32) IU/mL, and thyroid-stimulating immunoglobulin antibodies were 384% (range, 0-139%). On low-dose methimazole treatment, she developed hypothyroidism. Thyroid-stimulating hormone (TSH) level was 163 (range, 0.4-4.5) mIU/mL. Moreover, she later developed growth hormone deficiency. The second patient developed hypothyroidism at the age of 4 years, with a TSH level of 46 mIU/mL. However, TSH remained elevated at levels of 10 to 24 mIU/mL for 3 years, despite appropriate treatment, suggesting TSH resistance. She then developed hypocalcemic seizures and was diagnosed with pseudohypoparathyroidism. Her total calcium level was 6.6 (range, 8.5-10.5) mg/dL and parathyroid hormone level was 432 (range, 15-65) pg/dL.

Conclusion

The first patient had a mixed picture of autoimmune hypothyroidism and hyperthyroidism, requiring a combination of methimazole and levothyroxine to achieve a euthyroid state. For the second patient, the mild TSH resistance was possibly the early suggestion of a parathyroid hormone resistant state. Although growth hormone deficiency and hypothyroidism are common in patients with 18q- syndrome, the occurrence of hyperthyroidism due to Graves’ disease with the coexistence of Hashimoto’s hypothyroidism is rare. Pseudohypoparathyroidism has not yet been reported in patients with 18q- syndrome.

Key words: genetics, growth disorder, parathyroid diseases, pediatrics, thyroid diseases
Abbreviations: 18q-, 18q deletion; MTZ, methimazole; PTH, parathyroid hormone; PHP, pseudohypoparathyroidism; TPO, thyroid peroxidase; TSI, thyroid-stimulating immunoglobulin; TSH, thyroid-stimulating hormone

Introduction

18q deletion (18q-) syndrome is the second most common anomaly involving chromosome 18, with Trisomy 18 being the most common anomaly. The main features of 18q- syndrome are cleft palate, hearing loss, nystagmus, brachydactyly, hypotonia, cardiac anomalies, short stature, and multiple organ system involvement. Growth hormone deficiency and hypothyroidism with this condition have been well-documented.1 We report 2 patients with autoimmune thyroid disorders; 1 with a mixed autoimmune thyroid disease picture, with an evidence of both Hashimoto’s thyroiditis alternating with Graves’ disease, and the other with a persistently elevated thyroid-stimulating hormone (TSH) despite treatment for hypothyroidism. The first patient also had growth hormone deficiency, and the second patient developed pseudohypoparathyroidism (PHP). A brief review of the literature about endocrine dysfunction with this condition is discussed.

Patient 1

A 3.7-year-old female presented with excessive sweating, irritability, jitteriness, weight loss, and insomnia. The child was born at 28 weeks of gestation with multiple dysmorphic features, including cleft palate, nystagmus, and generalized hypotonia. She was diagnosed with 18q- syndrome during the neonatal period.

On physical examination, the child was restless. Both weight and height were less than the third percentile for age. Pulse rate was high at 140 beats/min. Findings included generalized hypotonia, nystagmus, widely spaced eyes, repaired cleft palate, and flattened nasal bridge. She had a goiter but no exophthalmos.

Laboratory findings showed hyperthyroidism, with a high free thyroxine and a low TSH. Both thyroid peroxidase (TPO) antibodies and thyroid-stimulating immunoglobulin (TSI) antibodies were positive, indicating both Hashimoto’s and Graves’ disease, respectively (Table 1). She was started on low-dose beta blockers and the lowest recommended dose of methimazole (MTZ), which is 2.5 mg, three times a day. Within 3 months, she became severely hypothyroid, and MTZ was discontinued. However, hyperthyroidism returned 4 months later, and MTZ was restarted at a much lower dose of 2.5 mg once daily. After 5 months on this therapy, she again developed hypothyroidism. Meanwhile, both TSI and TPO continued to remain high. From our previous experience, we decided to use the block and replace strategy with low-dose MTZ and levothyroxine (Table 1). Her thyroid function has remained normal on this regimen, and both antibodies have stayed positive. Additionally, growth rate continued to decline, and at approximately 5 years of age, she was diagnosed with growth hormone deficiency (Table 2). She started the recommended dose of growth hormone (0.04 mg/kg/d). She then developed joint swelling, puffy face, edema of the dorsum of the hands and feet, and generalized itching. She stopped taking the growth hormone for a month and was then restarted with a different brand at half of the previous dose. She did well without any untoward reaction, with a normal growth rate, and a noticeable improvement of her muscle tone. Growth hormone therapy did not require any titration of thyroid medications.

Table 1

Thyroid Profile of Patient 1

Age (y)Free thyroxine (0.8-1.8 ng/dL)Thyroid-stimulating hormone (0.4-4.5 mIU/mL)Thyroid-stimulating immunoglobulin (<139%)Thyroid peroxidase antibodies (<32 IU/mL)Treatment
3.73.9<0.007384%262Methimazole 2.5 mg three times a day
4.00.2163Methimazole stopped
4.32.40.04464%486Restart methimazole 2.5 mg daily
4.40.618299%>600Methimazole 2.5 mg daily and add levothyroxine 12.5 μg daily
5.11.22.1291%484Continue same dose
6.01.571.76278%578Continue same dose

Table 2

Growth Hormone Profile of Patient 1

Age (y)Insulin growth factor-1 (50-179 ng/mL)Insulin growth factor-binding protein-3 (1.8-5.2 mg/L)Growth hormone response to clonidine stimulation (≥10 ng/mL)Growth hormone response to arginine stimulation (≥10 ng/mL)
5552.15.478.0

Patient 2

A 4.6-year-old female was referred for an elevated TSH level with a low free thyroxine level. This child was born at 29 weeks of gestation and developed cerebral palsy, seizures, and hypotonia. She was diagnosed with 18q- syndrome during the neonatal period.

On physical examination, the height was less than the third percentile for age but the weight was at the 95 percentile for age. She had generalized hypotonia and small goiter.

Laboratory evaluation showed a low free thyroxine level with a significantly elevated TSH. TPO and antithyroglobulin antibodies were positive but TSI was negative (Table 3). Insulin growth factor-1, adrenocorticotropic hormone, cortisol, and bone age x-ray were all normal. The patient was started on levothyroxine, which promptly normalized her free thyroxine levels; however, her TSH remained elevated. Higher levothyroxine doses resulted in elevated thyroid hormone levels with hyperthyroid symptoms, yet TSH remained high, outside the reference range (Table 3). Hyperthyroid symptoms that our patient experienced were tachycardia even when resting, insomnia, diaphoresis, diarrhea, and increased appetite. Once her dose was decreased, even though the TSH remained high, all of the symptoms resolved. At 7 years of age, she developed tetany and seizures. The laboratory evaluation revealed severe hypocalcemia with high phosphorus, low 25-hydroxy vitamin D, and inappropriately low 1,25-hydroxy vitamin D levels with a very high parathyroid hormone (PTH) level (Table 4). She was diagnosed with pseudohypoparathyroidism. She was started on calcium carbonate, at a dose of 1.2 g of elemental calcium (40 mg/kg/d) in 3 divided doses and calcitriol 0.25 μg twice a day, which normalized her calcium levels. Her current dose has been decreased to calcium carbonateat a dose of 500 mg elemental calcium twice a day and calcitriol 0.25 μg once daily.

Table 3

Thyroid Profile of Patient 2

Age (y)Free thyroxine (0.93-1.8 ng/dL)Thyroid-stimulating hormone (0.4-4.5 mIU/mL)Thyroid peroxidase antibodies (<32 IU/mL)Antithyroglobulin antibodies (<10 IU/mL)Levothyroxine dose
40.8465221
51.32475 μg daily
61.911100 μg daily
72.11038<10125 μg daily

Table 4

Calcium Profile of Patient 2

Age (y)Total calcium (8.5-10.5 mg/dL)Ionized calcium (1.2-1.45 mmol/L)Phosphorus (2.5-4.9 mg/dL)Parathyroid hormone (15-65 pg/dL)25-hydroxy vitamin D (30-80 ng/dL)1,25-hydroxy vitamin D (20-60 pg/μL)
76.60.766.84322418

Patient 1

A 3.7-year-old female presented with excessive sweating, irritability, jitteriness, weight loss, and insomnia. The child was born at 28 weeks of gestation with multiple dysmorphic features, including cleft palate, nystagmus, and generalized hypotonia. She was diagnosed with 18q- syndrome during the neonatal period.

On physical examination, the child was restless. Both weight and height were less than the third percentile for age. Pulse rate was high at 140 beats/min. Findings included generalized hypotonia, nystagmus, widely spaced eyes, repaired cleft palate, and flattened nasal bridge. She had a goiter but no exophthalmos.

Laboratory findings showed hyperthyroidism, with a high free thyroxine and a low TSH. Both thyroid peroxidase (TPO) antibodies and thyroid-stimulating immunoglobulin (TSI) antibodies were positive, indicating both Hashimoto’s and Graves’ disease, respectively (Table 1). She was started on low-dose beta blockers and the lowest recommended dose of methimazole (MTZ), which is 2.5 mg, three times a day. Within 3 months, she became severely hypothyroid, and MTZ was discontinued. However, hyperthyroidism returned 4 months later, and MTZ was restarted at a much lower dose of 2.5 mg once daily. After 5 months on this therapy, she again developed hypothyroidism. Meanwhile, both TSI and TPO continued to remain high. From our previous experience, we decided to use the block and replace strategy with low-dose MTZ and levothyroxine (Table 1). Her thyroid function has remained normal on this regimen, and both antibodies have stayed positive. Additionally, growth rate continued to decline, and at approximately 5 years of age, she was diagnosed with growth hormone deficiency (Table 2). She started the recommended dose of growth hormone (0.04 mg/kg/d). She then developed joint swelling, puffy face, edema of the dorsum of the hands and feet, and generalized itching. She stopped taking the growth hormone for a month and was then restarted with a different brand at half of the previous dose. She did well without any untoward reaction, with a normal growth rate, and a noticeable improvement of her muscle tone. Growth hormone therapy did not require any titration of thyroid medications.

Table 1

Thyroid Profile of Patient 1

Age (y)Free thyroxine (0.8-1.8 ng/dL)Thyroid-stimulating hormone (0.4-4.5 mIU/mL)Thyroid-stimulating immunoglobulin (<139%)Thyroid peroxidase antibodies (<32 IU/mL)Treatment
3.73.9<0.007384%262Methimazole 2.5 mg three times a day
4.00.2163Methimazole stopped
4.32.40.04464%486Restart methimazole 2.5 mg daily
4.40.618299%>600Methimazole 2.5 mg daily and add levothyroxine 12.5 μg daily
5.11.22.1291%484Continue same dose
6.01.571.76278%578Continue same dose

Table 2

Growth Hormone Profile of Patient 1

Age (y)Insulin growth factor-1 (50-179 ng/mL)Insulin growth factor-binding protein-3 (1.8-5.2 mg/L)Growth hormone response to clonidine stimulation (≥10 ng/mL)Growth hormone response to arginine stimulation (≥10 ng/mL)
5552.15.478.0

Patient 2

A 4.6-year-old female was referred for an elevated TSH level with a low free thyroxine level. This child was born at 29 weeks of gestation and developed cerebral palsy, seizures, and hypotonia. She was diagnosed with 18q- syndrome during the neonatal period.

On physical examination, the height was less than the third percentile for age but the weight was at the 95 percentile for age. She had generalized hypotonia and small goiter.

Laboratory evaluation showed a low free thyroxine level with a significantly elevated TSH. TPO and antithyroglobulin antibodies were positive but TSI was negative (Table 3). Insulin growth factor-1, adrenocorticotropic hormone, cortisol, and bone age x-ray were all normal. The patient was started on levothyroxine, which promptly normalized her free thyroxine levels; however, her TSH remained elevated. Higher levothyroxine doses resulted in elevated thyroid hormone levels with hyperthyroid symptoms, yet TSH remained high, outside the reference range (Table 3). Hyperthyroid symptoms that our patient experienced were tachycardia even when resting, insomnia, diaphoresis, diarrhea, and increased appetite. Once her dose was decreased, even though the TSH remained high, all of the symptoms resolved. At 7 years of age, she developed tetany and seizures. The laboratory evaluation revealed severe hypocalcemia with high phosphorus, low 25-hydroxy vitamin D, and inappropriately low 1,25-hydroxy vitamin D levels with a very high parathyroid hormone (PTH) level (Table 4). She was diagnosed with pseudohypoparathyroidism. She was started on calcium carbonate, at a dose of 1.2 g of elemental calcium (40 mg/kg/d) in 3 divided doses and calcitriol 0.25 μg twice a day, which normalized her calcium levels. Her current dose has been decreased to calcium carbonateat a dose of 500 mg elemental calcium twice a day and calcitriol 0.25 μg once daily.

Table 3

Thyroid Profile of Patient 2

Age (y)Free thyroxine (0.93-1.8 ng/dL)Thyroid-stimulating hormone (0.4-4.5 mIU/mL)Thyroid peroxidase antibodies (<32 IU/mL)Antithyroglobulin antibodies (<10 IU/mL)Levothyroxine dose
40.8465221
51.32475 μg daily
61.911100 μg daily
72.11038<10125 μg daily

Table 4

Calcium Profile of Patient 2

Age (y)Total calcium (8.5-10.5 mg/dL)Ionized calcium (1.2-1.45 mmol/L)Phosphorus (2.5-4.9 mg/dL)Parathyroid hormone (15-65 pg/dL)25-hydroxy vitamin D (30-80 ng/dL)1,25-hydroxy vitamin D (20-60 pg/μL)
76.60.766.84322418

Discussion

Chromosome 18q deletion syndromes are survivable autosomal deletions, with an estimated incidence of 1:40 000 live births.2 Of the approximately 100 babies born in the U.S. per year with this condition, about 80% of cases are denovo mutations, 10% of cases are parental translocations, and 10% are mosaic with a less severe phenotype.12 Women appear to be more affected by the syndrome than men, with a ratio of 3:2.2 The most common distal deletions start at band 21, 22, or 23 and usually go to the end of the chromosome.3 It is important to remember no 2 people with distal q deletion are exactly alike. The severity of the phenotype is correlated not only with the size of the deletion but also with the location of the deletion on the chromosome.4 Both of our patients had de novo mutations, but we were unable to evaluate the exact location on the chromosome since the records are no longer available.

Several children with this condition also have poor growth and are found to have growth hormone deficiency.4 A total of 72% of these children with poor growth failed the growth hormone stimulation test. Most responded well with the growth hormone therapy in terms of growth and the improvement of muscle tone.45 Our first patient was treated with growth hormone therapy and developed generalized edema and itching. The etiology remains unclear, although it may be related to a preservative in the brand of the medication since changing the brand and lowering the dose solved the problem.

Most thyroid conditions associated with 18q- syndrome are from Hashimoto’s hypothyroidism, with an estimated incidence of about 12%.67 Hyperthyroidism from Graves’ disease is very rare in this population; there is 1 case report with Graves’ disease,8 1 with Graves’ disease and Type 1 diabetes,9 and 1 with Graves’ disease who presented with Ebstein Anomaly and Wolf Parkinson White Syndrome.10

Our first patient was found to have a mixed picture of both autoimmune Hashimoto’s thyroiditis and Graves’ disease, requiring a combination of MTZ and levothyroxine daily. Bhowmick et al11 reported 3 cases of Down syndrome with a similar presentation, who had Graves’ disease with very high TSI and TPO, suggesting the coexistence of Hashimoto’s thyroiditis with Graves’ disease. Those patients were successfully managed with a combination of antithyroid medication and levothyroxine. This combination was continued until TSI decreased to a negative range. All patients eventually developed hypothyroidism, although it took years before that was achieved.11 Our first patient was managed with this same approach and achieved a euthyroid state.

Our second patient was treated for autoimmune hypothyroidism, but had a persistently elevated TSH. She then developed PHP, which has not been previously reported in the literature with this condition. PHP is caused by heterozygous inactivating mutations affecting GNAS, the gene encoding the alfa chain of the stimulatory G protein, which couples receptors for several hormones.12 Retrospectively, the persistent TSH elevation in this patient may have been associated with PTH resistance,13 as both TSH and PTH are stimulatory G-protein-coupled stimulating hormones. TSH resistance may have been an early finding of resistance to the stimulatory G-protein-coupled hormones.

There are several distinct entities of PHP: Types 1a, 1b, and 1c, and Type 2. Patients with Type 1a frequently present with the classical features of Albright’s hereditary osteodystrophy and a multiple-hormone resistant state. Our patient most likely had Type 1b, characterized by late-onset symptoms, no clinical features of Albright’s, and the hormone resistance appeared to be limited to the renal action of PTH along with TSH resistance. In Type 1b, hormone resistance is less common and is typically TSH resistance.14 We believe that our patient did not have any other hormone resistance disorders as she had normal growth hormone and cortisol tests. She is prepubertal at this point, but her gonadotropins and pubertal development will be closely monitored to make sure that she does not develop gonadotropin resistance.

In summary, we present 2 cases of rarely reported endocrine dysfunction in patients with 18q- syndrome. The routine determination of TPO with TSI antibodies in patients presenting with thyroid dysfunctions may reveal the combination of mixed hypothyroidism with hyperthyroidism and help to decide the therapy. The second patient with a persistently elevated TSH developed PHP. Therefore, evaluating the calcium levels in patients with TSH resistance is suggested. These 2 cases illustrate that children with 18q- syndrome can develop other unusual endocrine problems outside of growth hormone deficiency and hypothyroidism; a high index of suspicion is warranted.

Disclosure

The authors have no multiplicity of interest to disclose.

Department of Pediatric Endocrinology, University of South Alabama, Mobile, Alabama
Anne Marie D. Kaulfers: ude.amabalahtuos.htlaeh@srefluaka
Address correspondence and reprint requests to Dr. Anne Marie D. Kaulfers, Department of Pediatric Endocrinology, University of South Alabama, 1601 Center Street, Suite 1S, Strada Center Pediatrics, Mobile, AL 36604. ude.amabalahtuos.htlaeh@srefluaka
This is an open access article under the CC BY license (http://creativecommons.org/licenses/by/4.0/).

References

  • 1. Cody J.D., Ghidoni P.D., DuPont B.RCongenital anomalies and anthropometry of 42 individuals with deletions of chromosome 18q. Am J Med Genet. 1999;85(5):455–462.[PubMed][Google Scholar]
  • 2. Brkanac Z., Cody J.D., Leach R.J., DuPont B.RIdentification of cryptic rearrangements in patients with 18q- deletion syndrome. Am J Hum Genet. 1998;62(6):1500–1506.[Google Scholar]
  • 3. Kline A.D., White M.E., Wapner RMolecular analysis of the 18q- syndrome--and correlation with phenotype. Am J Hum Genet. 1993;52(5):895–906.[Google Scholar]
  • 4. Hale D.E., Cody J.D., Baillargeon J., Schaub R., Danney M.M., Leach R.JThe spectrum of growth abnormalities in children with 18q deletions. J Clin Endocrinol Metab. 2000;85(12):4450–4454.[PubMed][Google Scholar]
  • 5. Ghidoni P.D., Hale D.E., Cody J.DGrowth hormone deficiency associated in the 18q deletion syndrome. Am J Med Genet. 1997;69(1):7–12.[PubMed][Google Scholar]
  • 6. Schaub R.L., Hale D.E., Rose S.R., Leach R.J., Cody J.DThe spectrum of thyroid abnormalities in individuals with 18q deletions. J Clin Endocrinol Metab. 2005;90(4):2259–2263.[PubMed][Google Scholar]
  • 7. Vaidya B., Kendall-Taylor P., Pearce S.HThe genetics of autoimmune thyroid disease. J Clin Endocrinol Metab. 2002;87(12):5385–5397.[PubMed][Google Scholar]
  • 8. Tutunculer F., Darendeliler F., Gunoz H., Karaman B., Kayserili H18q deletion syndrome associated with autoimmune thyroid disease presenting as hyperthyroidism. J Pediatr Endocrinol Metab. 2005;18(4):419–420.[PubMed][Google Scholar]
  • 9. Nishimura Y., Kosaka K., Kizaki ZAnomaly of chromosome 18 complicated with diabetes mellitus and hyperthyroidism. Pediatr Int. 1999;41(2):177–180.[PubMed][Google Scholar]
  • 10. van Trier D.C., Feenstra I., Bot P., de Leeuw N., Draaisma J.MCardiac anomalies in individuals with the 18q deletion syndrome; report of a child with Ebstein anomaly and review of the literature. Eur J Med Genet. 2013;56(8):426–431.[PubMed][Google Scholar]
  • 11. Bhowmick S.K., Grubb P.HManagement of multiple-antibody-mediated hyperthyroidism in children with Down’s syndrome. South Med J. 1997;90(3):312–315.[PubMed][Google Scholar]
  • 12. Germain-Lee E.LManagement of pseudohypoparathyroidism. Curr Opin Pediatr. 2019;31(4):537–549.[Google Scholar]
  • 13. Weinstein L.S., Liu J., Sakamoto A., Xie T., Chen MMinireview: GNAS: normal and abnormal functions. Endocrinology. 2004;145(12):5459–5464.[PubMed][Google Scholar]
  • 14. Liu J., Erlichman B., Weinstein L.SThe stimulatory G protein alpha-subunit Gs alpha is imprinted in human thyroid glands: implications for thyroid function in pseudohypoparathyroidism types 1A and 1B. J Clin Endocrinol Metab. 2003;88(9):4336–4341.[PubMed][Google Scholar]
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