Abstract
After 6 years of Growth Hormone (GH) therapy, three patients with a defect in minor spliceosome mRNA processing leading to an incompletely understood GH deficit present with excellent auxological response and improvement in the bone mineral density and trabecular bone structure.
Subject Categories: Development & Differentiation; Genetics, Gene Therapy & Genetic Disease; Pharmacology & Drug Discovery
Background
The etiology of GHD remains unknown in most cases (Alatzoglou et al, 2009). RNPC3 mutations emerged as a novel cause of familial isolated GHD and pituitary hypoplasia (Argente et al, 2014). RNPC3 encodes a 65‐kDa protein that is a structural component of the U11/U12 small nuclear ribonucleoprotein of the minor spliceosome (Verma et al, 2018). Mutations in RNPC3 lead to structural destabilization of the 65‐kDa protein, impaired binding of U12 snRNA, and global defects in splicing of U12‐type introns (Argente et al, 2014; Norppa et al, 2018).
We describe the effects of rhGH therapy on growth, body composition, bone mineral density (BMD), and bone microarchitecture in the first three patients identified with this condition.
Subjects and methods
Written informed consent was obtained from all subjects and their parents for all studies and their publication. Studies conformed to the principles set out in the WMA Declaration of Helsinki and the Department of Health and Human Services Belmont Report.
Three sisters were born to non‐consanguineous average‐height [target: 155.6 (−0.99 SDS)] Romanian parents. The father is a heterozygous carrier of a nonsense mutation (c.1504C>T, p.R502X), and the mother and only unaffected daughter are heterozygous for a missense mutation in RNPC3 (c.1320C>A, p.P474T). The three affected girls, compound heterozygous for both mutations, were born at term with normal length and weight, developing severe postnatal growth failure, typical phenotypic features of GHD, and delayed bone age (BA; Table 1 and Fig 1). They were referred to our clinic at 15.5, 8.1, and 6.0 years of age with extremely short stature (Table 1), undetectable serum IGF‐1, IGFBP‐3 and GH after stimuli (insulin and clonidine), and no clinical or hormonal signs of associated pituitary hormone deficiencies. Anterior pituitary hypoplasia was found in MRI.
Table 1.
Anthropometric data at baseline and after rhGH therapy onset
| Chronological age (bone age) | Height (SDS) | Growth velocity (SDS) | DXA (baseline) | DXA2 | DXA3 | DXA4 | ||
|---|---|---|---|---|---|---|---|---|
| Patient 1 | ||||||||
| Baseline | 15.5 (12.0) | 125.5 (−5.9) | — | Weight (kg) | 36.7 | 36.8 | 35.9 | 61.3 |
| 1st year | 16.5 (13.0) | 137.8 (−4.2) | 12.8 (+31.0) | BMI (kg/m2) | 23.3 | 20.75 | 20.91 | 27.1 |
| 2nd year | 17.5 (14.0) | 143.8 (−3.1) | 6.0 (+21.0) | BMD (g/cm2) | 0.6440 | 0.733 | 0.781 | 1,050 |
| 3rd year | 18.5 (14.0) | 146.4 (−2.6) | 2.6 (+14.4) | BMD (Z‐score) | −3.7 | −2.7 | −2.2 | 0.4 |
| 4th year | 19.5 | 148.8 (−2.2) | 2.3 (+12.5) | TBS | 1,270 | 1,280 | 1,400 | N.A. |
| Patient 2 | ||||||||
| Baseline | 8.1 (6.5) | 100.4 (−5.0) | — | Weight (kg) | 17.5 | 18.5 | 20.2 | 50.4 |
| 1st year | 9.0 (7.5) | 114.0 (−3.2) | 14.2 (+11.4) | BMI (kg/m2) | 17.4 | 15.75 | 14.76 | 20.81 |
| 2nd year | 10.0 (9.0) | 125.1 (−2.0) | 11.1 (+5.5) | BMD (g/cm2) | 0.478 | 0.515 | 0.523 | 0.825 |
| 3rd year | 11.1 (10.5) | 133.2 (−1.5) | 8.2 (+1.4) | BMD (Z‐score) | −1.3 | −0.7 | −1.0 | −1.0 |
| 4th year | 12.0 (11.3) | 138.5 (−1.6) | 5.7 (−1.2) | TBS | 1,260 | 1,270 | 1,360 | N.A. |
| 5th year | 13.0 (12.5) | 146.2 (−1.2) | 7.8 (+2.8) | |||||
| 6 year & 6 month | 14.5 (13.5) | 152.9 (−0.7) | 5.0 (+1.2) | |||||
| Patient 3 | ||||||||
| Baseline | 6.0 (3.5) | 84.5 (−6.7) | — | Weight (kg) | 9.8 | 11.5 | 12.7 | 36 |
| 1st year | 7.0 (5.0) | 98.5 (−4.4) | 14.6 (+9.3) | BMI (kg/m2) | 13.7 | 15.77 | 14.76 | 18.90 |
| 2nd year | 8.0 (6.5) | 106.9 (−3.6) | 8.4 (+3.7) | BMD (g/cm2) | 0.397 | 0.446 | 0.470 | 0.678 |
| 3rd year | 9.0 (7.5) | 114.2 (−3.2) | 7.4 (+1.1) | BMD (Z‐score) | −2.2 | −1.4 | −1.0 | −1.1 |
| 4th year | 10.0 (8.8) | 119.3 (−2.9) | 5.4 (+0.5) | TBS | 1,260 | 1,270 | 1,360 | N.A. |
| 5th year | 10.9 (10.0) | 126.4 (−2.5) | 7.1 (+1.3) | |||||
| 6 year & 6 month | 12.3 (11.3) | 137.5 (−1.9) | 7.4 (+0.5) | |||||
SDS, standard deviation score. Bone mineral density (BMD) and trabecular bone structure (TBS) in DXA (dual‐energy absorptiometry analysis) in the three patients before (baseline) and after 6 months (DXA2), 1 year (DXA3), and 6.5 years (DXA4) of rhGH therapy onset (patient 1 received 4.5 years of treatment, and patients 2 and 3 remain on treatment). All of the DXA data refer to lumbar spine (L1–L4) (N.A., not available).
Figure 1. Growth charts of the three sisters after GH therapy.
Facial appearance at baseline and growth charts of patients 1 (A), 2 (B), and 3 (C). Blue circles represent height for chronological age, whereas yellow triangles represent height for bone age. BA, bone age; CA, chronological age; GH, start of recombinant growth hormone treatment; TH, target height. Faces of the patients reproduced with permission. (D) Changes in body fat content and distribution showing the lipolytic effect of recombinant human growth hormone treatment in patient 1 after 6 and 12 months of therapy from baseline. Reproduced with permission.
Daily subcutaneous rhGH (0.025–0.035 mg/kg/day) was prescribed, with regular clinical, laboratory, and BA (Greulich & Pyle) evaluations.
Lumbar spine BMD (LS‐BMD) and body fat percentage were measured using dual‐energy X‐ray absorptiometry (DXA Discovery Wi, software version 13.3; Hologic, Inc., Waltham, MA, USA) before and 6 months, 1, and 6.5 years after rhGH therapy onset (coefficient of variation 0.70). Data for BMD were adjusted by height‐for‐age Z‐score (Zemel et al, 2010).
Trabecular bone structure (TBS) was calculated from the same DXA acquisition used for LS‐BMD (TBS iNsight software, v3.0; Medimaps, France). In children, there is no international consensus of what constitutes a normal or abnormal TBS. In adults, TBS ≥ 1,350 is proposed to be normal, values between 1,200 and 1,350 are consistent with partially degraded bone, and TBS ≤ 1,200 indicates degraded bone (Silva et al, 2014).
Results
Growth, puberty, and biochemical evolution
Patient 1
At age 15.5 years, she was 125.5 cm (−5.9 SDS) with proportional short stature, evident central adiposity, typical facial features of GHD (Fig 1A), no signs of pubertal development (Tanner stage I), and retarded skeletal maturation (3.5 years below chronological age). On rhGH therapy, growth increased drastically, particularly during the first 2 years [growth velocity (GV) 12.8 and 6.0 cm/year, for ages 16.5 and 17.5, respectively], achieving a height of 150.3 cm at age 20 (after 4.5 years on therapy; Fig 1A).
Puberty started spontaneously shortly after starting rhGH, with menarche at age 16. However, she had oligomenorrhea, with sparse menstrual bleedings despite pubertal FSH/LH and estradiol levels and a pubertal shaped uterus with endometrium present at ultrasonography (data not shown).
Patient 2
At treatment onset, she was 8.1 years and 100.4 cm (−5.0 SDS), with no signs of pubertal development (BA: 6.5 years) and phenotypic features of GHD (Fig 1B). She responded intensely to rhGH, especially during the first 2 years (+14.2 and +11.1 cm/year, respectively; Table 1). At her last visit (age 14.5 years), she was 152.9 cm (−0.7 SDS), close to her target height (155.6 ± 5 cm). She started puberty (Tanner stage II) spontaneously at age 9.75 years, progressing to Tanner stage IV, but without menarche up to her last visit.
Patient 3
She was 6 years old (BA 3.5 years) and 84.5 cm (−6.7 SDS) at the onset of rhGH (Fig 1C). Her GV also increased dramatically during the first 2 years on treatment (+14.6 and +8.4 cm/year, respectively; Table 1). She reached the 3rd centile in height at age 12.3 years, remaining prepubertal and with BA retarded 1 year, with a 4.9 height‐SDS increase after 6.5 years on treatment.
Patients 1 and 2 normalized serum IGFBP‐3 after 1 month of rhGH and IGF‐I after 6 months. In the youngest sister, IGF‐I and IGFBP‐3 did not reach reference ranges until 1 year on rhGH, remaining normal up to 4.5 years of therapy. In all patients, there was a 6‐month period during the fourth year of therapy when GV, IGF‐1, and IGFBP‐3 levels decreased (Table 1 and Fig 1) due to lack of treatment adherence.
The three siblings exhibited mild hypercholesterolemia (positive paternal family history) before therapy that did not change significantly during treatment.
Body composition
The first year of rhGH therapy improved LS‐BMD and normalized TBS in all patients (Table 1). BMD Z‐score remained unchanged after the 1‐year DXA in patients 2 and 3, but fully normalized in patient 1. An intense lipolytic effect of rhGH treatment was observed in patient 1 during her first year on therapy, decreasing body fat from 44.1% (+2.9 SDS) to 27.2% (+0.1 SDS) (Fig 1).
Discussion
In all three patients with GHD due to mutations in RNPC3, rhGH treatment was highly effective despite the severity of their short stature and considering that therapy was started after age 15 in the eldest. The improvement in height SDS after 4.5 (for the eldest) to 6.5 years on rhGH was between 4.0 and 4.9 SDS, with the two younger siblings continuing to grow. This change in height SDS is higher than the average response to rhGH in patients with isolated GHD (Darendelier et al, 2011 and Argente et al, 2014), but similar when compared with severe isolated GHD (Ranke & Lindberg, 2010 and Argente et al, 2014). This effect was maximum in patient 3, probably because rhGH was started at a younger age and her baseline height was more severely compromised (Ranke & Lindberg, 2010). However, the eldest sister increased her height in 24.8 cm despite her advanced chronological (15.5) and bone age (12 years) at therapy onset, with growth progressing even after menarche, achieving a 21.4‐cm pubertal growth spurt. However, this late onset of treatment might have compromised her adult height (−0.9 SDS below target height), which is below that expected for her siblings with their height centile close (patient 3) or above (patient 2) their target and still growing on therapy.
The improvements in BMD and TBS during the first year on therapy indicate that the GH‐induced rise in IGF‐I is fundamental for improving bone development, as we recently reported in patients with PAPP‐A2 deficiency (Hawkins‐Carranza et al, 2018). Follow‐up of the two younger sisters is required to determine whether BMD and TBS completely normalize and to investigate an eventual relationship between RNPC3 mutations and possible impairment of the GnRH axis as suggested by the pubertal and menstrual evolution in patients 1 and 2.
The extremely positive response to exogenous GH treatment suggests that the required receptors and downstream signaling molecules are intact. Indeed, these patients showed almost undetectable GH levels after standard stimuli and basal IGF‐I, IGFBP‐3, and ALS levels suggesting that the lack of pituitary GH secretion is the underlying cause for their growth failure. Moreover, their lack of antibody production in response to this treatment further indicates an intact GH1 gene. The data and the pituitary hypoplasia observed in these patients highly suggest that the minor spliceosome plays a crucial role in the processing of genes required for somatotroph development and GH synthesis.
The positive family history of hypercholesterolemia and lack of improvement during rhGH replacement (even when the lipolytic effect of rhGH was highly evident) suggest that this finding is most likely independent from GHD.
In summary, despite the fact that the underlying mechanism by which the RNPC3 mutations result in GHD is not completely understood, rhGH dramatically increased growth in three girls with severe isolated GH deficiency due to a defective minor spliceosome mRNA processing, determining a significant improvement in BMD, microarchitecture of the bone, and body composition.
Conflict of interest
The authors declare that they have no conflict of interest.
For more information
Publicly available 1,000 genomes (http://www.1000genomes.org) and 6,503 samples from exome variant server (http://www.gs.washington.edu/evs); and U12 database (U12DB, http://genome.crg.es/datasets/u12).
Acknowledgements
JA was funded by the Spanish Ministry of Health (FIS‐PI13/02195 & PI16/00485, co‐funded by FEDER), Centro de Investigación Biomédica en Red for obesity and nutrition (CIBEROBN) from Instituto de Salud Carlos III, Spain, and the Fundación de Endocrinología y Nutrición. LAPJ was funded by the Spanish Ministry of Health (FIS‐PI1302481, co‐funded by FEDER), the Generalitat de Catalunya (2014SRG1468), the Institució Catalana de Recerca i Estudis Avançats (ICREA Academia Program), Centro de Investigación Biomédica en Red for rare diseases (CIBERER) from Instituto de Salud Carlos III, Spain, and the Spanish Ministry of Economy and Competiveness “Programa de Excelencia María de Maeztu” (MDM‐2014‐0370).
EMBO Mol Med (2018) 10: e9143 29866761
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