Co-occurrence of genomic imbalances on Xp22.1 in the SHOX region and 15q25.2 in a girl with short stature, precocious puberty, urogenital malformations and bone anomalies
Mutations of SHOX represent the most frequent monogenic cause of short stature and related syndromes. The genetic alterations include point mutations and deletions/duplications spanning both SHOX and its regulatory regions, although microrearrangements are confined to either the downstream or upstream enhancers in many patients. Mutations in the heterozygous state have been identified in up to 60–80% of Leri-Weill Dyschondrosteosis (LWD; MIM #127300) and approximately 4–5% of Idiopathic Short Stature (ISS; MIM#300582) patients. Homozygous or compound heterozygous mutations as well as biallelic deletions of SHOX and/or the enhancer regions result in a more severe phenotype, which is known as Langer Mesomelic Dysplasia (LMD; MIM #249700).
A 17 year old girl, presented with severe short stature, growth hormone deficiency (GHD), precocious puberty, dorsal scoliosis, dysmorphisms and urogenital malformations. She was born with agenesis of the right tibia and fibula, as well as with a supernumerary digit on the left foot. Array comparative genomic hybridization (aCGH) analysis detected the presence of two distinct duplications on Xp22.1 flanking the SHOX coding sequence and involving its regulatory regions. An additional duplication of 1.6–2.5 Mb on 15q25.2 that included 13 genes was also identified. The girl was adopted and the parent’s DNA was not available to establish the origin of the chromosome imbalances.
The complex phenotype observed in our patient is probably the result of the co-occurrence of rearrangements on chromosomes Xp22.1 and 15q25.2. The duplicated region on 15q25.2 region is likely to contain dosage-sensitive genes responsible for some of the clinical features observed in this patient, whereas the extreme short stature and the skeletal anomalies are likely attributable to the comorbidity of GHD and copy number variants in the SHOX region.
KeywordsShort stature SHOX Enhancers CGH array
array Comparative Genomic Hybridization
Conserved Noncoding Elements
Copy Number Variations
Diamond-Blackfan anemia 4
Langer Mesomelic “Dysplasia”
Multiplex Ligation Probe Amplification
Pseudoautosomal Region 1
The presence of multiple independent genomic imbalances in the same patient might result in complex phenotypes due to either an additive or interactive effect of single rearrangements. Here, we report the case of a patient carrying two apparently distinct duplications on Xp22.1 that, involve the SHOX (Short Stature homeobox-containing gene, MIM *312865) region and a duplication on 15q25.2 that likely contributes to the the determination of her clinical features.
Molecular defects of SHOX, which is located on pseudoautosomal region 1 (PAR1), include intragenic mutations, complete or partial deletions/duplications of the coding sequence and/or the enhancer regions  that result in conditions that are generally characterized by mild to severe short stature. Haploinsufficiency of the SHOX gene can result in Lerì-Weill Dyschondrosteosis (LWD; MIM #127300) with disproportionate short stature, mesomelia and Madelung deformity of the wrist as well as tibial bowing. Loss of both copies of SHOX cause Langer mesomelic Dysplasia (LMD; MIM #249700), which is a condition with extreme short stature, severe shortening or aplasia of the ulna and fibula, as well as boththickening and curvature of the radius and tibia. SHOX mutations are also present in approximately 2–10% of Idiopathic Short Stature (ISS) patients, depending on which study cohort is considered .
Genomic rearrangements involving chromosome 15q25.2 constitute a rare finding. Nevertheless, there have been some reports of copy number variations (CNVs) within this region associated with recognizable phenotypes. In most cases, these mutations were represented by deletions, whereas 15q25.2 microduplications have been described in only three previous cases [3, 4] and a few patients who were reported on in the DECIPHER database (https://decipher.sanger.ac.uk/).
The patient was referred to our third-level Paediatric Endocrinology Unit when she was 9 years old for short stature and suspected precocious puberty. She was of Russian origin and was adopted at the age of 2 years. Limited data were available about her family and perinatal history. The biological mother was affected by insulin-dependent diabetes mellitus and arterial hypertension. Nothing was known about the biological father. No data were available about gestational age, neonatal weight and length as well as general conditions at birth. She was born with agenesis of the right tibia and fibula, and underwent mid-thigh amputation when she was 5 years old. She also presented a supernumerary digit of the left foot, which was excised when she was 8 years old.
Treatments with human recombinant GH and triptorelin were started to achieve the best growth gain. Triptorelin was able to block the puberty progression. At 14 years, triptorelin was withdrawn, and, at 15 years, menarche appeared. Her final height was 137.5 cm, which corresponds to <3rd percentile.
When she was 17 years old, she complained severe abdominal pain during a menses. A pelvic ultrasonography was performed revealing a picture of hematocolpos. The abdomen MR showed uterus didelphys with double vagina. Due to the presence of these uro-genital anomalies, arterial hypertension at a young age and the family history for insulin-dependent diabetes, molecular analyses of the HNF-1β gene was performed. No alteration was found in this gene.
The presence of the 15q25.2 duplication was confirmed through MLPA (Multiplex Ligation Probe Amplification) with a probe specifically designed within the CPEB1 gene. The 15q25.2 duplicated region was examined using the Human resource websites (https://www.ncbi.nlm.nih.gov/projects/genome/guide/human/) at NCBI and the Archive EnsEMBL (https://www.ensembl.org/info/website/archives/index.html). This region contains 13 genes, some of them with a known function (Additional file 1: Table S1). Three of these, namely RPS17, CPEB1 and HOMER, have been previously associated to well defined disorders albeit none of these is apparently related to the clinical features observed in our patient.
Unfortunately, the biological parents were not available to establish the origin of the duplications.
Discussion and conclusion
We found imbalances in the SHOX region and on 15q25.2 in a girl with short stature, precocious puberty, urogenital malformation and bone anomalies of the limbs.
The duplicated 15q25.2 region of 1.6–2.5 Mb includes 13 OMIM genes (Fig. 3 and Additional file 1: Table S1) among those, RPS17 and HOMER2 cause two Mendelian disorders, including Diamond-Blackfan Anemia 4 (DBA4) and autosomal dominant hearing loss, respectively. DBA4 is a recessive condition caused by biallelic loss of function mutations, whereas HOMER2 was found to be mutated only once in a family in which deafness co-segregated with a missense mutation . However, the effect of a duplications of these two genes remains unknown as well as its implication in the patient’s phenotype. Patients with similar duplications at 15q25.2 have rarely been reported in the literature [3, 4] and few cases are present in the DECIPHER database that present clinical features resembling those observed in our patient such as anomalies of the foot digits, hypertension, and a short neck (Fig. 1).
One of the genes included in the 15q25.2 duplicated region is CPEB1, and the deletion of CPEB1 is associated with premature ovarian insufficiency, which is characterized by primary amenorrhea . Conversely, we can speculate that CPEB1 duplication may account for the precocious puberty observed in our patient.
The extreme short stature might be the result of the co-occurrence of two independent causes: GHD and rearrangements in the SHOX region. Several patients with SHOX–deficiency related phenotypes have been described carrying duplications of either upstream or downstream conserved noncoding elements (CNEs) that function as enhancers of SHOX transcription. In the present patient, the aCGH identified two gains flanking SHOX, including all the upstream and downstream CNEs (Fig. 2) as well as a normal double dose of the SHOX coding sequence. However, aCGH did not allow us to establish if the two gains correspond to duplications lying in cis on the same chromosome affecting the expression of only one SHOX copy, or if there are two duplications carried in trans by the two different X-chromosomes. This latter situation should affect the expression of both copies of SHOX. Another possible explanation might be the presence of one uninterrupted duplication on one X-chromosome extending from 192,136 to 1453,835 on a length of 1262 Mb and a deletion of approximately193 Kb, including the SHOX coding sequence from 494,191 to 686,753 on the other X that compensates for the increased dose of SHOX. Additionally in this case, the patient would be compound heterozygous for two SHOX alterations. Homozygous or compound heterozygous defects of SHOX or its enhancer region cause Langer mesomelic “dysplasia” (LMD) (OMIM 249700), which is a rare recessive condition characterized by severe short stature, mesomelic and rhizomelic dysgenesis of the limbs involving hypoplasia or aplasia of the ulna and fibula. Our patients did not exhibit a typical LMD phenotype; however, in addition to the severe short stature, she was born with agenesis of the right tibia and fibula. Hypoplastic or absent proximal half of the fibula has been described among the principal clinical features of LMD , and it is thus conceivable that, in our patient, the expression of both SHOX alleles was altered.
In conclusion, the complex phenotype of our patient, including severe short stature and skeletal anomalies, was probably the result of rearrangements in the SHOX regulatory region exacerbated by GH deficiency. The duplication on 15q25.2 might have contributed to some of the clinical features through the action of unidentified dose-sensitive gene/s.
The Authors are grateful to the patient and her family.
No funding was secured for this study.
Availability of data and materials
The CGH custom array design will be available from the corresponding author upon request.
AM, GG, FP and SB clinically managed the patient. DB, SM, AF and MG performed the genetic analysis and interpreted the data. AM and MG drafted the initial manuscript, reviewed and revised the final manuscript. GG, FP and SB reviewed and revised the manuscript. All authors approved the final manuscript.
Ethics approval and consent to participate
The analysis on the here described patient (biochemical tests, hormonal tests, genetic analysis etc) have been performed for diagnostic puoposes and were done after obtaining the informed consent from the parent’s girl.
Consent for publication
We obtained a written consent for publication from the parent’s patient.
The authors declare that they have no competing interests
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
- 3.Wat MJ, Enciso VB, Wiszniewski W, Resnick T, Bader P, Roeder ER, Freedenberg D, Brown C, Stankiewicz P, Cheung SW, Scott DA. Recurrent microdeletions of 15q25.2 are associated with increased risk of congenital diaphragmatic hernia, cognitive deficits and possibly diamond--Blackfan anaemia. J Med Genet. 2010;47(11):777–81.CrossRefGoogle Scholar
- 6.Azaiez H, Decker AR, Booth KT, Simpson AC, Shearer AE, Huygen PL, Bu F, Hildebrand MS, Ranum PT, Shibata SB, Turner A, Zhang Y, Kimberling WJ, Cornell RA, Smith RJ. HOMER2, a stereociliary scaffolding protein, is essential for normal hearing in humans and mice. PLoS Genet. 2015;11(3):e1005137.CrossRefGoogle Scholar
Open AccessThis article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated.