The most 5′ truncating homozygous mutation of WNT1 in siblings with osteogenesis imperfecta with a variable degree of brain anomalies: a case report

Background WNT1 mutations cause bone fragility as well as brain anomalies. There are some reported cases of WNT1 mutations with normal cognition. Genotype and phenotype correlation of WNT1 mutations has not been established. Case presentation Here we present two female siblings with osteogenesis imperfecta (OI) born to a consanguineous couple. Both sustained severe bone deformities. However, only the younger had severe brain anomalies resulting in an early death from pneumonia, while the older had normal intellectual development. Next generation sequencing showed a homozygous mutation, c.6delG, p.Leu3Serfs*36 in WNT1. To our knowledge, it is the most 5′ truncating mutation to date. Conclusion This report emphasizes the intrafamilial variability of brain anomalies found in this OI type and suggests that WNT1 may not be necessary for normal human cognitive development.


Background
Osteogenesis imperfecta (OI) is a heritable connective tissue disease characterized by bone fragility and fracture susceptibility. More than 95% of OI have dominant mutations in COL1A1 or COL1A2, resulting in primary structural or quantitative defects of collagen type I. The recessive forms of OI are caused by mutations in CRTAP, BMP1, CREB3L1, IFITM5, FKBP10, LEPRE1, PPIB, SP7, PLOD2, TMEM38B, SERPINF, SERPINH1, SEC24D, SPARC, WNT1 [1], which lead to defects of proteins interacting with collagen post-translationally. Recently, an X-linked form caused by mutations in MBTPS2 was identified [2].
OI has been classified into several types according to clinical features and genetic alterations. Type XV OI, first described by Keupp in 2013, is caused by biallelic mutations in WNT1 [3]. So far, at least 30 cases have been reported. In addition to bone fragility, many of them had neurological abnormalities [4][5][6][7]. Defects in Wnts or related proteins could lead to derangements in axonal pathways, including commissural axon tracts such as the corpus callosum [8]. Monoallelic mutations in WNT1 cause early onset osteoporosis [9]. Genotype and phenotype correlation of WNT1 mutations is not yet determined, requiring a larger cohort of patients.
Here, we describe two siblings with OI. One of them had brain malformations and global developmental delay, while the other had normal cognition. Mutation analysis identified a homozygous frameshift mutation in WNT1, which is the most 5′ change reported to date.

Case presentation
A 14-year-old Thai girl was born via cesarean section due to premature rupture of the membrane with a birth weight of 2500 g. She is the first child of a consanguineous (second-degree relatives) couple. Both parents are healthy and have never had fractures. During her first year of life, she had delayed motor development and growth failure. At one year of age, she could not sit by herself and weighed 7.5 kg (< 3rd centile). She presented to our hospital at 14 months of age with fractures of both femora without a history of significant trauma. She was found to have ptosis of both eyes with normal teeth but no blue sclerae. She was small for her age. Her weight was 7.8 kg (3rd centile) and her length was 68 cm (< 3rd centile). Skeletal survey showed diffuse osteopenia, multiple healed fractures of the right humoral shaft, both tibiae and fibulae. Spine radiograph showed flattening and indentation of vertebral bodies (Fig. 1). A diagnosis of OI was made and intravenous bisphosphonate therapy (pamidronate 1 mg/kg/dose for 3 days) was initiated and given every 3 months. However, she sustained 1-2 long bone fractures per year from minor trauma. She required multiple corrective osteotomies to correct her deformities. At the last follow-up, she was 14 years old, weighing 20 kg. She could not walk due to her long bone deformity (Fig. 1). Remarkably, although she was in a special education class due to physical disabilities, her cognition was appropriate for age. She could talk fluently and do mathematics properly.
Prenatally, her younger sister was found to have a dilated fourth ventricle by an ultrasonography. She was born at term via cesarean section because of previous cesarean section and was diagnosed with hydrocephalus at birth. At 4 months of age, she had her first fracture without a history of a significant trauma, leading to a diagnosis of OI. Physical examination revealed a head circumference of 38 cm (> 95th centile) with a wide anterior fontanelle (3 × 3 cm.) and blue sclerae. She had global developmental delay (could not hold her head) and hypotonia. MRI of the brain demonstrated a large posterior fossa cyst connecting with the fourth ventricular system, moderate hydrocephalus, hypoplasia of cerebellar hemisphere with absence of cerebellar vermis, and hypoplasia of corpus collosum. She was also diagnosed with vesicoureteral reflux grade V and gastroesophageal reflux requiring tube feeding. The patient had multiple hospitalizations because of recurrent urinary tract infections and pneumonia. She expired at the age of one year.

Discussion and conclusions
To better understand the clinical manifestations and natural history of patients with type XV OI, more patients and long-term follow-up are needed. Here, we report two  Some other features of OI are inconsistent between our two patients. Blue sclerae were observed in only the younger sister, but not the proband. Previous reports found that blue sclerae could be observed in some cases with WNT1 mutations (Table 1). Consistent with previous studies, neither of our patients had dentinogenesis imperfecta. Notably, ptosis, one of the most common clinical presentations of OI patients with WNT1 mutations was only found in the proband. It is not usually found in other types of OI. Brain anomalies or intellectual disabilities were observed in 33% (9/27) of the previous reported cases (Table 1). Many patients have normal cognitive development. Remarkably, our proband had normal intellectual development, while her younger sister had severe brain anomalies, including hydrocephalus detected prenatally. This demonstrates a significant variability in neurological involvement between the affected siblings in this family and suggests that neurological abnormalities in WNT1 mutations might be subject to modifier genes, epigenetics or non-genetic factors. There are two other families in the literature with significantly different neurological manifestations among the family members; one affected sib had normal intelligence and the other had severe brain anomalies or delayed development [5,6]. Intrafamilial variable expression of this gene was substantiated.
Using Truseq Custom Amplicon sequencing, our proband was found to have an autosomal recessive form of OI caused by a homozygous truncating mutation in WNT1. Her sister's blood sample could not be obtained. With similar recurrent bone fractures, we assumed that she harbored Fig. 2 Reported mutations in WNT1 [3-7, 9, 11-15] (solid bars represent coding exons of WNT1) Fig. 3 Mutation analysis. Sanger sequencing shows that the proband is homozygous while his mother is heterozygous for the WNT1 c.6delG, p.Leu3Serfs*36 mutation the same homozygous mutation. WNT1 mutations were identified as a cause of malformations of midbrain and cerebellum in early brain development in mice long before it was identified as a cause of OI in humans [10]. In 2014, Swaying (Wnt1 sw/sw ) mice carrying WNT1 mutations were found to have OI phenotypes including bone fragility and severe osteopenia [4]. The first report of a patient with a WNT1 mutation was in 2013 [3]. As far as we know, the mutation identified in our patient is the first reported mutation in exon 1 and is the most 5′ truncating mutation (Fig. 2). The out-of-frame G deletion at the starting codon of WNT1 is expected to result in a nonsense-mediated mRNA decay (NMD). There are no in-frame methionines after the frameshifting variant, so there would not be the possibility of another in-frame start site.
The genotype and phenotype correlation of WNT1 mutations has not been established. The homozygous mutation found in our proband, which is a frameshift starting from the second codon, is expected to lead to a nonfunctional WNT1. She had normal cognition at the age of 14 years, indicating that humans without functional WNT1 could be intellectually normal. In summary, we report two siblings with an autosomal recessive OI caused by the most 5′ homozygous mutation in WNT1. The findings exemplify intrafamilial variability in the neurological phenotype and suggest that WNT1 may not be necessary for normal human cognitive development.