Immunolocalisation of fibrillin microfibrils in the calf metacarpal and vertebral growth plate

Acromicric dysplasia due to a novel missense mutation in the fibrillin 1 gene in a three-generation family

OBJECTIVES

Short stature is one of the most common reasons for consulting a paediatric endocrinologist. Targeted diagnosis of familial short stature can be challenging due to a broad spectrum of differential diagnoses.

CASE PRESENTATION

Here we report a novel mutation in the fibrillin 1 gene (FBN1) in six family members causing a mild phenotype of acromicric dysplasia. Additionally, we present the effects of growth hormone therapy in one of the affected children.

CONCLUSIONS

Acromicric dysplasia is a very rare skeletal dysplasia with a prevalence of <1 of 1.000.000 with only about 60 cases being reported worldwide. It is characterized by short stature, acromelia, mild facial dysmorphy but normal intelligence. This study aims to exemplify the clinical and molecular features of FBN1-related acromicric dysplasia and illustrates its pleiotropy by presenting a new, mild phenotype.

Downregulation of growth plate genes involved with the onset of femoral head separation in young broilers

Femoral head separation (FHS) is characterized by the detachment of growth plate (GP) and articular cartilage, occurring in tibia and femur. However, the molecular mechanisms involved with this condition are not completely understood. Therefore, genes and biological processes (BP) involved with FHS were identified in 21-day-old broilers through RNA sequencing of the femoral GP. 13,487 genes were expressed in the chicken femoral head transcriptome of normal and FHS-affected broilers. From those, 34 were differentially expressed (DE; FDR ≤0.05) between groups, where all of them were downregulated in FHS-affected broilers. The main BP were enriched in receptor signaling pathways, ossification, bone mineralization and formation, skeletal morphogenesis, and vascularization. RNA-Seq datasets comparison of normal and FHS-affected broilers with 21, 35 and 42 days of age has shown three shared DE genes (FBN2, C1QTNF8, and XYLT1) in GP among ages. Twelve genes were exclusively DE at 21 days, where 10 have already been characterized (SHISA3, FNDC1, ANGPTL7, LEPR, ENSGALG00000049529, OXTR, ENSGALG00000045154, COL16A1, RASD2, BOC, GDF10, and THSD7B). Twelve SNPs were associated with FHS (p &lt; 0.0001). Out of those, 5 were novel and 7 were existing variants located in 7 genes (RARS, TFPI2, TTI1, MAP4K3, LINK54, and AREL1). We have shown that genes related to chondrogenesis and bone differentiation were downregulated in the GP of FHS-affected young broilers. Therefore, these findings evince that candidate genes pointed out in our study are probably related to the onset of FHS in broilers.

Acromicric dysplasia with stiff skin syndrome-like severe cutaneous presentation in an 8-year-old boy with a missense FBN1 mutation: Case report and literature review

Background

Acromicric dysplasia is a rare heritable short‐stature syndrome with joint stiffness and varying degrees of cutaneous hardness. Stiff skin syndrome is a rare connective tissue disorder characterized by diffusely thick and hard skin from the time of birth. Heterozygous point mutations in the FBN1 have been proposed as the predominant cause of both diseases.

Methods

By performing skin biopsy, X‐ray imaging, electrocardiography, as well as whole‐genome sequencing and Sanger sequencing, we diagnosed an 8‐year‐old Chinese boy as acromicric dysplasia with severe skin stiffness caused by a heterogeneous mutation in the FBN1.

Results

The patient presented with skin tightness, wrist and ankle stiffness, short stature and limbs, several deformed joints in the extremities, cone‐shaped epiphyses, and distinct facial features. He also had a patent foramen ovale and frequent respiratory infections. Skin biopsy showed thickened dermis and excessive collagen aggregation. Alcian blue staining indicated dermal mucopolysaccharide deposition. Mutation analysis revealed a heterozygous missense mutation, c.5243G>A (p.Cys1748Tyr), in exon 42 of the FBN1.

Conclusion

This is a report about acromicric dysplasia with stiff skin syndrome‐like severe cutaneous presentation caused by a single hotspot mutation, further revealing the gene pleiotropy of FBN1.

Identification of novel FBN1 variations implicated in congenital scoliosis

Congenital scoliosis (CS) is a form of scoliosis caused by congenital vertebral malformations. Genetic predisposition has been demonstrated in CS. We previously reported that TBX6 loss-of-function causes CS in a compound heterozygous model; however, this model can explain only 10% of CS. Many monogenic and polygenic CS genes remain to be elucidated. In this study, we analyzed exome sequencing (ES) data of 615 Chinese CS from the Deciphering Disorders Involving Scoliosis and COmorbidities (DISCO) project. Cosegregation studies for 103 familial CS identified a novel heterozygous nonsense variant, c.2649G>A (p.Trp883Ter) in FBN1. The association between FBN1 and CS was then analyzed by extracting FBN1 variants from ES data of 574 sporadic CS and 828 controls; 30 novel variants were identified and prioritized for further analyses. A mutational burden test showed that the deleterious FBN1 variants were significantly enriched in CS subjects (OR = 3.9, P = 0.03 by Fisher’s exact test). One missense variant, c.2613A>C (p.Leu871Phe) was recurrent in two unrelated CS subjects, and in vitro functional experiments for the variant suggest that FBN1 may contribute to CS by upregulating the transforming growth factor beta (TGF-β) signaling. Our study expanded the phenotypic spectrum of FBN1, and provided nove insights into the genetic etiology of CS.

Development of spinal deformities in the tight-skin mouse

Tight-skin (TSK) mice are commonly used as an animal model to study the pathogenesis of Marfan syndrome (MFS), but little is known of their skeletal phenotype and in particular of the development of the spinal deformities, common in MFS. Here we examined growth of the axial skeletons of TSK and wild-type(B6) mice during their period of rapid growth. The whole bodies of mice, 4–12 weeks of age, were scanned after sacrifice, by micro-computed tomography (microCT). We reconstructed three-dimensional models of the spine and ribs, and measured vertebral body heights and rib lengths using the Mac-based image-processing software “OsiriX”. Although the TSK mice were smaller than the B6 mice at 4 weeks, they experienced an early growth spurt and by 8 weeks the height, but not the width, of the vertebral body was significantly greater in the TSK mice than the B6 mice. Measurement of the angles of scoliotic and kyphotic curves post-mortem in the mice was problematic, hence we measured changes that develop in skeletal elements in these disorders. As a marker of kyphosis, we measured anterior wedging of the vertebral bodies; as a marker for scoliosis we measured asymmetries in rib length. We found, unlike in the B6 mice where the pattern was diffuse, wedging in TSK mice was directly related to spinal level and peaked steeply at the thoracolumbar junction. There was also significant asymmetry in length of the ribs in the TSK mice, but not in the B6 mice. The TSK mice thus appear to exhibit spinal deformities seen in MFS and could be a useful model for gaining understanding of the mechanisms of development of scoliosis and kyphosis in this disorder.

Three novel mutations of the FBN1 gene in Chinese children with acromelic dysplasia

Geleophysic dysplasia (GD), acromicric dysplasia (AD) and Weill-Marchesani syndrome (WMS) are rare disorders with overlapping characteristics, such as short stature, short hands and feet, joint limitations, skin thickening, mild facial anomalies, normal intelligence and abnormal skeletal symptoms, with GD distinct by progressive cardiac valvular thickening and WMS distinct by microspherophakia and ectopia lentis. Mutations in FBN1 gene have been identified in AD, GD and WMS patients. By targeted next-generation sequencing of skeletal dysplasia-related genes, including FBN1 and ADAMTSL2, three novel missense mutations, c.5189A>T (p.N1730I), c.5198G>T (p.C1733F), c.5243G>T (p.C1748F), and one known mutation c.5198G>A (p.C1733Y) of FBN1 gene were identified in four probands, respectively. Clinically, p.C1733Y was associated with GD, as reported previously, as well as the novel p.N1730I, whereas p.C1733F and p.C1748F were associated with AD and WMS. Interestingly, different mutations at the same codon (p.C1733Y and p.C1733F) were associated with different phenotypes (GD and AD, respectively). However, the mutations p.C1748F and p.C1748R were associated with WMS. Our data support the importance of TGFβ-binding protein-like domain 5 of FBN1 protein in pathogenicity of acromelic dysplasia, and expands the genotype/phenotype relations of these rare forms of fibrilliopathies.