James C. Hyland

De novo ACTA2 mutation causes a novel syndrome of multisystemic smooth muscle dysfunction

Smooth muscle cells (SMCs) contract to perform many physiological functions, including regulation of blood flow and pressure in arteries, contraction of the pupils, peristalsis of the gut, and voiding of the bladder. SMC lineage in these organs is characterized by cellular expression of the SMC isoform of α‐actin, encoded by the ACTA2 gene. We report here on a unique and de novo mutation in ACTA2, R179H, that causes a syndrome characterized by dysfunction of SMCs throughout the body, leading to aortic and cerebrovascular disease, fixed dilated pupils, hypotonic bladder, malrotation, and hypoperistalsis of the gut and pulmonary hypertension.

A loss of function mutation in the COL9A2 gene causes autosomal recessive Stickler syndrome.

Stickler syndrome is characterized by ocular, auditory, skeletal, and orofacial abnormalities. We describe a family with autosomal recessive Stickler syndrome. The main clinical findings consisted of high myopia, vitreoretinal degeneration, retinal detachment, hearing loss, and short stature. Affected family members were found to have a homozygous loss‐of‐function mutation in COL9A2, c.843_c.846 + 4del8. A family with autosomal recessive Stickler syndrome was previously described and found to have a homozygous loss‐of‐function mutation in COL9A1. COL9A1, COL9A2, and COL9A3 code for collagen IX. All three collagen IX α chains, α1, α2, and α3, are needed for formation of functional collagen IX molecule. In dogs, two causative loci have been identified in autosomal recessive oculoskeletal dysplasia. This dysplasia resembles Stickler syndrome. Recently, homozygous loss‐of‐function mutations in COL9A2 and COL9A3 were found to co‐segregate with the loci. Together the data from the present study and the previous studies suggest that loss‐of‐function mutations in any of the collagen IX genes can cause autosomal recessive Stickler syndrome.

Aortic Disease Presentation and Outcome Associated with ACTA2 Mutations

Background—ACTA2 mutations are the major cause of familial thoracic aortic aneurysms and dissections. We sought to characterize these aortic diseases in a large case series of individuals with ACTA2 mutations. Methods and Results—Aortic disease, management, and outcome associated with the first aortic event (aortic dissection or aneurysm repair) were abstracted from the medical records of 277 individuals with 41 various ACTA2 mutations. Aortic events occurred in 48% of these individuals, with the vast majority presenting with thoracic aortic dissections (88%) associated with 25% mortality. Type A dissections were more common than type B dissections (54% versus 21%), but the median age of onset of type B dissections was significantly younger than type A dissections (27 years versus 36 years). Only 12% of aortic events were repair of ascending aortic aneurysms, which variably involved the aortic root, ascending aorta, and aortic arch. Overall, cumulative risk of an aortic event at age 85 years was 0.76 (95% confidence interval, 0.64–0.86). After adjustment for intrafamilial correlation, sex and race, mutations disrupting p.R179 and p.R258 were associated with significantly increased risk for aortic events, whereas p.R185Q and p.R118Q mutations showed significantly lower risk of aortic events compared with other mutations. Conclusions—ACTA2 mutations are associated with high risk of presentation with an acute aortic dissection. The lifetime risk for an aortic event is only 76%, suggesting that additional environmental or genetic factors play a role in expression of aortic disease in individuals with ACTA2 mutations.

Ectopia lentis as the presenting and primary feature in Marfan syndrome.

Marfan syndrome (MFS) is a multisystem connective tissue disorder with primary involvement of the ocular, cardiovascular, and skeletal systems. We report on eight patients, all presenting initially with bilateral ectopia lentis (EL) during early childhood. These individuals did not have systemic manifestations of MFS, and did not fulfill the revised Ghent diagnostic criteria. However, all patients had demonstratable, disease‐causing missense mutations in the FBN1 gene. Based on molecular results, cardiovascular imaging was recommended and led to the identification of mild aortic root changes in seven of the eight patients. The remaining patient had mitral valve prolapse with a normal appearing thoracic aorta. The findings presented in this paper validate the necessity of FBN1 gene testing in all individuals presenting with isolated EL. As we observed, these individuals are at increased risk of cardiovascular complications. Furthermore, we also noted that the majority of our patient cohorts mutations occurred in the 5′ portion of the FBN1 gene, and were found to affect highly conserved cysteine residues, which may indicate a possible genotype–phenotype correlation. We conclude that in patients with isolated features of EL, FBN1 mutation analysis is necessary to aid in providing prompt diagnosis, and to identify patients at risk for potentially life‐threatening complications. Additionally, knowledge of the type and location of an FBN1 mutation may be useful in providing further clinical correlation regarding phenotypic progression and appropriate medical management.

COL2A1-related skeletal dysplasias with predominant metaphyseal involvement

Skeletal dysplasias induced by mutations in the collagen 2 gene (the so‐called “type 2 collagenopathies”) form a wide spectrum in severity and are distinguished by subtle clinical and radiographic differential signs. The unifying features are predominant involvement of the vertebral bodies and the epiphyses of the long bones (“spondylo‐epiphyseal” pattern). A mild degree of metaphyseal dysplasia can be seen in the so‐called Strudwick variant of spondyloepimetaphyseal dysplasia and is generally mild or absent in other forms.

Similarity of geleophysic dysplasia and weill–marchesani syndrome

The acromelic dysplasias comprise short stature, hands and feet, and stiff joints. Three disorders are ascribed to this group, namely Weill–Marchesani syndrome, geleophysic dysplasia, and acromicric dysplasia, although similar in phenotype, can be distinguished clinically. Weill–Marchesani syndrome, on the basis of microspherophakia and ectopia lentis; geleophysic dysplasia by progressive cardiac valvular thickening, tracheal stenosis, and/or bronchopulmonary insufficiency, often leading to early death. Microspherophakia has not been reported previously in geleophysic dysplasia. Mutations in FBN1, ADAMTS10, or ADAMTS17 cause Weill–Marchesani syndrome by disrupting the microfibrillar environment, while geleophysic dysplasia is associated with enhanced TGF‐β signaling mediated through mutations in FBN1 or ADAMTSL2. We studied a 35‐year‐old woman with geleophysic dysplasia, with short stature, small hands and feet, limitation of joint mobility, mild skin thickening, cardiac valvular disease, restrictive pulmonary disease, and microspherophakia. Sequencing of ADAMTSL2 demonstrated two changes: IVS8‐2A>G consistent with a disease‐causing mutation, and IVS14‐7G>A with potential to generate a new splice acceptor site and result in aberrant mRNA processing. The unaffected mother carries only the IVS8‐2A>G transition providing evidence that the two changes are in trans‐configuration in our patient.

Genotype–phenotype correlation in DTDST dysplasias: Atelosteogenesis type II and diastrophic dysplasia variant in one family

Mutations in diastrophic dysplasia sulfate transporter (DTDST) cause a spectrum of autosomal recessive chondrodysplasias. In decreasing order of severity, they include processes designated as achondrogenesis type IB (ACG‐1B), atelosteogenesis type II (AO2), diastrophic dysplasia (DTD), diastrophic dysplasia variant (DTDv), and recessively inherited multiple epiphyseal dysplasia (rMED). This is the first report of an extended family with unequivocally distinct phenotypes on the DTDST spectrum. Two siblings have DTDv and their first cousin had AO2. They all share the common Finnish mutation (IVS1 + 2C>T). The two patients with DTDv have the previously reported R279W extracellular domain missense mutation. The second mutation in the patient with AO2 is c.172delA, a deletion of one nucleotide causing a previously unreported frameshift mutation. This is the first published case of an individual with a frameshift mutation combined with the Finnish mutation. These three patients provide an opportunity, in concert with a review of previous literature, to further examine the genotype–phenotype correlation of DTDST. Analysis suggests that, while the DTDST family of disorders contains at least seven different conditions, mutations in the DTDST gene, in fact, appear to cause a phenotypic continuum. Furthermore, DTDST genotype alone is an imperfect predictor of clinical severity along this continuum.

A dominantly inherited spondylometaphyseal dysplasia with “corner fractures” and congenital scoliosis

Spondylometaphyseal dysplasia (SMD) is a term applied to a varied group of skeletal dysplasias that principally involve the spine and the metaphyses of long bones. SMD Sutcliffe or “Corner Fracture” type is characterized by short stature, developmental coxa vara, fragmented appearance of the metaphyses (“corner fractures”), abnormally shaped vertebrae, odontoid hypoplasia, and dominant inheritance. We report a family with a dominantly inherited SMD with “corner fractures” and severe, congenital scoliosis but neither coxa vara nor odontoid abnormalities. This could either represent phenotypic variability in SMD‐“Corner Fracture” type, or be a new, dominantly inherited SMD. The presence of severe, congenital scoliosis and short stature is present in all members of this family, and not typically seen in SMD‐“Corner Fracture” type, supporting our hypothesis that this might represent a new, dominantly inherited SMD.

Clinical report: Two patients with atelosteogenesis type I caused by missense mutations affecting the same FLNB residue†

We present two patients with Atelosteogenesis Type I (AO type I) caused by two novel Filamin B (FLNB) mutations affecting the same FLNB residue: c.542G > A, predicting p.Gly181Asp and c.542G > C, predicting p.Gly181Arg. Both children had typical manifestations of AO type I, with severe rhizomelic shortening of the extremities, limited elbow and knee extension with mild webbing, pectus excavatum, broad thumbs with brachydactyly that was most marked for digits 3–5, dislocated hips and bilateral talipes equinovarus. Facial features included proptosis, hypertelorism, downslanting palpebral fissures, cleft palate, and retromicrognathia. The clinical course of one child was influenced by airway instability and bronchopulmonary dysplasia that complicated intubation and prevented separation from ventilator support. Respiratory insufficiency with tracheal hypoplasia, laryngeal stenosis, and pulmonary hypoplasia have all been described in patients with AO type I and we conclude that compromised pulmonary function is a major contributor to morbidity and mortality in this condition.