A Japanese family with FEOM1-linked congenital fibrosis of the extraocular muscles type 1 associated with spinal canal stenosis and refinement of the FEOM1 critical region

Clinical characteristics of a KIF21A mutation in a Chinese family with congenital fibrosis of the extraocular muscles type 1

The aim of the study is to characterize the clinical ocular phenotype with congenital fibrosis of the extraocular muscles type 1 (CFEOM1) and to confirm whether the kinesin family member 21A (KIF21A) mutation was the pathogenic gene in this Chinese family.Three affected individuals and 2 asymptomatic kinsfolk from a Chinese family underwent comprehensive ophthalmic examinations, orbital computerized tomography (CT), and postoperative histological examinations were performed in the proband. All the recruited members were screened for 3 exons (8, 20, and 21) of KIF21A mutations using the polymerase chain reaction (PCR) amplification and direct sequencing of corresponding PCR products.All patients shared the clinical characteristics including bilateral ophthalmoplegia, blepharoptosis, hypertropic, and exotropic position with inability to raise either eye above the midline and a chin-up head position. Direct DNA sequence analysis from the affected members revealed a missense mutation in KIF21A (c.2860C>T, p.R954W). The unaffected members did not harbor the p.R954W mutation. The candidate mutation was not present in multiple web-accessible and in-house exome databases.The p.Arg954Trp mutation of KIF21A was the causative mutation in this Chinese pedigree with CFEOM1.

Congenital cranial dysinnervation disorders

The European Neuromuscular Centre (ENMC) derived the term Congenital Cranial Dysinnervation Disorders in 2002 at an international workshop for a group of congenital neuromuscular diseases. CCDDs are congenital, non-progressive ophthalmoplegia with restriction of globe movement in one or more fields of gaze. This group of sporadic and familial strabismus syndromes was initially referred to as the 'congenital fibrosis syndromes' because it was assumed that the primary pathologic process starts in the muscles of eye motility. Over the last few decades, evidence has accumulated to support that the primary pathologic process of these disorders is neuropathic rather than myopathic. This is believed that for normal development of extra ocular muscles and for preservation of muscle fiber anatomy, normal intra-uterine development of the innervation to these muscles is essential. Congenital dysinnervation to these EOMs can lead to abnormal muscle structure depending upon the stage and the extent of such innervational defects. Over last few years new genes responsible for CCDD have been identified, permitting a better understanding of associated phenotypes, which can further lead to better classification of these disorders. Introduction of high-resolution MRI has led to detailed study of cranial nerves courses and muscles supplied by them. Thus, due to better understanding of pathophysiology and genetics of CCDDs, various treatment modalities can be developed to ensure good ocular alignment and better quality of life for patients suffering from the same.

KIF21A mutation in two Chinese families with congenital fibrosis of the extraocular muscles type 1 and 3

Congenital fibrosis of the extraocular muscles (CFEOM) is a hereditary ocular disease and can be classified into three subtypes. The aim of the present study was to determine the genetic basis and describe the clinical phenotype of CFEOM type 1 and 3. Two Chinese families with CFEOM type 1 and 3 were identified. The patients and their family members were subjected to comprehensive ophthalmic examinations, including best-corrected visual acuity, slit-lamp examination, fundus examination, assessment of palpebral fissure size, levator function, ocular motility, and cover and forced duction tests. Genomic DNA was extracted from the leukocytes of venous blood samples collected from the two families and from 200 unrelated control subjects from the same population. Coding exons of the KIF21A gene were amplified using polymerase chain reaction analysis and sequenced directly in the two probands. The detected mutations were further analyzed in all available family members and the unrelated control subjects. A heterozygous mutation, c.2860C>T (p.R954W), in KIF21A was identified in the two families, and this was cosegregated with the presence of the diseases in the two families, however, it was absent in the 200 normal control subjects. Among the three affected family members with CFEOM1, differences were observed with regard to the presence of aberrant eye movement. The results indicated that, in the patients with CFEOM1 and CFEOM3, the disease was caused by the same KIF21A gene mutation. The KIF21A gene may be a major disease-causing gene for Chinese patients with CFEOM3. Phenotypic heterogeneity was observed in the patients with CFEOM1.

Congenital innervation dysgenesis syndrome (CID)/congenital cranial dysinnervation disorders (CCDDs)

Congenital loss of innervation to the extra-ocular muscles (EOMs) can have a profound effect on the target muscle. This has been well recognised in Duane's retraction syndrome. However, it has been less emphasised in other congenital oculo-motor disorders. Such congenital ocular motor defects have been expanded to include DRS, congenital fibrosis of EOMs, monocular elevation defect, Möbius syndrome, as well as several other non-ocular muscles supplied by cranial nerves such as facial muscles. Such loss of innervation to motor muscles can be unified as a defined clinical entity, which can be labelled as congenital innervation dysgenesis syndrome or CID for short. CID may also affect other muscles supplied by nerves other than the cranial nerves and may be sensory as well as motor.

Mutation analysis of KIF21A in congenital fibrosis of the extraocular muscles (CFEOM) patients

PURPOSE

CFEOM type 1 refers to a group of congenital eye movement disorders that is characterized by nonprogressive ophthalmoplegia affecting all the extraocular muscles. Individuals with the classic form of CFEOM are born with bilateral ptosis, infraducted eyes, and impossibility to raise their eyes above midline. This phenotype is often inherited as an autosomal dominant trait. CFEOM1 maps to the FEOM1 locus on chromosome 12 and is the consequence of mutations in the KIF21A gene. We analyzed three families and one sporadic case for potential genetic heterogeneity.

METHODS

Blood samples were collected from members of three families (Swiss, Turkish, and French origin) and one sporadic case (Iranian origin). In families, haplotype was tested for linkage to the autosomal dominant CFEOM1 locus on chromosome 12. Linkage studies were conducted using 2 polymorphic DNA microsatellite markers, D12S331 and D12S1048. Mutation analysis was performed by PCR amplification and bidirectional direct sequencing.

RESULTS

Haplotype analysis was compatible with linkage to the CFEOM1 locus in all affected members. Mutation analysis revealed the classical mutation R954W in all affected cases, including the sporadic case, regardless of their ethnic origin. The c.2860C>T base change was not observed in 100 individuals from various ethnic origins.

CONCLUSIONS

As reported, the classical c.2860C>T mutation represents a hotspot for mutation in various ethnic groups, including Swiss, Turkish, French, and Iranian patients. Sporadic cases are often due to neo-mutations as in our case. Mutation analysis is important, especially in sporadic cases, to correctly evaluate recurrence and transmission risks.

Management of congenital fibrosis of the inferior rectus muscle associated with high myopia: a case report

BACKGROUND

Congenital fibrosis of the extraocular muscles includes a wide spectrum of phenotypically heterogeneous disorders involving a single or multiple muscles.

METHODS

We present a case of congenital fibrosis of the inferior rectus associated with ipsilateral high myopia. First we tried to treat the hypotropia with inferior rectus weakening and superior rectus strengthening procedures, but this failed, so we proceeded with an ocular sling with fascia lata and a vertical Hummelsheim procedure.

RESULTS

Hypotropia improved completely after the last operation and some degree of upward movement appeared.

CONCLUSION

It seems that in a highly myopic globe with fibrotic muscles, classical methods for the correction of deviation may have poor response and more innovative procedures may be required to correct the deviation.

Recurrent mutation of the KIF21A gene in Japanese patients with congenital fibrosis of the extraocular muscles

PURPOSE

To report recurrent mutation of the KIF21A gene in three Japanese families in which some members have congenital fibrosis of the extraocular muscles type 1 (CFEOM1), and to describe the clinical characteristics of the families.

METHODS

Standard ocular examinations were performed on 18 normal and affected members of three unrelated families. To detect mutations, we determined the DNA sequence of exons 8, 20, and 21 and the splice sites of the KIF21A gene.

RESULTS

All affected members had a heterozygous mutation of the KIF21A gene in exon 21 (R954W). Clinically, each patient had congenital bilateral ptosis, an infraducted primary position of each eye, and the inability to raise either eye above midline.

CONCLUSIONS

The KIF21A gene mutation R954W was detected in the patients with CFEOM1 screened in this study, all of whom were Japanese, reflecting similar reports from Europe, America, the Middle East, and Japan. We suggest that mutations of the KIF21A gene contribute to the development of CFEOM1 regardless of ethnicity. We also found that the delimitation of the KIF21A gene mutation site enabled us to efficiently detect the KIF21A gene mutation despite the large number of KIF21A gene exons.

Heterozygous mutations of the kinesin KIF21A in congenital fibrosis of the extraocular muscles type 1 (CFEOM1)

Congenital fibrosis of the extraocular muscles type 1 (CFEOM1; OMIM #135700) is an autosomal dominant strabismus disorder associated with defects of the oculomotor nerve. We show that individuals with CFEOM1 harbor heterozygous missense mutations in a kinesin motor protein encoded by KIF21A. We identified six different mutations in 44 of 45 probands. The primary mutational hotspots are in the stalk domain, highlighting an important new role for KIF21A and its stalk in the formation of the oculomotor axis.