foveal hypoplasia

Keratitis, Hereditary

Clinical Characteristics
Ocular Features: 

The disorder begins in the first year of life with a band of vascularized opacification inside the limbus.  Evidence of inflammation is seen in the anterior stroma and the Bowman membrane becomes replaced by fibrovascular tissue.  The disease is recurrent and progressive and there is usually asymmetry between the two eyes.  Non-penetrance and considerable variation in expression have been reported.  Acute episodes are characterized by photophobia, tearing, mucous discharge, and punctate keratitis.  The limbal opacification may progress centrally and eventually leads to a reduction in vision.  Deficits in visual acuity may lead to deprivation amblyopia and secondary esotropia.

In a 4 generation family, foveal hypoplasia, iris stromal defects, and ectropion uveae were seen in several of the fifteen affected individuals.  It has been suggested that this may be a variant of aniridia. 

Systemic Features: 

No systemic disease has been found. 

Genetics

This is an autosomal dominant disorder reported in several multigeneration families.  Mutations in the PAX6 gene (11p13) seem to be responsible.  The same gene is mutant in Gillespie syndrome (206700), aniridia (106210) and Peters anomaly (604229). 

Pedigree: 
Autosomal dominant
Treatment
Treatment Options: 

There is no effective treatment.  Penetrating keratoplasty in several individuals has been followed by similar disease in the donor tissue. 

References
Article Title: 

Dominantly inherited keratitis

Kivlin JD, Apple DJ, Olson RJ, Manthey R. Dominantly inherited keratitis. Arch Ophthalmol. 1986 Nov;104(11):1621-3.

PubMed ID: 
3778274

Gillespie Syndrome

Clinical Characteristics
Ocular Features: 

Bilateral aniridia, partial or complete, is the ocular characteristic of Gillespie syndrome.  The iris may be relatively intact but immobile leading to the description in some patients of "dilated and fixed pupils", or congenital mydriasis.  The pupillary margin may be scalloped with iris strands to the lens.  The pupillary sphincter is sometimes absent and the mesodermal surface missing.  The fovea sometimes appears hypoplastic and some patients have decreased visual acuity.  Strabismus and ptosis are often present.  There may also be retinal hypopigmentation.  Cataract, glaucoma, and corneal opacities are not present. 

Systemic Features: 

Most patients have some degree of developmental delay ranging from difficulties with fine motor tasks to frank mental retardation.  Many have a hand tremor, some degree of hypotonia, and learning difficulties.  MRI imaging often shows cerebellar and sometimes cerebral hypoplasia. 

Genetics

This is an autosomal dominant disorder usually due to a heterozygous mutation in the PAX6 gene (11p13).  However, some patients with typical features do not have a mutation in this gene suggesting that there is genetic heterogeneity.  Some patients without point mutations nevertheless have defects in adjacent DNA suggesting a positional effect.  The possibility of autosomal recessive inheritance in some families with parental consanguinity cannot be ruled out.  The PAX6 gene plays an important role in iris development as it is also mutant in simple aniridia (106210) and in Peters anomaly (604229).

Mutations in the ITPR1 gene have also been identified in Gillespie syndrome.

Pedigree: 
Autosomal dominant
Treatment
Treatment Options: 

No treatment is available.

References
Article Title: 

Albinism, Ocular Type 1

Clinical Characteristics
Ocular Features: 

Signs in ocular albinism include hypopigmentation of the fundus with clearly visible choroidal vessels, foveal hypoplasia, and hypopigmentation of the iris. Strabismus, nystagmus, photophobia, absent stereoacuity and high refractive errors including hypermetropia are other common features.  Vision may be near normal but usually worse, in the range of 20/100 to 20/300.  In at least some patients with ocular albinism, concentric macular rings have been identified using infrared reflectance images.

In ocular albinism there is a nearly complete crossing of nerve fibers in the optic chiasm as well as a decreased number of photoreceptors.  MRI imaging of the optic chiasm in humans with albinism reveals it to be smaller with a wider angle between optic tracts, reflecting the atypical crossing of nerve fibers.

This is an X-linked recessive disorder and affects mainly men. In 80% of female carriers a mosaic of pigmentary changes can be observed in the fundus, especially in the periphery as a result of lyonization.  A few female heterozygotes have ocular changes of albinism including nystagmus and reduced visual acuity, likely as a result of unequal X-chromosome inactivation.  Perhaps three-quarters of carrier females have transillumination defects in the iris.

Hearing loss is often associated with pigmentation disorders and families with X-linked ocular albinism have been reported with a late onset sensorineural deafness (300650).  The ocular findings are typical but deafness is not significant until late midlife.

Systemic Features: 

In ocular albinism, pigmentation is normal except in the eye.  Hearing loss has been reported in a single family but this may be a unique disorder since the genotype was not determined.

Male infertility has been reported in some patients with OCA1 and late-onset sensorineural hearing loss which has been hypothesized ro be part of a contiguous gene deletion syndrome involving GPR143, TBL1X and posssibly SHROOM2 genes.

Genetics

Ocular albinism (OA1) is a recessive X-linked disorder, caused by mutations in the GPR143 gene, located at Xp22.3.  The protein product, a G protein-coupled receptor, is localized on the membrane of melanosomes in pigmented cells in the eye.  The same gene is mutated in congenital nystagmus 6 (300814).  Ocular albinism with late onset sensorineural deafness (300650) results from mutations in the Xp22.3 region as well and may or may not be the same condition.  In some individuals the contiguous genes TBL1X and SHROOM2 may also have mutations (usually microdeletions).

It has been reported that mutations in GNA13 (17q24.1), activated by OA1, can also result in the ocular albinism phenotype.

Pedigree: 
X-linked recessive, carrier mother
X-linked recessive, father affected
Treatment
Treatment Options: 

Treatment for the ocular symptoms is targeted toward specific problems. Refractive errors are treated with corrective glasses with tinted lenses recommended for the photophobia. Low vision aids and special education may be required.

References
Article Title: 

Aniridia 1

Clinical Characteristics
Ocular Features: 

Aniridia is the name of both a disorder and a group of disorders.  This because aniridia is both an isolated ocular disease and a feature of several malformation syndromes.  Absence of the iris was first reported in the early 19th century.  The hallmark of the disease is bilateral iris hypoplasia which may consist of minimal loss of iris tissue with simple radial clefts, colobomas, pseudopolycoria, and correctopia, to nearly complete absence.  Goniosocopy may be required to visualize tags of iris root when no iris is visible externally.  Glaucoma is frequently present (~67%) and often difficult to treat.  It is responsible for blindness in a significant number of patients.  About 15% of patients are diagnosed with glaucoma in each decade of life but this rises to 35% among individuals 40-49 years of age.  Hypoplasia and dysplasia of the fovea are likely responsible for the poor vision in many individuals.  Nystagmus is frequently present.  The ciliary body may also be hypoplastic. 

Visual acuity varies widely.  In many families it is less than 20/60 in all members and the majority have less than 20/200.  Photophobia can be incapacitating.  Posterior segment OCT changes suggest that outer retinal damage suggestive of a phototoxic retinopathy may also be a factor in the reduced acuity.  Cataracts (congenital in >75%), ectopia lentis (bilateral in >26%), optic nerve hypoplasia, variable degrees of corneal clouding with or without a vascularized pannus, and dysgenesis of the anterior chamber angle are frequently present. 

Increased corneal thickness (>600 microns) has been found in some series and should be considered when IOP measurements are made.  In early stages of the disease, focal opacities are present in the basal epithelium, associated with sub-basal nerves.  Dendritic cells can infiltrate the central epithelium and normal limbal palisade architecture is absent. 

Meibomian gland anomalies also contribute to the corneal disease.  The glands may be decreased in number and smaller in size contributing to deficiencies of the tear film and unstable surface wetting.

Systemic Features: 

In addition to 'pure' aniridia in which no systemic features are found, at least six disorders have been reported in which systemic anomalies do occur.  Three of these have associated renal anomalies, including Wilms tumor with other genitourinary anomalies and mental retardation, sometimes called WAGR (194072) syndrome, another (612469) with similar features plus obesity sometime called WAGRO (612469) syndrome reported in isolated patients, and yet another with partial aniridia (206750) and unilateral renal agenesis and psychomotor retardation reported in a single family.  Aniridia with dysplastic or absent patella (106220) has been reported in a single three generation family.  Cerebellar ataxia and mental retardation with motor deficits (Gillespie syndrome; 206700) have been found in other families with anirdia.  Another 3 generation family has been reported in which aniridia, microcornea and spontaneously resorbed cataracts occured (106230).

About one-third of patients with aniridia also have Wilms tumor and many have some cognitive deficits.

Genetics

The majority of cases have a mutation in the paired box gene (PAX6) complex, or at least include this locus when chromosomal aberrations such as deletions are present in the region (11p13).  This complex (containing at least 9 genes) is multifunctional and important to the tissue regulation of numerous developmental genes.   PAX6 mutations, encoding a highly conserved transcription regulator, generally cause hypoplasia of the iris and foveal hypoplasia but are also important in CNS development.  It has been suggested that PAX6 gene dysfunction may be the only gene defect associated with aniridia.  More than 300 specific mutations, most causing premature truncation of the polypeptide, have been identified.  

AN1 results from mutations in the PAX6 gene.  Two additional forms of aniridia have been reported in which functional alterations in genes that modulate the expression of PAX6 are responsible: AN2 (617141) with mutations in ELP4 and AN3 (617142) with mutations in TRIM44.  Both ELP4 and TRIM44 are regulators of the PAX6 transcription gene.

Associated abnormalities may be due to a second mutation in the WT1 gene in WAGR (194072) syndrome, a deletion syndrome involving both WT1 and PAX6 genes at 11p13.  The WAGRO syndrome (612469) is caused by a contiguous deletion in chromosome 11 (11p12-p13) involving three genes: WT1, PAX6, and BDNF.  All types are likely inherited as autosomal dominant disorders although nearly one-third of cases occur sporadically.

Mutations in PAX6 associated with aniridia can cause other anterior chamber malformations such as Peters anomaly (604229).

Gillespie syndrome (206700 ) is an allelic disorder with neurological abnormalities including cerebellar ataxia and mental retardation.

Pedigree: 
Autosomal dominant
Treatment
Treatment Options: 

Treatment is directed at the associated threats to vision such as glaucoma, corneal opacities, and cataracts.  Glaucoma is the most serious threat and is the most difficult to treat. The best results have been reported with glaucoma drainage devices.  All patients should have eye examinations at appropriate intervals throughout life, focused on glaucoma screening.  It is well to keep in mind that foveal maldevelopment often precludes significant improvement in acuity and heroic measures must be carefully evaluated.  Specifically, corneal transplants and glaucoma control measures frequently fail.

Low vision aids are often helpful.  Tinted lenses can minimize photophobia.  Occupational and vocational training should be considered for older individuals.  Surface wetting of the cornea should be periodically evaluated and appropriate topical lubrication used as needed. 

Young children with aniridia should have periodic examinations with renal imaging as recommended by a urologist.

In mice, postnatal topical ocular application of ataluren-based eyedrop formulations can reverse malformations caused by PAX6 mutations.

References
Article Title: 

Familial aniridia with preserved

Elsas FJ, Maumenee IH, Kenyon KR, Yoder F. Familial aniridia with preserved ocular function. Am J Ophthalmol. 1977 May;83(5):718-24.

PubMed ID: 
868970

Aland Island Eye Disease

Clinical Characteristics
Ocular Features: 

This is an X-linked disorder in which males have a variety of ocular defects.  The fundus is hypopigmented and the fovea is incompletely developed.  The hypopigmentation is most pronounced in the posterior pole and peripapillary region.  Variable degrees of iris transillumination have also been noted.  Progressive axial myopia, nystagmus, astigmatism, defective night vision, and a protan color vision defect are additional cardinal features.  Females may be mildly affected with subtle nystagmus and color vision defects.  It is sometimes mislabeled as X-linked albinism (OA1, #300500) but differs importantly from that disorder by the lack of misrouting of optic nerve axons.  The eponymic label 'Forsius-Eriksson type ocular albinism' further adds to the confusion with ocular albinism. 

Systemic Features: 

No systemic abnormalities have been reported.

Genetics

This is an X-linked disorder resulting from a mutation in the CACNA1F gene located at Xp11.23.  Molecular DNA studies suggest that there may be some heterogeneity in the causative mutations but in the original family reported by Forsius and Eriksson, a 425-bp deletion in the CACNA1F gene has been found to segregate as expected in the phenotypes.  The highly variable and subtle nature of clinical manifestations in females limits their usefulness in determination of carrier status and genotyping is necessary.

The CSNB2A type of congenital stationary night blindness (300071) is caused by mutations in the same gene suggesting allelism of the two disorders.  Aland Island eye disease shares some clinical features such as night blindness and occasionally mild color vision defects but differs in the presence of progressive myopia and an abnormal fovea. 

CORDX3 (300476), a cone-rod dystrophy, is also allelic.

Pedigree: 
X-linked recessive, carrier mother
X-linked recessive, father affected
Treatment
Treatment Options: 

No treatment is available except for correction of the myopia.

References
Article Title: 

A novel CACNA1F gene mutation causes Aland Island eye disease

Jalkanen R, Bech-Hansen NT, Tobias R, Sankila EM, M?SSntyj?SSrvi M, Forsius H, de la Chapelle A, Alitalo T. A novel CACNA1F gene mutation causes Aland Island eye disease. Invest Ophthalmol Vis Sci. 2007 Jun;48(6):2498-502. PubMed PMID:17525176.

PubMed ID: 
17525176

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