photophobia

Cone-Rod Dystrophies, X-Linked

Clinical Characteristics
Ocular Features: 

Three X-linked forms of progressive cone-rod dystrophies each with mutations in different genes have been identified.  Central vision is often lost in the second or third decades of life but photophobia is usually noted before vision loss.  Cones are primarily involved but rod degeneration occurs over time.  The ERG reveals defective photopic responses early followed by a decrease in rod responses.   All three types are rare disorders affecting primarily males with symptoms of decreased acuity, photophobia, loss of color vision, and myopia.  The color vision defect early is incomplete but progressive cone degeneration eventually leads to achromatopsia.    Peripheral visual fields are usually full until late in the disease when constriction and nightblindness are evident.  The retina may have a tapetal-like sheen.  RPE changes in the macula often give it a granular appearance and there may be a bull's-eye configuration.   Fine nystagmus may be present as well.  The optic nerve often has some pallor beginning temporally.  Carrier females can have some diminished acuity, myopia, RPE changes, and even photophobia but normal color vision and ERG responses at least among younger individuals.

There is considerable variation in the clinical signs and symptoms in the X-linked cone-rod dystrophies among both affected males and heterozygous females.  Visual acuity varies widely and is to some extent age dependent.  Vision can be normal into the fourth and fifth decades but may reach the count fingers level after that. 

Systemic Features: 

None.

Genetics

Mutations in at least 3 genes on the X chromosome cause X-linked cone-rod dystrophy.

CORDX1 (304020) is caused by mutations in an alternative exon 15 (ORG15) of the RPGR gene (Xp11.4) which is also mutant in several forms of X-linked retinitis pigmentosa (300455, 300029).  These disorders are sometimes considered examples of X-linked ocular disease resulting from a primary ciliary dyskinesia (244400).

CORDX2 (300085) is caused by mutations in an unidentified gene at Xq27.  A single family has been reported.

CORDX3 (300476) results from mutations in CACNA1F.  Mutations in the same gene also cause a form of congenital stationary night blindness, CSNB2A (300071).  The latter, however, is a stationary disorder with significant nightblindness and mild dyschromatopsia, often with an adult onset, and is associated with high myopia. Aland Island Eye Disease (300600) is another allelic disorder.   

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

There is no treatment for these dystrophies but red-tinted lenses provide comfort and may sometimes improve acuity to some extent.  Low vision aids can be helpful. 

References
Article Title: 

Stargardt Disease

Clinical Characteristics
Ocular Features: 

Stargardt disease or fundus flavimaculatus is a progressive form of juvenile macular degeneration with considerable clinical and genetic heterogeneity.  It may be considered a syndromal cone-rod dystrophy because of overlapping clinical features such as loss of color vision and photophobia in some patients.  Adding to the confusion is the fact that mutations in at least 4 genes are responsible for similar clinical characteristics.  Due to the lack of diagnostic distinctions and the wide range of nonspecific clinical manifestations, Stargardt disease and fundus flavimaculatus are discussed here as a single entity.

Onset of vision loss is often noted late in the first decade of life usually with rapid progression.  However, some patients are asymptomatic until much later, even into the fifth decade.  There is evidence that patients with an early onset have a worse prognosis compared to those with a later onset.  Nevertheless, large series of patients contain at least 23% with 20/40 or better acuity, about 20% with 20/50 -20/100, 55% have 20/200-20/400, and a small number have vision less than 20/400. 

Some color discrimination is lost and photophobia may be a complaint.  Dark adaptation is prolonged but nightblindness does not usually occur and peripheral visual fields are normal.  The posterior pole characteristically has yellowish pisciform, round, and linear subretinal lipofuscin deposits which often extend to the equator.  These may be present before clinical symptoms are present.  Histopathology reveals accumulations of this material in RPE cells.  Atrophy of the RPE in the same region is often visible as well but these changes may be subtle initially.  Some patients have peripheral pigment clumping which may resemble the bone spicule configuration seen in retinitis pigmentosa.  However, retinal vessel caliber is normal in Stargardt disease.  Extensive macular disease can be associated with temporal pallor of the optic nerve.  The ERG shows reduced photopic responses with normal or near normal scotopic tracings.  Fluorescein angiography often reveals more extensive disease than seen on fundoscopy.  Window defects are common in the macula where the RPE is atrophied.  The flecks may be hypo- or hyperfluorescent.  Over 50% of patients have patches of angiographically dark choroid in the posterior pole which is thought to be secondary to transmission blockage by lipofuscin accumulations in the RPE. 

Systemic Features: 

None.

Genetics

This group of disorders may be caused by mutations in at least 4 genes.  These are: STGD1 (248200) caused by mutations in the ABCA4 gene located at 1p22.1, or in CNGB3 (262300) (8q21-q22) which also is mutant in achromatopsia 3 (ACHM3), STGD3 (605512) caused by mutations in the ELOVL4 gene at 6q14, and STGD4 (603786) caused by a mutation in PROM1 on chromosome 4p.  STGD4 and STGD3 disease have been found in pedigrees consistent with autosomal dominant inheritance but STGD1 disease seems to be inherited in an autosomal recessive pattern.

Genotyping is necessary for accurate diagnostic determinations.  In particular, a few patients clinically found to have typical areolar macular dystrophy, retinitis pigmentosa, juvenile macular degeneration, and cone dystrophies have been reported in association with several of these mutations and reports have also associated Stargardt disease with mutations in RDS.

A single family with a brother and sister with Stargardt disease and neurological malformations has been reported (612948).  Both had developmental delays associated with absence or hypoplasia of the corpus callosum, upslanted lid fissures, 'flared eyebrows', a broad nasal tip, a broad face with a pointed chin, and sensorineural hearing loss along with mild digital malformations.  Evidence of macular degeneration was seen at age 7 years and vision in both individuals was in the 20/100-20/200 range. No associated locus or mutation has been identified.

Pedigree: 
Autosomal dominant
Autosomal recessive
Treatment
Treatment Options: 

There is no treatment for this disorder but low vision aids can be helpful especially in the early stages of the disease.

Isotretinoin has been shown to slow the accumulation of lipofuscin pigments in mice but its role in human Stargardt disease has not been reported.  Trials using stem cells are underway with encouraging early results.

References
Article Title: 

Comprehensive analysis of patients with Stargardt macular dystrophy reveals new genotype-phenotype correlations and unexpected diagnostic revisions

Zaneveld J, Siddiqui S, Li H, Wang X, Wang H, Wang K, Li H, Ren H, Lopez I, Dorfman A, Khan A, Wang F, Salvo J, Gelowani V, Li Y, Sui R, Koenekoop R, Chen R. Comprehensive analysis of patients with Stargardt macular dystrophy reveals new genotype-phenotype correlations and unexpected diagnostic revisions. Genet Med. 2014 Dec 4.  [Epub ahead of print].

PubMed ID: 
25474345

Blue Cone Monochromacy

Clinical Characteristics
Ocular Features: 

This is usually a stationary cone dysfunction disorder in which the causative mechanism has yet to be worked out.  Typical patients have severe visual impairment from birth and some have pendular nystagmus and photophobia similar to other achromatopsia disorders.  Vision seems to be dependent solely on blue cones and rod photoreceptors.  The ERG always shows relatively normal rod function whereas the cones are usually dysfunctional. 

In some families, however, there is evidence of disease progression with macular RPE changes and myopia.  This has led to the designation of 'cone dystrophy 5' for such cases even though the mutation locus impacts the same cone opsin genes at Xq28 that are implicated in the more typical BCM phenotype.

Systemic Features: 

None.

Genetics

This is an X-linked recessive form of colorblindness in which DNA changes in the vicinity of Xq28 alters the red and green visual pigment cluster genes via recombination or point mutations.  Alternatively, the control locus adjacent to the cluster may be altered.  In either case, the result may be a loss of function of these genes leaving blue-cone monochromacy.

The mutation for cone dystrophy 5 maps to Xq26.1-qter but the locus encompasses the opsin gene complex at Xq28 as well. 

At least a quarter of individuals with blue cone monochromacy, however, do not have mutations in the vicinity of Xq28 suggesting that additional genetic heterogeneity remains.

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

Low vision aids can be helpful.  Tinted lenses for photophobia allow for greater visual comfort.  A magenta (mixture of red and blue) tint allows for best visual acuity since it protects the rods from saturation while allowing the blue cones to be maximally stimulated. 

References
Article Title: 

X-linked cone dystrophy caused by mutation of the red and green cone opsins

Gardner JC, Webb TR, Kanuga N, Robson AG, Holder GE, Stockman A, Ripamonti C, Ebenezer ND, Ogun O, Devery S, Wright GA, Maher ER, Cheetham ME, Moore AT, Michaelides M, Hardcastle AJ. X-linked cone dystrophy caused by mutation of the red and green cone opsins. Am J Hum Genet. 2010 Jul 9;87(1):26-39.

PubMed ID: 
20579627

Genetic heterogeneity among blue-cone monochromats

Nathans J, Maumenee IH, Zrenner E, Sadowski B, Sharpe LT, Lewis RA, Hansen E, Rosenberg T, Schwartz M, Heckenlively JR, et al. Genetic heterogeneity among blue-cone monochromats. Am J Hum Genet. 1993 Nov;53(5):987-1000.

PubMed ID: 
8213841

Molecular genetics of human blue cone monochromacy

Nathans J, Davenport CM, Maumenee IH, Lewis RA, Hejtmancik JF, Litt M, Lovrien E, Weleber R, Bachynski B, Zwas F, et al. Molecular genetics of human blue cone monochromacy. Science. 1989 Aug 25;245(4920):831-8.

PubMed ID: 
2788922

Colorblindness-Achromatopsia 5

Clinical Characteristics
Ocular Features: 

Poor visual acuity and congenital nystagmus are characteristic of ACHM5 and may be seen in infancy.  Vision loss can be progressive for those who have a milder form of colorblindness or incomplete achromatopsia.  Such patients have a somewhat later onset and may not have nystagmus or photophobia.  Cone responses are usually absent in the ERG whereas rod responses are often normal.  However, in the incomplete form there may be reduced but measureable cone responses.  There may be some reduction in rod responses with disease progression.  Myopia has been found in some patients.  Atrophy of the RPE in the posterior pole characteristic of progressive cone dystrophies may be seen. 

Systemic Features: 

No systemic abnormalities are found in this disorder. 

Genetics

This is an autosomal recessive disorder resulting from mutations in the PDE6C gene located at 10q24.  This condition is sometimes called cone dystrophy 4.

Other forms of achromatopsia are ACHM3 caused by mutations in CNGB3 (262300), ACHM2 caused by mutations in CNGA3 (216900), and ACHM4 by mutations in GNAT2 (139340).

 

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

There is no treatment for the cone dystrophy but dark glasses and red colored contact lenses are helpful in reducing the photophobia and can improve acuity to some extent.  Low vision aids can also be helpful. 

References
Article Title: 

A Nonsense Mutation in PDE6H Causes Autosomal-Recessive Incomplete Achromatopsia

Kohl S, Coppieters F, Meire F, Schaich S, Roosing S, Brennenstuhl C, Bolz S, van Genderen MM, Riemslag FC; the European Retinal Disease Consortium, Lukowski R, den Hollander AI, Cremers FP, De Baere E, Hoyng CB, Wissinger B. A Nonsense Mutation in PDE6H Causes Autosomal-Recessive Incomplete Achromatopsia. Am J Hum Genet. 2012 Sep 7; 91(3) :527-32.

PubMed ID: 
22901948

Homozygosity mapping reveals PDE6C mutations in patients with early-onset cone photoreceptor disorders

Thiadens AA, den Hollander AI, Roosing S, Nabuurs SB, Zekveld-Vroon RC, Collin RW, De Baere E, Koenekoop RK, van Schooneveld MJ, Strom TM, van Lith-Verhoeven JJ, Lotery AJ, van Moll-Ramirez N, Leroy BP, van den Born LI, Hoyng CB, Cremers FP, Klaver CC. Homozygosity mapping reveals PDE6C mutations in patients with early-onset cone photoreceptor disorders. Am J Hum Genet. 2009 Aug;85(2):240-7.

PubMed ID: 
19615668

Colorblindness-Achromatopsia 4

Clinical Characteristics
Ocular Features: 

The ocular phenotype in ACHM4 is similar to that of other forms of achromatopsia.  Nystagmus, poor visual acuity, photophobia, and defects in color vision are usually present.  Some subjects, however, retain some color discrimination, a condition referred to as incomplete achromatopsia.  The ERG documents the absence of cone function but normal rod responses.  The retina appears normal clinically.

Few families have been reported and the complete phenotype remains undocumented.  For example, it has been reported that visual acuity weakens with age in some patients although it is uncertain if this is true of all cases. 

Systemic Features: 

No systemic abnormalities are associated. 

Genetics

This is an autosomal recessive disorder caused by mutations in GNAT2 located at 1p13.  These mutations account for less than 2% of achromatopsia cases.  The majority are caused by mutations in CNGA3 (25%), responsible for ACHM2 (216900) and CNGB3 (50%), causing ACHM3 (262300).  Mutations in PDE6C (613093 ) causing ACHM5 are responsible for less than 2%. No doubt others will be found as many cases do not have mutations in these genes. 

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

No treatment is available for this disorder but tinted lenses and low vision aids can be helpful.  Red contact lenses can reduce the photophobia and may improve vision. 

References
Article Title: 

Colorblindness-Achromatopsia 2

Clinical Characteristics
Ocular Features: 

Patients with this congenital, nonprogressive condition often have nystagmus as infants which may improve later. Eccentric fixation secondary to a small central scotoma is often present.  Visual acuity is 20/200 or worse.  Hyperopia is common.  Photophobia is extreme and vision under daylight conditions improves in dim light.  Patients are unable to distinguish any colors.  However, there is considerable variability in symptoms and some individuals retain some color perception and have better visual acuity (sometimes 20/80) than others suggesting some residual cone function.  The term ‘incomplete achromatopsia’ is sometimes applied to such cases but the molecular basis for this variation is unknown.  Optical coherence tomography reveals the central retina to be thinner than in normal controls.  The fundus appearance is normal, however.

ERG responses indicate an absence of cone function with no photopic responses. 

Systemic Features: 

There are no associated systemic abnormalities. 

Genetics

Mutations in CNGA3 account for approximately 25% of cases of achromatopsia.  ACHM2 is an autosomal recessive disorder caused by mutations in CNGA3 (2q11).  Mutations in this gene also have been found in rare patients with progressive cone dystrophies.  A clinically similar but genetically distinct disorder, ACHM3, results from mutations in CNGB3 (262300).  Mutations in GNAT2 (ACHM4; 139340) and PDE6C (ACHM5; 613093) also cause achromatopsia. 

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

There is no treatment for the underlying condition but darkly tinted lenses can help in bright light.  Red contact lenses can alleviate photophobia and improve vision as well.  Low vision aids and vocational training can be of great benefit.  In spite of the poor vision, some patients may find that correction of the hyperopia enables them to see better. 

References
Article Title: 

Colorblindness-Achromatopsia 3

Clinical Characteristics
Ocular Features: 

Achromatopsia 3 is a congenital, nonprogressive form of blindness.  It is sometimes referred to as a rod monochromacy or stationary cone dystrophy.  Symptoms are usually present at birth or shortly thereafter.  Patients have pendular nystagmus, progressive lens opacities, severe photophobia, 'day' blindness, and, of course, color blindness.  High myopia is a feature in some populations.  Vision in daylight is often 20/200 or less but vision in dim light is somewhat better. The central scotoma often leads to eccentric fixation. 

The ERG shows a complete absence of cone function.  Optical coherence tomography has demonstrated a reduction in macular volume and thickness of the central retina, most marked in the foveolar region, presumably due in some way to the absence or dysfunction of cone photoreceptors.  Few histologic studies of adequately preserved retina have been reported but those available suggest dysmorphism of cones in the central macula.  The clinical appearance of the retina is usually normal. 

Systemic Features: 

There are no associated systemic abnormalities. 

Genetics

This is an autosomal recessive form of color blindness caused by mutations in CNGB3 (8q21-q22).  This mutation is found in nearly half of patients with achromatopsia.  It is especially common among Pingelapese islanders of the Pacific Caroline Islands where consanguinity occurs frequently due to the founder effect resulting from a 1775 typhoon.  A progressive cone dystrophy has been found in a few patients with mutations in this gene.

Other achromatopsia mutations are in CNGA3 causing ACHM2 (216900), GNAT2 causing ACHM4 (139340), and PDE6C causing ACHM5 (613093).   

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

No treatment is available but darkly tinted lenses can alleviate much of the photophobia.  Low vision aids and vocational training should be offered.  Refractive errors should, of course, be corrected and periodic examinations are especially important in children. 

References
Article Title: 

The cone dysfunction syndromes

Michaelides M, Hunt DM, Moore AT. The cone dysfunction syndromes. Br J Ophthalmol. 2004 Feb;88(2):291-7. Review.

PubMed ID: 
14736794

Leber Congenital Amaurosis

Clinical Characteristics
Ocular Features: 

Leber congenital amaurosis is a collective term applied to multiple recessively inherited conditions with early-onset retinal dystrophy causing infantile or early childhood blindness.  There are no established diagnostic criteria.  First signs are usually noted before the age of 6 months.  These consist of a severe reduction in vision accompanied by nystagmus, abnormal pupillary responses, and photophobia.  Ametropia in the form of hyperopia is common.  Keratoconus (and keratoglobus) is frequently found in older children but it is uncertain if this is a primary abnormality or secondary to eye rubbing as the latter is commonly observed.  Repeated pressure on the eye may also be responsible for the relative enophthalmos often seen in these patients.  The ERG is reduced or absent early and permanently.  Final visual acuity is seldom better than 20/400 and perhaps one-third of affected individuals have no light perception.  Some individuals experience a period of vision improvement.

The retina usually has pigmentary changes but these are not diagnostic.  Retinal vessels are generally attenuated.  The RPE may have a finely granulated appearance or, in some cases, whitish dots, and even 'bone spicules'.

Systemic Features: 

A variety of metabolic and physical abnormalities have been reported with LCA but many publications are from the pre-genomic era and the significance of such associations remains uncertain.  Most extraocular signs result from delays in mental development but it is uncertain what role, if any, that visual deprivation plays.  Perhaps 20% of patients are mentally retarded or have significant cognitive deficits.

Genetics

Leber congenital amaurosis is genetically heterogeneous with at least 18 known gene mutations associated with the phenotype.  It is also clinically heterogeneous both within and among families and this is the major obstacle to the delineation of individual clinicogenetic entities.  As more patients are genotyped, it is likely that more precise genotype-phenotype correlations will emerge.  At the present time, however, it is not possible to use clinical findings alone to distinguish individual conditions.

Below are links to the genotypic and phenotypic features of the 19 known types of LCA.  All cause disease in the homozygous or compound heterozygous state. 

LCA type               OMIM#                 Locus              Gene Symbol   

LCA 1                    204000                 7p13.1                 GUCY2D

LCA 2                    204100                 1p31                    RPE65**

LCA 3                    604232                 14q31.3               SPATA7

LCA 4                    604393                 17p13.1               AIPL1

LCA 5                    604537                 6q14.1                 LCA5

LCA 6                    613826                 14q11                  RPGRIP1

LCA 7                    613829                19q13.1                CRX*

LCA 8                    613835                 1q31-q32             CRB1

LCA 9                    608553                 1p36                    NMNAT1

LCA 10                  611755                 12q21                  CEP290

LCA 11                  613837                 7q31.3-q332        IMPDH1

LCA 12                  610612                 1q32.3                 RD3

LCA 13                  612712                 14q24.1               RDH12

LCA 14                  613341                 4q31                    LRAT

LCA 15                  613843                 6p21-31              TULP1

LCA 16                  614186                 2q37                    KCNJ13

LCA 17                  615360                 8q22.1                 GDF6

LCA 18                  608133                 6p21.1                 PRPH2***

It is likely that more mutant genes will be identified since these are found in only about half of patients studied in large series.  

*(Heterozygous mutations in CRX may also cause a cone-rod dystrophy).

**(Mutations in RPE65 has been described as also causing retinitis pigmentosa (RP20; 613794)  with choroidal involvement.)

***Mutations in PRPH2 (RDS) has also been reported to cause retinitis pigmentosa 7, choroidal dystrophy, and vitelliform macular dystrophy (179605) among others.

See also Leber Congenital Amaurosis with Early-Onset Deafness.

Mutations in the GUCY2D gene seem to be the most common being present in about 21% of LCA patients with CRB1 next at 10%.

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

Until recently, no treatment was available for LCA.  However, results from early clinical trials with adeno-associated virus vector mediated gene therapy for RPE65 mutations in LCA 2 show promise.  Subretinal placement of recombinant  adeno-virus carrying RPE65 complementary DNA results in both subjective and objective improvements in visual function.  Patients generally report subjective improvement in light sensitivity and visual mobility.  Some recovery of rod and cone photoreceptor function has been documented.  Studies have also documented an improvement in visual acuity, size of visual field, pupillary responses, and in the amouunt of nystagmus.  More than 230 patients have now  been treated and improvements seem to be maintained for at least 3 or more years.  However, we have also learned that along with the enzymatic dysfunction of RPE65 that disrupts the visual cycle, there is also degeneration of photoreceptors which continues after treatment and the long term prognosis remains guarded. Multiple phase I clinical trials have demonstrated the safety of this approach and phase III trials are now underway.

It is crucial for patients to be enrolled early in sensory stimulation programs to ensure optimum neural development.  For patients with residual vision, low vision aids can be beneficial.  Vocational and occupational therapy should be considered for appropriate patients.

References
Article Title: 

Mutations in NMNAT1 cause Leber congenital amaurosis and identify a new disease

Koenekoop RK, Wang H, Majewski J, Wang X, Lopez I, Ren H, Chen Y, Li Y,
Fishman GA, Genead M, Schwartzentruber J, Solanki N, Traboulsi EI, Cheng J, Logan
CV, McKibbin M, Hayward BE, Parry DA, Johnson CA, Nageeb M; Finding of Rare
Disease Genes (FORGE) Canada Consortium, Poulter JA, Mohamed MD, Jafri H, Rashid
Y, Taylor GR, Keser V, Mardon G, Xu H, Inglehearn CF, Fu Q, Toomes C, Chen R.
Mutations in NMNAT1 cause Leber congenital amaurosis and identify a new disease
pathway for retinal degeneration
. Nat Genet. 2012 Jul 29.
 

PubMed ID: 
22842230

A dominant mutation in RPE65 identified by whole-exome sequencing causes retinitis pigmentosa with choroidal involvement

Bowne SJ, Humphries MM, Sullivan LS, Kenna PF, Tam LC, Kiang AS, Campbell M, Weinstock GM, Koboldt DC, Ding L, Fulton RS, Sodergren EJ, Allman D, Millington-Ward S, Palfi A, McKee A, Blanton SH, Slifer S, Konidari I, Farrar GJ, Daiger SP, Humphries P. A dominant mutation in RPE65 identified by whole-exome sequencing causes retinitis pigmentosa with choroidal involvement. Eur J Hum Genet. 2011 Oct;19(10):1074-81. Erratum in: Eur J Hum Genet. 2011 Oct;19(10):1109.

PubMed ID: 
21654732

Treatment of leber congenital amaurosis due to RPE65 mutations by ocular subretinal injection of adeno-associated virus gene vector: short-term results of a phase I trial

Hauswirth WW, Aleman TS, Kaushal S, Cideciyan AV, Schwartz SB, Wang L, Conlon TJ, Boye SL, Flotte TR, Byrne BJ, Jacobson SG. Treatment of leber congenital amaurosis due to RPE65 mutations by ocular subretinal injection of adeno-associated virus gene vector: short-term results of a phase I trial. Hum Gene Ther. 2008 Oct;19(10):979-90.

PubMed ID: 
18774912

Effect of gene therapy on visual function in Leber's congenital amaurosis

Bainbridge JW, Smith AJ, Barker SS, Robbie S, Henderson R, Balaggan K, Viswanathan A, Holder GE, Stockman A, Tyler N, Petersen-Jones S, Bhattacharya SS, Thrasher AJ, Fitzke FW, Carter BJ, Rubin GS, Moore AT, Ali RR. Effect of gene therapy on visual function in Leber's congenital amaurosis. N Engl J Med. 2008 May 22;358(21):2231-9.

PubMed ID: 
18441371

Leber congenital amaurosis

Perrault I, Rozet JM, Gerber S, Ghazi I, Leowski C, Ducroq D, Souied E, Dufier JL, Munnich A, Kaplan J. Leber congenital amaurosis. Mol Genet Metab. 1999 Oct;68(2):200-8. Review.

PubMed ID: 
10527670

Sjogren-Larsson Syndrome

Clinical Characteristics
Ocular Features: 

The retina often has glistening white intraretinal dots which may be concentrated in the macula.  They have been found in 1 to 2 year old infants.  The macula may have ‘punched out’ lesions.  A pigmentary retinopathy is present in about 50% of patients and fluorescein angiography reveals a mottled hyperfluorescence. The cornea often has grayish stromal opacities that become vascularized, most commonly in the lower half.  Most patients have punctate keratitis resulting in marked photophobia.  Visual acuities can range from about 20/40 to finger counting.  The retinal changes may be progressive but EOG and ERG studies do not reveal abnormalities of retinal function.  VEPs though are often abnormal.  Ichthyosis may involve the lids and periorbital areas.

Systemic Features: 

The skin changes are present at birth and consist of an ichthyosiform erythroderma.  Hyperkeratosis is also present at birth and full blown ichthyosis develops during infancy.  The skin changes are most marked about the neck, flexion creases, and lower abdomen.  Scales in these areas are often darker than the surrounding skin.  Mental retardation may be mild to severe and spastic diplegia or quadriplegia is common but there is little evidence of progression.  There does not seem to be any correlation of age with the severity of neurological disease.

Genetics

Mutations in the ALDH3A2 gene (17p11.2) are responsible for this autosomal recessive disorder resulting in a deficiency of fatty aldehyde dehydrogenase. This can lead to long-chain fatty alcohol accumulation as demonstrated in the brain with proton magnetic resonance spectroscopy.

A form of Sjogren-Larsson syndrome with more severe neurologic signs is caused by recessive mutations in ELOVL4 (6p14,1),  Mutations in the same gene have been identified in patients with autosomal dominant Stargardt disease 3 (600110).

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

No treatment is available for this disorder but moisturizing skin treatments can be beneficial.

References
Article Title: 

Optic Atrophy 6

Clinical Characteristics
Ocular Features: 

Visual impairment is often noted under the age of 6 years.  The disease is bilateral and loss of vision procedes slowly, eventually reaching 20/100 to 20/200.  Moderate photophobia and dyschromatopsia are present but nystagmus is absent.  The impact on the visual field seems to be minimal and limited to decreased sensitivity in the central areas.

Systemic Features: 

No systemic abnormalities are associated.

Genetics

Evidence for this presumed autosomal recessive type of optic atrophy is based on a single large, consanguineous French Canadian family.  A locus in the 8q21-q22 region presumably containing the mutant gene, designated OPA6, was found.  Linkage analysis excluded genes linked to autosomal dominant optic atrophy.

Another autosomal recessive optic atrophy disorder (OPA7; 612989) has also been reported.

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

No treatment beyond low vision aids is helpful.

References
Article Title: 

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