retinal detachment

Retinal Detachment with Lattice Degeneration

Clinical Characteristics
Ocular Features: 

Lattice degeneration of the retina is well known to increase the risk of retinal detachment.  Lattice is found in 40% of all rhegmatogenous retinal detachments but is present in only 7-10% of eye bank eyes.  Lattice degeneration by itself can lead to retinal detachment in less than 1% of patients but the risk increases into the 50% range when myopia is also present. 

A four generation pedigree of 88 individuals has been reported in which 22% had lattice without myopia and 6% developed retinal detachments.  The atrophic changes were progressive since among those of the most recent generation, 9.5% had lattice at an average of 11 years whereas 75% in earlier generations had such changes at an average age of 56 years.

Systemic Features: 

No systemic abnormalities have been reported in this disorder.

Genetics

The reported pedigree showed a clear autosomal dominant pattern with male-to-male transmission.

Rhegmatogenous retinal detachments without lattice have also been reported in autosomal dominant patterns but at least some are due to mutations in COL2A1.

Pedigree: 
Autosomal dominant
Treatment
Treatment Options: 

Repair of the retinal detachment is indicated. No information regarding the benefits of prophylactic treatment is available. It may be prudent to counsel patients with this mutation to avoid contact sports and blunt trauma.

References
Article Title: 

Vitreoretinopathy with Epiphyseal Dysplasia

Clinical Characteristics
Ocular Features: 

The axial length is relatively normal in this disorder.  The vitreous is described as highly disorganized but without membranes or the usual lamellar array.  Lattice degeneration may be seen in all quadrants and rhegmatogenous retinal detachments are a lifelong risk, occurring as early as the second decade of life.

Systemic Features: 

This is a unique type of type II collagenopathy with joint and vitreous disease.  Patients do not have the short stature or midface hypoplasia of Kniest dysplasia (156550) nor the optically empty vitreous of Stickler syndrome type I (609508, 108300) caused by mutations in the same gene.  The arthropathy secondary to the epiphyseal dysplasia is mainly in the fingers but some patients do have premature degenerative hip disease.  The fingers are described as ‘stubby’.

Genetics

Mutations in the COL2A1 gene, important for collagen formation, cause various autosomal dominant skeletal dysplasias and some [Stickler type I (609508, 108300) syndrome and Kniest dysplasia (156550)] including this one exhibit vitreoretinopathy.  This is an example of allelic heterogeneity in which various alleles of COL2A1 cause clinically distinguishable phenotypes of bone and ocular disease.  Collagen II is found in cartilage and vitreous perhaps accounting for the associated clinical findings.

Pedigree: 
Autosomal dominant
Treatment
Treatment Options: 

Retinal detachments, of course, require repair.  The lifelong risk of detachments requires monitoring.

References
Article Title: 

The phenotypic spectrum of COL2A1 mutations

Nishimura G, Haga N, Kitoh H, Tanaka Y, Sonoda T, Kitamura M, Shirahama S, Itoh T, Nakashima E, Ohashi H, Ikegawa S. The phenotypic spectrum of COL2A1 mutations. Hum Mutat. 2005 Jul;26(1):36-43.

PubMed ID: 
15895462

Marshall Syndrome

Clinical Characteristics
Ocular Features: 

Myopia is a common feature.  The globes appear prominent with evident hypertelorism, perhaps in part due to shallow orbits.  The vitreous is abnormally fluid.  The beaded vitreous pattern seen in Stickler syndrome type II (604841), with which Marshall syndrome is sometimes confused, is not seen in Marshall syndrome, nor is the same frequency of retinal detachments.  Congenital or juvenile cataracts were present in Marshall’s original family.

Systemic Features: 

The midface is flat with some features of the Pierre-Robin phenotype.  The nasal root is flat and the nares anteverted.  Patients tend to be short in stature and joints are often stiff.  Small iliac wings and a thickened calvarium can be seen radiologically together with other bone deformities.  Abnormal frontal sinuses and intracranial calcifications have also been reported.  Sensorineural hearing loss may be noted during the first year of life with age-related progression.  Osteoarthritis of the knees and lumbosacral spine begins in the 4th and 5th decades.  Features of anhidrotic ectodermal dysplasia such as hypohidrosis and hypotrichosis are present in some patients.  Individuals may have linear areas of hyperpigmentation on the trunk and limbs.

Genetics

The syndromal status of Marshall syndrome as a unique entity remains uncertain inasmuch as there are many overlapping clinical features with Stickler syndrome type II (604841) and both result from mutations in the COL11A1 gene (1p21).  Autosomal dominant inheritance is common to both although autosomal recessive inheritance has been proposed for a few families with presumed Marshall syndrome. Stickler syndrome type II (604841) and Marshall syndrome may be allelic or even the same disorder.

Pedigree: 
Autosomal dominant
Autosomal recessive
Treatment
Treatment Options: 

No treatment is available for this disorder beyond cataract removal.  Patients need to be monitored for retinal breaks and detachments.

References
Article Title: 

Stickler Syndrome, Type II

Clinical Characteristics
Ocular Features: 

Virtually all (85%) patients have a nonprogresssive axial myopia.  The vitreous degeneration has a beaded pattern without the veils of type I, claimed by some to be important in the distinction of the two types.  Paravascular lattice retinopathy is seen in 38% of patients and 64% have cataracts, sometimes with wedge opacities similar to those in type I Stickler syndrome.  Nearly half (42%) of patients are reported to have retinal detachments.

Systemic Features: 

Hearing loss occurs early and many individuals (80%) eventually require hearing aids.    Midline clefting is present frequently with bifid uvula, a highly arched palate, or an actual cleft palate.  Joint laxity is common.

Genetics

There are reasons to classify type II Stickler syndrome as a unique disorder apart from type I (108300).  In addition to phenotypic evidence (vitreoretinal disease, amount of hearing loss, and degree of epiphyseal disease), mutation in two different genes are involved.  Type II results from a mutation in the COL11A1 (1p21) and type I (108300) in COL2A1.  Both types are inherited in autosomal dominant patterns.

Type IV (614234) with vitreoretinal changes, myopia, and a high risk of retinal detachment is inherited in an autsomal recessive pattern.

Pedigree: 
Autosomal dominant
Treatment
Treatment Options: 

Patients with type II Stickler disease need lifelong ophthalmologic monitoring because of the risk of retinal detachments and cataracts with treatment as indicated.
 

References
Article Title: 

Clinical features of type 2 Stickler syndrome

Poulson AV, Hooymans JM, Richards AJ, Bearcroft P, Murthy R, Baguley DM, Scott JD, Snead MP. Clinical features of type 2 Stickler syndrome. J Med Genet. 2004 Aug;41(8):e107.

PubMed ID: 
15286167

Ehlers-Danlos Syndrome, Type VIA

Clinical Characteristics
Ocular Features: 

The globe is thin and fragile and ruptures easily.  This results from scleral fragility which is in contrast to type VIB EDS  (229200) in which the cornea seems to be more fragile.  Retinal detachment is always a risk but no quantitative assessment can be made since early case reports did not always provide good classification of EDS types.  Other ocular abnormalities such as keratoconus and structural changes in the cornea are less common but frequent changes in classification and lack of genotyping in early cases make definitive clinical correlations difficult.

Systemic Features: 

The primary clinical manifestations of this form (VIA) of Ehlers-Danlos syndrome are extraocular.   The skin is soft, thin, easily extensible, and bruises easily.  The joints are highly flexible with a tendency to dislocate.  Arterial ruptures are not uncommon, often with severe consequences.  Scoliosis begins almost at birth and often progresses to severe kyphoscoliosis.  Patients are floppy (hypotonic).  Intellect is normal and there are generally no developmental delays.  Thirty per cent of infants have a club foot at birth.

Genetics

This an autosomal recessive disorder caused by molecular defects in the PLOD1 gene (1p36.3-p36.2).  The gene product is an enzyme, lysyl hydroxylase 1, important for the normal crosslinking of collagen. Mutations in PLOD1 may result in hydroxylase dysfunction with abnormal hydroxylation of lysine, weakened crosslinks, and fragile tissue.  

The classification of Ehlers-Danlos disease is under constant revision as new mutations and clinical subtypes are found (see 130000).

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

Joint dislocations, ocular trauma and vascular ruptures require prompt attention.  Longevity is not impacted by this syndrome.

References
Article Title: 

Kniest Dysplasia

Clinical Characteristics
Ocular Features: 

High myopia and vitreoretinal degeneration are characteristic ocular features in this disorder.   The myopia is in the range of -7.5 to -15.25 with most patients having about -11 diopters.  Acuity may be normal but inoperable retinal detachments can lead to blindness.  The vitreous demonstrates liquefaction and syneresis and often detaches posteriorly forming a retrolental curtain.  About half of affected eyes have perivascular lattice degeneration and the same proportion of patients at some point develop a retinal detachment.  Giant tears and retinal dialysis are commonly the cause.  The lens is often dislocated and cataracts are common.

Systemic Features: 

Short stature, cleft palate, stiff joints, and conductive hearing loss are characteristic extraocular features of Kniest dysplasia.  Some patients develop frank joint contractures and many are unable to make a tight fist due to inflexibility of the interphalangeal joints.  Lumber kyphoscoliosis is common.  Epiphyseal cartilage has a 'Swiss cheese appearance' with prominent lacunae.  The facies are round and the midface is underdeveloped with a flat nasal bridge.  Mild psychomotor retardation is sometimes seen.  

High levels of keratin sulfate are found in the urine.

Genetics

Mutations in the COL2A1 gene (12q13.11-q13.2) coding for type II collagen is responsible for this autosomal dominant disorder. This is one of a number of disorders known as type II collagenopathies (see Stickler syndrome I [609508]).  The clinical features arise from a defect in type II procollagen.

Pedigree: 
Autosomal dominant
Treatment
Treatment Options: 

There is no treatment for the dysplasia.  Displaced lenses can be removed but the myopia and degenerated vitreous require a cautious approach.  Rhegmatogenous detachments demand prompt attention.

References
Article Title: 

Ophthalmic and molecular genetic findings in Kniest dysplasia

Sergouniotis PI, Fincham GS, McNinch AM, Spickett C, Poulson AV, Richards AJ, Snead MP. Ophthalmic and molecular genetic findings in Kniest dysplasia. Eye (Lond). 2015 Jan 16. doi: 10.1038/eye.2014.334. [Epub ahead of print].

PubMed ID: 
25592122

The Kniest syndrome

Siggers CD, Rimoin DL, Dorst JP, Doty SB, Williams BR, Hollister DW, Silberberg R, Cranley RE, Kaufman RL, McKusick VA. The Kniest syndrome. Birth Defects Orig Artic Ser. 1974;10(9):193-208.

PubMed ID: 
4214536

Retinoblastoma

Clinical Characteristics
Ocular Features: 

Retinoblastoma is the most common intraocular malignancy of childhood occurring in 1 in 18,000 to 1 in 30,000 live births worldwide. The majority of cases are diagnosed before the age of 3 years. The most common clinical feature at time of diagnosis is leukocoria (white pupillary reflex) followed by strabismus. Other presenting features include intraocular inflammation, spontaneous hyphema, hypopyon, heterochromia, proptosis, spontaneous globe perforation, retinal detachment, cataract, neovascularization of iris, glaucoma, nystagmus, tearing and anisocoria.

Retinoblastoma can usually be observed during fundus exam as a white subretinal or vitreous mass, occasionally with multifocal nodules, typically with calcification of the surface. The growth of the tumor can be endophytic, exophytic or diffuse. Endophytic growth of retinoblastoma occurs when the tumor penetrates the inner limiting membrane of the retina and can result in vitreous seeding and growth and can simulate iridocyclitis or endophthalmitis.  Exophytic growth occurs when the tumor grows into the subretinal space, which results in accumulation of subretinal fluid and retinal detachments. If the tumor infiltrates Bruchs membrane, there is an increased risk of invasion of choroidal vessels or ciliary nerves and vessels. Diffuse growth is rare and characterized by slow infiltration of retina with diffuse thickening.

Imaging studies such as ultrasound, computerized tomography, and MRI can show the extent of tumor and the presence of calcification.

Systemic Features: 

In heritable cases there is an increased risk of developing other malignant neoplasms throughout life such as osteosarcomas, cutaneous melanomas, pinealomas, and thyroid carcinomas. The risk for secondary malignancies is higher in areas treated with radiation, where osteogenic sarcoma, fibrosarcoma and soft tissue sarcomas may occur. Patients should be closely monitored for secondary tumors throughout life.

Genetics

Retinoblastoma is a malignant tumor of the developing retinal cells caused in most cases by mutations in both copies of the RB1 gene.  The RB1 gene is a tumor suppressor gene, located on chromosome 13q14 and is the first human cancer gene to be cloned. The gene codes for the tumor suppressor protein pRB, which by binding to the transcription factor E2F, inhibits the cell from entering the S-phase during mitosis.  Recent evidence suggests that post-mitotic cone precursors are uniquely sensitive to pRB depletion and may be the cells in which retinoblastoma originates.

However, more recent information suggests that the occurrence and viability of retinoblastic cells may be more complex than suggested by simple loss of function of the RB1 alleles.  There is increasing evidence for the role of epigenetic factors such as DNA methylation impacting the differential expression of more than 100 additional genes which may be influencing the retinoblastoma phenotype.  Among these is an upregulation of spleen tyrosine kinase (SYK) required for tumor cell survival which, if inhibited, leads to retinoblastoma cell death in vivo and in vitro.

Pedigrees of familial cases have an autosomal dominant pattern but the disease requires homozygosity of the RB1 mutation.  This complicates genetic counseling for retinoblastoma. One third of cases have a germline mutation with a mutation in only one of the two gene copies in every cell.  A somatic mutation in the second allele then leads to  homozygosity causing tumor development.  Since one of the parents contributed the germinal mutation, and there is high penetrance (as much as 85%), this leads to the autosomal dominant pattern in these families. In 6% of retinoblastoma cases with germline mutations the family history is positive. The risk for developing bilateral and multifocal retinoblastoma is high and the age of onset is around 14 months.  This is the case for virtually all bilateral tumors.  The mean number of tumors is about 5 in the two eyes.  The offspring of a parent with bilateral retinoblastoma have a 45% chance of developing a tumor (they have a 50% chance of inheriting the germline mutant allele).  Reduced penetrance of 10 to 15% lowers the expected occurrence of disease from 50% to 45%.

However, two thirds of cases are of non-germinal origin with both somatic mutations occurring in a single retinal progenitor cell.  Because this is a highly unlikely event, these cases are generally unilateral and unifocal with an average age of onset of 24 months. Sporadic cases constitute about 94% of all retinoblastomas, of which about 60% have unilateral disease with no germline mutations.  Individuals who acquire mutations in both alleles somatically (with single, unilateral tumors) do not have a mutation in their germ cells and therefore usually transfer no tumor risk to their offspring.  Laterality and number of tumors alone, however, cannot be used for accurate predictions in this case since about 15% of patients with unilateral and monofocal tumors actually have germline mutations.  This leaves a residual risk of transferring heritability of about 1-5% in unilateral patients without a family history.

To further complicate the story, recent evidence suggests that retinoblastoma is genetically heterogeneous.  About 6% of patients have no RB1 mutation.  In one study, about half of such individuals have up-regulation of the MYCN oncogene (2p24.3) suggesting a second mechanism leading to clinical retinoblastoma.  For unknown reasons, such tumors tend to  be larger, more aggressive, and discovered at an earlier age than unilateral non-familial RB1 tumors.  The MYCN gene product is a transcription factor important for organ development during embryogenesis.  Its amplification has been implicated in about 25% of neuroblastomas.

Pedigree: 
Autosomal dominant
Treatment
Treatment Options: 

Enucleation may be necessary to eliminate the primary tumor, especially large ones, but other treatments can be used successfully to treat smaller tumors and spare vision. Intravenous chemotherapy is the most common treatment, which can be combined with subtenon chemotherapy, cryotherapy, thermotherapy, and plaque brachytherapy. External beam radiation can be used for refractive cases and recurrences. Another treatment alternative is localized ophthalmic artery intra-arterial chemotherapy.

It is necessary to follow all offspring of parents with bilateral tumors throughout the first decade because of the risk for new tumor development, as late as 5 to 7 years of age.   There are even a few case reports of retinoblastoma diagnosed in adults. However, since the retinal cells are generally mature by the age of 2.5 years, such events are very rare.  All parents of children with retinoblastoma should have complete fundus evaluations since rare tumors spontaneously regress leaving retinal scars, which in such a family pattern suggests that a germline mutation was inherited.

Survivors of hereditary retinoblastomas must be followed the rest of their lives, and especially so if radiation treatment was applied, because of the high risk of developing secondary neoplasms.  The risk rises with age.

References
Article Title: 

Characterisation of retinoblastomas without RB1 mutations: genomic, gene expression, and clinical studies

Rushlow DE, Mol BM, Kennett JY, Yee S, Pajovic S, Th?(c)riault BL, Prigoda-Lee NL, Spencer C, Dimaras H, Corson TW, Pang R, Massey C, Godbout R, Jiang Z, Zacksenhaus E, Paton K, Moll AC, Houdayer C, Raizis A, Halliday W, Lam WL, Boutros PC, Lohmann D, Dorsman JC, Gallie BL. Characterisation of retinoblastomas without RB1 mutations: genomic, gene expression, and clinical studies. Lancet Oncol. 2013 Mar 12:327-34.

PubMed ID: 
23498719

A novel retinoblastoma therapy from genomic and epigenetic analyses

Zhang J, Benavente CA, McEvoy J, Flores-Otero J, Ding L, Chen X, Ulyanov A, Wu G, Wilson M, Wang J, Brennan R, Rusch M, Manning AL, Ma J, Easton J, Shurtleff S, Mullighan C, Pounds S, Mukatira S, Gupta P, Neale G, Zhao D, Lu C, Fulton RS, Fulton LL, Hong X, Dooling DJ, Ochoa K, Naeve C, Dyson NJ, Mardis ER, Bahrami A, Ellison D, Wilson RK, Downing JR, Dyer MA. A novel retinoblastoma therapy from genomic and epigenetic analyses. Nature. 2012 Jan 11;481(7381):329-34.

PubMed ID: 
22237022

Marfan Syndrome

Clinical Characteristics
Ocular Features: 

Marfan syndrome typically has skeletal, ocular and cardiovascular abnormalities.  The globe is elongated creating an axial myopia and increasing the risk of rhegmatogenous retinal detachments.  Ectopia lentis is, of course, the classical ocular feature and is often if not always congenital with some progression.  The lenses most frequently dislocate superiorly and temporally and dilating the pupils often reveals broken and retracted lens zonules.  Phacodenesis and iridodenesis are commonly present even in the absence of evident lens dislocations. Cataracts develop several decades earlier than in unaffected individuals. The cornea is generally several diopters flatter than normal and there is an increased risk of open angle glaucoma.  There is considerable clinical variation among patients.

Systemic Features: 

Patients with the Marfan phenotype are usually tall with disproportionately long limbs (dolichostenomelia) and digits (arachnodactyly).   Patients frequently have scoliosis or kyphoscoliosis.  The joints are lax and hyperflexible although contractures can also occur.  The sternum is often deformed, either as a pectus excavatum, or sometimes pectus carinatum.  The hard palate is high and narrow resulting in crowding of the teeth and maloccclusion.  The defect in fibrillin is responsible for the weakness in connective tissue that leads to frequent cardiac valve malfunction, especially insufficiency of the aortic valve resulting from aortic dilatation, tear, and rupture.  The latter is often life-threatening as aortic dissection can be fatal.  Mitral valve prolapse is seen as well.  Cardiovascular disease is primarily responsible for the shortened life expectancy in this disease, more pronounced among males.

Genetics

As many as 25% of cases are caused by new mutations, but familial cases usually follow an autosomal dominant pattern of inheritance.  Autosomal recessive inheritance is claimed for several individuals in a consanguineous Turkish family.  Mutations in the fibrillin-1 gene (FBN1) on chromosome 15 (15q21.1) are considered responsible for the typical phenotype.  The exact nature of the fibrillin defect is unknown but the result is a generalized weakness in connective tissue.

The same gene is mutant in the autosomal dominant form of the Weill-Marchesani syndrome (608328) which is allelic to the Marfan syndrome.

Mutations in FBN1 have also been found in cases with isolated autosomal dominant ectopia lentis (129600).

Pedigree: 
Autosomal dominant
Treatment
Treatment Options: 

Isometric exercises such as weight lifting should be avoided as should contact sports in which blunt trauma to the chest may occur because of the weakened aortic wall due to cystic changes that predispose the athlete to aortic dissection.  A dislocated and/or cataractous lens may need to be removed from the visual axis, and, of course, periodic retinal examinations for retinal holes and retinal detachments should be made.   Beta-adrenergic blockade reduces the risk of aortic dilatation and improves survival.

Pravastatin has been reported to reduce aortic dilation in marfan mice.

References
Article Title: 

Pravastatin reduces marfan aortic dilation

McLoughlin D, McGuinness J, Byrne J, Terzo E, Huuskonen V, McAllister H, Black A, Kearney S, Kay E, Hill AD, Dietz HC, Redmond JM. Pravastatin reduces marfan aortic dilation. Circulation. 2011 Sep 13;124(11 Suppl):S168-73.

PubMed ID: 
21911808

Retinoschisis, Juvenile

Clinical Characteristics
Ocular Features: 

Retinoschisis is a retinal disorder characterized by a cystic degeneration of the retina, leading to a split of retinal layers mainly at the level of the nerve fiber layer. Almost all patients have macular involvement, most commonly with foveal spoke-like streaks consisting of microcystic cavities that may coalesce over time. Retinal pigment epithelium atrophy and pigment clumping may occur.  Peripheral schisis is evident in about 50% of patients with large bullous cavities that may resolve spontaneously leaving a pigmented demarcation line. Other retinal findings are white retinal flecks, exudative retinopathy with retinal detachment, perivascular sheathing and dendritiform vessels in the periphery. Vitreous veils are commonly seen that are caused by separation of the thin inner wall of a peripheral schisis cavity and inner wall holes. Bridging vessels may rupture into the cystic cavity or the vitreous. The onset of the disorder has been detected as early as three months, but the majority of cases are five years old or older. Many present with mildly decreased vision that cannot be corrected with glasses and the diagnosis is often delayed. Visual acuity is highly variable ranging from 20/20 to 20/200, but may decline with age and with complications such as vitreous hemorrhage and macular detachment.  The disorder is also associated with axial hyperopia, posterior subcapsular cataract and strabismus. Fluorescein angiography shows minimal or no leakage as opposed to cystoid macular edema. Focal areas of vascular leakage into schisis cavity may be present as well as peripheral capillary nonperfusion. Electroretinograms exhibit a reduced b-wave and a preserved a-wave.

Systemic Features: 

No general systemic manifestations are associated with juvenile retinoschisis.

Genetics

Juvenile retinoschisis is an X-linked recessive disorder that affects mainly males. The causative mutations involve the gene RS1 located on the X chromosome at Xp22. Female carriers may have peripheral schisis amd many allelic variants have been reported.  The encoded protein retinoschisin is a secreted protein produced by photoreceptors and bipolar cells and may be involved in cell-cell adhesion or ion channel regulation.

Treatment
Treatment Options: 

There is presently no effective treatment for the disorder, but decreased vision later in life can be aided with low vision aids. Cases with posterior subcapsular cataract can be treated with cataract extraction.  Improvement in the cystic macular lesions, central foveal zone thickness, and visual acuity have been reported to benefit from topical dorzolamide treatment.

References
Article Title: 

Peripheral fundus findings in X-linked retinoschisis

Fahim AT, Ali N, Blachley T, Michaelides M. Peripheral fundus findings in X-linked retinoschisis. Br J Ophthalmol. 2017 Mar 27. pii: bjophthalmol-2016-310110. doi: 10.1136/bjophthalmol-2016-310110. [Epub ahead of print].

PubMed ID: 
28348004

X-linked retinoschisis: an update

Sikkink SK, Biswas S, Parry NR, Stanga PE, Trump D. X-linked retinoschisis: an update. J Med Genet. 2007 Apr;44(4):225-32. 2006 Dec 15.

PubMed ID: 
17172462

Nanophthalmos 2

Clinical Characteristics
Ocular Features: 

In this condition the axial length of the globe is often only 14-16 mm (normal >20 mm) resulting in extreme hyperopia of +8-25 diopters.  Corrected vision is usually 20/40 to 20/80 but 20/200 is not uncommon.  The choroid and sclera are thickened in nanophthalmos to a greater degree than seen in common mild hyperopia.  While all ocular structures are small in microphthalmia, in nanophthalmos the lens dimensions are generally normal.  In a small globe this causes ‘crowding’ of the anterior chamber angles and angle closure glaucoma is a major risk.

Folds in the choroid and retina are common.  Choroidal effusions, retinal edema and retinal detachments are not uncommon.  The retinal pigment epithelial may have mild window defects.  Hypoplasia, cysts, yellowish discoloration, and horizontal striae of the macula have been reported.  The foveal reflex is frequently absent corresponding to the lack of a normal foveal pit as revealed by OCT.  The foveal avascular zone may be small or absent.  The disks often appear crowded.  ERGs and VEPs are usually normal.   Scleral collagen is abnormal and thickened, leading to the postulation that this interferes with suprachoroidal drainage resulting in effusion and non-rhegmatogenous retinal detachments.

Systemic Features: 

No systemic disease has been consistently associated with simple nanophthalmos. Individuals with Kenny’s syndrome, Hallerman-Streiff-Francois (234100) syndrome and oculodentodigital dysplasia syndrome (164200) with nanophthalmos have been reported.

Genetics

Nanophthalmos may result from several mutations. Most cases occur sporadically but familial cases suggesting autosomal recessive inheritance (NNO2, 609549) have been reported. The mutation is a frameshift insertion, 1143C, in the MFRP gene on chromosome 11 (11q23.3) and has been found in the homozygous configuration in several families. The protein product has a domain that may be related to the Frizzled family of transmembrane  cell-cell signaling molecules responsible for regulation of growth and differentiation. In this connection, it is of interest that this gene is highly expressed in the retinal pigment epithelium.

It seems that at least two dominant mutations can also cause nanophthalmos. One (NNO3, 611897), located on chromosome 2 (2q11-q14), has been identified in a large Chinese pedigree although the molecular mutation remains unknown. Another, NNO1, (600165), has also been mapped to chromosome 11 but at 11p.  The molecular mutations also remain unknown.

Homozygous mutations in serine protease PR2258 have also been reported in several families with nanophthalmos.

Pedigree: 
Autosomal dominant
Autosomal recessive
Treatment
Treatment Options: 

Prophylactic iridotomies should be considered.
 

References
Article Title: 

Familial nanophthalmos

Cross HE, Yoder F. Familial nanophthalmos. Am J Ophthalmol. 1976 81(3):300-6.

PubMed ID: 
1258954

The nanophthalmic macula

Serrano JC, Hodgkins PR, Taylor DS, Gole GA, Kriss A. The nanophthalmic macula. Br J Ophthalmol. 1998 Mar;82(3):276-9.

PubMed ID: 
9602624

Mutations in a novel serine protease PRSS56 in families with nanophthalmos

Orr A, Dub?(c) MP, Zenteno JC, Jiang H, Asselin G, Evans SC, Caqueret A, Lakosha H, Letourneau L, Marcadier J, Matsuoka M, Macgillivray C, Nightingale M, Papillon-Cavanagh S, Perry S, Provost S, Ludman M, Guernsey DL, Samuels ME. Mutations in a novel serine protease PRSS56 in families with nanophthalmos. Mol Vis. 2011;17:1850-61.  PubMed PMID: 21850159.

PubMed ID: 
21850159

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