cataracts

Myotonic Dystrophy 2

Clinical Characteristics
Ocular Features: 

Polychromatic lens opacities and posterior subcapsular sclerosis are found in 15-30% of patients. 

Ptosis, ophthalmoplegia and strabismus are not features of DM2.As many as 25% of patients with DM have a pigmentary retinopathy, usually in a butterfly pattern.

Systemic Features: 

Symptoms of myotonia usually appear in the third and fourth decades of life while evidence of limb girdle muscle weakness usually appears much later.  There is no infancy or childhood form of the disease and developmental delays do not occur.   In some patients the proximal muscles seem to be more affected than distal muscles and such cases are sometimes referred to as PROMM disease.  In these patients the neck and finger flexors may be the first to be affected.  However, there is considerable clinical variability.  Facial weakness is minimal.  Eventually both proximal and distal muscles weaken.  Myalgia of a burning, tearing nature can be debilitating.  Cardiac arrhythmias occur in a minority of patients.  Frontal balding is characteristic.  The long-term prognosis is better than in patients with myotonic dystrophy 1 (160900), and some but not all reports suggest fewer individuals experience age-related cognitive decline.  Insulin insensitivity and testicular failure occur in approximately half of patients.

PROMM disease and DM2 are now generally accepted as the same disease and the latter designation is preferred.

Genetics

Like classic myotonic dystrophy 1 (160900), this disorder also results from an abnormal number of repeats (in this case of CCTG).  Up to 30 tetranucleotide repeats in CNBP (3q21.3) is normal but patients with myotonic dystrophy 2 may have 11,000 or more and the number increases with age.  The repeat length may diminish with generational transmission.  Unlike DM 1, the repeat number does not seem to correlate with disease severity.  Both DM1 and DM2 are inherited in an autosomal dominant pattern.

Pedigree: 
Autosomal dominant
Treatment
Treatment Options: 

There is no treatment for the muscle disease but many patients require analgesic medication for muscle pain.  Visually significant cataracts should be removed.  Some patients require supportive care.

References
Article Title: 

Myotonic Dystrophy 1

Clinical Characteristics
Ocular Features: 

Posterior subcapsular cataracts may be seen at any age, often with striking iridescent opacities in the overlying cortex as well.  These polychromatic lens changes can be diagnostic but are present in only 50% of young adults with myotonic dystrophy.  When present, they are almost always bilateral.  Proximal muscle involvement leads to ptosis, strabismus, weakness of the orbicularis oculi, and sometimes ophthalmoplegia.  Such muscle weakness may lead to exposure keratitis. 

As many as 25% of patients with DM have a pigmentary retinopathy, usually in a butterfly pattern.

A low IOP and even hypotony is sometimes seen.  The mean IOP in a series of 51 patients has been reported as 10.9 compared with 15.4 in controls.  Using ultrasound biomicroscopy, ciliary body detachments were found in at least one quadrant of all eyes.

Systemic Features: 

In the congenital form, hypotonia, generalized weakness, mental retardation and respiratory insufficiency are often present.  There is a great deal of clinical heterogeneity among patients.  Those with mild disease may have only cataracts and mild myotonia with a normal life expectancy.  Those with more severe disease (classical myotonic dystrophy) have these signs plus marked muscle weakness and wasting.  Cardiac conduction defects with secondary arryhthmias are a significant cause of mortality. Such patients tend to become disabled in adulthood.  Symptoms become evident in the second decade or later.  Deep muscle pain is common and can be severe.  Distal muscle weakness usually begins before facial muscle weakness is apparent.  Myotonia often involves the tongue while proximal muscle weakness can cause dysphagia and dysarthria.  Such patients may also suffer respiratory distress. Reproductive fitness is reduced in males who can have gonadal atrophy.  Frontal balding is common.  Some age-related cognitive decline occurs.

Over 60% of patients have a hearing impairment and more than half of these have auditory brainstem response abnormalities.  Vestibular hypesthesia is present in 37.5%.

Genetics

Myotonic dystrophy 1 is an autosomal dominant disorder caused by a trinucleotide (CTG) repeat expansion in a region of the DMPK gene (19q13.2-q13.3).  The number of repeats varies widely and is roughly correlated with severity of disease.  Infants with congenital myotonia usually have the highest number of repeats and have the most severe cognitive deficits.  The number can expand during gametogenesis each generation (resulting in the phenomenon of anticipation) and females generally transmit larger numbers.  Most infants with congenital myotonia are offspring of affected mothers.  Reduced fetal movement and hydramnios are often noted during such pregnancies.

Affected males have few offspring secondary to gonadal atrophy.  Affected heterozygous females, however, do not have the expected ratio of affected offspring because of the dynamic nature of the number of repeats.  The risk of an affected offspring for a nulliparous afflicted female is only 3-9% and she has a 20-40% risk of recurrence after the birth of an affected child.

In a study of sibships with myotonic dystrophy, 58% of offspring were affected when the transmitting parent was male and 63% when the transmitting parent was female.

At least some of the variable transmission risks and clinical heterogeneity may be explained by somatic instability of the CTG repeat numbers.  The degree of instability, moreover, may also be heritable.  Age of onset, for example, is modified by the level of somatic instability.  Further, patients in whom the repeat expands more rapidly develop symptoms earlier. 

A similar disorder, myotonic dystrophy 2 (602668), is caused by a tetranucleotide repeat expansion in the CNBP gene.

Pedigree: 
Autosomal dominant
Treatment
Treatment Options: 

A variety of pharmaceutical agents have been tried for pain management without consistent results.  No treatment improves the muscle weakness.  Cholesterol lowering drugs such as statins should be avoided.  Physical therapy may be helpful.

Cardiac conduction and structural defects are a significant threat even in asymtomatic patients and require constant monitoring for the development of arrythmias.

References
Article Title: 

Inner ear dysfunction in myotonic dystrophy type 1

Balatsouras DG, Felekis D, Panas M, Xenellis J, Koutsis G, Kladi A, Korres SG. Inner ear dysfunction in myotonic dystrophy type 1. Acta Neurol Scand. 2012 Nov 5. doi: 10.1111/ane.12020. [Epub ahead of print].

PubMed ID: 
23121018

Somatic instability of the expanded CTG triplet repeat in myotonic dystrophy type 1 is a heritable quantitative trait and modifier of disease severity

les F, Couto JM, Higham CF, Hogg G, Cuenca P, Braida C, Wilson RH, Adam B, Del Valle G, Brian R, Sittenfeld M, Ashizawa T, Wilcox A, Wilcox DE, Monckton DG. Somatic instability of the expanded CTG triplet repeat in myotonic dystrophy type 1 is a heritable quantitative trait and modifier of disease severity. Hum Mol Genet. 2012 May 16. [Epub ahead of print].

PubMed ID: 
22595968

Incidence and predictors of sudden death, major conduction defects and sustained ventricular tachyarrhythmias in 1388 patients with myotonic dystrophy type 1

Wahbi K, Babuty D, Probst V, Wissocque L, Labombarda F, Porcher R, Becane HM, Lazarus A, Behin A, Laforet P, Stojkovic T, Clementy N, Dussauge AP, Gourraud JB, Pereon Y, Lacour A, Chapon F, Milliez P, Klug D, Eymard B, Duboc D. Incidence and predictors of sudden death, major conduction defects and sustained ventricular tachyarrhythmias in 1388 patients with myotonic dystrophy type 1. Eur Heart J. 2016 Dec 9. pii: ehw569. [Epub ahead of print] PubMed.

PubMed ID: 
27941019

Histiocytic Dermatoarthritis

Clinical Characteristics
Ocular Features: 

This disorder has some ocular similarities to dermochondrocorneal dystrophy of Francois (221800) such as the presence of cataracts, but differs in the absence of corneal opacities.  All patients examined have had glaucoma, uveitis and lens opacities.  Gonioscopy in one patient showed multiple anterior synechiae and another patient, an adult, had buphthalmos.

Systemic Features: 

Skin lesions and stiff, painful joints develop between 4 and 15 years of age.   The cutaneous nodules are found primarily on the hands, ears and the upper extremities.  These are nonulcerating, tender, violaceous to brown in color, and firm in consistency.  Firm subcutaneous plaques apparent only on palpation are also present.  No mucosal lesions or xanthelasmata are present.  Deforming, symmetric arthritis of the hands, feet and elbows is frequently seen with periarticular bony resorption.  The skin of the legs and feet are thick and lichenified.  Histology of the skin lesions shows a granulomatous appearance with a chronic inflammatory infiltrate.  No multinucleated giant cells are seen.

Genetics

A single family with 4 affected sibs born to an affected male parent has been reported which suggests autosomal dominant inheritance.  The mutation, if any, is unknown.

Pedigree: 
Autosomal dominant
Treatment
Treatment Options: 

The glaucoma should, of course, be treated but no treatment is available for the systemic disease beyond orthopedic correction of the joint deformities.

References
Article Title: 

Niemann-Pick Disease, Types A and B

Clinical Characteristics
Ocular Features: 

Affected infants usually develop prominent cherry red spots during the first 12 months of life and the entire retina has an ‘opaque’ appearance.  Intracellular lipid accumulation has been seen in retinal neurons, amacrine cells, retinal pigment epithelial cells, and receptors.  The cornea has stromal haziness.  The lens has a brownish coloration on the anterior surface with white spots on the posterior capsule.  Lens opacification seems to progress.

Vision in the first year of life is likely normal as infants have normal fixation, pupillary reactions, and following movements with no nystagmus.  However, by about 2 years of age visual responsiveness may be lost.

Systemic Features: 

Both the age of onset of neurological symptoms and the rate of progression are highly variable. Type A, known as the infantile form, is the more severe disease with onset by 6 months of age with rapid progression and few patients survive beyond three years of age.  Neonates seem to develop normally for the first 6 months but then become irritable, fail to thrive and feed poorly.  Hepatosplenomegaly is usually the first physical sign.  Hypotonia and pulmonary infections are common.  These patients never achieve normal developmental milestones such as sitting, walking or crawling and the neurodegeneration is relentless from this point with the median age at death 21 months, usually from respiratory disease.

The less severe form of Niemann-Pick disease, type B, has a later onset and slower course.  Such patients have widespread visceral disease affecting liver, spleen and lungs with hyperlipidemia but few neurologic symptoms and often survive into adulthood.  Mutations in the same gene are involved, however.  

Other rare cases have intermediate disease and some have proposed these be classified as types E and F but the phenotypes have not been well characterized.  The benefits of such a classification system are questionable as all result from mutations in the same gene simply illustrating the range in the clinical spectrum.

Sphingomyelin and other lipids accumulate in cells of various types including neurons and reticuloendothelial cells accounting for the hepatosplenomegaly and neurodegeneration.  Sphingomyelinase deficiency can be demonstrated in leukocytes and cultured fibroblasts.

Genetics

This is an autosomal recessive neurodegenerative disorder resulting from homozygous mutations in SMPD1 (11p15.4-p15.1) encoding sphingomyelin phosphodiesterase-1.  This recessive gene has an unusual biology.  Only the maternally inherited allele is active in the homozygous condition.  Such parent-specific gene activation is called gene imprinting.

Types A and B are allelic disorders.  

Niemann-Pick diseases designated types C1 and D (257220) are caused by mutations in the NPC1 gene (18q11-q12) and type C2 (607625)  from mutations in the NPC2 gene (14q24.3).

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

Enzyme replacement therapy trials are underway.  Amniotic membrane, bone marrow, and stem cell transplantation have been tried with some improvement in visceral disease but the results are mixed and await further studies.

References
Article Title: 

Hallermann-Streiff Syndrome

Clinical Characteristics
Ocular Features: 

Nearly all patients (80+ %) have microphthalmia and bilateral congenital cataracts.  Microcornea is common.  The eyebrows may be hypoplastic and the eyelashes likewise are sparse.  The lid fissures often slant down and telecanthus has been noted.  The distance between the two eyes appears reduced.  Blue sclerae, nystagmus, strabismus, and glaucoma are present in 10 to 30% of patients.

Systemic Features: 

The facies are sometimes described as 'bird-like' with a beaked nose, brachycephaly, and micrognathia.  Microstomia with a shortened ramus and forward displacement of the termporomandibular joints is characteristic. Upper airway obstruction may occur with severe respiratory distress.  The forehead is relatively prominent, the palate is highly arched, and the teeth are often small and some may be missing with misalignment of others.  A few teeth may even be present at birth (natal teeth).  Children appear petite and are often short in stature.  Scalp hair is thin, especially in the frontal and occipital areas, and the skin is atrophic.  Developmental delays are common but most patients have normal or near-normal intelligence.

Genetics

Most cases are sporadic but some have mutations in the GJA1 gene (6q21-q23.2).  Both autosomal dominant and autosomal recessive inheritance have been postulated.  Reproductive fitness may be low but rare affected individuals have had affected offspring.  Males and females are equally affected.

This disorder is allelic to oculodentodigital dysplasia (257850, 164200).

Pedigree: 
Autosomal dominant
Autosomal recessive
Treatment
Treatment Options: 

Airway obstruction may require intervention and its risks must be considered during administration of general anesthesia.  Lens opacification may be severe even early in life and requires prompt surgical intervention to prevent amblyopia.

References
Article Title: 

Smith-Lemli-Opitz Syndrome

Clinical Characteristics
Ocular Features: 

A large number of ocular anomalies have been found in SLO syndrome but the most common is blepharoptosis of some degree.  No consistent pattern of ocular abnormalities has been reported.  Atrophy and hypoplasia of the optic nerve, strabismus, nystagmus, and cataracts may be present.   Abnormally low concentrations of cholesterol and cholesterol precursors have been found in all ocular tissues studied.

Systemic Features: 

This is a syndrome of multiple congenital anomalies.  Among these are dwarfism, micrognathia, hard palate anomalies, hypotonia, anomalies of the external genitalia, polysyndactyly, microcephaly, and mental retardation.  It has been suggested that many individuals have a characteristic behavioral profile consisting of cognitive delays, hyperreactivity, irritability, language deficiency, and autism spectrum behaviors.  Some individuals exhibit aspects of self destructive behavior.  Tissue levels of cholesterol are low.

Genetics

SLO syndrome is an autosomal recessive disorder resulting from mutations in the sterol delta-7-reductase  (DHCR7) gene mapped to 11q12-q13. The result is a defect in cholesterol synthesis.

The clinical features significantly overlap those seen in Meckel (249000) and Joubert (213300) syndromes.

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

A high cholesterol diet has been reported to have a beneficial effect on behavior and general well-being.

References
Article Title: 

Cerebrooculofacioskeletal Syndrome

Clinical Characteristics
Ocular Features: 

Congenital cataracts and microphthalmia are frequent findings in this disorder.  Delayed mental development and early death in childhood have limited full delineation of the ocular phenotype.  Photosensitivity, nystagmus, optic nerve atrophy, and pigmentary retinopathy have been reported.  The eyes may appear deeply-set.

Systemic Features: 

Microcephaly, flexion contractures, prominent nasal root and an overhanging upper lip are common features.  Severe developmental and growth delays are evident early followed by progressive behavioral and intellectual deterioration.  Both hypotonia and hyperreflexia have been described.    Kyphosis and scoliosis are common.  CT scans may show intracranial calcifications and brain histology shows severe neurodegeneration with neuronal loss and gliosis.  Respiratory distress may also occur and some individuals have died in the first decade of life.

Genetics

Homozygous mutations in the ERCC6 gene (10q11) seem to be responsible for this autosomal recessive disorder.  Several sets of parents have been consanguineous.  Mutations in the same gene are responsible for Cockayne type B syndrome (133540and some suggest that the variable phenotype represents a spectrum of disease rather than individual entities. Cerebrooculofacioskeletal syndrome represents the more severe phenotype in this spectrum.

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

No treatment is available for this disorder.

References
Article Title: 

Homocystinuria, Beta-Synthase Deficiency

Clinical Characteristics
Ocular Features: 

More than half of patients have ectopia lentis by the age of 10 years and the dislocation is progressive.  Ectopia lentis occurs in 90% of patients and 94% of these are noted by the age of 20 years.  The lenses seem to be more mobile than those in Marfan syndrome with a significantly increased risk of lens migration into the anterior chamber (19%) or complete dislocation into the posterior chamber (14%).   Lens surgery is required in homocystinuria about 7 years earlier than in Marfan syndrome with 62% of procedures necessitated by pupillary block glaucoma or displacement into the anterior chamber.  Whereas nearly 70% of lenses dislocate superiorly in Marfan syndrome, only 9% of homocystinuria lenses do so.

Other ocular features include optic atrophy (23%), iris atrophy (21%), anterior staphylomas (13%) and corneal opacities (9%).  Retinal detachments occur in 5-10%.  The majority of patients both pre- and postoperatively have vision of 20/50 or worse.

Systemic Features: 

Arachnodactyly and tall stature in some patients may suggest Marfan syndrome.  Mental deficiencies or behavioral problems are present in a majority of patients (50-60%) with mental functioning higher in the subset of patients who are B6-responsive.  Thromboembolic events (strokes, myocardial infarctions) are a significant risk at any age, especially so after age 20 years, and this is responsible for considerable morbidity and mortality.  The risk is especially high following general anesthesia unless hydration is strictly controlled.  Osteoporosis and seizures are common.  Hypopigmentation is often present but darkening of hair has been noted following pyridoxine treatment.  Serum homocysteine is generally elevated and the urine contains elevated levels of methionine.

Genetics

Classic homocystinuria is an autosomal recessive disorder that results from mutations in the CBS (21q22.3) gene encoding cystathionine beta-synthase.  It is the second most common error of amino acid metabolism.  Numerous mutations have been identified but among the most common ones are I278T which causes a pyridoxine-responsive disorder, and the G3307S mutation which leads to a variant that is not responsive to pyridoxine treatment.

For another more aggressive form of homocystinuria caused by mutations in MTHFR (1p36.3) see Homosystinuria, MTHER Deficiency (236250).

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

Patients with this disorder form two groups: those who respond to pyridoxine (vitamin B6) and those who do not.  Those who do not respond to B6 tend to have more severe disease.  Methionine restriction administered neonatally has been reported to prevent mental retardation and reduce the rate of lens dislocation.  Neonates should be treated with B6 therapy, protein and methionine restriction, betaine, and folate with vitamin B12 supplementation.  Surgical removal of lenses may be required but the rate of vitreous loss is high.

References
Article Title: 

Familial Exudative Vitreoretinopathy, EVR2

Clinical Characteristics
Ocular Features: 

The basis for many of the ocular complications likely begins with incomplete development of the retinal vasculature.  Resulting retinal ischemia leads to neovascularization, vitreous hemorrhage and traction, and retinal folds, with some 20% going on to develop rhegmatogenous or traction detachments.  There is, however, considerable clinical variability, even within families, with some infants blind from birth whereas some (41%) adults have only areas of remaining avascularity or evidence of macular dragging.  In fact, some affected individuals are asymptomatic and diagnosed only as part of extensive family studies.  Intraretinal lipid is often seen.  Considerable asymmetry in the two eyes is common.  Secondary cataracts often occur and phthisis bulbi results in some patients.  The clinical picture is sometimes confused with retinopathy of prematurity.

Systemic Features: 

No consistent systemic abnormalities have been identified in EVR2.

Genetics

Familial exudative vitreoretinopathy is the name given to a clinically and genetically heterogeneous group of disorders caused by mutations in several genes.  Autosomal dominant (e.g., EVR1; 133780), and X-linked inheritance (this condition) have been reported with the former much more common. 

The X-linked form of FEVR (EVR2 described here) results from mutations in the NDP gene (Xp11.3) and is allelic to Norrie disease (310600).

Retinopathy of prematurity can be called a phenocopy of FEVR.

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

Retinal, vitreal, and cataract surgery are indicated in appropriate cases.

References
Article Title: 

Familial Exudative Vitreoretinopathy, EVR4

Clinical Characteristics
Ocular Features: 

The basis for many of the ocular complications likely begins with incomplete development of the retinal vasculature.  Resulting retinal ischemia leads to neovascularization, vitreous hemorrhage and traction, and retinal folds with some 20% going on to develop rhegmatogenous or traction detachments.  There is, however, considerable clinical variability, even within families, with some infants blind from birth whereas some (41%) adults have only areas of remaining avascularity or evidence of macular dragging.  In fact, some affected individuals are asymptomatic and diagnosed only as part of extensive family studies.  Intraretinal lipid is often seen.  Considerable asymmetry in the two eyes is common. Secondary cataracts often occur and phthisis bulbi results in some patients.  The clinical picture is sometimes confused with retinopathy of prematurity.

Systemic Features: 

Osteoporosis and endosteal hyperostosis has been reported among individuals with mutations in LRP5.

Genetics

The EVR4 form of FEVR results from mutations in the LRP5 gene (11q13.4) and the clinical features may be seen in both heterozygotes and homozygotes.  Thus the disease is inherited in both autosomal dominant and autosomal recessive patterns.  The osteoporosis-pseudoglioma syndrome (259770) is allelic to this condition.

Mutations in the FZD4 gene cause a phenotypically indistinguishable condition (EVR1; 133780) but is always inherited in an autosomal dominant pattern.  There is also an X-linked form (EVR2) caused by a mutation in NDP (305390).

Retinopathy of prematurity can be called a phenocopy of FEVR.

Pedigree: 
Autosomal dominant
Autosomal recessive
Treatment
Treatment Options: 

Retinal, vitreal, and cataract surgery are indicated in appropriate cases.

References
Article Title: 

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