ataxia

Spinocerebellar Ataxia 7

Clinical Characteristics
Ocular Features: 

Pigmentary changes in the retina are somewhat variable but often begin with a granular appearance in the macula and spread into the periphery.  The macula often becomes atrophic and dyschromatopsia is common.   Retinal thinning is evident, especially in the macula.  Decreased visual acuity and loss of color vision are early symptoms and the ERG shows abnormalities of both rod and cone function.  External ophthalmoplegia without ptosis is a frequent sign.  Most adults and some children eventually are blind. 

Systemic Features: 

Symptoms of developmental delay and failure to thrive may appear in the first year of life followed by loss of motor milestones.  Dysarthria and ataxia are nearly universal features while pyramidal and extrapyramidal signs are more variable.  This can be a rapidly progressive disease and children who develop symptoms by 14 months are often deceased before two years of age.  However, adults with mild disease can survive into the 5th and 6th decades.  Peripheral neuropathy with sensory loss and motor deficits are usually present to some degree but the range of clinical disease is wide.  Cognitive decline and some degree of dementia occur sometimes. 

Genetics

Spinocerebellar ataxia 7 is caused by expanded trinucleotide repeats (CAG) in the ATXN7 gene (3p21.1-p12) and inherited in an autosomal dominant pattern.  The number of repeats is variable and correlated with severity of disease.  Most patients with 36 or more repeats have significant disease. This disorder is sometimes classified as a progressive cone-rod dystrophy.  It is sometimes referred to as olivopontocerebellar atrophy type III or OPCA3.

This disorder exhibits genetic anticipation especially with paternal transmission as succeeding generations often have earlier onset with more severe and more rapidly progressive disease. This is explained by the fact that younger generations tend to have a larger number of repeats and sometimes the diagnosis is made in children before the disease appears in parents or grandparents.

Spinocerebellar ataxia 1 (164400) is a similar autosomal dominant disorder with many of the same clinical and genetic features.  It is caused by excess CAG repeats on the ATXN1 gene on chromosome 6. 

Pedigree: 
Autosomal dominant
Treatment
Treatment Options: 

No effective treatment is known for the disease.  Low vision aids and mobility training may be useful in early stages. 

References
Article Title: 

GM1 Gangliosidosis

Clinical Characteristics
Ocular Features: 

Based on clinical manifestations, three types have been described: type I or infantile form, type II or late-infantile/juvenile form, and type III or adult/chronic form but all are due to mutations in the same gene.  Only the infantile form has the typical cherry red spot in the macula but is present in only about 50% of infants.  The corneal clouding is due to intracellular accumulations of mucopolysaccharides in corneal epithelium and keratan sulfate in keratocytes.  Retinal ganglion cells also have accumulations of gangliosides.  Decreased acuity, nystagmus, strabismus and retinal hemorrhages have been described. 

Systemic Features: 

Infants with type I disease are usually hypotonic from birth but develop spasticity, psychomotor retardation, and hyperreflexia within 6 months.  Early death from cardiopulmonary disease or infection is common.  Hepatomegaly, coarse facial features, brachydactyly, and cardiomyopathy with valvular dysfunction are common.  Dermal melanocytosis has also been described in infants in a pattern some have called Mongolian spots.  Skeletal dysplasia is a feature and often leads to vertebral deformities and scoliosis.  The ears are often large and low-set, the nasal bridge is depressed, the tongue is enlarged and frontal bossing is often striking.  Hirsutism, coarse skin, short digits, and inguinal hernias are common.

The juvenile form, type II, has a later onset with psychomotor deterioration, seizures and skeletal changes apparent between 7 and 36 months and death in childhood.  Visceral involvement and cherry-red spots are usually not present. 

Type III, or adult form, is manifest later in the first decade or even sometime by the 4th decade.  Symptoms and signs are more localized.  Neurological signs are evident as dystonia or speech and gait difficulties.  Dementia, parkinsonian signs, and extrapyramidal disease are late features.  No hepatosplenomegaly, facial dysmorphism, or cherry red spots are present in most individuals. Lifespan may be normal in this type. 

Genetics

This is an autosomal recessive lysosomal storage disease secondary to a mutations in GLB1 (3p21.33).  It is allelic to Morquio B disease (MPS IVB) (253010).  The mutations in the beta-galactosidase-1 gene result in intracellular accumulation of GM1 ganglioside, keratan sulfate, and oligosaccharides.  The production of the enzyme varies among different mutations likely accounting for the clinical heterogeneity. 

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

There is no treatment that effectively alters the disease course. 

References
Article Title: 

Pelizeaus-Merzbacher Disease

Clinical Characteristics
Ocular Features: 

Nystagmus is the major ocular feature in this disease and may appear as early as the first weeks of life in severe cases.  However, more mildly affected individuals may never have nystagmus and, further, it can disappear later.  The ocular movements are usually pendular but may have horizontal and rotatory components as well.  The presence of nystagmus is diagnostically important as it is an uncommon finding in other leukodystrophies.

Systemic Features: 

The classic disease is infantile in onset with hypotonia, titubation, weakness, stridor, respiratory problems, and even seizures often noted in the first weeks of life.   Ataxia, spasticity and cognitive delay are soon apparent.  Infants affected early and severely may never achieve normal motor or mental milestones whereas those less severely affected may at some point ambulate and acquire some language skills.  However, acquired skills may be lost by adolescence.  Survival to the sixth decade of life is common but those with the most severe form of disease may not live beyond the second decade. 

This is an X-linked recessive disorder in which only males have the complete syndrome.  However, multiple carrier females have been studied and many have subtle evidence of disease mainly in gait and motor control.

Genetics

Pelizeaus-Merzbacher disease is the result of mutations in an X-linked gene PLP1 (Xq22).  It is inherited in an X-linked recessive pattern.  Duplication of the PLP1 gene is more common than point mutations.  The signs and symptoms are not diagnostic of PMD as mutations in other genes can cause a similar phenotype. 

Spastic paraplegia-2 (SPG2; 312920)is an allelic disorder in which nystagmus and optic atrophy are also found in some patients.

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

There is no effective treatment for this disease.  Airway protection and seizure control should be applied in specific situations.  Patients often need a feeding tube for adequate nutrition.

References
Article Title: 

Tay-Sachs Disease

Clinical Characteristics
Ocular Features: 

Retinal ganglion cells become dysfunctional as a result of the toxic accumulation of intra-lysosomal GM2 ganglioside molecules causing early visual symptoms.  These cells in high density around the fovea centralis create a grayish-white appearance.  Since ganglion cells are absent in the foveolar region, this area retains the normal reddish appearance, producing the cherry-red spot.  Axonal decay and loss of the ganglion cells leads to optic atrophy and blindness.

Systemic Features: 

Sandoff disease may be clinically indistinguishable from Tay-Sachs disease even though the same enzyme is defective (albeit in separate subunits A and B that together comprise the functional hexosaminidase enzyme).   The infantile form of this lysosomal storage disease is the most common.  Infants appear to be normal until about 3-6 months of age when neurological development slows and muscles become weak.  Seizures, loss of interest, and progressive paralysis begin after this together with loss of vision and hearing.  The facies are coarse and the tongue is enlarged.  An exaggerated startle response is considered an early and helpful sign in the diagnosis.  Hepatosplenomegaly is usually not present.  Among infants with early onset disease, death usually occurs by 3 or 4 years of age.     

Ataxia with spinocerebellar degeneration, motor neuron disease, and progressive dystonia are more common in individuals with later onset of neurodegeneration.  The juvenile and adult-onset forms of the disease also progress more slowly.

Genetics

Tay-Sachs disease is an autosomal recessive disorder caused by mutations in the hexosaminidase A gene, HEXA, (15q23-q24).  The altered enzyme is unable to break down GM2 ganglioside which accumulates in lysosomes and leads to neuronal death.

A related form, clinically and biochemically similar to Tay-Sachs disease , is GM2-gangliosidosis (272750) but it is caused by mutations in GM2A (5q31.3-q33.1) with normal hexosaminidase A and B.  Sandhoff disease (268800) is clinically indistinguishable but caused by mutations in the beta subunit of hexosaminidase (HEXB) A and B at 5q13. 

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

Treatment is largely supportive.  Anticonvulsant pharmaceuticals may help in the control of seizures but require frequent modifications as the neuronal degeneration progresses.  Airways and nutrition maintainence are important.

Application of gene therapy to cell cultures have shown promise in restoring enzyme function and may someday lead to human treatment. 

    

References
Article Title: 

Tay-Sachs disease

Fernandes Filho JA, Shapiro BE. Tay-Sachs disease. Arch Neurol. 2004 Sep;61(9):1466-8. Review.

PubMed ID: 
15364698

Usher Syndrome Type I

Clinical Characteristics
Ocular Features: 

The fundus dystrophy of retinitis pigmentosa in Usher syndrome is indistinguishable from isolated retinitis pigmentosa.   Night blindness begins by about 10 years of age and the ERG by that time is often markedly diminished or absent.  Patches of hyperfluorescence are seen in younger individuals and these enlarge and coalesce with age.  Tunnel vision occurs early as the peripheral visual field is constricted to 5-10 degrees by midlife.  The retinal disease is progressive and blindness may be the final result.

Systemic Features: 

Type I Usher syndrome is characterized by profound hearing impairment beginning at birth, vestibular dysfunction, and unintelligible speech in addition to retinitis pigmentosa.  Vestibular areflexia is virtually complete and constitutes a defining feature.  Ataxic gait disturbances are common secondary to labyrinthine dysfunction and many children do not walk until 18-24 months of age.  Sitting alone may also be delayed.  Sperm motility is abnormal which is likely the basis for reduced fertility in male patients.  An abnormal exoneme morphology from ciliated progenitors is likely the common basis for these clinical findings.  MRI imaging has found a significant decrease in intracranial volume and brain size.  About 1 in 4 children have behavioral problems or psychosocial difficulties.

Genetics

Type I Usher syndrome is an autosomal recessive genetically heterogeneous disorder as mutations in at least 8 genes produce a similar disease.  These are: MYO7A (276900) at 11q13.5 causing USH1B (USH1A is now considered to be the same), USH1C at 11p15.1 causing USH1C (276904), CDH23 at 10q21-q22, causing USH1D (601067), PCDH15 at 10q21.1 causing USH1F (602083), and USH1G at 17q24-25 causing USH1G (606943).  Mutations in as yet unnamed genes in loci at 21q21 (USH1E; 602097), 10p11.21-q21.1 (USH1K), and 15q22-q23 (USH1H; 612632) may also cause this type I phenotype. They are discussed here as a single entity designated type I since the clinical features of each are indistinguishable.'

A varant of USH1C resulting from homozygous deletions in 11p15-p14, known as homozygous 11p15-p14 deletion syndrome, has the additional feature of severe hyperinsulinemia due to the involvement of ABCC8 and KCNJ11 genes (606528).

Clinical differences have led to the categorization of three types of Usher syndrome:  type I described here, type II (276901) caused by mutations in at least 4 genes, and type III (276902) caused by mutations in CLRN1.

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

At-risk infants should have hearing evaluations as soon as possible after birth.  Assistive hearing devices are of little benefit.  Unless cochlear implants are placed in young children, speech may not develop.  Extra precautions during physical activities such as swimming, bicycling, and night-time driving are highly recommended. Speech therapy and low vision aids can be beneficial.

References
Article Title: 

Targeted exon sequencing in Usher syndrome type I

Bujakowska KM, Consugar MB, Place E, Harper S, Lena J, Taub DG, White J, Navarro-Gomez D, Weigel-DiFranco C, Farkas MH, Gai X, Berson EL, Pierce EA. Targeted exon sequencing in Usher syndrome type I. Invest Ophthalmol Vis Sci. 2014 Dec 2.  [Epub ahead of print].

PubMed ID: 
25468891

Heterogeneity in Phenotype of Usher-Congenital Hyperinsulinism Syndrome: Hearing Loss, Retinitis Pigmentosa, and Hyperinsulinemic Hypoglycemia Ranging from Severe to Mild with Conversion to Diabetes

Al Mutair AN, Brusgaard K, Bin-Abbas B, Hussain K, Felimban N, Al Shaikh A, Christesen HT. Heterogeneity in Phenotype of Usher-Congenital Hyperinsulinism Syndrome: Hearing Loss, Retinitis Pigmentosa, and Hyperinsulinemic Hypoglycemia Ranging from Severe to Mild with Conversion to Diabetes. Diabetes Care. 2012 Nov 12. [Epub ahead of print].

PubMed ID: 
23150283

Optic Atrophy 3 and Cataracts

Clinical Characteristics
Ocular Features: 

There is considerable variation in age of onset and severity of clinical disease.  Cataracts may be evident in the first decade of life but in most cases by the second decade.  They are usually described as anterior or posterior cortical opacities.  Progression of opacification is slow and most patients do not require removal until late adulthood and some never require surgery. Visual impairment from optic atrophy may be evident in infancy and some patients experience a worsening in late adulthood.  Visual acuity is highly variable.  Temporal pallor may be present in childhood or later.

Systemic Features: 

Neurologic signs such as tremor, extrapyramidal rigidity in the upper extremities, and ataxia are seldom present until after the age of 50 years.  However not all patients have neurologic disease.

Genetics

This disorder is inherited in an autosomal dominant pattern as a result of a mutation in the OP3 gene (19q13.2-q13.3) encoding an inner membrane mitochondrial protein.  It is allelic to autosomal recessive optic atrophy-3, or 3-methylglutaconic aciduria type III (258501), sometimes called Behr early onset optic atrophy (210000). 

Optic atrophy 3 is less severe than in Behr optic atrophy and the presence of cataracts is an important distinguishing feature.  For these reasons, optic atrophy 3 is discussed as a separate disorder here.   However, the nosology remains unclear since not all individuals with Behr optic atrophy have 3-methylglutaric acidemia.  

Pedigree: 
Autosomal dominant
Treatment
Treatment Options: 

No effective treatment is available for the optic atrophy.  Cataract surgery may be necessary for visually significant lens opacities.

References
Article Title: 

OPA3 gene mutations responsible for autosomal dominant optic atrophy and cataract

Reynier P, Amati-Bonneau P, Verny C, Olichon A, Simard G, Guichet A, Bonnemains C, Malecaze F, Malinge MC, Pelletier JB, Calvas P, Dollfus H, Belenguer P, Malthi?(r)ry Y, Lenaers G, Bonneau D. OPA3 gene mutations responsible for autosomal dominant optic atrophy and cataract. J Med Genet. 2004 Sep;41(9):e110.

PubMed ID: 
15342707

[On a heredo-familial disease combining cataract, optic atrophy, extrapyramidal symptoms and certain defects of Friedreich's disease]

GARCIN R, RAVERDY P, DELTHIL S, MAN HX, CHIMENES H. [On a heredo-familial disease combining cataract, optic atrophy, extrapyramidal symptoms and certain defects of Friedreich's disease. (Its nosological position in relation to the Behr's syndrome, the Marinesco-Sjogren syndrome and Friedreich's disease with ocular symptoms.]. Rev Neurol (Paris). 1961 May;104:373-9. French.

PubMed ID: 
13703570

Niemann-Pick Disease, Types C1 (D)

Clinical Characteristics
Ocular Features: 

The predominant ocular sign in types C1 is difficulty in upgaze described as a supranuclear palsy.  Abnormal saccadic movements have been reported as well.  Retinal signs such as a cherry red spot are not common.

Systemic Features: 

Hepatosplenomegaly and cognitive decline are similar in nature to those found in Niemann-Pick disease types A and B.  Types C1 and C2 are clinically similar but discussed separately as they are caused by mutations in separate genes.  Type D is caused by the same mutation causing C1.  Onset of disease manifested by ataxia, seizures and spasticity is usually between 2 and 4 years.  Dystonia, intention tremor, dysarthria, and hepatosplenomegaly are other features but visceral involvement may be absent.  Ascites and jaundice are sometimes present.  Dementia and extrapyramidal signs are often seen later.  However, there is considerable variation in onset and progression of disease but the symptoms are generally milder than that in types A and B.

Genetics

Type C1 (and D) are caused by mutations in the NPC1 gene (18q11-q12), and type C2 (607625) by mutations in the NPC2 gene (14q24.3).  Mutations in C1 are far more common (95%) than C2 mutations.  The gene mutations reduce the efficiency of sphingosine efflux from lysosomes and late endosomes as a result of a defect in esterification of cholesterol.

Types A (257200) and B (607616) Niemann-Pick disease generally cause more severe clinical signs and are the result of a sphingomyelinase deficiency.  All types of Niemann-Pick disease follow autosomal recessive patterns of inheritance.

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

It has recently been reported that intrathecal 2-hydroxypropyl-beta-cyclodextrin slows progression of clinical symptoms and prolonged lifespan.

References
Article Title: 

Intrathecal 2-hydroxypropyl-β-cyclodextrin decreases neurological disease progression in Niemann-Pick disease, type C1: a non-randomised, open-label, phase 1-2 trial

Ory DS, Ottinger EA, Farhat NY, King KA, Jiang X, Weissfeld L, Berry-Kravis E, Davidson CD, Bianconi S, Keener LA, Rao R, Soldatos A, Sidhu R, Walters KA, Xu X, Thurm A, Solomon B, Pavan WJ, Machielse BN, Kao M, Silber SA, McKew JC, Brewer CC, Vite CH, Walkley SU, Austin CP, Porter FD. Intrathecal 2-hydroxypropyl-v-cyclodextrin decreases neurological disease progression in Niemann-Pick disease, type C1: a non-randomised, open-label, phase 1-2 trial. Lancet. 2017 Aug 10. pii: S0140-6736(17)31465-4. doi: 10.1016/S0140-6736(17)31465-4. [Epub ahead of print].

PubMed ID: 
28803710

Niemann-Pick disease type C

Vanier MT, Millat G. Niemann-Pick disease type C. Clin Genet. 2003 Oct;64(4):269-81. Review.

PubMed ID: 
12974729

Krabbe Disease

Clinical Characteristics
Ocular Features: 

Subtle cherry red spots have been reported in one patient.  More than half (53%) have abnormal VEP response but the ERG is normal.  Optic atrophy with blindness is not uncommon but the full ocular phenotype remains unknown.  A 6-month-old male child had MRI T2 evidence of intracranial optic nerve hypertrophy which was attributed to an accumulation of globoid cells.

Systemic Features: 

There is considerable variation in the time of onset and rate of progression in Krabbe disease, even within families.  Patients with infantile disease may present with symptoms at about 6 months of life, while others are not diagnosed until late childhood or adolescence.  Some evidence of psychomotor retardation is often the first sign of disease with ataxia and limb spasticity soon following.  Irritability is an early sign.  Neurophysiologic studies often show abnormal nerve conduction and this has been documented even in newborns.  The disorder is one of progressive neurodegeneration of both central and peripheral nervous systems leading to weakness, seizures and loss of protective reflexes.  The MRI may reveal T2 hyperintensity in cerebral and cerebellar white matter, internal capsules and pyramidal tracts.  Infection and respiratory failure are responsible for most deaths.

The life-span of Infants with Krabbe disease is approximately one year while those with late-onset disease may not develop symptoms until almost any age and the clinical course is highly variable.

Genetics

This is an autosomal recessive disorder secondary to mutations in the GALC gene (14q31) encoding the enzyme galactosylceramidase, important in the growth and maintenance of myelin.

One patient has been reported with ‘atypical’ Krabbe disease (611722) secondary to a homozygous mutation in the PSAP gene (10q22.1).  The infant had a deficiency of saposin A as well as decreased galactocerebrosidase activity in white blood cells

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

Normal blood galactocerebrosidase can be restored and CNS deterioration may be delayed or improved with transplantation of allogeneic hematopoietic stem cells or umbilical cord blood.   However, some patients have residual language deficits and mild to severe delays in motor function.  Results are better if treatment is commenced during infancy before development of symptoms.  These treatments are experimental and long range outcomes remain uncertain.

References
Article Title: 

Refsum Disease, Adult

Clinical Characteristics
Ocular Features: 

A retinitis pigmentosa-like retinopathy is the major ocular manifestation of this disease.  There is typical night blindness and visual field constriction.   Rod ERG responses are usually subnormal.  However, central acuity is also reduced due to a degenerative maculopathy.   Cataracts and optic atrophy are common.  The macula may undergo progressive degeneration and optic atrophy is not uncommon.  Some patients have defective pupillary responses.

Systemic Features: 

Onset of symptoms is usually late in the first decade and sometimes into the third decade.  There is usually a polyneuropathy with impaired motor reflexes and paresis in the limbs.  A progressive sensorineural hearing loss occurs in many patients.  Sensory deficits also occur.  Some have ataxia and skin changes of ichthyosis.  Anosmia is a near universal feature.  Heart failure may occur and cardiac abnormalities such as conduction defects can occur.  A variety of skeletal abnormalities such as pes cavus, short fourth metatarsals, and evidence of epiphyseal dysplasia have been reported.  There is considerable clinical heterogeneity even within families.

Phytanic acid oxidase activity as measured in fibroblasts is often low while serum phytanic acid is increased.  The cerebrospinal fluid contains increased protein but no increase in cells.

Genetics

This disorder results from mutations in the PHYH (PAHX) gene (10pter-p11.2) encoding phytanoyl-CoA hydroxylase, or, more rarely in PEX7 (6q22-q24) encoding peroxin-7 resulting in an uncommon condition (10% of cases) sometimes called adult Refsum disease-2. 

Mutations in the latter gene also cause rhizomelic chondrodysplasia punctata type 1 (215100) which does not have all of the neurological features or the retinopathy.

There is also so-called infantile form of Refsum disease (266510).

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

A diet low in phytanic acid can lead to improvement in the neurologic symptoms such as the ataxia and polyneuropathy but must be instituted in early stages of the disease.  This approach may not be as beneficial for the visual or auditory symptoms.

References
Article Title: 

Cerebral Amyloid Angiopathy

Clinical Characteristics
Ocular Features: 

Posterior polar cataracts appear during the third decade of life.

Systemic Features: 

Progressive hearing loss has its onset in the third decade and becomes severe in the 5th decade.  Progressive dementia, often in the form of paranoid psychosis, begins about age 50.  Cerebellar ataxia and intention tremor have their onset in midlife.  There is a diffuse atrophy throughout the brain and cranial nerves are demyelinated.  Blood vessels throughout the CNS, spinal cord and retina show an amyloid angiopathy.  Intracranial hemorrhage is a significant risk and, when lobar in location, carries a significant risk of mortality within months.  Death generally occurs in the 5th and 6th decades of life.

Genetics

Pedigree patterns in the few reported families are consistent with autosomal dominant inheritance.  A mutation has been found in the ITM2B gene located at 13q14.

Pedigree: 
Autosomal dominant
Treatment
Treatment Options: 

No treatment is available.

References
Article Title: 

Heredopathia ophthalmo-oto-encephalica

Stromgrem, E. Heredopathia ophthalmo-oto-encephalica. In: Myrianthopoulos, N.C. Handbook of Clinical Neurology. Neurogenetic directory. New York: Elsevier/North Holland (pub.) 42, Part I: 150-152, 1981.

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