optic atrophy

Spinocerebellar Ataxia 1

Clinical Characteristics
Ocular Features: 

Early manifestations include gaze-evoked nystagmus and saccadic hypermetria.  Ophthalmoplegia develops later in the disease process.  Some patients experience a decrease in acuity and dyschromatopsia.  The ERG shows evidence of generalized rod and cone photoreceptor dysfunction in some patients.  Optic atrophy, central scotomas, central RPE changes, retinal arteriolar attenuation, and blepharospasm have also been reported.

Time-domain OCT has revealed microscopic changes in the macula with thinning of the inner-outer segment junction and nuclear layer in areas with RPE hypopigmentation. 

Systemic Features: 

This is a progressive cerebellar syndrome characterized by systems of ataxia, dysarthria, and bulbar palsy.  Speech is often scanning and explosive.  DTRs can be exaggerated, and dysmetria is common.  The mean age of onset is about age 40.  Some cognitive decline may occur.  Muscle atrophy, and symptoms of peripheral neuropathy can be present.  MRI shows atrophy in the cerebellum, spinal cord, and brainstem.  There is considerable variation in clinical expression.  Individuals with adult onset of symptoms can survive for 10-30 years whereas those with a juvenile-onset often do not live beyond the age of 16 years.

Genetics

This disorder is caused by an expanded CAG repeat in the ataxin-1 gene (ATXN1) at 6p23.  It is an autosomal dominant disorder.  Alleles with 39-44 or more CAG repeats are likely to be associated with symptoms. 

A male bias and the phenomenon of anticipation have been demonstrated in this disorder as in spinocerebellar ataxia 7 (SCA7) (164500), in which affected offspring of males with SCA develop disease earlier and symptoms progress more rapidly than in offspring of females.  This is often explained by the fact that males generally transmit a larger number of CAG repeats.

SCA7 (164500), also inherited in an autosomal dominant pattern and caused by expanded CAG repeats on chromosome 3, has many similar ocular and neurologic features.

Pedigree: 
Autosomal dominant
Treatment
Treatment Options: 

Supportive care is often required.          

References
Article Title: 

Wolfram Syndrome 2

Clinical Characteristics
Ocular Features: 

As in Wolfram syndrome 1, only insulin dependent diabetes mellitus and optic atrophy are essential to the diagnosis. The optic atrophy is progressive over a period of years and can be the presenting sign.  Its onset, however, is highly variable and may begin in infancy but almost always before the third decade of life.  The majority (77%) of patients are legally blind within a decade of onset.  The visual field may show paracentral scotomas and peripheral constriction.  Both VEPs and ERGs can be abnormal.  Diabetic retinopathy is uncommon and usually mild.

Systemic Features: 

The clinical features of this disorder are many and highly variable.  Sensorineural hearing loss, anemia, seizures, ataxia, and autonomic neuropathy are usually present. Respiratory failure secondary to brain stem atrophy may have fatal consequences by the age of 30 years.  A variety of mental disturbances including mental retardation, dementia, depression, and behavioral disorders have been reported.  The diabetes mellitus is insulin dependent with childhood onset.  Hydroureter is often present.

Diabetes insipidus may be present in patients with Wolfram syndrome 1 (222300) but has not been reported in patients reported with Wolfram syndrome 2.   Upper GI ulceration and bleeding were present in several individuals.

Genetics

This is an autosomal recessive disorder similar to Wolfram syndrome 1 (WFS1; 222300) but caused by mutations in the CISD2 gene (4q22-q24).  The gene codes for a small protein (ERIS) localized to the endoplasmic reticulum. It seems to occur less commonly than WFS1.

Some patients have mutations in mitochondrial DNA as the basis for their disease (598500).  Combined with evidence that point mutations at the 4p16.1 locus predisposes deletions in mtDNA, this suggests that at least some patients with Wolfram syndrome have a recessive disease caused by mutations in both nuclear and mitochondrial genes.

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

Treatment is supportive for specific organ disease.  Low vision aids may be helpful in selected individuals.

References
Article Title: 

Wolfram Syndrome 1

Clinical Characteristics
Ocular Features: 

Optic atrophy in association with diabetes mellitus is considered necessary to the diagnosis of Wolfram syndrome.  The optic atrophy is progressive over a period of years and can be the presenting symptom.  Its onset, however, is highly variable and may begin in infancy but almost always before the third decade of life.  The majority (77%) of patients are legally blind within a decade of onset.  The visual field may show paracentral scotomas and peripheral constriction.  Both VEPs and ERGs can be abnormal.  Diabetic retinopathy is uncommon and usually mild.

Two sibs with confirmed WFS1 have been reported with microspherophakia, congenital cataracts, and glaucoma in addition to optic atrophy .

Systemic Features: 

The clinical features of this disorder are many and highly variable.  Sensorineural hearing loss, diabetes insipidus, anemia, seizures, vasopressin deficiency, ataxia, and autonomic neuropathy are usually present. Respiratory failure secondary to brain stem atrophy may have fatal consequences by the age of 30 years.  A variety of mental disturbances including mental retardation, dementia, depression, and behavioral disorders have been reported.  The diabetes mellitus is insulin dependent with childhood onset.  Dilated ureters and neurogenic bladder are frequently seen, especially in older patients..

Genetics

Wolfram syndrome 1 is an autosomal recessive disorder that can be caused by mutations in the WFS1 gene (4p16.1) encoding wolframin, a small protein important to maintenance of the endoplasmic reticulum.  However, a minority of individuals also have deletion mutations in mitochondrial DNA (598500).  Some evidence suggests that point mutations at 4p16.1 predispose deletions in mtDNA, and, if so, this recessive disorder may owe its appearance to combined mutations in both nuclear and mitochondrial DNA.  In addition, rare families with the Wolfram syndrome phenotype and mutations in the WFS1 gene show transmission patterns consistent with autosomal dominant inheritance.

Wolfram syndrome 2 (WFS2) (604928) results from mutations in CISD2 at 4q22-q24.

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

No treatment is available for Wolfram syndrome but the administration of thiamin can correct the anemia.  Low vision aids may be helpful in early stages of disease.

References
Article Title: 

Cockayne Syndrome, Type A

Clinical Characteristics
Ocular Features: 

A progressive pigmentary retinopathy of a salt-and-pepper type and optic atrophy are commonly seen.  Retinal vessels are often narrowed and older patients can have typical bone spicule formation.  Night blindness, strabismus, and nystagmus may be present as well.  Enophthalmos, hyperopia, poor pupillary responses, and cataracts have been observed.  The lens opacities may in the nucleus or in the posterior subcapsular area and are often present in early childhood.  The ERG is often flat but may show some scotopic and photopic responses which are more marked in older individuals.  Vision loss is progressive but is better than expected in some patients based on the retina and optic nerve appearance.  The cornea may have evidence of exposure keratitis as many patients sleep with their eyes incompletely closed.  Recurrent corneal erosions have been reported in some patients.

The complete ocular phenotype and its natural history have been difficult to document due to the aggressive nature of this disease.

Ocular histopathology in a single patient (type unknown) revealed widespread pigment dispersion, degeneration of all retinal layers as well as thinning of the choriocapillaris and gliosis of the optic nerve.  Excessive lipofuscin deposition in the RPE was seen.

Systemic Features: 

Slow somatic growth and neural development are usually noted in the first few years of life.  Young children may acquire some independence and motor skills but progressive neurologic deterioration is relentless with loss of milestones and eventual development of mental retardation or dementia.  Patients often appear small and cachectic, with a 'progeroid' appearance.  The hair is thin and dry, and the skin is UV-sensitive but the risk of skin cancer is not increased.  Sensorineural hearing loss and dental caries are common.  Skeletal features include microcephaly, kyphosis, flexion contractures of the joints, large hands and feet, and disproportionately long arms and legs.  Perivascular calcium deposits are often seen, particularly in various brain structures while the brain is small with diffuse atrophy and patchy demyelination of white matter.  Peripheral neuropathy is characterized by slow conduction velocities.  Poor thermal regulation is often a feature. 

Type A is considered the classic form of CS.  Neurological deterioration and atherosclerotic disease usually lead to death early in the 2nd decade of life but some patients have lived into their 20s.  

Genetics

There is a great deal of clinical heterogeneity in Cockayne syndrome.  Type A results from homozygous or heterozygous mutations in ERCC8 (5q12).  CS type B (133540), is caused by mutations in ERCC6, and has an earlier onset with more rapidly progressive disease.  Both mutations impact excision-repair cross-complementing proteins important for DNA repair during replication.

Type III (216411) is poorly defined but seems to have a considerably later onset and milder disease.  The mutation in type III is unknown. 

Some patients have combined phenotypical features of Cockayne syndrome (CS) and xeroderma pigmentosum (XP) known as the XP-CS complex (216400).  Defective DNA repair resulting from mutations in nucleotide excision-repair cross-complementing or ERCC genes is common to both disorders.  Two complementation groups have been identified in CS and seven in XP.  XP patients with CS features fall into only three (B, D, G) of the XP groups.  XP-CS patients have extreme skin photosensitivity and a huge increase in skin cancers of all types.  They also have an increase in nervous system neoplasms. 

There may be considerable overlap in clinical features and rate of disease progression among all types.

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

No specific treatment is available for Cockayne syndrome.  Supportive care for specific health problems, such as physical therapy for joint contractures, is important. 

Justification of cataract extraction should be made on a case by case basis.  Lagophthalmos requires that corneal lubrication be meticulously maintained.

References
Article Title: 

The Cockayne Syndrome Natural History (CoSyNH) study: clinical findings in 102 individuals and recommendations for care

Wilson BT, Stark Z, Sutton RE, Danda S, Ekbote AV, Elsayed SM, Gibson L, Goodship JA, Jackson AP, Keng WT, King MD, McCann E, Motojima T, Murray JE, Omata T, Pilz D, Pope K, Sugita K, White SM, Wilson IJ. The Cockayne Syndrome Natural History (CoSyNH) study: clinical findings in 102 individuals and recommendations for care. Genet Med. 2015 Jul 23. doi: 10.1038/gim.2015.110. [Epub ahead of print].

PubMed ID: 
26204423

Ocular findings in Cockayne syndrome

Traboulsi EI, De Becker I, Maumenee IH. Ocular findings in Cockayne syndrome. Am J Ophthalmol. 1992 Nov 15;114(5):579-83.

PubMed ID: 
1443019

Cockayne syndrome and xeroderma pigmentosum

Rapin I, Lindenbaum Y, Dickson DW, Kraemer KH, Robbins JH. Cockayne syndrome and xeroderma pigmentosum. Neurology. 2000 Nov 28;55(10):1442-9. Review. PubMed PMID:

PubMed ID: 
11185579

Adrenoleukodystrophy, Autosomal

Clinical Characteristics
Ocular Features: 

This early onset and rapidly progressive form of adrenoleukodystrophy is rare.  The early onset and rapidly fatal course of the disease has limited full delineation of the ocular features.  The most striking is the presence of 'leopard-spots' pigmentary changes in the retina.  Polar cataracts, strabismus, and epicanthal folds have also been reported. 

Systemic Features: 

Onset of symptoms occurs shortly after birth often with seizures and evidence of psychomotor deficits.  Rapid neurologic deterioration begins at about 1 year of age with death usually by the age of 3 years.  Hyperpigmentation of the skin may be apparent a few months after birth.  Opisthotonus has been observed.  The ears may be low-set, the palate is highly arched, and the nostrils anteverted.  Frontal bossing may be present.  Serum pipecolic acid and very-long-chain fatty acids (VLCFAs) can be markedly elevated.  Cystic changes in the kidneys have been reported. 

Genetics

This is an autosomal recessive peroxismal disorder resulting from homozygous mutations in receptor gene mutations such as PEX1, PEX5, PEX13, and PEX26.

There is also an X-linked recessive adrenoleukodystrophy (300100) sometimes called ALD but it lacks some of the morphologic features and is somewhat less aggressive. 

Neonatal adrenoleukodystrophy along with infantile Refsum disease (266510, 601539) and Zellweger syndrome (214100) are now classified as Zellweger spectrum or perioxismal biogenesis disorders.

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

Treatment is mainly supportive for associated health problems. 

References
Article Title: 

Adrenoleukodystrophy, X-Linked

Clinical Characteristics
Ocular Features: 

Virtually all patients have visual symptoms.  Loss of acuity, hemianopia, visual agnosia, optic atrophy, and strabismus are the most common features.   Neuropathy may cause a decrease in corneal sensation.  Gaze abnormalities due to ocular apraxia are sometimes seen.  Ocular symptoms often occur after the systemic abnormalities are noted.  However, there is considerable heterogeneity in age of onset and progression of symptoms.

Histopathology of ocular structures reveals characteristic inclusions in retinal neurons, optic nerve macrophages, and the loss of ganglion cells with thinning of the nerve fiber layer of the retina. 

Systemic Features: 

This is a peroxisomal disorder of very-long-chain fatty acid (VLCF) metabolism that leads to progressive neurological and adrenal dysfunction from accumulation of VLCFAs in the nervous system, adrenal glands, and testes.  The age of onset and clinical course are highly variable and there may be several forms.  The childhood form begins between the ages of 4 and 8 years but in other patients with the adult form, symptoms may not appear until the third decade of life.  A viral illness may precipitate the onset.   Symptoms of both central and peripheral neurologic disease are often present with cognitive problems, ataxia, spasticity, aphasia, and loss of fine motor control.  Hearing loss is seen in some patients.  Younger patients tend to have more behavioral problems while older individuals may develop dementia.

Adrenal insufficiency leads to skin hyperpigmentation, weakness, loss of muscle mass and eventually coma.  Impotence in males is common. 

Genetics

This is an X-linked disorder secondary to mutations in the ABCD1 gene (Xp28).  The result is a deficiency in the cellular transporter known as adrenoleukodystrophy protein that is active in perioxosomes.

Although this X-linked disorder is primarily manifest in males, between 20 and 50% of female carriers have at least some symptoms, usually with a later onset than seen in males.

There are also rare cases with an apparent autosomal recessive pattern of inheritance (NALD) (202370) having an earlier onset and more aggressive course. 

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

Treatment of adrenal insufficiency is important and can be lifesaving.  Low vision aids, physical therapy and special education may be helpful.  Some young patients with early disease have benefitted from bone marrow transplantation.  "Lorenzo's Oil" (a mixture of oleic acid and erucic acid) has been reported to reduce or delay symptoms in some boys.

Recent reports suggest new treatment modalities may hold promise.  Infusion of autologous CD34+ cells transduced with the Lentin-D lentiviral vector reduced major symptoms in 15 of 17 boys within 29 months after treatment.  Likewise, intrathecal baclofen treatment in two boys with rapidly advancing cerebral manifestations provided symptomatic and palliative improvement.

 

References
Article Title: 

Hematopoietic Stem-Cell Gene Therapy for Cerebral Adrenoleukodystrophy

Eichler F, Duncan C, Musolino PL, Orchard PJ, De Oliveira S, Thrasher AJ, Armant M, Dansereau C, Lund TC, Miller WP, Raymond GV, Sankar R, Shah AJ, Sevin C, Gaspar HB, Gissen P, Amartino H, Bratkovic D, Smith NJC, Paker AM, Shamir E, O'Meara T, Davidson D, Aubourg P, Williams DA. Hematopoietic Stem-Cell Gene Therapy for Cerebral Adrenoleukodystrophy. N Engl J Med. 2017 Oct 4. doi: 10.1056/NEJMoa1700554. [Epub ahead of print].

PubMed ID: 
28976817

X-linked adrenoleukodystrophy

Moser HW, Mahmood A, Raymond GV. X-linked adrenoleukodystrophy. Nat Clin Pract Neurol. 2007 Mar;3(3):140-51. Review.

PubMed ID: 
17342190

Sandhoff Disease

Clinical Characteristics
Ocular Features: 

Retinal ganglion cells are rendered dysfunctional from 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: 

Sandhoff 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 enzymes).  The presence of hepatosplenomegaly in Sandoff disease may be distinguishing. The infantile form of this lysosomal storage disease seems to be the most severe.  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.  An exaggerated startle response is considered an early and helpful sign in the diagnosis.  Among infants with early onset disease, death usually occurs by 3 or 4 years of age.   

Ataxia with spinocerebellar degeneration, motor neuron disease, dementia, 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

Sandhoff disease results from mutations in the beta subunit of the hexosaminidase A and B enzymes.  It is an autosomal recessive disorder caused by mutations in HEXB (5q13). 

Tay-Sachs disease (272800) can be clinically indistinguishable from Sandoff disease and they are allelic disorders.  However, the mutation in Tay-Sachs (272800) is in HEXA resulting in dysfunction of the alpha subunit of hexosaminidase A enzyme. 

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

No specific treatment is available beyond general support with proper nutrition and maintainence of airways.  Anticonvulsants may be helpful in some stages.  Gene therapy in fibroblast cultures has achieved some restoration of  hexosaminidase A activity in Tay-Sachs disease and may have potential in Sandhoff disease as well. 

References
Article Title: 

Neuropathy, Ataxia, and Retinitis Pigmentosa

Clinical Characteristics
Ocular Features: 

Night blindness and visual field restriction are early symptoms usually in the second decade of life.  The retina may first show a salt-and-pepper pigmentary pattern which later resembles the classic bone-spicule pattern of retinitis pigmentosa with vascular attenuation.  The optic nerve becomes pale and eventually marked optic atrophy develops.  Severe vision loss is evident in young adults and some patients become blind. 

Systemic Features: 

The onset of systemic symptoms such as unsteadiness occurs some time in the second decade of life.  Irritability, delayed development, and psychomotor retardation may be evident in children whereas older individuals can have frank dementia.  The MRI may reveal cerebral and cerebellar atrophy.  Seizures may have their onset by the third decade.  Numbness, tingling and pain in the extremities are common.  EMG and nerve conduction studies can demonstrate a peripheral neuropathy.  Neurogenic muscle weakness can be marked and muscle biopsy may show partial denervation. Some patients have hearing loss.  A few patients have cardiac conduction defects. 

Genetics

This is a mitochondrial disorder with pedigrees showing maternal transmission.  Mutations (8993T-G) have been found in subunits of mitochondrial H(+)-ATPase or MTATP6.  The amount of heteroplasmy is variable and likely responsible for the clinical heterogeneity in this disorder.  Individuals with more than 90% mutated chromosomes are considered to have a subtype of Leigh syndrome (MILS) with earlier onset (3-12 months of age).  NARP patients usually have 70-80% or less of mutated mitochondria.  The amount of heteroplasmy may vary among tissues. 

Treatment
Treatment Options: 

No treatment is available for this disease but low vision aids can be helpful in early stages of disease.  Recently it has been demonstrated that alpha-ketoglutarate/aspartate application to fibroblast cell cultures can provide some protection from cell death in NARP suggesting a potential therapeutic option. 

References
Article Title: 

Retinopathy of NARP syndrome

Kerrison JB, Biousse V, Newman NJ. Retinopathy of NARP syndrome. Arch Ophthalmol. 2000 Feb;118(2):298-9.

PubMed ID: 
10676807

Neuronal Ceroid Lipofuscinoses

Clinical Characteristics
Ocular Features: 

At least 13 genotypically distinct forms of neuronal ceroid lipofuscinosis have been described.  The ocular features are highly similar in all forms with blindness the end result in all types (although not all cases with an adult onset suffer vision loss).  The onset of visual signs and symptoms is highly variable.  Optic atrophy is the most common finding which may occur as early as two years of age in the infantile form.  Night blindness is a symptom in those with a later onset but panretinal degeneration with unrecordable ERGs eventually occurs.  Pigmentary changes throughout the retina are often seen and sometimes occur in a bull’s-eye pattern.  Retinal blood vessels may be attenuated and lens opacities of various types are common. 

Systemic Features: 

The neuronal ceroid lipofuscinosis are a group of inherited neurodegenerative lysosomal-storage disorders characterized by the intracellular accumulation of autofluorescent lipopigment causing damage predominantly in the central nervous system.  The result is a progressive encephalopathy with cognitive and motor decline, eventual blindness, and seizures with early death.  While early descriptions distinguished several types based primarily on age of onset, genotyping has now identified responsible mutations in at least 10 genes and time of onset is no longer considered a reliable indicator of the NCL type. 

Genetics

The NCLs are usually inherited in autosomal recessive patterns with the exception of some adult onset cases in which an autosomal dominant pattern is sometimes seen.

The various forms of NCL are often divided according to ages of onset but overlap is common.  Thus the congenital form (CLN10; 610127), caused by a mutation in the CTSD gene at 11p15.5, can have an onset of symptoms at or around birth but also is responsible for an adult form (Vida infra).  The CLN1 infantile form (256730), caused by a mutation in the PPT1 gene at 1p32, has an onset between 6 and 24 months  There are several mutations causing late infantile disease (CLN2, 204500) involving the TPP1 gene (11p15.5) leading to symptoms between 2-4 years, the CLN5 gene (256731) at 13q21.1-q32 with onset between 4 and 7 years, the CLN6 gene (601780) at 15q21-q23 showing symptoms between 18 months and 8 years, and the CLN8 gene (610003) at 8p23 with symptoms beginning between 3 and 7 years.  Another early juvenile form (CLN7; 610951) is caused by mutations in MFSD8 (4q228.1-q28.2).

A juvenile form (sometimes called Batten disease or Spielmeyer-Vogt with onset between 4 and 10 years results from mutations in CLN3 (204200) as well as in TPP1, PPT1, and CLN9 (609055).  An adult form known as ANCL or Kuf’s disease results from mutations in CTSD, PPT, CLN3, CLN5, and CLN4 (204300) and has its onset generally between the ages of 15 and 50 years. 

Homozygous mutations in the ATP13A2 gene (1p36.13), known to cause Kufor-Rakeb type parkinsonism (606693), have also been found in NCL.

Pedigree: 
Autosomal dominant
Autosomal recessive
Treatment
Treatment Options: 

Treatment is primarily symptomatic for sleep disorders, seizures, psychoses, malnutrition, dystonia and spasticity.  However, there is recent progress in the application of enzyme-replacement therapies in the soluble lysosomal forms of CNL.  Gene therapies and the use of stem cells also hold promise. 

References
Article Title: 

Hyperoxaluria, Primary, Type I

Clinical Characteristics
Ocular Features: 

About 30% of patients with type I develop retinopathy and about half of those have a diffuse optic atrophy.  Oxalate crystal deposition can cause a 'fleck retina' picture sometimes described as a crystalline retinopathy.  There is wide variation in the retinal phenotype.  Retinal toxicity leads to early and progressive vision loss.  The RPE may respond with hyperpigmentation in the form of 'ringlets' in the posterior pole.  Retinal fibrosis has been described.  Some patients develop choroidal neovascularization.

Evaluation using EDI-OCT shows progressive deposition of oxalate crystals throughout the retina, pigment epiithelium, and choroid.

Systemic Features: 

The onset of this disease can occur any time from infancy to 25 years of age.  Failure to thrive can be a presenting sign in infants.  Most patients have glycolic aciduria and hyperoxaluria as the result of failure to transaminate glyoxylate to form glycine.  The result is deposition of insoluble oxalate crystals in various body tissues with nephrolithiasis and nephrocalcinosis often early signs.  Neurologic, cardiac, vascular, and kidney disease is often the result although oxalate crystals can be found throughout the body.  Arteriole occlusive disease may lead to gangrene, Raynaud phenomena, acrocyanosis and intermittent claudication.  Renal failure is common. 

Genetics

Hyperoxaluria type I is an autosomal recessive disorder resulting from a mutation in the alanine-glyoxylate aminotransferase gene (AGXT) located at 2q36-q37.  Failure of this liver peroxisomal enzyme to transaminate glyoxylate results in oxidation of this molecule to form oxalate.

Hyperoxaluria type II (260000) is caused by mutations in the GRHPR gene (9cen) and type III (613616) by mutations in DHDPSL (HOGA1) (10q24.2).  Urolithiasis is the only clinical feature in these types. 

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

Some patients benefit from oral pyridoxine (B6) treatment in type I hyperoxaluria.  Renal transplantation by itself is only temporarily helpful since the enzymatic defect remains and the donor tissue becomes damaged as well.  Combined renal-liver transplantation should be considered instead because it corrects the primary metabolic error and can even reverse the accumulation of oxalate crystals. 

References
Article Title: 

Primary hyperoxaluria in infants

Jellouli M, Ferjani M, Abidi K, Zarrouk C, Naija O, Abdelmoula J, Gargah T. Primary hyperoxaluria in infants. Saudi J Kidney Dis Transpl. 2016 May-Jun;27(3):526-32.

PubMed ID: 
27215245

Primary hyperoxaluria

Cochat P, Rumsby G. Primary hyperoxaluria. N Engl J Med. 2013 Aug 15;369(7):649-58. Review.

PubMed ID: 
23944302

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