atherosclerosis

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

Cerebrotendinous Xanthomatosis

Clinical Characteristics
Ocular Features: 

Juvenile cataracts are the primary ocular feature of this disorder and are found in virtually all patients.  These often cause the first symptoms and become evident in the first decade and almost always by the third decade of life.  Lens opacification may require extraction at that time and aspirated lens material may contain lipid-containing vacuoles.  However, some cataracts may not be diagnosed until the 5th or 6th decades after the onset of neurological symptoms, usually because the opacities are located in the peripheral cortex and do not cause visual symptoms. 

Optic atrophy occurs in nearly half of affected individuals.  Yellowish flakes resembling cholesterol crystals can sometimes be seen in the vitreous. The fundus may have scattered hard exudates and cholesterol-like deposits along the vascular arcades and arterioles show evidence of atherosclerosis.  RPE window defects are common.

Systemic Features: 

CTX has serious systemic neurologic signs and symptoms resulting from a deficiency of a mitochondrial enzyme, sterol 27-hydroxylase.  The result is reduced bile acid synthesis and increased levels of cholestanol in plasma, tissues, and CSF.  This results in a characteristic phenotype of tendon xanthomas, and neurological dysfunction including mental regression or illness, cerebellar ataxia, peripheral neuropathy, seizures, and pyramidal signs to various degrees.  Neonatal jaundice and diarrhea are common.

Genetics

This autosomal recessive disorder results from a mutation in the CYP27A1 gene (2q33-qter) encoding sterol 27-hydroxylase.

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

This is a treatable disorder in which administration of chenodeoxycholic acid (CDCA) is beneficial.  This compound is virtually absent from bile in people with CTX.  Exogenous administration reduces high levels of cholesterol and cholestanol in the CSF, tissues, and plasma with improvement in mental function and signs of peripheral neuropathy and cerebellar dysfunction.  It is frequently given in combination with other HMG-CoA inhibitors such as pravastatin.  Early diagnosis and treatment are important.

References
Article Title: 

Tangier Disease

Clinical Characteristics
Ocular Features: 

This disorder of lipoprotein metabolism is associated in many cases with corneal infiltrates, cicatricial ectropion, poor lid closure, and exposure keratopathy.  The corneal clouding alone generally cause little reduction of acuity but those with poor lid function and exposure keratopathy may have severe vision loss.  There may be weakness in the periorbital and lid muscles.  The corneal infiltration occurs late in life but is progressive with older individuals having the greatest visual impairment.  The corneal infiltrates are described as a “dot-like haze”, more prominent centrally and located in the stroma.  On electron microscopy, deposits in the conjunctiva are described as birefringent lipid particles located in pericytes and fibrocytes.  Lipid deposition occurs throughout the body including the conjunctiva.  Corneal hypesthesia has been reported.

In a series of 13 patients, ectropion and corneal scarring were reported in 3 and corneal infiltrates in 9.  Four had orbicular muscle weakness.  The latter together with corneal hypesthesia may be the earliest ocular signs of Tangier disease and should suggest the diagnosis even before the corneal clouding occurs.

Systemic Features: 

Patients with Tangier disease have significant enlargement of the liver, spleen and lymph nodes.  The tonsils are also frequently enlarged and have a characteristic yellow-orange  coloration.  The enlargement of these organs is due to lipid infiltration.  Plasma levels of cholesterol and HDL are characteristically slightly low while triglycerides are mildly elevated.  Peripheral neuropathy and muscle atrophy can be debilitating.  Severe coronary artery disease is common with onset sometime in the 5th decade.

Genetics

Tangier disease is an autosomal recessive disorder resulting from mutations in the ATP-binding cassette-1 gene ABCA1 (9p31.1) located in exon 22.  Parental consanguinity is common.

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

No treatment is available for this disorder beyond local organ treatment as indicated.
 

References
Article Title: 

Ocular complications of Tangier disease

Pressly, T. A.; Scott, W. J.; Ide, C. H.; Winkler, A.; Reams, G. P. : Ocular complications of Tangier disease. Am. J. Med. 83: 991-994, 1987.

PubMed ID: 
3314502
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