CRYBB2

Cataracts, Congenital Sutural with Punctate and Cerulean Opacities

Clinical Characteristics
Ocular Features: 

The anterior and posterior Y sutures have prominent, dense white opacities.  The embryonal and fetal nuclei are clear but the cortex contains gray-bluish, sharply defined and elongated as well as punctate opacities.  These are denser near the posterior pole and the posterior Y suture is also more heavily involved.  The cortical opacities may be arranged in concentric lamellae.  Considerable variation in density of opacities has been noted among patients.

Systemic Features: 

None reported.

Genetics

A large Indian family consisting of 5 generations containing 33 affected individuals has been described.  This is an autosomal dominant disorder in which a mutation has been found in exon 6 of the CRYBB2 gene (22q11.2-q12/22q11.23).  This region contains four crystallin genes as well as the CRYBP1 pseudogene.  It has been suggested that gene conversion between exon 6 of the CRYBB2 gene and CRYBR1 may be responsible for the phenotype.  Three additional families with identical mutations in the same CRYBB2 exon have been reported and, since each family seems to have a unique phenotype, it is likely that more than a simple bp mutation is responsible for the cataracts.  

Some Coppock-like cataracts (604307) also result from mutations in CRYBB2 at the same location but others have  mutations in the CRYGC gene.  Type 2 congenital cerulean cataracts (601547) have also been associated with mutations in the CRYBB2 gene. 

Another autosomal dominant congenital cataract with sutural opacities (600881) has a slightly different phenotype and results from a mutation on chromosome 17.  

Pedigree: 
Autosomal dominant
Treatment
Treatment Options: 

Visually significant cataracts may need to be removed.

References
Article Title: 

Cataracts, Coppock-Like

Clinical Characteristics
Ocular Features: 

Coppock-like cataracts consist of bilateral progressive opacities of the embryonic lens nucleus.  They are characterized by a pulverulent opacification with a gray disc appearance associated with variable zonular opacities.  Visual symptoms often begin during adolescence and some patients require cataract surgery by the 5th decade of life. 

Systemic Features: 

There is no systemic disease associated with this type of cataract.  

Genetics

CCL cataracts are embryonic in origin, developing during the time when gamma-crystallin genes are active.  The gamma E-crystallin gene is a pseudogene and the mutation in its promoter reactivates its activity 10-fold.  It is postulated that overexpression of the gamma-crystallin fragment is responsible for the nuclear opacification.

Mutations in at least 3 genes have been associated with this type of cataract.  In some families the mutations are in the CRYGC gene (2q33-q35), and in others mutations in CRYBB2 (22q11.2-q12.2) seem to be responsible.  It is of interest that one form of congenital cerulean cataract, CCA3 (608983), found in a single family, results in mutations in CRYGD also located at 22q11.2-q12.2.  A five-generation Chinese family has been reported in which mutations in GJA3 (13q12.11) was associated with this type of lens opacity.

Other forms of autosomal dominantly inherited, congenital, progressive lens opacities include congenital cerulean (115660, 601547, 608983, 610202), Volkmann type (115665), lamellar (116800), and congenital posterior polar (116600) cataracts. Due to clinical heterogeneity, it is not always possible to classify specific families based on the appearance and natural history of the lens opacities alone.

Pedigree: 
Autosomal dominant
Treatment
Treatment Options: 

Cataract surgery may be indicated.

References
Article Title: 

Cataracts, Congenital Cerulean

Clinical Characteristics
Ocular Features: 

Tiny lens opacities of blue or white color generally appear from birth through 18 and 24 months of age but may not be diagnosed until adulthood.  They first appear at the outer edge of the fetal lens nucleus or in more superficial cortical layers depending on the type.  Infants may be visually impaired from birth and develop nystagmus and amblyopia.  The opacities are usually bilateral and progressive.  Lens removal may be required in early infancy but often not until the 2nd to 4th decades.

Systemic Features: 

No systemic abnormalities are associated with cerulean cataracts.

Genetics

Lens opacities can, of course, be associated with chromosomal aberrations, developmental conditions, intrauterine infections, and metabolic errors as well as single gene mutations.   About 23% are familial but even among these there is considerable genetic and clinical heterogeneity that confounds the nosology despite notable recent progress in genotyping.  Due to clinical heterogeneity, it is not always possible to classify specific families based on the appearance and natural history of the lens opacities alone.

Cerulean cataracts of congenital or childhood onset can be due to mutations in genes that encode various lens crystallins.  Type 1 (CCA1; 115660) or 'blue dot' cerulean cataracts result from mutations in a gene located at 17q24 but its identity is as yet unknown. Intriguingly, it is located in the same chromosomal vicinity as the galactokinase deficiency gene (GALK1).  The lens opacities follow an autosomal dominant pattern of transmission. The mutation, however, does not appear to involve a gene that codes for any of the major structural proteins of the lens.

Type 2 (CCA2; 601547) results from mutations in the CRYBB2 gene (22q11.2-q12.2) encoding the beta-B2-crystallin protein.  Inheritance is autosomal dominant.

Type 3 (CCA3; 608983) is caused by mutations in CRYGD (2q33-q35) coding gamma-D-crystallin.  It has been reported in a single family in which it seemed to appear earlier and progress more rapidly than other types.  The pedigree pattern was consistent with autosomal dominant inheritance.  Mutations in the same gene also cause an allelic disorder designated nonnuclear polymorphic congenital cataracts or PCC (601286), which may simply be clinical heterogeneity of the same condition.

Type 4 (CCA4; 610202) is due to mutations in the MAF gene (16q22-q23) and is also inherited in an autosomal dominant pattern.  Lens opacities have a later, more juvenile onset and the lens opacities are located in a lamellar distribution in superficial cortical layers.  These are progressive and often result in posterior subcapsular opacification that requires lens extraction in adults.

Type 5 (CCA5; 614422) is the result of a mutation in a locus at 12q24 and is dominantly inherited.  The opacities are located throughout the lens but are most numerous in the cortex.   They are most commonly diagnosed in the second decade of life and lens extractions are required a decade or so later.

Other forms of autosomal dominantly inherited, congenital, progressive lens opacities include Volkmann type (115665), Coppock-like (604307), lamellar (116800), and congenital posterior polar (116600) cataracts. 

Pedigree: 
Autosomal dominant
Treatment
Treatment Options: 

No treatment is known to prevent the opacities but serial evaluations and cataract surgery are required to prevent amblyopia as the opacities progress.

References
Article Title: 

Conversion and compensatory evolution of the gamma-crystallin genes and identification of a cataractogenic mutation that reverses the sequence of the human CRYGD gene to an ancestral state

Plotnikova OV, Kondrashov FA, Vlasov PK, Grigorenko AP, Ginter EK, Rogaev EI. Conversion and compensatory evolution of the gamma-crystallin genes and identification of a cataractogenic mutation that reverses the sequence of the human CRYGD gene to an ancestral state. Am J Hum Genet. 2007 Jul;81(1):32-43.

PubMed ID: 
17564961
Subscribe to RSS - CRYBB2