skin hypopigmentation

Vici Syndrome

Clinical Characteristics
Ocular Features: 

Congenital cataracts, both unilateral and bilateral are common.  The fundus appears hypopigmented. Nystagmus, optic neuropathy, and mild ptosis have been reported.  Nothing is known regarding acuity. 

Systemic Features: 

Infants at birth have striking hypotonia with a weak cry and feeding difficulties.  Dysmorphic features such as micrognathia, microcephaly, low-set ears, some degree of generalized hypopigmentation (hair and skin), and a broad nose with a long philtrum may be present. The face may appear triangular.  Cleft lip and palate may be present.  Evidence of cardiac dysfunction may also be present early with both dilated and hypertrophic cardiomyopathy reported.  Hearing loss has been reported in some individuals.  Recurrent infections are common and immunologic studies have revealed, in some patients, granulocytopenia, low T cell counts (primarily T4+ cells), thymic dysplasia, and low levels of IgG.  Seizures may occur.  Liver dysfunction has been variably reported.

Neurological and brain evaluations have reported agenesis of the corpus callosum, defects in the septum pellucidum, and hypoplasia of the cerebellar vermis along with pontocerebellar hypoplasia.  Psychomotor retardation is severe in most individuals along with general growth retardation.

Histologic studies of skeletal muscle fibers have shown considerable variation in fiber size, centralized nuclei, fucsinophilic inclusions, and enlarged abnormal mitochondria.  Other central nervous system abnormalities include in some individuals a paucity of white matter, schizencephaly, neuronal heterotopias, and enlargement of the ventricles.

The cumulative effects of these multiorgan abnormalities lead to death within the first year or two of life, generally of heart failure or sepsis. 

Genetics

Homozygous or compound heterozygous mutations in the EPG5 gene (18q12.3) have been associated with this condition.

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

No treatment has been reported.

References
Article Title: 

Vici syndrome: a

Byrne S, Dionisi-Vici C, Smith L, Gautel M, Jungbluth H. Vici syndrome: a
review
. Orphanet J Rare Dis. 2016 Feb 29;11(1):

PubMed ID: 
4772338

Recessive mutations in EPG5 cause Vici syndrome, a multisystem disorder with defective autophagy

Cullup T, Kho AL, Dionisi-Vici C, Brandmeier B, Smith F, Urry Z, Simpson MA, Yau S, Bertini E, McClelland V, Al-Owain M, Koelker S, Koerner C, Hoffmann GF, Wijburg FA, ten Hoedt AE, Rogers RC, Manchester D, Miyata R, Hayashi M, Said E, Soler D, Kroisel PM, Windpassinger C, Filloux FM, Al-Kaabi S, Hertecant J, Del Campo M, Buk S, Bodi I, Goebel HH, Sewry CA, Abbs S, Mohammed S, Josifova D, Gautel M, Jungbluth H. Recessive mutations in EPG5 cause Vici syndrome, a multisystem disorder with defective autophagy. Nat Genet. 2013 Jan;45(1):83-7.

PubMed ID: 
23222957

Albinism, Oculocutaneous, Type V

Clinical Characteristics
Ocular Features: 

The phenotype in the two families studied includes photophobia, nystagmus, foveal hypoplasia and decreased visual acuity.  The fundus is hypopigmented.

Systemic Features: 

The hair is golden-colored and the skin is described as white. 

Genetics

The specific gene causing this form of oculocutaneous albinism has not been identified.  However, an area of homozygosity in the region of 4q24 has been identified in 6 members in two families belonging to a large consanguineous Pakistani pedigree in which it segregates with the OCA5 phenotype. 

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

No treatment is available for oculocutaneous albinism but appropriately tinted glasses could be beneficial.

References
Article Title: 

Increasing the complexity: new genes and new types of albinism

Montoliu L, Gronskov K, Wei AH, Martinez-Garcia M, Fernandez A, Arveiler B, Morice-Picard F, Riazuddin S, Suzuki T, Ahmed ZM, Rosenberg T, Li W. Increasing the complexity: new genes and new types of albinism. Pigment Cell Melanoma Res. 2014 Jan;27(1):11-18. Review.

PubMed ID: 
24066960

Waardenburg Syndrome, Type 1

Clinical Characteristics
Ocular Features: 

Waardenburg syndrome is a disorder of pigmentation, sensorineural deafness, and a characteristic facial (nasal root) morphology.  Some have neural tube defects.  Based on clinical criteria, the syndrome has been divided into types 1, 2, 3, and 4, with subtypes of 2 and 4.  Types 1 and 3 are caused by mutations in the same gene.

Patients often have a white forelock and iris heterochromia.  The latter may be partial in individual irides, or the entire iris in one eye with the fundus hypopigmentation often matching the iris pattern.  The fundus may also have segmental areas of pigmentary changes corresponding to the iris heterochromia. The hypopigmented portion of the iris is often a brilliant blue.  Dystopia canthorum is a prominent and nearly constant (>95%) feature of type 1, and together with the prominent nasal root and increased intercanthal distance may suggest hypertelorism.  Synophrys is often present and the medial portions of the eyebrows can be exceptionally bushy.  Sometimes the poliosis involves the lashes and eyebrows.

Systemic Features: 

Congenital sensorineural deafness is an important feature.  Individuals with type 1 often have a white forelock (29%), premature graying (44%), and hypopigmented skin patches (55%).  A few patients have cleft palate and/or lip. Neural tube defects have also been reported. The considerably more rare type 3 is caused by mutations in the same gene as type 1, but it is claimed by some to be a separate disorder because of the association of limb anomalies. 

Genetics

Autosomal dominant inheritance is typical for the Waardenburg syndrome.  Types 1 and 3 are caused by mutations in the PAX3 gene (2q35) and, of these, type 1 is far more common.  Type 1 is caused by a heterozygous mutation whereas type 3 may result from either a heterozygous, compound heterozygous, or homozygous mutation.  Both types have been reported to occur in the same pedigree.  PAX genes act as transcription factors that attach to specific sections of DNA and regulate protein production.  PAX3 gene products, among other things, specifically influence neural crest cells important to the development of cranialfacial bones and melanocytes.  Paternal age plays a role in new mutations which probably account for many sporadic cases.

Waardenburg syndrome is an excellant example of genetic heterogeneity as types 1 (193500), 2 (193510), 3 (148820  and 4 (277580) can all result from mutations in different genes.  In addition, types 2 and 4 are each caused by mutations in several different genes. 

A child has been reported who was doubly heterozygous for mutations involving both MITF and PAX3. Hypopigmentation in the scalp hair, eyebrows and eyelashes was more severe than usually seen in patients with single mutations. In addition the face showed marked patchy pigmentation. One parent contributed the MITF mutation and the other added the mutation in PAX3.

 

Pedigree: 
Autosomal dominant
Treatment
Treatment Options: 

No ocular treatment is necessary.  Patients may benefit from cochlear implants.

References
Article Title: 

Albinism, Oculocutaneous, Type I

Clinical Characteristics
Ocular Features: 

Oculocutaneous albinism is a genetically and clinically heterogeneous condition.  It is congenital in origin and the combination of foveal hypoplasia and anomalous decussation of neuronal axons in the chiasm results in a permanent reduction of vision in the range of 20/50-20/200.  Most individuals have nystagmus, photophobia, and strabismus.  The iris usually is light blue and transmits light.  The retina lacks pigmentation as well.  The ocular features are similar in types IA and IB.  The iris may darken with age in type IB (606952 ). 

Systemic Features: 

There are generally no systemic abnormalities in these pigmentation disorders with the exception of sensorineural hearing loss in some, and, of course, complete absence of pigment in skin and hair.  Anomalous decussation of axons in the auditory system has been demonstrated in such cases and otic pigment is lacking in albinos.  The skin contains amelanic melanocytes but these cells contain granules similar to those of normal cells.   Some patients with residual tyrosinase activity (type 1B, 606952 ) develop some pigmentation of hair and skin, especially in cooler areas of the body such as the extremities. 

Genetics

This type of oculocutaneous albinism is caused by mutations in the TYR gene (11q14-q21) and inherited in an autosomal recessive pattern. 

Type IA (OCA1A) has no demonstrable tyrosinase activity while type IB (OCA1B, 606952) has a reduction in enzyme activity.  Yet other patients with mutations in TYR have a variant called 'yellow albinism' in which tyrosinase activity resembles that found in type IB.  To explain the difference in skin color, it has been suggested that an individual's background ethnicity may impact the pigmentation phenotype.

Other types also transmitted as autosomal recessive conditions are OCA2 (203200), OCA3 (203290), AND OCA4 (606574). 

Pedigree: 
Autosomal recessive
Treatment
Treatment Options: 

There is no treatment for the basic disease but low vision aids may be helpful for some patients.  Dark glasses provide comfort for photophobic individuals.  The skin should be protected against sunburn. 

References
Article Title: 

A new hypothesis of OCA1B

Chiang PW, Drautz JM, Tsai AC, Spector E, Clericuzio CL. A new hypothesis of OCA1B. Am J Med Genet A. 2008 Nov 15;146A(22):2968-70.

PubMed ID: 
18925668

Oculocutaneous albinism

Gronskov K, Ek J, Brondum-Nielsen K. Oculocutaneous albinism. Orphanet J Rare Dis. 2007 Nov 2;2:43. Review.

PubMed ID: 
17980020

Waardenburg Syndrome, Type 2

Clinical Characteristics
Ocular Features: 

This type of Waardenburg syndrome is distinguished from type 1 and 3 (193500) by the fact that it is caused by mutations in a different gene and in the absence of dystopia canthorum.  It has been claimed that hearing loss is more common and severe in type 2 (77%) as is heterochromia of the iris (47%) while skin and hair hypopigmentation are less common.

Families with WS2A may have the full spectrum of eye findings seen in X-linked ocular albinism I (300500) including decreased acuity, photophobia, nystagmus, translucent irides, hypermetropia, and albinotic fundi with foveal hypoplasia.  Indeed, such families have been considered to have 'albinism, ocular, with sensorineural deafness' (103470).  Such families might be considered to have an autosomal dominant form of ocular albinism.

Systemic Features: 

Congenital sensorineural hearing loss is an important and common feature.  Also characteristic are the white forelock, poliosis, and hypopigmented skin patches.

Genetics

Waardenburg syndrome is an excellent example of genetic heterogeneity as types 1 and 3 (193500, 148820), 2 (193510), and 4 (277580) are all caused by mutations in different genes. 

Type 2 described here is a genetically heterogeneous autosomal dominant disorder.  WS2A is caused by a mutation in MITF (microphthalmia-associated transcription factor) (3p14.1-p12.3).  This is the same disorder described as 'Albinism, ocular, with sensorineural deafness' in OMIM (103470)  (WS2-OA).

A locus at 1p21-p13.3 is associated with WS2B (600193) and WS2C (606662) maps to 8p23.  In addition, homozygous SNAI2 mutations at 8q11 have been found in several patients with WS2D (608890) suggesting autosomal recessive inheritance but the normal parents were not studied.  Recent evidence suggests that SOX10 mutations can also play a role via MITF promoter modulation (WS2E) (611584).

Type 4 is also the result of mutations in at last three genes.

A child has been reported who was doubly heterozygous for mutations involving both MITF and PAX3.  Hypopigmentation in the scalp hair, eyebrows and eyelashes was more severe than usually seen in patients with single mutations.  In addition the face showed marked patchy pigmentation.  One parent contributed the MITF mutation and the other added the mutation in PAX3.

Pedigree: 
Autosomal dominant
Treatment
Treatment Options: 

No ocular treatment is necessary but assistive hearing devices can be helpful.

References
Article Title: 
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