Hypopigmentation Disorders




Introduction


A diverse group of conditions present with hypopigmentation in neonates and infants. A practical clinical approach would be to categorize them according to the distribution of the hypopigmentation: generalized, mosaic, or localized ( Box 23.1 ). Some may be present at birth, but not noticed until later in infancy because neonates often have a lighter skin at birth than in later life.



Box 23.1

Hypopigmentary disorders in neonates and infants


Generalized hypopigmentation involving skin, hair and eyes





  • Oculocutaneous albinism



  • Hermansky–Pudlak syndrome



  • Chediak–Higashi syndrome



  • Cross syndrome



  • Metabolic disorders




    • Phenylketonuria



    • Histidinemia



    • Homocystinuria




Generalized hypopigmentation involving skin and hair





  • Griscelli syndrome



  • Elejalde syndrome



  • Menkes disease and occipital horn syndrome



Mosaic hypopigmentation





  • Nevoid hypopigmentation (hypomelanosis of Ito)



  • Nevus depigmentosus



Localized hypopigmentation





  • Piebaldism



  • Waardenburg syndrome



  • Tuberous sclerosis complex



  • Nevus anemicus



  • Vitiligo



  • Post-inflammatory hypopigmentation



  • Congenital halo nevi



Miscellaneous hypopigmentation





  • Alezzandrini syndrome



  • Ziprkowski–Margolis syndrome




Any defect occurring in melanocyte development, melanin synthesis and transport, or distribution of melanosomes to keratinocytes can result in a hypopigmentary disorder. Melanocytes originate from the neural crest and are located in the epidermis, hair bulb, eye (choroid, ciliary body, iris), inner ear (cochlea) and central nervous system (leptomeninges). Melanin is synthesized in melanosomes, which are organelles that share characteristics with lysosomes.


This chapter discusses a variety of clinical conditions causing hypopigmentation in neonates and infants, many of which have a genetic basis.




Generalized hypopigmentation of skin, hair, and eyes


Oculocutaneous albinism


Oculocutaneous albinism (OCA) refers to a group of autosomal recessive disorders involving abnormal melanin synthesis. Affected individuals have absent (type 1A) or reduced (type 1B, 2, 3, and 4) pigmentation in the skin, hair, and eyes from birth. The color varies from white to light brown, depending on ethnicity and the specific type of OCA. Ocular manifestations include nystagmus, photophobia, and decreased visual acuity. These are caused by decreased melanin within the eye or misrouting of optic nerve fibers. The affected infant is typically less pigmented than unaffected siblings.


Historically, OCA was divided into two clinical types based on the presence or absence of tyrosinase, the rate-limiting enzyme in the melanin biosynthetic pathway. Advances in molecular genetics have given rise to a more accurate classi­fication and better understanding of pathogenesis. In OCA, epidermal and follicular melanocytes are present in normal quantity and distribution but do not synthesize melanin adequately ( Table 23.1 ).



TABLE 23.1

Classification of disorders with cutaneous and ocular albinism



































































OCA1A Tyrosinase negative OCA1B Tyrosinase positive OCA2 Tyrosinase positive OCA3 Rufous OCA4 HPS CHS
Skin color White White at birth, develops some pigmentation in first and second decades Creamy white to brown at birth. Slight darkening with age Light brown to red-bronze Creamy white to brown at birth. Slight darkening with age White to brown Creamy white to slate gray
Pigmented nevi and freckles Absent Present Present Absent Present Many in exposed areas Present
Hair color White throughout life; may become light yellow White to light yellow at birth; turns yellow or blond in first few years Light yellow, blond to brown at birth; may darken with age Light brown to red-brown. May darken with age Silvery white to light yellow at birth. May darken in childhood White, blond to brown Blond to light brown; metallic silver-gray sheen
Gene (mapping), function TYR (11q14.3)
Encodes tyrosinase
TYR (11q14.3)
Encodes tyrosinase
OCA2 (15q11.2-q12)
Encodes P protein, a melanosomal membrane protein
TYRP1 (9q23)
Encodes dihydroxyindol carboxylic acid oxidase, a melanogenic enzyme
SLC45A2 (5p13.2)
Encodes membrane-associated transporter protein
HPS1: HPS1 (10q24.2)
HPS2: AP3B1 (5q14.1)
HPS3: HPS3 (3q24)
HPS4: HPS4 (22q12.1)
HPS5: HPS5 (11p15.1)
HPS6: HPS6 (10q24.32)
HPS7: DTNBP1 (6p22.3)
HPS8: BLOC1S3 (19q13.32)
HPS9: PLDN (15q21.1)
Encode proteins involved in biogenesis of lysosomes and lysosome-related organelles, such as melanosomes and platelet-dense granules. Some may play a role in intracellular vesicle trafficking
LYST (1q42.3)
Encodes lysosomal-trafficking regulator, a cytoplasmic protein which may function as an adapter protein that mediates intracellular membrane fusion reactions
Mouse model Albino Albino Pink-eye dilution Brown Underwhite HPS1: Pale-ear
HPS2: Pearl
HPS3: Cocoa
HPS4: Light-ear
HPS5: Ruby eye 2
HPS6: Ruby eye
HPS7: Sandy
HPS8: Reduced pigmentation
Beige
Hair bulb melanosomes Stages I, II Stages I, II, III Stages I, II, III Stages I, II, III, IV Stages I, II, III Stages I, II, III Macromelanosomes and normal to Stage IV

HPS, Hermansky–Pudlak syndrome; CHS, Chediak–Higashi syndrome.


Oculocutaneous albinism type 1


Oculocutaneous albinism type 1 (OCA1) is the second most common OCA worldwide.


Cutaneous findings


In OCA1A, there is marked generalized hypopigmentation at birth, with white hair and skin ( Figs. 23.1 , 23.2 ). As the child matures, the skin remains white. Nevi are not pigmented and sun tanning does not occur. The hair may acquire a slightly yellowish tint as a result of denaturing of hair keratins.




Figure 23.1


OCA1A.

Generalized hypopigmentation, including snow-white hair at birth.



Figure 23.2


OCA1A.

Infant of African descent with diffuse skin and hair hypopigmentation.


In OCA1B, the variable decrease in tyrosinase activity results in several clinical phenotypes: yellow, minimal pigment, platinum, and temperature-sensitive. Individuals with OCA1B form pheomelanin, which requires less tyrosinase activity, and this results in some pigment production during the first two decades of life. Affected individuals have a similar appearance to those with OCA1A at birth, but with time develop some pigment. Hair color can change from white to light blond and even progress to light brown in adolescence. With sun exposure, some individuals with OCA1B may be able to tan, although it is more common to burn without tanning. Pigmented nevi and freckles may develop.


An interesting subtype of OCA1B is the temperature-sensitive phenotype in which the tyrosinase activity is seen mainly on the extremities. In these patients, the enzyme has no activity at 37°C, but some activity at 35°C. These individuals have white or lightly pigmented hairs on the scalp and trunk (axillae, pubic area) and darkly pigmented hair peripherally (legs, arms). The pattern is similar to that observed in Siamese cats.


Extracutaneous findings


In OCA1A, the irises are pale blue at birth and throughout life. In bright light, the entire iris can appear pink or red, which is caused by its translucency. Severe photophobia results from a lack of retinal pigment. Other ocular abnormalities include decreased visual acuity, nystagmus, and strabismus.


In OCA1B, the irises can progressively darken to light tan or brown. In both subtypes, vision may remain stable or deteriorate with age.


Etiology and pathogenesis


OCA1 is caused by loss-of-function mutations in the tyrosinase gene ( TYR ), which is mapped to chromosome 11q14.3. Tyrosinase is the key enzyme that catalyzes the first two steps in melanin synthesis, converting tyrosine to L-DOPA (L-3,4-dihyroxyphenylalanine), and L-DOPA to DOPAquinone. The OCA1A subtype is characterized by mutations that result in complete loss of tyrosinase activity, whereas OCA1B is caused by mutations that result in markedly reduced tyrosinase activity (5–10% of the normal level).


Oculocutaneous albinism type 2


Oculocutaneous albinism type 2 (OCA2) is the most common form of OCA. It is most prevalent in people of African descent.


Cutaneous findings


There is a spectrum of clinical phenotypes, depending on the ethnic background and the dilution of hair and skin pigment, which may be minimal to moderate. Comparison with a first-degree relative may be necessary to distinguish the degree of lightening. Most individuals are born with creamy white skin, and light yellow or blond hair. Depending on the individual’s ethnic background, hair may also be reddish blond or brown. Pigmented birthmarks may be present. With maturity, the amount of pigment in the skin and hair tends to increase. In sun-exposed areas, pigmented nevi and freckles can develop.


Extracutaneous findings


The dilution of iris pigment may be mild to moderate. With age, the amount of pigment in the eyes tends to increase. Ocular manifestations are generally not as severe as those seen in OCA1A. Visual acuity and nystagmus tend to improve with age.


OCA2 can be found in 1% of individuals with Prader–Willi and Angelman syndromes.


Etiology and pathogenesis


OCA2 results from loss-of-function mutations of the OCA2 gene (previously called the P gene), which is mapped to chromosome 15q11.2–q13. The OCA2 gene encodes the P protein, a melanosomal membrane protein. The specific function of the P protein is currently not known, but is believed to be involved in tyrosine transport within the melanocyte, regulation of melanosome pH and tyrosinase processing and transport. The melanocytes of affected individuals are able to synthesize some melanin, but the majority is yellow pheomelanin rather than black-brown eumelanin.


Prader–Willi syndrome involves deletions of the 15q region, including the OCA2 gene, on the paternally inherited copy of chromosome 15, whereas Angelman syndrome involves loss of the maternally inherited allele. Deletion of one copy of the OCA2 gene associated with a mutation in the second copy results in OCA2 in these patients.


Oculocutaneous albinism type 3


OCA3, previously called ‘rufous OCA’, is most commonly seen in people of African and Puerto Rican descent.


Cutaneous findings


At birth, individuals with this tyrosinase-positive OCA have light brown to red-brown skin and hair. With age, the hair becomes more pigmented. Mild sun tanning is possible.


Extracutaneous findings


At birth, the irises are light brown and become more pigmented with age. Ocular manifestations are present, but less severe. Red reflex on transillumination of the iris and nystagmus are important clues to the diagnosis in dark-skinned people.


Etiology and pathogenesis


OCA3 is due to loss-of-function mutations of tyrosinase-related protein-1 gene ( TYRP1 ), which is mapped to chromosome 9q23. The TYRP1 gene encodes dihydroxyindolcarboxylic acid oxidase, a melanogenic enzyme essential for eumelanin synthesis.


Oculocutaneous albinism type 4


OCA4 may be one of the most common types of OCA in Japan, with solute carrier family 45, member 2, SLC45A2 (previously called ‘membrane-associated transporter protein’, MATP ) gene mutations found in 24% of 75 unrelated Japanese patients with OCA.


Cutaneous findings


The phenotype resembles that of OCA2 and the range of skin pigmentation is broad, from creamy white to brown. The hair is silvery white to light yellow at birth, and may darken in childhood.


Extracutaneous findings


Ocular manifestations include nystagmus, decreased iris pigment with iris translucency, reduced retinal pigment, foveal hypoplasia associated with reduction in visual acuity, and strabismus.


Etiology and pathogenesis


OCA4 results from mutations in the SLC45A2 gene, which is mapped to chromosome 5p13.2. The gene encodes a melanosomal membrane protein that is likely to function as a transporter. The similar functions of the OCA2 and SLC45A2 genes may explain the phenotypic resemblance of OCA2 and OCA4.


Differential diagnosis


The diagnosis of OCA is usually made clinically and can be confirmed by DNA mutation analysis. Historically, the hair bulb incubator test for tyrosinase activity was used to differentiate between tyrosinase-positive and tyrosinase-negative OCA. In tyrosinase-negative albinism, there is the lack of pigment formation in hair bulbs when incubated with tyrosine, whereas in tyrosinase-positive albinism, pigment is produced. Prenatal diagnosis of OCA using DNA mutation analysis is available.


OCA can be differentiated from other disorders with cutaneous and ocular albinism by the absence of neurological defects, immunodeficiency, and bleeding diathesis.


Treatment and care


No specific treatment is available for OCA. The importance of photoprotection, including sun avoidance, broad-spectrum sunscreen, protective eyewear and clothing, should be stressed to reduce the risk of photodamage and cutaneous malignancies. Early ophthalmologic evaluation and management is important. As squamous cell carcinomas and basal cell carcinomas have been known to develop in all types of OCA, yearly examination by a dermatologist is recommended.


Hermansky–pudlak syndrome


Hermansky–Pudlak syndrome (HPS) comprises nine genetically different autosomal recessive disorders characterized by tyrosinase-positive OCA, a bleeding diathesis, and a lysosomal ceroid storage disease affecting the viscera. The majority of individuals affected are of Puerto Rican or Dutch descent. HPS type 1 is the most common.


Cutaneous findings


The degree of pigmentary dilution in the skin and hair is highly variable. The color of the skin and hair ranges from white to brown.


Extracutaneous findings


The degree of pigmentary dilution in the eyes is highly variable. Other ocular findings include nystagmus, reduced retinal pigment, and foveal hypoplasia with significant reduction in visual acuity. The nystagmus is most obvious during periods of fatigue or emotional change. The bleeding diathesis is caused by platelet storage pool deficiency and results in epistaxis, gingival, menstrual, colonic or post-surgical bleeding. Platelet numbers, prothrombin time, and partial thromboplastin time are normal but bleeding time is prolonged. The absence of dense bodies on electron microscopy of platelets is pathognomonic of HPS. Lysosomal ceroid accumulation can result in interstitial pulmonary fibrosis, granulomatous colitis, cardiomyopathy, and renal failure. These life-threatening complications usually develop in adulthood. Some patients with HPS type 2 have persistent neutropenia and suffer from recurrent bacterial infections.


Etiology and pathogenesis


Most of the HPS-related genes encode proteins involved in the biogenesis of lysosome-related organelles. Ceroid is produced by degradation of lipids and glycoproteins within lysosomes. Ceroid accumulation in HPS suggests a defect in the elimination mechanisms of lysosomes.


Differential diagnosis


The diagnosis of HPS is made on clinical findings of oculocutaneous albinism, bleeding diathesis, and absence of dense bodies on electron microscopy of platelets. Molecular genetic testing of some HPS types, e.g. HPS1, HPS3, is available on a clinical basis. The differential diagnosis includes the Griscelli, Elejalde and Cross syndromes.


Treatment and care


Photoprotection is important, as patients have a predisposition to develop basal cell carcinoma and squamous cell carcinoma. An examination by a dermatologist should be performed annually. Patients should avoid aspirin and trauma to minimize the chance of a bleeding episode. Platelet transfusions may be considered prior to surgical procedures. Cigarette smoking should be avoided, as this reduces pulmonary function and may hasten progression of pulmonary fibrosis.


Chediak–higashi syndrome


Chediak–Higashi syndrome (CHS) is an autosomal recessive disorder characterized by OCA, immunodeficiency, progressive neurological deterioration, a mild bleeding tendency and abnormal inclusions present in a wide variety of cells.


Cutaneous findings


Compared with unaffected family members, the skin and the hair of affected individuals are lighter in color. Cutaneous pigmentation is often slightly to moderately decreased. The hair is blond to light brown, often with a silvery tint ( Fig. 23.3 ). Recurrent skin and systemic pyogenic infections occur in early childhood. Cutaneous involvement usually manifests as a pyoderma, and there are a few reports of deeper involvement resembling pyoderma gangrenosum.




Figure 23.3


Chediak–Higashi syndrome.

The hair displays a silvery sheen.


Extracutaneous findings


Loss of ocular pigmentation results in a translucent iris and pale retina, leading to photophobia and an increased red reflex. Visual acuity is normal, but strabismus and nystagmus are common.


Infections typically involve the skin, lungs, and upper respiratory tract. These intractable infections are often fatal before the age of 10 years. Common culprits include Staphylococcus aureus , Streptococcus pyogenes and S. pneumoniae .


Periodontitis is an important manifestation of the immunologic dysfunction.


Progressive neurologic deterioration with clumsiness, abnormal gait, paresthesias, and dysesthesias is often apparent later in childhood. Other neurologic abnormalities include peripheral and cranial neuropathies, spinocerebellar degeneration, ataxia, seizures, decreased deep tendon reflexes, cranial nerve palsies, and motor weakness.


Most patients with CHS eventually develop a lymphoproliferative syndrome (‘accelerated phase’) characterized by fever, hepatosplenomegaly, lymphadenopathy, pancytopenia, bleeding, and generalized lymphohistiocytic infiltrates. Viral infections, particularly with the Epstein–Barr virus, have been implicated in causing the accelerated phase.


Etiology and pathogenesis


CHS results from mutations in the lysosomal trafficking regu­lator gene ( LYST ) gene. The LYST gene (1q 42.1–q42.2) encodes a large cytoplasmic protein that appears to function as an adapter protein to mediate intracellular membrane fusion reactions.


Natural killer (NK) cell function is drastically decreased. Diminished chemotaxis of granulocytes, monocytes, and lymphocytes has also been reported, as well as decreased antibody-dependent cytotoxicity and reduced suppressor T-cell function. The resulting susceptibility to infections is caused by the combination of these factors.


The diagnostic hallmark of CHS is the finding of giant lysosomal granules within leukocytes, melanocytes, platelets, and other cells due to uncontrolled fusion of lysosomes. In bone marrow myeloid cells, the giant granules appear prominent. In melanocytes, giant melanosomes result from uncontrolled fusion of melanosomes, and this failure to disperse melanin to adjacent keratinocytes accounts for the decrease in pigmentation. On a cellular level, abnormal intracellular transport to and from the lysosomes has been detected. Giant granules within the phagocytic cells cannot discharge their lysosomal and peroxidative enzymes into phagocytic vacuoles. Prenatal diagnosis has been successfully performed using light microscopy by examining fetal hair shafts for characteristic clumping of melanosomes.


Treatment and care


Hematopoietic stem-cell transplantation (HSCT) is the only definitive treatment for this disorder. The NK cell defects and immunodeficiencies can be reversed, but the neurological deterioration and pigmentary dilution are not altered.


Without allogenic HSCT, patients who develop an accelerated phase usually die in childhood, usually from pyogenic infections or hemorrhage. Patients who do not develop an accelerated phase tend to have fewer or no infections, but usually develop progressively debilitating neurologic manifestations. Supportive treatments in early infancy include antibiotics for infections, and intravenous γ-globulin. Nonsteroidal anti-inflammatory drugs can exacerbate the bleeding tendency and should be avoided. Ascorbic acid has been shown to partially correct the granulocytic function in some patients.


Cross syndrome


Cross syndrome, or oculocerebral syndrome with hypopigmentation, is an oculocutaneous albinism associated with ocular anomalies, postnatal growth retardation, and neurological defects. The inheritance is probably autosomal recessive.


Cutaneous findings


The affected neonate has cutaneous generalized hypopigmentation and silvery hair.


Extracutaneous findings


Ocular defects include microphthalmos, a small opaque cornea, and nystagmus. Neurological defects include mental retardation, ataxia, and spasticity.


Treatment and care


Treatment is supportive.


Phenylketonuria (phenylalanine hydroxylase deficiency)


Phenylketonuria (PKU) is an autosomal recessive disorder that results from the impaired conversion of phenylalanine to tyrosine, which is caused by the absence of hepatic phenylalanine hydroxylase (PAH) activity. The absence of this enzyme leads to a build-up of the amino acid phenylalanine and its byproducts in the bloodstream and spinal fluid. The incidence in the USA is estimated at 1 in 10 000 among Caucasians. It is most commonly observed in individuals of Scandinavian, Turkish and Irish descent, with males and females equally affected. PKU without treatment results in mental retardation and oculocutaneous pigment dilution. Most affected individuals have blond hair, blue eyes, fair skin, photosensitivity, a musty body odor, and neurologic disturbances.


Cutaneous findings


At birth, the neonate appears normal but may have a musty odor secondary to urinary and sweat phenylacetic acid or phenyl­acetaldehyde. Caucasian children with PKU almost invariably have blond hair, blue eyes, fair skin, and photosensitivity. African-American and Asian children tend to be lighter in color than their parents and unaffected siblings. The ability to tan is normal. Endogenous eczema often develops in these patients.


Extracutaneous findings


In affected babies, serum phenylalanine levels begin to rise on the third or fourth day of life. Newborn screening with the Guthrie card bacterial inhibition assay test was implemented in the USA beginning in 1963, testing all newborns for PKU. Prenatal diagnosis is also possible by performing amniocentesis or chorionic villus sampling, with identification of the gene. Untreated PKU results in neurologic defects, including mental retardation, seizures, psychosis, hyperreflexia, and growth retardation.


Etiology and pathogenesis


Phenylalanine hydroxylase deficiency is caused by mutations in the PAH gene (mapped to 12q23.2), with more than 400 different mutations identified so far. Hypotheses to account for the decrease in skin and hair pigmentation include a competitive inhibition of the binding of tyrosine to tyrosinase by excess phenylalanine or a decreased amount of tyrosine.


Treatment and care


With a low phenylalanine diet, the skin color, photosensitivity, odor, and eczema are reversible. Implementing a diet low in phenylalanine early in infancy can also dramatically reduce the mental retardation. Although children with treated PKU typically have a lower IQ than the general population, affected individuals can be expected to have a low-normal to normal intelligence if blood phenylalanine is maintained at a reasonable level in early childhood. Supplementation with tyrosine or tryptophan in the diet may be necessary. For women with PAH deficiency who are considering pregnancy, dietary restriction must be started before conception and continued throughout pregnancy. Aspartame, an artificial sweetener that contains phenylalanine, should be avoided.




Generalized hypopigmentation involving skin and hair


Griscelli syndrome


Griscelli first described this syndrome in 1978. It is a rare autosomal recessive syndrome that results in pigmentary dilution of the skin and hair, the presence of large clumps of pigment in hair shafts, and an accumulation of melanosomes in melanocytes. There are three types:




  • Type 1 (GS1): association of hypopigmentation and neurological abnormalities, due to mutations of the MYO5A gene (15q21.2)



  • Type 2 (GS2): association of hypopigmentation and immunological abnormalities, due to RAB27A gene (15q21.3) mutation



  • Type 3 (GS3): only hypopigmentation, due to melanophilin ( MLPH ) gene (2q37.3) mutation.



Cutaneous findings


In early childhood, individuals with all three types of GS have silvery gray hair, eyebrows, and eyelashes (findings that may also be present in the neonatal period), and skin hypopigmentation.


Histologically, the hair shafts reveal uneven clumps of melanin, mainly in the medulla. Skin biopsy specimens reveal hyperpigmented oval melanocytes and poorly pigmented adjacent keratinocytes. On electron microscopic examination, epidermal melanocytes are found to contain perinuclear stage IV melanosomes. Adjacent keratinocytes contain only sparse melanosomes.


Prenatal diagnosis of Griscelli syndrome has been accomplished by examination of hair from fetal scalp biopsies performed at 21 weeks’ gestation, with confirmatory postabortion examination of the fetus revealing silvery hair and identical microscopic findings.


Extracutaneous findings


Neurological defects in GS1 include intracranial hypertension, cerebellar signs, encephalopathy, hemiparesis, peripheral facial palsy, spasticity, hypotonia, seizures, psychomotor retardation, and progressive neurologic deterioration.


Immunological abnormalities in GS2 result in severe pyogenic infections, due to defective release of cytotoxic lysosomal contents from hematopoietic cells, and a hemophagocytic syndrome. There is combined T- and B-cell immunodeficiency. Frequent pyogenic infections, acute febrile episodes, neutropenia, and thrombocytopenia usually begin between 4 months of age and 4 years. The hemophagocytic syndrome is characterized by acute onset of uncontrolled lymphocyte and macrophage activation, resulting in infiltration and hemophagocytosis in multiple organs and death.


Etiology and pathogenesis


The MYO5A , RAB27A and MLPH genes encode respectively myosin 5a, rab27a and melanophilin, which form a complex that allows the transport of melanosomes on actin fibers and the docking of melanosomes on the dendritic tips.


Differential diagnosis


Differentiation from Chediak–Higashi syndrome can be made by pathognomonic light and electron microscopic features. Griscelli syndrome lacks the large cytoplasmic inclusions and granulocyte abnormalities that are characteristic of Chediak–Higashi syndrome. Both diseases, however, are associated with an accelerated phase and carry a poor prognosis without bone marrow transplantation.


Treatment and care


Bone marrow transplant is most successful when performed early in the course of disease.


Elejalde syndrome


Elejalde syndrome, also called neuroectodermal melanolysosomal disease, is a rare autosomal recessive disorder characterized by silvery hair, hypopigmented skin, severe central nervous system dysfunction, and abnormal intracytoplasmic inclusions in fibroblasts, histiocytes, and lymphocytes.


Cutaneous findings


Neonates have silvery hair and generalized hypopigmentation of the skin, which may develop a bronze color after sun exposure.


In homozygotes, abnormal melanolysosomes are found in melanocytes and keratinocytes, cultured fibroblasts, and histiocytes of bone marrow.


Extracutaneous findings


Extracutaneous features include mental retardation, hypotonic facies, plagiocephaly, nystagmus, diplopia, micrognathia, crowded teeth, a narrow high palate, pectus excavatum, and cryptorchidism. Neurological abnormalities range from severe hypotonia and the almost complete absence of movements, to seizures and spasticity. The age of onset of neurologic signs ranges from 1 month to 11 years.


Differential diagnosis


Several authors have suggested that subtypes of Elejalde syndrome and Griscelli syndrome type 1 are the same entity. However, the absence of immunologic defects allows Elejalde syndrome to be distinguished from the Griscelli syndrome type 1. Chediak–Higashi syndrome should also be considered in the differential diagnosis.


Treatment and care


Treatment is supportive and prognosis is poor.


Menkes disease (and occipital horn syndrome)


Classic Menkes disease is a multisystem disorder that manifests with hypopigmentation, hair abnormalities, failure to thrive, connective tissue changes, seizures, neurological degeneration, and death by the age of 3 years. The disorder has a prevalence of 1 in 250 000–350 000 live births. Most infants born with Menkes disease appear normal for the first few months of life before showing a rapid decline in growth and neurologic development.


Cutaneous findings


The cutaneous manifestations include alterations in hair, pigmentation, and elasticity of the skin. The scalp hair may appear normal at birth, but by about 3 months of age, it becomes sparse, light colored, lusterless, with a ‘steel wool’ quality. The hair is fragile and fractures easily, resulting in generalized alopecia ( Fig. 23.4 ). Pili torti is the most common hair shaft abnormality ( Fig. 23.5 ), demonstrating a flattened appearance under light microscopy with multiple twists of 180° around the long axis of the shaft. The twisted hairs result from excessive free sulfhydryl groups and a decrease in copper-dependent disulfide bonds. Cutaneous hypopigmentation is common, may be generalized or localized to the skin folds, and is caused by decreased tyrosinase, a copper-containing enzyme. Scaly dermatitis in a seborrheic distribution occurs frequently and transient neonatal erythroderma has been reported as an initial manifestation of Menkes disease. The skin is lax, and this doughy laxity is most prominent over the posterior neck, eyebrows, and leg folds ( Fig. 23.6 ). Generalized puffiness of the cheeks and feet has been noted.




Figure 23.4


Sparse, short, hypopigmented hair in Menkes disease.

(Reproduced with permission from Schachner L, Hansen R. Pediatric dermatology. 3rd ed. Edinburgh: Mosby; 2003.)



Figure 23.5


Light microscopy showing pili torti.

(Reproduced with permission from Schachner L, Hansen R. Pediatric dermatology. 3rd ed. Edinburgh: Mosby; 2003.)



Figure 23.6


Lax skin in the groins and on the thighs.

(Reproduced with permission from Peterson J, Drolet BA, Esterly NB. Pediatr Dermatol 1998; 15:137–139.)


Extracutaneous findings


Progressive neurodegeneration begins at about 2 months of age as a result of gliosis and demyelination of the cerebrum and cerebellum. Patients present with seizures, hypothermia, developmental retardation, spontaneous subdural hematomas, muscle hypotonia, and feeding difficulties. Urogenital problems include undescended testes, hydronephrosis, hydro-ureter, recurrent urinary tract infections, diverticula of the ureters and bladder, and rupture of the bladder. Chronic intractable diarrhea resulting in malnutrition and increased frequency of congenital heart defects are seen. Skeletal abnormalities are manifested as wormian bones of the skull and spurring of long bone metaphyses. Connective tissue changes are evidenced by loose joints and tortuous blood vessels, such as the carotid and cerebellar arteries, which may cause intracranial hemorrhages. This increased tortuosity is secondary to fragmentation of the internal elastic lamina of the arteries. Low copper and ceruloplasmin levels in the serum and high copper levels in cultured fibroblasts are useful in the diagnosis. Menkes disease can be considered a disorder of copper maldistribution.


Etiology and pathogenesis


Menkes disease and occipital horn syndrome are rare, allelic, X-linked recessive copper deficiency disorders caused by mutations in the ATP7A gene (mapped to Xq21.1), which encodes a copper-transporting P-type ATPase involved in transport of copper to copper-requiring proteins. ATPase is localized in the trans-Golgi membrane of cells. The clinical features are due to malfunction of one or more copper-requiring enzymes, such as lysyl oxidase, tyrosinase, cytochrome C oxidase, and dopamine beta-hydroxylase, caused by the deficiency of the ATP7A protein ( Table 23.2 ). Most patients are males, although a few female patients have also been reported. Most of the female patients have an X; autosome translocation, where the normal X-chromosome is preferentially inactivated.



TABLE 23.2

Effects of defective copper-dependent enzymes in Menkes disease

































Clinical manifestations Defective enzyme (function)
Connective tissue abnormalities: Lysyl oxidase (cross-linkage of collagen and elastin)
Laxity of skin and joints
Vascular abnormalities
Bony abnormalities
Bladder diverticulae
Hypopigmentation Tyrosinase (production of melanin)
Coarse, sparse brittle hair Cross-linkase (cross-linkage of keratin)
Degeneration of myelin: seizures and spasticity Superoxidase dismutase (detoxification of free radicals)
Deficient energy production: myopathy, ataxia, seizures Cytochrome C oxidase (electron transport)
Hypothalamic imbalances: hypothermia, dehydration, hypotension, somnolence Dopamine β hydroxylase (production of catecholamines)


Occipital horn syndrome, formerly classified as Ehlers–Danlos syndrome type IX or X-linked cutis laxa, is now recognized as a milder form of Menkes disease and is caused by mutations in the same gene. Occipital horn syndrome is characterized primarily by connective tissue abnormalities, including skin laxity, hyperextensible joints, urinary tract diverticuli, hernias, and bony changes such as osteoporosis, arthrosis, and exostoses, such as the presence of a spike of ossification within the occipital insertion of the paraspinal muscles trapezius and sternocleidomastoid muscles at their attachments to the occipital bone (occipital horns), which gives the syndrome its name. Intelligence is normal or borderline, and patients can survive into adulthood. The milder phenotype results from the presence of low levels of functional ATP7A, unlike Menkes disease, in which no normal ATP7A activity exists.


Treatment and care


Daily subcutaneous administration of copper-histidine has been shown to be helpful in preventing the severe neurodegenerative problems in some patients with Menkes disease when the treatment is initiated early in life before the onset of significant neurological symptoms. This treatment, however, does not prevent the development of connective tissue problems, and cannot be regarded as a cure for Menkes disease.




Mosaic hypopigmentation


Mosaicism refers to the presence of two or more genetically distinct cell lines within an individual. These cell lines may be due to X-inactivation, as is normal in all human females, or to postzygotic somatic mutation. When mosaicism affects the skin, the affected skin may show patchy hypopigmentation or hyperpigmentation in a linear or segmental distribution ( Figs. 23.7 , 23.8 ). (Pigmentary mosaicism associated with hyperpigmented disorders is discussed in Chapter 24 , and other mosaic conditions in Chapter 29 .) Segmental hypopigmented lesions may be seen as an isolated cutaneous skin condition or as part of a genetic syndrome. The presence of mosaicism can sometimes be documented by the karyotyping of lymphocytes from peripheral blood or by genomic evaluation of both involved and uninvolved skin.




Figure 23.7


Nevoid hypopigmentation.

Whorls and streaks of macular hypopigmentation following lines of Blaschko.





Figure 23.8


Nevoid hypopigmentation without systemic anomalies.

This child was otherwise well.


In 1901, Blaschko characterized the distribution of segmental and linear skin abnormalities by examining patients with linear lesions and formulating a patterned composite diagram. He described these patterns as V-shaped or fountain-like over the spine, S-shaped or whorled on the anterior and lateral aspects of the trunk, and linear over the extremities (see Chapter 3 ). These lines should not be confused with dermatomes, which are the segments of skin that correspond to sensory innervation. Hypopigmentation that follows the lines of Blaschko and segmental patterns is thought to reflect cellular migration during embryogenesis affecting pigmentation.


Nevoid hypopigmentation


In 1952, a Japanese dermatologist named Ito described a 21-year-old woman with hypopigmented cutaneous whorls and streaks. As the distribution of the hypopigmentation was analogous to that of the hyperpigmented streaks observed in incontinentia pigmenti, he called the disorder ‘incontinentia pigmenti achromians’. To avoid confusion of these two unrelated entities, the preferred terminology later became ‘hypomelanosis of Ito’ (HI).


HI is a descriptive term, rather than a diagnosis. It has been used for a phenotype with unilateral or bilateral hypopigmented streaks and whorls that follow the lines of Blaschko and which are present at birth or become apparent within the first 2 years of life ( Figs 23.7 , 23.8 ). There may be associated systemic findings.


Recently, the terms ‘nevoid hypopigmentation,’ ‘mosaic hypopigmentation’ or ‘segmental pigmentary disorder’ with or without systemic anomalies, were adopted to better reflect the heterogeneous nature of this group of disorders.


Cutaneous findings


Hypopigmented whorls and streaks are distributed along the lines of Blaschko. They tend to be stable, although there are reported cases in which the pigmentary changes become more or less pronounced over time. In some cases, both hypopigmented and hyperpigmented streaks are evident. Wood’s lamp examination may help to determine the extent of the lesions in fair-skinned patients.


Extracutaneous findings


Extracutaneous findings are variable, and include central nervous, musculoskeletal, and/or ocular abnormalities. Defects of teeth, hair, nails, and sweat glands, as well as aplasia cutis, fibromas, and generalized or focal hypertrichosis, have been reported. Additional abnormalities reported include limb-length discrepancies, facial hemiatrophy, scoliosis, sternal abnormalities, dysmorphic facies, genitourinary and cardiac anomalies. Nearly all of the defects are detectable by a thorough physical examination and regular follow-up. Infants should be observed for evidence of CNS involvement, reflected by developmental delay or seizures. Most children with CNS involvement manifest with neurological abnormalities before 2 years of age.


Etiology and pathogenesis


Embryonic somatic mutations are the likely pathogenesis, with distribution and pattern of lesions determined by the type of progenitor cell affected and the timing of mutation during embryogenesis. Multiple chromosomal abnormalities have been associated with HI, and most cases are sporadic and have negligible risk of recurrence. On histologic examination, the hypopigmented areas have either normal or reduced numbers of melanocytes, and those melanocytes that are present demonstrate a reduction in the number of melanosomes.


Differential diagnosis


This includes nevus depigmentosus (also known as nevus achromicus) and Goltz syndrome. Patients with Goltz syndrome have both hyper- and hypopigmentation, as well as depressed areas of depigmentation following Blaschko’s lines.


Treatment and care


Cosmetic cover-up products can be used to conceal the hypopigmented areas but are usually not needed. The use of sunscreens can prevent or lessen the accentuation of pigmentary differences.


Nevus depigmentosus


Cutaneous findings


Nevus depigmentosus (nevus achromicus) is an uncommon birthmark occurring in 0.4% of newborns. It is a well-circumscribed area of hypopigmentation with an off-white color that may occur as a small isolated (circular or rectangular) patch, or develop in a unilateral segmental distribution or follow the lines of Blaschko. Hair within a nevus depigmentosus may also be hypopigmented, and the margins may be irregular or serrated. The isolated form is the most common ( Fig. 23.9 ) and the lesions do not usually cross the midline. The term depigmentosus is a misnomer because the lesions are actually hypopigmented, not completely depigmented, and become more prominent under Wood’s lamp. They are usually present at birth or become evident shortly thereafter, and remain stable in size and shape. Increase in size is in proportion to the growth of the child. Some lesions may appear during the first 3 years of life, with the trunk being the most commonly affected site. Occasionally, lesions may appear after the age of 3 years. In particular, the back and buttocks are most commonly affected, followed by the chest and abdomen. Males and females are affected equally and there is no distinct pattern of inheritance. The hypothesis is that during embryogenesis a clone of cells with a reduced melanogenic potential arises via a post-zygotic somatic mutation.




Figure 23.9


Nevus depigmentosus.

Well-circumscribed hypopigmented patch on the cheek that was present at birth.


Extracutaneous findings


Systemic manifestations are rare in patients with nevus depigmentosus. Neurologic abnormalities such as seizures and mental retardation have been reported, as well as ipsilateral hypertrophy of the extremities. In a survey of 50 patients with nevus depigmentosus, none had any extracutaneous features on examination. In two studies involving 29 patients with nevus depigmentosus, extracutaneous abnormalities were present in about 10% of the children. Occasionally, lentigines can develop within the achromic nevi, and this could be explained by the reversion of a mutation in one of the genes involved in pigmentation. There is a report of an infant developing multiple primary milia within a nevus depigmentosus.


Etiology and pathogenesis


With dopa-staining, normal melanocytes are seen in nevus depigmentosus, and electron microscopic studies suggest a reduced synthesis of melanosomes and also a defect in their transfer to the keratinocytes, which could account for the hypopigmentation. Transfer of melanosomes from melanocytes to keratinocytes is essential for normal pigmentation.


Differential diagnosis


Other entities with which nevus depigmentosus is sometimes confused include nevus anemicus, segmental vitiligo, hypopigmented lesions of tuberous sclerosis, and hypomelanosis of Ito. The distinction between nevus depigmentosus and hypomelanosis of Ito may be artificial, as many patients with segmental hypopigmented macules also have linear pigmentary anomalies, similar to those seen in hypomelanosis of Ito, and underlying mosaicism is the common factor. Patients currently diagnosed with either of these conditions might simply be categorized as having nevoid hypopigmentation with or without extracutaneous anomalies. Genetic analysis may be considered in all patients with segmental or linear pigmentary abnormalities, and those with extracutaneous abnormalities to investigate cytogenic anomalies.


Treatment and care


There has been a report of spontaneous resolution of nevus depigmentosus after a 6-year period. One patient with a nevus depigmentosus had partial repigmentation following autologous melanocyte grafting. The use of noncultured epidermal cellular grafting has been reported to be successful in the treatment of nevus depigmentosus and a mottled repigmentation of 78% was observed. Repigmentation however, may not be permanent and recurrence of a successfully repigmented nevus depigmentosus 6 years after blister roof grafting has been noted. Twice weekly narrow-band UVB for 32 sessions was helpful in repigmenting a nevus depigmentosus lesion, as was the 308 nm excimer laser. Cosmetic camouflage may be helpful.




Localized hypopigmented disorders


Piebaldism


Piebaldism is an autosomal dominant condition caused by defective cell proliferation and migration of melanocytes during embryogenesis.


Cutaneous findings


Piebaldism is characterized by congenital depigmented white patches of skin and hair on the forehead, central chest and abdomen, upper arms and lower legs, with normally pigmented skin on the hands and feet ( Fig. 23.10 ). A white forelock, which consists of a tuft of white hair over the midfrontal scalp is present in 80–90% of patients and is associated with depigmentation of the underlying scalp. Additional findings include poliosis of the eyebrows and eyelashes. The presence of islands of normally pigmented and hyperpigmented macules within the depigmented patches is typical and aids in the clinical diagnosis. The lesions are generally stable in size and increase in proportion to the growth of the child, although in some cases spontaneous contraction or expansion with the appearance of new hyperpigmented macules has been reported. Spontaneous repigmentation of leukoderma in sun-exposed areas such as the forehead or knees has been reported.




Figure 23.10


Piebaldism.


Light and electron microscopy studies show a complete absence of melanin and melanocytes in the epidermis and hair bulbs in the areas of leukoderma and poliosis. The hypermelanotic macules contain a normal number of melanocytes, but an abundance of abnormal melanosomes that are granular and spherical in shape.


Extracutaneous findings


Piebaldism is not typically associated with abnormalities of other organs, although associated mental retardation has been reported. This may represent contiguous gene deletion syndromes, with inclusion of the KIT gene responsible for piebaldism as well as nearby genes whose absence result in neurologic deficits. There have been at least five reports of piebaldism associated with neurofibromatosis type 1(NF1). Whether the simultaneous occurrence of these two dominantly inherited diseases is more than chance remains to be established. It has been suggested that café-au-lait macules and intertriginous freckling are occasional features of piebaldism itself and that the diagnosis of NF1 must be based on non-pigmentary diagnostic criteria such as neurofibromas or the presence of an NF1 gene mutation by DNA testing.


Etiology and pathogenesis


Piebaldism results from mutations of the KIT gene on chromosome 4q11–q12. This codes for the tyrosine kinase transmembrane cellular receptor for mast/stem cell growth factor, a critical factor for melanoblast migration, proliferation, differentiation, and survival. The KIT proto-oncogenes consist of an extracellular ligand-binding domain, a transmembrane domain, and a cytoplasmic tyrosine kinase domain. The severity of the clinical phenotype in piebaldism correlates with the site of the mutation within the KIT gene. The most severe mutations tend to be dominant negative missense mutations involving the intracellular tyrosine kinase domain. Mutations causing an intermediate severity phenotype have largely been located at the transmembrane region, and the mildest phenotypes are those that occur in the amino terminal extracellular ligand-binding domain. It has been shown that KIT activation induces the expression of a zinc-finger neural crest transcription factor SLUG, and that SLUG is necessary for the normal development of melanocytes, hematopoietic stem cells, and germ cells. It has also been shown that deletions in the SLUG ( SNA12 ) gene on chromosome 8q11 are responsible for some cases of piebaldism that lacked mutations in KIT .


Differential diagnosis


Disorders with similar clinical presentations are vitiligo and Waardenburg syndrome. Vitiligo is acquired later in life, tends to progress, and has a different distribution. Waardenburg syndrome is the major entity in the differential diagnosis of piebaldism, and the patient should be examined for evidence of facial dysmorphism, heterochromia of the irides, and congenital sensorineural hearing loss.


Treatment and care


Photoprotection of the depigmented patches is important, beginning early in life to protect the amelanotic areas from burning with sun exposure and to avoid skin cancers later on. Cosmetic camouflage or the use of a pigmenting tanning product such as dihydroxyacetone to camouflage the depigmented lesions are useful, although temporary. PUVA therapy is generally disappointing, but a combination of dermabrasion and split-thickness skin grafting followed by minigrafting or the use of autologous cultured epidermal grafts may be worthwhile in selected patients. Recently, the use of noncultured epidermal cellular grafting and melanocyte transplant techniques using noncultured melanocytes (minigrafting) has been shown to be helpful with high repigmentation rates.


Waardenburg syndrome


Waardenburg syndrome is a rare autosomal dominant disorder characterized by depigmented patches of the skin and hair, heterochromia iridis, congenital nerve deafness, and craniofacial anomalies. It is caused by the absence of melanocytes in the skin, hair, eyes, and stria vascularis of the cochlea, and is classified as a disorder of neural crest development.


The estimated incidence of Waardenburg syndrome is 1 in 42 000 in the Netherlands and 1 in 20 000 in Kenya. It accounts for between 2% and 5% of cases of congenital deafness. Both sexes and all races are equally affected. Four types of Waardenburg syndrome have been described on clinical and genetic grounds ( Box 23.2 ).



Box 23.2

Types of Waardenburg syndrome


Type I




  • 1.

    Autosomal dominant


  • 2.

    Dystopia canthorum


  • 3.

    White forelock (poliosis)


  • 4.

    Piebald skin lesions


  • 5.

    Synophrys (thickening of medial eyebrows)


  • 6.

    Broad nasal root


  • 7.

    Hypoplasia of nasal alae


  • 8.

    Heterochromia irides


  • 9.

    Congenital sensorineural hearing loss


  • 10.

    PAX3 gene mutations (chromosome 2q36.1)



Type II




  • 1.

    Autosomal dominant


  • 2.

    Similar features to type I, but lacks dystopia canthorum


  • 3.

    MITF mutations (chromosome 3p12)


  • 4.

    SOX10 mutations (chromosome 22q13)



Type III (Klein–Waardenburg)




  • 1.

    Autosomal dominant


  • 2.

    Similar features to type I


  • 3.

    Musculoskeletal abnormalities


  • 4.

    PAX3 gene mutations (chromosome 2q36.1)



Type IV (Shah–Waardenburg)




  • 1.

    Autosomal recessive


  • 2.

    Craniofacial abnormalities


  • 3.

    No dystopia canthorum


  • 4.

    Extensive depigmentation


  • 5.

    Hirschsprung disease


  • 6.

    Endothelin-3 gene mutations or one of its receptors, endothelin beta receptor (chromosome 13q22.3)


  • 7.

    SOX10 mutations


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Jul 23, 2019 | Posted by in PEDIATRICS | Comments Off on Hypopigmentation Disorders

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