Health Effects in Some Forms of Albinism (Besides Skin Cancer)

Facts about Albino Dobermans

Health Effects in Some Forms of Albinism (Besides Skin Cancer)

(modified 6/1/04)

Here's just a few examples of some of the ways in which albinism can affect health:

Amann, J., Ganjam, V. K., & Prieur, D. (1987). Thyroid function and histology in feline Chediak-Higashi syndrome (CHS). Federation Proceedings, 46(3), 649.

Amann, J. F., & Prieur, D. J. (1986). Muscle lesions in beige (Chediak-Higashi syndrome) and heterozygous C57BL/6J mice. Veterinary Pathology, 23(6), 692-697.

Bachli EB, Brack T, Eppler E, Stallmach T, Trueb RM, Huizing M, Gahl WA. (2004). Hermansky-Pudlak syndrome type 4 in a patient from Sri Lanka with pulmonary fibrosis. Am J Med Genet. Jun 1;127A(2):201-7. Hermansky-Pudlak syndrome (HPS) is a rare autosomal recessive disorder characterized by oculocutaneous albinism and a platelet storage pool deficiency. Some patients also develop fatal pulmonary fibrosis and some have granulomatous colitis....

Bell, T. G., Meyers, K. M., Prieur, D. J., Fauci, A. S., Wolff, S. M., & Padgett, G. A. (1976). Decreased nucleotide and serotonin storage associated with defective function in Chediak-Higashi syndrome cattle and human platelets. Federation Proceedings, 35(3), 807.

Bell, T. G., Meyers, K. M., Prieur, D. J., Fauci, A. S., Wolff, S. M., & Padgett, G. A. (1976). Decreased nucleotide and serotonin storage associated with defective function in Chediak-Higashi syndrome cattle and human platelets. Blood, 48(2), 175-184. ...Platelets from cattle with CHS failed to aggregate in the presence of acid-soluble collagen, which aggregated normal platelets. ...Serotonin content in CHS bovine platelets was only about 1.2% of the content in normal platelets. ATP and ADP contents in bovine CHS platelets were subnormal. The ATP/ADP ratio in normal platelets was 5.04, as opposed to 29.38 in CHS platelets. Similar studies were carried out in platelets from human beings with CHS.

Bennett DC. (2003). The colours of mice and men - 100 genes and beyond?. Pigment Cell Res, Oct;16(5):576-7. The number of colour genes in the mouse (genes affecting pigmentation of the hair, skin and eyes) has now exceeded 100, reaching at least 127 currently (1). Of these, about 60 or nearly half have been cloned, and all appear to have human orthologs. These genes can readily be divided into functional sets, which give some insight into the biological processes required for normal pigmentation. The largest set controls development and differentiation of the pigment cells, including for example transcription factors and growth factors. Mutations in these tend to give rise to white spotting or total loss of integumentary pigment, usually without affecting the eyes. The human equivalent mutations produce congenital white spotting with or without other birth defects such as deafness. A second set of genes encode protein components of the melanosome; mutations in these often affect both skin and eyes to produce oculocutaneous albinism, or altered coat colours in the mouse. A third set controls the biogenesis of lysosome-related organelles including the melanosome. Their mutations produce Hermansky-Pudlak syndrome in humans, and its models (such as cocoa and ruby-eye) in the mouse. The fourth set is involved in organelle transport, giving Griscelli syndrome and its models when mutated. Apart from some genes involved in general metabolic processes like copper transport, a last set of genes controls eumelanin versus pheomelanin synthesis. Some of these affect normal hair color in humans. ....

Boissy, R. E., & Nordlund, J. J. (1997). Molecular basis of congenital hypopigmentary disorders in humans: a review. Pigment Cell Res, 10(1-2), 12-24. Many specific gene products are sequentially made and utilized by the melanocyte as it emigrates from its embryonic origin, migrates into specific target sites, synthesizes melanin(s) within a specialized organelle, transfers pigment granules to neighboring cells, and responds to various exogenous cues. A mutation in many of the respective encoding genes can disrupt this process of melanogenesis and can result in hypopigmentary disorders. Following are examples highlighting this scenario. A subset of neural crest derived cells emigrate from the dorsal surface of the neural tube, become committed to the melanoblast lineage, and are targeted along the dorsal lateral pathway. The specific transcription factors PAX3 and MITF (microphthalmia transcription factor) appear to play a regulatory role in early embryonic development of the pigment system and in associated diseases (the Waardenburg syndromes). During the subsequent development and commitment of the melanoblast, concomitant expression of the receptors for fibroblasts growth factor (FGFR2), endothelin-B (EDNRB), and steel factor (cKIT) also appears essential for the continued survival of migrating melanoblasts. Lack or dysfunction of these receptors result in Apert syndrome, Hirschsprung syndrome and piebaldism, respectively. Once the melanocyte resides in its target tissue, a plethora of melanocyte specific enzymes and structural proteins are coordinately expressed to form the melanosome and to convert tyrosine to melanin within it. Mutations in the genes encoding these proteins results in a family of congenital hypopigmentary diseases called oculocutaneous albinism (OCA). The tyrosinase gene family of proteins (tyrosinase, TRP1, and TRP2) regulate the type of eumelanin synthesized and mutations affecting them result in OCA1, OCA3, and slaty (in the murine system), respectively. The P protein, with 12 transmembrane domains localized to the melanosome, has no assigned function as of yet but is responsible for OCA2 when dysfunctional. There are other genetically based syndromes, phenotypically resembling albinism, in which the synthesis of pigmented melanosomes, as well as specialized organelles of other cell types, is compromised. The Hermansky-Pudlak syndrome (HPS) and the Chediak-Higashi syndrome (CHS) are two such disorders. Eventually, the functional melanocyte must be maintained in the tissue throughout life. In some cases it is lost either normally or prematurely. White hair results in the absence of melanocytes repopulating the germinative hair follicle during subsequent anagen stages. Vitiligo, in contrast, results from the destruction and removal of the melanocyte in the epidermis and mucous membranes.

Burns, G. L., Meyers, K. M., & Prieur, D. J. (1984). Secondary amyloidosis in a bull with Chediak-Higashi syndrome. Canadian Journal of Comparative Medicine, 48(1), 113-114.

Chieffo, C., Stalis, I. H., Winkle, T. J. v., Haskins, M. E., Patterson, D. F., & Van Winkle, T. J. (1994). Cerebellar Purkinje's cell degeneration and coat color dilution in a family of Rhodesian Ridgeback dogs. Journal of Veterinary Internal Medicine, 8(2), 112-116.

Chiyonobu T, Yoshihara T, Fukushima Y, Yamamoto Y, Tsunamoto K, Nishimura Y, Ishida H, Toda T, Kasubuchi Y. (2002). Sister and brother with Vici syndrome: agenesis of the corpus callosum, albinism, and recurrent infections. Am J Med Genet, Apr 15;109(1):61-6. A sister and brother with Vici syndrome are described. They both had oculocutaneous albinism, agenesis of the corpus callosum, cataracts, and cardiomyopathy. They were born to healthy unrelated parents, and had postnatal growth retardation, profound developmental delay, hypotonia, and cataracts. The sister had recurrent infections, and died of progressive heart failure at age 19 months. The brother is alive at age six months with mild cardiomyopathy, and had a single episode of acute bronchitis at age three months. Review of the clinical manifestations of the sibs we described and six children reported in the literature indicates that Vici syndrome is a distinct clinical entity. Its main clinical manifestations include growth retardation, profound developmental delay, hypotonia, albinism, agenesis of the corpus callosum, cataracts, cardiomyopathy, and recurrent infections. The occurrence of the syndrome in three pairs of sibs of both sexes born to unaffected parents supports autosomal recessive inheritance.

Collier, L. L., Bryan, G. M., & Prieur, D. J. (1979). Ocular manifestations of the Chediak-Higashi syndrome in four species of animals. Journal of the American Veterinary Medical Association, 175(6), 587-590. Ocular examinations performed on cattle, cats, mink, and mice affected with the Chediak-Higashi syndrome (CHS) revealed photophobia, pale irises, and fundic hypopigmentation associated with red fundic light reflections. Cats with CHS also had cataracts. Spontaneous nystagmus was observed in four of nine cats with CHS, and the duration of induced nystagmus was longer in affected and Siamese cats than in clinically normal cats of other breeds. Tear secretion appeared to be normal in all species of animals with CHS. The ocular manifestations of CHS in these animals were similar to those reported in man.

Coupry I, Taine L, Goizet C, Soriano C, Mortemousque B, Arveiler B, Lacombe D. (2001). Leucodystrophy and oculocutaneous albinism in a child with an 11q14 deletion. J Med Genet, Jan;38(1):35-8. We report a patient with an undetermined leucodystrophy associated with type 1A oculocutaneous albinism (OCA). Type 1 OCA results from recessive mutations in the tyrosinase gene (TYR) located in 11q14.3. ....

Courtens, W., Broeckx, W., Ledoux, M., & Vamosa, E. (1989). Oculocerebral hypopigmentation syndrome (Cross syndrome) in a Gipsy child. Acta Paediatr Scand, 78(5), 806-10. A boy aged 2 years, born prematurely to Gipsy parents, presented with hypopigmentation severe encephalopathy with athetoid movements, bilateral ocular anomalies including cloudy corneas, iris atrophy and cataracts, as well as dental defects.....the diagnosis of the oculocerebral hypopigmentation syndrome (Cross syndrome).

Creel, D. (1980). Inappropriate use of albino animals as models in research. Pharmacol Biochem Behav, 12(6), 969-7. Sensory-neural, biochemical-metabolic, and physiological anomalies occur in albino mammals. There are ontogenic and biochemical parallels between the senses, peripheral nervous system, endocrine glands, metabolism, and melanin pigmentation. All albino mammals examined have abnormal optic systems. Many drugs cannot be adequately evaluated in an albino model because of melanin's ability to bind and interact with some chemicals. There is evidence that a general reduction in melanin pigment is correlated with a paucity of amino acids necessary for normal chemical function of the brain. There is a high probability that enzyme levels indicative of metabolic performance are deficient in the liver and kidneys oif albinos. Congenital defects are associated with hypopigmentation in animal models and human syndromes. Melanin is found in abundance in the eye, inner ear, and midbrain where neural impulses are initiated indicating a possible role as an electrophysiologic mechanism. Microwave irradiation differentially affects albino and pigmented animals. Implications of these observations and other reports of anomalies associated with hypopigmentation suggest caution in the use of albino and other hypomelanotic animals as normal models in biological research.

Creel, D., Collier, L. L., Leventhal, A. G., Conlee, J. W., & Prieur, D. J. (1982). Abnormal retinal projections in cats with Chediak-Higashi syndrome. Investigative Ophthalmology and Visual Science, 23(6), 798-801. In two Siamese cats with the syndrome, fragmentation of the A1 layer of the dorsal lateral geniculate nucleus into several islands was observed by autoradiographic techniques.

del Campo M, Hall BD, Aeby A, Nassogne MC, Verloes A, Roche C, Gonzalez C, Sanchez H, Garcia-Alix A, Cabanas F, Escudero RM, Hernandez R, Quero J. (1999). Albinism and agenesis of the corpus callosum with profound developmental delay: Vici syndrome, evidence for autosomal recessive inheritance. Am J Med Genet, Aug 27;85(5):479-85. We report on two sibs and two other unrelated patients with agenesis of corpus callosum, oculocutaneous albinism, repeated infections, and cardiomyopathy. All manifested postnatal growth retardation, microcephaly, and profound developmental delay. Additional central nervous system anomalies present in at least one patient included hypoplasia of the cerebellar vermis, white matter neuronal heterotopia, or bilateral schizencephaly. Repeated viral, bacterial, and fungal infections were consistent with a primary immunodeficiency. However, immunological studies showed variable, nonspecific findings. Cardiomyopathy with progressive heart failure or infection led to death before age 2 years in three of the patients. ....

Dube P, Der Kaloustian VM, Demczuk S, Saabti H, Koenekoop RK. (2000). A new association of congenital hydrocephalus, albinism, megalocornea, and retinal coloboma in a syndromic child: a clinical and genetic study. Ophthalmic Genet. Dec;21(4):211-6. We describe a child with global developmental delay, prominent metopic suture, trigonocephaly, and cryptorchidism whose symptoms resemble the well-known 9p deletion syndrome or 9p monosomy. We also noted congenital hydrocephalus, oculocutaneous albinism, retinal coloboma, and megalocornea, which are not typical features of 9p monosomy. ....

Duran McKinster, C., Rodriguez Jurado, R., Ridaura, C., de la Luz Orozco Covarrubias, M., Tamayo, L., & Ruiz Maldonando, R. (1999). Elejalde syndrome--a melanolysosomal neurocutaneous syndrome: clinical and morphological findings in 7 patients. Arch Dermatol, 135(2), 182-6. BACKGROUND: Silvery hair and severe dysfunction of the central nervous system (neuroectodermal melanolysosomal disease or Elejalde syndrome) characterize this rare autosomal recessive disease. Main clinical features include silver-leaden hair, bronze skin after sun exposure, and neurologic involvement (seizures, severe hypotonia, and mental retardation). Large granules of melanin unevenly distributed in the hair shaft are observed. Abnormal melanocytes and melanosomes and abnormal inclusion bodies in fibroblasts may be present. Differential diagnosis with Chediak-Higashi syndrome and Griscelli syndrome must be done. ....

Feng, G. H., Bailin, T., Oh, J., & Spritz, R. A. (1997). Mouse pale ear (ep) is homologous to human Hermansky-Pudlak syndrome and contains a rare 'AT-AC' intron. Hum Mol Genet, 6(5), 793-7. Hermansky-Pudlak syndrome (HPS) is a rare, often fatal, autosomal recessive disorder in which albinism, bleeding and lysosomal storage are associated with defects of diverse cytoplasmic organelles, including melanosomes, platelet dense granules and lysosomes. Similar multi-organellar defects occur in the Chediak-Higashi syndrome (CHS), as well as in a large number of different mouse mutants.....

Griffiths GM. (2002). Albinism and immunity: what's the link? Curr Mol Med, Aug;2(5):479-83. A small number of inherited diseases show a combination of immunological and pigmentation defects. Chediak-Higashi, Griscellis and Hermansky-Pudlak syndromes are all autosomal recessive diseases with these characteristics. Recent advances in both the identification of the genes giving rise to these diseases and the cell biology of immune cells and melanocytes have begun to reveal the molecular links between immunodeficiencies and albinism. These studies identify key proteins, such as Rab27a, which are critical for secretion of specialised granules found in melanocytes and immune cells. The granules of these cells are modified lysosomes termed 'secretory lysosomes'. These studies reveal that secretory lysosomes use specialised mechanisms of secretion, not found in other cell types, which explains the selective defects in these diseases.

Griscelli, C., Durandy, A., Guy Grand, D., Daguillard, F., Herzog, C., & Prunieras, M. (1978). A syndrome associating partial albinism and immunodeficiency. Am J Med, 65(4), 691-702. Two unrelated patients with partial albinism, frequent pyogenic infections and acute episodes of fever, neutropenia and thrombocytopenia are described. Their pigmentary dilution was characterized by large clumps of pigments in the hair shafts and an accumulation of melanosomes in melanocytes. Melanocytes had few short dendritic expansions, and keratinocytes were hypopigmented. No or few Langerhans' cells were detected in skin by electron microscopy and ATP-ase reactions. This pigmentary dilution, different from all other human albinisms, resembles the unique defect of the mutant dilute (d-d) mouse. Despite the presence of an adequate number of T and B lymphocytes, the patients were hypogammaglobulinemic, deficient in antibody production and incapable of manifesting delayed skin hypersensitivity or of rejecting skin grafts. Their leukocytes did not stimulate normal lymphocytes and could not generate cytotoxic cells during mixed leukocyte reaction. T lymphocytes of one patient were unable to exert a helper effect on the maturation of B lymphocytes into immunoglobulin-containing cells following in vitro stimulation with pokeweed mitogen.....

Gul D, Odabas E, Kutlu M. (2000). Oculocutaneous albinism and reduced bone density in two sibs: a new autosomal recessive syndrome? Clin Dysmorphol, Oct;9(4):295-6. A sister and brother, with oculocutaneous albinism and reduced bone density are described. Autosomal recessive inheritance is possible. This association has not been previously described.

Klein, C., Philippe, N., Le Deist, F., Fraitag, S., Prost, C., Durandy, A., Fischer, A., & Griscelli, C. (1994). Partial albinism with immunodeficiency (Griscelli syndrome). J Pediatr, 125(6 Pt 1), 886-95. Partial albinism with immunodeficiency is a rare and fatal immunologic disorder characterized by pigmentary dilution and variable cellular immunodeficiency. ....Primary abnormalities included a silvery-grayish sheen to the hair, large pigment agglomerations in hair shafts, and an abundance of mature melanosomes in melanocytes, with reduced pigmentation of adjacent keratinocytes. Clinical onset occurred between the ages of 4 months and 4 years and was characterized by accelerated phases (lymphohistiocytic infiltration of multiple organs, including the brain and the meninges), triggered by viral and bacterial infections. Characteristic laboratory features included pancytopenia, hypofibrinogenemia, hypertriglyceridemia, and hypoproteinemia. Consistent immunologic abnormalities were characterized by absent delayed-type cutaneous hypersensitivity and impaired natural killer cell function. Some patients had secondary hypogammaglobulinemia, impaired major histocompatibility complex-mediated cytotoxic effects, a decreased capacity of lymphocytes to trigger a mixed lymphocyte reaction, or various functional granulocytic abnormalities. The disease seems to be invariably lethal without bone marrow transplantation; the mean age at the time of death was 5 years. ....

Kramer, J. W., Davis, W. C., & Prieur, D. J. (1975). An inherited condition of enlarged leukocytic and melanin granules in cats: probable homology with the Chediak-Higashi syndrome. Federation Proceedings, 34(No.3), 861. The Chediak-Hagashi syndrome (CHS) is an autosomal recessive condition manifested morphologically by enlarged cytoplasmic granules in many cell types. CHS has been described in man, mink, cattle, mice and in a killer whale. A condition in a line of Persian cats which resembles CHS was recently observed. Enlarged cytoplasmic granules were present in leucocytes and melanophores in all the Persian cats (4) with yellow eyes and the 'Blue Smoke' coat colour which were examined, but were absent in related cats without the specified ocular and coat colours. Analysis of the pedigree of this family of cats suggests that the trait is inherited as an autosomal recessive condition. Round acidophilic cytoplasmic inclusions varying in diameter from 1 to 2 mu were present in Wright's stained neutrophils. These inclusions were detected in neutrophils from the myeloblast to the segmented stage. Electron microscopic cytochemistry revealed enlarged peroxidase-positive granules which thus correspond to azurophilic (primary) granules. Hair and skin from these cats contained enlarged melanin granules as compared to normal cats. Although an increased susceptibility to infection was not apparent, a bleeding tendency was present in these cats. The evidence suggests that the condition in these cats is homologous with CHS.

Kramer, J. W., Davis, W. C., & Prieur, D. J. (1977). The Chediak-Higashi syndrome of cats. Laboratory Investigation, 36(5), 554-562. Initial clinical, genetic, cytochemical, and ultrastructural studies were carried out to characterize the Chediak-Higashi syndrome in cats. Three cats with Chediak-Higashi syndrome were found in a single line of 27 Persian cats, and three additional affected cats were produced from two prospective breedings of the original line. The disorder was characterized genetically as an autosomal recessive condition. All cats in the line with the combination of yellow eye color and "blue smoke" hair colour exhibited the disorder. Four of the five cats examined had bilateral nuclear cataracts as early as three months of age. No increased susceptibility to infectious disease was observed. A bleeding tendency was noted. Abnormally large eosinophilic, sudanophilic, peroxidase-containing granules were observed in the neutrophiles of the granulocytic series of blood and bone marrow by electron and light microscopy. Granules of eosinophiles and basophiles were also enlarged. Light microscopic studies of hair and skin revealed enlarged melanin granules. These manifestations were similar to those in man, mink, cattle, mice, and the killer whale with Chediak-Higashi syndrome. Cats are the sixth species in which this genetic disease has been reported.

Lyerla TA, Rusiniak ME, Borchers M, Jahreis G, Tan J, Ohtake P, Novak EK, Swank RT. (2003). Aberrant lung structure, composition, and function in a murine model of Hermansky-Pudlak syndrome. Am J Physiol Lung Cell Mol Physiol. Sep;285(3):L643-53. Hermansky-Pudlak syndrome (HPS) is a genetically heterogeneous inherited disease causing hypopigmentation and prolonged bleeding times. An additional serious clinical problem of HPS is the development of lung pathology, which may lead to severe lung disease and premature death. ....

Mancini, A. J., Chan, L. S., & Paller, A. S. (1998). Partial albinism with immunodeficiency: Griscelli syndrome: report of a case and review of the literature. J Am Acad Dermatol, 38(2 Pt 2), 295-300. Partial albinism with immunodeficiency (Griscelli syndrome) is an uncommon disorder characterized by pigmentary dilution and variable immunodeficiency. Features include a silvery-gray sheen to the hair, large clumped melanosomes in hair shafts, and prominent mature melanosomes in cutaneous melanocytes with sparse pigmentation of adjacent keratinocytes. Immunologic abnormalities most often include impaired natural killer cell activity, absent delayed-type hypersensitivity, and impaired responses to mitogens.....The syndrome...carries a poor prognosis without bone marrow transplantation. We describe a patient with Griscelli syndrome who presented with hepatosplenomegaly, hepatitis, pancytopenia, and silvery hair in the newborn period.

Martinez-Arias R, Comas D, Andres A, Abello MT, Domingo-Roura X, Bertranpetit J. (2000). The tyrosinase gene in gorillas and the albinism of 'Snowflake'. Pigment Cell Res, Dec;13(6):467-70. The sequence of the tyrosinase (Tyr) gene coding tracts has been obtained for the gorilla (Gorilla gorilla gorilla). The five exons of the gene were sequenced in three gorillas and in a normally pigmented human. The tyrosinase gene has been found to be a very conserved locus with a very low substitution rate. Some nucleotide and amino acid differences were found between the gorilla and human tyrosinase coding sequences. One of the gorillas included in the study is the only known case of albinism in a gorilla ('Snowflake'). Mutations of the TYR gene lead to Oculocutaneous Albinism type 1 (OCA1), the most common type of albinism in humans (OMIM accession number 203100). The TYR gene encodes the tyrosinase enzyme (E.C. 1.14.18.1), whose activity was found to be completely lacking in 'Snowflake', indicating that a mutation in the Tyr gene is the likely cause of his albinism. Nonetheless, no nucleotide changes were detected that could account for the lack of Tyr product or tyrosinase activity in Snowflake, and explanations of these findings are discussed. (an added note: Snowflake recently died of squamous cell carcinoma)

McGarry, M. P., Reddington, M., Novak, E. K., & Swank, R. T. (1999). Survival and lung pathology of mouse models of Hermansky-Pudlak syndrome and Chediak-Higashi syndrome. Proc Soc Exp Biol Med, 220(3), 162-8. Hermansky-Pudlak Syndrome (HPS), a recessively inherited disease in humans, affects the biosynthesis/processing of the related intracellular organelles: lysosomes, melanosomes, and platelet dense granules. ....Mice doubly homozygous for the pale ear and ruby eye or for the muted and pearl genes had the shortest life spans with none surviving the two-year experimental duration. Life spans were similarly severely reduced in the beige and gunmetal mutants. Intermediate life spans were apparent in the pearl, pallid, and cocoa mutants whereas minimal effects were noted in ruby eye, muted, light ear, and cocoa mutants. ....

Meyers, K. M., Seachord, C. I., Prieur, D., & Holmsen, H. (1979). A serotonin induced biphasic aggregation by platelets from cats with the Chediak-Higashi syndrome. Thrombosis and Haemostasis, 42(1), 195.

Mottonen M, Lanning M, Baumann P, Saarinen-Pihkala UM. (2003). Chediak-Higashi syndrome: four cases from Northern Finland. Acta Paediatr, Sep;92(9):1047-51. Chediak-Higashi syndrome (CHS) is a rare multiorgan disease entity with autosomal recessive inheritance characterized by oculocutaneous albinism, bleeding tendency, recurrent bacterial infections and various neurological symptoms. Intracellular vesicle formation is deficient, resulting in giant granules in many cells, e.g. giant melanosomes in the melanocytes. Diagnosis has been based on morphological examination of peripheral blood and bone marrow, with giant granules seen in cells of the myeloid lineage and in lymphocytes. The ultimate diagnostic test is to look for a mutated LYST gene. Most patients develop an accelerated phase of the disease with deposition of lymphohistiocytes in the liver, spleen, lymph nodes and bone marrow, resulting in hepatosplenomegaly, bone marrow infiltration and haemophagocytosis. Peripheral blood neutropenia becomes more profound as anaemia and thrombocytopenia develop. Most patients succumb before the age of 10 years. ....

Oh, J., Bailin, T., Fukai, K., Feng, G. H., Ho, L., Mao, J. I., Frenk, E., Tamura, N., & Spritz, R. A. (1996). Positional cloning of a gene for Hermansky-Pudlak syndrome, a disorder of cytoplasmic organelles [see comments]. Nat Genet, 14(3), 300-6. Hermansky-Pudlak syndrome (HPS) is an often-fatal autosomal recessive disease in which albinism, bleeding, and lysosomal storage result from defects of diverse cytoplasmic organelles: melanosomes, platelet dense bodies, and lysosomes. ....

Pastural, E., Barrat, F. J., Dufourcq Lagelouse, R., Certain, S., Sanal, O., Jabado, N., Seger, R., Griscelli, C., Fischer, A., & de Saint Basile, G. (1997). Griscelli disease maps to chromosome 15q21 and is associated with mutations in the myosin-Va gene. Nat Genet, 16(3), 289-92. Griscelli disease (OMIM 214450) is a rare autosomal recessive disorder characterized by pigmentary dilution, variable cellular immunodeficiency and onset of acute phases of uncontrolled lymphocyte and macrophage activation, leading to death in the absence of bone-marrow transplantation.....

Penner, J. D., & Prieur, D. J. (1986). Homology of Chediak-Higashi syndrome in humans, cats, and mink. [Abstract]. Proceedings of the Society for Experimental Biology and Medicine, 181(1), 196.

Prieur, D. J. (1972). Defective function of renal lysosomes in mice with the Chediak-Higashi syndrome. Dissertation Abstracts International, 32b(No.8), 4933.

Prieur, D. J., & Collier, L. L. (1978). Animal model of human disease: Chediak-Higashi syndrome. Animal model: Chediak-Higashi syndrome of animals. American Journal of Pathology, 90(2), 533-536.

Prieur, D. J., & Collier, L. L. (1987). Neutropenia in cats with the Chediak-Higashi syndrome. Canadian Journal of Veterinary Research, 51(3), 407-408. Neutropenia is often present in human patients with Chediak-Higashi syndrome, but has not been reported in affected animals. This study confirms that affected cats have neutropenia, whereas unaffected cats genotypically heterozygous for the syndrome do not. No lysozyme activity was detected in the serum.

Sanal, O., Kucukali, T., Ersoy, F., Tinaztepe, K., & Gogus, S. (1993). Griscelli's syndrome: clinical features of three siblings. Turk J Pediatr, 35(2), 115-9 Issn: 0041-4301. Three siblings diagnosed as having Griscelli's syndrome (GS) are presented. The clinical features were partial albinism, silvery hair and absence of giant granules in the white blood cells. ....The first sibling died at the age of two, having a clinical picture suggestive of bulbar poliomyelitis. However, no tissue was available for histopathologic examination. The second sibling developed fever, jaundice, seizure, hepatosplenomegaly and lymphadenopathy and died at the age of six. Postmortem examination of this sibling revealed lymphohistiocytosis in the liver and spleen. The propositus died at the age of five following development of central nervous system involvement. Immunologic studies were not available in the first sibling. The IgG level was slightly low and the T-lymphocyte number was normal in the second sibling. The propositus had normal serum immunoglobulin levels and T-cell numbers and skin tests were positive with phytohemagglutinin and candida.

Scheinfeld NS. (2003). Syndromic albinism: a review of genetics and phenotypes. Dermatol Online J, Dec;9(5):5. There are several syndromes of albinism associated with systemic pathology. These include Chediak-Higashi Syndrome (CHS), Hermansky-Pudlack Syndrome (HPS), Griscelli Syndrome (GS), Elejalde Syndrome (ES) and Cross-McKusick-Breen Syndrome (CMBS). In the last several years the genetic defects underlying some of these syndromes have been described. HPS is related to 7 genes in humans. GS is related to 3 genes: MYOVA, Rab-27A, and melanophilin (Mlph). CHS is related to one gene: LYST. The genetic defects in ES and CMBS are yet to be defined. Syndromic forms of albinism are associated with defects in the packaging of melanin and other cellular proteins. As such they are distinct from oculocutaneous albinism, which is associated with defects in the production of melanin (e.g., TRP1, P gene, and tyrosinase).

Searle, A. G. (1990). Comparative genetics of albinism. Ophthalmic Paediatr Genet, 11(3), 159-64. ....The optic track misrouting found in human albinos also occurs in albino alleles in other mammals, which may also show reduced activity and stress responses.....in the mouse, [albinistic mutations] are associated with defects of kidney, liver and thymus. Tyrosinase-positive albinos or near-albinos are known at a number of loci in mice and other mammals. They are the result of the absence or inhibition of melanocytes in the affected areas, so that no melanin is produced. In general they are associated with pathological pleiotropisms which may lead to anaemia, inner ear defects, megacolon, neurological effects, skeletal defects, microphthalmia, osteopetrosis, spina bifida, sterility and so on.....

Silveira-Moriyama L, Moriyama TS, Gabbi TV, Ranvaud R, Barbosa ER. (2004). Chediak-Higashi syndrome with parkinsonism. Mov Disord, Apr;19(4):472-5. Chediak-Higashi syndrome (CHS), typically presents with partial albinism and severe hematological abnormalities. About 10% of the patients have a mild adult form associated with various neurological manifestations....

Verheij JB, Kunze J, Osinga J, van Essen AJ, Hofstra RM. (2002). ABCD syndrome is caused by a homozygous mutation in the EDNRB gene. Am J Med Genet, 2002 Mar 15;108(3):223-5. ABCD syndrome is an autosomal recessive syndrome characterized by albinism, black lock, cell migration disorder of the neurocytes of the gut (Hirschsprung disease [HSCR]), and deafness. ....

Ziakas NG, Jogiya A, Michaelides M. (2004). Eye. A case of familial trichomegaly in association with oculocutaneous albinism type 1..

Back to the main page