Entry - #611804 - ELLIPTOCYTOSIS 1; EL1 - OMIM

 
ICD+
# 611804

ELLIPTOCYTOSIS 1; EL1


Alternative titles; symbols

ELLIPTOCYTOSIS, RHESUS-LINKED TYPE
PROTEIN 4.1 OF ERYTHROCYTE MEMBRANE, DEFECT OF
4.1-MINUS TRAIT
4.1- TRAIT


Phenotype-Gene Relationships

Location Phenotype Phenotype
MIM number 		Inheritance Phenotype
mapping key 		Gene/Locus Gene/Locus
MIM number
1p35.3 Elliptocytosis-1 611804 AD, AR 3 EPB41 130500
Clinical Synopsis
 

INHERITANCE
- Autosomal dominant
- Autosomal recessive
ABDOMEN
Spleen
- Splenomegaly
SKIN, NAILS, & HAIR
Skin
- Pallor
- Jaundice
HEMATOLOGY
- Elliptocytosis
- Anemia
- Aplastic crisis (in some patients)
MISCELLANEOUS
- Affected individuals may have heterozygous or homozygous mutations
- Patients with heterozygous mutations may be clinically asymptomatic
MOLECULAR BASIS
- Caused by mutation in the erythrocyte membrane protein band 4.1 gene (EPB41, 130500.0001)
▲ Close

TEXT

A number sign (#) is used with this entry because of evidence that elliptocytosis-1 (EL1) is caused by heterozygous or homozygous mutation in the gene encoding erythrocyte membrane protein 4.1 (EPB41; 130500) on chromosome 1p35.

Description

Elliptocytosis is a hematologic disorder characterized by elliptically shaped erythrocytes and a variable degree of hemolytic anemia. Usually inherited as an autosomal dominant trait, elliptocytosis results from mutation in any one of several genes encoding proteins of the red cell membrane skeleton (summary by McGuire et al., 1988).

Genetic Heterogeneity of Elliptocytosis

Elliptocytosis-2 (130600) is caused by mutation in the SPTA1 gene (182860). Elliptocytosis-3 (617948) is caused by mutation in the SPTB gene (182870). Elliptocytosis-4 (166900), also known as Southeast Asian ovalocytosis, is caused by mutation in the SLC4A1 gene (109270). Also see pyropoikilocytosis (266140).

See Delaunay (2007) for a discussion of the molecular basis of hereditary red cell membrane disorders.


Clinical Features

Because of the existence of at least 2 forms of elliptocytosis, one linked to Rh and one unlinked (Morton, 1956), phenotypic differences correlating with the differences in linkage relationships were sought. Geerdink et al. (1967) found more hemolysis in the 'unlinked' type than in the 'linked' type. Lux and Wolfe (1980) delineated 6 clinical varieties of hereditary elliptocytosis (HE). Peters et al. (1966), studying isolated red cell membranes, demonstrated an abnormality in erythrocyte sodium transport. The extensive study of elliptocytosis in Iceland reported by Jensson et al. (1967) showed how widely the manifestations may vary. All cases were plausibly considered to have the same gene. Additional evidence of heterogeneity in elliptocytosis may be provided by the effects of combination with beta-thalassemia. Aksoy and Erdem (1968) concluded that the combination sometimes results in mutual enhancement, whereas in other instances it does not.

Nielsen and Strunk (1968) described a Dutch family in which, among the 7 offspring of related parents, both with elliptocytosis, 2 died in infancy of severe anemia; a third had erythrocytes that showed more marked morphologic changes than in heterozygotes and had severe anemia which was compensated by splenectomy. All 3 were presumably homozygotes. Three other sibs were heterozygotes and one was stillborn. The elliptocytosis was of the Rh-linked variety. Lipton (1955) had reported an instance of presumed homozygosity; both parents had elliptocytosis without hemolysis and were second cousins. The child had hemolytic anemia. Splenectomy was beneficial.

Early demonstrations of abnormalities of band 4.1 were provided by Alloisio et al. (1981) and Tchernia et al. (1981). Tchernia et al. (1981) studied a family in which 3 of 5 sisters had severe hemolytic anemia, marked red cell fragmentation, and elliptocytic poikilocytosis. They were presumed to be homozygotes because both parents and a clinically unaffected (or minimally affected) sister had conventional elliptocytosis and were probably heterozygous. The parents were consanguineous. All 7 members of the nuclear family were Rh-identical (Rh-negative), making linkage study impossible. Band 4.1 in the red cell membrane proteins was markedly reduced in the 3 patients and reduced to an intermediate level in the 3 putative heterozygotes. Thus, band 4.1 is probably central to normal membrane stability and normal cell shape. The critical role of protein 4.1 in red cell membrane stability was demonstrated by the restoration of normal membrane stability with purified protein 4.1 (Takakuwa et al., 1986).

Alloisio et al. (1982) described a heritable variant of protein 4.1 that consists of shortening by about 75 amino acids, affecting both subcomponents a and b and involving one or more phosphorylation sites. The proposita was normal and was identified because of complete lack of protein 4.1 in her son with elliptocytosis. The father had elliptocytosis and reduced band 4.1. The son was presumably a compound heterozygote. Homozygotes with elliptocytosis and total absence of band 4.1 were described also by Feo et al. (1980). Morle et al. (1985) gave further information on the family reported by Alloisio et al. (1982) and referred to the variant as protein 4.1 Presles.

Alloisio et al. (1985) suggested that the heterozygous state of this form of hereditary elliptocytosis, called the 4.1(-) trait, results in a characteristic clinical picture. In the course of an elliptocytosis screening of 10 families from southeastern France and North Africa, Alloisio et al. (1985) found 4 in which a clinically silent, dominantly transmitted form of hereditary elliptocytosis was associated in every case with a decrease of band 4.1. In the other families, band 4.1 was normal, clinical signs were sometimes present, and in 3 the mode of inheritance was uncertain. Whereas heterozygous 4.1 deficiency accounts for one-fourth to one-third of hereditary elliptocytosis in Caucasians, homozygosity is rare. Dalla Venezia et al. (1992) suggested that the rarity of homozygous 4.1 deficiency is related to the severe effects on other cell types in addition to red cells.

Dhermy et al. (1986) reported studies of 38 cases of hereditary elliptocytosis. Fifteen patients showed a deficiency in protein 4.1. The other 24 patients showed a spectrin self-association defect (type I HE). A shortened spectrin beta chain was found in 1 family with a spectrin self-association defect. All patients with the protein 4.1 deficiency were Caucasian; most of the type I HE cases were of black extraction.

Lambert and Zail (1987) described partial deficiency of protein 4.1 as the cause of autosomal dominant hereditary elliptocytosis. They studied a total of 14 families, of which 1 was black, residing in South Africa.

Morle et al. (1987) described 2 sibs with severe congenital hemolytic anemia and red cells displaying a variety of abnormal shapes. Protein 4.1 was reduced by 30%. The parents, who were consanguineous, were devoid of any biochemical abnormality; however, their red cells were not normal. Whether the primary defect resided in protein 4.1 was not clear.


Mapping

On the basis of a family segregating for elliptocytosis and PGD (172200) as well as the common polymorphisms Rh, PGM1 and alpha-fucosidase, Cook et al. (1977) concluded that the map of 1p is, in the male, 1pter--PGD--18%--El--2%--Rh--2%--alpha-FUC--25%--PGM1--centromere. In the female, the above intervals were estimated to be 22, 4, 2, and 37%, respectively.

As knowledge of the molecular genetics of the red cell membrane proteins advanced, light was thrown on the early demonstration of linkage of Rh with one form of elliptocytosis and nonlinkage with other forms. The protein 4.1 gene was mapped to chromosome 1pter-p32 (Conboy et al. (1985, 1986)) by hybridization to chromosomes sorted onto nitrocellulose filters using a fluorescence-activated cell sorter. Studies of translocations also localized the gene to chromosome 1pter-p32, the region of the Rh gene (Kan, 1986). Thus, it seemed certain that the protein 4.1 gene is mutant in Rh-linked elliptocytosis. Parra et al. (1998) stated that the EPB41 gene is located on chromosome 1p33-p32.


Molecular Genetics

By Southern blot analysis of genomic DNA from affected members of an Algerian family with elliptocysis, Conboy et al. (1986) showed that the mutant protein 4.1 gene had a DNA rearrangement upstream from the initiation codon for translation (130500.0001). The mRNA from the mutant gene was aberrantly spliced.

McGuire and Agre (1987) demonstrated Rh linkage in 2 Caucasian families with a defect in protein 4.1. In 1 family the 4.1 band showed a reduction to about 65% of normal; in the other, a high molecular weight 4.1 was present. (A third proband had unstable 4.1.)

McGuire et al. (1988) found that variants of erythrocyte protein 4.1 were inherited in linkage with elliptocytosis and with Rh type in 3 white families.

Partial deletion of protein 4.1 was found in 1 family with elliptocytosis (Kan, 1986).

Lambert et al. (1988) found an elliptocytosis family in which an apparent rearrangement of the coding region of the protein 4.1 gene led to restriction fragment length polymorphism when DNA was tested using a fragment of the cDNA that encompassed the coding region of the gene.


History

In a family in which both elliptocytosis and hereditary hemorrhagic telangiectasia were segregating, Roberts (1945) pointed out that even small bodies of data are useful for excluding close linkage. The elliptocytosis/Rh linkage was one of the first autosomal linkages to be demonstrated (Morton, 1956).


REFERENCES

  1. Aksoy, M., Erdem, S. Combination of hereditary elliptocytosis and heterozygous beta-thalassemia: a family study. J. Med. Genet. 5: 298-301, 1968. [PubMed: 5713643, related citations] [Full Text]

  2. Alloisio, N., Dorleac, E., Delaunay, J., Girot, R., Galand, C., Boivin, P. A shortened variant of red cell membrane protein 4.1. Blood 60: 265-267, 1982. [PubMed: 7082842, related citations]

  3. Alloisio, N., Dorleac, E., Girot, R., Delaunay, J. Analysis of red cell membrane in a family with hereditary elliptocytosis: total or partial absence of protein 4.1. Hum. Genet. 59: 68-71, 1981. [PubMed: 10819025, related citations] [Full Text]

  4. Alloisio, N., Morle, L., Dorleac, E., Gentilhomme, O., Bachir, D., Guetarni, D., Colonna, P., Bost, M., Zouaoui, Z., Roda, L., Roussel, D., Delaunay, J. The heterozygous form of 4.1(-) hereditary elliptocytosis [the 4.1(-) trait]. Blood 65: 46-51, 1985. [PubMed: 3965051, related citations]

  5. Baker, S. J., Jacob, E., Rajan, K. T., Gault, E. W. Hereditary haemolytic anaemia associated with elliptocytosis: a study of three families. Brit. J. Haemat. 7: 210-222, 1961. [PubMed: 13686129, related citations] [Full Text]

  6. Clarke, C. A., Donohoe, W. T. A., Finn, R., McConnell, R. B., Sheppard, P. M., Nicol, D. S. H. Data on linkage in man: ovalocytosis, sickling and the Rhesus blood group complex. Ann. Hum. Genet. 24: 283-287, 1960. [PubMed: 13810494, related citations] [Full Text]

  7. Conboy, J. G., Mohandas, N., Wang, C., Tchernia, G., Shohet, S. B., Kan, Y. W. Molecular cloning and characterization of the gene coding for red cell membrane skeletal protein 4.1. (Abstract) Blood 66 (suppl. 1): 31A, 1985.

  8. Conboy, J., Mohandas, N., Tchernia, G., Kan, Y. W. Molecular basis of hereditary elliptocytosis due to protein 4.1 deficiency. New Eng. J. Med. 315: 680-685, 1986. [PubMed: 3755799, related citations] [Full Text]

  9. Cook, P. J. L., Noades, J. E., Newton, M. S., de Mey, R. On the orientation of the Rh:E1-1 linkage group. Ann. Hum. Genet. 41: 157-162, 1977. [PubMed: 413469, related citations] [Full Text]

  10. Dalla Venezia, N., Gilsanz, F., Alloisio, N., Ducluzeau, M.-T., Benz, E. J., Jr., Delaunay, J. Homozygous 4.1(-) hereditary elliptocytosis associated with a point mutation in the downstream initiation codon of protein 4.1 gene. J. Clin. Invest. 90: 1713-1717, 1992. [PubMed: 1430200, related citations] [Full Text]

  11. Delaunay, J. The molecular basis of hereditary red cell membrane disorders. Blood Rev. 21: 1-20, 2007. [PubMed: 16730867, related citations] [Full Text]

  12. Dhermy, D., Garbarz, M., Lecomte, M. C., Feo, C., Bournier, O., Chaveroche, I., Gautero, H., Galand, C., Boivin, P. Hereditary elliptocytosis: clinical, morphological and biochemical studies of 38 cases. Nouv. Rev. Franc. Hemat. 28: 129-140, 1986. [PubMed: 3748797, related citations]

  13. Feo, C. J., Fischer, S., Piau, J. P., Grange, M. J., Tchernia, G. Premiere observation de l'absence d'une proteine de la membrane erythrocytaire (bande 4-1) dans un cas d'anemie elliptocytaire familiale. Nouv. Rev. Franc. Hemat. 22: 315-325, 1980. [PubMed: 7255153, related citations]

  14. Garbarz, M., Dhermy, D., Lecomte, M. C., Feo, C., Chaveroche, I., Galand, C., Bournier, O., Bertrand, O., Boivin, P. A variant of erythrocyte membrane skeletal protein band 4.1 associated with hereditary elliptocytosis. Blood 64: 1006-1015, 1984. [PubMed: 6487803, related citations]

  15. Geerdink, R. A., Nijenhuis, L. E., Huizinga, J. Hereditary elliptocytosis: linkage data in man. Ann. Hum. Genet. 30: 363-378, 1967. [PubMed: 4981252, related citations] [Full Text]

  16. Jensson, O., Jonasson, T., Olafsson, O. Hereditary elliptocytosis in Iceland. Brit. J. Haemat. 13: 844-854, 1967. [PubMed: 6075442, related citations] [Full Text]

  17. Kan, Y.-W. Personal Communication. San Francisco, Calif. 2/28/1986.

  18. Kuroda, S., Takeuchi, T., Nagamori, H. Data on the linkage between elliptocytosis and Rh blood type. Jpn. J. Hum. Genet. 5: 112-118, 1960.

  19. Lambert, S., Conboy, J., Zail, S. A molecular study of heterozygous protein 4.1 deficiency in hereditary elliptocytosis. Blood 72: 1926-1929, 1988. [PubMed: 3058231, related citations]

  20. Lambert, S., Zail, S. Partial deficiency of protein 4.1 in hereditary elliptocytosis. Am. J. Hemat. 26: 263-272, 1987. [PubMed: 3674005, related citations] [Full Text]

  21. Lipton, E. L. Elliptocytosis with hemolytic anemia: the effects of splenectomy. Pediatrics 15: 67-82, 1955. [PubMed: 13224248, related citations]

  22. Lux, S. E., Wolfe, L. C. Inherited disorders of the red cell membrane skeleton. Pediat. Clin. N. Am. 27: 463-486, 1980. [PubMed: 6992078, related citations] [Full Text]

  23. McGuire, M., Agre, P. Three distinct variants of protein 4.1 in Caucasian hereditary elliptocytosis. (Abstract) Clin. Res. 35: 428A, 1987.

  24. McGuire, M., Smith, B. L., Agre, P. Distinct variants of erythrocyte protein 4.1 inherited in linkage with elliptocytosis and Rh type in three white families. Blood 72: 287-293, 1988. [PubMed: 3134067, related citations]

  25. Morle, L., Garbarz, M., Alloisio, N., Girot, R., Chaveroche, I., Boivin, P., Delaunay, J. The characterization of protein 4.1 Presles, a shortened variant of RBC membrane protein 4.1. Blood 65: 1511-1517, 1985. [PubMed: 3995181, related citations]

  26. Morle, L., Pothier, B., Alloisio, N., Ducluzeau, M.-T., Marques, S., Olim, G., Martins e Silva, J., Feo, C., Garbarz, M., Chaveroche, I., Boivin, P., Delaunay, J. Red cell membrane alteration involving protein 4.1 and protein 3 in a case of recessively inherited haemolytic anemia. Europ. J. Haemat. 38: 447-455, 1987. [PubMed: 3653367, related citations] [Full Text]

  27. Morton, N. E. The detection and estimation of linkage between the genes for elliptocytosis and the Rh blood type. Am. J. Hum. Genet. 8: 80-96, 1956. [PubMed: 13313518, related citations]

  28. Nielsen, J. A., Strunk, K. W. Homozygous hereditary elliptocytosis as the cause of haemolytic anemia in infancy. Scand. J. Haemat. 5: 486-496, 1968. [PubMed: 5731934, related citations] [Full Text]

  29. Parra, M., Gascard, P., Walensky, L. D., Snyder, S. H., Mohandas, N., Conboy, J. G. Cloning and characterization of 4.1G (EPB41L2), a new member of the skeletal protein 4.1 (EPB41) gene family. Genomics 49: 298-306, 1998. [PubMed: 9598318, related citations] [Full Text]

  30. Peters, J. C., Rowland, M., Israels, L. G., Zipursky, A. Erythrocyte sodium transport in hereditary elliptocytosis. Canad. J. Physiol. Pharm. 44: 817-827, 1966. [PubMed: 5970952, related citations] [Full Text]

  31. Roberts, J. A. F. Genetic linkage in man, with particular reference to the usefulness of very small bodies of data. Quart. J. Med. 14: 27-33, 1945.

  32. Takakuwa, Y., Tchernia, G., Rossi, M., Benabadji, M., Mohandas, N. Restoration of normal membrane stability to unstable protein 4.1-deficient erythrocyte membranes by incorporation of purified protein 4.1. J. Clin. Invest. 78: 80-85, 1986. [PubMed: 3722387, related citations] [Full Text]

  33. Tchernia, G., Mohandas, N., Shohet, S. B. Deficiency of skeletal membrane protein band 4.1 in homozygous hereditary elliptocytosis: implications for erythrocyte membrane stability. J. Clin. Invest. 68: 454-460, 1981. [PubMed: 6894932, related citations] [Full Text]

  34. Tomaselli, M. B., John, K. M., Lux, S. E. Elliptical erythrocyte membrane skeletons and heat-sensitive spectrin in hereditary elliptocytosis. Proc. Nat. Acad. Sci. 78: 1911-1915, 1981. [PubMed: 6940197, related citations] [Full Text]


Creation Date:
Victor A. McKusick : 2/20/2008
Edit History:
carol : 05/01/2018
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alopez : 04/25/2018
carol : 10/24/2016
carol : 10/20/2016
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# 611804

ELLIPTOCYTOSIS 1; EL1


Alternative titles; symbols

ELLIPTOCYTOSIS, RHESUS-LINKED TYPE
PROTEIN 4.1 OF ERYTHROCYTE MEMBRANE, DEFECT OF
4.1-MINUS TRAIT
4.1- TRAIT


ORPHA: 288;   DO: 2373;  


Phenotype-Gene Relationships

Location Phenotype Phenotype
MIM number 		Inheritance Phenotype
mapping key 		Gene/Locus Gene/Locus
MIM number
1p35.3 Elliptocytosis-1 611804 Autosomal dominant; Autosomal recessive 3 EPB41 130500

TEXT

A number sign (#) is used with this entry because of evidence that elliptocytosis-1 (EL1) is caused by heterozygous or homozygous mutation in the gene encoding erythrocyte membrane protein 4.1 (EPB41; 130500) on chromosome 1p35.

Description

Elliptocytosis is a hematologic disorder characterized by elliptically shaped erythrocytes and a variable degree of hemolytic anemia. Usually inherited as an autosomal dominant trait, elliptocytosis results from mutation in any one of several genes encoding proteins of the red cell membrane skeleton (summary by McGuire et al., 1988).

Genetic Heterogeneity of Elliptocytosis

Elliptocytosis-2 (130600) is caused by mutation in the SPTA1 gene (182860). Elliptocytosis-3 (617948) is caused by mutation in the SPTB gene (182870). Elliptocytosis-4 (166900), also known as Southeast Asian ovalocytosis, is caused by mutation in the SLC4A1 gene (109270). Also see pyropoikilocytosis (266140).

See Delaunay (2007) for a discussion of the molecular basis of hereditary red cell membrane disorders.


Clinical Features

Because of the existence of at least 2 forms of elliptocytosis, one linked to Rh and one unlinked (Morton, 1956), phenotypic differences correlating with the differences in linkage relationships were sought. Geerdink et al. (1967) found more hemolysis in the 'unlinked' type than in the 'linked' type. Lux and Wolfe (1980) delineated 6 clinical varieties of hereditary elliptocytosis (HE). Peters et al. (1966), studying isolated red cell membranes, demonstrated an abnormality in erythrocyte sodium transport. The extensive study of elliptocytosis in Iceland reported by Jensson et al. (1967) showed how widely the manifestations may vary. All cases were plausibly considered to have the same gene. Additional evidence of heterogeneity in elliptocytosis may be provided by the effects of combination with beta-thalassemia. Aksoy and Erdem (1968) concluded that the combination sometimes results in mutual enhancement, whereas in other instances it does not.

Nielsen and Strunk (1968) described a Dutch family in which, among the 7 offspring of related parents, both with elliptocytosis, 2 died in infancy of severe anemia; a third had erythrocytes that showed more marked morphologic changes than in heterozygotes and had severe anemia which was compensated by splenectomy. All 3 were presumably homozygotes. Three other sibs were heterozygotes and one was stillborn. The elliptocytosis was of the Rh-linked variety. Lipton (1955) had reported an instance of presumed homozygosity; both parents had elliptocytosis without hemolysis and were second cousins. The child had hemolytic anemia. Splenectomy was beneficial.

Early demonstrations of abnormalities of band 4.1 were provided by Alloisio et al. (1981) and Tchernia et al. (1981). Tchernia et al. (1981) studied a family in which 3 of 5 sisters had severe hemolytic anemia, marked red cell fragmentation, and elliptocytic poikilocytosis. They were presumed to be homozygotes because both parents and a clinically unaffected (or minimally affected) sister had conventional elliptocytosis and were probably heterozygous. The parents were consanguineous. All 7 members of the nuclear family were Rh-identical (Rh-negative), making linkage study impossible. Band 4.1 in the red cell membrane proteins was markedly reduced in the 3 patients and reduced to an intermediate level in the 3 putative heterozygotes. Thus, band 4.1 is probably central to normal membrane stability and normal cell shape. The critical role of protein 4.1 in red cell membrane stability was demonstrated by the restoration of normal membrane stability with purified protein 4.1 (Takakuwa et al., 1986).

Alloisio et al. (1982) described a heritable variant of protein 4.1 that consists of shortening by about 75 amino acids, affecting both subcomponents a and b and involving one or more phosphorylation sites. The proposita was normal and was identified because of complete lack of protein 4.1 in her son with elliptocytosis. The father had elliptocytosis and reduced band 4.1. The son was presumably a compound heterozygote. Homozygotes with elliptocytosis and total absence of band 4.1 were described also by Feo et al. (1980). Morle et al. (1985) gave further information on the family reported by Alloisio et al. (1982) and referred to the variant as protein 4.1 Presles.

Alloisio et al. (1985) suggested that the heterozygous state of this form of hereditary elliptocytosis, called the 4.1(-) trait, results in a characteristic clinical picture. In the course of an elliptocytosis screening of 10 families from southeastern France and North Africa, Alloisio et al. (1985) found 4 in which a clinically silent, dominantly transmitted form of hereditary elliptocytosis was associated in every case with a decrease of band 4.1. In the other families, band 4.1 was normal, clinical signs were sometimes present, and in 3 the mode of inheritance was uncertain. Whereas heterozygous 4.1 deficiency accounts for one-fourth to one-third of hereditary elliptocytosis in Caucasians, homozygosity is rare. Dalla Venezia et al. (1992) suggested that the rarity of homozygous 4.1 deficiency is related to the severe effects on other cell types in addition to red cells.

Dhermy et al. (1986) reported studies of 38 cases of hereditary elliptocytosis. Fifteen patients showed a deficiency in protein 4.1. The other 24 patients showed a spectrin self-association defect (type I HE). A shortened spectrin beta chain was found in 1 family with a spectrin self-association defect. All patients with the protein 4.1 deficiency were Caucasian; most of the type I HE cases were of black extraction.

Lambert and Zail (1987) described partial deficiency of protein 4.1 as the cause of autosomal dominant hereditary elliptocytosis. They studied a total of 14 families, of which 1 was black, residing in South Africa.

Morle et al. (1987) described 2 sibs with severe congenital hemolytic anemia and red cells displaying a variety of abnormal shapes. Protein 4.1 was reduced by 30%. The parents, who were consanguineous, were devoid of any biochemical abnormality; however, their red cells were not normal. Whether the primary defect resided in protein 4.1 was not clear.


Mapping

On the basis of a family segregating for elliptocytosis and PGD (172200) as well as the common polymorphisms Rh, PGM1 and alpha-fucosidase, Cook et al. (1977) concluded that the map of 1p is, in the male, 1pter--PGD--18%--El--2%--Rh--2%--alpha-FUC--25%--PGM1--centromere. In the female, the above intervals were estimated to be 22, 4, 2, and 37%, respectively.

As knowledge of the molecular genetics of the red cell membrane proteins advanced, light was thrown on the early demonstration of linkage of Rh with one form of elliptocytosis and nonlinkage with other forms. The protein 4.1 gene was mapped to chromosome 1pter-p32 (Conboy et al. (1985, 1986)) by hybridization to chromosomes sorted onto nitrocellulose filters using a fluorescence-activated cell sorter. Studies of translocations also localized the gene to chromosome 1pter-p32, the region of the Rh gene (Kan, 1986). Thus, it seemed certain that the protein 4.1 gene is mutant in Rh-linked elliptocytosis. Parra et al. (1998) stated that the EPB41 gene is located on chromosome 1p33-p32.


Molecular Genetics

By Southern blot analysis of genomic DNA from affected members of an Algerian family with elliptocysis, Conboy et al. (1986) showed that the mutant protein 4.1 gene had a DNA rearrangement upstream from the initiation codon for translation (130500.0001). The mRNA from the mutant gene was aberrantly spliced.

McGuire and Agre (1987) demonstrated Rh linkage in 2 Caucasian families with a defect in protein 4.1. In 1 family the 4.1 band showed a reduction to about 65% of normal; in the other, a high molecular weight 4.1 was present. (A third proband had unstable 4.1.)

McGuire et al. (1988) found that variants of erythrocyte protein 4.1 were inherited in linkage with elliptocytosis and with Rh type in 3 white families.

Partial deletion of protein 4.1 was found in 1 family with elliptocytosis (Kan, 1986).

Lambert et al. (1988) found an elliptocytosis family in which an apparent rearrangement of the coding region of the protein 4.1 gene led to restriction fragment length polymorphism when DNA was tested using a fragment of the cDNA that encompassed the coding region of the gene.


History

In a family in which both elliptocytosis and hereditary hemorrhagic telangiectasia were segregating, Roberts (1945) pointed out that even small bodies of data are useful for excluding close linkage. The elliptocytosis/Rh linkage was one of the first autosomal linkages to be demonstrated (Morton, 1956).


See Also:

Baker et al. (1961); Clarke et al. (1960); Garbarz et al. (1984); Kuroda et al. (1960); Tomaselli et al. (1981)

REFERENCES

  1. Aksoy, M., Erdem, S. Combination of hereditary elliptocytosis and heterozygous beta-thalassemia: a family study. J. Med. Genet. 5: 298-301, 1968. [PubMed: 5713643] [Full Text: https://doi.org/10.1136/jmg.5.4.298]

  2. Alloisio, N., Dorleac, E., Delaunay, J., Girot, R., Galand, C., Boivin, P. A shortened variant of red cell membrane protein 4.1. Blood 60: 265-267, 1982. [PubMed: 7082842]

  3. Alloisio, N., Dorleac, E., Girot, R., Delaunay, J. Analysis of red cell membrane in a family with hereditary elliptocytosis: total or partial absence of protein 4.1. Hum. Genet. 59: 68-71, 1981. [PubMed: 10819025] [Full Text: https://doi.org/10.1007/BF00278857]

  4. Alloisio, N., Morle, L., Dorleac, E., Gentilhomme, O., Bachir, D., Guetarni, D., Colonna, P., Bost, M., Zouaoui, Z., Roda, L., Roussel, D., Delaunay, J. The heterozygous form of 4.1(-) hereditary elliptocytosis [the 4.1(-) trait]. Blood 65: 46-51, 1985. [PubMed: 3965051]

  5. Baker, S. J., Jacob, E., Rajan, K. T., Gault, E. W. Hereditary haemolytic anaemia associated with elliptocytosis: a study of three families. Brit. J. Haemat. 7: 210-222, 1961. [PubMed: 13686129] [Full Text: https://doi.org/10.1111/j.1365-2141.1961.tb00330.x]

  6. Clarke, C. A., Donohoe, W. T. A., Finn, R., McConnell, R. B., Sheppard, P. M., Nicol, D. S. H. Data on linkage in man: ovalocytosis, sickling and the Rhesus blood group complex. Ann. Hum. Genet. 24: 283-287, 1960. [PubMed: 13810494] [Full Text: https://doi.org/10.1111/j.1469-1809.1960.tb01739.x]

  7. Conboy, J. G., Mohandas, N., Wang, C., Tchernia, G., Shohet, S. B., Kan, Y. W. Molecular cloning and characterization of the gene coding for red cell membrane skeletal protein 4.1. (Abstract) Blood 66 (suppl. 1): 31A, 1985.

  8. Conboy, J., Mohandas, N., Tchernia, G., Kan, Y. W. Molecular basis of hereditary elliptocytosis due to protein 4.1 deficiency. New Eng. J. Med. 315: 680-685, 1986. [PubMed: 3755799] [Full Text: https://doi.org/10.1056/NEJM198609113151105]

  9. Cook, P. J. L., Noades, J. E., Newton, M. S., de Mey, R. On the orientation of the Rh:E1-1 linkage group. Ann. Hum. Genet. 41: 157-162, 1977. [PubMed: 413469] [Full Text: https://doi.org/10.1111/j.1469-1809.1977.tb01910.x]

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Creation Date:
Victor A. McKusick : 2/20/2008

Edit History:
carol : 05/01/2018
ckniffin : 05/01/2018
alopez : 04/25/2018
carol : 10/24/2016
carol : 10/20/2016
carol : 03/28/2016
carol : 11/17/2015
carol : 11/17/2015
carol : 3/18/2009
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NOTE: OMIM is intended for use primarily by physicians and other professionals concerned with genetic disorders, by genetics researchers, and by advanced students in science and medicine. While the OMIM database is open to the public, users seeking information about a personal medical or genetic condition are urged to consult with a qualified physician for diagnosis and for answers to personal questions.
OMIM® and Online Mendelian Inheritance in Man® are registered trademarks of the Johns Hopkins University.
Copyright® 1966-2024 Johns Hopkins University.

NOTE: OMIM is intended for use primarily by physicians and other professionals concerned with genetic disorders, by genetics researchers, and by advanced students in science and medicine. While the OMIM database is open to the public, users seeking information about a personal medical or genetic condition are urged to consult with a qualified physician for diagnosis and for answers to personal questions.
OMIM® and Online Mendelian Inheritance in Man® are registered trademarks of the Johns Hopkins University.
Copyright® 1966-2024 Johns Hopkins University.
Printed: June 4, 2024