Biology:Glycophorin A

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Short description: Protein-coding gene in the species Homo sapiens


A representation of the 3D structure of the protein myoglobin showing turquoise α-helices.
Generic protein structure example

Glycophorin A (MNS blood group), also known as GYPA, is a protein which in humans is encoded by the GYPA gene.[1] GYPA has also recently been designated CD235a (cluster of differentiation 235a).

Function

Glycophorins A (GYPA; this protein) and B (GYPB) are major sialoglycoproteins of the human erythrocyte membrane which bear the antigenic determinants for the MN and Ss blood groups. In addition to the M or N and S or s antigens, that commonly occur in all populations, about 40 related variant phenotypes have been identified. These variants include all the variants of the Miltenberger complex and several isoforms of Sta; also, Dantu, Sat, He, Mg, and deletion variants Ena, S-s-U- and Mk. Most of the variants are the result of gene recombinations between GYPA and GYPB.[1]

Genomics

GypA, GypB and GypE are members of the same family and are located on the long arm of chromosome 4 (chromosome 4q31). The family evolved via two separate gene duplication events. The initial duplication gave rise to two genes one of subsequently evolved into GypA and the other which give rise via a second duplication event to GypB and GypE. These events appear to have occurred within a relatively short time span. The second duplication appears to have occurred via an unequal crossing over event.

The GypA gene itself consists of 7 exons and has 97% sequence homology with GypB and GypE from the 5' untranslated transcription region (UTR) to the coding sequence encoding the first 45 amino acids. The exon at this point encodes the transmembrane domain. Within the intron downstream of this pint is an Alu repeat. The cross over event which created the genes ancestral to GypA and GypB/E occurred within this region.

GypA can be found in all primates. GypB can be found only in gorillas and some of the higher primates suggesting that the duplication events occurred only recently.

Molecular biology

There are about one million copies of this protein per erythrocyte.[2]

Blood groups

The MNS blood group was the second set of antigens discovered. M and N were identified in 1927 by Landsteiner and Levine. S and s in were described later in 1947.

The frequencies of these antigens are

  • M: 78% Caucasoid; 74% Negroid
  • N: 72% Caucasoid; 75% Negroid
  • S: 55% Caucasoid; 31% Negroid
  • s: 89% Caucasoid; 93% Negroid

Molecular medicine

Transfusion medicine

The M and N antigens differ at two amino acid residues: the M allele has serine at position 1 (C at nucleotide 2) and glycine at position 5 (G at nucleotide 14) while the N allele has leucine at position 1 (T at nucleotide 2) and glutamate at position 5 (A at nucleotide 14). Both glycophorin A and B bind the Vicia graminea anti-N lectin.

There are about 40 known variants in the MNS blood group system. These have arisen largely as a result of mutations within the 4 kb region coding for the extracellular domain. These include the antigens Mg, Dantu, Henshaw (He), Miltenberger, Nya, Osa, Orriss (Or), Raddon (FR) and Stones (Sta). Chimpanzees also have an MN blood antigen system.[3] In chimpanzees M reacts strong but N only weakly.

Null mutants

In individuals who lack both glycophorin A and B the phenotype has been designated Mk.[4]

Dantu antigen

The Dantu antigen was described in 1984.[5] The Dantu antigen has an apparent molecular weight of 29 kilodaltons (kDa) and 99 amino acids. The first 39 amino acids of the Dantu antigen are derived from glycophorin B and residues 40-99 are derived from glycophorin A. Dantu is associated with very weak s antigen, a protease-resistant N antigen and either very weak or no U antigen. There are at least three variants: MD, NE and Ph.[6] The Dantu phenotype occurs with a frequency of Dantu phenotype is ~0.005 in American Blacks and < 0.001 in Germans.[7]

Henshaw antigen

The Henshaw (He) antigen is due to a mutation of the N terminal region. There are three differences in the first three amino acid residues: the usual form has Tryptophan1-Serine-Threonine-Serine-Glycine5 while Henshaw has Leucine1-Serine-Threonine-Threonine-Glutamate5. This antigen is rare in Caucasians but occurs at a frequency of 2.1% in US and UK of African origin. It occurs at the rate of 7.0% in blacks in Natal[8] and 2.7% in West Africans.[9] At least 3 variants of this antigen have been identified.

Miltenberger subsystem

The Miltenberger (Mi) subsystem originally consisting of five phenotypes (Mia, Vw, Mur, Hil and Hut)[10] now has 11 recognised phenotypes numbered I to XI (The antigen 'Mur' is named after to the patient the original serum was isolated from - a Mrs Murrel.) The name originally given to this complex refers to the reaction erythrocytes gave to the standard Miltenberger antisera used to test them. The subclasses were based on additional reactions with other standard antisera.

Mi-I (Mia), Mi-II(Vw), Mi-VII and Mi-VIII are carried on glycophorin A. Mi-I is due to a mutation at amino acid 28 (threonine to methionine: C→T at nucleotide 83) resulting in a loss of the glycosylation at the asparagine26 residue.[11][12] Mi-II is due to a mutation at amino acid 28 (threonine to lysine:C->A at nucleotide 83).[12] Similar to the case of Mi-I this mutation results in a loss of the glycosylation at the asparagine26 residue. This alteration in glycoslation is detectable by the presence of a new 32kDa glycoprotein stainable with PAS.[13] Mi-VII is due to a double mutation in glycophorin A converting an arginine residue into a threonine residue and a tyrosine residue into a serine at the positions 49 and 52 respectively.[14] The threonine-49 residue is glycosylated. This appears to be the origin of one of the Mi-VII specific antigens (Anek) which is known to lie between residues 40-61 of glycophorin A and comprises sialic acid residue(s) attached to O-glycosidically linked oligosaccharide(s). This also explains the loss of a high frequency antigen ((EnaKT)) found in normal glycophorin A which is located within the residues 46–56. Mi-VIII is due to a mutation at amino acid residue 49 (arginine->threonine).[15] M-VIII shares the Anek determinant with MiVII.[16] Mi-III, Mi-VI and Mi-X are due to rearrangements of glycophorin A and B in the order GlyA (alpha)-GlyB (delta)-GlyA (alpha).[17] Mil-IX in contrast is a reverse alpha-delta-alpha hybrid gene.[18] Mi-V, MiV(J.L.) and Sta are due to unequal but homologous crossing-over between alpha and delta glycophorin genes.[19] The MiV and MiV(J.L.) genes are arranged in the same 5' alpha-delta 3' frame whereas Sta gene is in a reciprocal 5'delta-alpha 3' configuration.

The incidence of Mi-I in Thailand is 9.7%.[20]

Peptide constructs representative of Mia mutations MUT and MUR have been attached onto red blood cells (known as kodecytes) and are able to detect antibodies against these Miltenberger antigens[21][22][23]

Although uncommon in Caucasians (0.0098%) and Japan ese (0.006%), the frequency of Mi-III is exceptionally high in several Taiwanese aboriginal tribes (up to 90%). In contrast its frequency is 2-3% in Han Taiwanese (Minnan). The Mi-III phenotype occurs in 6.28% of Hong Kong Chinese.[24]

Mi-IX (MNS32) occurs with a frequency of 0.43% in Denmark .[25]

Stone's antigen

Stones (Sta) has been shown to be the product of a hybrid gene of which the 5'-half is derived from the glycophorin B whereas the 3'-half is derived from the glycophorin A. Several isoforms are known. This antigen is now considered to be part of the Miltenberger complex.

Sat antigen

A related antigen is Sat. This gene has six exons of which exon I to exon IV are identical to the N allele of glycophorin A whereas its 3' portion, including exon V and exon VI, are derived from the glycophorin B gene. The mature protein SAT protein contains 104 amino acid residues.

Orriss antigen

Orriss (Or) appears to be a mutant of glycophorin A but its precise nature has not yet been determined.[26]

Mg antigen

The Mg antigen is carried on glycophorin A and lacks three O-glycolated side chains.[27]

Os antigen

Osa (MNS38) is due to a mutation at nucleotide 273 (C->T) lying within exon 3 resulting in the replacement of a proline residue with a serine.[28]

Ny antigen

Nya (MNS18) is due to a mutation at nucleotide 194 (T->A) which results in the substitution of an aspartate residue with a glutamate.[28]

Reactions

Anti-M although occurring naturally has rarely been implicated in transfusion reactions. Anti-N is not considered to cause transfusion reactions. Severe reactions have been reported with anti-Miltenberger. Anti Mi-I (Vw) and Mi-III has been recognised as a cause of haemolytic disease of the newborn.[29] Raddon has been associated with severe transfusion reactions.[30]

Relevance for infection

The Wright b antigen (Wrb) is located on glycophorin A and acts as a receptor for the malaria parasite Plasmodium falciparum.[31] Cells lacking glycophorins A (Ena) are resistant to invasion by this parasite.[32] The erythrocyte binding antigen 175 of P. falciparum recognises the terminal Neu5Ac(alpha 2-3)Gal-sequences of glycophorin A.[33]

Several viruses bind to glycophorin A including hepatitis A virus (via its capsid),[34] bovine parvovirus,[35] Sendai virus,[36] influenza A and B,[37] group C rotavirus,[38] encephalomyocarditis virus[39] and reoviruses.[40]

See also

References

  1. 1.0 1.1 "Entrez Gene: GYPA glycophorin A (MNS blood group)". https://www.ncbi.nlm.nih.gov/sites/entrez?Db=gene&Cmd=ShowDetailView&TermToSearch=2993. 
  2. Dean L. Blood Groups and Red Cell Antigens [Internet]. Bethesda (MD): National Center for Biotechnology Information (US); 2005. Chapter 12, The MNS blood group. Available from: https://www.ncbi.nlm.nih.gov/books/NBK2274/
  3. "The chimpanzee M blood-group antigen is a variant of the human M-N glycoproteins". Biochem. Genet. 21 (3–4): 333–48. April 1983. doi:10.1007/BF00499143. PMID 6860297. 
  4. "Two apparently healthy Japanese individuals of type MkMk have erythrocytes which lack both the blood group MN and Ss-active sialoglycoproteins". European Journal of Immunogenetics 6 (6): 383–90. December 1979. doi:10.1111/j.1744-313X.1979.tb00693.x. PMID 521666. 
  5. "Serology and genetics of an MNSs-associated antigen Dantu". Vox Sang. 46 (6): 377–86. 1984. doi:10.1111/j.1423-0410.1984.tb00102.x. PMID 6431691. 
  6. "A novel variety of the Dantu gene complex (DantuMD) detected in a Caucasian". Blut 58 (5): 247–53. May 1989. doi:10.1007/BF00320913. PMID 2470445. 
  7. "The Dantu erythrocyte phenotype of the NE variety. II. Serology, immunochemistry, genetics, and frequency". Blut 55 (1): 33–43. July 1987. doi:10.1007/BF00319639. PMID 3607294. 
  8. "Expression of the erythrocyte antigen Henshaw (He; MNS6): serological and immunochemical studies". Vox Sang. 68 (3): 183–6. 1995. doi:10.1111/j.1423-0410.1995.tb03924.x. PMID 7625076. 
  9. "A study of two unusual blood-group antigens in West Africans". Br Med J 2 (4829): 175–7. July 1953. doi:10.1136/bmj.2.4829.175. PMID 13059432. 
  10. Cleghorn TE (1966). "A memorandum on the Miltenberger blood groups". Vox Sang. 11 (2): 219–22. doi:10.1111/j.1423-0410.1966.tb04226.x. PMID 5955790. 
  11. "Molecular basis for the human erythrocyte glycophorin specifying the Miltenberger class I (MiI) phenotype". Blood 80 (1): 257–63. July 1992. doi:10.1182/blood.V80.1.257.257. PMID 1611092. 
  12. 12.0 12.1 "Structures of Miltenberger class I and II specific major human erythrocyte membrane sialoglycoproteins". Eur. J. Biochem. 138 (2): 259–65. January 1984. doi:10.1111/j.1432-1033.1984.tb07910.x. PMID 6697986. 
  13. "Miltenberger Class I and II erythrocytes carry a variant of glycophorin A". Biochem. J. 213 (2): 399–404. August 1983. doi:10.1042/bj2130399. PMID 6615443. 
  14. "Structural analysis of the major human erythrocyte membrane sialoglycoprotein from Miltenberger class VII cells". Eur. J. Biochem. 166 (1): 27–30. July 1987. doi:10.1111/j.1432-1033.1987.tb13478.x. PMID 2439339. 
  15. "Structural analysis of glycophorin A from Miltenberger class VIII erythrocytes". Biol. Chem. Hoppe-Seyler 370 (8): 855–9. August 1989. doi:10.1515/bchm3.1989.370.2.855. PMID 2590469. 
  16. "A new Miltenberger class detected by a second example of Anek type serum". Vox Sang. 41 (5–6): 302–5. 1981. doi:10.1111/j.1423-0410.1981.tb01053.x. PMID 6172902. 
  17. "Molecular genetics of human erythrocyte MiIII and MiVI glycophorins. Use of a pseudoexon in construction of two delta-alpha-delta hybrid genes resulting in antigenic diversification". J. Biol. Chem. 266 (11): 7248–55. April 1991. doi:10.1016/S0021-9258(20)89637-9. PMID 2016325. 
  18. "Molecular analysis of human glycophorin MiIX gene shows a silent segment transfer and untemplated mutation resulting from gene conversion via sequence repeats". Blood 80 (9): 2379–87. November 1992. doi:10.1182/blood.V80.9.2379.2379. PMID 1421409. 
  19. "Identification of recombination events resulting in three hybrid genes encoding human MiV, MiV(J.L.), and Sta glycophorins". Blood 77 (8): 1813–20. April 1991. doi:10.1182/blood.V77.8.1813.1813. PMID 2015404. 
  20. "Studies on the Miltenberger complex frequency in Thailand and family studies". Vox Sang. 28 (2): 152–5. 1975. doi:10.1111/j.1423-0410.1975.tb02753.x. PMID 1114793. 
  21. "Development of novel alloantibody screening cells – the first example of the addition of peptide antigens to human red cells using KODE technology. ISBT Regional Congress, Macao SAR China, 2008". (P-303)". Vox Sanguinis 95 (Suppl 1): 174. 2008. 
  22. "Novel antibody screening cells, MUT+Mur kodecytes, created by attaching peptides onto erythrocytes". Transfusion 50 (3): 635–641. 2010. doi:10.1111/j.1537-2995.2009.02480.x. PMID 19912581. 
  23. Flower R, Lin P-H, Heathcote D, Chan M, Teo D, Selkirk A, Shepherd R, Henry S. Insertion of KODE peptide constructs into red cell membranes: Creating artificial variant MNS blood group antigens. ISBT Regional Congress, Macao SAR China, 2008. (P-396) Vox Sanguinis 2008; 95:Suppl 1, 203-204
  24. "A survey of the incidence of Miltenberger antibodies among Hong Kong Chinese blood donors". Transfusion 34 (3): 238–41. March 1994. doi:10.1046/j.1537-2995.1994.34394196622.x. PMID 8146897. 
  25. "Miltenberger class IX of the MNS blood group system". Vox Sang. 61 (2): 130–6. 1991. doi:10.1111/j.1423-0410.1991.tb00258.x. PMID 1722368. 
  26. "Evidence that the low frequency antigen Orriss is part of the MN blood group system". Vox Sang. 52 (4): 330–4. 1987. doi:10.1111/j.1423-0410.1987.tb04902.x. PMID 2442891. 
  27. "Mg+ MNS blood group phenotype: further observations". Vox Sang. 66 (3): 237–41. 1994. doi:10.1111/j.1423-0410.1994.tb00316.x. PMID 8036795. 
  28. 28.0 28.1 "The low-frequency MNS blood group antigens Ny(a) (MNS18) and Os(a) (MNS38) are associated with GPA amino acid substitutions". Transfusion 40 (5): 555–9. May 2000. doi:10.1046/j.1537-2995.2000.40050555.x. PMID 10827258. 
  29. "Severe hemolytic disease of the newborn due to anti-Vw and detection of glycophorin A antigens on the Miltenberger I sialoglycoprotein by Western blotting". Vox Sang. 52 (4): 318–21. 1987. doi:10.1111/j.1423-0410.1987.tb04900.x. PMID 2442890. 
  30. "The first example of a Raddon-like antibody as a cause of a transfusion reaction". Transfusion 21 (1): 86–9. 1981. doi:10.1046/j.1537-2995.1981.21181127491.x. PMID 7466911. 
  31. "The Wrb antigen, a receptor for Plasmodium falciparum malaria, is located on a helical region of the major membrane sialoglycoprotein of human red blood cells". Biochem. J. 209 (1): 273–6. January 1983. doi:10.1042/bj2090273. PMID 6342608. 
  32. Facer CA (November 1983). "Merozoites of P. falciparum require glycophorin for invasion into red cells". Bull Soc Pathol Exot Filiales 76 (5): 463–9. PMID 6370471. 
  33. "A malaria invasion receptor, the 175-kilodalton erythrocyte binding antigen of Plasmodium falciparum recognizes the terminal Neu5Ac(alpha 2-3)Gal- sequences of glycophorin A". J. Cell Biol. 116 (4): 901–9. February 1992. doi:10.1083/jcb.116.4.901. PMID 1310320. 
  34. "Capsid region involved in hepatitis A virus binding to glycophorin A of the erythrocyte membrane". J. Virol. 78 (18): 9807–13. September 2004. doi:10.1128/JVI.78.18.9807-9813.2004. PMID 15331714. 
  35. "Binding of bovine parvovirus to erythrocyte membrane sialylglycoproteins". J. Gen. Virol.. 79 79 ( Pt 9) (9): 2163–9. September 1998. doi:10.1099/0022-1317-79-9-2163. PMID 9747725. 
  36. "Glycophorin as a receptor for Sendai virus". Biochemistry 35 (29): 9513–8. July 1996. doi:10.1021/bi9606152. PMID 8755731. 
  37. "Isolation and influenza virus receptor activity of glycophorins B, C and D from human erythrocyte membranes". Biochim. Biophys. Acta 1148 (1): 133–8. May 1993. doi:10.1016/0005-2736(93)90170-5. PMID 8499461. 
  38. Svensson L (September 1992). "Group C rotavirus requires sialic acid for erythrocyte and cell receptor binding". J. Virol. 66 (9): 5582–5. doi:10.1128/JVI.66.9.5582-5585.1992. PMID 1380096. 
  39. "Evidence for a direct role for sialic acid in the attachment of encephalomyocarditis virus to human erythrocytes". Biochemistry 29 (47): 10684–90. November 1990. doi:10.1021/bi00499a016. PMID 2176879. 
  40. "Glycophorin is the reovirus receptor on human erythrocytes". Virology 159 (1): 94–101. July 1987. doi:10.1016/0042-6822(87)90351-5. PMID 3604060. 

Further reading

External links

This article incorporates text from the United States National Library of Medicine, which is in the public domain.



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