Erythrocytosis is a disorder of red cell production that can arise from several different causes. Familial cases have been classified into four groups (ECYT1-4) by Online Mendelian Inheritance in Man (OMIM) as listed at the website: http://www.ncbi.nlm.nih.gov/sites/entrez?db=OMIM. Erythrocytosis associated with mutations in the erythropoietin receptor belong to group ECYT1 and arise from a primary cause that is intrinsic to the red cell.1 The other three categories of erythrocytosis, ECYT2-4, are secondary and are characterized by dysregulated erythropoietin (Epo) production resulting from defects in the oxygen sensing pathway.1 OMIM classification does not consider other secondary causes of erythrocytosis that are related to abnormal oxygen delivery such as hemoglobin (Hb) variants or 2,3-biphosphoglycerate mutase (BPG) deficiencies. Approximately 100 hemoglobin variants with a high affinity for oxygen have been described that cause a decrease in the supply of oxygen to tissues.2 These Hb variants are inherited in an autosomal dominant manner with an associated family history.2 Both α and β globin genes can be affected2 and the serum Epo would be inappropriately normal for the associated raised hematocrit.
During the differential diagnosis of erythrocytosis, a high oxygen affinity Hb can be excluded by studying the oxygen binding properties of freshly drawn blood.2–4 Blood gas analyzers available in all hospitals will calculate P50 values. High affinity Hbs cause a left shift in the oxygen dissociation curve and thus lower the P50 value. Not all high affinity Hb variants are detected by routine Hb electrophoresis and isoelectric focusing in polyacry-lamide and hence a number are misdiagnosed.
Over the last decade we have developed a data base of erythrocytosis patients referred from centers throughout the UK and Ireland.5 Before patients can be included in the registry all secondary causes of erythrocytosis should be excluded. During an audit of the data base we decided it may be useful to confirm the absence of high oxygen affinity Hb variants. Patients with a strong family history and serum Epo within the reference range or above were selected for β globin gene sequencing. Those patients negative for a β chain variant were further screened for an alpha globin gene variant. Four different high oxygen affinity Hb variants, Olympia (β20Va→Met),1,6,7 Pierre-Benite (β90Glu→Asp),6,8 Santa Clara (β97His→Asn)6,9 and Heathrow (β103Phe→Leu),6,10 were detected in 6 families from a data base of 205 individuals giving a prevalence of 3%. All are electrophoretically silent and hence difficult to detect by routine laboratory tests.6 Variants can be confirmed by high performance liquid chromatography or by mass spectrometry and identified by PCR-direct sequencing. 6 The hematological indices of the patients are listed in Table 1. In all cases the hematocrit and the hemoglobin level was raised, except for UPN224 which was found to be iron deficient. White blood cell and platelet counts were in the normal range. The serum Epo level was either elevated or inappropriately normal for the elevated Hb. Thrombotic events have been reported for only Patients 214 and 225.
The hemoglobin tetramer is composed of 2 chains of α and 2 chains of β globin arranged in two identical halves, containing one chain of each globin type. As Hb transfers from the low oxygen affinity state (known as T or tense) to the high affinity state (R or relaxed) there is an accompanying movement within the α1β2 subunit.1 Many of the amino acid changes associated with a high affinity phenotype map to the α1β2 interface or the C-terminal of the β chain.1 These mutations prevent the transition of the Hb molecule to the T state and hence are unable to release the bound oxygen molecules. The Santa Clara variant cannot achieve the T state9 while Pierre-Benite is thought to stabilize Hb in the T quaternary structure8,11 and Hb Olympia12 affects the surface of the protein causing it to self-associate. Other mutations cause structural alteration of the hemepocket. The presence of several aromatic amino acids around the hememoiety is crucial for the correct orientation of the hemegroup. Replacement of Phe103 with Leu (Hb Heathrow) causes the affinity of the hemegroup for oxygen to be increased.1
Table 1.Hematologic indices of erythrocytosis patients with hemoglobin variants.
During the differential diagnosis of erythrocytosis the first step would be the calculation of P50 using the routine blood gas analyzer. In those patients with a low value for P50 sequencing of the globin gene to establish the actual variant would be performed. In the absence of P50 values, as with patients in this study, it is important to eliminate the possibility of Hb variants by sequencing t he globin genes, which confirmed 6 positive cases on the registry.
References
- Percy MJ, Lee FS. Familial erythrocytosis: molecular links to red blood cell control. Haematologica. 2008; 93:963-7. Google Scholar
- Wajcman H, Galacteros F. Hemoglobins with high oxygen affinity leading to erythrocytosis. New variants and new concept. Hemoglobin. 2005; 29:91-106. Google Scholar
- Rumi E, Passamonti F, Pagano L, Ammirabile M, Arcaini L, Elena C. Blood p50 evaluation enhances diagnostic definition of isolated erythrocytosis. J Intern Med. 2009; 265:266-74. Google Scholar
- Agarwal N, Mojica-Henshaw MP, Simmons ED, Hussey D, Ou CN, Prchal JT. Familial polycythemia caused by a novel mutation in the beta globin gene: essential role of P50 in evaluation of familial polycythemia. Int J Med Sci. 2007; 4:232-6. Google Scholar
- Percy MJ, McMullin MF, Jowitt SN, Potter M, Treacy M, Watson WH, Lappin TR. Chuvash-type congenital poly-cythemia in 4 families of Asian and Western European ancestry. Blood. 2003; 102:1097-9. Google Scholar
- Stamatoyannopoulos G, Nute PE, Adamson JW, Bellingham AJ, Funk D. Hemoglobin olympia (20 valine leads to methionine): an electrophoretically silent variant associated with high oxygen affinity and erythrocytosis. J Clin Invest. 1973; 53:342-9. Google Scholar
- Baklouti F, Giraud Y, Francina A, Richard G, Favre-Gilly J, Delaunay J. Hemoglobin Pierre-Benite [β 90(F6)Glu→Asp], a new high affinity variant found in a French family. Hemoglobin. 1988; 12:171-7. Google Scholar
- Hoyer JD, Weinhold J, Mailhot E, Alter D, McCormick DJ, Snow K. Three new hemoglobin variants with abnormal oxygen affinity: Hb Saratoga Springs [α40(C5)Lys→Asn (α1)], Hb Santa Clara [β97(FG4)His→Asn], and Hb Sparta [β103(G5)Phe→Val]. Hemoglobin. 2003; 27:235-41. Google Scholar
- White J, MSzur L, Gillies ID, Lorkin PA, Lehmann H. Familial polycythaemia caused by a new haemoglobin variant: Hb Heathrow, beta 103 (G5) phenylalanine leads to leucine. Br Med J. 1973; 882:665-7. Google Scholar
- Beard ME, Potter HC, Spearing RL, Brennan SO. Haemoglobin Pierre-Benite - a high affinity variant associated with relative polycythaemia. Clin Lab Haematol. 2001; 23:407-9. Google Scholar
- Edelstein SJ, Poyart C, Blouquit Y, Kister J. Self-association of haemoglobin Olympia (α2β2 20 (B2) Val→Met). A human haemoglobin bearing a substitution at the surface of the molecule. J Mol Biol. 1986; 187:277-89. Google Scholar