Fetal haemoglobin levels and haematological characteristics of compound heterozygotes for haemoglobin S and deletional hereditary persistence of fetal haemoglobin.

Compound heterozygotes for sickle haemoglobin (HbS) and hereditary persistence of fetal haemoglobin (HPFH) have high fetal haemoglobin (HbF) levels but few, if any, sickle cell disease-related complications. We studied 30 cases of HbS-HPFH (types 1 and 2), confirmed by molecular analysis, and report the haematological features and change in HbF levels over time. These results were compared to those of patients with sickle cell anaemia or HbS-ß(0) thalassaemia, including a subgroup of patients carrying the XmnI polymorphism, known to be associated with elevated HbF. Among the HbS-HPFH patients, HbF level was 50-90% during infancy and declined steeply within the first few years of life, stabilizing between ages 3 and 5years, at approximately 30%. Mean HbF of individuals age 5 or older was 31±3%, average haemoglobin concentration was 130±10g/l and average mean corpuscular volume (MCV) was 75±4 fl. Univariate and multivariate regression analyses significantly associated HbF with age, haemoglobin concentration, and MCV (P<0·001). There was a strong inverse association between HbF and age (r=-0·9, P<0·001). Despite having a much higher HbF level, patients with HbS-HPFH have a similar age-related pattern of HbF decline and associations as patients with sickle cell anaemia or HbS-ß(0) thalassaemia.

Genomic approaches to identifying targets for treating ß hemoglobinopathies.

Sickle cell disease and ß thalassemia are common severe diseases with little effective pathophysiologically-based treatment. Their phenotypic heterogeneity prompted genomic approaches to identify modifiers that ultimately might be exploited therapeutically. Fetal hemoglobin (HbF) is the major modulator of the phenotype of the ß hemoglobinopathies. HbF inhibits deoxyHbS polymerization and in ß thalassemia compensates for the reduction of HbA. The major success of genomics has been a better understanding the genetic regulation of HbF by identifying the major quantitative trait loci for this trait. If the targets identified can lead to means of increasing HbF to therapeutic levels in sufficient numbers of sickle or ß-thalassemia erythrocytes, the pathophysiology of these diseases would be reversed. The availability of new target loci, high-throughput drug screening, and recent advances in genome editing provide the opportunity for new approaches to therapeutically increasing HbF production.