Idowu Akinsheye

Fetal hemoglobin in sickle cell anemia

Fetal hemoglobin (HbF) is the major genetic modulator of the hematologic and clinical features of sickle cell disease, an effect mediated by its exclusion from the sickle hemoglobin polymer. Fetal hemoglobin genes are genetically regulated, and the level of HbF and its distribution among sickle erythrocytes is highly variable. Some patients with sickle cell disease have exceptionally high levels of HbF that are associated with the Senegal and Saudi-Indian haplotype of the HBB-like gene cluster; some patients with different haplotypes can have similarly high HbF. In these patients, high HbF is associated with generally milder but not asymptomatic disease. Studying these persons might provide additional insights into HbF gene regulation. HbF appears to benefit some complications of disease more than others. This might be related to the premature destruction of erythrocytes that do not contain HbF, even though the total HbF concentration is high. Recent insights into HbF regulation have spurred new efforts to induce high HbF levels in sickle cell disease beyond those achievable with the current limited repertory of HbF inducers.

Sickle cell anemia and vascular dysfunction: The nitric oxide connection

Endothelial dysfunction and impaired nitric oxide bioavailability have been implicated in the pathogenesis of sickle cell anemia. Nitric oxide is a diatomic gas with a role in vascular homeostasis. Hemoglobin polymerization resulting from the HbS mutation produces erythrocyte deformation and hemolysis. Free hemoglobin, released into plasma by hemolysis scavenges on nitric oxide, and leads to reduced nitric oxide bioavailability. Pulmonary hypertension is a known consequence of sickle cell anemia. It occurs in 30–40% of patients with sickle cell anemia, and is associated with increased mortality. Several studies have implicated intravascular hemolysis, and impaired nitric oxide bioavailability in the pathogenesis of pulmonary hypertension. In this review, we summarize the mechanisms of altered nitric oxide bioavailability in sickle cell anemia and its possible role in the pathogenesis of pulmonary hypertension. J. Cell. Physiol. 224: 620–625, 2010.

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‐β0 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 5 years, at approximately 30%. Mean HbF of individuals age 5 or older was 31 ± 3%, average haemoglobin concentration was 130 ± 10 g/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‐β0 thalassaemia.

Fetal hemoglobin in sickle cell anemia: genetic studies of the Arab-Indian haplotype.

Sickle cell anemia is common in the Middle East and India where the HbS gene is sometimes associated with the Arab-Indian (AI) β-globin gene (HBB) cluster haplotype. In this haplotype of sickle cell anemia, fetal hemoglobin (HbF) levels are 3-4 fold higher than those found in patients with HbS haplotypes of African origin. Little is known about the genetic elements that modulate HbF in AI haplotype patients. We therefore studied Saudi HbS homozygotes with the AI haplotype (mean HbF 19.2±7.0%, range 3.6 to 39.6%) and employed targeted genotyping of polymorphic sites to explore cis- and trans- acting elements associated with high HbF expression. We also described sequences which appear to be unique to the AI haplotype for which future functional studies are needed to further define their role in HbF modulation. All cases, regardless of HbF concentration, were homozygous for AI haplotype-specific elements cis to HBB. SNPs in BCL11A and HBS1L-MYB that were associated with HbF in other populations explained only 8.8% of the variation in HbF. KLF1 polymorphisms associated previously with high HbF were not present in the 44 patients tested. More than 90% of the HbF variance in sickle cell patients with the AI haplotype remains unexplained by the genetic loci that we studied. The dispersion of HbF levels among AI haplotype patients suggests that other genetic elements modulate the effects of the known cis- and trans-acting regulators. These regulatory elements, which remain to be discovered, might be specific in the Saudi and some other populations where HbF levels are especially high.

Fetal hemoglobin in sickle cell anemia: Molecular characterization of the unusually high fetal hemoglobin phenotype in African Americans

Fetal hemoglobin (HbF) is a major modifier of disease severity in sickle cell anemia (SCA). Three major HbF quantitative trait loci (QTL) are known: the Xmn I site upstream of (G)γ- globin gene (HBG2) on chromosome 11p15, BCL11A on chromosome 2p16, and HBS1L-MYB intergenic polymorphism (HMIP) on chromosome 6q23. However, the roles of these QTLs in patients with SCA with uncharacteristically high HbF are not known. We studied 20 African American patients with SCA with markedly elevated HbF (mean 17.2%). They had significantly higher minor allele frequencies (MAF) in two HbF QTLs, BCL11A, and HMIP, compared with those with low HbF. A 3-bp (TAC) deletion in complete linkage disequilibrium (LD) with the minor allele of rs9399137 in HMIP was also present significantly more often in these patients. To further explore other genetic loci that might be responsible for this high HbF, we sequenced a 14.1 kb DNA fragment between the (A)γ-(HBG1) and δ-globin genes (HBD). Thirty-eight SNPs were found. Four SNPs had significantly higher major allele frequencies in the unusually high HbF group. In silico analyses of these four polymorphisms predicted alteration in transcription factor binding sites in 3.

A functional promoter polymorphism of the δ‐globin gene is a specific marker of the Arab‐Indian haplotype

Most sickle cell anemia (SCA) patients indigenous to the Eastern Province of Saudi Arabia have their HbS gene on the Arab-Indian (AI) HBB gene cluster haplotype. Their fetal hemoglobin (HbF) levels are near 20% and they have milder disease compared with SCA where the HbS gene is on African origin HBB haplotypes [1–9]. The AI haplotype is characterized by an Xmn1 restriction site at position 2158 50 to HBG2 (rs7482144), a Hinc2 site 50 to HBE (rs3834466) and other polymorphisms [10]. The causal elements that modify HbF might be in linkage disequilibrium with the b globin gene in this Saudi population. We first performed homozygosity mapping using genome-wide single nucleotide polymorphisms (SNPs) in AI HbS homozygotes [11,12] and identified a single large autozygous region including the HBB cluster and surrounding genes. By next generation sequencing, we examined this region in these same individuals and identified several variants that included a SNP in the HBD promoter region at position 268 bp 50 to HBD (CCAAC > TCAAC). We found this SNP only when the HbS gene was on an AI haplotype and not in SCA with other haplotypes. This SNP was functional in reporter assays in K562 cells and is an AI haplotype-specific marker. Table I summarizes the patient characteristics. Using genome-wide SNP data from a limited number of cases, a region of autozygosity was found only in AI HbS homozygotes on chromosome 11 (coordinates 5,196,450– 5,323,071). The region contains HBD, HBG1, HBG2, HBE1, and the Xmn1 50 HBG2 restriction site (rs7482144). By targeted deep sequencing of 400 kb of chromosome 11 (coordinates 5,143,424–5,543,424; average coverage 42x) in 4 AI patients 1,195 variants were found. A homozygous C-T variant 268 bp 50 HBD with high genotyping and mapping quality that was not in dbSNP build 135 or 1,000 Genomes, was present. Resequencing of 15.9 kb of chr11 (coordinates 5,253,531–5,269,435) by Sanger sequencing detected three new SNPs of which one was the 268 C > T SNP. We focused on this SNP because of its location within the Corfu deletion region and its location in the HBD promoter. The C > T SNP in the HBD promoter was found only in individuals with the AI haplotype. Saudi sickle cell trait carriers with the AI haplotype were heterozygous for this SNP; while siblings without HbS did not carry this mutation. Among 25 AI HbS-b thalassemia patients, 16 were heterozygous at this site (C/T) and 9 were homozygous (T/T). All AI HbS-b thalassemia patients who were homozygous T/T were also homozygous for the AI haplotype (Table I). Fifteen African American SCA patients with unusually high HbF, 54 Saudi SCA patients from the Southwestern Province (SW)—mainly Benin but including subjects with the Senegal haplotype—19 SW HbS-b thalassemia patients, 16 SW sickle cell trait cases, and 25 normal Saudi controls did not carry the 268 HBD SNP. This SNP was not found in 1,094 individuals in 1,000 Genomes May 2011 release. It is important to note that hemoglobin electrophoresis results in Table I were performed using different methods, so direct comparison of HbF and HbA2 between different groups will not be accurate. In addition, the effect of coinheritance of a-thalassemia, or presence of iron deficiency anemia on Hb A2 level was not assessed. Finally, HbA2 levels are artifactually high when HbS is present because of the co-elution of minor HbS species. For these reasons, it is not possible to estimate the effects of the 268 C-T SNP on these subjects HbA2 levels. Reduced expression of HBD relative to HBB in normal individuals is partly a result of a degenerate CCAAT box in the HBD promoter (CCAAC). The CCAAC motif is the site of the 268 C > T SNP (TCAAC) [13–15]. When we compared the activity of the wild-type HBD promoter with the promoter containing the 268 C > T SNP the variant promoter was associated with a significant decrease in the expression of a reporter construct suggesting that it could further impair already enfeebled HBD expression (Fig. 1). Although HBG is expressed at high levels in K562 cells, endogenous HBD is also expressed [16]. The expression studies were designed solely to test the hypothesis that the 268 C > T SNP downregulates the expression of the HBD promoter. The literature provides further evidence for a functional role of the 268 C > T SNP. Its presence was associated with d thalassemia in one individual with reduced HbA2 of 2% and a slightly increased HbF of 1.3% [13]. Moreover, mutations at positions 230, 231, 236, 255, 265, 276, and 277 in the HBD promoter were reported in HbVar database (http://globin.cse.psu.edu/) to cause d thalassemia [14,17–19], and HbF levels of 3.3–4.7% have been noted in some hematologically normal individuals with homozygous d thalassemia [19,20]. A mechanism for increased HbF in the presence of less common HBD promoter mutations is unknown. Any role for the 268 C-T SNP as a modifier of HbF in AI haplotype HbS sickle cell disease is unknown. Perhaps HBD promoter SNPs reduce the interaction of the locus control region and the transcription apparatus with this promoter permitting enhanced interactions with HBG promoters [21]. The paradox of the Corfu deletion first suggested the potential of the HBD-HBG1 intergenic area, the site of the 268 C-T SNP, as a silencer of HBG expression [22]. One potential functional area is the polypyrimidine (PYR) binding site about 960 bp upstream of HBD; however, polymorphisms