Abstract
Sickle cell disease (SCD) in patients of HbSC genotype is considered similar, albeit milder, to that in homozygous HbSS individuals — but with little justification. In SCD, elevated red cell cation permeability is critical as increased solute loss causes dehydration and encourages sickling. Recently, we showed that the KCl cotransporter (KCC) activity in red cells from HbSC patients correlated significantly with disease severity, but that in HbSS patients did not. Two transporters involved in red cell dehydration, the conductive channels Psickle and the Gardos channel, behaved similarly in red cells from the two genotypes, but were significantly less active in HbSC patients. By contrast, KCC activity was quantitatively greater in HbSC red cells. Results suggest that KCC is likely to have greater involvement in red cell dehydration in HbSC patients, which could explain its association with disease severity in this genotype. This work supports the hypothesis that SCD in HbSC patients is a distinct disease entity to that in HbSS patients. Results suggest the possibility of designing specific treatments of particular benefit to HbSC patients and a rationale for the development of prognostic markers, to inform early treatment of children likely to develop more severe complications of the disease.
Highlights
Sickle cell disease (SCD) is one of the commonest severe inherited disorders affecting millions of people worldwide (Piel et al, 2013)
Sickling and conductive K+ transport were measured in air and across the physiological range of O2 tensions in red cells from HbSC patients
The present findings show significant differences in cation homeostasis comparing red cells from HbSC and HbSS patients
Summary
Sickle cell disease (SCD) is one of the commonest severe inherited disorders affecting millions of people worldwide (Piel et al, 2013). In HbS, valine replaces glutamic acid in the 6th codon of the β chain, with loss of a negative charge (Bunn and Forget, 1986). On deoxygenation, this substitution allows neighbouring molecules of HbS to adhere, forming rigid polymers which distort the shape of the red cell. Co-inheritance of a second abnormal Hb, HbC, in which lysine replaces glutamic acid at the same position of the β chain, along with HbS produces the heterologous HbSC genotype (HbSC disease) (Nagel and Lawrence, 1991; Nagel and Steinberg, 2001). The vast majority of laboratory and clinical studies on SCD, including those on red cell cation homeostasis, have been carried out on HbSS patients, with HbSC patients being largely and unjustifiably neglected
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
