Genetic and Haematological Modifiers of SCD Severity in Kaduna State, Northern Nigeria (SCA)

Sickle cell anaemia (SCA) is a multisystem disorder with massive medical, social and financial implications worldwide. It is caused by a single mutation in the β-globin gene (β6 Glu>Val), which leads to the production of abnormal sickle haemoglobin (HbS). Africa is the major origin of the sickle (βS) mutation, which occurs on diverse genetic haplotype backgrounds. SCA has a Mendelian pattern of inheritance (βS gene homozygosity, i.e. HbSS). Although all SCA patients share the same genetic mutation, the disease exhibits wide heterogeneity in clinical expression, which can be explained by both environmental and genetic factors. The environmental factors include infections, trauma, climate (temperature and humidity) and air quality, as well as socioeconomic factors, many of which are controllable. The genetic factors, on the other hand, cannot be controlled. The best-characterized genetic factors include variants in the genes associated with foetal haemoglobin (HbF) production, co-inheritance of alpha-thalassaemia, sickle genotype, and the type of βS-globin haplotype. The role of other potential genetic modifiers is less clear, particularly with regards to sickle cell disease related organ damage (e.g., risk for stroke, haemolysis, and acute chest syndrome.

Understanding the molecular basis of clinical heterogeneity and disease severity for SCA can have direct clinical applications for prognosis via risk stratification of patients, also facilitating the use of personalized, targeted therapeutic interventions. As a turning-point in genomics, the advent of high-throughput sequencing and whole-genome analysis has made it feasible to discover hitherto unsuspected variants that could add to current understanding of genotype-phenotype relationships in SCA. The identification of modifying genetic variants might suggest new prognostic and/or therapeutic targets for investigation towards improved patient management and treatment.