Biogenesis of erythrocyte membrane skeleton in health and disease

Abstract

To study the biogenesis of red ceil membrane skeleton at various stages of erythroid differentiation, we have chosen the following model systems: a) Rauscher erythroleukemia cell line representing the early stages of differentiation, b) Friend erythroleukemia cells, and c) in vitro cultured human erythroblasts. The latter two systems represent terminally differentiated erythroblasts. Using these model systems, we have shown asynchronous synthesis of membrane proteins during erythroid differentiation. At the early stages of erythroid development, the synthesis of spectrin, ankyrin and band 4.1 proteins is initiated before that of the band 3 protein. Following erythroid induction with erythropoietin and dimethylsulfoxide (DMSO), there is a dramatic increase in the synthesis of the band 3 protein without noticeable changes in the synthesis of other membrane proteins. This increase in band 3 synthesis is accompanied by increased stability and recruitment of the skeletal proteins into the membrane skeleton, leading to increased steady state levels. The progressive increase in band 3 synthesis continues during terminal maturation of erythroblasts. This is accompanied by increased stability and assembly of spectrin and ankyrin on the membrane, despite their reduced synthesis. These results point to a key role for the band 3 protein in anchoring and stabilizing these proteins into the permanent skeletal network. Finally, to detect defects of skeletal biosynthesis, we have extended these studies to a patient with severe hereditary spherocytosis characterized by a combined deficiency of spectrin and ankyrin. We have shown that this combined deficiency is a consequence of reduced ankyrin synthesis and mRNA content representing a thalassemia-like membrane protein mutation.