Sequence Divergence in the 3′ Untranslated Regions of Human ζ- and α-Globin mRNAs Mediates a Difference in Their Stabilities and Contributes to Efficient α-to-ζ Gene Developmental Switching

Abstract

The developmental stage-specific expression of human globin proteins is characterized by a switch from the coexpression of ζ- and α-globin in the embryonic yolk sac to exclusive expression of α-globin during fetal and adult life. Recent studies with transgenic mice demonstrate that in addition to transcriptional control elements, full developmental silencing of the human ζ-globin gene requires elements encoded within the transcribed region. In the current work, we establish that these latter elements operate posttranscriptionally by reducing the relative stability of ζ-globin mRNA. Using a transgenic mouse model system, we demonstrate that human ζ-globin mRNA is unstable in adult erythroid cells relative to the highly stable human α-globin mRNA. A critical determinant of the difference between α- and ζ-globin mRNA stability is mapped by in vivo expression studies to their respective 3′ untranslated regions (3′UTRs). In vitro messenger ribonucleoprotein (mRNP) assembly assays demonstrate that the α- and ζ-globin 3′UTRs assemble a previously described mRNP stability-determining complex, the α-complex, with distinctly different affinities. The diminished efficiency of α-complex assembly on the ζ 3′UTR results from a single C→G nucleotide substitution in a crucial polypyrimidine tract contained by both the human α- and ζ-globin mRNA 3′UTRs. A potential pathway for accelerated ζ-globin mRNA decay is suggested by the observation that its 3′UTR encodes a shortened poly(A) tail. Based upon these data, we propose a model for ζ-globin gene silencing in fetal and adult erythroid cells in which posttranscriptional controls play a central role by providing for accelerated clearance of ζ-globin transcripts.