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.

ACKNOWLEDGMENTS

We thank Alice Lee and Faith Fox for expert technical assistance and Nancy Cooke and William Lee for critical reading of the manuscript.

This work was supported in part by NIH grants HL-K11-02623 (J.E.R.), HL-38632 (S.A.L.), and CA-72765 (S.A.L.). S.A.L. is an Investigator of the Howard Hughes Medical Institute.