Regulators of hemoglobin switching in zebrafish and human models

Hemoglobin switching is a developmental process involving the dynamic transcriptional regulation of multiple globin genes. This molecular process involves multiple layer of complexity, and elucidating new mechanisms in this process will result in a more complete understanding of general gene regulation and will likely have direct clinical implications for hemoglobinopathies, such as sickle cell anemia. In this dissertation, I develop and characterize a new model for hemoglobin switching, the zebrafish. I defined and fully annotated the two zebrafish globin loci, termed major and minor loci. Both loci contain α– and β–genes oriented in a head–to–head fashion. Characterization of the globin expression pattern precisely defined the timing of normal switching and demonstrated that zebrafish, like humans, have two globin switches. The locus control region for the major locus was identified and in conjunction with a proximal promoter was able to generate robust, erythroid–specific expression in a transgenic line

Zebrafish Globin Switching Occurs in Two Developmental Stages and Is Controlled by the LCR

Globin gene switching is a complex, highly regulated process allowing expression of distinct globin genes at specific developmental stages. Here, for the first time, we have characterized all of the zebrafish globins based on the completed genomic sequence. Two distinct chromosomal loci, termed major (chromosome 3) and minor (chromosome 12), harbor the globin genes containing α/β pairs in a 5′–3′ to 3′–5′ orientation. Both these loci share synteny with the mammalian α-globin locus. Zebrafish globin expression was assayed during development and demonstrated two globin switches, similar to human development. A conserved regulatory element, the locus control region (LCR), was revealed by analyzing DNase I hypersensitive sites, H3K4 trimethylation marks and GATA1 binding sites. Surprisingly, the position of these sites with relation to the globin genes is evolutionarily conserved, despite a lack of overall sequence conservation. Motifs within the zebrafish LCR include CACCC, GATA, and NFE2 sites, suggesting functional interactions with known transcription factors but not the same LCR architecture. Functional homology to the mammalian α-LCR MCS-R2 region was confirmed by robust and specific reporter expression in erythrocytes of transgenic zebrafish. Our studies provide a comprehensive characterization of the zebrafish globin loci and clarify the regulation of globin switching.Stem Cell and Regenerative Biolog