Genome architecture of the human beta-globin locus affects developmental regulation of gene expression.

To test the role of gene order in globin gene expression, mutant human beta-globin locus yeast artificial chromosome constructs were used, each having one additional globin gene encoding a "marked" transcript (epsilon(m), gamma(m), or beta(m)) integrated at different locations within the locus. When a beta(m)-globin gene was placed between the locus control region (LCR) and the epsilon-globin gene, beta(m)-globin expression dominated primitive and definitive erythropoiesis; only beta(m)-globin mRNA was detected during the fetal and adult definitive stages of erythropoiesis. When an (A)gamma(m)-globin gene was placed at the same location, (A)gamma(m)-globin was expressed during embryonic erythropoiesis and the fetal liver stage of definitive erythropoiesis but was silenced during the adult stage.

Rapid isolation of yeast genomic DNA: Bust n' Grab.

Background: Mutagenesis of yeast artificial chromosomes (YACs) often requires analysis of large numbers of yeast clones to obtain correctly targeted mutants. Conventional ways to isolate yeast genomic DNA utilize either glass beads or enzymatic digestion to disrupt yeast cell wall. Using small glass beads is messy, whereas enzymatic digestion of the cells is expensive when many samples need to be analyzed.

Chromatin structure and control of beta-like globin gene switching.

The human beta-globin locus is a complex genetic system widely used for analysis of eukaryotic gene expression. The locus consists of five functional beta-like globin genes, epsilon, (G)gamma, (A)gamma, delta, and beta, arrayed on the chromosome in the order that they are expressed during ontogeny. Globin gene expression is regulated, in part, by the locus control region, which physically consists of five DNaseI-hypersensitive sites located 6-22 Kb upstream of the epsilon -globin gene.