Multiple sequence-specific DNA binding activities are eluted from chicken nuclei at low ionic strengths.

DNA sequence-specific binding proteins eluted from chicken erythrocyte and thymus nuclei, and fractionated as described by Emerson and Felsenfeld (19), have been investigated by filter binding and footprint analyses. The erythrocyte nuclear protein fraction specifically binds to at least two sites within the 5' flanking chromatin hypersensitive site of the chicken beta A-globin gene, and to a site 5' to the human beta-globin gene. The major chicken beta A globin gene binding site [G)18CGGGTGG) and the human beta-globin gene binding site [TA)6(T)8C(T)4) occur at or near sequences which are hypersensitive to S1 nuclease cleavage in supercoiled plasmids. Downstream, the second chicken beta A-globin gene binding site includes the beta-globin gene CACCC consensus sequence. Filter binding studies also show other sequence specific binding activities to human N-ras and human (but not chicken) c-myc gene sequences.     

Conserved sequences and cell-specific DNase I hypersensitive sites upstream from the co-ordinately expressed alpha I- and alpha II-globin genes of Xenopus laevis

The globin gene family of Xenopus laevis comprises pairs of closely related genes that are arranged in two clusters, each pair of genes being co-ordinately and stage-specifically expressed. To get information on putative regulatory elements, we compared the DNA sequences and the chromatin conformation 5' to the co-ordinately expressed adult alpha-globin genes. Sequence analysis revealed a relatively conserved region from the cap site up to position -289, and further upstream seven distinct boxes of homology, separated by more diverged sequences or deletions/insertions. The homology boxes comprise 22 to 194 base-pairs showing 78 to 95% homology. Analysis of chromatin conformation showed that DNase I preferentially cuts the upstream region of both genes at similar positions, 5' to the T-A-T-A and the C-C-A-A-T boxes, only in chromatin of adult erythroblasts and erythrocytes, where adult globin genes are expressed, but not in chromatin of adult liver cells or larval erythrocytes, where these genes are silent. This suggests that cell- and stage-specific activation of these genes coincides with specific changes in chromatin conformation within the proximal upstream region. No difference was found in the nucleotide sequence within the DNase I hypersensitive region proximal to the adult alpha 1-globin gene in DNA from embryonic cells, in which this gene is inactive, and adult erythrocytes, expressing this gene.     

Isolation of the chicken beta-globin gene and a linked embryonic beta-like globin gene from a chicken DNA recombinant library.

A library of random chicken DNA fragments, 15-22 kb long, has been prepared in the vector lambda Charon 4A. This library was screened with combined adult and embryonic globin cDNA, and several independent globin gene-containing recombinants were isolated. One of these recombinants, lambda Chicken beta-globin 1 (lambda C beta G1), contains the adult chicken beta-globin gene and a closely linked embryonic beta-like globin gene. Both genes are transcribed in the same direction with the adult gene located 5' to the embryonic gene. Electron microscopic visualization of R loop structures generated by hybridization of globin RNA to lambda C beta G1 demonstrates that both globin genes contain major intervening sequences about 800 bp long, similar to those present in mammalian beta-globin genes. The adult beta-globin gene also contains a minor (approximately 100 bp long) intervening sequence analogous to the one observed in mammalian beta-globin genes. Restriction enzyme analysis of the adult beta-globin gene on lambda C beta G1 is consistent with the hypothesis that its two intervening sequences occur in the same positions with respect to the beta-globin amino acid sequence as do the corresponding mammalian intervening sequences.     

Expression of adult and tadpole specific globin genes from Xenopus laevis in transgenic mice.

Transgenic mice were generated which carried the adult alpha and beta-globin genes and the major tadpole specific beta-globin gene of Xenopus laevis. The adult specific alpha and beta genes were found to express in erythroid tissues in adult mice, while the major tadpole specific beta gene (beta T1) was expressed in blood from 12.5 day embryos. The pattern of expression of the beta T1 gene during mouse development was consistent with its being regulated as an embryonic globin gene in the mouse. This observation suggests that some of the factors mediating globin switching have been conserved during the evolution of modern amphibia and mammals and raises interesting questions concerning the evolution of vertebrate globin gene switching.     

(AT)n is an interspersed repeat in the Xenopus genome.

We have observed (AT)34 and (AT)23 tracts close to the coding sequences of the Xenopus laevis tadpole alpha T1 and adult beta 1 globin genes, respectively. We show that (AT)n sequences are found as interspersed repeats within the Xenopus globin and histone gene loci. Using (AT)n co-polymer in filter hybridisation experiments we estimate that there are 10(4) (AT)n tracts per haploid Xenopus genome. Hybridisation to genomic blots of DNA from yeast, slime mold, trypanosome, fruit fly, salmon, chicken, rat, human, crab and Xenopus species shows that strictly alternating AT of sufficient length to hybridise appears to be most abundant in Xenopus and crab genomes. We show that the specificity of the co-polymer probe for strictly alternating AT is, however, dependent on the length of the probe. Hybridisation experiments using (TG)n copolymer suggest that this highly conserved repeat is found as clustered repeats in the Xenopus genome in contrast to other eukaryotic genomes so far studied.     

Conservation and variation in the large scale organisation of the globin gene domains of duck and chicken

Summary The genomic DNA of cloned recombinants containing the duck globin genes was compared to that of the analogous domains of the chicken. A 36 kb insert including the three alpha-type globin genes was isolated from a newly prepared duck genomic library in the cosmid PJB8; another recombinant contained a 45 kb insert with the four beta globin genes. In the alpha globin gene domain, the relative positions of genes, of repetitive sequences, and of the A+T-rich segments (AT-rich linkers, ATRLs) which frame the gene cluster (Moreau et al. 1982), were found to be closely maintained between duck and chicken. Although ATRLs and repetitive sequences also frame the gene cluster in the beta globin domains of duck and chicken, there is more genetic drift in their relative positions than in the alpha domain. It is of interest that several repetitive DNA segments were detected in the chicken beta globin domain which do not exist in corresponding positions in the duck. In view of the strict conservation in both species of genes and their relative positions in the cluster, this observation seems to exclude a simple function of repetitive sequences in the control of individual genes. The data are discussed with regard to the possible significance of repetitive and AT-rich DNA segments in genome organisation and function.     

Perturbation of chromatin structure in the region of the adult beta-globin gene in chicken erythrocyte chromatin

An EcoRI chromatin fragment containing the adult beta-globin gene and flanking sequences, isolated from chicken erythrocyte nuclei, sediments at a reduced rate relative to bulk chromatin fragments of the same size. We show that the specific retardation cannot be reversed by adding extra linker histones to native chromatin. When the chromatin fragments are unfolded either by removing linker histones or lowering the ionic strength, the difference between globin and bulk chromatin fragments is no longer seen. The refolded chromatin obtained by restoring the linker histones to the depleted chromatin, however, exhibits the original sedimentation difference. This difference is therefore due to a special property of the histone octamers on the active gene that determines the extent of its folding into higher-order structure. That it is not due to the differential binding of linker histones in vitro is shown by measurements of the protein to DNA ratios using CsCl density-gradients. Both before and after selective removal of the linker histones, the globin gene fragment and bulk chromatin fragments exhibit only a marginal difference in buoyant density. In addition, we show that cleavage of the EcoRI fragment by digestion at the 5' and 3' nuclease hypersensitive sites flanking the globin gene liberates a fragment from between these sites that sediments normally. We conclude that the hypersensitive sites per se are responsible for the reduction in sedimentation rate. The non-nucleosomal DNA segments appear to be too long to be incorporated into the chromatin solenoid and thus create spacers between separate solenoidal elements in the chromatin, which can account for its hydrodynamic behaviour.     

The inactivation of the π gene in chicken erythroblasts of adult lineage is not mediated by packaging of the embryonic part of the α-globin gene domain into a repressive heterochromatin-like structure

The developmental switch of globin gene expression is a characteristic feature of vertebrate organisms. The switch of β-globin expression is believed to depend on reconfiguration of the active chromatin hub, which contains transcribed genes and regulatory elements. Mechanisms controlling the switch of α-globin gene expression are less clear. Here, we studied the mode of chromatin packaging of the chicken α-globin gene domain in red blood cells (RBCs) of primitive and definite lineages and the spatial configuration of this domain in RBCs of primitive lineage. It has been demonstrated that RBCs of primitive lineage already contain the adult-type active chromatin hub but the embryonal α-type globin π gene is not recruited to this hub. Distribution of active and repressive histone modifications over the α-globin gene domain in RBCs of definite and primitive lineages does not corroborate the hypothesis that inactivation of the π gene in RBCs of adult lineage is mediated via formation of a local repressed chromatin domain. This conclusion is supported by the demonstration that in chicken erythroblasts of adult lineage, the embryonal and adult segments of the α-globin gene domain show similar elevated sensitivities to DNase I.     

The duck beta-globin gene cluster contains a single enhancer element

An erythroid-specific enhancer was previously identified in the 3'-flanking region of the beta adult gene in chicken and duck, by transfection into AEV transformed chicken erythroblasts. Here we show that the duck enhancer is equally active in erythroid human K562 cells, presenting an embryonic/fetal program of globin gene expression. Furthermore, no other enhancer was found within the 20 kb of DNA including four beta-like globin genes as well as a 1.5 kb upstream and a 3 kb downstream sequence.     

The inactivation of the π gene in chicken erythroblasts of adult lineage is not mediated by packaging of the embryonic part of the α-globin gene domain into a repressive heterochromatin-like structure

The developmental switch of globin gene expression is a characteristic feature of vertebrate organisms. The switch of β-globin expression is believed to depend on reconfiguration of the active chromatin hub, which contains transcribed genes and regulatory elements. Mechanisms controlling the switch of α-globin gene expression are less clear. Here, we studied the mode of chromatin packaging of the chicken α-globin gene domain in red blood cells (RBCs) of primitive and definite lineages and the spatial configuration of this domain in RBCs of primitive lineage. It has been demonstrated that RBCs of primitive lineage already contain the adult-type active chromatin hub but the embryonal α-type globin π gene is not recruited to this hub. Distribution of active and repressive histone modifications over the α-globin gene domain in RBCs of definite and primitive lineages does not corroborate the hypothesis that inactivation of the π gene in RBCs of adult lineage is mediated via formation of a local repressed chromatin domain. This conclusion is supported by the demonstration that in chicken erythroblasts of adult lineage, the embryonal and adult segments of the α-globin gene domain show similar elevated sensitivities to DNase I.