Characterization of the chromatin structure in the upstream region of the chicken alpha-globin gene domain

The distribution of DNase I hypersensitive sites upstream of the chicken -globin gene cluster was studied. A group of hypersensitive sites with a complex pattern of tissue specificity, including erythroid-specific elements, was found at a distance of 11.5–14.5 kb upstream of the gene, the first gene in the cluster. The observations indicate that this area, located upstream of the block of AT-rich sequences and MAR sites (at –8 kb) and upstream of the site of permanent DNA attachment to the nuclear matrix (–3 kb), still belongs to the domain of the -globin genes.     

Spatial organization of the chicken alpha-globin gene domain in cells of different

We have developed a technique for mapping the sites of DNA attachment to the nuclear matrix by hybridization of nuclear matrix DNA with an oligonucleotide array. The latter was made by immobilization of 60-mer oligonucleotides distributed within the area under study with a 2 Kb step on nylon filter. Using this approach we have analyzed the mode of interaction of a 100 Kb fragment of chicken chromosome 16 including the alpha-globin gene domain with the nuclear matrix. The 40 Kb DNA loop including all alpha-globin genes was detected in erythroid cells. One of the borders of this loop colocalized with the previously mapped MAR element and CTCF-dependent enhancer-blocking element. Also, a long transcribed area was found to be preferentially associated with the nuclear matrix. The spatial organization of the area under study in lymphoid cells was drastically different from this observed in erythroid cells.     

Patterns of the histone modifications across the chicken alpha-globin genes domain

Using native chromatin immunoprecipitation (N-ChIP) followed by TaqMan RT-PCR quantitative analysis we have determined the profiles of histone acetylation and histone methylation within the alpha-globin gene domain before and after switching of embryonic globin genes expression. The results obtained do not support a supposition that the inactivation of the embryonic alpha-type globin gene pi in erythroid cells of the adult lineage is mediated via formation of an inactive chromatin domain. On the other hand we have demonstrated that suppression of the gene pi activity in erythroid cells of adult lineage correlates with the decrease of the histone acetylation level within the embryonic subdomain of the alpha-globin gene domain.     

Organization of specific DNA sequence elements in the region of the replication origin and matrix attachment site in the chicken alpha-globin gene domain.

Summary The distribution of specific DNA sequence elements in a 2.9 kb HindIII fragment of chicken DNA containing the replication origin and the upstream matrix attachment site (MAR) of the -globin gene domain was investigated. The fragment was shown to contain a CR1-type repetitive element and two stably bent DNA sequences. One of them colocalizes with the previously described MAR element and with the recognition site for a proliferating-cell-specific, DNA-binding protein. The melting pattern of a set of subfragments of the region proved to be non random. No correlation between the distribution of readily melting sequences and bent DNA was found. The possible importance of curved, low-melting and repetitive DNA sequences for the organization of the upstream boundary of the -globin gene domain and the function of the replication origin is discussed.     

GATA-1 modulates the chromatin structure and activity of the chicken alpha-globin 3' enhancer

Long-distance regulatory elements and local chromatin structure are critical for proper regulation of gene expression. Here we characterize the chromatin conformation of the chicken α-globin silencer-enhancer elements located 3′ of the domain. We found a characteristic and erythrocyte-specific structure between the previously defined silencer and the enhancer, defined by two nuclease hypersensitive sites, which appear when the enhancer is active during erythroid differentiation. Fine mapping of these sites demonstrates the absence of a positioned nucleosome and the association of GATA-1. Functional analyses of episomal vectors, as well as stably integrated constructs, revealed that GATA-1 plays a major role in defining both the chromatin structure and the enhancer activity. We detected a progressive enrichment of histone acetylation on critical enhancer nuclear factor binding sites, in correlation with the formation of an apparent nucleosome-free region. On the basis of these results, we propose that the local chromatin structure of the chicken α-globin enhancer plays a central role in its capacity to differentially regulate α-globin gene expression during erythroid differentiation and development.     

Genetic analysis of the cell binding domain region of the chicken fibronectin gene

We have determined the nucleotide sequence of the cell binding domain region of the chicken fibronectin gene and analyzed it evolutionaly. We present here the complete nucleotide sequence of 4.3 kb HindIII/EcoRI segment from the clone lambda FC23 of the chicken fibronectin gene. There were five exons in this segment. When we lined up the amino acid of exons 28, 29 and 31, three alignments, known as the Type III repeat, appeared. Tetrapeptide, -RGDS-, called the cell binding domain, existed in the second repeat, coding exon 30. It was presumed that the Type III repeats were composed of two exons in the chicken gene, the same as in the rat and humans. We found repeatedly appearing amino-acid sequences such as -TIT- (three arrays in these Type III repeats) but also found one of the amino acids substituted in the tripeptide in these Type III repeats (seven arrays). We analyzed these repeats from the point of view of evolution. We used three of the nucleotide sequences (12-18 bp) coding such -TIT- repeats as a unit length for comparing the various homologies after dividing the coding region into 56 segments. The mutual homology of the divided segments to each one of three showed 53% on average. On the other hand, the mutual nucleotide homology of the Type III repeat was 44%. This suggested that the Type III repeat may have been developed by frequent duplication of small gene units.