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.     

Spatial Organization of the Chicken α-Globin Gene Domain in Cells of Different Origins

Hybridization with an oligonucleotide array was used to map the regions of DNA anchorage to the nuclear matrix. Matrix-associated DNA served as a hybridization probe. To obtain the oligonucleotide array, 60-mer oligonucleotides regularly distributed throughout the genome region of interest at 2-kb intervals were immobilized on a nylon filter. The organization of DNA into loop domains was studied in a 100-kb region of chicken chromosome 16, including the α -globin gene cluster. A 40-kb DNA loop, which was fixed to the nuclear matrix and harbored all α-globin genes, was observed in erythroid cells. One of its anchorage regions colocalized with matrix associated region (MAR) and an insulator found previously in the 5′ region of the chicken α-globin gene domain. The spatial (domain-loop) organization of the α-globin gene cluster in lymphoid cells proved to be strikingly different from that in erythroid cells.     

Nonlymphoid cultured cells possess a system controlling cellular compatibility

We show that various nonlymphoid cultured cells can activate the production of cytotoxic factors in response to direct contact with cells of a different kind. Accumulation of cytotoxic factors in the medium was detected 1 h after contact of K562 and L929 cells or after contact of L929 cells with purified membranes of K562 cells. TNF-alpha or immunologically related proteins, or both, but not Fas-ligand or lymphotoxin, were also accumulated in membranes of K562 and L929 cells shortly after these cells had been allowed to contact each other. The cytotoxic factors expressed by nonlymphoid cells trigger apoptosis of target cells. These observations strongly suggest that nonlymphoid cells possess molecular mechanisms controlling cellular compatibility.     

Interbands of Drosophila melanogaster polytene chromosomes contain matrix association regions

The DNA of three previously cloned interband regions (85D9/D10, 86B4/B6, and 61C7/C8) of Drosophila melanogaster polytene chromosomes has been tested for the presence of matrix association regions (MAR), using the in vitro matrix-binding assay of Cockerill and Garrard. MARs were found in all three interband regions under study. These results are discussed in frames of a model postulating that interband regions of polytene chromosomes correspond to the chromosomal DNA loop borders, which can be identified in interphase nuclei using biochemical approaches.