The Chromatin of Active Genes Is Not in a Permanently Open Conformation

Quantitative measurements of local chromatin accessibility to DNase I in 15-day chicken embryo erythrocyte nuclei have been performed using a range of nuclease concentrations and real-time TaqMan PCR to monitor the loss of short (∼ 80 bp) amplicons. At the β-globin locus, well-established DNase I hypersensitive sites stand out against a background in which actively transcribed gene sequences (e.g., β-adult and β-hatching) are no more sensitive than the nearby constitutive heterochromatin that has previously been shown to form the 30-nm fibre structure. Similar observations were made at the lysozyme locus containing the active Gas41 gene and also at the GAPDH locus. We conclude that active genes are not continuously held in an open ‘beads-on-a-string’ configuration, but adopt a 30-nm-type structure most of the time. This implies that the compact nucleosomal supercoil re-forms in the wake of the polymerase complex.     

Linker histone subtype composition and affinity for chromatin in situ in nucleated mature erythrocytes

The replacement linker histones H1(0) and H5 are present in frog and chicken erythrocytes, respectively, and their accumulation coincides with cessation of proliferation and compaction of chromatin. These cells have been analyzed for the affinity of linker histones for chromatin with cytochemical and biochemical methods. Our results show a stronger association between linker histones and chromatin in chicken erythrocyte nuclei than in frog erythrocyte nuclei. Analyses of linker histones from chicken erythrocytes using capillary electrophoresis showed H5 to be the subtype strongest associated with chromatin. The corresponding analyses of frog erythrocyte linker histones using reverse-phase high performance liquid chromatography showed that H1(0) dissociated from chromatin at somewhat higher ionic strength than the three additional subtypes present in frog blood but at lower ionic strength than chicken H5. Which of the two H1(0) variants in frog is expressed in erythrocytes has thus far been unknown. Amino acid sequencing showed that H1(0)-2 is the only H1(0) subtype present in frog erythrocytes and that it is 100% acetylated at its N termini. In conclusion, our results show differences between frog and chicken linker histone affinity for chromatin probably caused by the specific subtype composition present in each cell type. Our data also indicate a lack of correlation between linker histone affinity and chromatin condensation.     

Analyses of linker histone--chromatin interactions in situ.

Recent studies, using cytometric techniques based on fluorescence microscopy, have provided new information on how linker histones interact with chromatin in vivo or in situ. In particular, the use of green fluorescent proteins (GFPs) has enabled detailed studies of how individual H1 subtypes, and specific motifs in them, interact with chromatin in vivo. Furthermore, the development of cytochemical methods to study the interaction between linker histones and chromatin using DNA-binding fluorochromes as indirect probes for linker histone affinity in situ, in combination with highly sensitive and specific analytical methods, has provided additional information on the interactions between linker histones and chromatin in several cell systems. Such results verified that linker histones have a substantially higher affinity for chromatin in mature chicken erythrocytes than in frog erythrocytes, and they also indicated that the affinity decreased during differentiation of the frog erythrocytes. Furthermore, in cultured human fibroblasts, the linker histones showed a relatively high affinity for chromatin in interphase, whereas it showed a significantly lower affinity in highly condensed metaphase chromosomes. This method also enables the analysis of linker histone affinity for chromatin in H1-depleted fibroblasts reconstituted with purified linker histones. No consistent correlation between linker histone affinity and chromatin condensation has so far been detected.     

Chromosomal arrangement of the chicken β-type globin genes

We have isolated the chicken β-type globin genes from a library of chicken DNA-λ Charon 4A recombinant bacteriophage. There are four β-type genes within this segment of the genome; we believe this represents all of the β-type genes of the chicken. The recombinant λCβG1 contains the embryonic ?- and adult β-globin genes. The hatching β^H and embryonic p-globin genes are found in the recombinant λCβG2. Although λCβG1 and λCβG2 do not physically overlap, we present evidence that all four genes are closely linked and transcribed from the same DNA strand. These experiments demonstrate that the chromosomal regions represented by λCβG1 and λCβG2 lie approximately 1.6 kb apart in the chicken genome. A third recombinant λCβG3 extends the genomic locus studied in the vicinity of the β-type globin genes to approximately 39 kb. The physical order of the chicken β-type globin genes within this segment of the chromosome is 5′ … ?-β^H-β-? … 3′. This arrangement is unique among the vertebrate β-type globin gene clusters thus far examined, in that embryonic genes are located at the 5′ and 3′ ends of the cluster while the hatching and adult genes occupy central positions.