[Opposite Effects of Histone H1 and HMGN5 Protein on Distant Interactions in Chromatin].

Transcriptional enhancers in the cell nuclei typically interact with the target promoters in cis over long stretches of chromatin, but the mechanism of this communication remains unknown. Previously we have developed a defined in vitro system for quantitative analysis of the rate of distant enhancer-promoter communication (EPC) and have shown that the chromatin fibers maintain efficient distant EPC in cis. Here we investigate the roles of linker histone H1 and HMGN5 protein in EPC. A considerable negative effect of histone H1 on EPC depending on its C- and N-tails was shown. Protein HMGN5 that affects chromatin compaction and is associated with active chromatin counteracts EPC inhibition by H1. The data suggest that the efficiency of the interaction between the enhancer and the promoter depends on the structure and dynamics of the chromatin fiber localized between them and can be regulated by proteins associated with chromatin.

NBP-45, a novel nucleosomal binding protein with a tissue-specific and developmentally regulated expression.

Here we characterize a novel murine nuclear protein, which we named NBP-45, that is related to the ubiquitous nuclear proteins HMG-14/-17, binds specifically to nucleosome core particles, and can function as a transcriptional activator. NBP-45 mRNA is expressed at low levels and in variable amounts in all mouse tissues tested but is especially abundant in RNA extracted from 7-day-old mouse embryos, suggesting that it functions in early embryonic development. NBP-45 is composed of 406 amino acids and is encoded by a single size transcript. The region spanning the N-terminal 85 amino acids contains three segments that are highly homologous to functionally important domains in the HMG-14/-17 protein family: the nuclear localization signal, the nucleosome binding domain, and the chromatin unfolding domain. The protein region spanning the C-terminal 321 amino acids has a 42% content of negatively charged residues. The first 23 amino acids contain a region necessary for nuclear entry of the protein, the region spanning residues 12-40 is the main nucleosomal binding domain of the protein, and the negatively charged, C-terminal domain is necessary for transcription activation. The functional domains of NBP-45 are indicative of a nuclear protein that binds to nucleosomes, thereby creating a chromatin region of high local negative charge. Our studies establish the nucleosomal binding domain as a protein motif that is present in other than just the ubiquitous HMG-14/-17 proteins. We suggest that the nucleosomal binding domain motif is a protein module that facilitates binding to nucleosomes in chromatin.

Clusters of nucleosomes containing chromosomal protein HMG-17 in chromatin.

Chromosomal proteins HMG-14 and HMG-17 are nucleosome binding proteins which can function as architectural elements to alter the structure of the chromatin fiber and enhance transcription from chromatin templates. Here we study the spatial organization of these HMG proteins in the nucleus and the distribution of nucleosomes containing HMG-17 in the chromatin fiber. By confocal immunofluorescence microscopy we find that HMG-14/17 proteins are clustered into foci containing either HMG-14 or HMG-17. These results suggest that HMG-14/17 proteins segregate into distinct nuclear domains. Indeed, immunofractionation of defined length oligonucleosomes, with affinity pure antibodies to HMG-17, indicates that oligonucleosomes containing HMG-17 are devoid of HMG-14. Quantitative analysis indicates that in cellular chromatin nucleosomes containing HMG-17 are clustered. The average size of the cluster is six contiguous HMG-17-containing nucleosomes. The nucleosomes in this cluster contain either two or zero molecules of HMG-17 and a complete set of four core histones. We suggest that HMG-14/17 proteins modify the nucleosomal organization of the 30 nm chromatin fiber, to unfold the higher order chromatin structure and facilitate access to the underlying DNA sequence. Clustering of architectural elements, such as HMG proteins and linker histone subtypes into distinct domains, may lead to structural and functional heterogeneity along the chromatin fiber.

Modular structure of chromosomal proteins HMG-14 and HMG-17: definition of a transcriptional enhancement domain distinct from the nucleosomal binding domain.

Chromosomal proteins HMG-14 and HMG-17 are the only known nuclear proteins which specifically bind to the nucleosome core particle and are implicated in the generation and/or maintenance of structural features specific to active chromatin. The two proteins facilitate polymerase II and III transcription from in vitro- and in vivo-assembled circular chromatin templates. Here we used deletion mutants and specific peptides to identify the transcriptional enhancement domain and delineate the nucleosomal binding domain of the HMG-14 and -17 proteins. Deletion of the 22 C-terminal amino acids of HMG-17 or 26 C-terminal amino acids of HMG-14 reduces significantly the ability of the proteins to enhance transcription from chromatin templates. In contrast, N-terminal truncation mutants had the same transcriptional enhancement activity as the full-length proteins. We conclude that the negatively charged C-terminal region of the proteins is required for transcriptional enhancement. Chromatin transcription enhancement assays, which involve binding competition between the full-length proteins and peptides derived from their nucleosomal binding regions, indicate that the minimal nucleosomal binding domain of human HMG-17 is 24 amino acids long and spans residues 17 to 40. The results suggest that HMG-14 and -17 proteins have a modular structure and contain distinct functional domains.

Homodimers of chromosomal proteins HMG-14 and HMG-17 in nucleosome cores.

In this work, we report that nucleosome core particles interact with an equimolar mixture of the chromosomal proteins HMG-14 and HMG-17 to form, exclusively, complexes containing two molecules of either HMG-14 or HMG-17 (homodimers). Analysis of the binding of various mixtures of wild-type proteins and their deletion mutants indicates that homodimer formation is not dependent on contacts between the nucleosome-bound HMG-14/-17 proteins themselves. We suggest that HMG-14/-17 proteins in nucleosomes cross-talk by inducing specific allosteric transitions in the chromatin subunit.

The HMG-14/-17 chromosomal protein family: architectural elements that enhance transcription from chromatin templates.

Chromosomal proteins HMG-14 and HMG-17 enhance the transcriptional potential of chromatin when incorporated into nucleosomes during, but not after, chromatin assembly on replicating DNA. Two molecules of either HMG-14 or HMG-17 can bind to nucleosome cores, independently of the underlying DNA sequence, in a cooperative fashion to limit nucleosome mobility and stabilize the structure of the nucleosome core without stabilizing the higher order chromatin structure. By modifying the structure of nucleosomes, the proteins affect the local structure of the chromatin fiber leading to an increase in the rate of transcriptional elongation but not initiation. We suggest that HMG-14/-17 are architectural elements which assist in the assembly of an unfolded chromatin fiber thereby decreasing the repressive activity of histones and facilitating transcriptional processes.

The cooperative binding of chromosomal protein HMG-14 to nucleosome cores is reduced by single point mutations in the nucleosomal binding domain.

Mutants of human chromosomal protein HMG-14 were generated by site directed mutagenesis and used to study functional domains in this protein. A replacement of serine by cysteine at position 7 did not affect the binding of the protein to nucleosome cores. The sulfhydryl group in the nucleosome-bound protein is accessible to modifying agents suggesting that position 7 in the protein is not in close contact with either the DNA or the histones in the core particles. Under cooperative binding conditions, replacements of alanine by proline at position 21, or of lysine by cysteine at position 26, decreased the affinity of the protein for nucleosome cores 6.7- and 3-fold respectively. In contrast, the non-cooperative mode of binding was only minimally affected. A replacement of glutamic acid by glutamine at position 76 caused only minor changes in the binding of the protein to the cores. The results indicate that single point mutations, which change either the conformation or change in the nucleosomal binding domain of the protein, significantly reduce the ability of the HMG-14 protein to bind to nucleosome cores. We suggest that in chromatin the protein binds to nucleosomes in a cooperative manner and that upon binding to nucleosomes the protein acquires a distinct conformation.

Distribution of high mobility group proteins 1/2, E and 14/17 and linker histones H1 and H5 on transcribed and non-transcribed regions of chicken erythrocyte chromatin.

Quantitative analysis of distribution of chromosomal proteins on single copy DNA sequences has been further developed. Our approach consists of DNA-protein crosslinking within whole cells or isolated nuclei, specific immunoaffinity isolation of crosslinked complexes via protein and identification of crosslinked DNA by hybridisation with single-stranded DNA probes. The present study shows that transcribed chromatin of chicken embryonic erythrocyte beta globin gene is characterized by about 1.5-2.5-fold higher density of HMG 14/17 and 2-fold lower density of H1 and H5 as compared with non-transcribed chromatin of ovalbumin and lysozyme genes, whereas HMG 1/2, E proteins were equally distributed between DNA of both transcribed and non-transcribed genes. The depletion of H1/H5 in beta globin sequences was verified by the 'protein image' hybridisation technique (1). The DNase I hypersensitive site located 5' upstream from beta globin gene is deficient in all the proteins assayed, what implies a drastic disruption in the nucleosomal array. Minor quantitative changes of protein pattern suggest transient local perturbation of the chromatin on transcription.