Chemical crosslinking of histone H1° to histone neighbours in nuclei and chromatin

Crosslinking of histones in mouse liver nuclei and extended chromatin with a bifunctional reagent leads to the formation of H1H1° heterodimers as well as H1°H1° homodimers. H1° can be also crosslinked to the core histones. Thus, the location of histone H1° within the basic repeating chromatin structure seems to be analogous to that of H1 histone.     

Occurrence of histone H1° protein in rat alveolar macrophages

Histone H1 of rat alveolar macrophages, neutrophilic granulocytes and monocytes extracted with 5% (v/v) perchloric acid was studied in order to see whether a protein similar to histone H1° of rat liver exists in these specialized cells. The biochemical methods used involved SDS and acid-urea polyacrylamide gel electrophoresis, gel filtration on BioGel P100 and raising antisera against chromatographically purified rat liver H1° and histone H1. The antiserum was applied for further characterization of the presumptive H1° fraction using ELISA and Western blot analysis.The results from our studies showed that histone H1° protein is present in rat alveolar macrophages, monocytes and neutrophilic granulocytes, but its quantity in neutrophilic granulocytes is very much less than macrophages and monocytes.     

The occurrence and properties of histone H1° in quiescent rabbit tissue

• 1.1. The issue of the existence and the properties of histone H1° in quiescent rabbit tissues was approached by electrophoretic, Chromatographic and immunochemical techniques.
• 2.2. The results demonstrated that the rabbit tissues did contain a typical histone H1°, its properties being comparable to those of H1° from all other sources studied thus far.

     

Inhibition of ADP-ribosylation of histone H1 by analogs of diadenosine 5′, 5‴-p1,p4-tetraphosphate

The effects of analogs of diadenosine 5,5-p¹,p⁴-tetraphosphate (Ap4A) were examined on the ADP-ribosylation reaction of histone Hl catalysed by purified bovine thymus poly(ADP-ribose)transferase. Among the compounds tested, Ap4A and ApCH₂PPPA were shown to be the most efficient inhibitors of the enzyme. From kinetic studies of their action, it appears that Ap4A and ApCH₂pppA might be mixed type inhibitors.Abbreviations ADP-ribose adenosine diphosphate ribose - ADPRT poly-(ADP-ribose)transferase - Ap4A diadenosine 5,5-p₁,p₄-tertraphosphate - Ap4A diadenosine 5,5-p¹,p⁴(-1,N⁶-ethenyl-)tetra-phosphate - ApAA diadenosine 5,5-p¹,p⁴(-N⁶(-1,N⁶-)bisethenyl-)tetraphosphate - ApCH₂pppA diadenosine 5,5-p¹,p⁴(-p¹,p²-methylene-)tetraphosphate - AppCH₂ppA diadenosine 5,5-p¹,p⁴(-p²,p³methylene-)tetraphosphate - AppNHppA diadenosine 5,5-p¹,p⁴(-p²,p³-amino-)tetraphosphate - AppCHBrppA diadenosine 5,5-p¹,p⁴(-p²,p³-bromine methyno-)tetraphosphate - CpCH₂ppCH₂PC dicytidine 5,5-p¹,p⁴(-p¹,p²-p³,p⁴-bismethylene-)tetraphosphate - ApCH₂ppCH₂pA diadenosine 5,5-p¹,p⁴(-p¹,p²-p³,p⁴-bismethylene-)tetraphosphate.     

The vertebrate linker histones H10, H5, and H1M are descendants of invertebrate “orphon” histone H1 genes

We investigated the evolutionary history of the divergent vertebrate linker histones H1⁰, H5, and HIM. We observed that the sequence of the central conserved domain of these vertebrate proteins shares characteristic features with histone H1 proteins of plants and invertebrate animals which otherwise never appear in any vertebrate histone H1 protein. A quantitative analysis of 58 linker histone sequences also reveals that these proteins are more similar to invertebrate and plant histone H1 than to histone H1 of vertebrates. A phylogenetic tree deduced from an alignment of the central domain of all known linker histones places H1⁰, H5, and HIM in close vicinity to invertebrate sperm histone H1 proteins and to invertebrate histone H1 proteins encoded by polyadenylated mRNAs. We therefore conclude that the ancestors of the vertebrate linker histones H1⁰, H5, and HIM diverged from the main group of histone H1 proteins before the vertebrate type of histone H1 was established in evolution. We discuss this observation in the general context of linker histone evolution. Correspondence to: B. and E. Schulze     

Sequence simplicity and evolution of the 3′ untranslated region of the histone H1° Gene

The H1° gene has a long 3′ untranslated region (3′UTR) of 1,125 nucleotides in the rat and 1,310 in humans. Analysis of the sequences shows that they have features of simple DNA that suggest involvement of replication slippage in their evolution. These features include the length imbalance between the rat and human sequences; the abundance of single-base repeats, two-base runs and other simple motifs clustered along the sequence; and the presence of single-base repeat length polymorphisms in the rat and mouse sequences. Pairwise comparisons show numerous short insertions/deletions, often flanked by direct repeats. In addition, a proportion of short insertions/deletions results from length differences in conserved single-base repeats. Quantification of the sequence simplicity shows that simple sequences have been more actively incorporated in the human lineage than in the rodent lineage. The combination of insertions/deletions and nucleotide substitutions along the sequence gives rise to three main regions of homology: a highly variable central region flanked by more conserved regions nearest the coding region and the polyA addition site. Correspondence to: P. Suau     

Isolation of sea urchin embryo histone H2Aα1 and immunological identification of other stage-specific H2A proteins

H2A_α1, the principal H2A histone synthesized prior to the blastula stage of the sea urchin, was isolated free of other putative H2A subtypes and other histones. Its amino acid composition provides confirmation that H2A_α1 is the H2A protein encoded in the histone gene cluster carried by pCO2. An antibody prepared against this protein cross-reacts strongly with CS2A (a putative H2A synthesized only during the cleavage stage) as well as with H2A_β, H2A_γ, and H2A_δ (putative H2As synthesized principally after the blastula stage) but not with non-H2A core histones or other nuclear proteins. The data support the view that CS2A, H2A_α1, H2A_β, H2A_γ, and H2A_δ are all H2A proteins.     

Are linker histones (histone H1) dispensable for survival?

In the multicelled filamentous ascomycete Ascolobus immersus, the single copy gene for histone H1 can be silenced by methylation in the process known as methylation-induced premeiotically (MIP). The results of a recent paper using this unique system(1) have shown that histone H1 silencing results in an enhanced DNA accessibility to nucleases and an increase in the overall extent of DNA methylation. Interestingly, while none of these effects appear to decrease the immediate viability of this fungus, silencing of histone H1 results in a significant decrease in its overall life span. These results suggest that while linker histones may be dispensable for the relatively short life span of an individual cell, they are most likely indispensable for survival of higher eukaryote organisms.     

Does high-mobility-group non-histone protein HMG 1 interact specifically with histone H1 subfractions?

The interaction of the non-histone chromosomal protein HMG (high-mobility group) 1 with histone H1 subfractions was investigated by equilibrium sedimentation and n.m.r. sectroscopy. In contrast with a previous report [Smerdon & Isenberg (1976) Biochemistry 15, 4242--4247], it was found, by using equilibrium-sedimentation analysis, that protein HMG 1 binds to all three histone H1 subfractions CTL1, CTL2, and CTL3, arguing against there being a specific interaction between protein HMG 1 and only two of the subfractions, CTL1 and CTL2. Raising the ionic strength of the solutions prevents binding of protein HMG 1 to total histone H1 and the three subfractions, suggesting that the binding in vitro is simply a non-specific ionic interaction between acidic regions of the non-histone protein and the basic regions of the histone. Protein HMG 1 binds to histone H5 also, supporting this view. The above conclusions are supported by n.m.r. studies of protein HMG 1/histone H1 subfraction mixtures. When the two proteins were mixed, there was little perturbation of the n.m.r. spectra and there was no evidence for specific interaction of protein HMG 1 with any of the subfractions. It therefore remains an open question as to whether protein HMG 1 and histone H1 are complexed together in chromatin.