Activity banding of human chromosomes as shown by histone acetylation

The expression of genes in mammalian cells depends on many factors including position in the cell cycle, stage of differentiation, age, and environmental influences. As different groups of genes are expressed, their packaging within chromatin changes and may be detected at the chromsomal level. The organization of DNA within a chromosome is determined to a large extent by the positively charged, highly conserved histones. Histone subtypes and the reversible chemical modifications of histones have been associated with gene activity. Active or potentially active genes have been associated with hyperacetylated histones and inactive genes with nonacetylated histones. Sodium butyrate increases the acetylation levels of histones in cell cultures and acts as both an inducer of gene activity and as a cell-cycle block. We describe a method to label the interphase distribution of DNA associated with various histone acetylation stages on chromosomes. Nucleosomes from untreated and butyrate-treated HeLa cells were fractionated by their acetylation level and the associated DNA labeled, and hybridized to normal human chromosomes. In the sodium butyrate-treated cells the resulting banding patterns of the high- and low-acetylated fractions were strikingly different. DNA from low-acetylated chromatin labeled several pericentric regions, whereas hybridization with DNA from highly acetylated chromatin resulted in a pattern similar to inverse G-bands on many chromsomes. The results from noninduced cells at both high and low acetylation levels were noticeably different from their induced counterparts. The capture and hybridization of DNA from interphase chromatin at different acetylation states provides a “snap-shot” of the distribution of gene activity on chromosomes at the time of cell harvest. Edited by: P.B. Moens     

Recognition of specific DNA sequences in eukaryotic chromosomes.

The packaging of DNA into chromatin probably places certain restrictions on how specific DNA sequences can be recognized by DNA sequence specific recognition proteins (SRP). Several unique features of this type of interaction are discussed. Specifically, as a consequence of the coiling of the DNA about a histone core, it is proposed that DNA recognition sites will be compound and that each element of the compound recognition site will be about 10 - 20 b.p. in length and distributed at approximately 80 b.p. intervals--the periodicity of the DNA wrapping around the nucleosome.     

A non-isotopic in vitro assay for histone acetylation

We describe a simple, robust, and relatively inexpensive non-radioactive in vitro assay for measuring histone acetyl-transferase activity. The assay takes advantage of easy to purify recombinant E. coli-derived fusion proteins containing the NH(2)-terminal tails of histones H3 and H4 linked to epitope-tagged maltose-binding protein (MBP), and immunoblotting with antibodies specific to acetylated H3 and H4. Here we show the specificity and dynamic range of this assay for the histone acetyl-transferases, p300 and PCAF. This assay may be adapted readily for other substrates by simply generating new fusion proteins and for other acetyl-transferases by modifying reaction conditions.     

Replication-independent nucleosome exchange is enhanced by local and specific acetylation of histone H4

We used a novel single-cell strategy to examine the fate of histones during G₂-phase. Consistent with previous results, we find that in G₂-phase, the majority of nuclear histones are assembled into chromatin, whereas a small fraction comprises an unassembled pool. Small increases in the amount of histones within the free pool affect the extent of exchange, suggesting that the free pool is in dynamic equilibrium with chromatin proteins. Unexpectedly, acetylated H4 is preferentially partitioned to the unassembled pool. Although an increase in global histone acetylation did not affect overall nucleosome dynamics, an H4 containing lysine to glutamine substitutions as mimics of acetylation significantly increased the rate of exchange, but did not affect the acetylation state of neighbouring nucleosomes. Interestingly, transcribed regions are particularly predisposed to exchange on incorporation of H4 acetylation mimics compared with surrounding regions. Our results support a model whereby histone acetylation on K8 and K16 specifically marks nucleosomes for eviction, with histones being rapidly deacetylated on reassembly.     

Plant histone acetylation: in the beginning ..

The study of histone acetylation in plants started with protein purification and sequencing, with gel analysis and the use of radioactive tracers. In alfalfa, acid urea Triton gel electrophoresis and in vivo labeling with tritated acetate and lysine quantified dynamic acetylation of core histones and identified the replication-coupled and -independent expression patterns of the histone H3.1 and H3.2 variants. Pulse-chase analyses demonstrated protein turnover of newly synthesized histone H3.2 and thereby identified the replacement H3 histones of plants which maintain the nucleosome density of transcribed chromatin. Sequence analysis of histone H4 revealed acetylation of lysine 20, a site typically methylated in animals and yeasts. Histone deacetylase inhibitors butyrate and trichostatin A are metabolized in alfalfa, but loss of TSA is slow, allowing its use to induce transient hyperacetylation of histones H2B, H4 and H3. This article is part of a Special Issue entitled: Epigenetic Control of cellular and developmental processes in plants.     

Enzymic acetylation of nucleosome histone.

Rat liver chromatin prepared from purified nuclei catalyzed the acetylation of histones in nucleosomes at the same level as that of nuclei. The activity of histone acetyltransferase in chromatin was destroyed by heat treatment at 65 degrees C for 5 min. Histones in exogenously added nucleosomes also served as substrate for the enzyme. The sites of acetylation in the nucleosomes appeared to be in the trypsin-digestable N-terminal regions of histones H4, H3, and H2A, as has been reported in an in vivo system.     

Highly specific antibodies determine histone acetylation site usage in yeast heterochromatin and euchromatin.

We have developed a highly specific antibody set for acetylation sites in yeast histones H4 (K5, K8, K12, and K16); H3 (K9, K14, K18, K23, and K27); H2A (K7); and H2B (K11 and K16). Since ELISA does not assure antibody specificity in chromatin immunoprecipitation, we have employed additional screens against the respective histone mutations. We now show that telomeric and silent mating locus heterochromatin is hypoacetylated at all histone sites. At the INO1 promoter, RPD3 is required for strongly deacetylating all sites except H4 K16, ESA1 for acetylating H2A, H2B, and H4 sites except H4 K16, and GCN5 for acetylating H2B and H3 sites except H3 K14. These data uncover the in vivo usage of acetylation sites in heterochromatin and euchromatin.     

The subunit-exchange model of histone acetylation

Increased histone acetylation has long been linked to gene activation, but little is known about how acetylation levels are regulated, largely because the histone acetyltransferase activities (HATs) responsible for this modification have been cloned only recently. Comparison of the biochemical nature of the Tetrahymena HAT A complex with the genetic and biochemical properties of the Saccharomyces Gcn5p-Ado complex leads us to propose that histone acetylase assemblies may be modular in nature and that this modularity may be an intimate part of the association of these enzymes with chromatin. The 'subunit-exchange' model provides a mechanism for the regulation and targeting of both histone acetylases and deacetylases and has implications for the control of cell growth, proliferation and tumorigenesis.     

Parent-of-origin specific histone acetylation and reactivation of a key imprinted gene locus in Prader-Willi syndrome

To examine the chromatin basis of imprinting in chromosome 15q11-q13, we have investigated the status of histone acetylation of the SNURF-SNRPN locus, which is a key imprinted gene locus in Prader-Willi syndrome (PWS). Chromatin immunoprecipitation (ChIP) studies revealed that the unmethylated CpG island of the active, paternally derived allele of SNURF-SNRPN was associated with acetylated histones, whereas the methylated maternally derived, inactive allele was specifically hypoacetylated. The body of the SNURF-SNRPN gene was associated with acetylated histones on both alleles. Furthermore, treatment of PWS cells with the DNA methyltransferase inhibitor 5-azadeoxycytidine (5-aza-dC) induced demethylation of the SNURF-SNRPN CpG island and restoration of gene expression on the maternal allele. The reactivation was associated with increased H4 acetylation but not with H3 acetylation at the SNURF-SNRPN CpG island. These findings indicate that (1) a significant role for histone deacetylation in gene silencing is associated with imprinting in 15q11-q13 and (2) silenced genes in PWS can be reactivated by drug treatment.     

Euchromatic domains in plant chromosomes as revealed by H4 histone acetylation and early DNA replication.

Using specific polyclonal antisera raised against acetylated isoforms of histone H4, we have analyzed their distribution in the dioecious plant Silene latifolia (syn. Melandrium album) possessing heteromorphic sex chromosomes. Our previous studies on this species have shown that one of the two X chromosomes in homogametic female cells is heavily methylated and late replicating, as a possible consequence of dosage compensation. Here we report that there are no detectable differences in intensity and distribution of H4 acetylation between these two X chromosomes. In S. latifolia only distal-subtelomeric chromosome regions, on both the sex chromosomes and autosomes, display strong signals of H4 acetylation at N-terminal lysines 5, 8, and 12. These acetylated domains correspond to the very early replicating distal chromosome regions as revealed by 5-bromodeoxyuridine pulses followed by the indirect immunofluorescence microscopy. The distribution of H4 acetylated at lysine 16 was uniform along the chromosomes. The unique distal-subtelomeric H4 acetylation signals were also observed in three other Silene species (S. vulgaris, S. pendula, and S. chalcedonica), but not in two non-related plant species tested (Allium cepa and Nicotiana tobacum). The presented data as well as our recent studies on the structure of S. latifolia chromosome ends indicate that Silene species possess the specific distal-subtelomeric location of euchromatin, gene-rich regions on chromosomes.