Affinity chromatography of cysteine-containing histone.

Affinity chromatography based on the reaction between SH groups in protein and +HgC6H4CO groups in the p-mercuribenzoylaminoethyl derivative of Sepharose 4B was examined with a crude preparation of calf thymus cysteine-containing histone. Adsorption of the histone onto the column by specific coupling was found to be optimal in 0.1 M citrate buffer, pH 5.5, containing 5M urea to prevent any aggregation of histones and their non-specific adsorption onto the column, and elution from the column was successfully performed by cleavage of the resulting S-Hg bond with urea-buffer solution containing 0.05 M 2-mercaptoethanol. Under these conditions both the adsorption and elution were quantitative; no adsorption was observed when either SH-blocked histone or unsubstituted Sepharose was used. The cysteine-containing histone thus recovered, after further purification by Bio-Gel P-60 chromatography to remove some cysteine-containing nonhistone proteins contaminating the starting material, showed a single band on polyacrylamide gel electrophoresis and an amino acid composition agreeing with the known sequence of this histone.     

Use of an oligonucleotide probe to detect transplacement of an amber mutation into a yeast histone H3 gene

We have used a synthetic 17-mer to direct mutagenesis of the cloned yeast histone H3 gene HHT2, creating an amber mutation at amino acid 41. This point mutation did not alter the restriction pattern of the HHT2 gene nor was it expected to provide an easily scorable phenotype in vivo. Therefore, nucleic acid hybridization was used to detect this point mutation during strain construction. The oligonucleotide was used to probe yeast genomic Southern blots to detect integration of the plasmid bearing the mutant HHT2 gene into the genome, and then to score the eventual excision of the plasmid vector with retention of the mutant gene on the chromosome. This technique can be used to score virtually any engineered point mutations in yeast.     

The histones of the sperm of Spisula solidissima include a novel, cysteine-containing H-1 histone

The histones remaining at the end of the spermiogenic differentiation, which are found associated with a highly basic protamine-like component [Ausio, J. and K.E. Van Holde (1987) Eur. J. Biochem. 165, 363-371] in the mature sperm of Spisula solidissima, have been isolated and characterized for the first time. All four core histones H2A, H2B, H3, H4, and the lysine-rich histone H1 are present. The core histones are found in equal stoichiometric amounts. As has been observed in other bivalve molluscs, the amino acid compositions of the core histones of S. solidissima sperm are very close to those of their counterparts in the calf thymus somatic histones. The spermatic histone H1 exhibits an amino acid composition and structural features similar to other histones of the histone H1 family. Yet this latter histone seems to be sperm-specific, and it contains at least two cysteine residues per molecule, which makes it unique in its class.     

Behaviour of tyrosyl residues of calf-thymus histone F3. Difference-spectroscopy studies.

We have studied the behaviour of microenvironments containing tyrosine of calf thymus histone F3 (or histone H3) by using the difference spectroscopy techniques of thermal and solvent perturbation. By comparison of the parameters found for the models L-tyrosine methyl ester and N-acetyl-L-tyrosine ethyl ester with those for the protein at various conditions, several aspects of the tertiary structure of histone F3 become apparent. The raising of ionic strength produces a general burial of tyrosyl residues of the histone, whereas low pH or urea treatment causes a complete exposure of tyrosyl groups with respect to the solvent. Anomalously high values can also be observed of accessibility of the perturbants sucrose and ethylene glycol at low concentrations of phosphate buffer. The relevance of these findings towards a better understanding of the tertiary structure of histone F3 and of its interactions with DNA is discussed.     

Inactivating mutation in histone deacetylase 3 stabilizes its active conformation

Histone deacetylases (HDACs), together with histone acetyltransferases (HATs), regulate gene expression by modulating the acetylation level of chromatin. HDAC3 is implicated in many important cellular processes, particularly in cancer cell proliferation and metastasis, making inhibition of HDAC3 a promising epigenetic treatment for certain cancers. HDAC3 is activated upon complex formation with both inositol tetraphosphate (IP4) and the deacetylase‐activating domain (DAD) of multi‐protein nuclear receptor corepressor complexes. In previous studies, we have shown that binding of DAD and IP4 to HDAC3 significantly restricts its conformational space towards its stable ternary complex conformation, and suggest this to be the active conformation. Here, we report a single mutation of HDAC3 that is capable of mimicking the stabilizing effects of DAD and IP4, without the presence of either. This mutation, however, results in a total loss of deacetylase activity, prompting a closer evaluation of our understanding of the activation of HDAC3.     

Iodination of Xenopus laevis histone F2a1 in chromatin.

The reaction of calf thymus and Xenopus laevis histones with radioactive iodine has been studied under various conditions that affect chromatin structure. All histones from both species contain at least one tyrosine residue and, in a denaturing solvent, all the the histones react with iodine. Histone F2a1 has been studied in detail. Calf thymus F2a1 is known to contain four tyrosyls and all four react with iodine. In high voltage paper electrophoresis, the tyrosine-containing peptides from calf co-migrate with those from Xenopus F2a1, suggesting that the amino acid sequence is strongly conserved between these two species. Therefore, the published calf thymus F2a1 sequence has been used to order the Xenopus F2a1 peptides within the molecules. When gently isolated native chromatin is iodinated in a low ionic strength medium 60% of the radioactivity in F2a1 is in tyrosyl 88, 30% in tyrosyl 51, and tyrosyl 72 and 98 have almost no radioactivity. Reagents which remove the protein from the DNA (2 M NaCl) or partially disrupt protein tertiary structure (5 M urea) increase the reactivity of each of the four tyrosyls five- to tenfold, suggesting that all four are protected about equally by the overall folding of the chromatin. Isolated F2a1 iodinated in the presence of 10 M urea shows uniform labeling in each of the four peptides, suggesting that tyrosyl 72 and 98 are afforded some protection solely by protein-protein interactions. The stepwise removal of histones in increasing NaCl concentrations differentially increases the availability of each F2a1 tyrosyl. The preferential exposure of tyrosyl 88 coincides with the removal of the majority of F1 histones at 0.5 M NaCl while the gradual and stepwise increase in reactivity of tyrosyl 51, 72, and 98 correlates with the gradual removal of histones other than F1. Radioactive iodination of chromatin has been shown to be a sensitive probe for detecting changes in the association state (or conformation) of histone F2a1.     

Dynamics of a novel centromeric histone variant CenH3 reveals the evolutionary ancestral timing of centromere biogenesis

The centromeric histone H3 variant (CenH3) serves to target the kinetochore to the centromeres and thus ensures correct chromosome segregation during mitosis and meiosis. The Dictyostelium H3-like variant H3v1 was identified as the CenH3 ortholog. Dictyostelium CenH3 has an extended N-terminal domain with no similarity to any other known proteins and a histone fold domain at its C-terminus. Within the histone fold, α-helix 2 (α2) and an extended loop 1 (L1) have been shown to be required for targeting CenH3 to centromeres. Compared to other known and putative CenH3 histones, Dictyostelium CenH3 has a shorter L1, suggesting that the extension is not an obligatory feature. Through ChIP analysis and fluorescence microscopy of live and fixed cells, we provide here the first survey of centromere structure in amoebozoa. The six telocentric centromeres were found to mostly consist of all the DIRS-1 elements and to associate with H3K9me3. During interphase, the centromeres remain attached to the centrosome forming a single CenH3-containing cluster. Loading of Dictyostelium CenH3 onto centromeres occurs at the G2/prophase transition, in contrast to the anaphase/telophase loading of CenH3 observed in metazoans. This suggests that loading during G2/prophase is the ancestral eukaryotic mechanism and that anaphase/telophase loading of CenH3 has evolved more recently after the amoebozoa diverged from the animal linage.     

Expression of a mutation affecting F incompatibility in the integrated but not the autonomous state of F.

Previously we have described a mutant Hfr strain in which incompatibility between the integrated F factor and an autonomous F-prime (F') factor was abolished. The mutation (inc) was located in the integrated F factor. F-prime factors isolated from the mutant Hfr strain have the same incompatibility behavior as those isolated from normal Hfr strains. Reintegration of these F' factors into the chromosome restores the Inc- phenotype characteristic of the mutant Hfr. The inc mutation thus affects incompatibility between integrated F and autonomous F(Fi-Fa incompatibility) but not incompatibility between two autonomous F factors (Fa-Fa incompatibility). The implications of this finding for the mechanism of plasmid incompatibility are discussed.     

The relationship between histones F 2al and F 2a2 and the ancestral histone A peptide. Further evidence for the common origin of histones F 2al, F 2a2 and F 3.

The relationship between histones F 2al and F 2a2 becomes much more apparent if the alignment is not made between the total sequences but between the ancestral A peptide, reconstructed earlier for histone F 2al (IV) and F 2a2. 46.5% of the latter's sequence can thus be clearly connected with F 2al through this ancestral dodecapeptide. A parallel development of histones F 2al, F 2a2 and F 3 from the A peptide is proposed.     

The evolutionary history of histone H3 suggests a deep eukaryotic root of chromatin modifying mechanisms

Background  

The phenotype of an organism is an outcome of both its genotype, encoding the primary sequence of proteins, and the developmental orchestration of gene expression. The substrate of gene expression in eukaryotes is the chromatin, whose fundamental units are nucleosomes composed of DNA wrapped around each two of the core histone types H2A, H2B, H3 and H4. Key regulatory steps involved in the determination of chromatin conformations are posttranslational modifications (PTM) at histone tails as well as the assembly of histone variants into nucleosomal arrays. Although the mechanistic background is fragmentary understood, it appears that the chromatin signature of metazoan cell types is inheritable over generations. Even less understood is the conservation of epigenetic mechanisms among eukaryotes and their origins.     

Escaping an evolutionary lobster trap: drug resistance and compensatory mutation in a fluctuating environment

The fitness landscape concept aids intuition on adaptive evolution through low fitness genotypes. Evolutionary processes become complex when environments and therefore fitnesses fluctuate. Antibiotic resistance evolution in bacteria is an important example of such dynamics. Resistance bears a cost in the drug-free environment, but compensatory mutation can lower this cost, creating a fitness valley. With the drug present, the valley becomes a hill that is easily climbed. Once a population is dominated by resistant-compensated genotypes, reversion to sensitivity is difficult: this phenomenon has been described as an evolutionary lobster trap. With increasing frequencies of drug resistance among pathogenic bacteria, it is critical to understand how this trap can be escaped. Here, we develop stochastic models to investigate these dynamics. The residual fitness cost (the cost remaining after compensatory mutation has occurred) is a key parameter. Reversion to sensitivity is favored when the time spent in the absence of the drug relative to its presence is high compared to the residual fitness cost. Population sizes are also important: in large populations, resistant-compensated mutants appear in resistant-uncompensated or sensitive-compensated genotypes without fixation of these intermediates. This stochastic tunneling effect occurs when sufficient time is allowed by the rates of environmental fluctuation.     

A method for the purification of histone fraction F3 by affinity chromatography

Calf thymus histone fraction F3 has been purified in high yield by affinity chromatography. The protein is attached reversibly to an organomercurial—Sepharose—by the thiol groups of its cysteinyl residues, while all other histones lacking -SH groups pass through the column. Histone F3 is subsequently eluted with -SH reagents of low molecular weight, such as cysteine or β-mercaptoethanol. The purified F3 shows electrophoretic heterogeneity due to different degrees of acetylation of the parent polypeptide chain. Under oxidizing conditions it forms a complex mixture of dimers and oligomers, all of which have some available -SH groups.     

An unusual evolutionary behaviour of a sea urchin histone gene cluster

DNA sequences of cloned histone coding sequences and spacers of sea urchin species that diverged long ago in evolution were compared. The highly repeated H4 and H3 genes active during early embryogenesis had evolved (in their silent sites) at a rate (0.5-0.6% base changes/Myr) similar to single-copy protein-coding genes and nearly as fast as spacer DNA (0.7% base changes/Myr) and unique DNA. Thus, evolution in the major histone genes conforms to a universal evolutionary clock based on the rate of base sequence change. By contrast, the H4 and H3 coding sequences and a non-transcribed spacer of the DNA clone h19 of Psammechinus miliaris show an exceptionally low rate of sequence evolution only 1/100 to 1/200 that predicted from the clock hypothesis. According to the classical model of gene inheritance, the h19 DNA sequences in the Psammechinus genome require unusual conservation mechanisms by selection at the level of the gene and spacer sequences. An alternative explanation could be recent horizontal gene transfer of a histone gene cluster from the very distantly related Strongylocentrotus dröbachiensis to the P. miliaris genome.