Preferential and asymmetric interaction of linker histones with 5S DNA in the nucleosome.

We establish that linker histones H1 and H5 bind preferentially to a Xenopus borealis somatic 5S RNA gene associated with an octamer of core histones rather than to naked 5S DNA. This preferential binding requires free linker DNA to either side of the nucleosome core. Incorporation of a single linker histone molecule into the nucleosome protects an additional 20 bp of linker DNA from micrococcal nuclease digestion. This additional DNA is asymmetrically distributed with respect to the nucleosome core. Incorporation of linker histones causes no change to the cleavage of DNA in the nucleosome by hydroxyl radical or DNase I.     

Compact oligomers and nucleosome phasing.

Micrococcal nuclease (EC 3.1.4.7) digestion of histone H1- and H5-depleted chicken erythrocyte chromatin yields, in addition to 140-base-pair (bp) core particles, a series of nucleosome oligomers containing about 260 bp (compact dimer), 380 bp (compact trimer), etc. of DNA. These are postulated to represent members of a class of oligomers in which the DNA is tightly wound on stacked protein cores. The physical properties (melting, circular dichroism) as well as DNase I (EC 3.1.4.5) digestion patterns support this view. DNase I digestion of tight oligomers in which the 5' ends of the DNA have been labeled yields results consistent with this model and inconsistent with some other possible models. Several classes of such particles are postulated to exist, differing in DNA length by 10-bp increments. This may be an explanation of the 10-bp nucleosome "phasing" that has been observed in some nuclei.     

Primary organization of nucleosome core particle of chromatin: sequence of histone arrangement along DNA.

A high-resolution map for the arrangement of histones along DNA in the nucleosome core particle has been determined by a sequencing procedure based on crosslinking histones to the 5'-terminal DNA fragments produced by scission of one DNA strand at the point of crosslinking. The position of histones on DNA has been identified by measuring the length of crosslinked DNA fragments. The results demonstrate that each of the histones is arranged within several adjacent or dispersed DNA segments of a little less than 10 nucleotides in length. Histone-free intervals are located between these segments at the regular distances of about (10)n nucleotides from the 5' end of the DNA and are likely to face one side of the DNA helix. Histones appear to be arranged in a similar manner on both DNA strands and do not form "locks" around DNA. A linearized model of the core particle is proposed.     

Reaction of nucleosome DNA with dimethyl sulfate.

We have measured the effect of the histones in the nucleosome core particle on methylation of purines in nucleosome DNA by dimethyl sulfate. By using 32P terminally labeled nucleosome cores, we have examined the pattern of strand cleavage at methylated sites in the nucleosome DNA and compared it to the pattern observed in histone-free DNA. We are unable to detect any significant difference between the reactivity of N7 of guanines in nucleosome DNA and of that in naked DNA, with the exception of a single site of enhanced reactivity at approximately nucleotide 62 from the 5' end of the nucleosome. Contrary to our expectation, there is no detectable periodic modulation of reactivity corresponding to the twist of the DNA on the nucleosome surface. We are able to place a low upper limit on the extent to which the histones of the nucleosome can protect N7 of guanine in the large groove. With somewhat less precision, we also conclude that the N3 of adenine in the small groove is largely unprotected. These results indicate that in nucleosome DNA the bases are nearly as accessible to solvent as they are in DNA free of protein.     

Archaeal nucleosomes

Archaea contain histones that have primary sequences in common with eukaryal nucleosome core histones and a three-dimensional structure that is essentially only the histone fold. Here we report the results of experiments that document that archaeal histones compact DNA in vivo into structures similar to the structure formed by the histone (H3+H4)₂ tetramer at the center of the eukaryal nucleosome. After formaldehyde cross-linking in vivo, these archaeal nucleosomes have been isolated from Methanobacterium thermoautotrophicum and Methanothermus fervidus, visualized by electron microscopy on plasmid and genomic DNAs, and shown by immunogold labeling, SDS/PAGE, and immunoblotting to contain archaeal histones, cross-linked into tetramers. Archaeal nucleosomes protect ≈60 bp of DNA and multiples of ≈60 bp from micrococcal nuclease digestion, and immunoprecipitation has demonstrated that most, but not all, M. fervidus genomic DNA sequences are associated in vivo with archaeal histones.     

Nucleosome positioning is determined by the (H3-H4)2 tetramer.

It is demonstrated that the histone (H3-H4)2 tetramer can find specific positions on DNA, even in the absence of other histones. Purified histone (H3-H4)2 tetramers were reconstituted onto 208-base-pair (bp) DNA molecules containing a nucleosome-positioning sequence by using salt-gradient dialysis. The stoichiometry of histone tetramer to DNA was shown to be 1:1. Digestion with micrococcal nuclease led to formation of protected DNA fragments of approximately 73 bp. Cleavage of the 73-bp DNA with restriction enzymes produced a small set of defined bands, demonstrating positioning of the (H3-H4)2 tetramer on DNA. Analysis of the restriction digests shows that the 73-bp DNA corresponds mainly to two fragments, one lying on either side of the pseudo-dyad axis of the major position adopted by complete histone octamers on this DNA. This result means that a single (H3-H4)2 histone tetramer can fold approximately 146 bp of DNA with the same positioning as the complete octamer but that a region near the pseudo-dyad is only weakly protected against micrococcal nuclease attack in the absence of histones H2A and H2B.     

Molecular basis of human growth hormone gene deletions.

Crossover sites resulting from unequal recombination within the human growth hormone (GH) gene cluster that cause GH1 gene deletions and isolated GH deficiency type 1A were localized in nine patients. In eight unrelated subjects homozygous for 6.7-kilobase (kb) deletions, the breakpoints are within two blocks of highly homologous DNA sequences that lie 5' and 3' to the GH1 gene. In seven of these eight cases, the breakpoints map within a 1250-base-pair (bp) region composed of 300-bp Alu sequences of 86% homology and flanking non-Alu sequences that are 600 and 300 bp in length and are of 96% and 88% homology, respectively. In the eighth patient, the breakpoints are 5' to these Alu repeats and are most likely within a 700-bp region of 96% homologous DNA sequences. In the ninth patient homozygous for a 7.6-kb deletion, the breakpoints are contained within a 29-bp perfect repeat lying 5' to GH1 and the human chorionic somatomammotropin pseudogene (CSHP1). Together, these results indicate that the presence of highly homologous DNA sequences flanking GH1 predispose to recurrent unequal recombinational events presumably through chromosomal misalignment.     

Nucleotide sequence analysis of the chicken c-myc gene reveals homologous and unique coding regions by comparison with the transforming gene of avian myelocytomatosis virus MC29, delta gag-myc.

Myelocytomatosis virus MC29 is a defective avian retrovirus with a hybrid transforming gene (delta gag-myc) consisting of a 1,358-base pair (bp) sequence from the retroviral gag gene and a 1,568-bp sequence (v-myc) shared with a cellular locus, termed c-myc. We have subjected to sequence analysis 2,735 bp of the cloned c-myc gene, which includes the v-myc-related region of 1,568 bp, an intervening sequence of 971 bp, and unique flanking sequences of 45 bp and 195 bp at the 5' and 3' ends, respectively. Analysis of the genetic information and alignment of the c-myc sequence with the known sequence of MC29 indicates that: (i) the two myc sequences share the same reading frame, including the translational termination signal; (ii) there are nine nucleotide changes between c-myc and v-myc that correspond to seven amino acid changes; (iii) the 971-bp intervening sequence of c-myc can be defined as an intron by consensus splice signals; (iv) the unique 5' sequence of c-myc could either extend its reading frame beyond the homology with v-myc or could be an intron because its junction with the myc region of the locus is a canonical 3' splice-acceptor site; (v) the v-myc contains 10 nucleotides at its 5' end not shared with the c-myc analyzed here and also not with known gag genes, probably derived from an upstream exon; and (vi) the c-myc locus can generate a mRNA whose termination signals have been identified to be located 83 bp and 119 bp from the point of divergence between the v-myc and c-myc. We conclude that the gene of the c-myc locus of the chicken and the onc gene of MC29 share homologous myc regions and differ in unique 5' coding regions and we speculate, on this basis, that their protein products may have different functions. The hybrid onc gene of MC29 must have been generated from the c-myc gene by deletion of the 5' cellular coding sequence, followed by substitution with the 5' region of the viral gag gene.     

Effect of the B--Z transition in poly(dG-m5dC) . poly(dG-m5dC) on nucleosome formation.

We have studied the properties of complexes formed between histones and the methylated synthetic polydeoxynucleotide poly(dG-m5dC). poly(dG-m5dC). This polymer undergoes the transition from B DNA to left-handed Z DNA at moderate ionic strength. When the polymer is in the Z form it will bind histones, but nucleosomes are not detected. When the polymer in the B form is combined with equimolar quantities of the four core histones and digested with micrococcal nuclease, particles are formed which behave in all respects as normal nucleosome cores. When these core particles are placed in solvents that would result in conversion of the protein-free polymer to the Z form, no transition is observed. The formation of a nucleosome core particle thus stabilizes the B form, whereas the presence of the Z form prevents nucleosome formation. The results suggest that if Z DNA is present in eukaryotic nuclei, it will serve to disrupt the normal chromatin structure.     

Artificial nucleosome positioning sequences.

We have used the emerging rules for the sequence dependence of DNA bendability to design and test a series of DNA molecules that incorporate strongly into nucleosomes. Competitive reconstitution experiments showed the superiority in histone octamer binding of DNA molecules in which segments consisting exclusively of A and T or G and C, separated by 2 base pairs (bp), are repeated with a 10-bp period. These repeated (A/T)3NN(G/C)3NN motifs are superior in nucleosome formation to natural positioning sequences and to other repeated motifs such as AANNNTTNNN and GGNNNCCNNN. Studies of different lengths of repetitive anisotropically flexible DNA showed that a segment of approximately 40 bp embedded in a 160-bp fragment is sufficient to generate nucleosome binding equivalent to that of natural nucleosome positioning sequences from 5S RNA genes. Bending requirements along the surface of the nucleosome seem to be quite constant, with no large jumps in binding free energy attributable to protein-induced kinks. The most favorable sequences incorporate into nucleosomes more strongly by 100-fold than bulk nucleosomal DNA, but differential bending free energies are small when normalized to the number of bends: a free energy difference of only about 100 cal/mol per bend (1 cal = 4.184 J) distinguishes the best bending sequences and bulk DNA. We infer that the distortion energy of DNA bending in the nucleosome is only weakly dependent on DNA sequence.     

The [(G/C)3NN]n motif: a common DNA repeat that excludes nucleosomes.

Nucleosomes, the basic structural elements of chromosomes, consist of 146 bp of DNA coiled around an octamer of histone proteins, and their presence can strongly influence gene expression. Considerations of the anisotropic flexibility of nucleotide triplets containing 3 cytosines or guanines suggested that a [5'(G/C)3 NN3']n motif might resist wrapping around a histone octamer. To test this, DNAs were constructed containing a 5'-CCGNN-3' pentanucleotide repeat with the Ns varied. Using in vitro nucleosome reconstitution and electron microscopy, a plasmid with 48 contiguous CCGNN repeats strongly excluded nucleosomes in the repeat region. Competitive reconstitution gel retardation experiments using DNA fragments containing 12, 24, or 48 CCGNN repeats showed that the propensity to exclude nucleosomes increased with the length of the repeat. Analysis showed that a 268-bp DNA containing a (CCGNN)48 block is 4.9 +/- 0.6-fold less efficient in nucleosome assembly than a similar length pUC19 fragment and approximately 78-fold less efficient than a similar length (CTG)n sequence, based on results from previous studies. Computer searches against the GenBank database for matches with a [(G/C)3NN]48 sequence revealed numerous examples that frequently were present in the control regions of "TATA-less" genes, including the human ETS-2 and human dihydrofolate reductase genes. In both cases the (G/C)3NN repeat, present in the promoter region, co-maps with loci previously shown to be nuclease hypersensitive sites.     

Interaction of the bacteriophage P1 recombinase Cre with the recombining site loxP.

The interaction between the P1 recombinase protein Cre and the DNA site at which it acts, loxP, has been studied by using nuclease protection techniques. The region of DNA protected by Cre against nuclease attack by DNase I or neocarzinostatin is a 34-base-pair (bp) region containing two 13-bp inverted repeats separated by an 8-bp spacer region. These protected sequences have previously been shown to be required for efficient Cre-mediated recombination at loxP. The results of the above protection experiments suggest (i) that no more than 34 bp may be required for loxP recombination and (ii) that the asymmetry of loxP recombination is due to the 8-bp spacer sequence. With neocarzinostatin, a specific nucleotide within the 8-bp spacer region is not protected. This nucleotide is located in a 2-bp sequence shown to be involved in a loxP crossover event, suggesting that this region remains exposed after Cre binding. Protection experiments have also been done with loxP sites that have either the left or right inverted repeat deleted. The nuclease protection pattern of these sites reveals that each loxP site consists of two binding domains for Cre, each being composed of one 13-bp inverted repeat and the contiguous 4 bp of the 8-bp spacer region.     

sigma, a repetitive element found adjacent to tRNA genes of yeast.

sigma is a DNA element of about 340 base pairs (bp) that is repeated many times in the yeast genome. The element has 8-bp inverted repeats at its ends and is flanked by 5-bp direct repeats. The 5-bp repeats are different for each sigma and have no homology with the ends of the sigma sequence. sigma is located 16 or 18 bp from the 5' end of several tRNA genes. Southern analysis of different yeast strains shows that the pattern of hybridization is different even for closely related strains.     

Mechanical disruption of individual nucleosomes reveals a reversible multistage release of DNA

The dynamic structure of individual nucleosomes was examined by stretching nucleosomal arrays with a feedback-enhanced optical trap. Forced disassembly of each nucleosome occurred in three stages. Analysis of the data using a simple worm-like chain model yields 76 bp of DNA released from the histone core at low stretching force. Subsequently, 80 bp are released at higher forces in two stages: full extension of DNA with histones bound, followed by detachment of histones. When arrays were relaxed before the dissociated state was reached, nucleosomes were able to reassemble and to repeat the disassembly process. The kinetic parameters for nucleosome disassembly also have been determined.