两种模式生物核小体定位比较研究

在对两种模式生物酵母与果蝇胚胎期核小体定位进行研究时,发现不同物种间以及同一物种中不同表达模式基因上的核小体分布呈现出差显著异性。在总体上,转录起始位点附近的酵母核小体NFR区域比果蝇的NFR短。经基因中心对齐后,酵母与果蝇胚胎期沉默型基因的核小体缺失区域的两个边界中间处共同呈现了一个明确有着均匀间隔的核小体数n,且随着基因长度L的变长其周期性特性逐渐变模糊,但果蝇的图谱表现的更为复杂。结果表明,从单细胞酵母生物到多细胞果蝇生物间基因组的进化过程中,核小体组织的演化既有变异性,也具有保守性。     

High‐resolution analysis of DNA synthesis start sites and nucleosome architecture at efficient mammalian replication origins

DNA replication origins are poorly characterized genomic regions that are essential to recruit and position the initiation complex to start DNA synthesis. Despite the lack of specific replicator sequences, initiation of replication does not occur at random sites in the mammalian genome. This has lead to the view that DNA accessibility could be a major determinant of mammalian origins. Here, we performed a high‐resolution analysis of nucleosome architecture and initiation sites along several origins of different genomic location and firing efficiencies. We found that mammalian origins are highly variable in nucleosome conformation and initiation patterns. Strikingly, initiation sites at efficient CpG island‐associated origins always occur at positions of high‐nucleosome occupancy. Origin recognition complex (ORC) binding sites, however, occur at adjacent but distinct positions marked by labile nucleosomes. We also found that initiation profiles mirror nucleosome architecture, both at endogenous origins and at a transgene in a heterologous system. Our studies provide a unique insight into the relationship between chromatin structure and initiation sites in the mammalian genome that has direct implications for how the replication programme can be accommodated to diverse epigenetic scenarios.     

Sperm-derived histones contribute to zygotic chromatin in humans

Background

about 15% to 30% of the DNA in human sperm is packed in nucleosomes and transmission of this fraction to the embryo potentially serves as a mechanism to facilitate paternal epigenetic programs during embryonic development. However, hitherto it has not been established whether these nucleosomes are removed like the protamines or indeed contribute to paternal zygotic chromatin, thereby potentially contributing to the epigenome of the embryo.

Results

to clarify the fate of sperm-derived nucleosomes we have used the deposition characteristics of histone H3 variants from which follows that H3 replication variants present in zygotic paternal chromatin prior to S-phase originate from sperm. We have performed heterologous ICSI by injecting human sperm into mouse oocytes. Probing these zygotes with an antibody highly specific for the H3.1/H3.2 replication variants showed a clear signal in the decondensed human sperm chromatin prior to S-phase. In addition, staining of human multipronuclear zygotes also showed the H3.1/H3.2 replication variants in paternal chromatin prior to DNA replication.

Conclusion

these findings reveal that sperm-derived nucleosomal chromatin contributes to paternal zygotic chromatin, potentially serving as a template for replication, when epigenetic information can be copied. Hence, the execution of epigenetic programs originating from transmitted paternal chromatin during subsequent embryonic development is a logical consequence of this observation.     

Nucleosome structure and repair of N-methylpurines in the GAL1-10 genes of Saccharomyces cerevisiae

Nucleosome structure and repair of N-methylpurines were analyzed at nucleotide resolution in the divergent GAL1-10 genes of intact yeast cells, encompassing their common upstream-activating sequence. In glucose cultures where genes are repressed, nucleosomes with fixed positions exist in regions adjacent to the upstream-activating sequence, and the variability of nucleosome positioning sharply increases with increasing distance from this sequence. Galactose induction causes nucleosome disruption throughout the region analyzed, with those nucleosomes close to the upstream-activating sequence being most striking. In glucose cultures, a strong correlation between N-methylpurine repair and nucleosome positioning was seen in nucleosomes with fixed positions, where slow and fast repair occurred in nucleosome core and linker DNA, respectively. Galactose induction enhanced N-methylpurine repair in both strands of nucleosome core DNA, being most dramatic in the clearly disrupted, fixed nucleosomes. Furthermore, N-methylpurines are repaired primarily by the Mag1-initiated base excision repair pathway, and nucleotide excision repair contributes little to repair of these lesions. Finally, N-methylpurine repair is significantly affected by nearest-neighbor nucleotides, where fast and slow repair occurred in sites between pyrimidines and purines, respectively. These results indicate that nucleosome positioning and DNA sequence significantly modulate Mag1-initiated base excision repair in intact yeast cells.     

A phase relationship associates tRNA structural gene sequences with nucleosome cores

DNA (760 bp) isolated from nucleosome tetramers of staphylococcal nuclease-digested chicken embryo chromatin was highly enriched for tRNA genes and subsequently cloned in E. coli chi 1776. The location of genes coding for chicken embryo tRNALys, tRNAPhe and tRNAiMet within the cloned nucleosome tetramer DNA was determined using restriction endonucleases for which single cleavage sites could be predicted from the respective tRNA base sequence. All our tRNA genes reside nonrandomly at four locations on nucleosome tetramer DNA. The spacing between the tRNA gene locations is approximately 190 bp, similar to the DNA repeat length of chicken embryo chromatin. The four tRNA gene locations were also defined in noncloned nucleosome tetramer DNA highly enriched for tRNA genes. The majority of genes coding for tRNALys, tRNAPhe and tRNAiMet, respectively, are located in equal proportion 40-45, 230, 420 and 610 bp distant from the 5' end of the tRNA-identical strand. Thus the tRNA structural gene sequences all appear to begin about 20 bp "inside" the nucleosome core. As observed with nucleosomal DNA not enriched for tRNA genes, the phase relationship between tRNA genes and nucleosome location is maintained over a distance of 4-6 subsequent nucleosomes. A cloned molecule of nucleosomal DNA containing both a tRNALys gene and a tRNAiMet gene in the same polarity reveals that a phase adjustment might be necessary for the nucleosomes between these two tRNA genes in chicken embryo chromatin.     

Nucleosome positioning signals in the DNA sequence of the human and mouse H19 imprinting control regions

We have investigated the sequences of the mouse and human H19 imprinting control regions (ICRs) to see whether they contain nucleosome positioning information pertinent to their function as a methylation-regulated chromatin boundary. Positioning signals were identified by an in vitro approach that employs reconstituted chromatin to comprehensively describe the contribution of the DNA to the most basic, underlying level of chromatin structure. Signals in the DNA sequence of both ICRs directed nucleosomes to flank and encompass the short conserved sequences that constitute the binding sites for the zinc finger protein CTCF, an essential mediator of insulator activity. The repeat structure of the human ICR presented a conserved array of strong positioning signals that would preferentially flank these CTCF binding sites with positioned nucleosomes, a chromatin structure that would tend to maintain their accessibility. Conversely, all four CTCF binding sites in the mouse sequence were located close to the centre of positioning signals that were stronger than those in their flanks; these binding sites might therefore be expected to be more readily incorporated into positioned nucleosomes. We found that CpG methylation did not effect widespread repositioning of nucleosomes on either ICR, indicating that allelic methylation patterns were unlikely to establish allele-specific chromatin structures for H19 by operating directly upon the underlying DNA-histone interactions; instead, epigenetic modulation of ICR chromatin structure is likely to be mediated principally at higher levels of control. DNA methylation did, however, both promote and inhibit nucleosome positioning at several sites in both ICRs and substantially negated one of the strongest nucleosome positioning signals in the human sequence, observations that underline the fact that this epigenetic modification can, nevertheless, directly and decisively modulate core histone-DNA interactions within the nucleosome.