ATP依赖的染色质改构复合物及其作用机制

染色质高度紧密的折叠阻止了转录因子和辅因子与DNA的结合, 因而通过染色质重塑以解除这样的抑制环境, 对于转录活动的正常进行是至关重要的。目前认为, 染色质重塑至少是通过两种机制来完成的, 一种是通过ATP依赖的染色质改构复合物, 另一种是通过对组蛋白尾部进行共价修饰的组蛋白修饰酶复合物。文章结合近年来的研究进展, 对前者进行染色质重塑的机制及两者在基因转录调控过程中如何相互协作等进行了论述。     

CHD7对发育和疾病的表观遗传调控研究进展

染色质重塑是指染色质通过其结构的动态变化影响基因组DNA的可接近性,进而影响DNA复制、转录、修复和重组的过程,属于表观遗传调控。染色质域解旋酶DNA结合蛋白7(CHD7)是一种ATP依赖的染色质重塑酶,能够调控发育过程中多种重要转录因子,广泛参与众多生理过程。本文对CHD7在发育和疾病当中的表观遗传调控作用进行简要概述。     

Genetic and Physical Analysis of the M26 Recombination Hotspot of Schizosaccharomyces Pombe

The ade6-M26 mutation of Schizosaccharomyces pombe has previously been reported to stimulate ade6 intragenic meiotic recombination. We report here that the ade6-M26 mutation is a single G----T nucleotide change, that M26 stimulated recombination within ade6 but not at other distinct loci, and that M26 stimulated meiotic but not mitotic recombination. In addition, M26 stimulated recombination within ade6 when M26 is homozygous; this result demonstrates that a base-pair mismatch at the M26 site was not required for the stimulation. These results are consistent with the ade6-M26 mutation creating a meiotic recombination initiation site.     

Natural meiotic recombination hot spots in the Schizosaccharomyces pombe genome successfully predicted from the simple sequence motif M26

The M26 hot spot of meiotic recombination in Schizosaccharomyces pombe is the eukaryotic hot spot most thoroughly investigated at the nucleotide level. The minimum sequence required for M26 activity was previously determined to be 5'-ATGACGT-3'. Originally identified by a mutant allele, ade6-M26, the M26 heptamer sequence occurs in the wild-type S. pombe genome approximately 300 times, but it has been unclear whether any of these are active hot spots. Recently, we showed that the M26 heptamer forms part of a larger consensus sequence, which is significantly more active than the heptamer alone. We used this expanded sequence as a guide to identify a smaller number of sites most likely to be active hot spots. Ten of the 15 sites tested showed meiotic DNA breaks, a hallmark of recombination hot spots, within 1 kb of the M26 sequence. Among those 10 sites, one occurred within a gene, cds1(+), and hot spot activity of this site was confirmed genetically. These results are, to our knowledge, the first demonstration in any organism of a simple, defined nucleotide sequence accurately predicting the locations of natural meiotic recombination hot spots. M26 may be the first example among a diverse group of simple sequences that determine the distribution, and hence predictability, of meiotic recombination hot spots in eukaryotic genomes.     

Active and Inactive Transplacement of the M26 Recombination Hotspot in Schizosaccharomyces Pombe

The ade6-M26 mutation of the fission yeast Schizosaccharomyces pombe creates a meiotic recombination hotspot that elevates ade6 intragenic recombination ~10-15-fold. A heptanucleotide sequence including the M26 point mutation is required but not sufficient for hotspot activity. We studied the effects of plasmid and chromosomal context on M26 hotspot activity. The M26 hotspot was inactive on a multicopy plasmid containing M26 embedded within 3.0 or 5.9 kb of ade6 DNA. Random S. pombe genomic fragments totaling ~7 Mb did not activate the M26 hotspot on a plasmid. M26 hotspot activity was maintained when 3.0-, 4.4-, and 5.9-kb ade6-M26 DNA fragments, with various amounts of non-S. pombe plasmid DNA, were integrated at the ura4 chromosomal locus, but only in certain configurations relative to the ura4 gene and the cointegrated plasmid DNA. Several integrations created new M26-independent recombination hotspots. In all cases the non-ade6 DNA was located >1 kb from the M26 site, and in some cases >2 kb. Because the chromosomal context effect was transmitted over large distances, and did not appear to be mediated by a single discrete DNA sequence element, we infer that the local chromatin structure has a pronounced effect on M26 hotspot activity.     

抗原受体基因重组的表观遗传学调控研究新进展

淋巴细胞是哺乳动物唯一能发生体细胞基因组变化的一类细胞,淋巴细胞在发育过程中通过V(D)J重组获得成熟的特异的抗原受体基因,实现了免疫细胞抗原识别惊人的多样性.关于V(D)J重组的调控机制一直是免疫学研究的重要问题,然而直到将表观遗传学研究引入这一领域,综合遗传学和表观遗传学的研究才真正揭示V(D)J重组精细的调控机制.综述了新近发现的V(D)J重组过程中重要的表观遗传学调控机制,如CpG甲基化,组蛋白修饰,核小体重塑及核拓扑学变化.