盐离子作用下组蛋白变体H2A.Z增强核小体结构的稳定性

真核生物染色质的基本结构组成单元是核小体,基因组DNA被压缩在染色质中,核小体的存在通常会抑制转录、复制、修复和重组等发生在DNA模板上的生物学过程。组蛋白变体H2A.Z可以调控染色质结构进而影响基因的转录过程,但其详细的调控机制仍未研究清楚。为了比较含有组蛋白变体H2A.Z的核小体和常规核小体在盐离子作用下的稳定性差异,本文采用Förster共振能量转移的方法检测氯化钠、氯化钾、氯化锰、氯化钙、氯化镁等离子对核小体的解聚影响。实验对Widom 601 DNA序列进行双荧光Cy3和Cy5标记,通过荧光信号值的变化来反映核小体的解聚变化。Förster共振能量转移检测结果显示:在氯化钠、氯化钾、氯化锰、氯化钙和氯化镁作用下,含有组蛋白变体H2A.Z的核小体解聚速度相比于常规核小体要慢,且氯化钙、氯化锰和氯化镁的影响更明显。电泳分析结果表明,在75℃条件下含有组蛋白变体H2A.Z的核小体的解聚速率明显低于常规核小体。采用荧光热漂移检测(fluorescence thermal shift analysis , FTS)进一步分析含有组蛋白变体H2A.Z核小体的稳定性,发现两类核小体的荧光信号均呈现2个明显的增长期,含有组蛋白变体H2A.Z核小体的第1个荧光信号增速期所对应的温度明显高于常规核小体,表明核小体中H2A.Z/H2B二聚体的解聚变性温度要高于常规的H2A/H2B二聚体,含有组蛋白变体H2A.Z核小体的热稳定性高。研究结果均表明,含有组蛋白变体H2A.Z的核小体的结构比常规核小体的结构稳定。     

技术与方法体外组装含有组蛋白变体H2A.Z及H3.3的核小体

核小体是构成真核生物染色质的基本结构单位,组蛋白变体H2A.Z及H3.3对染色质结构及基因转录过程发挥着重要的调控作用。体内研究核小体及染色质结构受到诸多因素限制,体外重构含有H2A.Z及H3.3的核小体结构是研究与组蛋白变体相关基因表达调控的重要方法之一。实验表达纯化了6种组蛋白,在复性的过程中装配了含有H2A.Z和H3.3的组蛋白八聚体。基于DNA序列10bp周期性及序列模体设计了3条易于形成核小体的DNA序列,通过PCR大量扩增的方法,回收了标记Cy3荧光分子的目的DNA序列。采用盐透析法体外组装了含有H2A.Z和H3.3的核小体结构,利用荧光标记、EB染色及考马斯亮蓝染色检测了含有组蛋白变体的核小体形成效率及形成过程的吉布斯自由能变化。结果发现,设计的3条DNA序列可以有效地组装形成含有组蛋白电梯的核小体结构,而且随着组蛋白八聚体与DNA比例的增加,核小体的形成效率显著提高;采用Cy3荧光标记可以灵敏且定量地计算组装过程的吉布斯自由能。该方法的建立对研究组蛋白变体相关的结构生物学及转录调控等具有一定的意义。     

体外组装含有组蛋白变体H2A.Z及H3.3的核小体

核小体是构成真核生物染色质的基本结构单位,组蛋白变体H2A.Z及H3.3对染色质结构及基因转录过程发挥着重要的调控作用。体内研究核小体及染色质结构受到诸多因素限制,体外重构含有H2A.Z及H3.3的核小体结构是研究与组蛋白变体相关基因表达调控的重要方法之一。实验表达纯化了6种组蛋白,在复性的过程中装配了含有H2A.Z和H3.3的组蛋白八聚体。基于DNA序列10bp周期性及序列模体设计了3条易于形成核小体的DNA序列,通过PCR大量扩增的方法,回收了标记Cy3荧光分子的目的 DNA序列。采用盐透析法体外组装了含有H2A.Z和H3.3的核小体结构,利用荧光标记、EB染色及考马斯亮蓝染色检测了含有组蛋白变体的核小体形成效率及形成过程的吉布斯自由能变化。结果发现,设计的3条DNA序列可以有效地组装形成含有组蛋白电梯的核小体结构,而且随着组蛋白八聚体与DNA比例的增加,核小体的形成效率显著提高;采用Cy3荧光标记可以灵敏且定量地计算组装过程的吉布斯自由能。该方法的建立对研究组蛋白变体相关的结构生物学及转录调控等具有一定的意义。     

基于DNA变形能的核小体定位预测方法研究进展

真核细胞中,作为染色质基本结构单元的核小体参与调控基因的转录、DNA复制、重组以及RNA剪接等诸多生物学过程。阐明核小体定位机制并准确预测核小体在染色体上的位置对解读染色质结构与功能有重要生物学意义。在过去30多年时间里,研究人员发展了多种预测核小体位置的方法。最理想的方法应考虑DNA序列、组蛋白修饰和染色质重塑等影响核小体定位的诸多因素,然而现实中,捕捉主要因素的模型也往往具有很高的鲁棒性和实用价值。DNA序列偏好性是在全基因组尺度上影响核小体定位的最重要因素之一,因此基于DNA序列的核小体定位预测方法也最常见。这种方法可大致分为两类,即基于DNA序列信息的生物信息学模型和基于DNA变形能的生物物理学模型。本文重点介绍生物物理学模型近些年取得的主要进展。     

基于核小体位置预测的酵母进化印迹研究

在利用核小体定位实验数据训练支持向量机(SVM)对任意酵母DNA序列的核小体形成能力进行预测的过程中,发现染色质结构对基因组DNA分子进化过程有着显著影响。我们观察到核小体DNA比连接DNA的平均预测准确率低15%,这种普遍存在的局部预测准确率差异性代表了酵母核小体定位的进化印迹(Evolutionary footprint),它揭示了核小体组织在基因组的整个进化过程中所具有的保守性。     

鸭呼肠孤病毒强毒株致鸭胚原代成纤维细胞凋亡的研究

通过光镜、电镜、DNA Ladder法、流式细胞术、荧光染色对鸭呼肠孤病毒(DRV)诱导鸭胚原代成纤维细胞(DEF)凋亡情况进行检测.结果显示,光镜可见细胞形态学上出现细胞皱缩,染色质浓染边移;电镜观察到细胞胞浆浓缩,细胞核染色质凝聚、部分形成凋亡小体;荧光染色结果显示,在感染后24h有激发绿色荧光的凋亡细胞出现,随着时间的推移,激发红色荧光的死亡细胞数量增多;DNA Ladder检测到感染后24～144h的DNA样品呈梯形条带;流式细胞术于感染后24h检测到凋亡细胞,其数量在72～96h达到高峰,144h开始下降.研究结果表明,DRV在DEF增殖的过程中具有诱导宿主细胞凋亡的作用.     

染色质重塑与肌肉分化

在真核生物中,基因组DNA是以染色质的状态存在和发挥作用的。目前的研究已经鉴定了多种可以调节染色质结构和功能的蛋白质和酶复合物,包括不依赖ATP的染色质修饰酶、依赖于ATP的染色质重塑复合物,以及募集DNA甲基化／去甲基化装置的核小体相关蛋白质复合物等。在骨骼肌分化过程中,MyoD家族和MEF2家族的转录因子起着重要作用。染色质修饰酶通过MyoD和MEF2介导的染色质重塑影响肌肉分化。     

非细胞体系核重建并非必需核小体与染色质的装配

以质粒DNA在爪蟾卵提取物S- 1 5 0中进行核小体构建时形成的超螺旋结构检测核小体的形成 ;利用阳离子交换剂CM -Cellulose定量结合组蛋白H2A和H2B ;并结合小球菌核酸酶分析核小体的形成 ,研究了爪蟾去膜精子在去除H2A ,H2B的S- 1 5 0中的核重建过程 .结果表明CM -Cellulose可有效去除组蛋白并阻止质粒DNA的核小体构建和精子染色质的改建 .但处理后的S- 1 5 0与膜泡组分仍可诱导去膜精子进行体外核重建 ,进一步表明非细胞体系核重建与外源DNA长度无关 ;核小体及染色质的组装对于核重建并非必需 .     

体外装配核小体过程组蛋白浓度依赖的动力学模型

为探索组蛋白浓度对核小体体外装配的影响,本研究表达纯化了4种组蛋白,通过控制实验反应体系中组蛋白的浓度,利用盐透析法在体外装配了核小体,检测分析了组蛋白浓度与核小体组装效率的关系。以此实验数据为基础,提出了核小体组装过程组蛋白浓度依赖性的动力学模型。实验结果发现,反应体系中组蛋白浓度与核小体生成量呈典型的线性关系。依据动力学理论模型,进行线性回归拟合,回归系数达到0.963;经计算601 DNA序列组装核小体的反应速率常数k为1.49×10^-5mL·h·μg^-1。CS1序列验证动力学模型的线性回归相关系数为0.989,反应速率常数为1.52×10^-5mL·h·μg^-1。该实验方法及动力学模型中反应速率常数k可用于评价相同长度的DNA序列组装核小体的能力、组蛋白与其突变体以及组蛋白变体之间形成核小体结构能力的差异。该动力学模型的建立为理解核小体装配、核小体定位、染色质结构等相关问题提供了理论指导。     

核小体及染色质修饰的基因组分布模式和染色质状态

染色质是真核DNA的存在方式,可以通过影响DNA的可及性调节基因转录,其基本单元为核小体,系由约147 bp的DNA缠绕在组蛋白八联体上形成的结构,核小体之间以连接DNA相连．核小体组蛋白上能发生甲基化和乙酰化等化学修饰．核小体位置、DNA的甲基化和组蛋白的修饰等对染色质状态(常染色质或异染色质)及基因组之间的长程相互作用有重要影响．近年,基于高通量测序技术,核小体位置和染色质修饰在多种细胞中的基因组分布已被测定．结果显示,这些标记的分布模式具有位点特异、动态变化、相互偶联和高度复杂的特征．本文详细回顾并评述了核小体位置和染色质修饰的分布模式、对应生物学功能、修饰之间的关联、实验测定技术、染色质状态的计算分析等内容．该工作对于深入认识和理解染色质的表观遗传调节机制有重要意义．     

Stability of nucleosome placement in newly repaired regions of DNA

Rearrangements of chromatin structure during excision repair of UV-damaged DNA appear to involve unfolding of nucleosomal DNA while repair is taking place, followed by refolding of this DNA into a native nucleosome structure. Recently, we found that repair patches are not distributed uniformly along the DNA in nucleosome core particles immediately following their refolding into nucleosomes (Lan, S. Y., and Smerdon, M. J. (1985) Biochemistry, 24,7771). Therefore, the distribution of repair patches in nucleosome core DNA was used to monitor the stability of nucleosome placement in these regions. Our results indicate that in nondividing human cells undergoing excision repair there is a slow change in the positioning of nucleosomes in newly repaired regions of chromatin, resulting in the eventual randomization of repair patches in nucleosome core DNA. Furthermore, the nonrandom placement of nucleosomes observed just after the refolding event is not re-established during DNA replication. Possible mechanisms for this change in nucleosome placement along the DNA are discussed.     

Development of a fluorescent probe for the study of nucleosome assembly and dynamics

To develop a probe for use in real-time dynamic studies of nucleosomes, core histones (from Drosophila) were conjugated to a DNA-intercalating dye, thiazole orange, by a reaction targeting Cys 110 of histone H3. In the absence of DNA, the conjugated histones are only very weakly fluorescent. However, upon reconstitution into nucleosomes by standard salt dialysis procedures, the probe fluoresces strongly, reflecting its ability to intercalate into the nucleosomal DNA. The probe is also sensitive to the nature of the DNA-histone interaction. Nucleosomes reconstituted by stepwise salt dialysis give a fluorescence signal quite different from that of the species formed when DNA and histones are simply mixed in low salt. In addition, changing either the DNA length or the type of sequence (nucleosome positioning sequences versus random DNA of the same size) used in the reconstitution alters the resulting fluorescence yield. The results are all consistent with the conclusion that a more rigid, less flexible nucleosome structure results in less fluorescence than a looser structure, presumably due to structural constraints on dye intercalation. This probe should be well suited to analyzing nucleosome dynamics and to following factor-mediated assembly and remodeling of nucleosomes in real time, particularly at the single-molecule level.     

Quantitative analysis of single-molecule force spectroscopy on folded chromatin fibers

Single-molecule techniques allow for picoNewton manipulation and nanometer accuracy measurements of single chromatin fibers. However, the complexity of the data, the heterogeneity of the composition of individual fibers and the relatively large fluctuations in extension of the fibers complicate a structural interpretation of such force-extension curves. Here we introduce a statistical mechanics model that quantitatively describes the extension of individual fibers in response to force on a per nucleosome basis. Four nucleosome conformations can be distinguished when pulling a chromatin fiber apart. A novel, transient conformation is introduced that coexists with single wrapped nucleosomes between 3 and 7 pN. Comparison of force-extension curves between single nucleosomes and chromatin fibers shows that embedding nucleosomes in a fiber stabilizes the nucleosome by 10 k_BT. Chromatin fibers with 20- and 50-bp linker DNA follow a different unfolding pathway. These results have implications for accessibility of DNA in fully folded and partially unwrapped chromatin fibers and are vital for understanding force unfolding experiments on nucleosome arrays.     

Characterization and applications of CataCleave probe in real-time detection assays

Cycling probe technology (CPT), which utilizes a chimeric DNA-RNA-DNA probe and RNase H, is a rapid, isothermal probe amplification system for the detection of target DNA. Upon hybridization of the probe to its target DNA, RNase H cleaves the RNA portion of the DNA/RNA hybrid. Utilizing CPT, we designed a catalytically cleavable fluorescence probe (CataCleave probe) containing two internal fluorophores. Fluorescence intensity of the probe itself was weak due to F?rster resonance energy transfer. Cleavage of the probe by RNase H in the presence of its target DNA caused enhancement of donor fluorescence, but this was not observed with nonspecific target DNA. Further, RNase H reactions with CataCleave probe exhibit a catalytic dose-dependent response to target DNA. This confirms the capability for the direct detection of specific target DNA through a signal amplification process. Moreover, CataCleave probe is also ideal for detecting DNA amplification processes, such as polymerase chain reaction (PCR) and isothermal rolling circle amplification (RCA). In fact, we observed signal enhancement proportional to the amount of RCA product formed. We were also able to monitor real-time PCR by measuring enhancement of donor fluorescence. Hence, CataCleave probe is useful for real-time monitoring of both isothermal and temperature-cycling nucleic acid amplification methods.     

DNA hybridization detection in a microfluidic channel using two fluorescently labelled nucleic acid probes

A conceptually new technique for fast DNA detection has been developed. Here, we report a fast and sensitive online fluorescence resonance energy transfer (FRET) detection technique for label-free target DNA. This method is based on changes in the FRET signal resulting from the sequence-specific hybridization between two fluorescently labelled nucleic acid probes and target DNA in a PDMS microfluidic channel. Confocal laser-induced microscopy has been used for the detection of fluorescence signal changes. In the present study, DNA hybridizations could be detected without PCR amplification because the sensitivity of confocal laser-induced fluorescence detection is very high. Two probe DNA oligomers (5'-CTGAT TAGAG AGAGAA-TAMRA-3' and 5'-TET-ATGTC TGAGC TGCAGG-3') and target DNA (3'-GACTA ATCTC TCTCT TACAG GCACT ACAGA CTCGA CGTCC-5') were introduced into the channel by a microsyringe pump, and they were efficiently mixed by passing through the alligator teeth-shaped PDMS microfluidic channel. Here, the nucleic acid probes were terminally labelled with the fluorescent dyes, tetrafluororescein (TET) and tetramethyl-6-carboxyrhodamine (TAMRA), respectively. According to our confocal fluorescence measurements, the limit of detection of the target DNA is estimated to be 1.0 x 10(-6) to 1.0 x 10(-7)M. Our result demonstrates that this analytical technique is a promising diagnostic tool that can be applied to the real-time analysis of DNA targets in the solution phase.     

Stepwise unfolding of chromatin by urea. A flow linear dichroism and photoaffinity labeling study

The unfolding of chromatin by urea (0-7 M) was studied by means of flow linear dichroism, photoaffinity labeling and nuclease digestion. The linear dichroism results indicate that the unfolding of the DNA is accomplished through two distinct transitions at 1-2 M urea and 6-8 M urea, respectively. The photoaffinity labeling studies indicate that an opening of the nucleosome histone core occurs above 2 M urea, accompanied by general loosening of the structure. Based on the results a model for the unfolding of chromatin fibers by urea is proposed, which includes a stretching of the linker DNA (0-2 M urea) followed by a "loosening" of the nucleosome core, possibly to a one-loop DNA conformation (2-6 M urea), and finally resulting in an almost total stretching of the DNA (greater than 6 M urea).