On the occurrence of nucleosome phasing in chromatin.

We have found that DNAase I digestion of yeast, HeLa and chicken erythrocyte nuclei produces a pattern of DNA fragments spaced 10 bases apart and extending to at least 300 bases. This "extended ladder" of DNA fragments is most clearly seen with yeast, and least clearly with chicken erythrocytes. The appearance of regular and discrete bands at sizes much larger than the repeat size shows that the core particles (140 bp of DNA + H2A, H2B, H3 H4) in at least some fraction of chromatin are spaced in a particular fashion, by discrete lengths of spacer DNA, and not randomly. Based on the abundance of small repeats in yeast and from experiments with nucleosome oligomers, we conclude that the extended ladder and nucleosomal phasing probably arise mainly from regions in the chromatin in which nucleosome cores are closely packed or closely spaced (140-160 bp X n). Contributions from less closely packed but still accurately phased nucleosomes, however, cannot be entirely excluded.     

Nucleosome structure in Aspergillus nidulans

The structure of chromatin from Aspergillus nidulans was studied using micrococcal nuclease and DNAase I. Limited digestion with micrococcal nuclease revealed a nucleosomal repeat of 154 base pairs for Aspergillus and 198 base pairs for rat liver. With more extensive digestion, both types of chromatin gave a similar quasi-limit product with a prominent fragment at 140 base pairs. The similarity of the two limit digests suggests that the structure of the 140 base pair nucleosome core is conserved. This implies that the difference in nucleosome repeat lengths between Aspergillus and rat liver is caused by a difference in the length of the DNA between two nucleosome cores. Digestion of Aspergillus chromatin with DNAase I produced a pattern of single-stranded fragments at intervals of 10 bases which was similar to that produced from rat liver chromatin.     

A partial characterization of DNA fragments protected from nuclease degradation in histone depleted metaphase chromosomes of the Chinese hamster.

A small proportion (0.1-0.5%) of the total DNA content of native Chinese hamster metaphase chromosomes is protected from nucleolytic degradation following the removal of histones by extraction with either 0.2 N HCl or 2 M NaCl, and remains attached to the nonhistone protein core. Acid extraction followed by DNase I digestion leads to small fragments of 10-30 bases. Salt extraction followed by micrococcal nuclease digestion gives approx. 140 b.p. fragments which are undistinguishable in size from nucleosome core DNA fragments. Furthermore, DNase I treatment of salt extracted chromosomes gives DNA fragments containing single strands which are multiples of 10 bases in length, again characteristic of the nucleosome structure. Reassociation kinetics using the 32P-labelled 140 b.p. fragments as probes suggests they are enriched for rapidly reassociating sequences.     

Simple repeated sequences in human satellite DNA.

In an extensive analysis, using a range of restriction endonucleases, HinfI and TaqI were found to differentiate satellites I, II and III & IV. Satellite I is resistant to digestion by TaqI, but is cleaved by HinfI to yield three major fragments of approximate size 770, 850 and 950bp, associated in a single length of DNA. The 770bp fragment contains recognition sites for a number of other enzymes, whereas the 850 and 950bp fragments are "silent" by restriction enzyme analysis. Satellite II is digested by HinfI into a large number of very small (10-80bp) fragments, many of which also contain TaqI sites. A proportion of the HinfI sites in satellite II have the sequence 5'GA(GC)TC. The HinfI digestion products of satellites III and IV form a complete ladder, stretching from 15bp or less to more than 250bp, with adjacent multimers separated by an increment of 5bp. The ladder fragments do not contain TaqI sites and all HinfI sites have the sequence 5'GA(AT)TC. Three fragments from the HinfI ladder of satellite III have been sequenced, and all consist of a tandemly repeated 5bp sequence, 5'TTCCA, with a non-repeated, G+C rich sequence, 9bp in length, at the 3' end.     

Self-assembly of single and closely spaced nucleosome core particles.

Self-assembly of DNA with the four core histones but in the absence of H1 generates nucleosome core particles which are spaced randomly over large distances. Closely spaced core particles, however, exhibit a preferred short linkage which is not a multiple of 10 base pairs. They bind about 140 base pairs whereas apparently shorter DNA lengths per nucleosome observed after digestion with micrococcal nuclease are the result of degradation from the ends. The DNA length of one superhelical turn in the core particle is 83 +/- 4 base pairs. Single core particles may bind more DNA than closely spaced core particles but probably less than two full turns of 168 base pairs. The internal structures of single and of native core particles are very similar as judged by their amount of DNA, sedimentation coefficient, appearance in the electron microscope, and digestion with DNase I. In addition to core particles, a particle is described which sediments at 9 S and consists of 108 base pairs of DNA bound to the histone octamer. It appears to be the smallest stable "core particle" but it is not a degradation product of the 146-base-pair core particle. Digestion of end-labeled 9 S and nucleosome core particles with DNase I shows distinct differences.     

A nonuniform distribution of excision repair synthesis in nucleosome core DNA

We have investigated the distribution in nucleosome core DNA of nucleotides incorporated by excision repair synthesis occurring immediately after UV irradiation in human cells. We show that the differences previously observed for whole nuclei between the DNase I digestion profiles of repaired DNA (following its refolding into a nucleosome structure) and bulk DNA are obtained for isolated nucleosome core particles. Analysis of the differences obtained indicates that they could reflect a significant difference in the level of repair-incorporated nucleotides at different sites within the core DNA region. To test this possibility directly, we have used exonuclease III digestion of very homogeneous sized core particle DNA to "map" the distribution of repair synthesis in these regions. Our results indicate that in a significant fraction of the nucleosomes the 5' and 3' ends of the core DNA are markedly enhanced in repair-incorporated nucleotides relative to the central region of the core particle. A best fit analysis indicates that a good approximation of the data is obtained for a distribution where the core DNA is uniformly labeled from the 5' end to position 62 and from position 114 to the 3' end, with the 52-base central region being devoid of repair-incorporated nucleotides. This distribution accounts for all of the quantitative differences observed previously between repaired DNA and bulk DNA following the rapid phase of nucleosome rearrangement when it is assumed that linker DNA and the core DNA ends are repaired with equal efficiency and the nucleosome structure of newly repaired DNA is identical with that of bulk chromatin. Furthermore, the 52-base central region that is devoid of repair synthesis contains the lowest frequency cutting sites for DNase I in vitro, as well as the only "internal" locations where two (rather than one) histones interact with a 10-base segment of each DNA strand.     

DNA associated with nucleosomes in plants.

50 to 55% of tobacco and barley nuclear DNA is accessible to micrococcal endonuclease digestion. The DNA fragments resulting from a mild endonuclease treatment are multiples of a basic unit of 194 +/- 6 base pairs in tobacco and 195 +/- 6 base pairs in barley. After extensive digestion, a DNA fragment of approximately 140 base pairs is predominant. Hence the "extra-core" or "linker"-DNA is 55 base pairs long. Other fragments having 158 and less than 140 base pairs are present as well. Treatment with DNase I results in multiples of 10 bases when analysed under denaturating conditions. These results show that the general organization of the DNA within the nucleosomes is about the same in higher plants as in other higher eukaryotes.     

Deletion analysis of a DNA sequence that positions itself precisely on the nucleosome core

Exonuclease III digests DNA sequentially from the 3' end. This enzyme is used to analyse the location of nucleosomes on DNA fragments containing a particular 145 base-pair (bp) sequence. When one of these fragments is assembled into chromatin and digested with exonuclease, a strong and persistent pause in digestion is detected at a single location. That this pause is due to the enzyme encountering a nucleosome is suggested, firstly, by its absence from digests of free DNA and, secondly, by the detection of a corresponding pause on the other strand. The two pauses, 146 bp apart, specify the location of a single precisely positioned nucleosome on the DNA fragment. This position corresponds exactly to one of two possible positions of the 145 bp sequence identified previously. A fragment containing only about 80 bp of the original 145 bp continues to position itself in the nucleosome like the parent sequence. Therefore, some of the sequence can be replaced with different DNA without affecting nucleosome positioning. Further exonuclease III analysis of an extensive set of deletions demonstrates that a central region of about 40 bp is essential for positioning the 145 bp sequence. When deletions advance into this region from either side, only a very small proportion of the DNA remains in the original position on the nucleosome. Therefore, the two short lengths of DNA at the edges of the region must each contain all or part of an essential nucleosome-positioning signal. These two critical sequences are symmetrically located across the nucleosome dyad and interact with the same region of histone H3. The sequence TGC occurs at the same place in both sequences; otherwise they are dissimilar.     

Micrococcal nuclease digestion of nuclei reveals extended nucleosome ladders having anomalous DNA lengths for chromatin assembled on non-replicating plasmids in transfected cells.

The chromatin structures of a variety of plasmids and plasmid constructions, transiently transfected into mouse Ltk- cells using the DEAE-dextran procedure, were studied by micrococcal nuclease digestion of nuclei and Southern hybridization. Although regularly arranged nucleosome-like particles clearly were formed on the transfected DNA, the nucleosome ladders, in some cases with 13-14 bands, were anomalous. Most often, a ladder of DNA fragments with lengths of approximately 300, 500, 700, 900 bp, etc. was generated. In contrast, typical 180-190 bp multiples were generated from bulk cellular or endogenous beta-actin gene chromatin. Very similar results were obtained with all DNA's transfected, and in a variety of cell lines, provided that plasmid replication did not occur. Additionally, after digestion of nuclei, about 90% of the chromatin fragments that contained transfected DNA sequences could not be solubilized at low ionic strength, in contrast with bulk cellular chromatin, suggesting association with nuclear structures or nuclear matrix. The remaining 10% of transfected DNA sequences, arising from soluble chromatin fragments, generated a typical nucleosome ladder. These results are consistent with the idea that assembly of atypical chromatin structures might be induced by proximity to elements of the nuclear pore complex or by nuclear compartmentalization.     

Periodicity of exonuclease III digestion of chromatin and the pitch of deoxyribonucleic acid on the nucleosome

Exonuclease III has previously been shown to pause about every 10 nucleotides along the 3' strands while it invades the nucleosome core. Here, the exact periodicity of this digestion, i.e., the spacing of the pauses, was determined. Results showed that the exonuclease digests the first 20 nucleotides at the edge of the nucleosome core with a periodicity of approximately 11 nucleotides; in contrast, DNA closer to the center of the particle is digested with a smaller periodicity of about 10 nucleotides. These figures differ from the known periodicity of DNase I digestion, approximately 10 and 10.5 nucleotides at the edge and in the center of the nucleosome, respectively. Moreover, as shown by sedimentations in sucrose gradients, the structure of the nucleosome does not appear to be significantly altered by the gradual destruction of its DNA moiety by the exonuclease. Such stability of the nucleosome, along with other complementary observations, indicates that the transition in the digestion periodicity of the exonuclease may not be the consequence of a structural rearrangement of the particle upon trimming. This transition may rather be ascribed to the properties of the native nucleosome and to the intrinsic mechanism of action of the enzyme. Finally, evidence is presented which suggests that the exonuclease 10-nucleotide periodicity of digestion of the inner region of the nucleosome reflects a 10 base pair/turn pitch of the DNA in that region.     

大鼠老化过程大脑皮层及小脑神经元染色质构象分析

 本文在前文~[2]的基础上进一步以MCN和DNaseⅠ为探针研究大鼠脑神经元终末分化后不同生理时期染色质构象,结果表明:MCN酶解DNA产物PAGE显示脑老化过程大脑皮层及小脑神经元染色质核小体单体DNA分别保持在176bp和215bp水平,核小体连接DNA长度存在组织差异,但不受老化影响;<2>DNaseⅠ酶解DNA产物PAGE显示各年龄组大脑皮层及小脑神经元染色质DNA存在10bp间隔重复结构和相同的泳动区带分布特征,提示脑老化中染色质具有稳定的B型双螺旋结构和一致的螺线管卷曲形式。染色质DNaseⅠ降解率随年龄增加而降低,提示老化导致活性染色质区域减少,老化过程脑神经元染色质构象改变成为其转录功能减退的结构基础。     

DNA sequence analysis of ARS elements from chromosome III of Saccharomyces cerevisiae: identification of a new conserved sequence.

Four fragments of Saccharomyces cerevisiae chromosome III DNA which carry ARS elements have been sequenced. Each fragment contains multiple copies of sequences that have at least 10 out of 11 bases of homology to a previously reported 11 bp core consensus sequence. A survey of these new ARS sequences and previously reported sequences revealed the presence of an additional 11 bp conserved element located on the 3' side of the T-rich strand of the core consensus. Subcloning analysis as well as deletion and transposon insertion mutagenesis of ARS fragments support a role for 3' conserved sequence in promoting ARS activity.     

Precise location of DNase I cutting sites in the nucleosome core determined by high resolution gel electrophoresis.

The precise locations of the DNase I cutting sites in the nucleosome core have been determined by analysis of the DNA products of a DNase I digestion of 32P end-labelled mucleosome cores on a high resolution gel electrophoresis system. This system is capable of resolving fragments of mixed sequence DNA differing by one base into the region of 160 bases in length. The DNase I cutting sites in the core are found to be spaced at multiples of about 10.4 (i.e. clearly different from 10.0) bases along the DNA, but show significant variations about this value. In addition to the location of the sites, the stagger between individual sites on opposite strands has been determined and is found to be inconsistent with at least one proposed mechanism for nuclease cleavage of chromatin DNA. Finally, a calculated distribution of fragment lengths in a DNase I digest of nuclei has been determined from the data obtained from the nucleosome core and found to be in reasonable agreement with the observed distribution. The periodicity of 10.4 is discussed with respect to the number of base pairs per turn of chromatin DNA and the number of superhelical turns of DNA per nucleosome.     

A 145-base pair DNA sequence that positions itself precisely and asymmetrically on the nucleosome core.

A 145-bp DNA sequence, cloned from Escherichia coli, was reconstituted into nucleosome core particles by a number of methods. The behaviour of the resulting complex upon sucrose gradient sedimentation and nucleoprotein gel electrophoresis closely resembled that of control bulk nucleosome core particles. DNase I digestion of the 32P-end-labelled complex revealed the 10-bp periodicity of cleavages expected for DNA bound on a histone surface. The narrow cleavage sites observed (1 bp wide) imply that the sequence occupies a single preferred position on the nucleosome core, accurate to the level of single base pairs. By relating the digestion pattern observed to the pattern of site protection found for random sequence nucleosomes, the DNA position was found to be offset by 17 bp from that in the normal core particle. A number of experiments argue against the involvement of length or end effects and suggest that it is some feature of the DNA sequence itself that determines this precise positioning of DNA on the nucleosome.     

Deoxyribonuclease I generates single-stranded gaps in chromatin deoxyribonucleic acid

Production of 10-base multiple DNA ladder fragments during DNase I digestion of chromatin is explained by a model which does not involve site-specific nicking by the DNase I. This model was tested because it explains why 10-base (actually 10.4 base) multiple-related fragments are paradoxically generated by both endonucleolytic (DNase I) and exonucleolytic (exonuclease III) mechanisms. This new model also explains the phenomenon of substantial single-stranded DNA production during DNase I digestion of chromatin. The latter phenomenon has been widely observed but is not explained by previous models. The single-stranded gap model to be presented makes testable predictions. Primarily, these are that DNase I produces single-stranded gaps in chromatin DNA and that the termini of 10-base multiple ladder fragments are separated by single-stranded gaps. Single-stranded gap production by DNase I was confirmed by a number of methods. Sensitivity of ladder band components (from DNase I but not staphylococcal nuclease digests) to S1 nuclease suggested that the ladder fragments themselves may compose a significant portion of these gaps. Separation of ladder fragment termini by single-stranded gaps was verified by demonstrating both resistance to the nick-specific NAD+-dependent ligase and sensitivity to T4 ligase which can ligate across gaps. Many single-stranded gaps, occurring both individually and clusters, were observed by electron microscopy using either cytochrome c labeling (where the gaps) are thinner than duplex) or gene 32 protein labeling (gaps thicker than duplex). Gap sizes were estimated by protecting them with gene 32 protein and digesting away unprotected duplexes. By this method, gap sizes fall into a ladder distribution (from 10 or 20 bases up to 120 bases), which, at least in the region of the shorter sizes, clearly indicates the sizes of single-stranded gaps formed in chromatin by DNase I.     

Sea urchin sperm chromatin structure as probed by pancreatic DNase I: Evidence for a novel cutting periodicity

Chromatin from mature sea urchin spermatozoa is highly compacted and composed almost entirely of DNA and the five histones, although sperm H1, H2A, and H2b histones differ from those found in embryo or somatic cell nuclei. Release of acid-soluble DNA during pancreatic DNase I digestion is 20-fold slower from sperm nuclei than from embryonic nuclei. Following DNase I digestion, most sperm nuclear DNA remains at high molecular weight, although there appears to be some release of 10 base oligomer fragments. Size analysis of the higher molecular weight DNA reveals a series of fragments that indicate a cutting periodicity of approximately 500 base pairs. This pattern remains when electrophoretic separation is carried out under denaturing conditions. The 500 base pair cleavage pattern was not detected in digestions of embryonic nuclei. Nucleosomes reconstituted with fractionated core histones from sperm gave, upon digestion, a characteristic 10 base “ladder,” with no resistant high molecular weight DNA. Micrococcal nuclease and DNase II digested sperm nuclei to produce DNA fragments with a calculated repeat length of 248 ± 3 and 246 ± 6 base pairs, respectively. The structural basis for the 500 base pair cutting periodicity in sperm nuclei may reside in the unique sperm H1 histone.     

Limited nucleosome migration can completely randomize DNA repair patches in intact human cells

Following irradiation of human cells with ultraviolet light, DNA repair patches are initially inserted near the 5' and 3' ends of nucleosome core DNA leaving a "gap" in repair synthesis (of approximately 50 bases) near the center of the core DNA. With time, however, these same repair patches become randomized, apparently by nucleosome migration. We have developed both an analytical expression and a computer algorithm (which simulates nucleosome migration along DNA) to determine the average distance nucleosomes must migrate to change the initial, non-uniform distribution of repair patches in nucleosomes to a random distribution. Both of these methods yielded the same result: nucleosomes must migrate an average of about 50 base-pairs in either direction to produce the randomization observed.     

Periodicity and fragment size of DNA from mouse TLT hepatoma chromatin and chromatin fractions using endogenous and exogenous nucleases

Summary The action of micrococcal nuclease, DNase I and DNase II on mouse TLT hepatoma chromatin revealing the periodicity of its structure as visualized by denaturing and nondenaturing gel electrophoresis, was consistent with the action of these enzymes on other chromatins. Micrococcal nuclease showed a complex subnucleosome fragment pattern based on multiples of 10 base pairs with a prominant couplet at 140/160 base pairs and the absence of the 80 base pair fragment. This couplet of the core and minimal nucleosome fragments was conspicuously present in the mononucleosomes found in the 11S fractions of a glycerol gradient centrifugation. DNase I and II produced a fairly even distribution of a 10 base pair increasing series of fragments to about 180 base pairs, a pattern also repeated in the DNA of nucleosome glycerol-gradient fractions. In limited digestions by these nucleases multinucleosomic DNA fragments are pronounced. These fragment lengths are multiples of an estimated average repeat length of nucleosome DNA of 180 base pairs. The action of the endogenous Mg/Ca-stimulated endonuclease produced only limited cuts in the hepatoma chromatin resulting primarily in multi-nucleosommc DNA fragment lengths and only upon lengthy digestion limited subnucleosomic, 10-base-pair multiple fragments are produced. The putative euchromatin-enriched fractions (50–75S) of the glycerol gradient centrifugation of autodigested chromatin, similarly, contained primarily the multinucleosomic DNA fragment lengths. These results are consistent with our previous electron microscopic demonstration that autodigested chromatin as well as the putative euchromatin-enriched fractions were composed of multinucleosomic chromatin segments containing a full complement of histones.