Differential DNase I Sensitivity of the Two Complementary Nucleosomal DNA Strands in Cycloheximide-Treated Ehrlich Ascites Tumor Cells

Abstract

The accessibility of the two complementary DNA strands in newly replicated chromatin of Ehrlich ascites tumor (EAT) cells grown under conditions of cycloheximide-inhibrted protein synthesis was studied by analysis of the DNase I digestion of isolated nuclei. Bulk DNA was labeled with ¹⁴C-thymidine and the newly synthesized strands - with bromodeoxyu ridine and ³H-thymidine. The DNase I digests were fractionated in two successive CsCl density gradient centrifugations to obtain a dense fraction containing 15–20% newly replica ted DNA Analysis of the distribution of ¹⁴C-labeled parental DNA fragments complementary to the ³H-nascent strand has shown that the ¹⁴C-labeled fragments prevail in the region of 30–50 nucleotides. Simulation experiments using the rate constants for DNase I attack show that this result may be explained by an enhanced accessibility at the nucleosomal 5′-end region of the parental strands, where the H2a-H2b dimer interacts with DNA. This asymmetry seems tobe induced by interactions in the chromatin.     

Patterns of nuclease protection during strand exchange. recA protein forms heteroduplex DNA by binding to strands of the same polarity

recA protein, in the presence of ATP, polymerizes on single-stranded DNA (plus strand) to form a presynaptic nucleoprotein filament that pairs with linear duplex DNA and actively displaces the plus strand from the recipient molecule in a polarized fashion to form a new heteroduplex molecule. The interaction between recA protein and DNA during strand exchange was studied by labeling different strands and probing the intermediate with pancreatic deoxyribonuclease I (DNase I) or restriction endonuclease. The incoming single strand was resistant to DNase I in the original nucleoprotein filament and remained resistant even after extensive strand exchange had occurred. Both strands of the parental duplex molecule were sensitive to DNase I in the absence of joint molecule formation; but as strand exchange progressed following homologous pairing, increasing stretches of the parental plus strand became resistant, whereas the complementary parental minus strand remained sensitive to DNase I throughout the reaction. Except for a region of 50-100 base pairs at the end of the newly formed heteroduplex DNA where strand exchange was initiated, the rest of the heteroduplex region was resistant to cleavage by restriction endonucleases. The data suggest that recA protein promotes strand exchange by binding both the incoming and outgoing strands of the same polarity, whereas the complementary strand, which must switch pairing partners, is unhindered by direct contact with the protein.     

The structure of 4-way DNA junctions: specific binding of bis-intercalators with rigid linkers.

During replication and recombination, two DNA duplexes lie side by side. We have developed reagents that might be used to probe structure during these critical processes; they contain two intercalating groups connected by a rigid linker that forces those groups to point in opposite directions. If their stereochemistry proves appropriate, such structure-specific agents should intercalate specifically into adjacent duplexes in the Y- and X-shaped structures (i.e. 3- and 4-way junctions, now known as 3H and 4H junctions) found at replication and recombination sites. We prepared DNA structures in which four duplexes were arranged in all possible combinations around 2- and 4-way junctions and then probed the accessibility to DNase I of all their phosphodiester bonds. In the absence of any bis-intercalators, 7-9 nucleotides (nt) in each of the strands in 4-way junctions were protected from attack; protected regions were significantly offset to the 3' side of the junction in continuous strands, but only slightly offset, if at all, in exchanging strands. All the intercalators decreased accessibility throughout the structure, but none did so at specific points in the two adjacent arms of 4-way junctions. However, one bis-intercalator--but not its sister with a shorter linker--strikingly increased access to a particular CpT bond that lay 9 nt away from the centre of some 4-way junctions without reducing access to neighbouring bonds. Binding was both sequence and structure specific, and depended on complementary stereochemistry between bis-intercalator and junction.     

Mode of extension of the daughter strands in the replication of closed circular mitochondrial DNA in vitro.

1. The properties of nascent DNA in the replicative closed circular mitochondrial DNA were examined in the in vitro system of discontinuous replication, using newborn rat liver mitochondria containing endogeneous DNA templates and enzymes. 2. The nascent DNA associated with the closed circular DNA fraction was found to be of two types; one class consisted of the fragments, and the other of the higher molecular-weight DNAs. Data from pulse and chase experiments indicate that the fragments were initially synthesized and subsequently converted into both heavy and light strands of the higher molecular-weight DNAs in an asymmetrical mode. 3. DNA - DNA hybridization experiments revealed that half of the fragments at least were copies of complementary parts of the parental DNA. 4. Based on the present in vitro data, a tentative structure of the replicating region and its expansion are discussed.     

Chromatin assembly in isolated mammalian nuclei.

Cellular DNA replication was stimulated in confluent monolayers of CV-1 monkey kidney cells following infection with SV40. Nuclei were isolated from CV-1 cells labeled with [3H]thymidine and then incubated in the presence of [alpha-32P]deoxyribonucleoside triphosphates under conditions that support DNA replication. To determine whether or not the cellular DNA synthesized in vitro was assembled into nucleosomes the DNA was digested in situ with either micrococcal nuclease or pancreatic DNase I, and the products were examined by electrophoretic and sedimentation analysis. The distribution of DNA fragment lengths on agarose gels following micrococcal nuclease digestion was more heterogeneous for newly replicated than for the bulk of the DNA. Nonetheless, the state of cellular DNA synthesized in vitro (32P-labeled) was found to be identical with that of the DNA in the bulk of the chromatin (3H-labeled) by the following criteria: (i) The extent of protection against digestion by micrococcal nuclease of DNase I. (ii) The size of the nucleosomes (180 base pairs) and core particles (145 base pairs). (iii) The number and sizes of DNA fragments produced by micrococcal nuclease in a limit digest. (iv) The sedimentation behavior on neutral sucrose gradients of nucleoprotein particles released by micrococcal nuclease. (v) The number and sizes of DNA fragments produced by DNase I digestion. These results demonstrate that cellular DNA replicated in isolated nuclei is organized into typical nucleosomes. Consequently, subcellular systems can be used to study the relationship between DNA replication and the assembly of chromatin under physiological conditions.     

Multiple and Specific Initiation of T4 DNA Replication

Partially replicated T4 DNA molecules (PRM) whose parental or progeny DNA was labeled with bromodeoxyuridine BUdR was analyzed by gradual shearing followed by CsCl banding of the sheared product. Analysis of PRM containing 18-mum replicated DNA showed that each replicated region was 3- to 6-mum long, indicating three to 6 replicative sites per molecule. Analysis of PRM containing 9-mum replicated DNA similarly indicated two to three replicated regions per molecule. DNA from the replicated regions of PRM containing 10-mum replicated DNA ("donor") was hybridized to DNA from mature phage ("recipient"), and the resulting hybrid was subjected to digestion with exonuclease I. The extent of protection of the recipient and more efficient self-annealing of progeny fragments from PRM indicated that the replicated regions represented 8 to 10 nonrandom locations of the genome. Possible significance of multiple sites for initiation of DNA replication is discussed.     

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.     

A rapid in vitro method for obtaining RNA accessibility patterns for complementary DNA probes: correlation with an intracellular pattern and known RNA structures.

A technique is described to identify the rare sequences within an RNA molecule that are available for efficient interaction with complementary DNA probes: the target RNA is digested by RNase H in the presence of a random pool of complementary DNA fragments generated from the same DNA preparation that was used for target RNA synthesis. The DNA region was amplified by PCR, partially digested with DNase and denatured prior to RNA binding. In the presence of single-stranded DNA fragments the RNA was digested with RNase H such that, on average, each molecule was cut once. Cleavage sites were detected by gel electrophoresis either directly with end-labeled RNA or by primer extension. The pattern of accessible sites on c- raf mRNA was determined and compared with the known profile of activity of oligonucleotides found in cells, showing the merit of the method for predicting oligonucleotides which are efficient for in vivo antisense targeting. New susceptible sites in the 3'-untranslated region of c- raf mRNA were identified. Also, four RNAs were probed to ascertain to what extent structure predicts accessibility: the P4-P6 domain of the Tetrahymena group I intron, yeast tRNAAsp, Escherichia coli tmRNA and a part of rat 18S rRNA.     

Identification of proteins interacting with newly replicated DNA in SV40-infected cells by UV-induced DNA-protein cross-linking

Protein species interacting with newly replicated DNA were analyzed using a photo cross-linking technique. Nascent DNA was labeled in vitro with [alpha-32P]dCTP and BrdUTP in SV40-infected CV-1 cells made permeable with saponin. The labeled cells were then irradiated with UV light (254 nm) and were treated extensively with DNase I. Proteins with radioactive DNA tags were separated by SDS-PAGE and visualized by autoradiography. Among 10-15 proteins which were cross-linked, the proteins with apparent molecular weights of 16.5 K, 44 K, 82 K and those in the 94-140 K region appeared to be associated with newly replicated SV40 DNA. A pulse-chase experiment showed that the 82 K and 94-140 K proteins interacted with new DNA in a relatively localized region close to the replication fork. The 44 K protein was identified as the major viral capsid protein, VP1, using antiserum to SV40 capsid proteins. It was suggested that VP1 binds to nascent DNA shortly after DNA synthesis and migrates into chromatin maturation regions.     

Strandedness of newly synthesized short pieces of polyoma DNA from isolated nuclei.

The discontinuous synthesis of the complementary strands of polyoma DNA in isolated nuclei has been studied by hybridization techniques. The relative amounts of the newly synthesized complementary strands were compared by separately annealing them to denatured HpaII restriction fragments. In every case an excess (1.4- to 2.4-fold) of short pieces of the strand growing in the 3' leads to 5' direction was found.     

Chromatin assembly during DNA replication in somatic cells.

Newly replicated DNA is assembled into chromatin through two principle pathways. Firstly, parental nucleosomes segregate to replicated DNA, and are transferred directly to one of the two daughter strands during replication fork passage. Secondly, chromatin assembly factors mediate de-novo assembly of nucleosomes on replicating DNA using newly synthesized and acetylated histone proteins. In somatic cells, chromatin assembly factor 1 (CAF-1) appears to be a key player in assembling new nucleosomes during DNA replication. It provides a molecular connection between newly synthesized histones and components of the DNA replication machinery during the S phase of the cell division cycle.     

The tertiary structure of the four-way DNA junction affords protection against DNase I cleavage.

The accessibility of phosphodiester bonds in the DNA of four-way helical junctions has been probed with the nuclease DNase I. Regions of protection were observed on all four strands of the junctions, that tended to be longer on the strands that are exchanged between the coaxially stacked pairs of helices. The protected regions on the continuous strands of the stacked helices were not located exactly at the junction, but were displaced towards the 3' side of the strand. This is the region of backbone that becomes located in the major groove of the opposed helix in the non-crossed, right-handed structure for the junction, and might therefore be predicted to be protected against cleavage by an enzyme. However, the major grooves of the structure remain accessible to the much smaller probe dimethyl sulphate.     

Histone deacetylation is required for the maturation of newly replicated chromatin

The effects of inhibiting histone deacetylation on the maturation of newly replicated chromatin have been examined. HeLa cells were labeled with [3H]thymidine in the presence or absence of sodium butyrate; control experiments demonstrated that butyrate did not significantly inhibit DNA replication for at least 70 min. Like normal nascent chromatin, chromatin labeled for brief periods (0.5-1 min) in the presence of butyrate was more sensitive to digestion with DNase I and micrococcal nuclease than control bulk chromatin. However, chromatin replicated in butyrate did not mature as in normal replication, but instead retained approximately 50% of its heightened sensitivity to DNase I. Incubation of mature chromatin in butyrate for 1 h did not induce DNase I sensitivity: therefore, the presence of sodium butyrate was required during replication to preserve the increased digestibility of nascent chromatin DNA. In contrast, sodium butyrate did not inhibit or retard the maturation of newly replicated chromatin when assayed by micrococcal nuclease digestion, as determined by the following criteria: 1) digestion to acid solubility, 2) rate of conversion to mononucleosomes, 3) repeat length, and 4) presence of non-nucleosomal DNA. Consistent with the properties of chromatin replicated in butyrate, micrococcal nuclease also did not preferentially attack the internucleosomal linkers of chromatin regions acetylated in vivo. The observation of a novel chromatin replication intermediate, which is highly sensitive to DNase I but possesses normal resistance to micrococcal nuclease, suggests that nucleosome assembly and histone deacetylation are not obligatorily coordinated. Thus, while deacetylation is required for chromatin maturation, histone acetylation apparently affects chromatin organization at a level distinct from that of core particle or linker, possibly by altering higher order structure.     

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.     

Mechanism of degradation of duplex DNA by the DNase induced by herpes simplex virus

Reaction intermediates formed during the degradation of linear PM2, T5, and λ DNA by herpes simplex virus (HSV) DNase have been examined by agarose gel electrophoresis. Digestion of T5 DNA by HSV type 2 (HSV-2) DNase in the presence of Mn²⁺ (endonuclease only) gave rise to 6 major and 12 minor fragments. Some of the fragments produced correspond to those observed after cleavage of T5 DNA by the single-strand-specific S1 nuclease, indicating that the HSV DNase rapidly cleaves opposite a nick or gap in a duplex DNA molecule. In contrast, HSV DNase did not produce distinct fragments upon digestion of linear PM2 or λ DNA, which do not contain nicks. In the presence of Mg²⁺, when both endonuclease and exonuclease activities of the HSV DNase occur, most of the same distinct fragments from digestion of T5 DNA were observed. However, these fragments were then further degraded preferentially from the ends, presumably by the action of the exonuclease activity. Unit-length λ DNA, EcoRI restriction fragments of λ DNA, and linear PM2 DNA were also degraded from the ends by HSV DNase in the same manner. Previous studies have suggested that the HSV exonuclease degrades in the 3′ → 5′ direction. If this is correct, and since only 5′-monophosphate nucleosides are produced, then HSV DNase should “activate” DNA for DNA polymerase. However, unlike pancreatic DNase I, neither HSV-1 nor HSV-2 DNase, in the presence of Mg²⁺ or Mn²⁺, activated calf thymus DNA for HSV DNA polymerase. This suggests that HSV DNase degrades both strands of a linear double-stranded DNA molecule from the same end at about the same rate. That is, HSV DNase is apparently capable of degrading DNA strands in the 3′ → 5′ direction as well as in the 5′ → 3′ direction, yielding progressively smaller double-stranded molecules with flush ends. Except with minor differences, HSV-1 and HSV-2 DNases act in a similar manner.     

An effective family shuffling method using single-stranded DNA

Family shuffling, which is one of the most powerful techniques for in vitro protein evolution, always involves the problem of reassembling the gene fragments into parental gene sequences, because such a process prevents the formation of chimeric sequences. In order to improve the efficiency of hybrid formation in family shuffling, single-stranded DNAs (ssDNAs) were used as templates. The ssDNAs of two catechol 2,3-dioxygenase genes, nahH and xylE, were prepared, the xylE strand being complementary to the nahH strand. When these ssDNAs were digested by DNase I and reassembled, chimeric genes were obtained at a rate of 14%, which was much higher than the rate of less than 1% obtained by shuffling with double-stranded DNAs. Chimeric catechol 2,3-dioxygenases that were more thermally stable than the parental enzymes, XylE and NahH, were obtained by this ssDNA-based DNA shuffling.     

Unwinding of Parental Strands During Simian Virus 40 DNA Replication

Pools of young (less than 60% replicated) and mature (60-90% replicated) replicating molecules of simian virus 40 (SV40) DNA have been treated at pH 12.2 in order to dissociate growing chains from the parental strands. The molecules are neutralized so that the parental strands can reassociate and they have then been isolated. They are covalently closed structures which sediment rapidly in alkaline sucrose gradients; however, the sedimentation rates are less than the sedimentation rate of SV40 DNA I. Isopycnic banding in CsCl-ethidium bromide and sedimentation velocity studies in the presence of various amounts of ethidium bromide indicate that these structures contain negative superhelical turns and several-fold-higher superhelix densities than SV40 DNA I (the covalently closed DNA molecule). These structures are those that would be predicted if nicking, unwinding, and sealing of the parental strands occurred as replication proceeded. These experiments provide a direct demonstration that there is a progressive decrease in the topological winding number which accompanies SV40 DNA replication.     

Deoxyribonuclease I produces staggered cuts in the DNA of chromatin

The relationship of cuts made by deoxyribonuclease I (DNase I, EC. 3.1.4.5) on the two strands of DNA of chromatin has been investigated. DNA was extracted from a DNase I digest of rat liver nuclei and incubated with the large fragment of DNA polyrnerase I. Analysis of the products of this incubation indicates the cuts made by DNase I on opposite strands are staggered with respect to one another. A cut on one strand is about two bases in the 3′ direction or eight bases in the 5′ direction from the position on its own strand which is directly across from the cut on the other strand. A different result is obtained when a DNase I digest of native DNA is analyzed. Current models for the organization of DNA in the nucleosome are discussed with respect to these results.     

The structure of replicating adenovirus 2 DNA molecules

Adenovirus 2 (Ad2)-infected KB cells were exposed to a 2.5 min pulse of ³H-thymidine at 19 hr after infection. The labeled DNA molecules were separated from cell DNA and mature Ad2 DNA by sucrose gradient sedimentation and CsCI equilibrium centrifugation under conditions designed to minimize branch migration and hybridization of single strands. Electron microscopy-of fractions containing radioactivity revealed two basic types of putative replicating molecules: Ad2 length duplex DNA molecules with one or more single-stranded branches (type I) and Ad2 length linear DNA molecules with a single-stranded region extending a variable distance from one end (type II). Length measurements, partial denaturation studies and 3′ terminal labeling experiments were consistent with the following model for Ad2 DNA replication. Initiation of DNA synthesis occurs at or near an end of the Ad2 duplex. Following initiation, a daughter strand is synthesized in the 5′ to 3′ direction, displacing the parental strand with the same polarity. This results in the formation of a branched replicating molecule (type I). Initiations at the right and left molecular ends are approximately equal in frequency, and multiple initiations on the same replicating molecule are common. At any given displacement fork in a type I molecule, only one of the two parental strands is replicated. Two nonexclusive mechanisms are proposed to account for the replication of the other parental strand. In some cases, before completion of a round of displacement synthesis initiated at one end of the Ad2 duplex, a second initiation will occur at the opposite end. In these doubly initiated molecules, both parental strands serve as templates for displacement synthesis. Two type II molecules are generated when the oppositely moving displacement forks meet. Alternatively, displacement synthesis may proceed to the end of the Ad2 duplex, resulting in the formation of a daughter duplex and a parental single strand. Replication of the displaced parental strand is then initiated at or near its 3′ terminus, producing a type II molecule. Daughter strand synthesis proceeds in the 5′ to 3′ direction in type II molecules generated by either mechanism, and completion of synthesis results in the formation of a daughter duplex.