Bacteriophage T2 DNA modification by O-methylhydroxylamine]

A comparative study of the reactivities of free 5-hydroxymethylcytosine (5-HMC) and 5-HMC found in the composition of native, denaturated and intraphage DNA of the T2 phage with that of O-methylhydroxylamine (OMHA) demonstrated that the DNA secondary structure in situ is partially disturbed. The interaction DNA-protein in the phage particle channels the reaction into a predominant formation of 4N-methoxy-6-methoxyamino-5,6-dihydro-5-hydroxymethyl cytosine, but not 4N-methoxy-5-hydroxymethyl cytosine, which is formed in vitro. In the course of the reaction the interaction DNA-protein is probably fixed by covalent binding.     

Similarity of the Structure of DNA from a Variety of Sources

DNA's from diverse cells of different species and from diverse tissues give the same x-ray diffraction pattern. The presently observable structure of DNA appears, then, to be the same in all cells. Thus, DNA in the resting state—the stored genetic material, from sperm of Paracentrotus lividus, Arbacia lixula, and salmon and from T₂ and T₇ bacteriophage—gives a pattern indistinguishable from DNA from very rapidly dividing cells, e.g., human acute leukemic leukocytes, human leukemic myeloid cells, mouse sarcoma 180, and bacteria—E. coli and pneumococci—during their logarithmic growth. The same x-ray patterns are given by DNA's from more slowly dividing tissues, e.g. calf liver, calf thymus, and human normal and leukemic lymphatic tissue. DNA from chicken erythrocytes—a DNA presumably metabolically inert—gives a similar picture. DNA's from several sources with a wide range in nitrogen base ratios, prepared independently by different workers using various methods, have given final products in varying yield; these all gave the same x-ray pattern, suggesting that all DNA is in the double-helical configuration. Finally, separation of the DNA molecule into a number of fractions with a varying adenine + thymine:guanine + cytosine ratio, but a constant adenine:thymine and guanine:cytosine ratio, each giving the same x-ray pattern as the original whole molecule, suggests that DNA cannot exist in significant amounts in forms other than the double-helix. X-ray diffraction photographs of sperm heads, extracted nucleoprotamine, calf thymus nuclei and extracted nucleohistone, and of chicken erythrocyte nuclei, are not all as well defined as those given by extracted DNA, but it is clear from the general characteristics of the pattern that much of the DNA bound to protein in these nuclei has the usual helical configuration, and that the double-helical structure of DNA exists in the cell and is not an artifact.     

Structural dynamics of double-stranded DNA with epigenome modification

Modification of cytosine plays an important role in epigenetic regulation of gene expression and genome stability. Cytosine is converted to 5-methylcytosine (5mC) by DNA methyltransferase; in turn, 5mC may be oxidized to 5-hydroxymethylcytosine (5hmC) by ten-eleven translocation enzyme. The structural flexibility of DNA is known to affect the binding of proteins to methylated DNA. Here, we have carried out a semi-quantitative analysis of the dynamics of double-stranded DNA (dsDNA) containing various epigenetic modifications by combining data from imino ¹H exchange and imino ¹H R_1ρ relaxation dispersion NMR experiments in a complementary way. Using this approach, we characterized the base-opening (k_open) and base-closing (k_close) rates, facilitating a comparison of the base-opening and -closing process of dsDNA containing cytosine in different states of epigenetic modification. A particularly striking result is the increase in the k_open rate of hemi-methylated dsDNA 5mC/C relative to unmodified or fully methylated dsDNA, indicating that the Watson–Crick base pairs undergo selective destabilization in 5mC/C. Collectively, our findings imply that the epigenetic modulation of cytosine dynamics in dsDNA mediates destabilization of the GC Watson–Crick base pair to allow base-flipping in living cells.     

Chain growth rate of -galactosidase during exponential growth and amino acid starvation

S_d phage were incubated in 1 m-O-methylhydroxylamine. At various time-intervals, samples of modified phage were isolated and disrupted either by heating or by treatment with detergent. Changes in viscosity and buoyant density of disrupted preparations took place in the course of modification. Three transient synchronous drops in viscosity and buoyant density levels were observed with minima at five minutes, one and three hours of modification. The specific viscosity of the preparations at minima was 10 to 20% that of the disrupted unmodified phage.Properties of the phage preparation isolated during the third period of decreased viscosity were studied in more detail. This preparation, subjected to thermal disruption, gives a single DNA-containing band in Cs₂SO₄ gradient centrifugation corresponding to a buoyant density of 1.37 g/cm³ (cf. 1.39, 1.29 and 1.43 g/cm³ for whole phage, phage ghosts and native phage DNA, respectively).The band contains practically all the ³⁵S label that was present in the starting phage, suggesting that it corresponds to a complex of phage DNA with protein. Electron microscopy revealed complexes as thick strands of 50 to 300 Å diameter bonded to globular particles of varying size.In four hours of modification, the viscosity and buoyant density of disrupted phage returned to values characteristic of unmodified preparations. The DNA band contained no ³⁵S label. Electron microscopy of the substance of this band revealed fibres of 20 Å diameter.A possible explanation of the results is based on the assumption of pre-existing non-covalent interaction of C₍₄₎—NH₂ moieties of cytidine residues with nucleophilic groupings of coating protein within the virion. It is assumed that it is this interaction that holds DNA in “non-native” conformation within intact phage particles and thus explains its peculiar properties discovered earlier. In the present case, the interaction determines the formation of DNA-protein crosslinks under O-methylhydroxylamine treatment via the earlier postulated intermediate product of cytosine modification. Restoration of “normal” physical properties of disrupted phage after more prolonged modification is explained by cleavage of the DNA-protein cross-links due to reaction of the postulated intermediate with O-methylhydroxylamine affording N₍₄₎-methoxy-6-methoxy-amino-5,6-dihydrocytidine residues.     

Isolation and site-directed mutagenesis of DNA methyltransferase SssI

Prokaryotic DNA methyltransferase SssI (M.SssI) methylates cytosines at C5 in CpG sequences. Bacterial strains that produced M.SssI and its mutants as His₆-tagged proteins were constructed. To verify the role of Ser300 in recognizing the CpG sequence by the enzyme, Ser300 was replaced by Gly or Pro. The substitutions had virtually no effect on DNA binding and methylation by M.SssI apart from a slight decrease in binding in the case of S300P. It was assumed that no contact with DNA is formed by the side chain of Ser300 and the carbonyl oxygen and amide nitrogen of its peptide bonds. In addition, Ala was substituted for highly conserved Val188, presumably involved in stabilization of the flipped-out cytosine during the reaction. The substitution decreased fivefold the dissociation constant of the enzyme-substrate complex and halved the initial rate of DNA methylation. Despite the lack of a considerable effect of V188A, it was assumed that Val188 does form a contact with the target cytosine, but such a contact is formed with Ala in the case of the V188A mutant.     

The secondary structure of bacteriophage DNA in situ. VIII. The reaction of sodium bisulphite with intraphage cytosine as a probe for studying the DNA-protein interaction

To obtain data on the viral nucleoprotein a study has been made of the reaction of sodium bisulphite with cytosine in the intraphage DNA of the phage Sd. The CHlO4 hydrolysates of the bisulphite-modified phage Sd have demonstrated a decrease of 18% in the cytosine content and the presence of the products with the properties of cytosyl-amino acids (the main amino acid responsible for the DNA-protein interaction involving cytosine is lysine). But when prior to hydrolysis the modified phage was disintegrated under mild conditions in 0.1--1 M NaCl solution or Tris-HCl buffer (pH 7), neither the decrease in the cytosine content nor cytosyl-amino acids have been found. An exception is the heating of the phage at 70 degrees C in a medium containing 0.05 M phosphate buffer (pH 7.9--8.5), when an 18% decrease in the cytosine content and subsequent appearance of cytosyl-amino acids have also been observed. The presence of cytosyl-amino acids which are the nucleotide-protein cross-links is confirmed by the results of viscometry, equilibrium centrifugation in cesium sulphate gradient and determinations of the survival percentage. It is suggested that the reaction between bisulphite and cytosine in the phage Sd stops at the stage of the intermediate product C5-C6-dihydro-C6-sulphopyrimidine whose amino group is shielded by interaction with protein (product VII). This product can exist only under in situ conditions: with disintegration of nucleoprotein (destruction of phage particles or ejection of the DNA) in phosphate-free media the product VII reverts into the initial cytosine. Under the conditions of acid hydrolysis or destruction of phage in the presence of phosphate ions product VII undergoes transamination with cleavage of SO3 and restoration of the C5-C6 double bond producing cytosyl-amino acids. The factors determining the stability of the product VII are discussed.     

Correlation between synthesis and methylation of DNA in HeLa cells

For the whole cell cycle the methylation of DNA was studied in synchronized $\text{HeLa}$ cells and in nuclei isolated from them. In the intact cells the methylation of DNA cytosine runs parallel to DNA synthesis. The pattern of DNA cytosine methylation by the isolated nuclei is almost identical to that obtained with the whole cells. Since the isolated nuclei do not synthesize DNA, it is shown that DNA methylation continues for at least 30 min after DNA synthesis is over. No DNA minor thymine is found in the isolated nuclei.     

Influence of glycosaminoglycans on endogenous DNA synthesis in isolated normal and cancer cell nuclei. Differential effect of heparin

The influence of exogenously-added glycosaminoglycans and glycoproteins on DNA synthesis in isolated nuclei, from normal and malignant tissues, was investigated. Heparin stimulated DNA synthesis in normal cell nuclei at concentrations (heparin/DNA (w/w) <0.9) which inhibited DNA synthesis in tumor cell nuclei. At higher concentrations (heparin/DNA (w/w) > 0.9) heparin inhibited DNA synthesis in both normal and tumor cell nuclei. The chondroitin-4 and 6-sulfates, heparan sulfate, cartilage proteoglycan, N-desulfated heparin, and glycophorin caused inhibition of DNA synthesis at all concentrations tested and in all nuclei examined. Hyaluronic acid, dermatan sulfate, keratan sulfate, α₁-acid glycoprotein and fetuin had no significant influence on DNA synthesis in isolated nuclei.     

Hybrid DNA i-motif: Aminoethylprolyl-PNA (pC5) enhance the stability of DNA (dC5) i-motif structure

This report describes the synthesis of C-rich sequence, cytosine pentamer, of aep-PNA and its biophysical studies for the formation of hybrid DNA:aep-PNAi-motif structure with DNA cytosine pentamer (dC₅) under acidic pH conditions. Herein, the CD/UV/NMR/ESI-Mass studies strongly support the formation of stable hybrid DNA i-motif structure with aep-PNA even near acidic conditions. Hence aep-PNA C-rich sequence cytosine could be considered as potential DNA i-motif stabilizing agents in vivo conditions.     

Changing the target base specificity of the EcoRV DNA methyltransferase by rational de novo protein-design

The EcoRV DNA-(adenine-N⁶)-methyltransferase (M.EcoRV) specifically modifies the first adenine residue within GATATC sequences. During catalysis, the enzyme flips its target base out of the DNA helix and binds it into a target base binding pocket which is formed in part by Lys16 and Tyr196. A cytosine residue is accepted by wild-type M.EcoRV as a substrate at a 31-fold reduced efficiency with respect to the k_cat/K_M values if it is located in a CT mismatch substrate (GCTATC/GATATC). Cytosine residues positioned in a CG base pair (GCTATC/GATAGC) are modified at much more reduced rates, because flipping out the target base is much more difficult in this case. We intended to change the target base specificity of M.EcoRV from adenine-N⁶ to cytosine-N⁴. To this end we generated, purified and characterized 15 variants of the enzyme, containing single, double and triple amino acid exchanges following different design approaches. One concept was to reduce the size of the target base binding pocket by site-directed mutagenesis. The K16R variant showed an altered specificity, with a 22-fold preference for cytosine as the target base in a mismatch substrate. This corresponds to a 680-fold change in specificity, which was accompanied by only a small loss in catalytic activity with the cytosine substrate. The K16R/Y196W variant no longer methylated adenine residues at all and its activity towards cytosine was reduced only 17-fold. Therefore, we have changed the target base specificity of M.EcoRV from adenine to cytosine by rational protein design. Because there are no natural paragons for the variants described here, a change of the target base specificity of a DNA interacting enzyme was possible by rational de novo design of its active site.     

Measuring topology of low-intensity DNA methylation sites for high-throughput assessment of epigenetic drug-induced effects in cancer cells

Epigenetic anti-cancer drugs with demethylating effects have shown to alter genome organization in mammalian cell nuclei. The interest in the development of novel epigenetic drugs has increased the demand for cell-based assays to evaluate drug performance in pre-clinical studies. An imaging-based cytometrical approach that can measure demethylation effects as changes in the spatial nuclear distributions of methylated cytosine and global DNA in cancer cells is introduced in this paper. The cells were studied by immunofluorescence with a specific antibody against 5-methylcytosine (MeC), and 4,6-diamidino-2-phenylindole (DAPI) for delineation of methylated sites and global DNA in nuclei. In the preprocessing step the segmentation of nuclei in three-dimensional images (3-D) is followed by an automated assessment of nuclear DAPI/MeC patterns to exclude dissimilar entities. Next, low-intensity MeC (LIM) and low-intensity DNA (LID) sites of similar nuclei are localized and processed to obtain specific nuclear density profiles. These profiles sampled at half of the total nuclear volume yielded two parameters: LIM_0.5 and LID_0.5. The analysis shows that zebularine and 5-azacytidine—the two tested epigenetic drugs introduce changes in the spatial distribution of low-intensity DNA and MeC signals. LIM_0.5 and LID_0.5 were significantly different (p < 0.001) in 5-azacytidine treated (n = 660) and zebularine treated (n = 496) vs. untreated (n = 649) DU145 human prostate cancer cells. In the latter case the LIM sites were predominantly found at the nuclear border, whereas treated populations showed different degrees of increase in LIMs towards the interior nuclear space, in which a large portion of heterochromatin is located. The cell-by-cell evaluation of changes in the spatial reorganization of MeC/DAPI signals revealed that zebularine is a more gentle demethylating agent than 5-azacytidine. Measuring changes in the topology of low-intensity sites can potentially be a valuable component in the high-throughput assessment of demethylation and risk of chromatin reorganization in epigenetic-drug screening tasks.     

Dnmt2 is the most evolutionary conserved and enigmatic cytosine DNA methyltransferase in eukaryotes

Dnmt2 is the most strongly conserved cytosine DNA methyltransferase in eukaryotes. It has been found in all organisms possessing methyltransferases of the Dnmt1 and Dnmt3 families, whereas in many others Dnmt2 is the sole cytosine DNA methyltransferase. The Dnmt2 molecule contains all conserved motifs of cytosine DNA methyltransferases. It forms 3D complexes with DNA very similar to those of bacterial DNA methyltransferases and performs cytosine methylation by a catalytic mechanism common to all cytosine DNA methyltransferases. Catalytic activity of the purified Dnmt2 with DNA substrates is very low and could hardly be detected in direct biochemical assays. Dnmt2 is the sole cytosine DNA methyltransferase in Drosophila and other dipteran insects. Its overexpression as a transgene leads to DNA hypermethylation in all sequence contexts and to an extended life span. On the contrary, a null-mutation of the Dnmt2 gene leads to a diminished life span, though no evident anomalies in development are observed. Dnmt2 is also the sole cytosine DNA methyltransferase in several protists. Similar to Drosophila these protists have a very low level of DNA methylation. Some limited genome compartments, such as transposable sequences, are probably the methylation targets in these organisms. Dnmt2 does not participate in genome methylation in mammals, but seems to be an RNA methyltransferase modifying the 38th cytosine residue in anticodon loop of certain tRNAs. This modification enhances stability of tRNAs, especially in stressful conditions. Dnmt2 is the only enzyme known to perform RNA methylation by a catalytic mechanism characteristic of DNA methyltransferases. The Dnmt2 activity has been shown in mice to be necessary for paramutation establishment, though the precise mechanisms of its participation in this form of epigenetic heredity are unknown. It seems likely, that either of the two Dnmt2 activities could become a predominant one during the evolution of different species. The high level of the Dnmt2 evolutionary conservation proves its activity to have a significant adaptive value in natural environment.     

A unique family of Mrr-like modification-dependent restriction endonucleases

Mrr superfamily of homologous genes in microbial genomes restricts modified DNA in vivo. However, their biochemical properties in vitro have remained obscure. Here, we report the experimental characterization of MspJI, a remote homolog of Escherichia coli’s Mrr and show it is a DNA modification-dependent restriction endonuclease. Our results suggest MspJI recognizes ^mCNNR (R = G/A) sites and cleaves DNA at fixed distances (N₁₂/N₁₆) away from the modified cytosine at the 3′ side (or N₉/N₁₃ from R). Besides 5-methylcytosine, MspJI also recognizes 5-hydroxymethylcytosine but is blocked by 5-glucosylhydroxymethylcytosine. Several other close homologs of MspJI show similar modification-dependent endonuclease activity and display substrate preferences different from MspJI. A unique feature of these modification-dependent enzymes is that they are able to extract small DNA fragments containing modified sites on genomic DNA, for example ∼32 bp around symmetrically methylated CG sites and ∼31 bp around methylated CNG sites. The digested fragments can be directly selected for high-throughput sequencing to map the location of the modification on the genomic DNA. The MspJI enzyme family, with their different recognition specificities and cleavage properties, provides a basis on which many future methods can build to decode the epigenomes of different organisms.     

Myxosporea (Myxozoa,Cnidaria) Lack DNA Cytosine Methylation

DNA cytosine methylation is central to many biological processes, including regulation of gene expression, cellular differentiation, and development. This DNA modification is conserved across animals, having been found in representatives of sponges, ctenophores, cnidarians, and bilaterians, and with very few known instances of secondary loss in animals. Myxozoans are a group of microscopic, obligate endoparasitic cnidarians that have lost many genes over the course of their evolution from free-living ancestors. Here, we investigated the evolution of the key enzymes involved in DNA cytosine methylation in 29 cnidarians and found that these enzymes were lost in an ancestor of Myxosporea (the most speciose class of Myxozoa). Additionally, using whole-genome bisulfite sequencing, we confirmed that the genomes of two distant species of myxosporeans, Ceratonova shasta and Henneguya salminicola, completely lack DNA cytosine methylation. Our results add a notable and novel taxonomic group, the Myxosporea, to the very short list of animal taxa lacking DNA cytosine methylation, further illuminating the complex evolutionary history of this epigenetic regulatory mechanism.     

Promiscuous methylation of non-canonical DNA sites by HaeIII methyltransferase

The cytosine C5 methyltransferase M.HaeIII recognises and methylates the central cytosine of its canonical site GGCC. Here we report that M.HaeIII can also, with lower efficiency, methylate cytosines located in a wide range of non-canonical sequences. Using bisulphite sequencing we mapped the methyl- cytosine residues in DNA methylated in vitro and in vivo by M.HaeIII. Methyl-cytosine residues were observed in multiple sequence contexts, most commonly, but not exclusively, at star sites (sites differing by a single base from the canonical sequence). The most frequently used star sites had changes at positions 1 and 4, but there is little or no methylation at star sites changed at position 2. The rate of methylation of non-canonical sites can be quite significant: a DNA substrate lacking a canonical site was methylated by M.HaeIII in vitro at a rate only an order of magnitude slower than an otherwise identical substrate containing the canonical site. In vivo methylation of non-canonical sites may therefore be significant and may have provided the starting point for the evolution of restriction–modification systems with novel sequence specificities.     

Testing models of the arrangement of DNA inside bacteriophage lambda by crosslinking the packaged DNA

Bis-psoralens can make crosslinks between two adjacent segments of a condensed DNA molecule. We have used bis-psoralen crosslinking as a covalent means of preserving structural features of DNA packaged inside bacteriophage λ. A single bis-crosslink prevents normal electron microscopic spreading of intact λ DNA: after deproteinization the molecules appear as tangled rosettes which are presumably due either to trapped knots or supercoils. However, restriction nuclease digestion of the crosslinked DNA yields fragments that spread normally. The location of crosslinks can be studied by their appearance in such a digest as X-shaped molecular features. Significant crosslinking frequencies are found between all six possible pairs of the four largest BglII fragments of λ DNA. Little or no evidence is seen for crosslinked loops within individual fragments. These results are inconsistent with two previously suggested models of intraphage DNA packaging. Determination of the positions of crosslinks within restriction fragments yields a pattern of DNA contacts too complex for any simple analysis. The finding of hints of periodicity in the sites of crosslinks, preferential crosslinking of some restriction fragments, and the occurrence of one particularly efficient crosslinking reaction between two restriction fragments appear to rule out purely random packaging arrangements.     

Methylation of DNA in early development: 5-methyl cytosine content of DNA in sea urchin sperm and embryos

By separating formic acid hydrolysates with high pressure chromatography on an Aminex-10 column, we determined the ratio of 5-methyl cytosine to cytosine and other bases of DNA from sea urchin sperm and nuclei of embryos from early cleavage through pluteus stages. Contrary to several previous reports, we could not find any measurable changes in the methylation levels of embryonic nuclear DNAs at different stages of development. We also found no consistent differences between the methylation levels of sea urchin sperm and embryonic nuclei or the 5-methyl cytosine content of fish (Mugilcephalus) sperm and liver nuclei. While these measurements would not have detected subtle variations associated with differentiation, they would have indicated the gross changes previously reported for embryos or between sperm and somatic nuclei had those changes been present.     

Formation of deoxycytidine diphosphate-diglyceride by nuclei isolated from HeLa cells.

Isolated nuclei from HeLa cells synthesize dCDP-diglyceride from dCTP at the rapid rate of 5–10 nmol/20 min/10⁸ nuclei. The incorporation of dCTP into this phospholipid precursor is thus 10 to 20 times faster than the incorporation of dCTP into DNA, in vitro, under the same conditions. ATP, phosphatidic acid, and MgCl₂ are required for optimal synthesis of dCDP-diglyceride. The reaction is completely inhibited by the presence of 0.04% Triton N-101. Liponucleotide formation occurs equally well with dCTP or CTP in this system and competition studies suggest that a single enzyme catalyzes the formation of dCDP- and CDP-diglyceride.     

Binding of proflavin to T2L bacteriophage and its DNA.

We have measured the binding equilibria of proflavin to T2L bacteriophage, in both “slow” and “fast” sedimenting forms, and to free T2L DNA. Measurements were carried out by difference spectroscopy at 430 nm at temperatures from 13 to 43°C and at pH 5.6 and 7.6. We found no significant difference in the binding parameters of the two phage forms. Also, the fraction of nucleotides available as binding sites for proflavin was the same for both free and intraphage DNA. However, the binding constant is about an order of magnitude lower for encapsulated than for free T2L DNA, due to the decreased exothermicity of the binding reaction within the phage head.     

Dehydration, deamination and enzymatic repair of cytosine glycols from oxidized poly(dG-dC) and poly(dI-dC)

Cytosine glycols (5,6-dihydroxy-5,6-dihydrocytosine) are initial products of cytosine oxidation. Because these products are not stable, virtually all biological studies have focused on the stable oxidation products of cytosine, including 5-hydroxycytosine, uracil glycols and 5-hydroxyuracil. Previously, we reported that the lifetime of cytosine glycols was greatly enhanced in double-stranded DNA, thus implicating these products in DNA repair and mutagenesis. In the present work, cytosine and uracil glycols were generated in double-stranded alternating co-polymers by oxidation with KMnO₄. The half-life of cytosine glycols in poly(dG-dC) was 6.5 h giving a ratio of dehydration to deamination of 5:1. At high substrate concentrations, the excision of cytosine glycols from poly(dG-dC) by purified endonuclease III was comparable to that of uracil glycols, whereas the excision of these substrates was 5-fold greater than that of 5-hydroxycytosine. Kinetic studies revealed that the V_max was several fold higher for the excision of cytosine glycols compared to 5-hydroxycytosine. In contrast to cytosine glycols, uracil glycols did not undergo detectable dehydration to 5-hydroxyuracil. Replacing poly(dG-dC) for poly(dI-dC) gave similar results with respect to the lifetime and excision of cytosine glycols. This work demonstrates the formation of cytosine glycols in DNA and their removal by base excision repair.