Sequence-specific protection of duplex DNA against restriction and methylation enzymes by pseudocomplementary PNAs

A new generation of PNAs, so-called pseudocomplementary PNAs (pcPNAs), which are able to target the designated sites on duplex DNA with mixed sequence of purines and pyrimidines via double-duplex invasion mode, has recently been introduced. It has been demonstrated that appropriate pairs of decameric pcPNAs block an access of RNA polymerase to the corresponding promoter. Here, we show that this type of PNAs protects selected DNA sites containing all four nucleobases from the action of restriction enzymes and DNA methyltransferases. We have found that pcPNAs as short as octamers form stable and sequence-specific complexes with duplex DNA in a very salt-dependent manner. In accord with a strand-invasion mode of complex formation, the pcPNA binding proceeds much faster with supercoiled than with linear plasmids. The double-duplex invasion complexes selectively shield specific DNA sites from BclI restriction endonuclease and dam methylase. The pcPNA-assisted protection against enzymatic methylation is more efficient when the PNA-binding site embodies the methylase-recognition site rather than overlaps it. We conclude that pcPNAs may provide the robust tools allowing to sequence-specifically manipulate DNA duplexes in a virtually sequence-unrestricted manner.     

鼠肝细胞癌变中DNA甲基化作用的研究

Activity of DNA methylase and DNA methylation level were measured from normal mouse liver, mouse liver charged with H22a ascitic hepatoma and H22a ascitic hepatoma cell by measuring incorporation of H3-methyl. S-Adenosyl-3H-methyl-methionine (3H-SAM) was used as methyl donor. DNA methylation level of different cells were measured by HP-LC. DNA methylase activity and DNA methylation level of H22a ascitic hepatoma, mouse liver charged with H22a ascitic hepatoma are lower than normal mouse liver. Treatments of antitumor drugs lead to a rising of DNA methylase activity of tumor cell, however, the DNA methylation level of tumor cell has not rised after such treatments.     

Comparison of DNA methylation patterns among mouse cell lines by restriction landmark genomic scanning.

Restriction landmark genomic scanning (RLGS) is a novel method which enables us to simultaneously visualize a large number of loci as two-dimensional gel spots. By this method, the status of DNA methylation can efficiently be determined by monitoring the appearance or disappearance of spots by using a methylation-sensitive restriction enzyme. In the present study, using RLGS with NotI, we examined, in comparison with a brain RLGS profile, the status of DNA methylation of more than 900 loci among three types of mouse cell lines: the embryonal carcinoma cell line P19, the stable mesenchymal cell line 10T1/2, and our established neuroepithelial (EM) cell lines. We found that the relative numbers of RLGS spots which appeared were less than 3.3% of those surveyed in all cell lines examined. However, 5 to 14% of spots disappeared, the numbers increasing with an increase in the length of the culture period, and many spots were commonly lost in 10T1/2 and in three EM cell lines. Thus, for these cell lines, many more spots disappeared than appeared. However, the numbers of spots disappearing and appearing were well balanced, and the ratio in P19 cells was almost equal to that in liver cells in vivo. These RLGS experimental observations suggested that permanent cell lines such as 10T1/2 are hypermethylated and that our newly established EM cell lines are also becoming heavily methylated at common loci. On the other hand, methylation and demethylation seem to be balanced in P19 cells in a manner similar to that in in vivo liver tissue.     

DNA methylation in mouse embryonic stem cells and development

Mammalian development is associated with considerable changes in global DNA methylation levels at times of genomic reprogramming. Normal DNA methylation is essential for development but, despite considerable advances in our understanding of the DNA methyltransferases, the reason that development fails when DNA methylation is deficient remains unclear. Furthermore, although much is known about the enzymes that cause DNA methylation, comparatively little is known about the mechanisms or significance of active demethylation in early development. In this review, we discuss the roles of the various DNA methyltransferases and their likely functions in development.     

DNA methylation in mouse gametogenesis

DNA methylation is involved in many biological processes and is particularly important for both development and germ cell differentiation. Several waves of demethylation and de novo methylation occur during both male and female germ line development. This has been found at both the gene and all genome levels, but there is no demonstrated correlation between them. During the postnatal germ line development of spermatogenesis, we found very complex and drastic DNA methylation changes that we could correlate with chromatin structure changes. Thus, detailed studies focused on localization and expression pattern of the chromatin proteins involved in both DNA methylation, histone tails modification, condensin and cohesin complex formation, should help to gain insights into the mechanisms at the origin of the deep changes occurring during this particular period.     

DNA methylation in mouse A-repeats in DNA methyltransferase-knockout ES cells and in normal cells determined by bisulfite genomic sequencing

Mouse ES cells with a null mutation of the known DNA methyltransferase retain some residual DNA methylation and can methylate foreign sequences de novo. We have used bisulfite genomic sequencing to examine the sequence specificity and distributions of methylation of a hypermethylated CG island sequence, mouse A-repeats. There were 13 CG dinucleotides in the region examined, 12 of which were methylated to variable extents in all DNAs. We found that: (1) there is considerable residual DNA methylation in ES cells lacking the known DNA methyltransferase (29% of normal methylation in the complete knockout ES DNA); (2) this other activity methylates at exactly the same CG sites as the major methyltransferase; and (3) differences in the distribution of methylated sites between A-repeats in these DNAs are consistent with this other activity methylating in a random de novo fashion. Also, the lack of any methylation in non-CG sites argues that, in other studies where non-CG methylation sites have been found by bisulfite sequencing, detection of such sites of non-CG methylation is not an inherent artifact in this methodology.     

Changes in methylation of tissue cultured soybean cells detected by digestion with the restriction enzymes HpaII and MspI

Each of the tandemly arranged 5S RNA genes of soybean contain two CCGG sites which, if unmethylated, can be digested by both MspI and HpaII. Methylation of the internal cytosine (CmeCGG) prevents digestion by HpaII but allows digestions by MspI.Suspension cultures were prepared from soybean plants and the DNA from these cultures was examined for the susceptibility of 5S RNA genes to digestion by MspI and HpaII. 5S genes from DNA extracted from intact plants can be partially digested with MspI but not at all by HpaII. In contrast, shortly after cells were cultured the 5S RNA could be hydrolyzed by both HpaII and MspI. After prolonged cell culture, the 5S genes from some cell lines were found to have become partially or even completely resistant to HpaII digestion. The results suggest that lack of methylation can occur when cells are cultured and that such methylation may play a role in the heritable changes observed in cell culture.Research supported by Grant 01498 from the National Institutes of Environmental Health Sciences     

Genome modifications in plant cells by custom-made restriction enzymes

Genome editing, i.e. the ability to mutagenize, insert, delete and replace sequences, in living cells is a powerful and highly desirable method that could potentially revolutionize plant basic research and applied biotechnology. Indeed, various research groups from academia and industry are in a race to devise methods and develop tools that will enable not only site-specific mutagenesis but also controlled foreign DNA integration and replacement of native and transgene sequences by foreign DNA, in living plant cells. In recent years, much of the progress seen in gene targeting in plant cells has been attributed to the development of zinc finger nucleases and other novel restriction enzymes for use as molecular DNA scissors. The induction of double-strand breaks at specific genomic locations by zinc finger nucleases and other novel restriction enzymes results in a wide variety of genetic changes, which range from gene addition to the replacement, deletion and site-specific mutagenesis of endogenous and heterologous genes in living plant cells. In this review, we discuss the principles and tools for restriction enzyme-mediated gene targeting in plant cells, as well as their current and prospective use for gene targeting in model and crop plants.     

Recognition of native DNA methylation by the PvuII restriction endonuclease

Recognizing the methylation status of specific DNA sequences is central to the function of many systems in eukaryotes and prokaryotes. Restriction–modification systems have to distinguish between ‘self’ and ‘non-self’ DNA and depend on the inability of restriction endonucleases to cleave their DNA substrates when the DNA is appropriately methylated. These endonucleases thus provide a model system for studying the recognition of DNA methylation by proteins. We have characterized the interaction of R·PvuII with DNA containing the physiologically relevant N4-methylcytosine modification. R·PvuII binds ^N4mC-modified DNA and cleaves it very slowly. Methylated strands in hemimethylated duplexes were cleaved at a higher rate than in fully methylated duplexes, in parallel with a higher binding affinity for hemimethylated DNA. The co-crystal structures of R·PvuII–DNA, together with a mutagenesis study, have implicated specific amino acids in recognition of the methylatable base; one of these is His84. We report that replacing His84 with Ala reduced the rate of cleavage of unmodified DNA but, in contrast, slightly increased the cleavage of ^N4mC-modified DNA.     

MethylRAD: a simple and scalable method for genome-wide DNA methylation profiling using methylation-dependent restriction enzymes

Characterization of dynamic DNA methylomes in diverse phylogenetic groups has attracted growing interest for a better understanding of the evolution of DNA methylation as well as its function and biological significance in eukaryotes. Sequencing-based methods are promising in fulfilling this task. However, none of the currently available methods offers the ‘perfect solution’, and they have limitations that prevent their application in the less studied phylogenetic groups. The recently discovered Mrr-like enzymes are appealing for new method development, owing to their ability to collect 32-bp methylated DNA fragments from the whole genome for high-throughput sequencing. Here, we have developed a simple and scalable DNA methylation profiling method (called MethylRAD) using Mrr-like enzymes. MethylRAD allows for de novo (reference-free) methylation analysis, extremely low DNA input (e.g. 1 ng) and adjustment of tag density, all of which are still unattainable for most widely used methylation profiling methods such as RRBS and MeDIP. We performed extensive analyses to validate the power and accuracy of our method in both model (plant Arabidopsis thaliana) and non-model (scallop Patinopecten yessoensis) species. We further demonstrated its great utility in identification of a gene (LPCAT1) that is potentially crucial for carotenoid accumulation in scallop adductor muscle. MethylRAD has several advantages over existing tools and fills a void in the current epigenomic toolkit by providing a universal tool that can be used for diverse research applications, e.g. from model to non-model species, from ordinary to precious samples and from small to large genomes, but at an affordable cost.     

Cleavage of mispaired heteroduplex DNA substrates by numerous restriction enzymes

The utility of restriction endonucleases as a tool in molecular biology is in large part due to the high degree of specificity with which they cleave well-characterized DNA recognition sequences. The specificity of restriction endonucleases is not absolute, yet many commonly used assays of biological phenomena and contemporary molecular biology techniques rely on the premise that restriction enzymes will cleave only perfect cognate recognition sites. In vitro, mispaired heteroduplex DNAs are commonly formed, especially subsequent to polymerase chain reaction amplification. We investigated a panel of restriction endonucleases to determine their ability to cleave mispaired heteroduplex DNA substrates. Two straightforward, non-radioactive assays are used to evaluate mispaired heteroduplex DNA cleavage: a PCR amplification method and an oligonucleotide-based assay. These assays demonstrated that most restriction endonucleases are capable of site-specific double-strand cleavage with heteroduplex mispaired DNA substrates, however, certain mispaired substrates do effectively abrogate cleavage to undetectable levels. These data are consistent with mispaired substrate cleavage previously reported for Eco RI and, importantly, extend our knowledge of mispaired heteroduplex substrate cleavage to 13 additional enzymes.     

Two methods to detect DNA fragments produced by restriction enzymes

This report summarizes two methods for detecting limited amounts of DNA from restriction endonuclease digests. The first is a photographic system for visualizing ethidium bromide-stained DNA fragments in agarose gels which can detect as little as 50-100 pg DNA per band. The second technique is direct sulfonation of DNA fragments bound to nylon membranes followed by visualization of the fragments by nonradioactive immunoblot methods. The immunohistochemical staining can detect 10 pg DNA per band. The direct sulfonation technique is not intended to identify specific DNA sequences; DNA-DNA hybridization with sulfonated probes has previously been described (P. Lebacq, D. Squalli, M. Duchenne, P. Poulety, and M. Johannes (1988) J. Biochem. Biophys. Methods 15, 255-266). Direct sulfonation can be used when samples are relatively free of contaminating nucleic acids and is a useful alternative to end-labeling. These highly sensitive techniques may be suitable when the DNA source is of limited quantity or in instances where radiolabeling is not permitted.     

Qualitative differences between replicative and repair synthesis of DNA in normal and transformed mouse cells as measured by precursor discrimination

Inhibitors of DNA polymerase alpha such as aphidicolin (APC) or 1-beta-D-arabinofuranosyl-cytosine (araC) cause DNA-strand breaks to accumulate after UV-irradiation, at sites where repair resynthesis is inhibited. Transformed cells accumulate fewer such breaks than normal cells do; this may be due to differences in the extent, or the nature, of excision-repair synthesis in transformed and in normal cells. We have looked for differences in the nature of repair synthesis, comparing the labelling of DNA by deoxycytidine (dC) and araC through UV-induced repair in normal and transformed mouse cells. We have made parallel determinations of precursor discrimination in replicative synthesis, and find that normal cells discriminate better against araC in replicative synthesis than do transformed cells. But repair synthesis discriminates against araC less than normal replicative synthesis does, to a similar extent in both cell types. Thus, there are qualitative differences between the DNA polymerases engaged in UV excision repair and replication in normal and transformed mouse cells; but there is no evidence for a predominantly araC-insensitive repair synthesis in transformed cells, such as might account for the difference in break accumulation.     

DNA methylation levels in normal and chemically-transformed mouse 3T3 cells

Normal mouse embryo 3T3 cell cultures and those oncogenically transformed by the chemical carcinogens benzo(a)pyrene and methylcholanthrene were analyzed by high performance liquid chromatography to determine the 5-methylcytosine to cytosine base ratios in their total genomic DNA. The DNA methylation levels appear to be approximately equal in the three cell lines examined.     

Cell-wall-hydrolysing enzymes in wall formation as measured by pollen-tube extension

Summary Cell-wall-softening enzymes affect the plasticity of the tip wall of pollen tubes and modity tube elongation. Length of pear pollen tubes is increased by the addition of -1,3-glucanase at the beginning of in-vitro germination. The longer tubes after 3 hours are primarily the result of earlier germination. Application of -1,4-glucanase or pectinase to germinating pollen does not affect germination but enhances the growth rate of 1-hour-old pollen tubes. The stimulating effects of -1,4-glucanase and pectinase are additive. Denatured enzymes had no effect. Proteinase, pectin esterase, acid phosphatase and -amylase only inhibited growth and germination. Replacing the medium 1 hour after germination begins stops pollen-tube growth; growth can be restored by adding cellulase-pectinase mixtures to the replacement medium. These results provide evidence that cellulase and pectinase are important in pollen-wall extension, and that callose-hydrolyzing enzymes are involved in pollen germination but not wall extension.A contribution of the Florida Agricultural Experiment Station, Journal Series No. 3069.