Is the DNA of virus T7 methylated?

A universal fluorescence-based toolkit for real-time quantification of DNA and RNA nuclease activity

DNA and RNA nucleases play a critical role in a growing number of cellular processes ranging from DNA repair to immune surveillance. Nevertheless, many nucleases have unknown or poorly characterized activities. Elucidating nuclease substrate specificities and co-factors can support a more definitive understanding of cellular mechanisms in physiology and disease. Using fluorescence-based methods, we present a quick, safe, cost-effective, and real-time versatile nuclease assay, which uniquely studies nuclease enzyme kinetics. In conjunction with a substrate library we can now analyse nuclease catalytic rates, directionality, and substrate preferences. The assay is sensitive enough to detect kinetics of repair enzymes when confronted with DNA mismatches or DNA methylation sites. We have also extended our analysis to study the kinetics of human single-strand DNA nuclease TREX2, DNA polymerases, RNA, and RNA:DNA nucleases. These nucleases are involved in DNA repair, immune regulation, and have been associated with various diseases, including cancer and immune disorders.

In vitro packaging of heteroduplex bacteriophage T7 DNA: evidence for repair of mismatched bases

Heteroduplex DNA molecules that were wild type or contained combinations of amber, missense, and temperature-sensitive mutations were prepared from bacteriophage T7. These DNA molecules were then encapsulated in in vitro packaging reactions so as to produce infective T7 phage. The genotypes of the phage were examined to determine the degree to which mismatched base pairs in the heteroduplex had been corrected. The data show that conversion of the mismatches took place either during in vitro packaging or immediately after infection of either an Escherichia coli or Shigella sonnei host. The mode of mismatch conversion observed in these experiments was independent of the host mutH, mutL, mutS, and uvrD genes. There was no significant amount of discrimination between markers on either of the two complementary strands. The observed frequency of conversion of a mismatch depended on the genetic marker being monitored and on experimental conditions but was generally in the range between 5 and 30%.

DNA methylation of bacterial viruses T3 and T7 by different DNA methylases in Escherichia coli K12 cells

We have investigated the susceptibility of the genomes of the related bacteriophages T3 and T7 to the three major DNA methyltransferases (EcoK, dam, dcm) of their host, Escherichia coli K12. In vivo the EcoK host specificity enzyme only methylates the DNA of ocr- phages. This is due to an inhibition of the enzyme by the phage ocr+ gene product, which had previously been shown to be an inhibitor of the restriction endonuclease. EcoK-specific DNA methylation protects the ocr- viruses after one growth cycle on these host cells against the action of corresponding restriction endonuclease EcoK. Owing to the unique S-adenosyl-L-methionine hydrolase (sam+) activity of the T3-coded ocr+ protein, the T3 DNA is absolutely devoid of the methylated bases 6-methylaminopurine and 5-methylcytosine. In contrast to this, T7 derivatives and sam- derivatives of T3 carry a small number of about 2-4 molecules 6-methylaminopurine and 5-methylcytosine per genome. The presence of 6-methylaminopurine is due to dam methylation, though the majority of dam sites remain unmethylated. In vivo as well as in vitro the ocr+ protein has no influence on the activities of the dam and dcm methylase. The experiments gave some evidence for the existence of a second cytosine methylase in E. coli K12. Besides dam and dcm recognition sites being undermethylated, their absolute number in T3 and T7 DNAs is far below the expected value. Moreover, one of the two dcm sites present in T7 (Studier strain) is missing in our T7 strain owing to a 1300-base-pair deletion in gene 0.7.

Evidence that Escherichia coli virus T1 induces a DNA methyltransferase

DNA of Escherichia coli virus T1 is resistant to MboI cleavage and appears to be heavily methylated. Analysis of methylation by the isoschizomeric restriction enzymes Sau3AI and DpnI revealed that recognition sites for E. coli DNA adenine methylase (dam methylase) are methylated. The same methylation pattern was found for virus T1 DNA grown on an E. coli dam host, indicating a T1-specific DNA methyltransferase.

Absence in Bacillus subtilis and Staphylococcus aureus of the sequence-specific deoxyribonucleic acid methylation that is conferred in Escherichia coli K-12 by the dam and dcm enzymes

Restriction analysis of plasmid pHV14 deoxyribonucleic acid isolated from Escherichia coli K-12, Bacillus subtilis, and staphylococcus aureus with restriction endonucleases MboI, Sau3AI, and EcoRII was used to study the methylation of those nucleotide sequences which in E. coli contain the major portions of N6-methyladenine and 5-methylcytosine. The results showed that neither B. subtilis nor S. aureus methylates deoxyribonucleic acid at the same sites and nucleotides which are recognized and methylated by dam and dcm enzymes in E. coli K-12.

Asymmetric repair of bacteriophage T7 heteroduplex DNA

Heteroduplex DNA molecules were prepared in vitro using one strand of DNA carrying a point mutation and one strand of the corresponding wild-type DNA. The heteroduplex DNA was transfected into competent bacteria and the progeny genotypes in the resulting infective centers were determined. From the results we conclude that about 80% of all transfected DNA molecules are repaired before DNA replication starts. This fraction of repaired DNA is independent of the location of the mismatched nucleotide pair. However, mismatch correction occurs preferentially on the H strand of the heteroduplex DNA. The repair does not depend on a known phage coded function but requires the active bacterial genes mutU, mutH, mutS and probably mutL.