EcoKI with an amino acid substitution in any one of seven DEAD-box motifs has impaired ATPase and endonuclease activities.

For type I restriction systems, recently determined nucleotide sequences predict conserved amino acids in the subunit that is essential for restriction but not modification (HsdR). The conserved sequences emphasize motifs characteristic of the DEAD-box family of proteins which comprises putative helicases, and they identify a new candidate for motif IV. We provide evidence based on an analysis of Eco KI which supports both the relevance of DEAD-box motifs to the mechanism of restriction and the new definition of motif IV. Amino acid substitutions within the newly identified motif IV and those in six other previously identified DEAD-box motifs, but not in the original motif IV, confer restriction-deficient phenotypes. We have examined the relevance of the DEAD-box motifs to the restriction pathway by determining the steps permitted in vitro by the defective enzymes resulting from amino acid substitutions in each of the seven motifs. Eco KI purified from the seven restriction-deficient mutants binds to an unmethylated target sequence and, in the presence of AdoMet, responds to ATP by undergoing the conformational change essential for the pathway of events leading to DNA cleavage. The seven enzymes have little or no ATPase activity and no endonuclease activity, but they retain the ability to nick unmodified DNA, though at reduced rates. Nicking of a DNA strand could therefore be an essential early step in the restriction pathway, facilitating the ATP-dependent translocation of DNA, particularly if this involves DNA helicase activity.

The in vitro assembly of the EcoKI type I DNA restriction/modification enzyme and its in vivo implications.

Type I DNA restriction/modification enzymes protect the bacterial cell from viral infection by cleaving foreign DNA which lacks N6-adenine methylation within a target sequence and maintaining the methylation of the targets on the host chromosome. It has been noted that the genes specifying type I systems can be transferred to a new host lacking the appropriate, protective methylation without any adverse effect. The modification phenotype apparently appears before the restriction phenotype, but no evidence for transcriptional or translational control of the genes and the resultant phenotypes has been found. Type I enzymes contain three types of subunit, S for sequence recognition, M for DNA modification (methylation), and R for DNA restriction(cleavage), and can function solely as a M2S1 methylase or as a R2M2S1 bifunctional methylase/nuclease. We show that the methylase is not stable at the concentrations expected to exist in vivo, dissociating into free M subunit and M1S1, whereas the complete nuclease is a stable structure. The M1S1 form can bind the R subunit as effectively as the M2S1 methylase but possesses no activity; therefore, upon establishment of the system in a new host, we propose that most of the R subunit will initially be trapped in an inactive complex until the methylase has been able to modify and protect the host chromosome. We believe that the in vitro assembly pathway will reflect the in vivo situation, thus allowing the assembly process to at least partially explain the observations that the modification phenotype appears before the restriction phenotype upon establishment of a type I system in a new host cell.

The domains of a type I DNA methyltransferase. Interactions and role in recognition of DNA methylation.

The DNA methyltransferases of type I restriction-modification systems are trimeric enzymes composed of one DNA specificity (S) subunit and two modification (M) subunits. The S subunit contains two large regions, each of which recognizes one part of the split, asymmetrical DNA target sequence. Each M subunit contains an amino acid motif for binding the methyl group donor and cofactor, S-adenosyl methionine. The EcoKI methyltransferase has a strong preference for methylating a hemimethylated DNA target rather than an unmodified target. We have used partial proteolytic digestion of EcoKI methyltransferase to generate polypeptide domains that we have identified by amino acid sequencing. The S subunit was cut into two large, folded domains each containing one DNA binding region. Binding of DNA partially protected the S subunit from digestion. The M subunit was also cut into two large domains joined together by a short flexible loop, and a C-terminal tail region. The short loop contained part of the S-adenosyl methionine binding motif, and cofactor binding protected the loop and the two large domains from proteolysis. The C-terminal domain of M remained associated with the N-terminal domain of the S subunit even after the rest of the protein had been digested. The conformation of the tail region of the M subunit was sensitive to the methylation state of DNA in ternary complexes also containing S-adenosyl methionine, and could differentiate between unmethylated and hemimethylated DNA substrates.

Purification and characterization of the methyltransferase from the type 1 restriction and modification system of Escherichia coli K12.

The DNA methyltransferase component of the type I restriction and modification enzyme of Escherichia coli K12 has been purified. The active component, a trimer of molecular mass 170 kDa consisting of one DNA recognition subunit (S) and two modification subunits (M), showed the expected preference for modifying a hemimethylated substrate rather than an unmethylated one. Small amounts of the dimers M2 and M1S1 were also isolated. Subunit rearrangements of the three protein species occurred on ion exchange and heparin-agarose chromatography. Denaturation of the trimer gave folding intermediates, and these and the dimer forms isolated during purification may reflect the assembly of the protein in vivo. Enzyme activity was recovered on refolding the denatured protein by dilution of the denaturant. A comparison of the predicted isoelectric points of all known S subunits of type I restriction and modification enzymes revealed values that correlated with the arrangement of type I systems in several families. Electrostatic interactions may explain the different subunit stoichiometries observed during purification of type I enzymes and the differing preferences for hemimethylated DNA displayed by the three type I families.