Genomic hsd-Mu(lac) operon fusion mutants of Escherichia coli K-12

Tracking EcoKI and DNA fifty years on: a golden story full of surprises

1953 was a historical year for biology, as it marked the birth of the DNA helix, but also a report by Bertani and Weigle on 'a barrier to infection' of bacteriophage lambda in its natural host, Escherichia coli K-12, that could be lifted by 'host-controlled variation' of the virus. This paper lay dormant till Nobel laureate Arber and PhD student Dussoix showed that the lambda DNA was rejected and degraded upon infection of different bacterial hosts, unless it carried host-specific modification of that DNA, thus laying the foundations for the phenomenon of restriction and modification (R-M). The restriction enzyme of E.coli K-12, EcoKI, was purified in 1968 and required S-adenosylmethionine (AdoMet) and ATP as cofactors. By the end of the decade there was substantial evidence for a chromosomal locus hsdK with three genes encoding restriction (R), modification (M) and specificity (S) subunits that assembled into a large complex of >400 kDa. The 1970s brought the message that EcoKI cut away from its DNA recognition target, to which site the enzyme remained bound while translocating the DNA past itself, with concomitant ATP hydrolysis and subsequent double-strand nicks. This translocation event created clearly visible DNA loops in the electron microscope. EcoKI became the archetypal Type I R-M enzyme with curious DNA translocating properties reminiscent of helicases, recognizing the bipartite asymmetric site AAC(N6)GTGC. Cloning of the hsdK locus in 1976 facilitated molecular understanding of this sophisticated R-M complex and in an elegant 'pas de deux' Murray and Dryden constructed the present model based on a large body of experimental data plus bioinformatics. This review celebrates the golden anniversary of EcoKI and ends with the exciting progress on the vital issue of restriction alleviation after DNA damage, also first reported in 1953, which involves intricate control of R subunit activity by the bacterial proteasome ClpXP, important results that will keep scientists on the EcoKI track for another 50 years to come.

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.

A new restriction-modification system, KpnBI, recognized in Klebsiella pneumoniae

A unique DNA restriction-modification (R-M) system has been identified in the GM236 strain of Klebsiella pneumoniae using the newly isolated phage, SBS. The system was designated KpnBI. The gene (hsdRKpnBI) complementing the restriction activity of the KpnBI system was cloned in pBR322. The nucleotide sequence of the cloned DNA revealed one open reading frame (ORF) of 3035 bp. Analysis of the deduced amino-acid sequence shows seven helicase motifs which are common to the restriction (R) subunit of both type-I and type-III R-M systems. Computer analysis (Dendrogram) of the R polypeptide of KpnBI suggests a closer relationship to EcoR124/3I, a member of type-IC family, than to other representative type-I and type-III systems.

Restriction enzymes in cells, not eppendorfs

Restriction enzymes are essential reagents to molecular biologists, but their relevance to bacterial populations is less obvious. Most bacteria encode restriction and modification systems and these are commonly considered to be a barrier to phage infection. Current evidence also supports a more general role for them in genetic recombination.

The expression and regulation of hsdK genes after conjugative transfer

The type I restriction and modification genes of Escherichia coli can be transferred to other non-modified strains by conjugation without killing the recipient, implying that the restriction function must be regulated. In this study, two isogenic F' plasmids (r+K and r-K) served as donors in quantitative conjugation experiments with various restriction-deficient strains of E. coli and Salmonella typhimurium. Conjugation studies with hsd::lacZ operon fusions in F' plasmids indicate that both of the hsdK promoters, p(res) and pmod, express simultaneously following conjugative transfer. Thus these genes do not appear to be regulated at the transcriptional level. A spontaneous mutant of E. coli C was discovered that is presumably killed upon conjugative transfer of the hsdK genes (defined as a Crc- phenotype). The gene that is defective in the mutant was tentatively designated hsdC (control). Hfr gene replacement studies led to the localization of the putative hsdC gene between 6 and 16 min on the E. coli genetic map.

Delayed expression of in vivo restriction activity following conjugal transfer of Escherichia coli hsdK (restriction-modification) genes

Following conjugal transfer of the hsdK genes (hsdRK, hsdMK, and hsdSK) of Escherichia coli K-12, restriction activity was first detected only after approximately 15 generations, whereas modification activity was observed immediately. This sequential expression explains the establishment of hsdK genes in a nonmodified host and suggests regulation of restriction activity after conjugal transfer.