Isolation and characterization of Escherichia coli dnaA amber mutants

The Ser176 of T4 endonuclease IV is crucial for the restricted and polarized dC-specific cleavage of single-stranded DNA implicated in restriction of dC-containing DNA in host Escherichia coli

Endonuclease (Endo) IV encoded by denB of bacteriophage T4 is an enzyme that cleaves single-stranded (ss) DNA in a dC-specific manner. Also the growth of dC-substituted T4 phage and host Escherichia coli cells is inhibited by denB expression presumably because of the inhibitory effect on replication of dC-containing DNA. Recently, we have demonstrated that an efficient cleavage by Endo IV occurs exclusively at the 5′-proximal dC (dC₁) within a hexameric or an extended sequence consisting of dC residues at the 5′-proximal and the 3′-proximal positions (dCs tract), in which a third dC residue within the tract affects the polarized cleavage and cleavage rate. Here we isolate and characterize two denB mutants, denB(W88R) and denB(S176N). Both mutant alleles have lost the detrimental effect on the host cell. Endo IV(W88R) shows no enzymatic activity (<0.4% of that of wild-type Endo IV). On the other hand, Endo IV(S176N) retains cleavage activity (17.5% of that of wild-type Endo IV), but has lost the polarized and restricted cleavage of a dCs tract, indicating that the Ser¹⁷⁶ residue of Endo IV is implicated in the polarized cleavage of a dCs tract which brings about a detrimental effect on the replication of dC-containing DNA.

Biochemical analysis of the substrate specificity and sequence preference of endonuclease IV from bacteriophage T4, a dC-specific endonuclease implicated in restriction of dC-substituted T4 DNA synthesis

Endonuclease IV encoded by denB of bacteriophage T4 is implicated in restriction of deoxycytidine (dC)-containing DNA in the host Escherichia coli. The enzyme was synthesized with the use of a wheat germ cell-free protein synthesis system, given a lethal effect of its expression in E.coli cells, and was purified to homogeneity. The purified enzyme showed high activity with single-stranded (ss) DNA and denatured dC-substituted T4 genomic double-stranded (ds) DNA but exhibited no activity with dsDNA, ssRNA or denatured T4 genomic dsDNA containing glucosylated deoxyhydroxymethylcytidine. Characterization of Endo IV activity revealed that the enzyme catalyzed specific endonucleolytic cleavage of the 5' phosphodiester bond of dC in ssDNA with an efficiency markedly dependent on the surrounding nucleotide sequence. The enzyme preferentially targeted 5'-dTdCdA-3' but tolerated various combinations of individual nucleotides flanking this trinucleotide sequence. These results suggest that Endo IV preferentially recognizes short nucleotide sequences containing 5'-dTdCdA-3', which likely accounts for the limited digestion of ssDNA by the enzyme and may be responsible in part for the indispensability of a deficiency in denB for stable synthesis of dC-substituted T4 genomic DNA.

Initiation of chromosomal DNA replication which is stimulated without oversupply of DnaA protein in Escherichia coli

The temperature-sensitive dnaA46 mutation in Escherichia coli can be phenotypically suppressed at 42 degrees C by oversupply of GroELS proteins, and the suppressed cells grow extremely slowly at 30 degrees C. We found that the phenotype of dnaA46 showing this cold sensitivity was dominant over the phenotype of dnaA+, and could not be rescued by introduction of oriC-independent replication systems. These results suggest that the cold sensitivity was not caused by a simple defect in replication. When a growing culture of a dnaA46 strain with a GroELS-overproducing plasmid was shifted from 42 degrees to 30 degrees C in the presence of chloramphenicol, the chromosomal DNA replicated excessively. Initiation of replication occurred at the site of oriC repeatedly four or five times during a 4 h incubation period without concomitant protein synthesis, indicating an excessive capacity for initiation. Such overreplication did not take place at 42 degrees C in the suppressed dnaA46 strain, or at either temperature in GroELS-oversupplied dnaA+ cells. No significant difference was detected between the cellular content of DnaA protein in suppressed cells where the initiation capacity was abnormally high, and that in wild-type cells in which the initiation capacity was normal. Thus, DnaA protein might function in vivo through some phase control mechanism for initiation, apart from a simple regulation by its total amount. A possible mechanism is proposed based on the participation of GroELS proteins in protein folding.

Requirement of the Escherichia coli dnaA gene function for integrative suppression of dnaA mutations by plasmid R 100-1

The phenotype of Escherichia coli dnaA missense and nonsense mutations was integratively suppressed by plasmid R100-1. The suppressed strains, however, could not survive when the dnaA function was totally inactivated. This was demonstrated by the inability of replacing the dnaA allele in the suppressed strain by a dnaA::Tn10 insertion using phage P1-mediated transduction. When the intact dnaA+ allele was additionally supplied by a specialized transducing phage, lambda imm21 dnaA+, which integrated at the att lambda site on the E. coli chromosome, then the dnaA::Tn10 insertion, together with a delta oriC deletion, were able to be introduced into the suppressed strain. Thus, the mechanisms of dnaA function for oriC and for the replication origin of R100-1 may not be quite the same.

Requirement of the Escherichia coli dnaA gene function for ori-2-dependent mini-F plasmid replication

The mini-F plasmids pSC138, pKP1013, and pKV513 were unable to transform Escherichia coli cells with a dnaA-defective mutation under nonpermissive conditions. The dnaA defect was suppressed for host chromosome replication either by the simultaneous presence of the rnh-199 (amber) mutation or by prophage P2 sig5 integrated at the attP2II locus on the chromosome, both providing new origins for replication independent of dnaA function. The dnaA mutations tested were dnaA17, dnaA5, and dnaA46. dnaA5 and dnaA46 are missense mutations. dnaA17 is an amber mutation whose activity is controlled by the temperature-sensitive amber suppressor supF6. Under permissive conditions in which active DnaA protein was available, the mini-F plasmids efficiently transformed the cells. However, the transformants lost the plasmid as the cells multiplied under conditions in which DnaA protein was inactivated or its synthesis was arrested. As controls, plasmids pSC101 and pBR322 were examined along with mini-F; pSC101 behaved in the same manner as mini-F, showing complete dependence on dnaA for stable maintenance, whereas pBR322 was indifferent to the dnaA defect. Thus, ori-2-dependent mini-F plasmid replication seems to require active dnaA gene function. This notion was strengthened by the results of deletion analysis which revealed that integrity of at least one of the two DnaA boxes present as a tandem repeat in ori-2 was required for the origin activity of mini-F replication.

Autoregulation of the dnaA gene of Escherichia coli K12

Regulation of the dnaA gene, which codes for an essential factor for the initiation of replication from the chromosomal origin, was studied in vivo using transcriptional and translational gene fusions. We found that the dnaA gene was autoregulated over a 30-fold range by the activity of dnaA protein. Expression from the dnaA promoter region of a dnaA"lacZ fusion was inhibited up to sevenfold by surplus dnaA protein and was stimulated up to fivefold upon thermoinactivation of the mutant protein in five different dnaA(Ts) strains. The autoregulation was found to be exerted at transcription from the major dnaA promoter and was eliminated by deletion of sequences around position -65 of this promoter where a 9-bp sequence, which is also found four times in the chromosomal origin, is located.

Allele-specific suppression of dnaA(Ts) mutations by rpoB mutations in Escherichia coli

Extragenic suppressor mutations for dnaA (Ts) mutations mapping in the rpoB gene (beta-subunit of RNA polymerase) were isolated by selection of spontaneous rifampicin resistant mutants and screening for temperature resistance. Six rpoB mutations were analysed for suppression of 12 different dnaA (Ts) mutations. The analysis showed that all dnaA(Ts) mutations could be suppressed by some rpoB mutation. All six rpoB mutations showed allele specificity when tested for suppression of 12 dnaA(Ts) mutant strains. The allele specificity was found to correlate with the map position of the dnaA (Ts) alleles.

Structural analysis of the dnaA and dnaN genes of Escherichia coli

The nucleotide sequence of the entire region containing the Escherichia coli dnaA and dnaN genes was determined. Base substitutions by such mutations as dnaA46, dnaA167, dnaN59, and dnaN806 were also identified. Analyses of coding frames, the mutational base substitutions, and other data indicate that dnaN follows dnaA, both have the same orientation, and are separated by only 4 bp. The deduced amino acid sequence specifies Mrs and isoelectric points consistent with those of the previously identified gene products. The transcriptional initiation site of the dnaA gene was assigned by analysis of in vitro RNA products. Examination of the intercistronic sequence and analysis of in vitro transcription supported the notion that the dnaA and dnaN genes constitute a single operon.

Effect of dnaA and rpoB mutations on attenuation in the trp operon of Escherichia coli

The rate of synthesis of tryptophan synthetase was found to be increased by heat inactivation of the dnaA protein in three dnaA mutants temperature sensitive for initiation of DNA replication. The effect of the dnaA mutations was dependent upon the presence of an intact attenuator in the tryptophan operon. The activity of the mutated dnaA protein at the tryptophan attenuator and its activity as initiator for chromosome replication decreased gradually with increasing temperature. Two rpoB mutations that suppress the temperature defect of the dnaA46 mutation in initiation of replication were tested for effects on attenuation in the tryptophan operon. One of the rpoB mutations caused increased transcription termination at the attenuator independent of the dnaA allele, whereas the other mutation had no effect. Expression of the histidine and threonine operons, which are also regulated by attenuation, was unaffected by the dnaA mutations.

Purified dnaA protein in initiation of replication at the Escherichia coli chromosomal origin of replication

Soluble protein fractions from Escherichia coli dnaA+ cells but not dnaA temperature-sensitive cells replicate plasmids containing the E. coli chromosomal origin of replication (oriC). Complementation of these mutant fractions provided an assay for dnaA protein activity in initiation of replication at oriC. From a strain (constructed in vitro) that overproduces the dnaA protein more than 200-fold, the 52,000-dalton polypeptide was purified to near homogeneity. Although the protein tends to aggregate, monomer-sized protein purified by high-performance liquid chromatography is fully active for replication. It binds specifically and tightly to oriC in a supercoiled plasmid as judged by a Millipore filter-binding assay and by protection of the unique HindIII site within the oriC sequence. In the oriC replication reaction, dnaA protein acts at an early step preceding DNA synthesis.

Organization and transcription of the dnaA and dnaN genes of Escherichia coli

The locations of the linked dnaA and dnaN genes of Escherichia coli in a specialized transducing lambda phage genome have been determined by electron microscopic heteroduplex analysis, using phages with deletions or insertions in the dnaA or dnaN gene. The transcription initiation sites for the dna genes were also localized by electron microscopic analysis of DNA-RBA heteroduplex molecules formed between the E. coli DNA fragment of the phage genome and the in vitro transcription products of the fragment. The dnaN gene was found to be transcribed in the same direction as the dnaA gene, and predominantly from the promoter of the dnaA gene.