Conditionally lethal amber mutations in the dnaA region of the Escherichia coli chromosome that affect chromosome replication

H-NS, IHF, and DnaA lead to changes in nucleoid organizations, replication initiation, and cell division

Histone-like nucleoid-structuring protein (H-NS) and integration host factor (IHF) are major nucleoid-associated proteins, and DnaA, a replication initiator, may also be related with nucleoid compaction. It has been shown that protein-dependent DNA compaction is related with many aspects of bacterial physiology, including transcription, DNA replication, and site-specific recombination. However, the mechanism of bacterial physiology resulting from nucleoid compaction remains unknown. Here, we show that H-NS is important for correct nucleoid compaction in a medium-independent manner. H-NS-mediated nucleoid compaction is not required for correct cell division, but the latter is dependent on H-NS in rich medium. Further, it is found that the IHFα-mediated nucleoid compaction is needed for correct cell division, and the effect is dependent on medium. Also, we show that the effects of H-NS and IHF on nucleoid compaction are cumulative. Interestingly, DnaA also plays an important role in nucleoid compaction, and the effect of DnaA on nucleoid compaction appears to be related to cell division in a medium-dependent manner. The results presented here suggest that scrambled initiation of replication, improper cell division, and slow growth is likely associated with disturbances in nucleoid organization directly or indirectly.

Translational Control using an Expanded Genetic Code

A bio-orthogonal and unnatural substance, such as an unnatural amino acid (Uaa), is an ideal regulator to control target gene expression in a synthetic gene circuit. Genetic code expansion technology has achieved Uaa incorporation into ribosomal synthesized proteins in vivo at specific sites designated by UAG stop codons. This site-specific Uaa incorporation can be used as a controller of target gene expression at the translational level by conditional read-through of internal UAG stop codons. Recent advances in optimization of site-specific Uaa incorporation for translational regulation have enabled more precise control over a wide range of novel important applications, such as Uaa-auxotrophy-based biological containment, live-attenuated vaccine, and high-yield zero-leakage expression systems, in which Uaa translational control is exclusively used as an essential genetic element. This review summarizes the history and recent advance of the translational control by conditional stop codon read-through, especially focusing on the methods using the site-specific Uaa incorporation.

Crosstalk between DnaA protein, the initiator of Escherichia coli chromosomal replication, and acidic phospholipids present in bacterial membranes

Anionic (i.e., acidic) phospholipids such as phosphotidylglycerol (PG) and cardiolipin (CL), participate in several cellular functions. Here we review intriguing in vitro and in vivo evidence that suggest emergent roles for acidic phospholipids in regulating DnaA protein-mediated initiation of Escherichia coli chromosomal replication. In vitro acidic phospholipids in a fluid bilayer promote the conversion of inactive ADP-DnaA to replicatively proficient ATP-DnaA, yet both PG and CL also can inhibit the DNA-binding activity of DnaA protein. We discuss how cellular acidic phospholipids may positively and negatively influence the initiation activity of DnaA protein to help assure chromosomal replication occurs once, but only once, per cell-cycle. Fluorescence microscopy has revealed that PG and CL exist in domains located at the cell poles and mid-cell, and several studies link membrane curvature with sub-cellular localization of various integral and peripheral membrane proteins. E. coli DnaA itself is found at the cell membrane and forms helical structures along the longitudinal axis of the cell. We propose that there is cross-talk between acidic phospholipids in the bacterial membrane and DnaA protein as a means to help control the spatial and temporal regulation of chromosomal replication in bacteria.

Regulation of DnaA assembly and activity: taking directions from the genome

To ensure proper timing of chromosome duplication during the cell cycle, bacteria must carefully regulate the activity of initiator protein DnaA and its interactions with the unique replication origin oriC. Although several protein regulators of DnaA are known, recent evidence suggests that DnaA recognition sites, in multiple genomic locations, also play an important role in controlling assembly of pre-replicative complexes. In oriC, closely spaced high- and low-affinity recognition sites direct DnaA-DnaA interactions and couple complex assembly to the availability of active DnaA-ATP. Additional recognition sites at loci distant from oriC modulate DnaA-ATP availability by repressing new synthesis, recharging inactive DnaA-ADP, or titrating DnaA. Relying on genomic DnaA binding sites, as well as protein regulators, to control DnaA function appears to provide the best combination of high precision and dynamic regulation necessary to couple DNA replication with cell growth over a range of nutritional conditions.

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

Ribonuclease E organizes the protein interactions in the Escherichia coli RNA degradosome

The Escherichia coli RNA degradosome is the prototype of a recently discovered family of multiprotein machines involved in the processing and degradation of RNA. The interactions between the various protein components of the RNA degradosome were investigated by Far Western blotting, the yeast two-hybrid assay, and coimmunopurification experiments. Our results demonstrate that the carboxy-terminal half (CTH) of ribonuclease E (RNase E) contains the binding sites for the three other major degradosomal components, the DEAD-box RNA helicase RhlB, enolase, and polynucleotide phosphorylase (PNPase). The CTH of RNase E acts as the scaffold of the complex upon which the other degradosomal components are assembled. Regions for oligomerization were detected in the amino-terminal and central regions of RNase E. Furthermore, polypeptides derived from the highly charged region of RNase E, containing the RhlB binding site, stimulate RhlB activity at least 15-fold, saturating at one polypeptide per RhlB molecule. A model for the regulation of the RhlB RNA helicase activity is presented. The description of RNase E now emerging is that of a remarkably complex multidomain protein containing an amino-terminal catalytic domain, a central RNA-binding domain, and carboxy-terminal binding sites for the other major components of the RNA degradosome.

Amplification and cloning of the Mycobacterium tuberculosis dnaA gene

To identify and subsequently clone the gene encoding the DnaA protein, degenerate oligodeoxyribonucleotide (oligo) primers targeted against two highly conserved domains of the eubacterial DnaA were used to amplify a 780-bp DNA region spanning the two primers from genomic DNA preparations of Mycobacterium tuberculosis (Mt), M. bovis (Mb) and M. avium (Ma). Nucleotide (nt) sequences and deduced amino acid (aa) sequences of these fragments revealed homologies with each other and with the corresponding regions from other bacteria. Using an oligo specific to Mt dnaA as a probe, the Mt genomic DNA cosmid libraries propagated in Escherichia coli were screened and a cosmid DNA clone hybridizing with the oligo was identified. Furthermore, a 5-kb DNA fragment containing the Mt dnaA was subcloned into a pUC18 vector.

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.

Nalidixic acid-resistant mutations of the gyrB gene of Escherichia coli

DNA fragments of 3.4 kb containing the gyrB gene were cloned from Escherichia coli KL-16 and from spontaneous nalidixic acid-resistant mutants. The mutations (nal-24 and nal-31) had been determined to be in the gyrB gene by transduction analysis. Nucleotide sequence analysis of the cloned DNA fragments revealed that nal-24 was a G to A transition at the first base of the 426th codon of the gyrB gene, resulting in an amino acid change from aspartic acid to asparagine, and nal-31 was an A to G transition at the first base of the 447th codon, resulting in an amino acid change from lysine to glutamic acid. This indicates tha mutations in the gyrB gene are responsible for nalidixic acid resistance.

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.

Cloning and deletion mapping of the recF dnaN region of the Escherichia coli chromosome

By cloning a 3.6-kb EcoRI fragment of the Escherichia coli chromosome with pBR322 we located more precisely recF relative to dnaN. By deletion mapping we localized functional recF to a 1.65-kb region of the cloned fragment and allowed rough mapping of the C terminus of dnaN. Cloned recF+, separated from functional flanking genes dnaN and gyrB, complemented chromosomal recF mutations presumably by coding for a cytodiffusible product. The protein encoded by dnaN was observed as a band on a polyacrylamide gel from minicells. Identification of a recF protein was not made.

Regulation of DNA synthesis and capacity for initiation in DNA temperature mutants of Escherichia coli. III. Synthesis of the dnaA protein and of DNA-binding proteins

The synthesis and action of the dnaA product with respect to DNA initiation and the synthesis of DNA-binding proteins in Escherichia coli was examined. Results indicate that when dnaA product is irreversibly denatured and must be synthesized before initiation can occur, its synthesis and action appear to be complete approximately 30 min before initiation takes place. However, in mutants whose dnaA product is temperature reversible the action of the dnaA product appears to occur near the time of initiation. Examination of the DNA-binding proteins from the mutants suggests that a 53 kd protein, possibly the dnaA product, may be synthesized at the time of initiation under normal conditions at permissive temperature. The presence of active dnaA product appears to trigger the synthesis of a 60-65 kd protein which may be responsible for preventing another immediate initiation event.

An amber mutation in the gene rpsA for ribosomal protein S1 in Escherichia coli

An amber mutation has been induced in the gene rpsA (which codes for ribosomal protein S1) of Escherichia coli K-12 strain in the presence of an amber suppressor (supD) and mutations sueA, sueB and sueC that additively enhance the efficiency of suppression. That the amber mutation has occurred in the gene rpsA was confirmed by complementation with a plasmid which carried the wild-type allele of rpsA. The mutation is lethal in the absence of an amber suppressor, indicating that ribosomal protein S1 is indispensable to E. coli.

Functional cooperation of the dnaE and dnaN gene products in Escherichia coli

A system was designed to isolate second-site intergenic suppressors of a thermosensitive mutation of the dnaE gene of Escherichia coli. The dnaE gene codes for the alpha subunit of DNA polymerase III [McHenry, C. S. & Crow, W. (1979) J. Biol. Chem. 254, 1748-1753]. One such suppressor, named sueA77, was finely mapped and found to be located at 82 min on the E. coli chromosome, between dnaA and recF, and within the dnaN gene [Sakakibara, Y. & Mizukami, T. (1980) Mol. Gen. Genet. 178, 541-553]. The dnaN gene codes for the beta subunit of DNA polymerase III holoenzyme [Burgers, P. M. J., Kornberg, A. & Sakakibara, Y. (1981) Proc. Natl. Acad. Sci. USA 78, 5391-5395]. The sueA77 mutation was trans-dominant over its wild-type allele, and it suppressed different thermosensitive mutations of dnaE with different maximal permissive temperature. These properties were interpreted as providing genetic evidence for interaction of the dnaE and dnaN gene products in E. coli.

Blue ghosts: a new method for isolating amber mutants defective in essential genes of Escherichia coli

We describe a technique which permits an easy screening for amber mutants defective in essential genes of Escherichia coli. Using this approach, we have isolated three amber mutants defective in the rho gene. An extension of the technique allows the detection of ochre mutants and transposon insertions in essential genes.

Genetic and physiological characterization of a spontaneous mutant of Escherichia coli B/r with aberrant control of deoxyribonucleic acid replication

Strain TJK16, a low-thymine-requiring thyA deoB derivative of Escherichia coli B/r A, was found to have an increased initiation mass due to a mutation in a gene affecting the control of initiation of deoxyribonucleic acid replication. In contrast to temperature-sensitive initiation mutants, initiation in TJK16 was not temperature sensitive. By phage P1 transduction, it was found that the mutation lies within a small region of the chromosome between dnaA and gyrB; this region includes dnaN and recF. Coumermycin-resistant derivatives of B/r and TJK16 had the same initiation mass as their coumermycin-sensitive parents, and TJK16 had the same sensitivity to coumermycin as the B/r parent, suggesting that the initiation mutation is not in gyrB.

dnaA alleles are recessive

Dominance tests of several dnaA alleles from Escherichia coli, including two previously reported to be dominant, show that all of the mutant alleles examined are recessive to dnaA+.

Identification of the dnaA and dnaN gene products of Escherichia coli

A specialized transducing lambda phage carrying the dnaN genes of Escherichia coli specifies two proteins of about 41 and 48 kilodaltons (kd). The temperature-sensitive mutations, dnaN59 and dnaA167, were found to result in altered isoelectric points of the 41 and 48 kd proteins, respectively. Thus the dnaN gene product was identified as a weakly acidic 41 and 48 kd protein. The synthesis of the dnaN gene product is greatly reduced by insertion of a transposon Tn3 in the dnaA gene and by deletion in the gene at the distal end to the dnaN gene. Temperature-sensitive dnaA mutations, on the dnaN gene product. These results indicate that the synthesis of the dnaN gene product is dependent on the structural integrity of the dnaA gene.

Isolation and characterization of Escherichia coli dnaA amber mutants

Specialized transducing phage lambda (formula, see text) dnaA-2 was mutagenized, and two derivatives designated lambda (formula) dnaA17(Am) and lambda (formula) dnaA452(Am) were obtained. They did not transduce such mutations as dnaA46, dnaA167, and dnaA5 when an amber suppressor was absent, but they did so in the presence of an amber suppressor. By contrast, they transduced the dna-806 and tna-2 mutations in the absence of an active amber suppressor. The dna-806 and tna-2 mutations are known to be located very close to the dnaA gene, but in separate cistrons. When ultraviolet light-irradiated uvrB cells were infected with the derivative phages and proteins specified by them were analyzed by gel electrophoresis, a 50,000-dalton protein was found to be specifically missing if an amber suppressor was absent. This protein was synthesized when an amber suppressor was present. The dnaA17(Am) mutation on the transducing phage genome was then transferred by genetic recombination onto the chromosome of an Escherichia coli strain carrying a temperature-sensitive amber suppressor supF6(Ts), yielding a strain which was temperature sensitive for growth and deoxyribonucleic acid replication. The temperature-sensitive trait was suppressed by supD, supE, or supF. We conclude that, most likely, the derivative phages acquired amber mutations in the dnaA gene whose product is a 50,000-dalton protein as identified by gel electrophoretic analysis.

Amber mutations in the structural gene for RNA polymerase sigma factor of Escherichia coli

Amber mutants of Escherichia coli K-12 affected in the structural gene (rpoD) for the sigma subunit of RNA polymerase have been obtained from a strain harboring a temperature-sensitive amber suppressor (supF-Ts6) which is active only at low temperatures. These mutants grow normally at low temperature (30 degrees C) but do not grow at high temperature (42 degrees C) due to the inability to synthesize sigma factor. In one mutant studied in detail (rpoD40), the rate of sigma-factor synthesis at 30 degrees C is about half that of the wild type and is decreased to 10%-15% within 1 h of incubation at 42 degrees C. The synthesis of core polymerase subunits or bulk protein is virtually unaffected at least for 2 h. The defect of the mutant in sigma synthesis and growth at high temperature can be suppressed by any of the amber suppressors tested (supD. supE or supF). RNA-polymerase holoenzymes prepared from the mutant cells carrying each of the suppressors (grown at 42 degrees C) exhibit different thermostabilities attributable to alterations in the sigma factor. The reduced sigma synthesis in the mutant is accompanied by the synthesis of polypeptide tentatively identified as 'amber fragment'. These results as well as the genetic mapping data indicate that the amber mutation (rpoD40) resides within the structural gene for the sigma factor and directly affects sigma synthesis upon inactivation of the suppressor at high temperature.

Genetic and physical mapping of recF in Escherichia coli K-12

Two factor transductional crosses place recF at approximately 82 min on the E. coli chromosome; recF is highly cotransducible with dnaA and gyrB (cou). Transductional analysis with a series of lambda tna specialized transducing phages carrying chromosomal DNA from the tnaA region place recF between dnaA and gyrB. This analysis also indicates that a gene lying in the same region and producing an easily detectable protein (estimated MW of 45 kD) is dnaN and not recF.

Cloning and physical mapping of the dnaA region of the Escherichia coli chromosome

The dnaA gene of Escherichia coli K-12, supposedly present in the deoxyribonucleic acid (DNA) of specialized transducing phase lambda i21 dnaA-2, was cloned onto plasmid pBR322. The new plasmid was named pMCR501. Physical analyses of DNAs of lambda i21 dnaA-2 and pMCR501 revealed the following. The lambda i21 dnaA-2 DNA retained the delta sr I lambda 1-2 and ninR5 deletions and imm21 substitution which were originally present in the parental phage. The size reduction was compensated for by the insertion-substitution segment (tna-dnaA region) in lambda i21 dnaA-2 DNA. The fractional size of this segment was approximately 7 megadaltons (Md), or 10 kilobases, which was found to be the sum of the tna insertion subsegment of ca. 3.5 Md and the dnaA substitution subsegment of ca. 3.5 Md. Phage P1-mediated transductional mapping between the dnaA46 and tna mutations gave a cotransduction frequency of 84%, corresponding to approximately 5 kilobases. Thus, it is strongly suggested that the dnaA gene resides in the lambda i21 dnaA-2 DNA. Cleavage mapping with the restriction endonuclease of pMCR501 DNA confirmed that it was constructed by excising a BamHI fragment of 4.29 Md, containing the 3.5-Md dnaA substitution segment, from the lambda i21 dnaA-2 DNA, inserting it into the sole BamHI cleavage site on pBR322.