Determination of the secondary structure in solution of the Escherichia coli DnaA DNA-binding domain

DnaA protein binds specifically to a group of binding sites collectively called as DnaA boxes within the bacterial replication origin to induce local unwinding of duplex DNA. The DNA-binding domain of DnaA, domain IV, comprises the C-terminal 94 amino acid residues of the protein. We overproduced and purified a protein containing only this domain plus a methionine residue. This protein was stable as a monomer and maintained DnaA box-specific binding activity. We then analyzed its solution structure by CD spectrum and heteronuclear multi-dimensional NMR experiments. We established extensive assignments of the 1H, 13C, and 15N nuclei, and revealed by obtaining combined analyses of chemical shift index and NOE connectivities that DnaA domain IV contains six alpha-helices and no beta-sheets, consistent with results of CD analysis. Mutations known to reduce DnaA box-binding activity were specifically located in or near two of the alpha-helices. These findings indicate that the DNA-binding fold of DnaA domain IV is unique among origin-binding proteins.     

Analysis of the DNA-binding domain of Escherichia coli DnaA protein

The DNA-binding domain of the Escherichia coli DnaA protein is represented by the 94 C-terminal amino acids (domain 4, aa 374-467). The isolated DNA-binding domain acts as a functional repressor in vivo, as monitored with a mioC:lacZ translational fusion integrated into the chromosome of the indicator strain. In order to identify residues required for specific DNA binding, site-directed and random PCR mutagenesis were performed, using the mioC:lacZ construct for selection. Mutations defective in DNA binding were found all over the DNA-binding domain with some clustering in the basic loop region, within presumptive helix B and in a highly conserved region at the N-terminus of presumptive helix C. Surface plasmon resonance (SPR) analysis revealed different binding classes of mutant proteins. No or severely reduced binding activity was demonstrated for amino acid substitutions at positions R399, R407, Q408, H434, T435, T436 and A440. Altered binding specificity was found for mutations in a 12 residue region close to the N-terminus of helix C. The defects of the classical temperature sensitive mutants dnaA204, dnaA205 and dnaA211 result from instability of the proteins at higher temperatures. dnaX suppressors dnaA71 and dnaA721 map to the region close to helix C and bind DNA non-specifically.     

Insights into the quality of DnaA boxes and their cooperativity

Plasmids carrying the mioC promoter region with its two DnaA boxes are as efficient in titration of DnaA protein as plasmids carrying a replication-inactivated oriC region with its five DnaA boxes. The two DnaA boxes upstream of the mioC promoter were mutated in various ways to study the cooperativity between the DnaA boxes, and to study in vivo the in vitro-defined 9mer DnaA box consensus sequence (TT(A)/(T)TNCACA). The quality and cooperativity of the DnaA boxes were determined in two complementary ways: as titration of DnaA protein leading to derepression of the dnaA promoter, and as repression of the mioC promoter caused by the DnaA protein binding to the DnaA boxes. Titration of DnaA protein correlated with repression of the mioC promoter. The level of titration and repression with the normal promoter-proximal box (TTTTCCACA) depends strongly on the presence and the quality of a DnaA box in the promoter-distal position, whereas a promoter-proximal DnaA box with the sequence TTATCCACA titrated DnaA protein and caused significant repression of the mioC promoter without a promoter-distal DnaA box. The quality of the eight different consensus DnaA boxes located in the promoter-proximal position was determined: TTATCCACA had the highest affinity for DnaA protein. In the third position, A was better than T, and the four possibilities in the fifth position could be ranked as C >A >or=G >T. Parallel in vitro experiments using a purified DNA-binding domain of DnaA protein gave the same ranking of the binding affinities of the eight DnaA boxes.     

DNA binding specificity of the replication initiator protein, DnaA from Helicobacter pylori

The key protein in the initiation of Helicobacter pylori chromosome replication, DnaA, has been characterized. The amount of the DnaA protein was estimated to be approximately 3000 molecules per single cell; a large part of the protein was found in the inner membrane. The H.pylori DnaA protein has been analysed using in vitro (gel retardation assay and surface plasmon resonance (SPR)) as well as in silico (comparative computer modeling) studies. DnaA binds a single DnaA box as a monomer, while binding to the fragment containing several DnaA box motifs, the oriC region, leads to the formation of high molecular mass nucleoprotein complexes. In comparison with the Escherichia coli DnaA, the H.pylori DnaA protein exhibits lower DNA-binding specificity; however, it prefers oriC over non-box DNA fragments. As determined by gel retardation techniques, the H.pylori DnaA binds with a moderate level of affinity to its origin of replication (4nM). Comparative computer modelling showed that there are nine residues within the binding domain which are possible determinants of the reduced H.pylori DnaA specificity. Of these, the most interesting is probably the triad PTL; all three residues show significant divergence from the consensus, and Thr398 is the most divergent residue of all.     

The N-terminus promotes oligomerization of the Escherichia coli initiator protein DnaA

Initiation of chromosome replication in Escherichia coli is governed by the interaction of the initiator protein DnaA with the replication origin oriC. Here we present evidence that homo-oligomerization of DnaA via its N-terminus (amino acid residues 1-86) is also essential for initiation. Results from solid-phase protein-binding assays indicate that residues 1-86 (or 1-77) of DnaA are necessary and sufficient for self interaction. Using a 'one-hybrid-system' we found that the DnaA N-terminus can functionally replace the dimerization domain of coliphage lambda cl repressor: a lambdacl-DnaA chimeric protein inhibits lambda plasmid replication as efficiently as lambdacI repressor. DnaA derivatives with deletions in the N-terminus are incapable of supporting chromosome replication from oriC, and, conversely, overexpression of the DnaA N-terminus inhibits initiation in vivo. Together, these results indicate that (i) oligomerization of DnaA N-termini is essential for protein function during initiation, and (ii) oligomerization does not require intramolecular cross-talk with the nucleotide-binding domain III or the DNA-binding domain IV. We propose that E. coli DnaA is composed of largely independent domains - or modules - each contributing a partial, though essential, function to the proper functioning of the 'holoprotein'.     

Acidic phospholipids inhibit the DNA-binding activity of DnaA protein,the initiator of chromosomal DNA replication in Escherichia coli

In order to initiate chromosomal DNA replication in Escherichia coli, the DnaA protein must bind to both ATP and the origin of replication (oriC). Acidic phospholipids are known to inhibit DnaA binding to ATP, and here we examine the effects of various phospholipids on DnaA binding to oriC. Among the phospholipids in E. coli membrane, cardiolipin showed the strongest inhibition of DnaA binding to oriC. Synthetic phosphatidylglycerol containing unsaturated fatty acids inhibited binding more potently than did synthetic phosphatidylglycerol containing saturated fatty acids, suggesting that membrane fluidity is important. Thus, acidic phospholipids seem to inhibit DnaA binding to both oriC and adenine nucleotides in the same manner. Adenine nucleotides bound to DnaA did not affect the inhibitory effect of cardiolipin on DnaA binding to oriC. A mobility-shift assay re-vealed that acidic phospholipids inhibited formation of a DnaA-oriC complex containing several DnaA molecules. DNase I footprinting of DnaA binding to oriC showed that two DnaA binding sites (R2 and R3) were more sensitive to cardiolipin than other DnaA binding sites. Based on these in vitro data, the physiological relevance of this inhibitory effect of acidic phospholipids on DnaA binding to oriC is discussed.     

Quantitative analysis of the mechanism of DNA binding by Bacillus DnaA protein

DnaA protein has the sole responsibility of initiating a new round of DNA replication in prokaryotic organisms. It recognizes the origin of DNA replication, and initiates chromosomal DNA replication in the bacterial genome. In Gram-negative Escherichia coli, a large number of DnaA molecules bind to specific DNA sequences (known as DnaA boxes) in the origin of DNA replication, oriC, leading to the activation of the origin. We have cloned, expressed, and purified full-length DnaA protein in large quantity from Gram-positive pathogen Bacillus anthracis (DnaA_BA). DnaA_BA was a highly soluble monomeric protein making it amenable to quantitative analysis of its origin recognition mechanisms. DnaA_BA bound DnaA boxes with widely divergent affinities in sequence and ATP-dependent manner. In the presence of ATP, the K_D ranged from 3.8 × 10⁻⁸ M for a specific DnaA box sequence to 4.1 × 10⁻⁷ M for a non-specific DNA sequence and decreased significantly in the presence of ADP. Thermodynamic analyses of temperature and salt dependence of DNA binding indicated that hydrophobic (entropic) and ionic bonds contributed to the DnaA_BA·DNA complex formation. DnaA_BA had a DNA-dependent ATPase activity. DNA sequences acted as positive effectors and modulated the rate (V_max) of ATP hydrolysis without any significant change in ATP binding affinity.     

Initiation of DNA replication in Escherichia coli after overproduction of the DnaA protein

Summary Flow cytometry was used to study initiation of DNA replication in Escherichia coli K12 after induced expression of a plasmid-borne dnaA ⁺ gene. When the dnaA gene was induced from either the plac or the pL promoter initiation was stimulated, as evidenced by an increase in the number of origins and in DNA content per mass unit. During prolonged growth under inducing conditions the origin and DNA content per mass unit were stabilized at levels significantly higher than those found before induction or in similarly treated control cells. The largest increase was observed when using the stronger promoter pL compared to plac. Synchrony of initiation was reasonably well maintained with elevated DnaA protein concentrations, indicating that simultaneous initiation of all origins was still preferred under these conditions. A reduced rate of replication fork movement was found in the presence of rifampin when the DnaA protein was overproduced. We conclude that increased synthesis levels or increased concentrations of the DnaA protein stimulate initiation of DNA replication. The data suggest that the DnaA protein may be the limiting factor for initiation under normal physiological conditions.     

The initiator protein DnaA contributes to keeping new origins inactivated by promoting the presence of hemimethylated DNA

The Escherichia coli replication origin oriC and other regions with high numbers of GATC sites remain hemimethylated after replication much longer than regions with average numbers of GATC sites. The prolonged period of hemimethylation has been attributed to the presence of bound SeqA protein. Here, it was found that a GATC cluster inserted at the datA site, which binds large amounts of DnaA in vivo, did not become remethylated at all, unless the availability of the DnaA protein was severely reduced. Sequestration of oriC was also found to be affected by the availability of DnaA. The period of origin hemimethylation was reduced by approximately 30% upon a reduction in the availability of DnaA. The result shows that not only SeqA binding but also DnaA binding to newly replicated origins contributes to keeping them hemimethylated. It was also found that the number of SeqA foci increased in cells with a combination of DnaA-mediated protection and sequestration at the GATC::datA cluster.     

Prediction of the structure of the replication initiator protein DnaA

The secondary structure of DnaA protein and its interaction with DNA and ribonucleotides has been predicted using biochemical, biophysical techniques, and prediction methods based on multiple-sequence alignment and neural networks. The core of all proteins from the DnaA family consists of an “open twisted α/β structure,” containing five α-helices alternating with five β-strands. In our proposed structural model the interior of the core is formed by a parallel β-sheet, whereas the α-helices are arranged on the surface of the core. The ATP-binding motif is located within the core, in a loop region following the first β-strand. The N-terminal domain (80 aa) is composed of two α-helices, the first of which contains a potential leucine zipper motif for mediating protein-protein interaction, followed by a β-strand and an additional α-helix. The N-terminal domain and the α/β core region of DnaA are connected by a variable loop (45–70 aa); major parts of the loop region can be deleted without loss of protein activity. The C-terminal DNA-binding domain (94 aa) is mostly α-helical and contains a potential helix-loop-helix motif. DnaA protein does not dimerize in solution; instead, the two longest C-terminal α-helices could interact with each other, forming an internal “coiled coil” and exposing highly basic residues of a small loop region on the surface, probably responsible for DNA backbone contacts. © 1997 Wiley-Liss Inc.     

Genetic recombination in Escherichia coli. IV. Isolation and characterization of recombination-deficiency mutants of Escherichia coli K12

19 independent recombination-deficient mutants were isolated. 7 carried mutations that mapped near or in the recB and recC genes between thyA and argA. 10 mutants carried mutations cotransducible with pheA and exhibited no complementation with recA in temporary zygotic diploids.     

Microsecond hydrophobic collapse in the folding of Escherichia coli dihydrofolate reductase, an alpha/beta-type protein

Using small-angle X-ray scattering combined with a continuous-flow mixing device, we monitored the microsecond compaction dynamics in the folding of Escherichia coli dihydrofolate reductase, an alpha/beta-type protein. A significant collapse of the radius of gyration from 30 A to 23.2 A occurs within 300 micros after the initiation of refolding by a urea dilution jump. The subsequent folding after the major chain collapse occurs on a considerably longer time-scale. The protein folding trajectories constructed by comparing the development of the compactness and the secondary structure suggest that the specific hydrophobic collapse model rather than the framework model better explains the experimental observations. The folding trajectory of this alpha/beta-type protein is located between those of alpha-helical and beta-sheet proteins, suggesting that native structure determines the folding landscape.     

Overproduction of DnaA protein stimulates initiation of chromosome and minichromosome replication in Escherichia coli

Summary Increased synthesis of DnaA protein, obtained with plasmids carrying the dnaA gene controlled by the heat inducible pL promoter, stimulated initiation of replication from oriC about threefold. The overinitiation was determined both as an increase in copy number of a minichromosome and as an increase in chromosomal gene dosage of oriC proximal DNA. The additional replication forks which were initiated on the chromosome did not lead to an overall increase in DNA content. DNA/DNA hybridization showed an amplification encompassing less than a few hundred kilobases on each side of oriC. Kinetic studies showed that the overinitiation occurred very rapidly after the induction, and that the initiation frequency then decreased to a near normal frequency per oriC. The results indicate that the DnaA protein is one important factor in regulation of initiation of DNA replication from oriC.     

The Multifaceted Benefits of Protein Co-expression in Escherichia coli

We report here that the expression of protein complexes in vivo in Escherichia coli can be more convenient than traditional reconstitution experiments in vitro. In particular, we show that the poor solubility of Escherichia coli DNA polymerase III ε subunit (featuring 3’-5’ exonuclease activity) is highly improved when the same protein is co-expressed with the α and θ subunits (featuring DNA polymerase activity and stabilizing ε, respectively). We also show that protein co-expression in E. coli can be used to efficiently test the competence of subunits from different bacterial species to associate in a functional protein complex. We indeed show that the α subunit of Deinococcus radiodurans DNA polymerase III can be co-expressed in vivo with the ε subunit of E. coli. In addition, we report on the use of protein co-expression to modulate mutation frequency in E. coli. By expressing the wild-type ε subunit under the control of the araBAD promoter (arabinose-inducible), and co-expressing the mutagenic D12A variant of the same protein, under the control of the lac promoter (inducible by isopropyl-thio-β-D-galactopyranoside, IPTG), we were able to alter the E. coli mutation frequency using appropriate concentrations of the inducers arabinose and IPTG. Finally, we discuss recent advances and future challenges of protein co-expression in E. coli.