Resolution of Holliday junctions by RuvC resolvase: cleavage specificity and DNA distortion

E. coli RuvC protein resolves Holliday junctions during genetic recombination and postreplication repair. Using small synthetic junctions, we show that junction recognition is structure-specific and occurs in the absence of metal cofactors. In the presence of Mg2+, Holliday junctions are resolved by the introduction of symmetrically related nicks at the 3' side of thymine residues. The nicked duplex products are repaired by the action of DNA ligase. Within the RuvC-Holliday junction complex, the DNA is distorted such that 2 of the 4 strands become hypersensitive to hydroxyl radical attack. The ionic requirements of binding, hydroxyl radical sensitivity, and strand cleavage indicate three distinct steps in the mechanism of RuvC-mediated Holliday junction resolution: structure-specific recognition, DNA distortion, and sequence-dependent cleavage.     

DNA binding and helicase domains of the Escherichia coli recombination protein RecG

The Escherichia coli RecG protein is a unique junction-specific helicase involved in DNA repair and recombination. The C-terminus of RecG contains motifs conserved throughout a wide range of DNA and RNA helicases and it is thought that this C-terminal half of RecG contains the helicase active site. However, the regions of RecG which confer junction DNA specificity are unknown. To begin to assign structure-function relationships within RecG, a series of N- and C-terminal deletions have been engineered into the protein, together with an N-terminal histidine tag fusion peptide for purification purposes. Junction DNA binding, unwinding and ATP hydrolysis were disrupted by mutagenesis of the N-terminus. In contrast, C-terminal deletions moderately reduced junction DNA binding but almost abolished unwinding. These data suggest that the C-terminus does contain the helicase active site whereas the N-terminus confers junction DNA specificity.     

Mechanism and control of interspecies recombination in Escherichia coli. I. Mismatch repair, methylation, recombination and replication functions

A genetic analysis of interspecies recombination in Escherichia coli between the linear Hfr DNA from Salmonella typhimurium and the circular recipient chromosome reveals some fundamental aspects of recombination between related DNA sequences. The MutS and MutL mismatch binding proteins edit (prevent) homeologous recombination between these 16% diverged genomes by at least two distinct mechanisms. One is MutH independent and presumably acts by aborting the initiated recombination through the UvrD helicase activity. The RecBCD nuclease might contribute to this editing step, presumably by preventing reiterated initiations of recombination at a given locus. The other editing mechanism is MutH dependent, requires unmethylated GATC sequences, and probably corresponds to an incomplete long-patch mismatch repair process that does not depend on UvrD helicase activity. Insignificant effects of the Dam methylation of parental DNAs suggest that unmethylated GATC sequences involved in the MutH-dependent editing are newly synthesized in the course of recombination. This hypothetical, recombination-associated DNA synthesis involves PriA and RecF functions, which, therefore, determine the extent of MutH effect on interspecies recombination. Sequence divergence of recombining DNAs appears to limit the frequency, length, and stability of early heteroduplex intermediates, which can be stabilized, and the recombinants mature via the initiation of DNA replication.     

Strand specificity in the interactions of Escherichia coli primary replicative helicase DnaB protein with a replication fork

The interactions of the Escherichia coli primary replicative helicase DnaB protein, with synthetic DNA replication fork substrates, having either a single arm or both arms, have been studied using the thermodynamically rigorous fluorescence titration techniques. This approach allows us to obtain absolute stoichiometries of the formed complexes and interaction parameters without any assumptions about the relationship between the observed signal (fluorescence) and the degree of binding. Subsequently, the formation of the complexes, with different replication fork substrates, has also been characterized using the sedimentation velocity technique. To our knowledge, this is the first quantitative characterization of interactions of a hexameric helicase with replication fork substrates. In the presence of the ATP nonhydrolyzable analog, AMP-PNP, the E. coli DnaB helicase preferentially binds to the 5' arm of the single-arm fork substrate with an intrinsic affinity 6-fold higher than its affinity for the 3' arm. ATP hydrolysis is not necessary for formation of the helicase-fork complex. The asymmetric interactions are consistent with the 5' --> 3' directionality of the helicase activity of the DnaB protein and most probably reflects a preferential 5' --> 3' polarity in the helicase binding to ssDNA, with respect to the ssDNA backbone. The double-stranded part of the fork contributes little to the free energy of binding. The data indicate a rather passive role of the duplex part of the fork in the binding of the helicase. This role seems to be limited to impose steric hindrance in the formation of nonproductive complexes of the enzyme with the fork. Quantitative analysis of binding of the helicase to the two-arm fork substrate shows that two DnaB hexamers can bind to the fork, with each single hexamer associated with a single arm of the fork. In this complex, the intrinsic affinity of the DnaB hexamer for the 5' arm in a two-arm fork is not affected by the presence of the 3' arm. Moreover, the results show that the 3' arm is in a conformation which makes it easily available for the binding of the next DnaB hexamer. Because of the large size of the DnaB hexamer, the data indicate that the 3' arm is separated from the 5' arm. The separation of both arms must be to such an extent that the 3' arm can bind an additional large DnaB hexamer. These results reveal that the 3' arm is not engaged in thermodynamically stable interactions with the helicase hexamer, when it is bound in its stationary complex to the 5' arm of the fork. The significance of the these results for a mechanistic model of the hexameric DnaB helicase action is discussed.     

Genetic requirements and mutational specificity of the Escherichia coli SOS mutator activity

To better understand the mechanisms of SOS mutagenesis in the bacterium Escherichia coli, we have undertaken a genetic analysis of the SOS mutator activity. The SOS mutator activity results from constitutive expression of the SOS system in strains carrying a constitutively activated RecA protein (RecA730). We show that the SOS mutator activity is not enhanced in strains containing deficiencies in the uvrABC nucleotide excision-repair system or the xth and nfo base excision-repair systems. Further, recA730-induced errors are shown to be corrected by the MutHLS-dependent mismatch-repair system as efficiently as the corresponding errors in the rec+ background. These results suggest that the SOS mutator activity does not reflect mutagenesis at so-called cryptic lesions but instead represents an amplification of normally occurring DNA polymerase errors. Analysis of the base-pair-substitution mutations induced by recA730 in a mismatch repair-deficient background shows that both transition and transversion errors are amplified, although the effect is much larger for transversions than for transitions. Analysis of the mutator effect in various dnaE strains, including dnaE antimutators, as well as in proofreading-deficient dnaQ (mutD) strains suggests that in recA730 strains, two types of replication errors occur in parallel: (i) normal replication errors that are subject to both exonucleolytic proofreading and dnaE antimutator effects and (ii) recA730-specific errors that are not susceptible to either proofreading or dnaE antimutator effects. The combined data are consistent with a model suggesting that in recA730 cells error-prone replication complexes are assembled at sites where DNA polymerization is temporarily stalled, most likely when a normal polymerase insertion error has created a poorly extendable terminal mismatch. The modified complex forces extension of the mismatch largely at the exclusion of proofreading and polymerase dissociation pathways. SOS mutagenesis targeted at replication-blocking DNA lesions likely proceeds in the same manner.     

Protein interactions in genetic recombination in Escherichia coli. Interactions involving RecO and RecR overcome the inhibition of RecA by single-stranded DNA-binding protein

RecA promotes homologous pairing of single-stranded DNA (ssDNA) with double-stranded DNA (dsDNA). This reaction occurs inefficiently if the ssDNA substrate is preincubated with Escherichia coli ssDNA-binding protein (SSB). However, RecO and RecR can act together as accessory factors for RecA to overcome this inhibition by SSB (Umezu, K., Chi, N.-W., and Kolodner, R. D. (1993) Proc. Natl. Acad. Sci. U.S.A. 90, 3875-3879). To elucidate the mechanism that underlies this process, we examined protein-protein interactions between RecA, RecF, RecO, RecR, and SSB, and characterized the structure and activity of the ssDNA complexes formed with different combinations of these proteins. We obtained the following results. (i) RecO physically interacts with both RecR and SSB. The interaction between RecO and SSB is stronger than the RecO-RecR interaction. (ii) RecO and RecR do not remove SSB from SSB.ssDNA complexes, but instead bind to these complexes. The resulting RecO.RecR.SSB.ssDNA complexes were more active in RecA-mediated joint molecule formation than were SSB.ssDNA complexes. (iii) RecA can nucleate on the RecO.RecR.SSB.ssDNA complexes more efficiently than on SSB.ssDNA complexes. (iv) When RecA presynaptic filaments were formed in the presence of SSB, RecO, and RecR, the protein-DNA complexes obtained contained 70% of the amount of RecA required to saturate ssDNA. These complexes, however, can mediate joint molecule formation and strand exchange as efficiently as presynaptic filaments which are fully saturated with RecA. Based on these results, we propose dual roles for RecO and RecR in joint molecule formation. First, RecO and RecR bind to SSB.ssDNA complexes and modify their structure to allow RecA to nucleate on them efficiently. Second, RecO and RecR are retained in RecA presynaptic filaments and play a role in the subsequent homologous pairing process promoted by RecA.     

Analysis of substrate specificity of the RuvC holliday junction resolvase with synthetic Holliday junctions

The Escherichia coli RuvC protein endonucleolytically resolves Holliday junctions, which are formed as intermediates during genetic recombination and recombination repair. Previous studies using model Holliday junctions suggested that a certain size of central core of homology and a specific sequence in the junction were required for efficient cleavage by RuvC, although not for binding. To determine the minimum length of sequence homology required for RuvC cleavage, we made a series of synthetic Holliday junctions with various lengths of homologous sequence in the core region. It was demonstrated that a monomobile junction possessing only 2 base pairs of the homology core was efficiently cleaved by RuvC. To study the sequence specificity for cleavage, we made 16 bimobile junctions, which differed only in the homologous core sequence. Among them, 6 junctions were efficiently cleaved. Cleavage occurred by introduction of nicks symmetrically at the 3'-side of thymine in all cases. However, the nucleotide bases at the 3'-side of the thymines were not always identical between the two strands nicked. These results suggest that RuvC recognizes mainly topological symmetry of the Holliday junction but not the sequence symmetry per se, that the thymine residue at the cleavage site plays an important role for RuvC-mediated resolution, and that a long homologous core sequence is not essential for cleavage.     

DNA specificity of Escherichia coli deoP1 operator-DeoR repressor recognition

We have studied the importance of the specific DNA sequence of the deo operator site for DeoR repressor binding by introducing symmetrical, single basepair substitutions at all positions in the deo operator and tested the ability of these variants to titrate DeoR in vivo. Our results show that a 16 bp palindromic sequence constitutes the deo operator. Positions outside this palindrome (positions +/- 9, +/- 10) can be changed without any major effect on DeoR binding. Most of the central 6-8 bp of the palindrome (positions +/- 1, +/- 2, +/- 3) can be substituted with other nucleotides with no or only minor effects on DeoR binding, while changes at position +/- 4 and +/- 5 give a more heterogeneous response. Finally, changes at positions +/- 6, +/- 7 and +/- 8 severely disrupt DeoR binding.     

Sequence specificity and biochemical characterization of the RusA Holliday junction resolvase of Escherichia coli

The RusA protein of Escherichia coli is an endonuclease that resolves Holliday intermediates in recombination and DNA repair. Analysis of its subunit structure revealed that the native protein is a dimer. Its resolution activity was investigated using synthetic X-junctions with homologous cores. Resolution occurs by dual strand incision predominantly 5' of CC dinucleotides located symmetrically. A junction lacking homology is not resolved. The efficiency of resolution is related inversely to the number of base pairs in the homologous core, which suggests that branch migration is rate-limiting. Inhibition of resolution at high ratios of protein to DNA suggests that binding of RusA may immobilize the junction point at non-cleavable sites. Resolution is stimulated by alkaline pH and by Mn2+. The protein is unstable in the absence of substrate DNA and loses approximately 80% of its activity within 1 min under standard reaction conditions. DNA binding stabilizes the activity. Junction resolution is inhibited in the presence of RuvA. This observation probably explains why RusA is unable to promote efficient recombination and DNA repair in ruvA+ strains unless it is expressed at a high level.     

Escherichia coli strains lacking protein HU are UV sensitive due to a role for HU in homologous recombination

hupA and hupB encode the alpha and beta subunits of the Escherichia coli histone-like protein HU. Here we show that E. coli hup mutants are sensitive to UV in the rec+ sbc+, recBC sbcA, recBC sbcBC, umuDC, recF, and recD backgrounds. However, hupAB mutations do not enhance the UV sensitivity of resolvase-deficient recG ruvA strains. hupAB uvrA and hupAB recG strains are supersensitive to UV. hup mutations enhance the UV sensitivity of ruvA strains to a much lesser extent but enhance that of rus-1 ruvA strains to the same extent as for rus+ ruv+ strains. Our results suggest that HU plays a role in recombinational DNA repair that is not specifically limited to double-strand break repair or daughter strand gap repair; the lack of HU affects the RecG RusA and RuvABC pathways for Holliday junction processing equally if the two pathways are equally active in recombinational repair; the function of HU is not in the substrate processing step or in the RecFOR-directed synapsis action during recombinational repair. Furthermore, the UV sensitivity of hup mutants cannot be suppressed by overexpression of wild-type or mutant gyrB, which confers novobiocin resistance, or by different concentrations of a gyrase inhibitor that can increase or decrease the supercoiling of chromosomal DNA.     

Coupling protein stability and protein function in Escherichia coli CspA

Idiopathic thrombocytopenic purpura (ITP, also known as immune thrombocytopenic purpura) in adults is principally a disease of young women. Although in some patients the onset is acute and complete resolution occurs, in most patients, the onset is insidious and the course is chronic. In spite of the relative frequency of ITP, there are important unresolved issues in its diagnosis and management. For this reason, the American Society of Hematology (ASH) chose ITP as the disease topic for its initial sponsored practice guideline in 1993. A major conclusion of the published guideline was the lack of firm evidence on which to base diagnostic procedures and management strategies. This review describes the clinical features of ITP in adults, emphasizes the principal unresolved issues in diagnosis and management, and outlines the critical areas for future research.     

Early intermediates in the folding of dihydrofolate reductase from Escherichia coli detected by hydrogen exchange and NMR

The kinetic folding mechanism for Escherichia coli dihydrofolate reductase postulates two distinct types of transient intermediates. The first forms within 5 ms and has substantial secondary structure but little stability. The second is a set of four species that appear over the course of several hundred milliseconds and have secondary structure, specific tertiary structure, and significant stability (Jennings PA, Finn BE, Jones BE, Matthews CR, 1993, Biochemistry 32:3783-3789). Pulse labeling hydrogen exchange experiments were performed to determine the specific amide hydrogens in alpha-helices and beta-strands that become protected from exchange through the formation of stable hydrogen bonds during this time period. A significant degree of protection was observed for two subsets of the amide hydrogens within the dead time of this experiment (6 ms). The side chains of one subset form a continuous nonpolar strip linking six of the eight strands in the beta-sheet. The other subset corresponds to a nonpolar cluster on the opposite face of the sheet and links three of the strands and two alpha-helices. Taken together, these data demonstrate that the complex strand topology of this eight-stranded sheet can be formed correctly within 6 ms. Measurement of the protection factors at three different folding times (13 ms, 141 ms, and 500 ms) indicates that, of the 13 amide hydrogens displaying significant protection within 6 ms, 8 exhibit an increase in their protection factors from approximately 5 to approximately 50 over this time range; the remaining five exhibit protection factors > 100 at 13 ms. Only approximately half of the population of molecules form this set of stable hydrogen bonds. Thirteen additional hydrogens in the beta-sheet become protected from exchange as the set of native conformers appear, suggesting that the stabilization of this network reflects the global cooperativity of the folding reaction.     

Use of bacteriophage lambda recombination functions to promote gene replacement in Escherichia coli

Replacement of Escherichia coli's RecBCD function with phage lambda's Red function generates a strain whose chromosome recombines with short linear DNA fragments at a greatly elevated rate. The rate is at least 70-fold higher than that exhibited by a recBC sbcBC or recD strain. The value of the system is highlighted by gene replacement with a PCR-generated DNA fragment. The deltarecBCD::Plac-red kan replacement allele can be P1 transduced to other E. coli strains, making the hyper-Rec phenotype easily transferable.     

Optimization of heterologous protein production in Escherichia coli

Escherichia coli has long been the primary prokaryotic host for the synthesis of heterologous proteins. Recent advances have been made in the expression of complex proteins as soluble, functional molecules, complete with prosthetic groups, disulfide bonds, and quaternary structure. The development of alternative promoter and induction strategies has improved the options available for manipulating the expression conditions, which are frequently critical to soluble yield.     

Role of the Escherichia coli SurA protein in stationary-phase survival

SurA is a periplasmic peptidyl-prolyl isomerase required for the efficient folding of extracytoplasmic proteins. Although the surA gene had been identified in a screen for mutants that failed to survive in stationary phase, the role played by SurA in stationary-phase survival remained unknown. The results presented here demonstrate that the survival defect of surA mutants is due to their inability to grow at elevated pH in the absence of sigmaS. When cultures of Escherichia coli were grown in peptide-rich Luria-Bertani medium, the majority of the cells lost viability during the first two to three days of incubation in stationary phase as the pH rose to pH 9. At this time the surviving cells resumed growth. In cultures of surA rpoS double mutants the survivors lysed as they attempted to resume growth at the elevated pH. Cells lacking penicillin binding protein 3 and sigmaS had a survival defect similar to that of surA rpoS double mutants, suggesting that SurA foldase activity is important for the proper assembly of the cell wall-synthesizing apparatus.     

Structure-function analysis of the Escherichia coli GrpE heat shock protein

We have isolated various missense mutations in the essential grpE gene of Escherichia coli based on the inability to propagate bacteriophage lambda. To better understand the biochemical mechanisms of GrpE action in various biological processes, six mutant proteins were overexpressed and purified. All of them, GrpE103, GrpE66, GrpE2/280, GrpE17, GrpE13a and GrpE25, have single amino acid substitutions located in highly conserved regions throughout the GrpE sequence. The biochemical defects of each mutant GrpE protein were identified by examining their abilities to: (i) support in vitro lambda DNA replication; (ii) stimulate the weak ATPase activity of DnaK; (iii) dimerize and oligomerize, as judged by glutaraldehyde crosslinking and HPLC size chromatography; (iv) interact with wild-type DnaK protein using either an ELISA assay, glutaraldehyde crosslinking or HPLC size chromatography. Our results suggest that GrpE can exist in a dimeric or oligomeric form, depending on its relative concentration, and that it dimerizes/oligomerizes through its N-terminal region, most likely through a computer predicted coiled-coil region. Analysis of several mutant GrpE proteins indicates that an oligomer of GrpE is the most active form that interacts stably with DnaK and that the interaction is vital for GrpE biological function. Our results also demonstrate that both the N-terminal and C-terminal regions are important for GrpE function in lambda DNA replication and its co-chaperone activity with DnaK.