The replication time of the Escherichia coli K12 chromosome as a function of cell doubling time

Replisomal coupling between the α-pol III core and the τ-subunit of the clamp loader complex (CLC) are essential for genomic integrity in Escherichia coli

Coupling interactions between the alpha (α) subunit of the polymerase III core (α-Pol III core) and the tau (τ) subunit of the clamp loader complex (τ-CLC) are vital for efficient and rapid DNA replication in Escherichia coli. Specific and targeted mutations in the C-terminal τ-interaction region of the Pol III α-subunit disrupted efficient coupled rolling circle DNA synthesis in vitro and caused significant genomic defects in CRISPR-Cas9 dnaE edited cell strains. These α-Pol III mutations eliminated the interaction with τ-CLC but retained WT polymerase and exonuclease activities. The most severely affected mutant strains, dnaE:Y1119A and dnaE:L1097/8S, had significantly reduced doubling times, reduced fitness, and increased cellular length phenotypes as a result of this targeted decoupling of the replisome and the generation of replication stress. Those strains also showed significant SOS induction from unwound but unreplicated regions within the genome. In support, significant ssDNA gaps were detected by fluorescence microscopy and quantified by fluorescence activated cytometry using an in situ PLUG assay for those dnaE:mut strains. By comparing the biochemical and genomic consequences of disrupting the τ-CLC-α-Pol III coupling contacts, we have unveiled a more cohesive picture and mechanistic understanding of replisome dynamics and the essential interactions required to maintain overall fitness through a stable genome.

Clues to transcription/replication collision-induced DNA damage: it was RNAP, in the chromosome, with the fork

DNA replication and RNA transcription processes compete for the same DNA template and, thus, frequently collide. These transcription-replication collisions are thought to lead to genomic instability, which places a selective pressure on organisms to avoid them. Here, we review the predisposing causes, molecular mechanisms, and downstream consequences of transcription-replication collisions (TRCs) with a strong emphasis on prokaryotic model systems, before contrasting prokaryotic findings with cases in eukaryotic systems. Current research points to genomic structure as the primary determinant of steady-state TRC levels and RNA polymerase regulation as the primary inducer of excess TRCs. We review the proposed mechanisms of TRC-induced DNA damage, attempting to clarify their mechanistic requirements. Finally, we discuss what drives genomes to select against TRCs.

Spatio-temporal organization of the E. coli chromosome from base to cellular length scales

Escherichia coli has been a vital model organism for studying chromosomal structure, thanks, in part, to its small and circular genome (4.6 million base pairs) and well-characterized biochemical pathways. Over the last several decades, we have made considerable progress in understanding the intricacies of the structure and subsequent function of the E. coli nucleoid. At the smallest scale, DNA, with no physical constraints, takes on a shape reminiscent of a randomly twisted cable, forming mostly random coils but partly affected by its stiffness. This ball-of-spaghetti-like shape forms a structure several times too large to fit into the cell. Once the physiological constraints of the cell are added, the DNA takes on overtwisted (negatively supercoiled) structures, which are shaped by an intricate interplay of many proteins carrying out essential biological processes. At shorter length scales (up to about 1 kb), nucleoid-associated proteins organize and condense the chromosome by inducing loops, bends, and forming bridges. Zooming out further and including cellular processes, topological domains are formed, which are flanked by supercoiling barriers. At the megabase-scale both large, highly self-interacting regions (macrodomains) and strong contacts between distant but co-regulated genes have been observed. At the largest scale, the nucleoid forms a helical ellipsoid. In this review, we will explore the history and recent advances that pave the way for a better understanding of E. coli chromosome organization and structure, discussing the cellular processes that drive changes in DNA shape, and what contributes to compaction and formation of dynamic structures, and in turn how bacterial chromatin affects key processes such as transcription and replication.

Tau-mediated coupling between Pol III synthesis and DnaB helicase unwinding helps maintain genomic stability

The τ-subunit of the clamp loader complex physically interacts with both the DnaB helicase and the polymerase III (Pol III) core α-subunit through domains IV and V, respectively. This interaction is proposed to help maintain rapid and efficient DNA synthesis rates with high genomic fidelity and plasticity, facilitating enzymatic coupling within the replisome. To test this hypothesis, CRISPR-Cas9 editing was used to create site-directed genomic mutations within the dnaX gene at the C terminus of τ predicted to interact with the α-subunit of Pol III. Perturbation of the α-τ binding interaction in vivo resulted in cellular and genomic stress markers that included reduced growth rates, fitness, and viabilities. Specifically, dnaX:mut strains showed increased cell filamentation, mutagenesis frequencies, and activated SOS. In situ fluorescence flow cytometry and microscopy quantified large increases in the amount of ssDNA gaps present. Removal of the C terminus of τ (I618X) still maintained its interactions with DnaB and stimulated unwinding but lost its interaction with Pol III, resulting in significantly reduced rolling circle DNA synthesis. Intriguingly, dnaX:L635P/D636G had the largest induction of SOS, high mutagenesis, and the most prominent ssDNA gaps, which can be explained by an impaired ability to regulate the unwinding speed of DnaB resulting in a faster rate of in vitro rolling circle DNA replication, inducing replisome decoupling. Therefore, τ-stimulated DnaB unwinding and physical coupling with Pol III acts to enforce replisome plasticity to maintain an efficient rate of synthesis and prevent genomic instability.

Dysregulated DnaB unwinding induces replisome decoupling and daughter strand gaps that are countered by RecA polymerization

The replicative helicase, DnaB, is a central component of the replisome and unwinds duplex DNA coupled with immediate template-dependent DNA synthesis by the polymerase, Pol III. The rate of helicase unwinding is dynamically regulated through structural transitions in the DnaB hexamer between dilated and constricted states. Site-specific mutations in DnaB enforce a faster more constricted conformation that dysregulates unwinding dynamics, causing replisome decoupling that generates excess ssDNA and induces severe cellular stress. This surplus ssDNA can stimulate RecA recruitment to initiate recombinational repair, restart, or activation of the transcriptional SOS response. To better understand the consequences of dysregulated unwinding, we combined targeted genomic dnaB mutations with an inducible RecA filament inhibition strategy to examine the dependencies on RecA in mitigating replisome decoupling phenotypes. Without RecA filamentation, dnaB:mut strains had reduced growth rates, decreased mutagenesis, but a greater burden from endogenous damage. Interestingly, disruption of RecA filamentation in these dnaB:mut strains also reduced cellular filamentation but increased markers of double strand breaks and ssDNA gaps as detected by in situ fluorescence microscopy and FACS assays, TUNEL and PLUG, respectively. Overall, RecA plays a critical role in strain survival by protecting and processing ssDNA gaps caused by dysregulated helicase activity in vivo.

Escherichia coli DNA replication: the old model organism still holds many surprises

Research on Escherichia coli DNA replication paved the groundwork for many breakthrough discoveries with important implications for our understanding of human molecular biology, due to the high level of conservation of key molecular processes involved. To this day, it attracts a lot of attention, partially by virtue of being an important model organism, but also because the understanding of factors influencing replication fidelity might be important for studies on the emergence of antibiotic resistance. Importantly, the wide access to high-resolution single-molecule and live-cell imaging, whole genome sequencing, and cryo-electron microscopy techniques, which were greatly popularized in the last decade, allows us to revisit certain assumptions about the replisomes and offers very detailed insight into how they work. For many parts of the replisome, step-by-step mechanisms have been reconstituted, and some new players identified. This review summarizes the latest developments in the area, focusing on (a) the structure of the replisome and mechanisms of action of its components, (b) organization of replisome transactions and repair, (c) replisome dynamics, and (d) factors influencing the base and sugar fidelity of DNA synthesis.

Does Silver in Different Forms Affect Bacterial Susceptibility and Resistance? A Mechanistic Perspective

The exceptional increase in antibiotic resistance in past decades motivated the scientific community to use silver as a potential antibacterial agent. However, due to its unknown antibacterial mechanism and the pattern of bacterial resistance to silver species, it has not been revolutionized in the health sector. This study deciphers mechanistic aspects of silver species, i.e., ions and lysozyme-coated silver nanoparticles (L-Ag NPs), against E. coli K12 through RNA sequencing analysis. The obtained results support the reservoir nature of nanoparticles for the controlled release of silver ions into bacteria. This study differentiates between the antibacterial mechanism of silver species by discussing the pathway of their entry in bacteria, sequence of events inside cells, and response of bacteria to overcome silver stress. Controlled release of ions from L-Ag NPs not only reduces bacterial growth but also reduces the likelihood of resistance development. Conversely, direct exposure of silver ions, leads to rapid activation of the bacterial defense system leading to development of resistance against silver ions, like the well-known antibiotic resistance problem. These findings provide valuable insight on the mechanism of silver resistance and antibacterial strategies deployed by E. coli K12, which could be a potential target for the generation of aim-based and effective nanoantibiotics.

Single-Molecule Insights Into the Dynamics of Replicative Helicases

Helicases are molecular motors that translocate along single-stranded DNA and unwind duplex DNA. They rely on the consumption of chemical energy from nucleotide hydrolysis to drive their translocation. Specialized helicases play a critically important role in DNA replication by unwinding DNA at the front of the replication fork. The replicative helicases of the model systems bacteriophages T4 and T7, Escherichia coli and Saccharomyces cerevisiae have been extensively studied and characterized using biochemical methods. While powerful, their averaging over ensembles of molecules and reactions makes it challenging to uncover information related to intermediate states in the unwinding process and the dynamic helicase interactions within the replisome. Here, we describe single-molecule methods that have been developed in the last few decades and discuss the new details that these methods have revealed about replicative helicases. Applying methods such as FRET and optical and magnetic tweezers to individual helicases have made it possible to access the mechanistic aspects of unwinding. It is from these methods that we understand that the replicative helicases studied so far actively translocate and then passively unwind DNA, and that these hexameric enzymes must efficiently coordinate the stepping action of their subunits to achieve unwinding, where the size of each step is prone to variation. Single-molecule fluorescence microscopy methods have made it possible to visualize replicative helicases acting at replication forks and quantify their dynamics using multi-color colocalization, FRAP and FLIP. These fluorescence methods have made it possible to visualize helicases in replication initiation and dissect this intricate protein-assembly process. In a similar manner, single-molecule visualization of fluorescent replicative helicases acting in replication identified that, in contrast to the replicative polymerases, the helicase does not exchange. Instead, the replicative helicase acts as the stable component that serves to anchor the other replication factors to the replisome.

DnaB helicase dynamics in bacterial DNA replication resolved by single-molecule studies

In Escherichia coli, the DnaB helicase forms the basis for the assembly of the DNA replication complex. The stability of DnaB at the replication fork is likely important for successful replication initiation and progression. Single-molecule experiments have significantly changed the classical model of highly stable replication machines by showing that components exchange with free molecules from the environment. However, due to technical limitations, accurate assessments of DnaB stability in the context of replication are lacking. Using in vitro fluorescence single-molecule imaging, we visualise DnaB loaded on forked DNA templates. That these helicases are highly stable at replication forks, indicated by their observed dwell time of ∼30 min. Addition of the remaining replication factors results in a single DnaB helicase integrated as part of an active replisome. In contrast to the dynamic behaviour of other replisome components, DnaB is maintained within the replisome for the entirety of the replication process. Interestingly, we observe a transient interaction of additional helicases with the replication fork. This interaction is dependent on the τ subunit of the clamp-loader complex. Collectively, our single-molecule observations solidify the role of the DnaB helicase as the stable anchor of the replisome, but also reveal its capacity for dynamic interactions.

Patterns of virus growth across the diversity of life

Although viruses in their natural habitats add up to less than 10% of the biomass, they contribute more than 90% of the genome sequences [1]. These viral sequences or 'viromes' encode viruses that populate the Earth's oceans [2, 3] and terrestrial environments [4, 5], where their infections impact life across diverse ecological niches and scales [6, 7], including humans [8-10]. Most viruses have yet to be isolated and cultured [11-13], and surprisingly few efforts have explored what analysis of available data might reveal about their nature. Here, we compiled and analyzed seven decades of one-step growth and other data for viruses from six major families, including their infections of archaeal, bacterial and eukaryotic hosts [14-191]. We found that the use of host cell biomass for virus production was highest for archaea at 10%, followed by bacteria at 1% and eukarya at 0.01%, highlighting the degree to which viruses of archaea and bacteria exploit their host cells. For individual host cells, the yield of virus progeny spanned a relatively narrow range (10-1000 infectious particles per cell) compared with the million-fold difference in size between the smallest and largest cells. Furthermore, healthy and infected host cells were remarkably similar in the time they needed to multiply themselves or their virus progeny. Specifically, the doubling time of healthy cells and the delay time for virus release from infected cells were not only correlated (r = 0.71, p < 10-10, n = 101); they also spanned the same range from tens of minutes to about a week. These results have implications for better understanding the growth, spread and persistence of viruses in complex natural habitats that abound with diverse hosts, including humans and their associated microbes.

Interaction with single-stranded DNA-binding protein localizes ribonuclease HI to DNA replication forks and facilitates R-loop removal

DNA replication complexes (replisomes) routinely encounter proteins and unusual nucleic acid structures that can impede their progress. Barriers can include transcription complexes and R-loops that form when RNA hybridizes with complementary DNA templates behind RNA polymerases. Cells encode several RNA polymerase and R-loop clearance mechanisms to limit replisome exposure to these potential obstructions. One such mechanism is hydrolysis of R-loops by ribonuclease HI (RNase HI). Here, we examine the cellular role of the interaction between Escherichia coli RNase HI and the single-stranded DNA-binding protein (SSB) in this process. Interaction with SSB localizes RNase HI foci to DNA replication sites. Mutation of rnhA to encode an RNase HI variant that cannot interact with SSB but that maintains enzymatic activity (rnhAK60E) eliminates RNase HI foci. The mutation also produces a media-dependent slow-growth phenotype and an activated DNA damage response in cells lacking Rep helicase, which is an enzyme that disrupts stalled transcription complexes. RNA polymerase variants that are thought to increase or decrease R-loop accumulation enhance or suppress, respectively, the growth phenotype of rnhAK60E rep::kan strains. These results identify a cellular role for the RNase HI/SSB interaction in helping to clear R-loops that block DNA replication.

Static and Dynamic Factors Limit Chromosomal Replication Complexity in Escherichia coli, Avoiding Dangers of Runaway Overreplication

We define chromosomal replication complexity (CRC) as the ratio of the copy number of the most replicated regions to that of unreplicated regions on the same chromosome. Although a typical CRC of eukaryotic or bacterial chromosomes is 2, rapidly growing Escherichia coli cells induce an extra round of replication in their chromosomes (CRC = 4). There are also E. coli mutants with stable CRC∼6. We have investigated the limits and consequences of elevated CRC in E. coli and found three limits: the "natural" CRC limit of ∼8 (cells divide more slowly); the "functional" CRC limit of ∼22 (cells divide extremely slowly); and the "tolerance" CRC limit of ∼64 (cells stop dividing). While the natural limit is likely maintained by the eclipse system spacing replication initiations, the functional limit might reflect the capacity of the chromosome segregation system, rather than dedicated mechanisms, and the tolerance limit may result from titration of limiting replication factors. Whereas recombinational repair is beneficial for cells at the natural and functional CRC limits, we show that it becomes detrimental at the tolerance CRC limit, suggesting recombinational misrepair during the runaway overreplication and giving a rationale for avoidance of the latter.

Interlinked sister chromosomes arise in the absence of condensin during fast replication in B. subtilis

Condensin-an SMC-kleisin complex-is essential for efficient segregation of sister chromatids in eukaryotes [1-4]. In Escherichia coli and Bacillus subtilis, deletion of condensin subunits results in severe growth phenotypes and the accumulation of cells lacking nucleoids [5, 6]. In many other bacteria and under slow growth conditions, however, the reported phenotypes are much milder or virtually absent [7-10]. This raises the question of what role prokaryotic condensin might play during chromosome segregation under various growth conditions. In B. subtilis and Streptococcus pneumoniae, condensin complexes are enriched on the circular chromosome near the single origin of replication by ParB proteins bound to parS sequences [11, 12]. Using conditional alleles of condensin in B. subtilis, we demonstrate that depletion of its activity results in an immediate and severe defect in the partitioning of replication origins. Multiple copies of the chromosome remain unsegregated at or near the origin of replication. Surprisingly, the growth and chromosome segregation defects in rich medium are suppressed by a reduction of replication fork velocity but not by partial inhibition of translation or transcription. Prokaryotic condensin likely prevents the formation of sister DNA interconnections at the replication fork or promotes their resolution behind the fork.

Replication-fork dynamics

The proliferation of all organisms depends on the coordination of enzymatic events within large multiprotein replisomes that duplicate chromosomes. Whereas the structure and function of many core replisome components have been clarified, the timing and order of molecular events during replication remains obscure. To better understand the replication mechanism, new methods must be developed that allow for the observation and characterization of short-lived states and dynamic events at single replication forks. Over the last decade, great progress has been made toward this goal with the development of novel DNA nanomanipulation and fluorescence imaging techniques allowing for the direct observation of replication-fork dynamics both reconstituted in vitro and in live cells. This article reviews these new single-molecule approaches and the revised understanding of replisome operation that has emerged.

Rescuing stalled or damaged replication forks

In recent years, an increasing number of studies have shown that prokaryotes and eukaryotes are armed with sophisticated mechanisms to restart stalled or collapsed replication forks. Although these processes are better understood in bacteria, major breakthroughs have also been made to explain how fork restart mechanisms operate in eukaryotic cells. In particular, repriming on the leading strand and fork regression are now established as critical for the maintenance and recovery of stalled forks in both systems. Despite the lack of conservation between the factors involved, these mechanisms are strikingly similar in eukaryotes and prokaryotes. However, they differ in that fork restart occurs in the context of chromatin in eukaryotes and is controlled by multiple regulatory pathways.

Escherichia coli single-stranded DNA-binding protein: nanoESI-MS studies of salt-modulated subunit exchange and DNA binding transactions

Single-stranded DNA-binding proteins (SSBs) are ubiquitous oligomeric proteins that bind with very high affinity to single-stranded DNA and have a variety of essential roles in DNA metabolism. Nanoelectrospray ionization mass spectrometry (nanoESI-MS) was used to monitor subunit exchange in full-length and truncated forms of the homotetrameric SSB from Escherichia coli. Subunit exchange in the native protein was found to occur slowly over a period of hours, but was significantly more rapid in a truncated variant of SSB from which the eight C-terminal residues were deleted. This effect is proposed to result from C-terminus mediated stabilization of the SSB tetramer, in which the C-termini interact with the DNA-binding cores of adjacent subunits. NanoESI-MS was also used to examine DNA binding to the SSB tetramer. Binding of single-stranded oligonucleotides [one molecule of (dT)(70), one molecule of (dT)(35), or two molecules of (dT)(35)] was found to prevent SSB subunit exchange. Transfer of SSB tetramers between discrete oligonucleotides was also observed and is consistent with predictions from solution-phase studies, suggesting that SSB-DNA complexes can be reliably analyzed by ESI mass spectrometry.

Regulatory consequences of gene translocation in bacteria

Gene translocations play an important role in the plasticity and evolution of bacterial genomes. In this study, we investigated the impact on gene regulation of three genome organizational features that can be altered by translocations: (i) chromosome position; (ii) gene orientation; and (iii) the distance between a target gene and its transcription factor gene (‘target-TF distance’). Specifically, we quantified the effect of these features on constitutive expression, transcription factor binding and/or gene expression noise using a synthetic network in Escherichia coli composed of a transcription factor (LacI repressor) and its target gene (yfp). Here we show that gene regulation is generally robust to changes in chromosome position, gene orientation and target-TF distance. The only demonstrable effect was that chromosome position alters constitutive expression, due to changes in gene copy number and local sequence effects, and that this determines maximum and minimum expression levels. The results were incorporated into a mathematical model which was used to quantitatively predict the responses of a simple gene network to gene translocations; the predictions were confirmed experimentally. In summary, gene translocation can modulate constitutive gene expression levels due to changes in chromosome position but it has minimal impact on other facets of gene regulation.

DnaB helicase activity is modulated by DNA geometry and force

The replicative helicase for Escherichia coli is DnaB, a hexameric, ring-shaped motor protein that encircles and translocates along ssDNA, unwinding dsDNA in advance of its motion. The microscopic mechanisms of DnaB are unknown; further, prior work has found that DnaB's activity is modified by other replication proteins, indicating some mechanistic flexibility. To investigate these issues, we quantified translocation and unwinding by single DnaB molecules in three tethered DNA geometries held under tension. Our data support the following conclusions: 1), Unwinding by DnaB is enhanced by force-induced destabilization of dsDNA. 2), The magnitude of this stimulation varies with the geometry of the tension applied to the DNA substrate, possibly due to interactions between the helicase and the occluded ssDNA strand. 3), DnaB unwinding and (to a lesser extent) translocation are interrupted by pauses, which are also dependent on force and DNA geometry. 4), DnaB moves slower when a large tension is applied to the helicase-bound strand, indicating that it must perform mechanical work to compact the strand against the applied force. Our results have implications for the molecular mechanisms of translocation and unwinding by DnaB and for the means of modulating DnaB activity.

Single-molecule studies of the replisome

Replication of DNA is carried out by the replisome, a multiprotein complex responsible for the unwinding of parental DNA and the synthesis of DNA on each of the two DNA strands. The impressive speed and processivity with which the replisome duplicates DNA are a result of a set of tightly regulated interactions between the replication proteins. The transient nature of these protein interactions makes it challenging to study the dynamics of the replisome by ensemble-averaging techniques. This review describes single-molecule methods that allow the study of individual replication proteins and their functioning within the replisome. The ability to mechanically manipulate individual DNA molecules and record the dynamic behavior of the replisome while it duplicates DNA has led to an improved understanding of the molecular mechanisms underlying DNA replication.

Active and passive mechanisms of helicases

In this work, we discuss the active or passive character of helicases. In the past years, several studies have used the theoretical framework proposed by Betterton and Julicher [Betterton, M.D. and Julicher, F. (2005) Opening of nucleic-acid double strands by helicases: active versus passive opening. Phys. Rev. E, 71, 11904-11911.] to analyse the unwinding data and assess the mechanism of the helicase under study (active versus passive). However, this procedure has given rise to apparently contradictory interpretations: helicases exhibiting similar behaviour have been classified as both active and passive enzymes [Johnson, D.S., Bai, L. Smith, B.Y., Patel, S.S. and Wang, M.D. (2007) Single-molecule studies reveal dynamics of DNA unwinding by the ring-shaped T7 helicase. Cell, 129, 1299-1309; Lionnet, T., Spiering, M.M., Benkovic, S.J., Bensimon, D. and Croquette, V. (2007) Real-time observation of bacteriophage T4 gp41 helicase reveals an unwinding mechanism Proc. Natl Acid. Sci., 104, 19790-19795]. In this work, we show that when the helicase under study has not been previously well characterized (namely, if its step size and rate of slippage are unknown) a multi-parameter fit to the afore-mentioned model can indeed lead to contradictory interpretations. We thus propose to differentiate between active and passive helicases on the basis of the comparison between their observed translocation velocity on single-stranded nucleic acid and their unwinding rate of double-stranded nucleic acid (with various GC content and under different tensions). A threshold separating active from passive behaviour is proposed following an analysis of the reported activities of different helicases. We study and contrast the mechanism of two helicases that exemplify these two behaviours: active for the RecQ helicase and passive for the gp41 helicase.

Allosteric control of the RNA polymerase by the elongation factor RfaH

Efficient transcription of long polycistronic operons in bacteria frequently relies on accessory proteins but their molecular mechanisms remain obscure. RfaH is a cellular elongation factor that acts as a polarity suppressor by increasing RNA polymerase (RNAP) processivity. In this work, we provide evidence that RfaH acts by reducing transcriptional pausing at certain positions rather than by accelerating RNAP at all sites. We show that ‘fast’ RNAP variants are characterized by pause-free RNA chain elongation and are resistant to RfaH action. Similarly, the wild-type RNAP is insensitive to RfaH in the absence of pauses. In contrast, those enzymes that may be prone to falling into a paused state are hypersensitive to RfaH. RfaH inhibits pyrophosphorolysis of the nascent RNA and reduces the apparent Michaelis–Menten constant for nucleotides, suggesting that it stabilizes the post-translocated, active RNAP state. Given that the RfaH-binding site is located 75 Å away from the RNAP catalytic center, these results strongly indicate that RfaH acts allosterically. We argue that despite the apparent differences in the nucleic acid targets, the time of recruitment and the binding sites on RNAP, unrelated antiterminators (such as RfaH and λQ) utilize common strategies during both recruitment and anti-pausing modification of the transcription complex.

FtsK controls metastable recombination provoked by an extra Ter site in the Escherichia coli chromosome terminus

The FtsK protein is required for septum formation in Escherichia coli and as a DNA translocase for chromosome processing while the septum closes. Its domain of action on the chromosome overlaps the replication terminus region, which lies between replication pause sites TerA and TerC. An extra Ter site, PsrA*, has been inserted at a position common to the FtsK and terminus domains. It is well tolerated, although it compels replication forks travelling clockwise from oriC to stall and await arrival of counter-clockwise forks. Elevated recombination has been detected at the stalled fork. Analysis of PsrA*-induced homologous recombination by an excision test revealed unique features. (i) rates of excision near PsrA* may fluctuate widely from clone to clone, a phenomenon we term whimsicality, (ii) excision rates are nevertheless conserved for many generations, a phenomenon we term memorization; their metastability at the clone level is explainable by frequent shifting between three cellular states--high, medium and low probability of excision, (iii) PsrA*-induced excision is RecBC-independent and is strongly counteracted by FtsK, which in addition is involved in its whimsicality and (iv) whimsicality disappears as the distance from the pause site increases. Action of FtsK at a replication fork was unexpected because the factor was thought to act on the chromosome only at septation, i.e. after replication is completed. Idiosyncrasy of PsrA*-induced recombination is discussed with respect to possible intermingling of replication, repair and post-replication steps of bacterial chromosome processing during the cell cycle.

Single-molecule studies of complex systems: the replisome

A complete, system-level understanding of biological processes requires comprehensive information on the kinetics and thermodynamics of the underlying biochemical reactions. A wide variety of structural, biochemical, and molecular biological techniques have led to a quantitative understanding of the molecular properties and mechanisms essential to the processes of life. Yet, the ensemble averaging inherent to these techniques limits us in understanding the dynamic behavior of the molecular participants. Recent advances in imaging and molecular manipulation techniques have made it possible to observe the activity of individual enzymes and record "molecular movies" that provide insight into their dynamics and reaction mechanisms. An important future goal is extending the applicability of single-molecule techniques to the study of larger, more complex multi-protein systems. In this review, the DNA replication machinery will be used as an example to illustrate recent progress in the development of various single-molecule techniques and its contribution to our understanding of the orchestration of multiple enzymatic processes in large biomolecular systems.

Characterization of the unique C terminus of the Escherichia coli tau DnaX protein. Monomeric C-tau binds alpha AND DnaB and can partially replace tau in reconstituted replication forks

A contact between the dimeric tau subunit within the DNA polymerase III holoenzyme and the DnaB helicase is required for replication fork propagation at physiologically-relevant rates (Kim, S., Dallmann, H. G., McHenry, C. S., and Marians, K. J. (1996) Cell 84, 643-650). In this report, we exploit the OmpT protease to generate C-tau, a protein containing only the unique C-terminal sequences of tau, free of the sequences shared with the alternative gamma frameshifting product of dnaX. We have established that C-tau is a monomer by sedimentation equilibrium and sedimentation velocity ultracentrifugation. Monomeric C-tau binds the alpha catalytic subunit of DNA polymerase III with a 1:1 stoichiometry. C-tau also binds DnaB, revealed by a coupled immunoblotting method. C-tau restores the rapid replication rate of inefficient forks reconstituted with only the gamma dnaX gene product. The acceleration of the DnaB helicase can be observed in the absence of primase, when only leading-strand replication occurs. This indicates that C-tau, bound only to the leading-strand polymerase, can trigger the conformational change necessary for DnaB to assume the fast, physiologically relevant form.

Resolution of concerted versus sequential mechanisms in photo-induced double-proton transfer reaction in 7-azaindole H-bonded dimer

The experimental and theoretical bases for a synchronous or concerted double-proton transfer in centro-symmetric H-bonded electronically excited molecular dimers are presented. The prototype model is the 7-azaindole dimer. New research offers confirmation of a concerted mechanism for excited-state biprotonic transfer. Recent femtosecond photoionization and coulombic explosion techniques have given rise to time-of-flight MS observations suggesting sequential two-step biprotonic transfer for the same dimer. We interpret the overall species observed in the time-of-flight experiments as explicable without conflict with the concerted mechanism of proton transfer.

Coupling of a replicative polymerase and helicase: a tau-DnaB interaction mediates rapid replication fork movement

The E. coli replication fork synthesizes DNA at the rate of nearly 1000 nt/s. We show here that an interaction between the tau subunit of the replicative polymerase (the DNA polymerase III holoenzyme) and the replication fork DNA helicase (DnaB) is required to mediate this high rate of replication fork movement. In the absence of this interaction, the polymerase follows behind the helicase at a rate equal to the slow (approximately 35 nt/s) unwinding rate of the helicase alone, whereas upon establishing a tau-DnaB contact, DnaB becomes a more effective helicase, increasing its translocation rate by more than 10-fold. This finding establishes the existence of both a physical and communications link between the two major replication machines in the replisome: the DNA polymerase and the primosome.

Accessory protein function in the DNA polymerase III holoenzyme from E. coli

DNA polymerases which duplicate cellular chromosomes are multiprotein complexes. The individual functions of the many proteins required to duplicate a chromosome are not fully understood. The multiprotein complex which duplicates the Escherichia coli chromosome, DNA polymerase III holoenzyme (holoenzyme), contains a DNA polymerase subunit and nine accessory proteins. This report summarizes our current understanding of the individual functions of the accessory proteins within the holoenzyme, lending insight into why a chromosomal replicase needs such a complex structure.

Detection and possible role of two large nondivisible zones on the Escherichia coli chromosome

Inversion of many predetermined segments of the Escherichia coli chromosome was attempted by using a system for in vivo selection of genomic rearrangements. Two types of constraints on these inversions were observed: (i) a sensitivity to rich medium when the distance between oriC and the 86- to 91-min region (which carries loci essential for transcription and translation) is increased; (ii) a poor viability or inviability of inversions having at least one endpoint in the one-third of the chromosome around replication terminators (with an exception for some inversions ending between these terminators). Although the first constraint is simply explained by a decreased dosage of the region involved, the second one may result from disruption of two long-range chromosomal organizations. The nondivisible zones thus disclosed coincide remarkably well with the two zones that we have previously described, which are polarized with respect to their replication. It is proposed that the two phenomena result from a sequence-dependent and polarized organization of the terminal region of the chromosome, which defines chromosome replication arms and may participate in nucleoid organization.

Early increases in the frequency of DNA initiations and of phospholipid synthesis discontinuities after nutritional shift-up in Escherichia coli

Cultures of Escherichia coli (strains ML30 and K12 AB1157), synchronized by repeated phosphate starvation, were submitted to nutritional shifts-up at various cell ages. The progression of the replication forks was assessed by DNA-DNA hybridization of pulse-labelled chromosomal DNA with plasmid DNA probes containing specific chromosomal sequences. The rate of phospholipid synthesis and its cyclic discontinuities were measured by continuous and pulse labelling with palmitate. The DNA-DNA hybridization experiments showed that a shift-up induces a burst of initiation from the oriC region. These hybridization results, taken together with older data from the literature, suggest that most DNA initiations belonging to this burst are not followed by complete replication. Following a shift-up, the rate of phospholipid synthesis is maintained for 13-20 min, depending on cell age at shift-up, then doubles. The new steady-state rate of phospholipid synthesis is reached through a series of three doublings, while the cell mass doubles approximately twice. This discrepancy brings the rate of phospholipid synthesis per mass unit to its steady-state postshift value.

A stochastic process determines the time at which cell division begins in Escherichia coli

The theoretical distributions of cell masses in exponential cultures of bacteria were derived for both total cells and cells having formed a constriction in preparation for division. The parameters used for this derivation include the mass doubling time, tau, the T-period, and 3 statistical parameters (h, sigma 1, sigma 2) which describe the variability of the cell cycle. The theoretical distributions were compared with observed distributions from E. coli B/rA growing in glucose minimal medium (45 min doubling time) to determine whether a stochastic process in the division pathway affects the time of initiation of constriction or the duration of the constriction process. The results indicate that the stochastic process determines the onset rather than the completion of constriction and that the timing of this process is coupled (6% variability, = sigma 1) to a given cell mass. The values obtained for the duration of the T-period, T = 9.3 min, and for a half-life parameter associated with the stochastic process, h = 4.3 min, agree with previously reported data.

Initiation of enzymatic replication at the origin of the Escherichia coli chromosome: primase as the sole priming enzyme

The enzymatic replication of plasmids containing the unique (245 base pair) origin of the Escherichia coli chromosome (oriC) can be initiated with any of three enzyme priming systems: primase alone, RNA polymerase alone, or both combined (Ogawa, T., Baker, T. A., van der Ende, A. & Kornberg, A. (1985) Proc. Natl. Acad. Sci. USA 82, 3562-3566). At certain levels of auxiliary proteins (topoisomerase I, protein HU, and RNase H), the solo primase system is efficient and responsible for priming synthesis of all DNA strands. Replication of oriC plasmids is here separated into four stages: (i) formation of an isolable, prepriming complex requiring oriC, dnaA protein, dnaB protein, dnaC protein, gyrase, single-strand binding protein, and ATP; (ii) formation of a primed template by primase; (iii) rapid, semiconservative replication by DNA polymerase III holoenzyme; and (iv) conversion of nearly completed daughter molecules to larger DNA forms. Optimal initiation of the leading strand of DNA synthesis, over a range of levels of auxiliary proteins, appears to depend on transcriptional activation of the oriC region by RNA polymerase prior to priming by primase.

DNA polymerase III holoenzyme of Escherichia coli: components and function of a true replicative complex

The DNA polymerase III holoenzyme is a complex, multisubunit enzyme that is responsible for the synthesis of most of the Escherichia coli chromosome. Through studies of the structure, function and regulation of this enzyme over the past decade, considerable progress has been made in the understanding of the features of a true replicative complex. The holoenzyme contains at least seven different subunits. Three of these, alpha, epsilon and theta, compose the catalytic core. Apparently alpha is the catalytic subunit and the product of the dnaE gene. Epsilon, encoded by dnaQ (mutD), is responsible for the proofreading 3'----5' activity of the polymerase. The function of the theta subunit remains to be established. The auxiliary subunits, beta, gamma and delta, encoded by dnaN, dnaZ and dnaX, respectively, are required for the functioning of the polymerase on natural chromosomes. All of the proteins participate in increasing the processivity of the polymerase and in the ATP-dependent formation of an initiation complex. Tau causes the polymerase to dimerize, perhaps forming a structure that can coordinate leading and lagging strand synthesis at the replication fork. This dimeric complex may be asymmetric with properties consistent with the distinct requirements for leading and lagging strand synthesis.

Replication initiated at the origin (oriC) of the E. coli chromosome reconstituted with purified enzymes

A crude soluble enzyme system capable of authentic replication of a variety of oriC plasmids has been replaced by purified proteins constituting three functional classes: initiation proteins (RNA polymerase, dnaA protein, gyrase) that recognize the oriC sequence and presumably prime the leading strand of the replication fork; replication proteins (DNA polymerase III holoenzyme, single-strand binding protein, primosomal proteins) that sustain progress of the replication fork; and specificity proteins (topoisomerase I, RNAase H, protein HU) that suppress initiation of replication at sequences other than oriC, coated with dnaA protein. Protein HU and unidentified factors in crude enzyme fractions stimulate replication at one or more stages. Replication has been separated temporally and physically into successive stages of RNA synthesis and DNA synthesis.

Cell cycle in Mycobacterium phlei

The initial replication region of the chromosome on the replication map of M. phlei constructed by means of sequential mutagenesis in synchronous populations was accurately determined. By following the time shift of the replication moment of the genes bac and met in the control culture and in the culture with the initial inhibition of DNA synthesis by nalidixic acid the start of replication of the chromosome was determined at 15 min before replication of the gene ile. On the basis of the results obtained a scheme of the cell cycle in M. phlei was proposed. Intervals C and D depend on the generation time, become prolonged independently of each other and assume the whole cycle. The ratio C/(C + D) equals to 0.56 and the interval D has a value of 0.76 of the interval C. The mutual ratio of the intervals C : D is 1.3 : 1.0. The obtained results make it possible to form the assumption about mutual ratios between the chromosome replication and cell division in bacteria exhibiting slow growth rates.

The repA2 gene of the plasmid R100.1 encodes a repressor of plasmid replication

We have constructed two miniplasmids, derived from the resistance plasmid R100.1. In one of these plasmids 400 bp of R100.1 DNA have been replaced by DNA from the transposon Tn1000 (gamma-delta). This substitution removes the amino-terminal end of the repA2 coding sequence of R100.1 and results in an increased copy number of the plasmid carrying the substitution. The copy number of the substituted plasmid is reduced to normal levels in the presence of R100.1. The repA2 gene thus encodes a trans-acting repressor function involved in the control of plasmid replication.

Autoregulation of the tyrR gene

Strains of Escherichia coli K-12 in which the transcription of lacZ is initiated from the tyrR promoter have been constructed by use of the Mu d (Apr lac) phage of Casadaban and Cohen (Proc. Natl. Acad. Sci. U.S.A. 76:4530-4533, 1979). These strains have been used to examine the regulation of expression from the tyrR promoter, with the synthesis of beta-galactosidase used as an index of expression. The specific activity of beta-galactosidase fell to 51% upon introduction of lambda (Tn10) tyrR+; to 39% upon introduction of F123, an F-prime carrying tyrR+; to 29% upon introduction of pMU309, a derivative of the plasmid RP4 carrying tyrR+; and to 13.6% upon introduction of pMU352, a derivative of the multicopy plasmid pBR322 carrying tyrR+. These results indicate that the tyrR gene product interacts with its own promoter-operator region, decreasing synthesis of beta galactosidase in the tyrR::Mu d (Apr lac) strains. The increasing extent of repression of beta-galactosidase synthesis with increasing tyrR+ gene dosage was accompanied by increasing repression of the synthesis of tyrosine- and phenylalanine-repressible 3-deoxy-D-arabinoheptulosonic acid-7-phosphate synthetases. The interaction of the repressor with tyrRo appears unusual in the sense that aporepressor alone is probably one of the repressing species. The levels of beta-galactosidase synthesized in the tyrR::Mu d (Apr lac) strains indicate that tyrR has a relatively efficient promoter, the maximum levels representing on the order of a relatively efficient promoter, the maximum levels representing on the order of 1,000 monomers of beta-galactosidase per cell in the tyrR strain and about 500 monomers in the tyrR+ haploid strain.

The initiation of chromosome replication in a dnaAts46 and a dnaA+ strain at various temperatures

The regulation of chromosome replication initiation was studied at various temperatures with an E. coli dnaA46 strain and its dnaA+ parent. We find that, in both strains, the "initiation mass" varies depending upon growth temperature while the replication time remains constant relative to the cell doubling time. In the permissive temperature range, the initiation mass of the dnaA46 mutant strain is larger by a constant factor than that for a dnaA+ strain. We conclude that, even at temperatures permissive for growth of the dnaA46 strain, the activity of the dnaA46 product is lower than that of the wild-type protein. The dnaA gene product, therefore, plays an important role in regulating initiation.

DNA synthesis in Escherichia coli during a nutritional shift-up

DNA synthesis in a thymine-requiring Escherichia coli K12 strain was studied by exploiting deoxyguanosine, so simulating the behaviour of Thy+ strains. DNA synthesis is inhibited during the first 24 min after a nutritional shift-up. The new DNA/mass is lower than that predicted by current models for initiation control.