Dissociative Properties of the Proteins within the Bacteriophage T4 Replisome

C-terminal Domain of T4 gene 32 Protein Enables Rapid Filament Reorganization and Dissociation

Bacteriophage T4 gene 32 protein (gp32) is a single-stranded DNA (ssDNA) binding protein essential for DNA replication. gp32 forms stable protein filaments on ssDNA through cooperative interactions between its core and N-terminal domain. gp32's C-terminal domain (CTD) is believed to primarily help coordinate DNA replication via direct interactions with constituents of the replisome. However, the exact mechanisms of these interactions are not known, and it is unclear how tightly-bound gp32 filaments are readily displaced from ssDNA as required for genomic processing. Here, we utilized truncated gp32 variants to demonstrate a key role of the CTD in regulating gp32 dissociation. Using optical tweezers, we probed the binding and dissociation dynamics of CTD-truncated gp32, *I, to an 8.1 knt ssDNA molecule and compared these measurements with those for full-length gp32. The *I-ssDNA helical filament becomes progressively unwound with increased protein concentration but remains significantly more stable than that of full-length, wild-type gp32. Protein oversaturation, concomitant with filament unwinding, facilitates rapid dissociation of full-length gp32 from across the entire ssDNA segment. In contrast, *I primarily unbinds slowly from only the ends of the cooperative clusters, regardless of the protein density and degree of DNA unwinding. Our results suggest that the CTD may constrain the relative twist angle of proteins within the ssDNA filament such that upon critical unwinding the cooperative interprotein interactions largely vanish, facilitating prompt removal of gp32. We propose a model of CTD-mediated gp32 displacement via internal restructuring of its filament, providing a mechanism for rapid ssDNA clearing during genomic processing.

Understanding DNA replication by the bacteriophage T4 replisome

The T4 replisome has provided a unique opportunity to investigate the intricacies of DNA replication. We present a comprehensive review of this system focusing on the following: its 8-protein composition, their individual and synergistic activities, and assembly in vitro and in vivo into a replisome capable of coordinated leading/lagging strand DNA synthesis. We conclude with a brief comparison with other replisomes with emphasis on how coordinated DNA replication is achieved.

Coordinated DNA Replication by the Bacteriophage T4 Replisome

The T4 bacteriophage encodes eight proteins, which are sufficient to carry out coordinated leading and lagging strand DNA synthesis. These purified proteins have been used to reconstitute DNA synthesis in vitro and are a well-characterized model system. Recent work on the T4 replisome has yielded more detailed insight into the dynamics and coordination of proteins at the replication fork. Since the leading and lagging strands are synthesized in opposite directions, coordination of DNA synthesis as well as priming and unwinding is accomplished by several protein complexes. These protein complexes serve to link catalytic activities and physically tether proteins to the replication fork. Essential to both leading and lagging strand synthesis is the formation of a holoenzyme complex composed of the polymerase and a processivity clamp. The two holoenzymes form a dimer allowing the lagging strand polymerase to be retained within the replisome after completion of each Okazaki fragment. The helicase and primase also form a complex known as the primosome, which unwinds the duplex DNA while also synthesizing primers on the lagging strand. Future studies will likely focus on defining the orientations and architecture of protein complexes at the replication fork.

Insights into Okazaki fragment synthesis by the T4 replisome: the fate of lagging-strand holoenzyme components and their influence on Okazaki fragment size

In this study, we employed a circular replication substrate with a low priming site frequency (1 site/1.1 kb) to quantitatively examine the size distribution and formation pattern of Okazaki fragments. Replication reactions by the T4 replisome on this substrate yielded a patterned series of Okazaki fragments whose size distribution shifted through collision and signaling mechanisms as the gp44/62 clamp loader levels changed but was insensitive to changes in the gp43 polymerase concentration, as expected for a processive, recycled lagging-strand polymerase. In addition, we showed that only one gp45 clamp is continuously associated with the replisome and that no additional clamps accumulate on the DNA, providing further evidence that the clamp departs, whereas the polymerase is recycled upon completion of an Okazaki fragment synthesis cycle. We found no support for the participation of a third polymerase in Okazaki fragment synthesis.

RETRACTED: Polymerase exchange during Okazaki fragment synthesis observed in living cells

DNA replication machineries have been studied extensively, but the kinetics of action of their components remains largely unknown. We report a study of DNA synthesis during replication in living Escherichia coli cells. Using single-molecule microscopy, we observed repetitive fluorescence bursts of single polymerase IIIs (Pol IIIs), indicating polymerase exchange at the replication fork. Fluctuations in the amount of DNA-bound single-stranded DNA-binding protein (SSB) reflect different speeds for the leading- and lagging-strand DNA polymerases. Coincidence analyses of Pol III and SSB fluctuations show that they correspond to the lagging-strand synthesis and suggest the use of a new Pol III for each Okazaki fragment. Based on exchanges involving two Pol IIIs, we propose that the third polymerase in the replisome is involved in lagging-strand synthesis.

Response of the bacteriophage T4 replisome to noncoding lesions and regression of a stalled replication fork

DNA is constantly damaged by endogenous and exogenous agents. The resulting DNA lesions have the potential to halt the progression of the replisome, possibly leading to replication fork collapse. Here, we examine the effect of a noncoding DNA lesion in either leading strand template or lagging strand template on the bacteriophage T4 replisome. A damaged base in the lagging strand template does not affect the progression of the replication fork. Instead, the stalled lagging strand polymerase recycles from the lesion and initiates the synthesis of a new Okazaki fragment upstream of the damaged base. In contrast, when the replisome encounters a blocking lesion in the leading strand template, the replication fork only travels approximately 1 kb beyond the point of the DNA lesion before complete replication fork collapse. The primosome and the lagging strand polymerase remain active during this period, and an Okazaki fragment is synthesized beyond the point of the leading strand lesion. There is no evidence for a new priming event on the leading strand template. Instead, the DNA structure that is produced by the stalled replication fork is a substrate for the DNA repair helicase UvsW. UvsW catalyzes the regression of a stalled replication fork into a "chicken-foot" structure that has been postulated to be an intermediate in an error-free lesion bypass pathway.

Coupling DNA unwinding activity with primer synthesis in the bacteriophage T4 primosome

The unwinding and priming activities of the bacteriophage T4 primosome, which consists of a hexameric helicase (gp41) translocating 5′ to 3′ and an oligomeric primase (gp61) synthesizing primers 5′ to 3′, has been investigated on DNA hairpins manipulated by a magnetic trap. We find that the T4 primosome continuously unwinds the DNA duplex while allowing for primer synthesis through a primosome disassembly mechanism or a novel DNA looping mechanism. A fused gp61-gp41 primosome unwinds and primes DNA exclusively via the DNA looping mechanism. Other proteins within the replisome control the partitioning of these two mechanisms disfavoring primosome disassembly thereby increasing primase processivity. In contrast priming in bacteriophage T7 involves discrete pausing of the primosome and in Escherichia coli appears to be associated primarily with dissociation of the primase from the helicase. Thus nature appears to use several strategies to couple the disparate helicase and primase activities within primosomes.

Motors, switches, and contacts in the replisome

Replisomes are the protein assemblies that replicate DNA. They function as molecular motors to catalyze template-mediated polymerization of nucleotides, unwinding of DNA, the synthesis of RNA primers, and the assembly of proteins on DNA. The replisome of bacteriophage T7 contains a minimum of proteins, thus facilitating its study. This review describes the molecular motors and coordination of their activities, with emphasis on the T7 replisome. Nucleotide selection, movement of the polymerase, binding of the processivity factor, unwinding of DNA, and RNA primer synthesis all require conformational changes and protein contacts. Lagging-strand synthesis is mediated via a replication loop whose formation and resolution is dictated by switches to yield Okazaki fragments of discrete size. Both strands are synthesized at identical rates, controlled by a molecular brake that halts leading-strand synthesis during primer synthesis. The helicase serves as a reservoir for polymerases that can initiate DNA synthesis at the replication fork. We comment on the differences in other systems where applicable.

Repetitive lagging strand DNA synthesis by the bacteriophage T4 replisome

Our studies on the T4 replisome build on the seminal work from the Alberts laboratory. They discovered essentially all the proteins that constitute the T4 replisome, isolated them, and measured their enzymatic activities. Ultimately, in brilliant experiments they reconstituted in vitro a functioning replisome and in the absence of structural information created a mosaic as to how such a machine might be assembled. Their consideration of the problem of continuous leading strand synthesis opposing discontinuous lagging strand synthesis led to their imaginative proposal of the trombone model, an illustration that graces all textbooks of biochemistry. Our subsequent work deepens their findings through experiments that focus on defining the kinetics, structural elements, and protein-protein contacts essential for replisome assembly and function. In this highlight we address when Okazaki primer synthesis is initiated and how the primer is captured by a recycling lagging strand polymerase--problems that the Alberts laboratory likewise found mysterious and significant for all replisomes.

RNA primer handoff in bacteriophage T4 DNA replication: the role of single-stranded DNA-binding protein and polymerase accessory proteins

In T4 phage, coordinated leading and lagging strand DNA synthesis is carried out by an eight-protein complex termed the replisome. The control of lagging strand DNA synthesis depends on a highly dynamic replisome with several proteins entering and leaving during DNA replication. Here we examine the role of single-stranded binding protein (gp32) in the repetitive cycles of lagging strand synthesis. Removal of the protein-interacting domain of gp32 results in a reduction in the number of primers synthesized and in the efficiency of primer transfer to the polymerase. We find that the primase protein is moderately processive, and this processivity depends on the presence of full-length gp32 at the replication fork. Surprisingly, we find that an increase in the efficiency of primer transfer to the clamp protein correlates with a decrease in the dissociation rate of the primase from the replisome. These findings result in a revised model of lagging strand DNA synthesis where the primase remains as part of the replisome after each successful cycle of Okazaki fragment synthesis. A delay in primer transfer results in an increased probability of the primase dissociating from the replication fork. The interplay between gp32, primase, clamp, and clamp loader dictates the rate and efficiency of primer synthesis, polymerase recycling, and primer transfer to the polymerase.

Residence time of receptor-ligand complexes and its effect on biological function

The formation and duration of binary receptor-ligand complexes are fundamental to many physiologic processes. Most often, the effectiveness of interaction between a receptor and its ligand is quantified in terms of closed system, equilibrium affinity measurements, such as IC50 and Kd. In the context of in vivo biology, however, the extent and duration of responses to receptor-ligand interactions depend greatly on the time period over which the ligand is in residence on its receptor. Here we define receptor-ligand complex residence time in quantitative terms and describe its significance to biological function. Examples of the importance of residence time are presented for natural ligands of different receptor types. The impact of residence time on the optimization of potential ligands as drugs for human medicine is also described.

Structure and mechanical properties of artificial protein hydrogels assembled through aggregation of leucine zipper peptide domains

Artificial protein hydrogels made from a triblock protein (designated AC10A, where A is an acidic zipper domain and C10 comprises 10 repeats of the nonapeptide sequence exhibit normalized plateau storage moduli (G'∞/nkT) less than 0.13 at all concentrations, pH values, and ionic strengths examined. These gels are surprisingly soft due to loop formation at the expense of bridges between physical junctions. Molecular-level evidence of loop formation is provided by strong fluorescence energy transfer (FRET) between distinct chromophores placed at the C- and N-termini of labelled chains diluted in an excess of unlabelled chains. The tendency to form loops originates from the compact size of the random coil midblock (mean RH(C10)≈ 20 Å, determined from quasi-elastic light scattering of C10), and is facilitated by the ability of the leucine zipper domains to form antiparallel aggregates. Although the aggregation number of the leucine zipper domains is small (tetrameric, determined from multi-angle static light scattering of AC10 diblock), the average center-to-center distance between aggregates is roughly 1.5 times the average end-to-end distance of the C10 domain in a 7% w/v network. To avoid stretching the C10 domain, the chains tend to form loops. Changes in pH or ionic strength that expand the polyelectrolyte midblock favor bridging, leading to greater G'∞ as long as leucine zipper endblocks do not dissociate. Understanding of the network structure provided successful design strategies to increase the rigidity of these hydrogels. In contrast to intuitive design concepts for rubber and gel materials, it was shown that increasing either the length or the charge density of the midblock increases rigidity, because fewer chains are wasted in loop formation.

The replication clamp-loading machine at work in the three domains of life

Sliding clamps are ring-shaped proteins that tether DNA polymerases to DNA, which enables the rapid and processive synthesis of both leading and lagging strands at the replication fork. The clamp-loading machinery must repeatedly load sliding-clamp factors onto primed sites at the replication fork. Recent structural and biochemical analyses provide unique insights into how these clamp-loading ATPase machines function to load clamps onto the DNA. Moreover, these studies highlight the evolutionary conservation of the clamp-loading process in the three domains of life.

The Control Mechanism for Lagging Strand Polymerase Recycling during Bacteriophage T4 DNA Replication

Given the polarity of DNA duplex, replication by the leading strand polymerase is continuous whereas that by the lagging strand polymerase is discontinuous proceeding through Okazaki fragments. Yet the respective polymerases act processively, implying that the recycling of the lagging strand polymerase is a controlled process. We demonstrate that the rate of the lagging strand polymerase relative to that of fork movement affects Okazaki fragment size and generates ssDNA gaps. We show by using a substrate with limited priming sites that Okazaki fragments can be shifted to shorter lengths by varying the rate of the primase. We find that clamp and clamp loader levels affect both primer utilization and Okazaki fragment size, possibly implicating clamp loading onto the RNA primer in the mechanism of lagging strand polymerase recycling. We formulate a signaling model capable of rationalizing the distribution of Okazaki fragments under various conditions for this and possibly other replisomes.

The oligomeric T4 primase is the functional form during replication

Replisome DNA primases are responsible for the synthesis of short RNA primers required for the initiation of repetitive Okazaki fragment synthesis on the lagging strand during DNA replication. In bacteriophage T4, the primase (gp61) interacts with the helicase (gp41) to form the primosome complex, an interaction that greatly stimulates the priming activity of gp61. Because gp41 is hexameric, a question arises as to whether gp61 also forms a hexameric structure during replication. Several results from this study support such a structure. Titration of the primase/single-stranded DNA binding followed by fluorescence anisotropy implicated a 6:1 stoichiometry. The observed rate constant, k(cat), for priming was found to increase with the primase concentration, implicating an oligomeric form of the primase as the major functional species. The generation of hetero-oligomeric populations of the hexameric primase by controlled mixing of wild type and an inactive mutant primase confirmed the oligomeric nature of the most active primase form. Mutant primases defective in either the N- or C-terminal domains and catalytically inactive could be mixed to create oligomeric primases with restored catalytic activity suggesting an active site shared between subunits. Collectively, these results provide strong evidence for the functional oligomerization of gp61. The potential roles of gp61 oligomerization during lagging strand synthesis are discussed.

Mechanistic studies of the T4 DNA (gp41) replication helicase: functional interactions of the C-terminal Tails of the helicase subunits with the T4 (gp59) helicase loader protein

We compare the activities of the wild-type (gp41WT) and mutant (gp41delta C20) forms of the bacteriophage T4 replication helicase. In the gp41delta C20 mutant the helicase subunits have been genetically truncated to remove the 20 residue C-terminal tail peptide domains present in the wild-type enzyme. Here, we examine the interactions of these helicase forms with the T4 gp59 helicase loader and the gp32 single-stranded DNA binding proteins, both of which are physically and functionally coupled with the helicase in the T4 DNA replication complex. We show that the wild-type and mutant forms of the helicase do not differ in their ability to assemble into dimers and hexamers, nor in their interactions with gp61 (the T4 primase). However they do differ in their gp59-stimulated unwinding activities and in their abilities to translocate along a ssDNA strand that has been coated with gp32. We demonstrate that functional coupling between gp59 and gp41 involves direct interactions between the C-terminal tail peptides of the helicase subunits and the loading protein, and measure the energetics and kinetics of these interactions. This work helps to define a gp41-gp59 assembly pathway that involves an initial interaction between the C-terminal tails of the helicases and the gp59 loader proteins, followed by a conformational change of the helicase subunits that exposes new interaction surfaces, which can then be trapped by the gp59 protein. Our results suggest that the gp41-gp59 complex is then poised to bind ssDNA portions of the replication fork. We suggest that one of the important functions of gp59 may be to aid in the exposure of the ssDNA binding sites of the helicase subunits, which are otherwise masked and regulated by interactions with the helicase carboxy-terminal tail peptides.

Bacteriophage T4 helicase loader protein gp59 functions as gatekeeper in origin-dependent replication in vivo

Bacteriophage T4 initiates origin-dependent replication via an R-loop mechanism in vivo. During in vitro reactions, the phage-encoded gp59 stimulates loading of the replicative helicase, gp41, onto branched intermediates, including origin R-loops. However, although gp59 is essential for recombination-dependent replication from D-loops, it does not appear to be required for origin-dependent replication in vivo. In this study, we have analyzed the origin-replicative intermediates formed during infections that are deficient in gp59 and other phage replication proteins. During infections lacking gp59, the initial replication forks from two different T4 origins actively replicated both leading- and lagging-strands. However, the retrograde replication forks from both origins were abnormal in the gp59-deficient infections. The lagging-strand from the initial fork was elongated as a new leading-strand in the retrograde direction without lagging-strand synthesis, whereas in the wild-type, leading- and lagging-strand synthesis appeared to be coupled. These results imply that gp59 inhibits the polymerase holoenzyme in vivo until the helicase-primase (gp41-gp61) complex is loaded, and we thereby refer to gp59 as a gatekeeper. We also found that all origin-replicative intermediates were absent in infections deficient in the helicase gp41 or the single-strand-binding protein gp32, regardless of whether gp59 was present or absent. These results argue that replication from the origin in vivo is dependent on both the helicase and single-strand-binding protein and demonstrate that the strong replication defect of gene 41 and 32 single mutants is not caused by gp59 inhibition of the polymerase.

The dynamic processivity of the T4 DNA polymerase during replication

The polymerase (gp43) processivity during T4 replisome mediated DNA replication has been investigated. The size of the Okazaki fragments remains constant over a wide range of polymerase concentrations. A dissociation rate constant of approximately 0.0013 sec(-1) was measured for the polymerases from both strands, consistent with highly processive replication on both the leading and lagging strands. This processive replication, however, can be disrupted by a catalytically inactive mutant D408N gp43 that retains normal affinity for DNA and the clamp. The inhibition kinetics fit well to an active exchange model in which the mutant polymerase (the polymerase trap) displaces the replicating polymerase. This kinetic model was further strengthened by the observation that the sizes of both the Okazaki fragments and the extension products on a primed M13mp18 template were reduced in the presence of the mutant polymerase. The effects of the trap polymerase therefore suggest a dynamic processivity of the polymerase during replication, namely, a solution/replisome polymerase exchange takes place without affecting continued DNA synthesis. This process mimics the polymerase switching recently suggested during the translesion DNA synthesis, implies the multiple functions of the clamp in replication, and may play a potential role in overcoming the replication barriers by the T4 replisome.

Inactivation of the 3'-5' exonuclease of the replicative T4 DNA polymerase allows translesion DNA synthesis at an abasic site

Here, we have investigated the consequences of the loss of proof-reading exonuclease function on the ability of the replicative T4 DNA polymerase (gp43) to elongate past a single abasic site located on model DNA substrates. Our results show that wild-type T4 DNA polymerase stopped at the base preceding the lesion on two linear substrates having different sequences, whereas the gp43 D219A exonuclease-deficient mutant was capable of efficient bypass when replicating the same substrates. The structure of the DNA template did not influence the behavior of the exonuclease-proficient or deficient T4 DNA polymerases. In fact, when replicating a damaged "minicircle" DNA substrate constructed by circularizing one of the linear DNA, elongation by wild-type enzyme was still completely blocked by the abasic site, while the D219A mutant was capable of bypass. During DNA replication, the T4 DNA polymerase associates with accessory factors whose combined action increases the polymerase-binding capacity and processivity, and could modulate the behavior of the enzyme towards an abasic site. We thus performed experiments measuring the ability of wild-type and exonuclease-deficient T4 DNA polymerases, in conjunction with these replicative accessory proteins, to perform translesion DNA replication on linear or circular damaged DNA substrates. We found no evidence of either stimulation or inhibition of the bypass activities of the wild-type and exonuclease-deficient forms of T4 DNA polymerase following addition of the accessory factors, indicating that the presence or absence of the proof-reading activity is the major determinant in dictating translesion synthesis of an abasic site by T4 DNA polymerase.

The application of a minicircle substrate in the study of the coordinated T4 DNA replication

A reconstituted in vitro bacteriophage T4 DNA replication system was studied on a synthetic 70-mer minicircle substrate. This substrate was designed so that dGMP and dCMP were exclusively incorporated into the leading and the lagging strand, respectively. This design allows the simultaneous and independent measurement of the leading and lagging strand synthesis. In this paper, we report our results on the characterization of the 70-mer minicircle substrate. We show here that the minicircle substrate supports coordinated leading and lagging strand synthesis under the experimental conditions employed. The rate of the leading strand fork movement was at an average of approximately 150 nucleotides/s. This rate decreased to less than 30 nucleotides/s when the helicase was omitted from the reaction. These results suggest that both the holoenzyme and the primosome can be simultaneously assembled onto the minicircle substrate. The lagging strand synthesized on this substrate is of an average of 1.5 kb, and the length of the Okazaki fragments increased with decreasing [rNTPs]. The proper response of the Okazaki fragment size toward the change of the priming signal further indicates a functional replisome assembled on the minicircle template. The effects of various protein components on the leading and lagging strand synthesis were also studied. The collective results indicate that coordinated strand synthesis only takes place within certain protein concentration ranges. The optimal protein levels of the proteins that constitute the T4 replisome generally bracket the concentrations of the same proteins in vivo. Omission of the primase has little effect on the rate of dNMP incorporation or the rate of the fork movement on the leading strand within the first 30 s of the reaction. This inhibition only becomes significant at later times of the reaction and may be associated with the accumulation of single-stranded DNA leading to the collapse of active replisomes.