Opening of a monomer-monomer interface of the trimeric bacteriophage T4-coded GP45 sliding clamp is required for clamp loading onto DNA

Replication clamps and clamp loaders

To achieve the high degree of processivity required for DNA replication, DNA polymerases associate with ring-shaped sliding clamps that encircle the template DNA and slide freely along it. The closed circular structure of sliding clamps necessitates an enzyme-catalyzed mechanism, which not only opens them for assembly and closes them around DNA, but specifically targets them to sites where DNA synthesis is initiated and orients them correctly for replication. Such a feat is performed by multisubunit complexes known as clamp loaders, which use ATP to open sliding clamp rings and place them around the 3' end of primer-template (PT) junctions. Here we discuss the structure and composition of sliding clamps and clamp loaders from the three domains of life as well as T4 bacteriophage, and provide our current understanding of the clamp-loading process.

Processivity factor of DNA polymerase and its expanding role in normal and translesion DNA synthesis

Clamp protein or clamp, initially identified as the processivity factor of the replicative DNA polymerase, is indispensable for the timely and faithful replication of DNA genome. Clamp encircles duplex DNA and physically interacts with DNA polymerase. Clamps from different organisms share remarkable similarities in both structure and function. Loading of clamp onto DNA requires the activity of clamp loader. Although all clamp loaders act by converting the chemical energy derived from ATP hydrolysis to mechanical force, intriguing differences exist in the mechanistic details of clamp loading. The structure and function of clamp in normal and translesion DNA synthesis has been subjected to extensive investigations. This review summarizes the current understanding of clamps from three kingdoms of life and the mechanism of loading by their cognate clamp loaders. We also discuss the recent findings on the interactions between clamp and DNA, as well as between clamp and DNA polymerase (both the replicative and specialized DNA polymerases). Lastly the role of clamp in modulating polymerase exchange is discussed in the context of translesion DNA synthesis.

Multiple ATP binding is required to stabilize the "activated" (clamp open) clamp loader of the T4 DNA replication complex

Most DNA replication systems include a sliding clamp that encircles the genomic DNA and links the polymerase to the template to control polymerase processivity. A loading complex is required to open the clamp and place it onto the DNA. In phage T4 this complex consists of a trimeric clamp of gp45 subunits and a pentameric loader assembly of four gp44 and one gp62 subunit(s), with clamp loading driven by ATP binding. We measure this binding as a function of input ligand concentration and show that four ATPs bind to the gp44/62 complex with equal affinity. In contrast, the ATPase rate profile of the clamp-clamp loader complex exhibits a marked peak at an input ATP concentration close to the overall Kd (approximately 30 microm), with further increases in bound ATP decreasing the ATPase rate to a much lower level. Thus the progressive binding of the four ATPs triggers a conformational change in the complex that markedly inhibits ATPase activity. This inhibition is related to ring opening by using a clamp that is covalently cross-linked across its subunit interfaces and thus rendered incapable of opening. Binding of this clamp abolishes substrate inhibition of the ATPase but leaves ATP binding unchanged. We show that four ATP ligands must bind to the T4 clamp loader before the loader can be fully "activated" and the clamp opened, and that ATP hydrolysis is required only for release of the loader complex after clamp loading onto the replication fork has been completed.

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.

Chemical cross-linking and mass spectrometry for protein structural modeling

The growth of gene and protein sequence information is currently so rapid that three-dimensional structural information is lacking for the overwhelming majority of known proteins. In this review, efforts towards rapid and sensitive methods for protein structural characterization are described, complementing existing technologies. Based on chemical cross-linking and offering the analytical speed and sensitivity of mass spectrometry these methodologies are thought to contribute valuable tools towards future high throughput protein structure elucidation.

Communication over a large distance: enhancers and insulators

Enhancers are regulatory DNA sequences that can work over a large distance. Efficient enhancer action over a distance clearly requires special mechanisms for facilitating communication between the enhancer and its target. While the chromatin looping model can explain the majority of the observations, some recent experimental findings suggest that a chromatin scanning mechanism is used to establish the loop. These new findings help to understand the mechanism of action of the elements that can prevent enhancer-promoter communication (insulators).

Bacteriophage T4 genome

Phage T4 has provided countless contributions to the paradigms of genetics and biochemistry. Its complete genome sequence of 168,903 bp encodes about 300 gene products. T4 biology and its genomic sequence provide the best-understood model for modern functional genomics and proteomics. Variations on gene expression, including overlapping genes, internal translation initiation, spliced genes, translational bypassing, and RNA processing, alert us to the caveats of purely computational methods. The T4 transcriptional pattern reflects its dependence on the host RNA polymerase and the use of phage-encoded proteins that sequentially modify RNA polymerase; transcriptional activator proteins, a phage sigma factor, anti-sigma, and sigma decoy proteins also act to specify early, middle, and late promoter recognition. Posttranscriptional controls by T4 provide excellent systems for the study of RNA-dependent processes, particularly at the structural level. The redundancy of DNA replication and recombination systems of T4 reveals how phage and other genomes are stably replicated and repaired in different environments, providing insight into genome evolution and adaptations to new hosts and growth environments. Moreover, genomic sequence analysis has provided new insights into tail fiber variation, lysis, gene duplications, and membrane localization of proteins, while high-resolution structural determination of the "cell-puncturing device," combined with the three-dimensional image reconstruction of the baseplate, has revealed the mechanism of penetration during infection. Despite these advances, nearly 130 potential T4 genes remain uncharacterized. Current phage-sequencing initiatives are now revealing the similarities and differences among members of the T4 family, including those that infect bacteria other than Escherichia coli. T4 functional genomics will aid in the interpretation of these newly sequenced T4-related genomes and in broadening our understanding of the complex evolution and ecology of phages-the most abundant and among the most ancient biological entities on Earth.

The mechanism of transcriptional activation by the topologically DNA-linked sliding clamp of bacteriophage T4

Three viral proteins participate directly in transcription of bacteriophage T4 late genes: the sigma-family protein gp55 provides promoter recognition, gp33 is the co-activator, and gp45 is the activator of transcription; gp33 also represses transcription in the absence of gp45. Transcriptional activation by gp45, the toroidal sliding clamp of the T4 DNA polymerase holoenzyme, requires assembly at primer-template junctions by its clamp loader. The mechanism of transcriptional activation has been analyzed by examining rates of formation of open promoter complexes. The basal gp55-RNA polymerase holoenzyme is only weakly held in its initially formed closed promoter complex, which subsequently opens very slowly. Activation ( approximately 320-fold in this work) increases affinity in the closed complex and accelerates promoter opening. Promoter opening by gp55 is also thermo-irreversible: the T4 late promoter does not open at 0 degrees C, but once opened at 30 degrees C remains open upon shift to the lower temperature. At a hybrid promoter for sigma(70) and gp55-holoenzymes, only gp55 confers thermo-irreversibility of promoter opening. Interaction of gp45 with a C-terminal epitope of gp33 is essential for the co-activator function of gp33.

Replisome-mediated DNA replication

The elaborate process of genomic replication requires a large collection of proteins properly assembled at a DNA replication fork. Several decades of research on the bacterium Escherichia coli and its bacteriophages T4 and T7 have defined the roles of many proteins central to DNA replication. These three different prokaryotic replication systems use the same fundamental components for synthesis at a moving DNA replication fork even though the number and nature of some individual proteins are different and many lack extensive sequence homology. The components of the replication complex can be grouped into functional categories as follows: DNA polymerase, helix destabilizing protein, polymerase accessory factors, and primosome (DNA helicase and DNA primase activities). The replication of DNA derives from a multistep enzymatic pathway that features the assembly of accessory factors and polymerases into a functional holoenzyme; the separation of the double-stranded template DNA by helicase activity and its coupling to the primase synthesis of RNA primers to initiate Okazaki fragment synthesis; and the continuous and discontinuous synthesis of the leading and lagging daughter strands by the polymerases. This review summarizes and compares and contrasts for these three systems the types, timing, and mechanism of reactions and of protein-protein interactions required to initiate, control, and coordinate the synthesis of the leading and lagging strands at a DNA replication fork and comments on their generality.

Dynamic protein interactions in the bacteriophage T4 replisome

The bacteriophage T4 DNA replisome is a complex dynamic system employing a variety of proteins to orchestrate the synthesis of DNA on both the leading and lagging strands. Assembly of the protein complexes responsible for DNA synthesis and priming requires the coordination of transient biomolecular interactions. This interplay of proteins has been dissected through the use of small molecules including fluorescent probes and crosslinkers, enabling the development of a complex dynamic structural and kinetic model for DNA polymerase holoenzyme assembly and primosome formation.

Dissection of the ATP-driven reaction cycle of the bacteriophage T4 DNA replication processivity clamp loading system

Processive DNA replication requires the loading of a multisubunit ring-shaped protein complex, known as a sliding or processivity clamp, onto the primer-template (p/t) DNA. This clamp then binds to the replication polymerase to form a processive polymerase holoenzyme. The processivity of the holoenzyme derives from the topological properties of the clamp, which encircles the DNA without actually binding to it. Multisubunit complexes known as clamp-loaders utilize ATP to drive the placement of this ring around the DNA. To further understand the role of ATP binding and hydrolysis in driving clamp-loading in the DNA replication system of bacteriophage T4, we report the results of a series of presteady-state and steady-state kinetic ATPase experiments involving the various components of the reconstituted system. The results obtained are consistent with a mechanism in which a slow step, which involves the binary ATP-bound clamp-clamp loader complex, activates this complex and permits p/t DNA to bind and stimulate ATP hydrolysis. ATP hydrolysis itself, as well as the subsequent (after clamp-loading) dissociation of the clamp-loader and the slippage of the loaded clamp from the p/t DNA construct, are shown to be fast steps. A second slow step occurs after ATP hydrolysis. This step involves the dissociated clamp loader complex and may reflect ADP release. Only one molecule of ATP is hydrolyzed per clamp-loading event. Rate constants for each step, and an overall reaction mechanism for the T4 clamp-loading system, are derived from these data and from other results in the literature. The principles that emerge fit into a general framework that can apply to many biological processes involving ATP-driven reaction cycles.