The role of the bacteriophage T4 gene 32 protein in homologous pairing

Enzyme-Assisted Nucleic Acid Amplification in Molecular Diagnosis: A Review

Infectious diseases and tumors have become the biggest medical challenges in the 21st century. They are driven by multiple factors such as population growth, aging, climate change, genetic predispositions and more. Nucleic acid amplification technologies (NAATs) are used for rapid and accurate diagnostic testing, providing critical information in order to facilitate better follow-up treatment and prognosis. NAATs are widely used due their high sensitivity, specificity, rapid amplification and detection. It should be noted that different NAATs can be selected according to different environments and research fields; for example, isothermal amplification with a simple operation can be preferred in developing countries or resource-poor areas. In the field of translational medicine, CRISPR has shown great prospects. The core component of NAAT lies in the activity of different enzymes. As the most critical material of nucleic acid amplification, the key role of the enzyme is self-evident, playing the upmost important role in molecular diagnosis. In this review, several common enzymes used in NAATs are compared and described in detail. Furthermore, we summarize both the advances and common issues of NAATs in clinical application.

In vitro reconstitution of DNA replication initiated by genetic recombination: a T4 bacteriophage model for a type of DNA synthesis important for all cells

Using a mixture of 10 purified DNA replication and DNA recombination proteins encoded by the bacteriophage T4 genome, plus two homologous DNA molecules, we have reconstituted the genetic recombination–initiated pathway that initiates DNA replication forks at late times of T4 bacteriophage infection. Inside the cell, this recombination-dependent replication (RDR) is needed to produce the long concatemeric T4 DNA molecules that serve as substrates for packaging the shorter, genome-sized viral DNA into phage heads. The five T4 proteins that catalyze DNA synthesis on the leading strand, plus the proteins required for lagging-strand DNA synthesis, are essential for the reaction, as are a special mediator protein (gp59) and a Rad51/RecA analogue (the T4 UvsX strand-exchange protein). Related forms of RDR are widespread in living organisms—for example, they play critical roles in the homologous recombination events that can restore broken ends of the DNA double helix, restart broken DNA replication forks, and cross over chromatids during meiosis in eukaryotes. Those processes are considerably more complex, and the results presented here should be informative for dissecting their detailed mechanisms.

Isothermal Amplification of Long, Discrete DNA Fragments Facilitated by Single-Stranded Binding Protein

Isothermal amplification methods for detection of DNA and RNA targets have expanded significantly in recent years, promising a new wave of simple and rapid molecular diagnostics. Current isothermal methods result in the generation of short fragments (<150 base pairs) or highly branched long DNA products. Here we report the amplification of discrete target fragments of several kilobases at 37 °C from both double- and single-stranded circular template DNA using specific primer pairs. In contrast to existing methods, this amplification requires only the single-stranded DNA-binding protein gp32 from bacteriophage T4 and a strand-displacing DNA polymerase. In addition to the discrete amplicon products, this method also produces higher molecular weight products consisting of multiple repeated copies of the amplicon and template DNA. We demonstrate that two features of gp32 enable this amplification: a facilitation of primer strand invasion into double-stranded DNA, and a suppression of non-homologous primer annealing and nonspecific amplification. The ability presented here to produce long, discrete DNA products in an isothermal reaction extends the scope of isothermal amplification to enable more useful applications of these promising methods.

Control of helicase loading in the coupled DNA replication and recombination systems of bacteriophage T4

The Gp59 protein of bacteriophage T4 promotes DNA replication by loading the replicative helicase, Gp41, onto replication forks and recombination intermediates. Gp59 also blocks DNA synthesis by Gp43 polymerase until Gp41 is loaded, ensuring that synthesis is tightly coupled to unwinding. The distinct polymerase blocking and helicase loading activities of Gp59 likely involve different binding interactions with DNA and protein partners. Here, we investigate how interactions of Gp59 with DNA and Gp32, the T4 single-stranded DNA (ssDNA)-binding protein, are related to these activities. A previously characterized mutant, Gp59-I87A, exhibits markedly reduced affinity for ssDNA and pseudo-fork DNA substrates. We demonstrate that on Gp32-covered ssDNA, the DNA binding defect of Gp59-I87A is not detrimental to helicase loading and translocation. In contrast, on pseudo-fork DNA the I87A mutation is detrimental to helicase loading and unwinding in the presence or absence of Gp32. Other results indicate that Gp32 binding to lagging strand ssDNA relieves the blockage of Gp43 polymerase activity by Gp59, whereas the inhibition of Gp43 exonuclease activity is maintained. Our findings suggest that Gp59-Gp32 and Gp59-DNA interactions perform separate but complementary roles in T4 DNA metabolism; Gp59-Gp32 interactions are needed to load Gp41 onto D-loops, and other nucleoprotein structures containing clusters of Gp32. Gp59-DNA interactions are needed to load Gp41 onto nascent or collapsed replication forks lacking clusters of Gp32 and to coordinate bidirectional replication from T4 origins. The dual functionalities of Gp59 allow it to promote the initiation or re-start of DNA replication from a wide variety of recombination and replication intermediates.

Coordinated Binding of Single-Stranded and Double-Stranded DNA by UvsX Recombinase

Homologous recombination is important for the error-free repair of DNA double-strand breaks and for replication fork restart. Recombinases of the RecA/Rad51 family perform the central catalytic role in this process. UvsX recombinase is the RecA/Rad51 ortholog of bacteriophage T4. UvsX and other recombinases form presynaptic filaments on ssDNA that are activated to search for homology in dsDNA and to perform DNA strand exchange. To effectively initiate recombination, UvsX must find and bind to ssDNA within an excess of dsDNA. Here we examine the binding of UvsX to ssDNA and dsDNA in the presence and absence of nucleotide cofactor, ATP. We also examine how the binding of one DNA substrate is affected by simultaneous binding of the other to determine how UvsX might selectively assemble on ssDNA. We show that the two DNA binding sites of UvsX are regulated by the nucleotide cofactor ATP and are coordinated with each other such that in the presence of ssDNA, dsDNA binding is significantly reduced and correlated with its homology to the ssDNA bound to the enzyme. UvsX has high affinity for dsDNA in the absence of ssDNA, which may allow for sequestration of the enzyme in an inactive form prior to ssDNA generation.

Assembly and dynamics of Gp59-Gp32-single-stranded DNA (ssDNA), a DNA helicase loading complex required for recombination-dependent replication in bacteriophage T4

The Gp59 protein of bacteriophage T4 plays critical roles in recombination-dependent DNA replication and repair by correctly loading the replicative helicase, Gp41, onto recombination intermediates. Previous work demonstrated that Gp59 is required to load helicase onto single-stranded DNA that is saturated with Gp32, the T4 single-stranded DNA (ssDNA)-binding protein. Gp59 and Gp32 bind simultaneously to ssDNA, forming a Gp59-Gp32-ssDNA complex that is a key intermediate in helicase loading. Here we characterize the assembly and dynamics of this helicase loading complex (HLC) through changes in the fluorescent states of Gp32F, a fluorescein-Gp32 conjugate. Results show that HLC formation requires a minimum Gp32-ssDNA cluster size and that Gp59 co-localizes with Gp32-ssDNA clusters in the presence of excess free ssDNA. These and other results indicate that Gp59 targets helicase assembly onto Gp32-ssDNA clusters that form on the displaced strand of D-loops, which suggests a mechanism for the rapid initiation of recombination-dependent DNA replication. Helicase loading at the HLC requires ATP binding (not hydrolysis) by Gp41 and results in local remodeling of Gp32 within the HLC. Subsequent ATPase-driven translocation of Gp41 progressively disrupts Gp32-ssDNA interactions. Evidence suggests that Gp59 from the HLC is recycled to promote multiple rounds of helicase assembly on Gp32-ssDNA, a capability that could be important for the restart of stalled replication forks.

Assembly and dynamics of the bacteriophage T4 homologous recombination machinery

Homologous recombination (HR), a process involving the physical exchange of strands between homologous or nearly homologous DNA molecules, is critical for maintaining the genetic diversity and genome stability of species. Bacteriophage T4 is one of the classic systems for studies of homologous recombination. T4 uses HR for high-frequency genetic exchanges, for homology-directed DNA repair (HDR) processes including DNA double-strand break repair, and for the initiation of DNA replication (RDR). T4 recombination proteins are expressed at high levels during T4 infection in E. coli, and share strong sequence, structural, and/or functional conservation with their counterparts in cellular organisms. Biochemical studies of T4 recombination have provided key insights on DNA strand exchange mechanisms, on the structure and function of recombination proteins, and on the coordination of recombination and DNA synthesis activities during RDR and HDR. Recent years have seen the development of detailed biochemical models for the assembly and dynamics of presynaptic filaments in the T4 recombination system, for the atomic structure of T4 UvsX recombinase, and for the roles of DNA helicases in T4 recombination. The goal of this chapter is to review these recent advances and their implications for HR and HDR mechanisms in all organisms.

Dynamics of bacteriophage T4 presynaptic filament assembly from extrinsic fluorescence measurements of Gp32-single-stranded DNA interactions

In the bacteriophage T4 homologous recombination system, presynaptic filament assembly on single-stranded (ssDNA) DNA requires UvsX recombinase, UvsY mediator, and Gp32 ssDNA-binding proteins. Gp32 exerts both positive and negative effects on filament assembly: positive by denaturing ssDNA secondary structure, and negative by competing with UvsX for ssDNA binding sites. UvsY is believed to help UvsX displace Gp32 from the ssDNA. To test this model we developed a real-time fluorescence assay for Gp32-ssDNA interactions during presynapsis, based on changes in the fluorescence of a 6-iodoacetamidofluorescein-Gp32 conjugate. Results demonstrate that the formation of UvsX presynaptic filaments progressively disrupts Gp32-ssDNA interactions. Under stringent salt conditions the disruption of Gp32-ssDNA by UvsX is both ATP- and UvsY-dependent. The displacement of Gp32 from ssDNA during presynapsis requires ATP binding, but not ATP hydrolysis, by UvsX protein. Likewise, UvsY-mediated presynapsis strongly requires UvsY-ssDNA interactions, and is optimal at a 1:1 stoichiometry of UvsY to UvsX and/or ssDNA binding sites. Presynaptic filaments formed in the presence of UvsY undergo assembly/collapse that is tightly coupled to the ATP hydrolytic cycle and to stringent competition for ssDNA binding sites between Gp32 and various nucleotide-liganded forms of UvsX. The data directly support the Gp32 displacement model of UvsY-mediated presynaptic filament assembly, and demonstrate that the transient induction of high affinity UvsX-ssDNA interactions by ATP are essential, although not sufficient, for Gp32 displacement. The underlying dynamics of protein-ssDNA interactions within presynaptic filaments suggests that rearrangements of UvsX, UvsY, and Gp32 proteins on ssDNA may be coupled to central processes in T4 recombination metabolism.

The Rad51-dependent pairing of long DNA substrates is stabilized by replication protein A

Rad51 protein forms nucleoprotein filaments on single-stranded DNA (ssDNA) and then pairs that DNA with the complementary strand of incoming duplex DNA. In apparent contrast with published results, we demonstrate that Rad51 protein promotes an extensive pairing of long homologous DNAs in the absence of replication protein A. This pairing exists only within the Rad51 filament; it was previously undetected because it is lost upon deproteinization. We further demonstrate that RPA has a critical postsynaptic role in DNA strand exchange, stabilizing the DNA pairing initiated by Rad51 protein. Stabilization of the Rad51-generated DNA pairing intermediates can be can occur either by binding the displaced strand with RPA or by degrading the same DNA strand using exonuclease VII. The optimal conditions for Rad51-mediated DNA strand exchange used here minimize the secondary structure in single-stranded DNA, minimizing the established presynaptic role of RPA in facilitating Rad51 filament formation. We verify that RPA has little effect on Rad51 filament formation under these conditions, assigning the dramatic stimulation of strand exchange nevertheless afforded by RPA to its postsynaptic function of removing the displaced DNA strand from Rad51 filaments.

Mediator proteins orchestrate enzyme-ssDNA assembly during T4 recombination-dependent DNA replication and repair

Studies of recombination-dependent replication (RDR) in the T4 system have revealed the critical roles played by mediator proteins in the timely and productive loading of specific enzymes onto single-stranded DNA (ssDNA) during phage RDR processes. The T4 recombination mediator protein, uvsY, is necessary for the proper assembly of the T4 presynaptic filament (uvsX recombinase cooperatively bound to ssDNA), leading to the recombination-primed initiation of leading strand DNA synthesis. In the lagging strand synthesis component of RDR, replication mediator protein gp59 is required for the assembly of gp41, the DNA helicase component of the T4 primosome, onto lagging strand ssDNA. Together, uvsY and gp59 mediate the productive coupling of homologous recombination events to the initiation of T4 RDR. UvsY promotes presynaptic filament formation on 3' ssDNA-tailed chromosomes, the physiological primers for T4 RDR, and recent results suggest that uvsY also may serve as a coupling factor between presynapsis and the nucleolytic resection of double-stranded DNA ends. Other results indicate that uvsY stabilizes uvsX bound to the invading strand, effectively preventing primosome assembly there. Instead, gp59 directs primosome assembly to the displaced strand of the D loop/replication fork. This partitioning mechanism enforced by the T4 recombination/replication mediator proteins guards against antirecombination activity of the helicase component and ensures that recombination intermediates formed by uvsX/uvsY will efficiently be converted into semiconservative DNA replication forks. Although the major mode of T4 RDR is semiconservative, we present biochemical evidence that a conservative "bubble migration" mode of RDR could play a role in lesion bypass by the T4 replication machinery.

Mutations in the N-terminal cooperativity domain of gene 32 protein alter properties of the T4 DNA replication and recombination systems

The gene 32 protein (gp32) of bacteriophage T4 is the essential single-stranded DNA (ssDNA)-binding protein required for phage DNA replication and recombination. gp32 binds ssDNA with high affinity and cooperativity, forming contiguous clusters that optimally configure the ssDNA for recognition by DNA polymerase or recombination enzymes. The precise roles of gp32 affinity and cooperativity in promoting replication and recombination have yet to be defined, however. Previous work established that the N-terminal "B-domain" of gp32 is essential for cooperativity and that point mutations at Arg(4) and Lys(3) positions have varying and dramatic effects on gp32-ssDNA interactions. Therefore, we examined the effects of six different gp32 B-domain mutants on T4 in vitro systems for DNA synthesis and homologous pairing. We find that the B-domain is essential for gp32's stimulation of these reactions. The stimulatory efficacy of gp32 B-domain mutants generally correlates with the hierarchy of relative ssDNA binding affinities, i.e. wild-type gp32 approximately R4K > K3A approximately R4Q > R4T > R4G gp32-B. However, the functional defect of a particular mutant is often greater than can be explained simply by its ability to saturate the ssDNA at equilibrium, suggesting additional defects in the proper assembly and activity of DNA polymerase and recombinase complexes on ssDNA, which may derive from a decreased lifetime of gp32-ssDNA clusters.

Mechanistic parallels between DNA replication, recombination and transcription

The multiprotein complexes that mediate replication, transcription and homologous recombination in eukaryotic cells face many of the same molecular challenges. These include the recognition of DNA sites embedded in large chromatinized genomes, the denaturation of duplex DNA, and partial dissociation and reassociation at different stages of the catalytic cycle. Therefore, it is not surprising that several steps in the respective catalytic cycles are strikingly similar at the DNA level and may proceed by similar mechanisms. Some of these relationships are reviewed here. It is argued that speculation based on such 'crosspathway' comparisons may be a valuable paradigm for the design of new experiments.

Characterization of an amino-terminal fragment of the bacteriophage T4 uvsY recombination protein

The uvsY protein plays essential roles in homologous genetic recombination processes in the bacteriophage T4. In vitro, uvsY promotes the formation of presynaptic filaments containing stoichiometric amounts of the T4 uvsX recombinase bound to single-stranded DNA. uvsY protein has intrinsic binding activities towards ssDNA, uvsX, and gp32, the T4-encoded SSB, however, it has not been directly determined which of these activities are essential for uvsY's role in presynapsis. We have therefore sought to generate altered forms of uvsY deficient in uvsX- and/or gp32-binding, in order to assess whether these specific protein-protein interactions are essential for uvsY recombination functions. Limited chymotrypsinolysis of the 16 kDa uvsY protein generates two major fragments: an 11.5 kDa fragment containing the N-terminus of uvsY, and a 4.5 kDa C-terminal fragment. We have expressed and purified the large fragment as a fusion protein containing the N-terminal 101 amino acids of uvsY. We show that this truncated uvsY species, which we call uvsYNT, retains ssDNA-binding activity, but is devoid of both uvsX- and gp32-binding activities. Like native uvsY, uvsYNT stimulates the ssDNA-dependent ATPase activity of the uvsX protein, however, the synergistic effects observed between uvsY, uvsX, and gp32 are not observed with uvsYNT. In addition, uvsYNT weakly stimulates uvsX-catalyzed DNA strand exchange reactions. The latter result is surprising since it suggests that specific interactions with uvsX and/or gp32 are not absolutely essential for uvsY recombination functions. Taken together, the data are consistent with a model in which uvsY-ssDNA interactions alone are capable of promoting the assembly of functional uvsX-ssDNA complexes, while uvsY-protein interactions stabilize uvsX-ssDNA complexes.

Role of the bacteriophage T7 and T4 single-stranded DNA-binding proteins in the formation of joint molecules and DNA helicase-catalyzed polar branch migration

Bacteriophage T7 gene 2.5 single-stranded DNA-binding protein and gene 4 DNA helicase together promote pairing of two homologous DNA molecules and subsequent polar branch migration (Kong, D., and Richardson, C. C. (1996) EMBO J. 15, 2010-2019). In this report, we show that gene 2.5 protein is not required for the initiation or propagation of strand transfer once a joint molecule has been formed between the two DNA partners, a reaction that is mediated by the gene 2.5 protein alone. A mutant gene 2.5 protein, gene 2.5-Delta21C protein, lacking 21 amino acid residues at its C terminus, cannot physically interact with gene 4 protein. Although it does bind to single-stranded DNA and promote the formation of joint molecule via homologous base pairing, subsequent strand transfer by gene 4 helicase is inhibited by the presence of the gene 2.5-Delta21C protein. Bacteriophage T4 gene 32 protein likewise inhibits T7 gene 4 protein-mediated strand transfer, whereas Escherichia coli single-stranded DNA-binding protein does not. The 63-kDa gene 4 protein of phage T7 is also a DNA primase in that it catalyzes the synthesis of oligonucleotides at specific sequences during translocation on single-stranded DNA. We find that neither the rate nor extent of strand transfer is significantly affected by concurrent primer synthesis. The bacteriophage T4 gene 41 helicase has been shown to catalyze polar branch migration after the T4 gene 59 helicase assembly protein loads the helicase onto joint molecules formed by the T4 UvsX and gene 32 proteins (Salinas, F., and Kodadek, T. (1995) Cell 82, 111-119). We find that gene 32 protein alone forms joint molecules between partially single-stranded homologous DNA partners and that subsequent branch migration requires this single-stranded DNA-binding protein in addition to the gene 41 helicase and the gene 59 helicase assembly protein. Similar to the strand transfer reaction, strand displacement DNA synthesis catalyzed by T4 DNA polymerase also requires the presence of gene 32 protein in addition to the gene 41 and 59 proteins.

The gene 32 single-stranded DNA-binding protein is not bound stably to the phage T4 presynaptic filament

A central reaction in homologous recombination is synapsis, which involves invasion of duplex DNA by a homologous single strand. A key intermediate in this process is the presynaptic filament, a protein-DNA complex composed of a "strand transferase" polymerized along the invading single strand. In this report, the organization and mechanism of assembly of the bacteriophage T4 presynaptic filament are explored. Three T4 proteins, encoded by the uvsX, uvsY and 32 genes, are involved in this process. It is demonstrated that a well-defined series of events involving multiple protein-DNA and protein-protein interactions is required to mediate a transition from an initial gene 32-DNA complex to a mature presynaptic filament in which the UvsX and UvsY proteins are in contact with the DNA and each other, while most or all of the gene 32 protein is removed from the complex.

Intron mobility in phage T4 occurs in the context of recombination-dependent DNA replication by way of multiple pathways

Numerous group I introns in both prokaryotes and eukaryotes behave as mobile genetic elements. The functional requirements for intron mobility were determined in the T4 phage system using an in vivo assay to measure intron homing with wild-type and mutant derivatives. Thus, it was demonstrated that intron mobility occurs in the context of phage recombination-dependent replication, a pathway that uses overlapping subsets of replication and recombination functions. The functional requirements for intron homing and the nature of recombinant products are only partially consistent with the accepted double-strand-break repair (DSBR) model for intron inheritance, and implicate additional homing pathways. Whereas ambiguities in resolvase requirements and underrepresentation of crossover recombination products are difficult to rationalize strictly by DSBR, these properties are most readily consistent with a synthesis-dependent strand annealing (SDSA) pathway. These pathways share common features in the strand invasion steps, but differ in subsequent repair synthesis and resolution steps, influencing the genetic consequences of the intron transfer event.

Phage T4 homologous strand exchange: a DNA helicase, not the strand transferase, drives polar branch migration

Homologous strand exchange is a central step in general genetic recombination. A multiprotein complex composed of five purified bacteriophage T4 proteins (the products of the uvsX, uvsY, 32, 41, and 59 genes) that mediates strand exchange under physiologically relevant conditions has been reconstituted. One of these proteins, the product of the uvsY gene, is required for homologous pairing but strongly inhibits branch migration catalyzed by UvsX protein, the phage RecA analog. Branch migration is completely dependent on the gene 41 protein, a DNA helicase that also functions in phage replication. The helicase is delivered to the strand exchange complex by the gene 59 accessory protein in a strand-specific fashion through direct interactions between the gene 59 and gene 32 proteins. These data suggest that strand transferases such as UvsX protein are essential for homologous pairing in vivo, but that a DNA helicase drives polar branch migration.

Enhancement of RecA strand-transfer activity by the RecJ exonuclease of Escherichia coli

We have examined coupled reactions with the RecA protein of Escherichia coli, which can mediate DNA strand exchange in vitro between homologous DNA molecules, and the RecJ exonuclease, a 5' to 3' single-stranded DNA exonuclease. In RecA-mediated strand-transfer reactions between circular single-stranded and duplex linear DNA, we have found that RecJ stimulates the rate of heteroduplex product formation. Because RecJ must be present concurrent with strand transfer and RecJ does not detectably stimulate the synapsis stage of the reaction, we believe that RecJ stimulates specifically the branch migration phase of the RecA strand-transfer reaction. RecJ also dramatically enhances the efficiency with which RecA is able to transverse regions of non-homology in the substrates. We propose a model where RecJ degrades the displaced strand produced by strand exchange which competes for pairing with the transferred strand, thus driving forward the unidirectional branch migration mediated by RecA protein. This suggests a new role for exonucleases in genetic recombination, facilitating the strand-transfer reaction itself.

Recombination apparatus of T4 phage

The substantial process of general DNA recombination consists of production of ssDNA, exchange of the ssDNA and its homologous strand in a duplex, and cleavage of branched DNA to maturate recombination intermediates. Ten genes of T4 phage are involved in general recombination and apparently encode all of the proteins required for its own recombination. Several proteins among them interact with each other in a highly specific manner based on a protein-protein affinity and constitute a multicomponent protein machine to create an ssDNA gap essential for production of recombinogenic ssDNA, a machine to supply recombinogenic ssDNA which has a free end, or a machine to transfer the recombinogenic single strand into a homologous duplex.

Effects of substitution of proposed Zn(II) ligand His81 or His64 in phage T4 gene 32 protein: spectroscopic evidence for a novel zinc coordination complex

T4 gene 32 protein (gp32), the prototype helix-destabilizing or single-stranded (ss) DNA binding protein, contains one tightly coordinated Zn2+ ion bound tetrahedrally by three cysteines (residues 77, 87, and 90) and a fourth non-thiol donor. In previous work, it was shown that the proposed non-thiol ligand His81 could be readily substituted with nonliganding glutamine and alanine residues without deleterious effects on gp32 structure and simple assays of ssDNA binding. In this paper we show that exchange broadening of bulk 35Cl- anion by protein-bound Zn(II) is not observed in the His81-->Ala (H81A) mutant, unless the coordination site is disrupted with an organomercurial, p-mercuriphenylsulfonate. This suggests that, in the mutant protein, anions, and by implication solvent molecules, do not gain access to a newly formed inner shell Zn(II) coordination site as a result of mutagenesis. H81A gp32 is characterized by nearly wild-type helix-destabilizing activity on poly(d[A-T]) and highly cooperative binding to the polynucleotide poly(A) at pH 7.7 over the temperature range from 20 to 42 degrees C at 0.35 M NaCl, exhibiting only a approximately 2.5-4-fold decrease in poly(A) affinity. Limited proteolysis experiments show that an additional tryptic cleavage site maps to the Arg111-Lys112 bond within the protease-resistant core domain of the H81A gp32 following long incubation times and results in the accumulation of a 16-kDa subcore fragment. This new cleavage site is within the internal LAST motif, which has been proposed to be directly involved in cooperative ssDNA binding [Casas-Finet, J. R., & Karpel, R. L. (1993) Biochemistry 32, 9735-9744]. Thus substitution of His81 with Ala subtly alters the conformation or dynamics of the backbone around the LAST motif, which may be manifest as a moderately lower cooperative binding affinity of H81A gp32 for polynucleotides. H81A gp32, however, is fully functional in stimulating in vitro homologous pairing catalyzed by the T4 recombinase uvsX protein. Since substitution of His81 with a nonliganding Ala is nearly silent, we propose an alternative mode of Zn(II) coordination in T4 gene 32 protein, involving His64 rather than His81 as the fourth non-thiol ligand. That replacement of His64, and not His81, with Cys results in marked changes in the first coordination sphere of ligands as evidenced by the optical spectrum of Co(II)-substituted H64C gp32 is consistent with the noninvolvement of His81 and implicates a novel His64-X12-Cys77-X9-Cys87-X2-Cys90 coordination motif, unique among zinc-containing nucleic acid binding proteins.

Energetics of arginine-4 substitution mutants in the N-terminal cooperativity domain of T4 gene 32 protein

Gene 32 protein (gp32) from bacteriophage T4 is a sequence-nonspecific single-strand (ss) nucleic acid binding protein which binds highly cooperatively to ss nucleic acids. The N-terminal "B" or basic domain (residues 1-21) is known to be required for highly cooperative binding by gp32 (where K(app) = K(int) omega, omega > or = 500), since its removal results in a protein which binds ss nucleic acids noncooperatively (omega = 1). In this paper, we probe the molecular details of cooperative binding by gp32 by physicochemical characterization of a set of four single amino acid substitution mutants of Arg4: Lys4 (R4K gp32), Gln4 (R4Q gp32), Thr4 (R4T gp32), and Gly4 (R4G gp32). The qualitative ranking of binding affinities to poly(A) is wild-type > or = R4K > R4Q > R4T > R4G > gp32-B (gp32 lacking the first 21 amino acids). The occluded site size is n(app) = 7.5 +/- 0.5 for all gp32s. Resolution of K(int) and omega for wild-type, R4K, R4Q, and R4T gp32s was estimated under conditions of low lattice saturation (v < or = 0.011) using multiple reverse fluorescence titrations collected at 10 mM Tris-HCl, pH 8.1, 20 degrees C, and a NaCl concentration where K(app) was (2-4) x 10(6) M-1 for each gp32 on the ribohomopolymer poly(A). Binding parameters for all gp32s were obtained directly or compared by conservative extrapolation of the [NaCl] dependence of K(app) to 0.20 M NaCl, 20 degrees C, pH 8.1. The magnitude of omega was then assumed not to vary with [NaCl] (shown for R4T gp32), allowing estimation of K(int) at 0.20 M NaCl. We find that R4K gp32 binds to poly(A) with an overall affinity (K(app)) which is 2-3-fold lower than wild-type gp32, while omega for each molecule seems indistinguishable (wild-type gp32, omega approximately 800-1300; R4K gp32, omega approximately 600-1200). Surprisingly, R4Q gp32 is characterized by an omega also not readily distinguishable from the wild-type and R4K proteins (omega approximately 800-4400), while K(app) is reduced about 10-fold. This mutant also shows a significantly reduced [NaCl] dependence of the binding to poly(A). R4T gp32 binds about 10-fold weaker than the Q mutant. It exhibits an omega ranging from 300 to 700 and a substantially reduced [NaCl] dependence (delta log K(int)/delta log [NaCl] = -1.4 from 0.10 to 0.20 M NaCl), indicative of significant perturbations in both K(int) and omega terms.(ABSTRACT TRUNCATED AT 400 WORDS)

The genetics of the Luria-Latarjet effect in bacteriophage T4: evidence for the involvement of multiple DNA repair pathways

The Luria-Latarjet effect is an increase in resistance of a virus to DNA damage during infection of a host. It has often been assumed to involve recombinational repair, but this has never been demonstrated experimentally. Using nine bacteriophage (phage) T4 mutants, I present evidence indicating that, for phage T4, the Luria-Latarjet effect is due to three repair pathways-excision repair, post-replication-recombinational-repair (PRRR) and multiplicity reactivation (MR) (a second form of recombinational repair). The results also show that the Luria-Latarjet effect develops in two stages. The first stage starts soon after infection. Damage which occurs during the first stage can be repaired by excision repair or PRRR. The second stage appears to start after the first round of DNA replication is complete. DNA damage which occurs during this stage can apparently be repaired by MR as well as the other two repair pathways. The results of this study support the hypothesis that recombinational repair has been selected to ensure that the progeny phage genomes which are packaged have minimum DNA damage. Since other viruses which infect bacterial, animal and plant cells show a Luria-Latarjet effect similar to that in phage T4, the conclusions from this study may have wide applicability.

An overview of homologous pairing and DNA strand exchange proteins

Processes fundamental to all models of genetic recombination include the homologous pairing and subsequent exchange of DNA strands. Biochemical analysis of these events has been conducted primarily on the recA protein of Escherichia coli, although proteins which can promote such reactions have been purified from many sources, both prokaryotic and eukaryotic. The activities of these homologous pairing and DNA strand exchange proteins are either ATP-dependent, as predicted based on the recA protein paradigm, or, more unexpectedly, ATP-independent. This review examines the reactions promoted by both classes of proteins and highlights their similarities and differences. The mechanistic implications of the apparent existence of 2 classes of strand exchange protein are discussed.

Functional interactions between phage T4 and E. coli DNA-binding proteins during the presynapsis phase of homologous recombination

The "protein machine" for phage T4 homologous recombination has begun to be assembled in vitro. A particularly heavily studied reaction has been the uvsX protein (a RecA-like strand transferase)-mediated homologous pairing reaction between single and double-stranded DNAs, a key step in the recombination cycle in vivo. A necessary prerequisite for uvsX protein-mediated pairing is the polymerization of this factor along the invading single strand, a process known as presynapsis. Recent work has indicated that at least two other T4 recombination factors are involved in this process as well, the uvsY and gene 32 products. These proteins are also ssDNA-binding factors and exhibit an affinity for UvsX and each other. In order to begin to sort out the potential functional roles played by these protein-protein interactions in presynapsis, I have examined the ability of the uvsX protein to form stable filaments along ssDNA in the presence of these proteins. It is shown that the uvsY protein relieves the inhibition to filament formation due to the presence of the gene 32 protein, but experiments with the E. coli SSB protein (the bacterial analogue of gp32) suggest that this effect does not involve a direct interaction between UvsY and gp32.