T4 DNA Research Articles

3' Branch ligation: a novel method to ligate non-complementary DNA to recessed or internal 3'OH ends in DNA or RNA.

Nucleic acid ligases are crucial enzymes that repair breaks in DNA or RNA during synthesis, repair and recombination. Various genomic tools have been developed using the diverse activities of DNA/RNA ligases. Herein, we demonstrate a non-conventional ability of T4 DNA ligase to insert 5′ phosphorylated blunt-end double-stranded DNA to DNA breaks at 3′-recessive ends, gaps, or nicks to form a Y-shaped 3′-branch structure. Therefore, this base pairing-independent ligation is termed 3′-branch ligation (3′BL). In an extensive study of optimal ligation conditions, the presence of 10% PEG-8000 in the ligation buffer significantly increased ligation efficiency to more than 80%. Ligation efficiency was slightly varied between different donor and acceptor sequences. More interestingly, we discovered that T4 DNA ligase efficiently ligated DNA to the 3′-recessed end of RNA, not to that of DNA, in a DNA/RNA hybrid, suggesting a ternary complex formation preference of T4 DNA ligase. These novel properties of T4 DNA ligase can be utilized as a broad molecular technique in many important genomic applications, such as 3′-end labelling by adding a universal sequence; directional tagmentation for NGS library construction that achieve theoretical 100% template usage; and targeted RNA NGS libraries with mitigated structure-based bias and adapter dimer problems.

Microscale Objects via Restructuring of Large, Double-Stranded DNA Molecules.

As the interest in DNA nanotechnology increases, so does the need for larger and more complex DNA structures. In this work, we describe two methods of using large, double-stranded (ds) DNA to self-assemble sequence-specific, nonrepetitive microscale structures. A model system restructures T7 DNA (40 kb) through sequence-specific biotinylation followed by intramolecular binding to a 40 nm diameter neutravidin bead to create T7 "rosettes". This model system informed the creation of "nodal DNA" where "nodes" with single-stranded DNA flaps are attached to a large dsDNA insert so that a complementary oligonucleotide "strap" bridges the two nodes for restructuring to form a DNA "bolo". To do this in high yield, several methodologies were developed, including a protection/deprotection scheme using RNA/RNase H and dialysis chambers, which remove excess straps while retaining large DNA molecules. To assess these restructuring processes, the DNA was adsorbed onto supported lipid bilayers, allowing for a visual assay of their structure using single-molecule fluorescence microscopy. Good agreement between the expected and observed fluorescence intensity measurements of the individual features of restructured DNA for both the DNA rosettes and bolos gives us a high degree of confidence that both processes give sequence-specific restructuring of large, dsDNA molecules to create microscale objects.

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.

Stretching of single DNA molecules caused by accelerating flow on a microchip.

DNA elongation induced by fluidic stress was investigated on a microfluidic chip composed of a large inlet pool and a narrow channel. Through single-DNA observation with fluorescence microscopy, the manner of stretching of individual T4 DNA molecules (166 kbp) was monitored near the area of accelerating flow with narrowing streamlines. The results showed that the DNA long-axis length increased in a sigmoidal manner depending on the magnitude of flow acceleration, or shear, along the DNA chain. To elucidate the physical mechanism of DNA elongation, we performed a theoretical study by adopting a model of a coarse-grained nonlinear elastic polymer chain elongated by shear stress due to acceleration flow along the chain direction.

Probing conformational change of T7 RNA polymerase and DNA complex by solid-state nanopores**Project supported by the National Natural Science Foundation of China (Grant Nos. 51622201, 91733301, and 61571015).

Proteins are crucial to most biological processes, such as enzymes, and in various catalytic processes a dynamic motion is required. The dynamics of protein are embodied as a conformational change, which is closely related to the flexibility of protein. Recently, nanopore sensors have become accepted as a low cost and high throughput method to study the features of proteins. In this article, we used a SiN nanopore device to study the flexibility of T7 RNA polymerase (RNAP) and its complex with DNA promoter. By calculating full-width at half-maximum (FWHM) of Gaussian fits to the blockade histograms, we found that T7 RNAP becomes more flexible after binding DNA promoter. Moreover, the distribution of fractional current blockade suggests that flexibility alters due to a breath-like change of the volume.

Comprehensive Profiling of Four Base Overhang Ligation Fidelity by T4 DNA Ligase and Application to DNA Assembly.

Synthetic biology relies on the manufacture of large and complex DNA constructs from libraries of genetic parts. Golden Gate and other Type IIS restriction enzyme-dependent DNA assembly methods enable rapid construction of genes and operons through one-pot, multifragment assembly, with the ordering of parts determined by the ligation of Watson-Crick base-paired overhangs. However, ligation of mismatched overhangs leads to erroneous assembly, and low-efficiency Watson Crick pairings can lead to truncated assemblies. Using sets of empirically vetted, high-accuracy junction pairs avoids this issue but limits the number of parts that can be joined in a single reaction. Here, we report the use of comprehensive end-joining ligation fidelity and bias data to predict high accuracy junction sets for Golden Gate assembly. The ligation profile accurately predicted junction fidelity in ten-fragment Golden Gate assembly reactions and enabled accurate and efficient assembly of a lac cassette from up to 24-fragments in a single reaction.

Engineering, Cloning and Expression of Interleukin 2–Com1 Chimera with Aim of Recombinant Subunit Vaccine Production Against Coxiella burnetii

Query fever is an important disease caused by Coxiella burnetii, therefore vaccination against this disease is so crucial. Com1 is one the most important immunogenic proteins of C. burnetii which can be appropriate candidate to design a subunit vaccine. It seems, fusion of this protein with interleukin 2 as a molecular adjuvant can promote its efficacy. To do current study, first, Com1 and interleukin 2 genes were individually amplified by PCR, then these PCR products were applied to fuse interleukin 2 with Com1 using splice overlap extension PCR. The product of splice overlap extension PCR was cloned in pTZ57R/T vector by T/A cloning strategy, after digestion, interleukin 2–Com1 gene was sub-cloned in pET-22b(+) by T4 DNA ligase enzyme. Ligation product was applied to express in BL21 (DE3) strain of Escherichia coli. Expressed interleukin 2–Com1 protein was purified by Nik–NTA affinity column and then confirmed by sodium dodecyl sulfate polyacrylamide gel electrophoresis and western blotting. The results of electrophoresis on agarose 1% gel revealed that, PCR of target genes and splice overlap extension PCR were successfully performed. The results of electrophoresis on 12% sodium dodecyl sulfate polyacrylamide gel confirmed expression and purification of interleukin 2–Com1 protein. Finally, the results of western blotting shown, purified protein with a molecular size of 43.5 kDa belonged IL2–Com1 chimera. The results of present study shown, BL21 (DE3) is an appropriate host to express interleukin 2–Com1 protein. It seems, this chimera can be introduced as a potent candidate to fight with Query fever.

Autocyclized and oxidized forms of SCR7 induce cancer cell death by inhibiting nonhomologous DNA end joining in a Ligase IV dependent manner.

Nonhomologous DNA end joining (NHEJ) is the major DNA double-strand break (DSB) repair pathway in mammals. Previously, we have described a small molecule inhibitor, SCR7, which can inhibit NHEJ in a Ligase IV-dependent manner. Administration of SCR7 within the cells resulted in the accumulation of DNA breaks, cell death, and inhibition of tumor growth in mice. In the present study, we report that parental SCR7, which is unstable, can be autocyclized into a stable form. Both parental SCR7 and cyclized SCR7 possess the same molecular weight (334.09) and molecular formula (C18 H14 N4 OS), whereas its oxidized form, SCR7-pyrazine, possesses a different molecular formula (C18 H12 N4 OS), molecular weight (332.07), and structure. While cyclized form of SCR7 showed robust inhibition of NHEJ in vitro, both forms exhibited efficient cytotoxicity. Cyclized and oxidized forms of SCR7 inhibited DNA end joining catalyzed by Ligase IV, whereas their impact was minimal on Ligase III, Ligase I, and T4 DNA Ligase-mediated joining. Importantly, both forms inhibited V(D)J recombination, although the effect was more pronounced for SCR7-cyclized. Both forms blocked NHEJ in a Ligase IV-dependent manner leading to the accumulation of DSBs within the cells. Although cytotoxicity due to SCR7-cyclized was Ligase IV specific, the pyrazine form exhibited nonspecific cytotoxicity at higher concentrations in Ligase IV-null cells. Finally, we demonstrate that both forms can potentiate the effect of radiation. Thus, we report that cyclized and oxidized forms of SCR7 can inhibit NHEJ in a Ligase IV-dependent manner, although SCR7-pyrazine is less specific to Ligase IV inside the cell.

Hydrophobic Residue in Escherichia coli Thioredoxin Critical for the Processivity of T7 DNA Polymerase.

Bacteriophage T7 uses the thioredoxin of its host, Escherichia coli, to enhance the processivity of its DNA polymerase, a requirement for the growth of phage T7. The evolutionarily conserved structure and high degree of homology of amino acid sequence of the thioredoxin family imply that homologues from other organisms might also interact with T7 DNA polymerase to support the phage growth. Despite the structural resemblance, human thioredoxin, whose X-ray crystallographic structure overlaps with that of the E. coli protein, cannot support T7 phage growth. It does not form a complex with T7 DNA polymerase as determined by surface plasmon resonance and thus does not increase the processivity. Homologous scanning analysis using this nonfunctional homologue reveals that the 60 N-terminal and the 12 C-terminal amino acid residues of E. coli thioredoxin can be substituted for its human counterpart without significantly affecting phage growth. Comparison of chimeric thioredoxins, followed by site-directed mutagenesis, identifies leucine 95 as a critical element. This residue may contribute to hydrophobic interactions with the thioredoxin-binding loop of the polymerase; levels of DNA binding and thus nucleotide polymerization are significantly decreased in the absence of this residue. The results suggest that the specific interactions at the interface of thioredoxin and DNA polymerase, rather than the overall structure, are important in the interactions that promote high processivity.

Quick Click: The DNA-Templated Ligation of 3'-O-Propargyl- and 5'-Azide-Modified Strands Is as Rapid as and More Selective than Ligase.

The copper(I)-mediated azide-alkyne cycloaddition (CuAAC) of 3'-propargyl ether and 5'-azide oligonucleotides is a particularly promising ligation system because it results in triazole linkages that effectively mimic the phosphate-sugar backbone of DNA, leading to unprecedented tolerance of the ligated strands by polymerases. However, for a chemical ligation strategy to be a viable alternative to enzymatic systems, it must be equally as rapid, as discriminating, and as easy to use. We found that the DNA-templated reaction with these modifications was rapid under aerobic conditions, with nearly quantitative conversion in 5 min, resulting in a kobs value of 1.1 min-1 , comparable with that measured in an enzymatic ligation system by using the highest commercially available concentration of T4 DNA ligase. Moreover, the CuAAC reaction also exhibited greater selectivity in discriminating C:A or C:T mismatches from the C:G match than that of T4 DNA ligase at 29 °C; a temperature slightly below the perfect nicked duplex dissociation temperature, but above that of the mismatched duplexes. These results suggest that the CuAAC reaction of 3'-propargyl ether and 5'-azide-terminated oligonucleotides represents a complementary alternative to T4 DNA ligase, with similar reaction rates, ease of setup and even enhanced selectivity for certain mismatches.

Two-Holder Strategy for Efficient and Selective Synthesis of Lk 1 ssDNA Catenane

DNA catenanes are characterized by their flexible and dynamic motions and have been regarded as one of the key players in sophisticated DNA-based molecular machines. There, the linking number (Lk) between adjacent interlocked rings is one of the most critical factors, since it governs the feasibility of dynamic motions. However, there has been no established way to synthesize catenanes in which Lk is controlled to a predetermined value. This paper reports a new methodology to selectively synthesize Lk 1 catenanes composed of single-stranded DNA rings, in which these rings can most freely rotate each other due to minimal inter-ring interactions. To the mixture for the synthesis, two holder strands (oligonucleotides of 18–46 nt) were added, and the structure of the quasi-catenane intermediate was interlocked through Watson–Crick base pairings into a favorable conformation for Lk 1 catenation. The length of the complementary part between the two quasi-rings was kept at 10 bp or shorter. Under these steric constraints, two quasi-rings were cyclized with the use of T4 DNA ligase. By this simple procedure, the formation of undesired topoisomers (Lk ≥ 2) was almost completely inhibited, and Lk 1 catenane was selectively prepared in high yield up to 70 mole%. These Lk 1 catenanes have high potentials as dynamic parts for versatile DNA architectures.

T4 DNA ligase structure reveals a prototypical ATP-dependent ligase with a unique mode of sliding clamp interaction.

DNA ligases play essential roles in DNA replication and repair. Bacteriophage T4 DNA ligase is the first ATP-dependent ligase enzyme to be discovered and is widely used in molecular biology, but its structure remained unknown. Our crystal structure of T4 DNA ligase bound to DNA shows a compact α-helical DNA-binding domain (DBD), nucleotidyl-transferase (NTase) domain, and OB-fold domain, which together fully encircle DNA. The DBD of T4 DNA ligase exhibits remarkable structural homology to the core DNA-binding helices of the larger DBDs from eukaryotic and archaeal DNA ligases, but it lacks additional structural components required for protein interactions. T4 DNA ligase instead has a flexible loop insertion within the NTase domain, which binds tightly to the T4 sliding clamp gp45 in a novel α-helical PIP-box conformation. Thus, T4 DNA ligase represents a prototype of the larger eukaryotic and archaeal DNA ligases, with a uniquely evolved mode of protein interaction that may be important for efficient DNA replication.

Nano-channel of viral DNA packaging motor as single pore to differentiate peptides with single amino acid difference

Detection, differentiation, mapping, and sequencing of proteins are important in proteomics for the assessment of cell development such as protein methylation or phosphorylation as well as the diagnosis of diseases including metabolic disorder, mental illness, immunological ailments, and malignant cancers. Nanopore technology has demonstrated the potential for the sequencing or sensing of DNA, RNA, chemicals, or other macromolecules. Due to the diversity of protein in shape, structure and charge and the composition versatility of 20 amino acids, the sequencing of proteins remains challenging. Herein, we report the application of the channel of bacteriophage T7 DNA packaging motor for the differentiation of an assortment of peptides of a single amino acid difference. Explicit fingerprints or signatures were obtained based on current blockage and dwell time of individual peptide. Data from the clear mapping of small proteins after protease digestion suggests the potential of using T7 motor channel for proteomics including protein sequencing.

Protein Interactions in the T7 DNA Replisome Facilitate DNA Damage Bypass.

The DNA replisome inevitably encounters DNA damage during DNA replication. The T7 DNA replisome contains a DNA polymerase (gp5), the processivity factor thioredoxin (trx), a helicase-primase (gp4), and a ssDNA-binding protein (gp2.5). T7 protein interactions mediate this DNA replication. However, whether the protein interactions could promote DNA damage bypass is still little addressed. In this study, we investigated strand-displacement DNA synthesis past 8-oxoG or O6 -MeG lesions at the synthetic DNA fork by the T7 DNA replisome. DNA damage does not obviously affect the binding affinities between helicase, polymerase, and DNA fork. Relative to unmodified G, both 8-oxoG and O6 -MeG-as well as GC-rich template sequence clusters-inhibit strand-displacement DNA synthesis and produce partial extension products. Relative to the gp4 ΔC-tail, gp4 promotes DNA damage bypass. The presence of gp2.5 also promotes it. Thus, the interactions of polymerase with helicase and ssDNA-binding protein facilitate DNA damage bypass. Accessory proteins in other complicated DNA replisomes also facilitate bypassing DNA damage in similar manner. This work provides new mechanistic information relating to DNA damage bypass by the DNA replisome.

Motor-like DNA motion due to an ATP-hydrolyzing protein under nanoconfinement

We report that long double-stranded DNA confined to quasi-1D nanochannels undergoes superdiffusive motion under the action of the enzyme T4 DNA ligase in the presence of necessary co-factors. Inside the confined environment of the nanochannel, double-stranded DNA molecules stretch out due to self-avoiding interactions. In absence of a catalytically active enzyme, we see classical diffusion of the center of mass. However, cooperative interactions of proteins with the DNA can lead to directed motion of DNA molecules inside the nanochannel. Here we show directed motion in this configuration for three different proteins (T4 DNA ligase, MutS, E. coli DNA ligase) in the presence of their energetic co-factors (ATP, NAD+).

Abstract LB-195: Identifying cooperative effects of tumor suppressor gene mutations in lung adenocarcinoma using paired CRISPR-Cas9

Abstract Cancer is a heterogeneous disease that arises from the accumulation of genetic mutations that lead to a loss of tumor suppressor genes and activation of oncogenes. Mutational inactivation of genes that regulate epigenetic mechanisms, such as post translational modifications to DNA and histones, also contribute to cancer progression but the mechanisms are poorly understood. Trimethylation on histone 3 lysine 36 (H3K36me3) is encoded by the histone lysine methyltransferase (SETD2). SETD2 is recurrently inactivated by missense and frameshift mutations in multiple tumor types. Previously, we identified that Setd2 loss has potent tumor promoting activities in a mouse model of oncogenic Kras-induced lung adenocarcinoma. However, whether Setd2 loss has cooperating effects with other tumor suppressor gene mutations remains unstudied. To simultaneously inactivate distinct tumor suppressor genes, we use a lentiviral-based CRISPR/Cas gene editing approach to express a combination of specific gRNA-pairs along with Cas9 and Cre recombinase. Inhalation of these lentiviral particles leads activation of an oncogenic KrasLSL-G12D allele and simultaneously inactivation two gRNA-targeted genes. We hypothesize that SETD2 will collaborate with other tumor suppressor gene mutations in lung adenocarcinoma. To clone lentivirus vectors that have two different gRNA we use oligonucleotides encoding gRNAs targeting Setd2 and either Lkb1, Apc, or Rb1 to PCR amplify the 3' region of the murine U6 (mU6) promoter and the 5' region of the gRNA scaffold. Overlapping sequences in the 148-bp PCR amplicon, facilitate recombination with a 415-bp donor fragment derived from BbsI-digested pDonor plasmid using the Gibson cloning method. The newly circularized fragment is then re-linearized via BbsI digestion and cloned into LentiCRISPRv2Cre vector through the Golden Gate method using BsmBI type IIs restriction endonuclease and T4 DNA ligase. Our data demonstrate the development and presence of dual gRNA nucleotides through NotI/EcoRI restriction enzymes digestion and DNA Sequencing. Moreover, to study the cooperative effects of these mutations in mice, we created viruses and corroborated through Flow cytometry and Fluorescence microscopy. In conclusion, we generate lentiviral particles expressing pairs of gRNAs targeting distinct tumor suppressor genes, to identify cooperative effects of their mutation in lung adenocarcinoma models. Citation Format: Mabel G. Perez-Oquendo, David M. Feldser, David Walter. Identifying cooperative effects of tumor suppressor gene mutations in lung adenocarcinoma using paired CRISPR-Cas9 [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr LB-195.

Homologous alignment cloning: a rapid, flexible and highly efficient general molecular cloning method.

Homologous alignment cloning (HAC) is a rapid method of molecular cloning that facilitates low-cost, highly efficient cloning of polymerase chain reaction products into any plasmid vector in approximately 2 min. HAC facilitates insert integration due to a sequence alignment strategy, by way of short, vector-specific homology tails appended to insert during amplification. Simultaneous exposure of single-stranded fragment ends, utilising the 3′→5′ exonuclease activity of T4 DNA polymerase, creates overlapping homologous DNA on each molecule. The exonuclease activity of T4 polymerase is quenched simply by the addition of EDTA and a simple annealing step ensures high yield and high fidelity vector formation. The resultant recombinant plasmids are transformed into standard E. coli cloning strains and screened via established methods as necessary. HAC exploits reagents commonly found in molecular research laboratories and achieves efficiencies that exceed conventional cloning methods, including another ligation-independent method we tested. HAC is also suitable for combining multiple fragments in a single reaction, thus extending its flexibility.

The Bacteriophage T4 MotB Protein, a DNA-Binding Protein, Improves Phage Fitness

The lytic bacteriophage T4 employs multiple phage-encoded early proteins to takeover the Escherichia coli host. However, the functions of many of these proteins are not known. In this study, we have characterized the T4 early gene motB, located in a dispensable region of the T4 genome. We show that heterologous production of MotB is highly toxic to E. coli, resulting in cell death or growth arrest depending on the strain and that the presence of motB increases T4 burst size 2-fold. Previous work suggested that motB affects middle gene expression, but our transcriptome analyses of T4 motBam vs. T4 wt infections reveal that only a few late genes are mildly impaired at 5 min post-infection, and expression of early and middle genes is unaffected. We find that MotB is a DNA-binding protein that binds both unmodified host and T4 modified [(glucosylated, hydroxymethylated-5 cytosine, (GHme-C)] DNA with no detectable sequence specificity. Interestingly, MotB copurifies with the host histone-like proteins, H-NS and StpA, either directly or through cobinding to DNA. We show that H-NS also binds modified T4 DNA and speculate that MotB may alter how H-NS interacts with T4 DNA, host DNA, or both, thereby improving the growth of the phage.

Direct Pathway Cloning Combined with Sequence- and Ligation-Independent Cloning for Fast Biosynthetic Gene Cluster Refactoring and Heterologous Expression

The need for new pharmacological lead structures, especially against drug resistances, has led to a surge in natural product research and discovery. New biosynthetic gene cluster capturing methods to efficiently clone and heterologously express natural product pathways have thus been developed. Direct pathway cloning (DiPaC) is an emerging synthetic biology strategy that utilizes long-amplification PCR and HiFi DNA assembly for the capture and expression of natural product biosynthetic gene clusters. Here, we have further streamlined DiPaC by reducing cloning time and reagent costs by utilizing T4 DNA polymerase (sequence- and ligation-independent cloning, SLIC) for gene cluster capture. As a proof of principle, the majority of the cyanobacterial hapalosin gene cluster was cloned as a single piece (23 kb PCR product) using this approach, and predicted transcriptional terminators were removed by simultaneous pathway refactoring, leading to successful heterologous expression. The complementation of DiPaC with SLIC depicts a time and cost-efficient method for simple capture and expression of new natural product pathways.

Electrochemical monitoring of single nucleotide polymorphisms of rice varieties related to blast resistance based on PCR product and T4 DNA polymerase

Rice blast is one of the most destructive disease, which is estimated to cause 10–30% loss of global rice output annually. Single nucleotide change in bsr-d1 promoter (SNP-33 G) is conferred broad-spectrum resistance to rice blast. In this paper, we reported the construction of a relatively simple, inexpensive and ultrasensitive electrochemical DNA biosensor to detect SNP-33 G for the first time. PCR product with a 19-nt-long sticky end was generated in the presence of T4 DNA polymerase and dGTP, which was used as a powerful signal amplifying tool in the assay. The biosensor was immersed in RuHex buffer as a redox, and a high current signal could be observed due to the electrostatically bound between RuHex and the phosphate backbone of PCR product. Under optimal conditions, the electrochemical DNA biosensor exhibited satisfied performance for the determination of mutant-type of bsr-d1 promoter with a linearity ranging from 0.1 fM to 0.1 pM and a relatively low detection limit of 0.1 fM. The proposed biosensor showed excellent selectivity of SNP-33 G compared to that of wild type bsr-d1 promoter at a ratio of 1:10,000. The results provided a novel method for potential applications in variety screen and breeding for rice blast resistance.