Single-molecule polymerase chain reaction reduces bias: application to DNA methylation analysis by bisulfite sequencing

The treatment of DNA with bisulfite, which converts C to U but leaves 5-methyl-C unchanged, forms the basis of many analytical techniques for DNA methylation analysis. Many techniques exist for measuring the methylation state of a single CpG but, for analysis of an entire region, cloning and sequencing remains the gold standard. However, biases in polymerase chain reaction (PCR) amplification and in cloning can skew the results. We hypothesized that single-molecule PCR (smPCR) amplification would eliminate the PCR amplification bias because competition between templates that amplify at different efficiencies no longer exists. The amplified products can be sequenced directly, thus eliminating cloning bias. We demonstrated this accurate and unbiased approach by analyzing a sample that was expected to contain a 50:50 ratio of methylated to unmethylated molecules: a region of the X-linked FMR1 gene from a human female cell line. We compared traditional cloning and sequencing to smPCR and sequencing. Sequencing smPCR products gave an expected methylated to unmethylated ratio of 48:52, whereas conventional cloning and sequencing gave a biased ratio of 72:28. Our results show that smPCR sequencing can eliminate both PCR and cloning bias and represents an attractive approach to bisulfite sequencing.     

Evaluation of the efficiency and utility of recombinant enzyme-free seamless DNA cloning methods

Simple and low-cost recombinant enzyme-free seamless DNA cloning methods have recently become available. In vivo Escherichia coli cloning (iVEC) can directly transform a mixture of insert and vector DNA fragments into E. coli, which are ligated by endogenous homologous recombination activity in the cells. Seamless ligation cloning extract (SLiCE) cloning uses the endogenous recombination activity of E. coli cellular extracts in vitro to ligate insert and vector DNA fragments. An evaluation of the efficiency and utility of these methods is important in deciding the adoption of a seamless cloning method as a useful tool. In this study, both seamless cloning methods incorporated inserting DNA fragments into linearized DNA vectors through short (15–39 bp) end homology regions. However, colony formation was 30–60-fold higher with SLiCE cloning in end homology regions between 15 and 29 bp than with the iVEC method using DH5α competent cells. E. coli AQ3625 strains, which harbor a sbcA gene mutation that activates the RecE homologous recombination pathway, can be used to efficiently ligate insert and vector DNA fragments with short-end homology regions in vivo. Using AQ3625 competent cells in the iVEC method improved the rate of colony formation, but the efficiency and accuracy of SLiCE cloning were still higher. In addition, the efficiency of seamless cloning methods depends on the intrinsic competency of E. coli cells. The competency of chemically competent AQ3625 cells was lower than that of competent DH5α cells, in all cases of chemically competent cell preparations using the three different methods. Moreover, SLiCE cloning permits the use of both homemade and commercially available competent cells because it can use general E. coli recA^? strains such as DH5α as host cells for transformation. Therefore, between the two methods, SLiCE cloning provides both higher efficiency and better utility than the iVEC method for seamless DNA plasmid engineering.     

Classifying DNA assembly protocols for devising cellular architectures

DNA assembly is one of the most fundamental techniques in synthetic biology. Efficient methods can turn traditional DNA cloning into time-saving and higher efficiency practice, which is a foundation to accomplish the dreams of synthetic biologists for devising cellular architectures, reprogramming cellular behaviors, or creating synthetic cells. In this review, typical strategies of DNA assembly are discussed with special emphasis on the assembly of long and multiple DNA fragments into intact plasmids or assembled compositions. Constructively, all reported strategies were categorized into in vivo and in vitro types, and protocols are presented in a functional and practice-oriented way in order to portray the general nature of DNA assembly applications. Significantly, a five-step blueprint is proposed for devising cell architectures that produce valuable chemicals.     

T4 DNA polymerase: Rates and processivity on single-stranded DNA templates

Three different methods have been used to determine the rate at which an individual bacteriophage T4 DNA polymerase molecule moves when synthesizing DNA on a single-stranded DNA template chain. These methods agree in suggesting an in vitro rate for this enzyme of about 250 nucleotides per second at 37 °C. This rate is close to the rate at which bacteriophage T4 replication forks move in vivo (about 500 nucleotides per second). Comparison with the overall amount of DNA synthesis seen in in vitro reactions reveals that only a small fraction of the T4 DNA polymerase molecules present are synthesizing DNA at any one time. This is explicable in terms of the limited processivity of the enzyme in these reactions, along with its capacity for non-productive DNA binding to the DNA template molecules.     

Validation of an entirely in vitro approach for rapid prototyping of DNA regulatory elements for synthetic biology

A bottleneck in our capacity to rationally and predictably engineer biological systems is the limited number of well-characterized genetic elements from which to build. Current characterization methods are tied to measurements in living systems, the transformation and culturing of which are inherently time-consuming. To address this, we have validated a completely in vitro approach for the characterization of DNA regulatory elements using Escherichia coli extract cell-free systems. Importantly, we demonstrate that characterization in cell-free systems correlates and is reflective of performance in vivo for the most frequently used DNA regulatory elements. Moreover, we devise a rapid and completely in vitro method to generate DNA templates for cell-free systems, bypassing the need for DNA template generation and amplification from living cells. This in vitro approach is significantly quicker than current characterization methods and is amenable to high-throughput techniques, providing a valuable tool for rapidly prototyping libraries of DNA regulatory elements for synthetic biology.     

High Efficiency Ex Vivo Cloning of Antigen-Specific Human Effector T Cells

While cloned T cells are valuable tools for the exploration of immune responses against viruses and tumours, current cloning methods do not allow inferences to be made about the function and phenotype of a clone''s in vivo precursor, nor can precise cloning efficiencies be calculated. Additionally, there is currently no general method for cloning antigen-specific effector T cells directly from peripheral blood mononuclear cells, without the need for prior expansion in vitro. Here we describe an efficient method for cloning effector T cells ex vivo. Functional T cells are detected using optimised interferon gamma capture following stimulation with viral or tumour cell-derived antigen. In combination with multiple phenotypic markers, single effector T cells are sorted using a flow cytometer directly into multi-well plates, and cloned using standard, non antigen-specific expansion methods. We provide examples of this novel technology to generate antigen-reactive clones from healthy donors using Epstein-Barr virus and cytomegalovirus as representative viral antigen sources, and from two melanoma patients using autologous melanoma cells. Cloning efficiency, clonality, and retention/loss of function are described. Ex vivo effector cell cloning provides a rapid and effective method of deriving antigen-specific T cells clones with traceable in vivo precursor function and phenotype.     

Heme Mediates Cytotoxicity from Artemisinin and Serves as a General Anti-Proliferation Target

Heme (Fe2+ protoporphyrin IX) is an essential molecule that has been implicated the potent antimalarial action of artemisinin and its derivatives, although the source and nature of the heme remain controversial. Artemisinins also exhibit selective cytotoxicity against cancer cells in vitro and in vivo. We demonstrate that intracellular heme is the physiologically relevant mediator of the cytotoxic effects of artemisinins. Increasing intracellular heme synthesis through the addition of aminolevulinic acid, protoporphyrin IX, or transferrin-bound iron increased the cytotoxicity of dihydroartemisinin, while decreasing heme synthesis through the addition of succinyl acetone decreased its cytotoxic activity. A simple and robust high throughput assay was developed to screen chemical compounds that were capable of interacting with heme. A natural products library was screened which identified the compound coralyne, in addition to artemisinin, as a heme interacting compound with heme synthesis dependent cytotoxic activity. These results indicate that cellular heme may serve a general target for the development of both anti-parasitic and anti-cancer therapeutics.     

DNA Replication by a membrane-DNA complex from rat liver mitochondria

The results presented here indicate that mitochondrial DNA (mtDNA) synthesis occurs on the inner mitochondrial membrane and that a membrane-DNA complex, enriched in newly synthesized DNA, can be isolated. The complex is able to synthesize DNA in vitro. Enrichment studies demonstrated that mtDNA synthesis occurs on an intact membrane-DNA complex in vitro and that pulse-labeled mtDNA could be chased from the membrane-DNA complex to the top fraction of the discontinuous sucrose gradient. The membrane-DNA complex was also shown to carry out replicative synthesis of mtDNA in vitro. Replication was shown to be asynchronous with heavy-strand synthesis preceding light-strand synthesis. The progression of mtDNA replication by the membrane-DNA complex was shown to be from small fragments (<13 S) to larger fragments (14–24 S) liberated from closed circular molecules, to a heat-stable 27 S molecule, and finally to a 38 S heat-stable molecule. The time estimated to progress from small fragments to the 38 S molecule is 120 min.     

Synthesis of internal re-initiation fragments of beta-galactosidase in vitro and in vivo.

Internal re-initiation polypeptides which are products of the lacZ gene of Escherichia coli have been synthesized in a DNA-directed cell-free protein synthesis system. Some of the properties of these protein fragments have been characterized. The de novo synthesized re-initiation proteins, unlike both in vitro synthesized wild-type β-galactosidase and nonsense termination fragments, are insoluble when synthesized at 37 °C, but soluble if synthesis takes place at 25 °C. The same re-initiation proteins which are made in vivo have been detected in vitro. Unlike their in vivo counterparts, which are degraded rapidly, the in vitro synthesized restart proteins are completely stable for at least one hour following their synthesis. Both in vivo and in vitro, the re-initiation proteins are not synthesized from DNA containing a wild-type Z gene, but require a specific nonsense mutation in order to be expressed. Furthermore, the location of the mutation within the Z gene is very important in determining whether or not re-initiation will occur at a given site.Several nonsense mutations which do not result in the synthesis of detectable amounts of restart protein in vivo produce specific re-initiation polypeptides in vitro. These restart proteins display many of the same properties as do those which are made both in vivo and in vitro: they are not made from wild-type DNA, and they are only made from DNA containing a specific nonsense mutation. One of these mutations is 118, which is an extreme polar mutation in vivo. Another is 545, which synthesizes a restart protein in vivo if, and only if, it is coupled with a secondary mutation, π(1). π(1) thus appears to be necessary for the synthesis of a particular re-initiation protein in vivo but unnecessary for the synthesis of the same protein in vitro. The efficiencies of re-initiation vary at the different sites, but in all cases are less than the initiation frequency at the start of the gene. The experiments thus show that when complicating factors, such as polarity and protein degradation, are eliminated, translational re-initiation can be detected at many sites in the lacZ gene.     

In vitro HeLa cell DNA synthesis similarity to in vivo replication

An in vitro DNA synthesizing system, consisting of a HeLa cell lysate which incorporated dNTPs into an acid-insoluble, DNase-labile product, was optimized for incorporation per nucleus. Synthesis depended on the presence of all four dNTPs and was linear for about 15 minutes, then slowed and finally stopped after one to two hours at 37 °C. The DNA synthesized in vitro was found to be preferentially attached by covalent linkage to sites which had just been replicated in vivo. DNA fiber autoradiography of DNA labeled in vitro suggests that synthesis occurs by the replicon mechanism proposed for in vivo replication, but at a fork movement rate 50 to 60% of that in vivo.When analyzed on alkaline sucrose gradients, dNTPs appeared to be incorporated by a semidiscontinuous mechanism, with label after brief pulses (10 to 20 s) distributed about equally between a peak of Okazaki fragments and a very heterogeneous distribution of longer DNA strands. Okazaki fragments, which can be initiated in vitro, sedimented in a broad peak averaging 180 nucleotides in length.     

Cloning Should Be Simple: Escherichia coli DH5α-Mediated Assembly of Multiple DNA Fragments with Short End Homologies

Numerous DNA assembly technologies exist for generating plasmids for biological studies. Many procedures require complex in vitro or in vivo assembly reactions followed by plasmid propagation in recombination-impaired Escherichia coli strains such as DH5α, which are optimal for stable amplification of the DNA materials. Here we show that despite its utility as a cloning strain, DH5α retains sufficient recombinase activity to assemble up to six double-stranded DNA fragments ranging in size from 150 bp to at least 7 kb into plasmids in vivo. This process also requires surprisingly small amounts of DNA, potentially obviating the need for upstream assembly processes associated with most common applications of DNA assembly. We demonstrate the application of this process in cloning of various DNA fragments including synthetic genes, preparation of knockout constructs, and incorporation of guide RNA sequences in constructs for clustered regularly interspaced short palindromic repeats (CRISPR) genome editing. This consolidated process for assembly and amplification in a widely available strain of E. coli may enable productivity gain across disciplines involving recombinant DNA work.     

In vitro replicative arrest in dnaAts mutants.

Toluene-treated Escherichia coli, conditionally defective in initiation of DNA replication, have been studied. Toluenized mutants of the dnaA_ts, class rapidly stop DNA synthesis at the restrictive temperature. This is in contrast to the slow arrest of replicative synthesis noted in vivo in these strains. The in vitro cessation of replicative DNA synthesis can be prevented by the presence of the detergent Triton X-100. Our results suggest a role in elongation of DNA by the dnaA gene product during replicative synthesis in vitro.     

EVIDENCE FOR AN ESSENTIALLY CONSTANT DURATION OF DNA SYNTHESIS IN RENEWING EPITHELIA OF THE ADULT MOUSE

Tritiated thymidine autoradiography has been applied to several renewing epithelial tissues of the adult mouse in order to determine (a) the average time required for DNA synthesis; and (b) the temporal relationship of the synthesis period to the progenitor cycles of these populations. The average duration of DNA synthesis has been computed from curves describing the rates of appearance and disappearance of labeled metaphase figures in epithelia of colon, ileum, duodenum, esophagus, and oral cavity, in both normal and colchicine-treated animals. In general, application of colchicine does not significantly influence the derived values for DNA synthesis duration. The DNA synthetic time is remarkably similar in the tissues examined, despite wide differences in the times required for completion of the progenitor cycle (and for tissue renewal). Synthesis of DNA in these epithelial cells of the mouse requires approximately 7 hours. Agreement between this value and those derived by other investigators for mammalian cells in vivo and in vitro indicates that DNA synthetic time may be a temporal constant, of considerable potential utility to studies of cell proliferation. The advantages and shortcomings of this experimental approach to problems of cell population kinetics in vivo are discussed.     

One-step zero-background IgG reformatting of phage-displayed antibody fragments enabling rapid and high-throughput lead identification

We describe a novel cloning method, referred to as insert-tagged (InTag) positive selection, for the rapid one-step reformatting of phage-displayed antibody fragments to full-length immunoglobulin Gs (IgGs). InTag positive selection enables recombinant clones of interest to be directly selected without cloning background, bypassing the laborious process of plating out cultures and colony screening and enabling the cloning procedure to be automated and performed in a high-throughput format. This removes a significant bottleneck in the functional screening of phage-derived antibody candidates and enables a large number of clones to be directly reformatted into IgG without the intermediate step of Escherichia coli expression and testing of soluble antibody fragments. The use of InTag positive selection with the Dyax Fab-on-phage antibody library is demonstrated, and optimized methods for the small-scale transient expression of IgGs at high levels are described. InTag positive selection cloning has the potential for wide application in high-throughput DNA cloning involving multiple inserts, markedly improving the speed and quality of selections from protein libraries.     

DNA binding and aggregation by carbon nanoparticles

Significant environmental and health risks due to the increasing applications of engineered nanoparticles in medical and industrial activities have been concerned by many communities. The interactions between nanomaterials and genomes have been poorly studied so far. This study examined interactions of DNA with carbon nanoparticles (CNP) using atomic force microscopy (AFM). We experimentally assessed how CNP affect DNA molecule and bacterial growth of Escherichia coli. We found that CNP were bound to the DNA molecules during the DNA replication in vivo. The results revealed that the interaction of DNA with CNP resulted in DNA molecule binding and aggregation both in vivo and in vitro in a dose-dependent manner, and consequently inhabiting the E. coli growth. While this was a preliminary study, our results showed that this nanoparticle may have a significant impact on genomic activities.