Targeting in linear DNA duplexes with two complementary probe strands for hybrid stability

Field Demonstration of a Multiplexed Point-of-Care Diagnostic Platform for Plant Pathogens

Effective disease management strategies to prevent catastrophic crop losses require rapid, sensitive, and multiplexed detection methods for timely decision making. To address this need, a rapid, highly specific and sensitive point-of-care method for multiplex detection of plant pathogens was developed by taking advantage of surface-enhanced Raman scattering (SERS) labeled nanotags and recombinase polymerase amplification (RPA), which is a rapid isothermal amplification method with high specificity. In this study, three agriculturally important plant pathogens (Botrytis cinerea, Pseudomonas syringae, and Fusarium oxysporum) were used to demonstrate potential translation into the field. The RPA-SERS method was faster, more sensitive than polymerase chain reaction, and could detect as little as 2 copies of B. cinerea DNA. Furthermore, multiplex detection of the three pathogens was demonstrated for complex systems such as the Arabidopsis thaliana plant and commercial tomato crops. To demonstrate the potential for on-site field applications, a rapid single-tube RPA/SERS assay was further developed and successfully performed for a specific target outside of a laboratory setting.

Evolutionary engineering by genome shuffling

An upsurge in the bioeconomy drives the need for engineering microorganisms with increasingly complex phenotypes. Gains in productivity of industrial microbes depend on the development of improved strains. Classical strain improvement programmes for the generation, screening and isolation of such mutant strains have existed for several decades. An alternative to traditional strain improvement methods, genome shuffling, allows the directed evolution of whole organisms via recursive recombination at the genome level. This review deals chiefly with the technical aspects of genome shuffling. It first presents the diversity of organisms and phenotypes typically evolved using this technology and then reviews available sources of genetic diversity and recombination methodologies. Analysis of the literature reveals that genome shuffling has so far been restricted to microorganisms, both prokaryotes and eukaryotes, with an overepresentation of antibiotics- and biofuel-producing microbes. Mutagenesis is the main source of genetic diversity, with few studies adopting alternative strategies. Recombination is usually done by protoplast fusion or sexual recombination, again with few exceptions. For both diversity and recombination, prospective methods that have not yet been used are also presented. Finally, the potential of genome shuffling for gaining insight into the genetic basis of complex phenotypes is also discussed.

Multiplex target capture with double-stranded DNA probes

Target enrichment technologies utilize single-stranded oligonucleotide probes to capture candidate genomic regions from a DNA sample before sequencing. We describe target capture using double-stranded probes, which consist of single-stranded, complementary long padlock probes (cLPPs), each selectively capturing one strand of a genomic target through circularization. Using two probes per target increases sensitivity for variant detection and cLPPs are easily produced by PCR at low cost. Additionally, we introduce an approach for generating capture libraries with uniformly randomized template orientations. This facilitates bidirectional sequencing of both the sense and antisense template strands during one paired-end read, which maximizes target coverage.

Rad52 promotes second-end DNA capture in double-stranded break repair to form complement-stabilized joint molecules

Saccharomyces cerevisiae Rad52 performs multiple functions during the recombinational repair of double-stranded DNA (dsDNA) breaks (DSBs). It mediates assembly of Rad51 onto single-stranded DNA (ssDNA) that is complexed with replication protein A (RPA); the resulting nucleoprotein filament pairs with homologous dsDNA to form joint molecules. Rad52 also catalyzes the annealing of complementary strands of ssDNA, even when they are complexed with RPA. Both Rad51 and Rad52 can be envisioned to promote "second-end capture," a step that pairs the ssDNA generated by processing of the second end of a DSB to the joint molecule formed by invasion of the target dsDNA by the first processed end. Here, we show that Rad52 promotes annealing of complementary ssDNA that is complexed with RPA to the displaced strand of a joint molecule, to form a complement-stabilized joint molecule. RecO, a prokaryotic homolog of Rad52, cannot form complement-stabilized joint molecules with RPA-ssDNA complexes, nor can Rad52 promote second-end capture when the ssDNA is bound with either human RPA or the prokaryotic ssDNA-binding protein, SSB, indicating a species-specific process. We conclude that Rad52 participates in second-end capture by annealing a resected DNA break, complexed with RPA, to the joint molecule product of single-end invasion event. These studies support a role for Rad52-promoted annealing in the formation of Holliday junctions in DSB repair.

Double displacement loops (double d-loops) are templates for oligonucleotide-directed mutagenesis and gene repair

Appreciable levels of gene repair result from the hybridization of two oligonucleotides at a specific site in a mutated gene and subsequent correction by a form of oligonucleotide-directed mutagenesis known as gene repair. The incorporation of the two oligonucleotides into superhelical plasmid DNA leads to the formation of double d-loops, structures shown to be templates for the repair of both frameshift and point mutations. Structural limitations placed on the template indicate that correction is influenced significantly by the positioning of the second oligonucleotide, known as the annealing oligonucleotide. Complexes constructed with two oligonucleotides directly opposite each other exhibit the highest levels of gene repair activity. Blocking the 3'-end of either oligonucleotide with an amino C7 group does not diminish the performance of the double d-loop as a template for correction of the point mutation, suggesting that primer extension does not play a pivotal role in the mechanism of gene repair.

Fluorescent detection and isolation of DNA variants using stabilized RecA-coated oligonucleotides

Several genome resequencing strategies have been developed to detect genetic variation in populations and correlate diversity with phenotypic consequences. Commonly used methods of detecting single nucleotide polymorphisms (SNPs) use PCR amplification and indirect analysis, which can create template biases and enable user contamination. Here we present a novel assay to detect and isolate DNA variants using stabile nanostructures formed directly on duplex DNA. The assay incorporates the well-established RecA-catalyzed strand invasion process with a novel stabilizing hybridization step. First, short RecA-coated oligonucleotide filaments invade duplex DNA to form a synaptic intermediate or "D-loop." Sequentially, chemically modified oligonucleotide probes anneal to the displaced DNA strand of the complex to form a stable "double D-loop." These joint molecules resist dissociation when both oligonucleotides are completely complementary to the target duplex; however, if the probes are mismatched, the complex is inherently instable and rapidly dissociates. SNPs are identified by detecting the fluorophore assimilated into stable complexes produced by homologous probes compared to unstable differentially labeled mismatched probes. Furthermore, this strategy can be used to isolate specific allelic variants by affinity purification from complex populations. Stabilized double D-Loop intermediates accordingly offer the promise of haplotyping and pharmacogenomic analysis directly in double-stranded DNA samples.

Increased efficiency of transgenic livestock production

Production of transgenic livestock by pronuclear microinjection of DNA into fertilized zygotes suffers from the compounded inefficiencies of low embryo survival and low integration frequencies of the injected DNA into the genome. These inefficiencies are one of the major obstacles to the large-scale use of pronuclear microinjection techniques in livestock. We investigated exploiting the properties of recombinase proteins that allow them to bind DNA to generate transgenic animals via pronuclear microinjection. In theory, the use of recombinase proteins has the potential to generate transgenic animals with targeted changes, but in practice we found that the use of RecA recombinase-coated DNA increases the efficiency of transgenic livestock production. The use of RecA protein resulted in a significant increase in both embryo survival rates and transgene integration frequencies. Embryo survival rates were doubled in goats, and transgene integration was 11-fold higher in goats and three-fold higher in pigs when RecA protein-coated DNA was used compared with conventional DNA constructs without RecA protein coating. However, a large number of the transgenic founders generated with RecA protein-coated DNA were mosaic. The RecA protein coating of DNA is straightforward and can be applied to any species and any existing microinjection apparatus. These findings represent significant improvements on standard pronuclear microinjection methods by enabling the more efficient production of transgenic livestock.

DNA pairing is an important step in the process of targeted nucleotide exchange

Modified single-stranded DNA oligonucleotides can direct the repair of genetic mutations in yeast, plant and mammalian cells. The mechanism by which these molecules exert their effect is being elucidated, but the first phase is likely to involve the homologous alignment of the single strand with its complementary sequence in the target gene. In this study, we establish the importance of such DNA pairing in facilitating the gene repair event. Oligonucleotide-directed repair occurs at a low frequency in an Escherichia coli strain (DH10B) lacking the RECA DNA pairing function. Repair activity can be rescued by using purified RecA protein to catalyze the assimilation of oligonucleotide vectors into a plasmid containing a mutant kanamycin resistance gene in vitro. Electroporation of the preformed complex into DH10B cells results in high levels of gene repair activity, evidenced by the appearance of kanamycin-resistant colonies. Gene repair is dependent on the formation of a double-displacement loop (double-D-loop), a recombination intermediate containing two single-stranded oligonucleotides hybridized to opposite strands of the plasmid at the site of the point mutation. The heightened level of stability of the double-D-loop enables it to serve as an active template for the DNA repair events. The data establish DNA pairing and the formation of the double-D-loop as important first steps in the process of gene repair.

The use of recombinase proteins to generate transgenic large animals

The endogenous properties of recombinase proteins allow them to associate with and bind DNA to catalyze homologous recombination. These endogenous properties of cellular recombination enzymes may be useful to the field of transgenesis. The production of transgenic animals, in particular livestock, is an inefficient process by both conventional pronuclear microinjection techniques and nuclear transfer. Furthermore, the use of pronuclear microinjection is currently limited to the random addition of genes and does not allow for the replacement of an endogenous gene with a more desired one. The functions of cellular recombination enzymes have been exploited to develop a technique that is compatible with pronuclear microinjection and may make the process of generating transgenic livestock more efficient while also enabling the targeting of homologous chromosomal genes. In our hands, transgenic animals generated by the pronuclear microinjection of various recombinase protein-coated DNA fragments led to a higher than expected birth rate as well as transgene integration frequency. Most founder animals generated were likely mosaic, indicating that integration occurred after cell division. The presence of multiple related genes makes detection of any recombination event difficult. Overall, this technique is a straightforward, rapid, and efficient procedure that can be applied to any segment of DNA and any microinjection apparatus, and is less labor intensive than nuclear transfer.

Duration time of a one-dimensional random walk as a function of the energies of the intermediate states: application for dissociation and relaxation processes in DNA hybrids

Kinetic parameters of macromolecular systems are important for their function in vitro and in vivo. These parameters describe how fast the system dissociates (the characteristic dissociation time), and how fast the system reaches equilibrium (characteristic relaxation time). For many macromolecular systems, the transitions within the systems are described as a random walk through a number of states with various free energies. The rate of transition between two given states within the system is characterized by the average time which passes between starting the movement from one state, and reaching the other state. This time is referred to as the mean first-passage time between two given states. The characteristic dissociation and relaxation times of the system depend on the first-passages times between the states within the system. Here, for a one-dimensional random walk we derived an equation, which connects the mean first-passage time between two states with the free energies of the states within the system. We also derived the general equation, which is not restricted to one-dimensional systems, connecting the relaxation time of the system with the first-passage times between states. The application of these equations to DNA branch migration, DNA structural transitions and other processes is discussed.

Sequence-specific ligation of DNA using RecA protein

A method is described that allows the sequence-specific ligation of DNA. The method is based on the ability of RecA protein from Escherichia coli to selectively pair oligonucleotides to their homologous sequences at the ends of fragments of duplex DNA. These three-stranded complexes were protected from the action of DNA polymerase. When treated with DNA polymerase, unprotected duplex fragments were converted to fragments with blunt ends, whereas protected fragments retained their cohesive ends. By using conditions that greatly favored ligation of cohesive ends, a second DNA fragment could be selectively ligated to a previously protected fragment of DNA. When this second DNA was a vector, selected fragments were preferentially cloned. The method had sufficient power to be used for the isolation of single-copy genes directly from yeast or human genomic DNA, and potentially could allow the isolation of much longer fragments with greater fidelity than obtainable by using PCR.

G/C-modified oligodeoxynucleotides with selective complementarity: synthesis and hybridization properties

Modified oligodeoxyribonucleotides (ODNs) that have unique hybridization properties were designed and synthesized for the first time. These ODNs, called selective binding complementary ODNs (SBC ODNs), are unable to form stable hybrids with each other, yet are able to form stable, sequence specific hybrids with complementary unmodified strands of nucleic acid. To make SBC ODNs, deoxyguanosine (dG) and deoxycytidine (dC) were substituted with deoxyinosine (dI) and 3-(2'-deoxy-beta-D-ribofuranosyl)pyrrolo-[2,3-d]-pyrimidine-2-(3H)-one (dP), respectively. The hybridization properties of several otherwise identical complementary ODNs containing one or both of these nucleoside analogs were studied by both UV monitored thermal denaturation and non-denaturing PAGE. The data showed that while dI and dP did form base pairs with dC and dG, respectively, dI did not form a stable base pair with dP. A self-complementary ODN uniformly substituted with dI and dP acquired single-stranded character and was able to strand invade the end of a duplex DNA better than an unsubstituted ODN. This observation implies that SBC ODNs should effectively hybridize to hairpins present in single-stranded DNA or RNA.

Biochemistry of homologous recombination in Escherichia coli

Homologous recombination is a fundamental biological process. Biochemical understanding of this process is most advanced for Escherichia coli. At least 25 gene products are involved in promoting genetic exchange. At present, this includes the RecA, RecBCD (exonuclease V), RecE (exonuclease VIII), RecF, RecG, RecJ, RecN, RecOR, RecQ, RecT, RuvAB, RuvC, SbcCD, and SSB proteins, as well as DNA polymerase I, DNA gyrase, DNA topoisomerase I, DNA ligase, and DNA helicases. The activities displayed by these enzymes include homologous DNA pairing and strand exchange, helicase, branch migration, Holliday junction binding and cleavage, nuclease, ATPase, topoisomerase, DNA binding, ATP binding, polymerase, and ligase, and, collectively, they define biochemical events that are essential for efficient recombination. In addition to these needed proteins, a cis-acting recombination hot spot known as Chi (chi: 5'-GCTGGTGG-3') plays a crucial regulatory function. The biochemical steps that comprise homologous recombination can be formally divided into four parts: (i) processing of DNA molecules into suitable recombination substrates, (ii) homologous pairing of the DNA partners and the exchange of DNA strands, (iii) extension of the nascent DNA heteroduplex; and (iv) resolution of the resulting crossover structure. This review focuses on the biochemical mechanisms underlying these steps, with particular emphases on the activities of the proteins involved and on the integration of these activities into likely biochemical pathways for recombination.