Felicie F. Andersen

Assembly and structural analysis of a covalently closed nano-scale DNA cage

The inherent properties of DNA as a stable polymer with unique affinity for partner molecules determined by the specific Watson–Crick base pairing makes it an ideal component in self-assembling structures. This has been exploited for decades in the design of a variety of artificial substrates for investigations of DNA-interacting enzymes. More recently, strategies for synthesis of more complex two-dimensional (2D) and 3D DNA structures have emerged. However, the building of such structures is still in progress and more experiences from different research groups and different fields of expertise are necessary before complex DNA structures can be routinely designed for the use in basal science and/or biotechnology. Here we present the design, construction and structural analysis of a covalently closed and stable 3D DNA structure with the connectivity of an octahedron, as defined by the double-stranded DNA helices that assembles from eight oligonucleotides with a yield of ∼30%. As demonstrated by Small Angle X-ray Scattering and cryo-Transmission Electron Microscopy analyses the eight-stranded DNA structure has a central cavity larger than the apertures in the surrounding DNA lattice and can be described as a nano-scale DNA cage, Hence, in theory it could hold proteins or other bio-molecules to enable their investigation in certain harmful environments or even allow their organization into higher order structures.

Detection of Single Enzymatic Events in Rare or Single Cells Using Microfluidics

In the present study we demonstrate highly sensitive detection of rare, aberrant cells in a population of wild-type human cells by combining a rolling-circle-enhanced enzyme activity single-molecule detection assay with a custom-designed microfluidic device. Besides reliable detection of low concentrations of aberrant cells, the integrated system allowed multiplexed detection of individual enzymatic events at the single cell level. The single cell sensitivity of the presented setup relies on the combination of single-molecule rolling-circle-enhanced enzyme activity detection with the fast reaction kinetics provided by a picoliter droplet reaction volume and subsequent concentration of signals in a customized drop-trap device. This setup allows the fast reliable analyses of enzyme activities in a vast number of single cells, thereby offering a valuable tool for basic research as well as theranostics.

Single-Molecule Detection of Human Topoisomerase I Cleavage−Ligation Activity

In the present study, we demonstrate the conversion of a single human topoisomerase I mediated DNA cleavage-ligation event happening within nanometer dimensions to a micrometer-sized DNA molecule, readily detectable using standard fluorescence microscopy. This conversion is achieved by topoisomerase I mediated closure of a nicked DNA dumbbell structure, followed by rolling circle amplification. The resulting product consists of multiple tandem repeats of the DNA dumbbell and can subsequently be visualized by annealing to fluorescently labeled probes. Since amplification involves no thermal cycling, each fluorescent rolling circle product, which gives rise to an individual signal upon microscopic analysis, will correspond to a single human topoisomerase I mediated cleavage-ligation event. Regarding sensitivity, speed, and ease of performance, the presented activity assay based on single-molecule product detection is superior to current state of the art assays using supercoiled plasmids or radiolabeled oligonucleotides as the substrate for topoisomerase I activity. Moreover, inherent in the experimental design is the easy adaptation to multiplexed and/or high-throughput systems. Human topoisomerase I is the cellular target of clinically important anticancer drugs, and the effect of such drugs corresponds directly to the intracellular topoisomerase I cleavage-ligation activity level. We therefore believe that the presented setup, measuring directly the number of cleavage-ligation events in a given sample, has great diagnostic potential, adding considerably to the possibilities of accurate prognosis before treatment with topoisomerase I directed chemotherapeutics.

Structure of nanoscale truncated octahedral DNA cages: variation of single-stranded linker regions and influence on assembly yields.

The assembly, structure, and stability of DNA nanocages with the shape of truncated octahedra have been studied. The cages are composed of 12 double-stranded B-DNA helices interrupted by single-stranded linkers of thymidines of varying length that constitute the truncated corners of the structure. The structures assemble with a high efficiency in a one-step procedure, compared to previously published structures of similar complexity. The structures of the cages were determined by small-angle X-ray scattering. With increasing linker length, there is a systematic increase of the cage size and decrease of the twist angle of the double helices with respect to the symmetry planes of the cage structure. In the present study, we demonstrate the length of the single-stranded linker regions, which impose a certain degree of flexibility to the structure, to be the important determinant for efficient assembly. The linker length can be decreased to three thymidines without affecting assembly yield or the overall structural characteristics of the DNA cages. A linker length of two thymidines represents a sharp cutoff abolishing cage assembly. This is supported by energy minimization calculations suggesting substantial hydrogen bond deformation in a cage with linkers of two thymidines.

A Novel Secondary DNA Binding Site in Human Topoisomerase I Unravelled by using a 2D DNA Origami Platform

The biologically and clinically important nuclear enzyme human topoisomerase I relaxes both positively and negatively supercoiled DNA and binds consequently DNA with supercoils of positive or negative sign with a strong preference over relaxed DNA. One scheme to explain this preference relies on the existence of a secondary DNA binding site in the enzyme facilitating binding to DNA nodes characteristic for plectonemic DNA. Here we demonstrate the ability of human topoisomerase I to induce formation of DNA synapses at protein containing nodes or filaments using atomic force microscopy imaging. By means of a two-dimensional (2D) DNA origami platform, we monitor the interactions between a single human topoisomerase I covalently bound to one DNA fragment and a second DNA fragment protruding from the DNA origami. This novel single molecule origami-based detection scheme provides direct evidence for the existence of a secondary DNA interaction site in human topoisomerase I and lends further credence to the theory of two distinct DNA interaction sites in human topoisomerase I, possibly facilitating binding to DNA nodes characteristic for plectonemic supercoils.

Multiplexed Detection of Site Specific Recombinase and DNA Topoisomerase Activities at the Single Molecule Level

We previously demonstrated the conversion of a single human topoisomerase I mediated DNA cleavage-ligation event happening within nanometer dimensions to a micrometer-sized DNA molecule, readily detectable using standard fluorescence microscopy. This conversion was achieved by topoisomerase I mediated closure of a nicked DNA circle followed by rolling circle amplification leading to an anchored product that was visualized at the single molecule level by hybridization to fluorescently labeled probes (Stougaard et al. ACS Nano 2009, 3, 223-33). An important inherent property of the presented setup is, at least in theory, the easy adaptability to multiplexed enzyme detection simply by using differently labeled probes for the detection of rolling circle products of different circularized substrates. In the present study we demonstrate the specific detection of three different enzyme activities, human topoisomerase I, and Flp and Cre recombinase in nuclear extracts from human cells one at a time or multiplexed using the rolling circle amplification based single-molecule detection system. Besides serving as a proof-of-principle for the feasibility of the presented assay for multiplexed enzyme detection in crude human cell extracts, the simultaneous detection of Flp and Cre activities in a single sample may find immediate practical use since these enzymes are often used in combination to control mammalian gene expression.

The RNA Splicing Factor ASF/SF2 Inhibits Human Topoisomerase I Mediated DNA Relaxation

Human topoisomerase I interacts with and phosphorylates the SR-family of RNA splicing factors, including ASF/SF2, and has been suggested to play an important role in the regulation of RNA splicing. Here we present evidence to support the theory that the regulation can go the other way around with the SR-proteins controlling topoisomerase I DNA activity. We demonstrate that the splicing factor ASF/SF2 inhibits relaxation by interfering with the DNA cleavage and/or DNA binding steps of human topoisomerase I catalysis. The inhibition of relaxation correlated with the ability of various deletion mutants of the two proteins to interact directly, suggesting that an interaction between the RS-domain of ASF/SF2 and a region between amino acid residues 208-735 on topoisomerase I accounts for the observed effect. Consistently, phosphorylation of the RS-domain with either topoisomerase I or a human cell extract reduced the inhibition of relaxation activity. Taken together with the previously published studies of the topoisomerase I kinase activity, these observations suggest that topoisomerase I activity is shifted from relaxation to kinasing by specific interaction with SR-splicing factors.

Tryptophane-205 of human topoisomerase I is essential for camptothecin inhibition of negative but not positive supercoil removal

Positive supercoils are introduced in cellular DNA in front of and negative supercoils behind tracking polymerases. Since DNA purified from cells is normally under-wound, most studies addressing the relaxation activity of topoisomerase I have utilized negatively supercoiled plasmids. The present report compares the relaxation activity of human topoisomerase I variants on plasmids containing equal numbers of superhelical twists with opposite handedness. We demonstrate that the wild-type enzyme and mutants lacking amino acids 1–206 or 191–206, or having tryptophane-205 replaced with a glycine relax positive supercoils faster than negative supercoils under both processive and distributive conditions. In contrast to wild-type topoisomerase I, which exhibited camptothecin sensitivity during relaxation of both negative and positive supercoils, the investigated N-terminally mutated variants were sensitive to camptothecin only during removal of positive supercoils. These data suggest different mechanisms of action during removal of supercoils of opposite handedness and are consistent with a recently published simulation study [Sari and Andricioaei (2005) Nucleic Acids Res., 33, 6621–6634] suggesting flexibility in distinct parts of the enzyme during clockwise or counterclockwise strand rotation.

Deciphering the structural properties that confer stability to a DNA nanocage.

A DNA nanocage has been recently characterized by small-angle X-ray scattering (SAXS) and cryo-transmission electron microscopy as a DNA octahedron having a central cavity larger than the apertures in the surrounding DNA lattice. Starting from the SAXS data, a DNA nanocage has been modeled and simulated by classical molecular dynamics to evaluate in silico its structural properties and stability. Global properties, principal component analysis, and DNA geometrical parameters, calculated along the entire trajectory, indicate that the cage is stable and that the B-DNA conformation, also if slightly distorted, is maintained for all the simulation time. Starting from the initial model, the nanocage scaffold undergoes a contraction of the thymidine strands, connecting the DNA double helices, suggesting that the length of the thymidine strands is a crucial aspect in the modulation of the nanocage stability. A comparison of the average structure as obtained from the simulation shows good agreement with the SAXS experimental data.

Variant Plasmodium ovale isolated from a patient infected in Ghana

Recent data have found that Plasmodium ovale can be separated in two distinct species: classic and variant P. ovale based on multilocus typing of different genes. This study presents a P. ovale isolate from a patient infected in Ghana together with an analysis of the small subunit RNA, cytochrome b, cytochrome c oxidase I, cysteine protease and lactate dehydrogenase genes, which show that the sample is a variant P. ovale and identical or highly similar to variant P. ovale isolated from humans in South-East Asia and Africa, and from a chimpanzee in Cameroon. The split between the variant and classic P. ovale is estimated to have occurred 1.7 million years ago.