Analysis of Sources of Error in Quantitation of Purified DNA Fragments and Unpurified PCR Products by DNA Microchip Electrophoresis

We have investigated the accuracy and reproducibility of DNA quantitation on the DNA Lab-Chip and the relationship of these to the size and concentration of the DNA fragments. We found that quantitation of small DNA fragments, i.e. less than 200 bp, suffers from high relative error which can be improved by using an internal standard of similar size to the sample. The effects of trace chloride ion on quantitation error and sensitivity of the DNA Lab-Chip were also studied, and it was revealed that 0.2 mM chloride ion reduces quantitation sensitivity by 30% and increases the relative error. We also studied the effects of purification on quantitation errors in analysis of PCR products from cloning vector pUC118 and showed that use of an unpurified sample reduces chip sensitivity by 25%.Dedicated to Professor K. Jinno on the occasion of his 60^th birthday.Revised: 9 December 2004 and 17 January 2005     

Surface‐Assisted Large‐Scale Ordering of DNA Origami Tiles

The arrangement of DNA‐based nanostructures into extended higher order assemblies is an important step towards their utilization as functional molecular materials. We herein demonstrate that by electrostatically controlling the adhesion and mobility of DNA origami structures on mica surfaces by the simple addition of monovalent cations, large ordered 2D arrays of origami tiles can be generated. The lattices can be formed either by close‐packing of symmetric, non‐interacting DNA origami structures, or by utilizing blunt‐end stacking interactions between the origami units. The resulting crystalline lattices can be readily utilized as templates for the ordered arrangement of proteins.     

Applications of MALDI‐TOF MS to large‐scale human mtDNA population‐based studies

Analysis of the mitochondrial DNA variation in populations is commonly carried out in many fields of biomedical research. We propose the analysis of mitochondrial DNA coding region SNP (mtSNP) variation to a high level of phylogenetic resolution based on MALDI‐TOF MS. The African phylogeny has been chosen to test the applicability of the technique but any other part of the worldwide phylogeny (or any other mtSNP panel) could be equally suitable for MALDI‐TOF MS genotyping. SNP selection thus aimed to fully cover all the mtSNPs defining major and minor branches of the known African tree, including, macro‐haplogroup L, and haplogroups M1, and U6. A total of 230 mtSNPs were finally selected. We used tests samples collected from two different African locations, namely, Mozambique and Chad Basin. Different internal genotyping controls and other indirect approaches (e.g. phylogenetic checking coupled with automatic sequencing) were used in order to evaluate the reproducibility of the technique, which resulted to be 100% using samples previously subjected to whole genome amplification. The advantages of the MALDI‐TOF MS are also discussed in comparison with other popular methods such as minisequencing, highlighting its high‐throughput nature, which is particularly suitable for case–control medical studies, forensic databasing or population and anthropological studies.     

Sequence‐specific nucleic acid mobility using a reversible block copolymer gel matrix and DNA amphiphiles (lipid‐DNA) in capillary and microfluidic electrophoretic separations

Reversible noncovalent but sequence‐dependent attachment of DNA to gels is shown to allow programmable mobility processing of DNA populations. The covalent attachment of DNA oligomers to polyacrylamide gels using acrydite‐modified oligonucleotides has enabled sequence‐specific mobility assays for DNA in gel electrophoresis: sequences binding to the immobilized DNA are delayed in their migration. Such a system has been used for example to construct complex DNA filters facilitating DNA computations. However, these gels are formed irreversibly and the choice of immobilized sequences is made once off during fabrication. In this work, we demonstrate the reversible self‐assembly of gels combined with amphiphilic DNA molecules, which exhibit hydrophobic hydrocarbon chains attached to the nucleobase. This amphiphilic DNA, which we term lipid‐DNA, is synthesized in advance and is blended into a block copolymer gel to induce sequence‐dependent DNA retention during electrophoresis. Furthermore, we demonstrate and characterize the programmable mobility shift of matching DNA in such reversible gels both in thin films and microchannels using microelectrode arrays. Such sequence selective separation may be employed to select nucleic acid sequences of similar length from a mixture via local electronics, a basic functionality that can be employed in novel electronic chemical cell designs and other DNA information‐processing systems.     

Determination of DNA Hypermethylation Using Anti‐cancer Drug‐Temozolomide

An electrochemical drug‐DNA biosensor was developed for the detection of interaction between the anti‐cancer drug, Temozolomide (TMZ), and DNA sequences by using Differential Pulse Voltammetry at the graphite electrode surfaces. TMZ is a pro‐drug and an alkylating agent that crosses the blood‐brain barrier, so it is mainly used for brain cancers treatment. In this study, we aim to develop a‐proof‐of‐concept study to investigate the effect of TMZ on formerly methylated DNA sequences since TMZ shows its anti‐cancer activity by methylating the DNA. Interaction between TMZ and DNA causes localized distortion of DNA away from an idealized B‐form, resulting in a wider major groove and greater steric accessibility of functional groups in the base of the groove. According to the results, TMZ behaves as a ‘hybridization indicator’ because of its different electrochemical behavior to different strands of DNA. After interaction with TMZ, hybrid (double stranded DNA‐dsDNA) signals decreased dramatically whereas probe (single stranded DNA‐ssDNA) and control signals remain almost unchanged. The signal differences enabled us to distinguish ssDNA and dsDNA without using a label or tag. It is the first study to demonstrate the interaction between the TMZ and dsDNA created from probe and target. We use specific oligonucleotides sequences instead of using long dsDNA sequences.     

Assembly of DNA Nanostructures with Branched Tris‐DNA

Branched tris‐DNA, in which two oligonucleotides of the same sequence and one other oligonucleotide of a different sequence are connected with a rigid central linker, was prepared chemically by using a DNA synthesizer. Two branched tris‐DNA molecules with complementary DNA sequences form dimer and tetramer as well as linear and spherical oligomer complexes. The complex formation was studied by UV/thermal denaturation, enzyme digestion, gel electrophoresis, and AFM imaging.     

Binding‐Induced DNA Nanomachines Triggered by Proteins and Nucleic Acids

We introduce the concept and operation of a binding‐induced DNA nanomachine that can be activated by proteins and nucleic acids. This new type of nanomachine harnesses specific target binding to trigger assembly of separate DNA components that are otherwise unable to spontaneously assemble. Three‐dimensional DNA tracks of high density are constructed on gold nanoparticles functionalized with hundreds of single‐stranded oligonucleotides and tens of an affinity ligand. A DNA swing arm, free in solution, is linked to a second affinity ligand. Binding of a target molecule to the two ligands brings the swing arm to AuNP and initiates autonomous, stepwise movement of the swing arm around the AuNP surface. The movement of the swing arm, powered by enzymatic cleavage of conjugated oligonucleotides, cleaves hundreds of oligonucleotides in response to a single binding event. We demonstrate three nanomachines that are specifically activated by streptavidin, platelet‐derived growth factor, and the Smallpox gene. Substituting the ligands enables the nanomachine to respond to other molecules. The new nanomachines have several unique and advantageous features over DNA nanomachines that rely on DNA self‐assembly.     

Molecular dynamics of minimal B‐DNA

Stable and accurate molecular dynamics (MD) of B‐DNA duplexes can be obtained in inexpensive computational conditions where only the minor groove is filled with water while the bulk solvent is represented implicitly. This model system presents significant theoretical as well as practical interest because, due to its simplicity and exceptional computational performance, it can be employed in simulations of very long DNA fragments. To better understand its properties and clarify the physical background of the effects produced by the limited water shell, dynamics of several different DNA oligomers was studied. It is found that optimal simulation conditions are reached when the explicit water is confined within the minor groove while the major groove is cleaned periodically. The internal solvent mobility appears high enough to observe in the nanosecond time scale spontaneous formation of sequence‐specific hydration patterns known from experiments. It is shown that the model produces stable MD trajectories close to the B‐DNA form regardless of the base pair sequence and that, on the other hand, the dynamics are strongly sequence dependent. Independent observations suggest that B‐DNA with only minor groove hydrated resembles its natural thermodynamic state at low water concentration; therefore, this model system can be tentatively called “minimal B‐DNA.” © 2001 John Wiley & Sons, Inc. J Comput Chem 22: 457–467, 2001     

Direct Surface‐Enhanced Raman Scattering Analysis of DNA Duplexes

The exploration of the genetic information carried by DNA has become a major scientific challenge. Routine DNA analysis, such as PCR, still suffers from important intrinsic limitations. Surface‐enhanced Raman spectroscopy (SERS) has emerged as an outstanding opportunity for the development of DNA analysis, but its application to duplexes (dsDNA) has been largely hampered by reproducibility and/or sensitivity issues. A simple strategy is presented to perform ultrasensitive direct label‐free analysis of unmodified dsDNA with the means of SERS by using positively charged silver colloids. Electrostatic adhesion of DNA promotes nanoparticle aggregation into stable clusters yielding intense and reproducible SERS spectra at nanogram level. As potential applications, we report the quantitative recognition of hybridization events as well as the first examples of SERS recognition of single base mismatches and base methylations (5‐methylated cytosine and N6‐methylated Adenine) in duplexes.